DP83TG720S-Q1 [TI]
DP83TG720R-Q1 1000BASE-T1 Automotive Ethernet PHY;型号: | DP83TG720S-Q1 |
厂家: | TEXAS INSTRUMENTS |
描述: | DP83TG720R-Q1 1000BASE-T1 Automotive Ethernet PHY |
文件: | 总129页 (文件大小:2774K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
DP83TG720R-Q1
SNLS603B – DECEMBER 2020 – REVISED MARCH 2021
DP83TG720R-Q1 1000BASE-T1 Automotive Ethernet PHY
1 Features
2 Applications
•
•
IEEE802.3bp 1000BASE-T1 compliant
Open Alliance TC12 Interoperability and EMC
compliant
•
•
•
Telematics control unit (TCU, TBOX)
Gateway and body control
ADAS: LIDAR, RADAR, Front Camera
– Interoperability tested with OA/IEEE compliant
PHYs
3 Description
The DP83TG720R-Q1 device is an IEEE 802.3bp
and Open Alliance compliant automotive Ethernet
physical layer transceiver. It provides all physical layer
functions needed to transmit and receive data over
unshielded/shielded single twisted-pair cables. The
device supports RGMII for interfacing with a MAC.
– EMC immunity Class-IV compliant for UTP
(unshielded twisted pair)
Integrated LPF on MDI pins
•
•
•
•
MAC Interface: RGMII
Supported I/O voltages: 3.3 V, 2.5 V, and 1.8 V
Pin compatible with TI's 100BASE-T1 PHY
– Single board design for 100BASE-T1 and
1000BASE-T1 with required BOM change
Power savings features:
– standby and sleep
– local and remote wake-up
Diagnostic tool kit
– high accuracy temperature monitor
– voltage monitor
– ESD event monitor
– Data throughput calculator : inbuilt MAC packet
generator, counter and error checker
– link quality monitoring
– cable open and short fault detection
– loopback modes
DP83TG720 is compliant to Open Alliance EMC and
interoperable specifications over unshielded twisted
cable. DP83TG720 is pin-2-pin compatible to TI's
100Base-T1 PHY enabling design scalability with
single board for both speeds.This device offers the
Diagnostic Tool Kit, with an extensive list of real-
time monitoring tools, debug tools and test modes.
Within the tool kit is the first integrated electrostatic
discharge (ESD) monitoring tool. It is capable of
counting ESD events on both the xMII and MDI
as well as providing real-time monitoring through
the use of a programmable interrupt. Additionally,
the DP83TG720R-Q1 includes a data generator and
checker tool to generate customizable MAC packets
and check the errors on incoming packets.This
enables system level datapath tests/optimizations
without dependency on MAC.
•
•
•
•
•
25MHz clock output source
VQFN, wettable flank packaging
AEC-Q100 Qualified
– Inbuilt ESD protection : IEC61000-4-2 ESD :
±8-kV contact discharge
Device Information(1)
PART NUMBER
PACKAGE
BODY SIZE (NOM)
DP83TG720R-Q1
VQFN (36)
6.00 mm × 6.00 mm
– Device temperature grade 1: –40°C to +125°C
ambient operating temperature
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
RGMII
CMC
Automotive
Connector
DP83TG720R-Q1
1000 Mbps
Ethernet PHY
CPU/MPU
MAC
CM
Termination
25-MHz
Clock Source
Status
LEDs
GND
Figure 3-1. Simplified Schematic
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
DP83TG720R-Q1
SNLS603B – DECEMBER 2020 – REVISED MARCH 2021
www.ti.com
Table of Contents
1 Features............................................................................1
2 Applications.....................................................................1
3 Description.......................................................................1
4 Revision History.............................................................. 2
5 Device Comparison Table...............................................3
6 Pin Configuration and Functions...................................4
Pin Functions.................................................................... 5
7 Specifications.................................................................. 9
7.1 Absolute Maximum Ratings ....................................... 9
7.2 ESD Ratings .............................................................. 9
7.3 Recommended Operating Conditions ......................10
7.4 Thermal Information .................................................10
7.5 Electrical Characteristics ..........................................10
7.6 Timing Requirements ...............................................13
7.7 Timing Diagrams.......................................................17
7.8 LED Drive Characteristics.........................................21
8 Detailed Description......................................................22
8.1 Overview...................................................................22
8.2 Functional Block Diagram.........................................23
8.3 Feature Description...................................................24
8.4 Device Functional Modes..........................................40
8.5 Programming............................................................ 54
8.6 Register Maps...........................................................58
9 Application and Implementation................................ 112
9.1 Application Information............................................112
9.2 Typical Applications.................................................112
10 Power Supply Recommendations............................114
11 Compatibility with TI's 100BT1 PHY ........................117
12 Layout.........................................................................118
12.1 Layout Guidelines................................................. 118
13 Device and Documentation Support........................120
13.1 Receiving Notification of Documentation Updates120
13.2 Support Resources............................................... 120
13.4 Electrostatic Discharge Caution............................120
13.5 Glossary................................................................120
14 Mechanical, Packaging, and Orderable
Information.................................................................. 121
14.1 Package Option Addendum..................................121
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision A (February 2021) to Revision B (March 2021)
Page
•
IOZ, 2 level boot-strap's Mode 2 threshold and Rpull-down min/max datasheet limits updated to give more
margin to customer application...........................................................................................................................9
Min/Max values of rgmii DLL_TX_DELAY, sleep mode timing parameters, latency parameters, reset mode
power, standby mode power and sleep mode power added ............................................................................. 9
Changed Integrated Pull-Down Resistance from 4.5 kΩ to 4.725 kΩ.................................................................9
Further details added to remote sleep exit procedure...................................................................................... 43
Note added for more margins for 1.8V two level straps....................................................................................54
Updated Power Supply Recommendation Note............................................................................................. 114
•
•
•
•
•
Changes from Revision * (December 2020) to Revision A (February 2021)
Page
•
Pull-down resistor value of rx_cntrl and strp_1 pins in pin-state tables updated from 6 K to 6.3 K to match
exact value in specification ................................................................................................................................5
SQI section updated to meet OA requirements................................................................................................24
Strap circuit diagram updated to remove external pull-down............................................................................54
Register map enhanced with added description...............................................................................................58
•
•
•
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5 Device Comparison Table
PART
RGMII
SGMII
OPERATING
NUMBER
SUPPORT
SUPPORT
TEMPERATURE
DP83TG720R-Q1
DP83TG720S-Q1
Yes
Yes
No
–40°C to 125°C
–40°C to 125°C
Yes
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6 Pin Configuration and Functions
27
26
25
24
23
22
21
20
19
TX_CLK
TX_CTRL
TX_D3
28
29
30
31
32
33
34
35
36
18
17
16
15
14
13
12
11
10
DNC
DNC
CLKOUT / GPIO_2
RX_CTRL
STRAP_1
TRD_M
TRD_P
TX_D2
TX_D1
GND
TX_D0
VDDIO
LED_0 / GPIO_0
MDIO
VDDA
INH
1
2
3
4
5
6
7
8
9
Figure 6-1. RHA Package 36-Pin VQFN Top View
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Pin Functions
PIN
STATE(1)
DESCRIPTION
NAME
NO.
MAC INTERFACE
RX_D3
RX_D2
RX_D1
RX_D0
RX_CLK
23
Receive Data: Symbols received on the cable are decoded and transmitted out of these pins synchronous to
the rising edge of RX_CLK. They contain valid data when RX_DV(decoded from RX_CTL) is asserted. A nibble,
RX_D[3:0], is transmitted in RGMII mode.
24
25
26
27
S, PD, O
O
Receive Clock: In RGMII mode, PHY provides this 125-MHz clock to MAC.
RGMII Receive Control: Receive control combines receive data valid indication and receive error indication into a
single signal. RX_DV is presented on the rising edge of RX_CLK and RX_ER is presented on the falling edge of
RX_CLK.
RX_CTRL
15
S, PD, O
TX_CLK
28
29
I
I
Transmit Clock: In RGMII mode, MAC provides this 125-MHz clock to PHY.
RGMII Transmit Control: Transmit control combines transmit enable and transmit error indication into a single
TX_CTRL
signal. TX_EN is presented prior to the rising edge of TX_CLK; TX_ER is presented on the falling edge of TX_CLK.
TX_D3
TX_D2
30
31
I
Transmit Data: In RGMII mode, the transmit data nibble, TX_D[3:0], is received from the MAC .
TX_D1
TX_D0
32
33
SERIAL MANAGEMENT INTERFACE
MDC
1
I
Management Data Clock: Synchronous clock to the MDIO serial management input and output data.
Management Data Input/Output: Bidirectional management data signal that may be sourced by the management
MDIO
36
OD, IO
station or the PHY. This pin requires an external pull-up resistor (recommended value = 2.2-kΩ) .
CONTROL INTERFACE
Interrupt: Active-LOW output, which will be asserted LOW when an interrupt condition occurs. This pin has a weak
internal pullup. Register access is necessary to enable various interrupt triggers. Once an interrupt event flag is set,
register access is required to clear the interrupt event on this pin.
INT
2
PU, OD, O
This pin can be configured as an Active-HIGH output using register[0x0011].
RESET: Active-LOW input, which initializes or reinitializes the DP83TG720R-Q1. Asserting this pin LOW for at least
10 μs will force a reset process to occur. All internal registers will reinitialize to their default states as specified for
each bit in the Register Map section. All bootstrap pins are resampled upon deassertion of reset.
RESET
INH
3
PU, I
INH: Active-HIGH PMOS open-drain output. When the PHY enters the sleep state, PHY will release the INH pin
to allow an external pull-down resistor (recommended value = 10 kΩ) to pull the line to ground. When in any other
state, the INH pin will drive a HIGH state to the VSLEEP rail.
10
PMOS OD
WAKE: Active-HIGH (this pin works on VSLEEP domain) pulse on wake-up pin wakes up the PHY from the sleep
state. For pulse width, refer to timing section. This pin can be directly tied to the VSLEEP rail when the sleep state
is not used or left float.
WAKE
8
PD, I
PD, I
STRP_1
14
Strap 1: This pin is for strapping PHY_AD bits.
CLOCK INTERFACE
Reference Clock Input: Reference clock 25-MHz ±100 ppm-tolerance crystal or oscillator input. The device
supports either an external crystal resonator connected across pins XI and XO, or an external CMOS-level oscillator
connected to pin XI only and XO left floating.
XI
5
4
I
Reference Clock Output: XO pin is used for crystal only. This pin should be left floating when a CMOS-level
XO
O
oscillator is connected to XI.
LED/GPIO INTERFACE
LED_0 /
35
S, PD, IO
LED_0: Link Status
GPIO_0
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PIN
STATE(1)
DESCRIPTION
NAME
LED_1 /
NO.
6
S, PD, IO
IO
LED_1: Link Status and BLINK for TX/RX Activity
GPIO_1
Clock Output: 25-MHz reference clock(buffered replication of XI) by default. If not used, clock output can be
CLKOUT /
GPIO_2
16
disabled by writing register 0x0453 = 0x0006.
MEDIUM DEPENDENT INTERFACE
TRD_M
TRD_P
13
12
Differential Transmit and Receive: Bidirectional differential signaling configured for 1000BASE-T1 operation,
IO
IEEE 802.3bp compliant.
POWER AND GROUND CONNECTIONS
VDDA3P3
VDDIO
11
SUPPLY
SUPPLY
SUPPLY
Core Supply: 3.3 V. Refer to power supply recommendations for decoupling network.
IO Supply: 1.8 V, 2.5 V, or 3.3 V. Refer to power supply recommendations for decoupling network.
Core Supply: 1.0 V. Refer to power supply recommendations for decoupling network.
22, 34
9, 21
VDD1P0
Sleep Supply: 3.3 V. Refer to power supply recommendations for decoupling network.
VSLEEP
7
SUPPLY
This pin shall be tied to VDDA3P3 if sleep functionality is not used.
GROUND
DAP
GROUND
Ground
DO NOT CONNECT
DNC: Do Not Connect (test structures connected to these pins and should be kept floating to avoid damage or
17, 18,
19, 20
DNC
DNC
wrong mode entry of PHY)
(1) Type: I = Input
O = Output
IO = Input/Output
OD = Open Drain
PD = Internal Pulldown
PU = Internal Pullup
S = Strap: Configuration pin (all configuration pins have weak internal pullups or pulldowns)
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Table 6-1. Pin States - RGMII
POWER-UP / RESET
NORMAL OPERATION - RGMII
PULL VALUE
PIN
NAME
PULL VALUE
(kΩ)
PIN STATE
PULL TYPE
PIN STATE
PULL TYPE
(kΩ)
MDC
INT_N
RESET_N
XO
I
I
none
PU
-
9
9
-
I
OD
I
none
PU
-
9
9
-
I
PU
PU
O
I
none
none
PD
O
I
none
none
none
PD
XI
-
-
LED_1
WAKE
I
9
50
O
I
-
I
PD
50
STRP_1
INH
I
I
I
PD
none
PD
6.3
-
I
PMOS OD, O
O
none
none
none
-
-
-
RX_CTRL
6.3
CLKOUT/GPIO_2
RX_D3
O
I
none
PD
-
9
9
9
9
9
-
O
O
O
O
O
O
I
none
none
none
none
none
none
none
none
none
none
none
none
none
none
-
-
-
-
-
-
-
-
-
-
-
-
-
-
RX_D2
I
PD
RX_D1
I
PD
RX_D0
I
PD
RX_CLK
TX_CLK
TX_CTRL
TX_D3
I
PD
I
none
none
none
none
none
none
PD
I
-
I
I
-
I
TX_D2
I
-
I
TX_D1
I
-
I
TX_D0
I
-
I
LED_0
I
9
-
O
IO
MDIO
I
none
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Table 6-2. Pin States - Sleep and Isolate
MAC ISOLATE
SLEEP
PIN
PULL VALUE
(kΩ)
PULL VALUE
NAME
PIN STATE
PULL TYPE
PIN STATE
PULL TYPE
(kΩ)
MDC
INT_N
RESET_N
XO
I
O
I
none
PU
-
9
9
-
Float
Float
Float
Float
Float
Float
none
none
none
none
none
none
-
-
-
-
-
-
PU
O
I
none
none
none
XI
-
LED_1
O
-
WAKE
I
PD
50
I
none
50
STRP_1
INH
I
I
I
none
none
PD
-
-
Float
PMOS OD, O
Float
none
none
none
-
-
-
RX_CTRL
6.3
CLKOUT/GPIO_2
RX_D3
O
I
none
PD/none(1)
PD/none(1)
PD
-
9
9
9
9
9
-
Float
Float
Float
Float
Float
Float
Float
Float
Float
Float
Float
Float
Float
Float
none
none
none
none
none
none
none
none
none
none
none
none
none
none
-
-
-
-
-
-
-
-
-
-
-
-
-
-
RX_D2
I
RX_D1
I
RX_D0
I
PD
RX_CLK
TX_CLK
TX_CTRL
TX_D3
I
PD
I
none
I
none
-
I
none
-
TX_D2
I
none
-
TX_D1
I
none
-
TX_D0
I
none
-
LED_0
O
IO
none
-
MDIO
none
-
(1) PD only for Rgmii's isolate mode.
Note
For sleep mode entry vdda, vddio and vdd1p0 are supposed to be powered-down. See figure
Required Implementation of Sleep Mode for further details.
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7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)
MIN
TYP
MAX
UNIT
Supply
VDDA3P3
Voltage
-0.5
4
V
Supply
VDD1P0
Voltage
-0.5
-0.5
-0.5
-0.5
1.4
4
V
V
V
V
Supply
VDDIO (3.3V)
Voltage
Supply
VDDIO (2.5V)
Voltage
2.9
2.2
Supply
VDDIO (1.8V)
Voltage
Supply
VSLEEP
Voltage
-0.5
-0.5
4
4
V
V
MDI Pins
TRD_M, TRD_P
LVCMOS/
LVTTL Input
Voltage
MDC, RESET, XI, LED_1, STRP_1, RX_CTRL, CLKOUT,
RX_D[3:0], TX_CLK, TX_CTRL, TX_D[3:0], LED_0, MDIO
-0.5
-0.5
-0.5
-0.5
VDDIO + 0.3
VSLEEP + 0.3
VDDIO + 0.3
V
V
V
V
LVCMOS/
LVTTL Input WAKE
Voltage
LVCMOS/
LVTTL Output
Voltage
INT, LED_1, RX_CTRL, CLKOUT, RX_D[3:0], RX_CLK,
LED_0, MDIO
LVCMOS/
LVTTL Output INH
Voltage
VSLEEP +
0.3
TJ
Junction Temperature
Storage temperature
150
150
°C
°C
Tstg
-65
(1) Stresses beyond those listed under Absolute Maximum Rating may cause permanent damage to the device. These are stress
ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated
under Recommended Operating Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device
reliability.
7.2 ESD Ratings
VALUE UNIT
Human body model (HBM), per
V(ESD) Electrostatic discharge
V(ESD) Electrostatic discharge
All pins
±2000
±8000
V
V
AEC Q100-002(1)
Human body model (HBM), per
AEC Q100-002(1)
TRD_M, TRD_P
Charged device model (CDM), per
AEC Q100-011
V(ESD) Electrostatic discharge
V(ESD) Electrostatic discharge
All pins
±500
V
V
IEC 61000-4-2 contact discharge
TRD_M, TRD_P
±8000
(1) AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
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7.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
1.62
2.25
2.97
2.97
0.95
2.97
–40
NOM
1.8
2.5
3.3
3.3
1
MAX
1.98
2.75
3.63
3.63
1.1
UNIT
IO Supply Voltage, 1.8V operation
VDDIO
IO Supply Voltage, 2.5V operation
IO Supply Voltage, 3.3V operation
V
VDDA3P3 Core Supply Voltage, 3.3V
VDDA1P0 Core Supply Voltage, 1.0V
V
V
VSLEEP
TA
Sleep Supply Voltage, 3.3V
Ambient temperature
3.3
3.63
125
V
°C
7.4 Thermal Information
DP83TG720
THERMAL METRIC(1)
RHA (VQFN)
36 PINS
32.5
UNIT
RθJA
Junction-to-ambient thermal resistance
Junction-to-case (top) thermal resistance
Junction-to-board thermal resistance
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
RθJC(top)
RθJB
22.2
13.3
ΨJT
Junction-to-top characterization parameter
Junction-to-board characterization parameter
Junction-to-case (bottom) thermal resistance
0.3
ΨJB
13.3
RθJC(bot)
3.2
(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report.
7.5 Electrical Characteristics
Over operating free-air temperature range (unless otherwise noted)(1)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DC CHARACTERISTICS
XI
VIH
VIL
High-level Input Voltage
Low-level Input Voltage
1.3
V
V
0.5
WAKE
pin
WAKE
pin
WAKE
pin
WAKE WAKE
WAKE pin
WAKE pin
pin
pin
VIH
VIL
High-level Input Voltage
Low-level Input Voltage
VSLEEP = 3.3V ± 10%
VSLEEP = 3.3V ± 10%
INH pin
2
V
0.8
V
INH pin INH pin
INH pin INH pin INH pin INH pin
VOH
High-level Output Voltage
IOH = -2mA, VSLEEP = 3.3V ± 10%
2.4
2.4
2
V
3.3V VDDIO (2)
VOH
VOL
VIH
VIL
High-level Output Voltage
IOH = -2mA, VDDIO = 3.3V ± 10%
IOL = 2mA, VDDIO = 3.3V ± 10%
VDDIO = 3.3V ± 10%
V
V
V
V
Low-level Output Voltage
High-level Input Voltage
Low-level Input Voltage
0.4
0.8
VDDIO = 3.3V ± 10%
2.5V VDDIO (2)
VOH
VOL
VIH
VIL
High-level Output Voltage
IOH = -2mA, VDDIO = 2.5V ± 10%
IOL = 2mA, VDDIO = 2.5V ± 10%
VDDIO = 2.5V ± 10%
2
V
V
V
V
Low-level Output Voltage
High-level Input Voltage
Low-level Input Voltage
0.4
0.7
1.7
VDDIO = 2.5V ± 10%
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Over operating free-air temperature range (unless otherwise noted)(1)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
1.8V VDDIO (2)
VDDIO –
0.45
VOH
VOL
VIH
High-level Output Voltage
Low-level Output Voltage
High-level Input Voltage
IOH = -2mA, VDDIO = 1.8V ± 10%
IOL = 2mA, VDDIO = 1.8V ± 10%
VDDIO = 1.8V ± 10%
V
V
V
0.45
0.7 *
VDDIO
0.3 *
VDDIO
VIL
IIH
IIH
Low-level Input Voltage
VDDIO = 1.8V ± 10%
V
Input High Current (MDIO)
VIN = VCC, -40°C to 125°C
VIN = VCC, -40°C to 125°C
-5
5
µA
µA
Input High Current (RGMII Input
pin,MDC)
-20
20
VIN swept from 0V till VCC, -40°C to
125°C
IOZ
Input High Current (MDIO)
-40
-40
40
µA
Input Low Current (RGMII Input pin,
MDC, MDIO)
IIL
VIN = GND, -40°C to 125°C
INH
5
6
µA
µA
µA
IOZL
IOZ
VIN swept from 0V till VCC, -40°C to
125°C
Tri-state Output Current (5)
-40
-60
10
VIN swept from 0V till VCC, -40°C to
125°C
IOZ
Tri-state Output Current (6)
Input Capacitance
60
µA
CIN
LVCMOS/LVTTL pins (3)
LVCMOS/LVTTL pins (4)
XI
2
4
pF
pF
pF
pF
pF
pF
kΩ
kΩ
kΩ
kΩ
CIN
Input Capacitance
1
COUT
COUT
Rpull-up
Output Capacitance
LVCMOS/LVTTL pins (3)
LVCMOS/LVTTL pins (4)
XO
2
4
Output Capacitance
1
Integrated Pull-Up Resistance
INT, RESET
6.5
4.725
7.3
9
6.3
9
12.5
7.875
13
Rpull-down Integrated Pull-Down Resistance
STRP_1, RX_CTRL
LED_1, RX_D[3:0], RX_CLK, LED_0
WAKE
Rpull-down Integrated Pull-Down Resistance
35
50
62.5
Integrated Pull-Up Resistance when
Rpull-down
Active
INH
106
42
Ω
Ω
Integrated MAC Series Termination
Resistor ( Default)
Rseries
RX_D[3:0], RX_CTRL, and RX_CLK
24
30
52
65
Integrated MAC Series Terminatin
Rseries Resistor (with register<0x0456> =
0x0148)
RX_D[3:0], RX_CTRL, and RX_CLK
RX_D[3:0], RX_CTRL, and RX_CLK
52
70
Ω
Ω
Integrated MAC Series Terminatin
Rseries Resistor (with register<0x0456> =
0x0168)
40
84
CURRENT CONSUMPTION, SLEEP MODE
ISLEEP
Sleep Supply Current
VSLEEP
485
840
µA
CURRENT CONSUMPTION, RESET ASSERTED
IDDIO
IO Supply Current, VDDIO = 1.8V
IO Supply Current, VDDIO = 2.5V
IO Supply Current, VDDIO = 3.3V
Core Supply Current, 3.3V
VDDIO
4
5
9
12
15
8
mA
mA
mA
mA
mA
IDDIO
VDDIO
IDDIO
VDDIO
6.5
5
IDDA3P3
IDD1P0
VDDA3P3
VDD1P0
Core Supply Current, 1.0V
30
110
CURRENT CONSUMPTION, STANDBY
IDDIO IO Supply Current, VDDIO = 1.8V
VDDIO
4
11
mA
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Over operating free-air temperature range (unless otherwise noted)(1)
PARAMETER
TEST CONDITIONS
MIN
TYP
6
MAX
UNIT
mA
IDDIO
IO Supply Current, VDDIO = 2.5V
IO Supply Current, VDDIO = 3.3V
Core Supply Current, 3.3V
Core Supply Current, 1.0V
VDDIO
13
15
IDDIO
VDDIO
8
mA
IDDA3P3
IDD1P0
VDDA3P3
VDD1P0
16
33
18
mA
112
mA
CURRENT CONSUMPTION, ACTIVE MODE, Voltage: +/- 10%, Traffic : 100%,Packet Size: 1518, Content : Random
IDDIO
IO Supply Current, VDDIO = 1.8V
IO Supply Current, VDDIO = 2.5V
IO Supply Current, VDDIO = 3.3V
Core Supply Current, 3.3V
RGMII
20
26
25
30
mA
mA
mA
mA
mA
µA
IDDIO
RGMII
IDDIO
RGMII
33
40
IDDA3P3
IDD1P0
ISLEEP
RGMII
85
89
Core Supply Current, 1.0V
RGMII
177
1000
250
1500
Sleep Supply Current
VSLEEP = 3.3V +/- 10%
MDI CHARACTERISTICS
VOD-MDI Output Differential Voltage
RL(diff) = 100 Ω
1.3
V
Integrated Differential MDI Termination
(Active State)
RMDI-DIFF
TRD_P, TRD_M
100
100
Ω
Integrated Differential MDI Termination
(Sleep State)
RMDI-DIFF
TRD_P, TRD_M
Ω
BOOTSTRAP DC CHARACTERISTICS
2 level
straps
0.35*VD
DIO
Vbsl_1v8 Bootstrap Threshold
Mode 1, VDDIO = 1.8V ± 10%, 2-level
0
V
Vbsh_1v
Bootstrap Threshold
8
Mode 2, VDDIO = 1.8V ± 10%, 2-level
Mode 1, VDDIO = 2.5V ± 10%, 2-level
Mode 2, VDDIO = 2.5V ± 10%, 2-level
Mode 1, VDDIO = 3.3V ± 10%, 2-level
Mode 2, VDDIO = 3.3V ± 10%, 2-level
1.175
0
VDDIO
0.7
V
V
V
V
V
Vbsl_2v5 Bootstrap Threshold
Vbsh_2v
Bootstrap Threshold
5
1.175
0
VDDIO
0.7
Vbsl_3v3 Bootstrap Threshold
Vbsh_3v
Bootstrap Threshold
3
1.175
VDDIO
3 level
straps
0.35 *
VDDIO
Vbs1_1V8 Bootstrap Threshold
Vbs2_1V8 Bootstrap Threshold
Vbs3_1V8 Bootstrap Threshold
Vbs1_2V5 Bootstrap Threshold
Vbs2_2V5 Bootstrap Threshold
Vbs3_2V5 Bootstrap Threshold
Vbs1_3V3 Bootstrap Threshold
Vbs2_3V3 Bootstrap Threshold
Mode 1, VDDIO = 1.8V ± 10%, 3-level
Mode 2, VDDIO = 1.8V ± 10%, 3-level
Mode 3, VDDIO = 1.8V ± 10%, 3-level
Mode 1, VDDIO = 2.5V ± 10%, 3-level
Mode 2, VDDIO = 2.5V ± 10%, 3-level
Mode 3, VDDIO = 2.5V ± 10%, 3-level
Mode 1, VDDIO = 3.3V ± 10%, 3-level
Mode 2, VDDIO = 3.3V ± 10%, 3-level
Mode 3, VDDIO = 3.3V ± 10%, 3-level
0
V
V
V
V
V
V
V
V
V
0.40 *
VDDIO
0.75 *
VDDIO
0.84 *
VDDIO
VDDIO
0.19 *
VDDIO
0
0.27 *
VDDIO
0.41 *
VDDIO
0.58 *
VDDIO
VDDIO
0.18 *
VDDIO
0
0.22 *
VDDIO
0.42 *
VDDIO
0.46 *
VDDIO
Vbs3_3V3 Bootstrap Threshold
Temperature Sensor
VDDIO
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Over operating free-air temperature range (unless otherwise noted)(1)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Temperature Sensor Resolution (LSB)
-40℃ to 125℃
-40℃ to 125℃
1.5
℃
Temperature Sensor Accuracy ( Voltage
and Temperature Variation on single part)
-7.5
7.5
℃
Temperature Sensor Accuracy ( Voltage,
Temperature and Part-to-Part variation)
-40℃ to 125℃
-21.5
-40
20
℃
℃
Temperature Sensor Range
140
Voltage Sensor
VDDA3P3 Sensor Range
2.66
3.3
8.6
3.96
V
VDDA3P3 Sensor Resolution (LSB)
-40℃ to 125℃
-40℃ to 125℃
mV
VDDA3P3 Sensor Accuracy ( Voltage and
Temperature Variation)
8.6
mV
VDDA3P3 Sensor Accuracy Part-to-Part -40℃ to 125℃
-68.8
0.8
68.8
1.2
mV
V
VDD1P0 Sensor Range
VDD1P0 Sensor Resolution (LSB)
-40℃ to 125℃
-40℃ to 125℃
-40℃ to 125℃
2.8
2.8
mV
VDD1P0 Sensor Accuracy ( Voltage and
Temperature Variation)
mV
VDD1P0 Sensor Accuracy Part-to-Part
VDDIO Sensor Range
-22.4
1.44
22.4
3.8
mV
V
VDDIO Sensor Resolution (LSB)
-40℃ to 125℃
-40℃ to 125℃
-40℃ to 125℃
15.4
15.4
mV
VDDIO Sensor Accuracy ( Voltage and
Temperature Variation)
mV
mV
VDDIO Sensor Accuracy Part-to-Part
-78
78
(1) Ensured by production test, characterization or design
(2) For pins: LED_1, STRP_1, RX_CTRL, CLKOUT, RX_D[3:0], RX_CLK, LED_0
(3) For pins: MDC, INT, RESET, LED_1, STRP_1, RX_CTRL, CLKOUT, RX_D0, RX_D1, RX_CLK, TX_CLK, TX_CTRL, TX_D2, TX_D3,
LED_0, and MDIO
(4) For pins: TX_D0, TX_D1, RX_D2, and RX_D3
(5) For pins : LED_1, RX_D[3:0], RX_CLK, LED_0
(6) For pins : STRP_1 and RX_CTRL
7.6 Timing Requirements
(1)
TEST
CONDITIONS
PARAMETER
MIN
NOM
MAX
UNIT
POWER-UP TIMING
0% to 100% (+/- 10
VDDA3P3)
T5.1
T5.2
VDDA3P3 Duration(2)
0.5
0.1
40
40
ms
ms
0% to 100% (+/- 10
VDD1P0)
VDD1P0 Duration(2)
T5.2
T5.2
T5.2
VDDIO Duration(2)
VDDIO Duration(2)
VDDIO Duration(2)
VDDIO = 1.8V
VDDIO = 2.5V
VDDIO = 3.3V
0% to 100% (+/- 10
0.1
0.1
0.1
40
40
40
ms
ms
ms
(2)
T5.2
T5.3
T5.4
VSLEEP Duration
0.1
40
ms
µs
VSLEEP
)
Crystal stabilization-time post power-up (from last power rail
ramp to 100%)
1500
Osillator stabilization-time post power-up ( from last power
rail ramp to 100%)(3)
20
ms
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(1)
TEST
CONDITIONS
PARAMETER
MIN
NOM
MAX
UNIT
Post power-up stabilization-time prior to MDC preamble for
register access
T5.5
65
ms
ms
ns
T5.6
T5.7
T5.8
Hardware configuration latch-in time from power-up
60
110
60
Hardware configuration pins transition to functional mode from
latch-in completion
PAM3 IDLE Stream from power-up (Master Mode)
ms
RESET TIMING (RESET_N)
T6.1
T6.2
T6.3
T6.4
T6.5
RESET pulse width
5
1
µs
ms
µs
µs
µs
Post reset stabilization-time prior to MDC preamble for register
access
Hardware configuration latch-in time from reset
2
1.5
Hardware configuration pins transition to functional mode from
latch-in completion
PAM3 IDLE Stream from reset (Master Mode)
1500
SMI TIMING
T4.1
T4.2
T4.3
MDC to MDIO (Output) Delay Time (25 pF load)
0
10
10
6
10
20
ns
ns
MDIO (Input) to MDC Setup Time
MDIO (Input) to MDC Hold Time
MDC Frequency ( 25 pF load)
ns
2.5
MHz
RECEIVE LATENCY TIMING
SSD symbol on MDI to Rising edge of RGMII RX_CLK with
8
µs
ns
assertion of RX_CTRL
SSD symbol on MDI to Rising edge of RGMII RX_CLK with
assertion of RX_CTRL (RS-FEC bypass mode)
400
TRANSMIT LATENCY TIMING
RGMII Rising edge TX_CLK with assertion TX_CTRL to SSD
symbol on MDI
0.8
µs
ns
RGMII Rising edge TX_CLK with assertion TX_CTRL to SSD
symbol on MDI (RS-FEC bypass mode)
600
25 MHz OSCILLATOR REQUIREMENTS
Frequency (XI)
25
50
MHz
ppm
ns
Frequency Tolerance and Stability Over temperature and aging
Rise / Fall Time (10% - 90%)(6)
–100
40
100
8
Integrated upto
5MHz
Jitter (RMS)
Duty Cycle
1
ps
%
60
RGMII TIMING
TsetupR
TholdR
TX_D[3:0], TX_CTRL Setup to TX_CLK
on PHY pins
on PHY pins
1
1
2
2
ns
ns
TX_D[3:0], TX_CTRL Hold from TX_CLK (5)
RX_D[3:0], RX_CTRL Delay from RX_CLK (Align Mode
Enabled)
TskewT
On PHY Pins
On PHY Pins
-500
0
500
ps
ns
TskewT
RX_D[3:0], RX_CTRL Delay from RX_CLK (Shift Mode
Enabled, default)(4)
2.240
2.650
2.970
(Shift)
Tcyc
Tcyc
Clock Cycle Duration
Clock Cycle Duration
RX_CLK
7.2
7.2
45
8
8
8.8
8.8
55
ns
ns
%
TX_CLK
Duty_G Duty Cycle
Duty_G Duty Cycle
RX_CLK
50
50
TX_CLK
45
55
%
Tr
Rise Time (20% - 80%)
CL=Ctrace=5pF
0.75
ns
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(1)
TEST
CONDITIONS
PARAMETER
Fall Time (20% - 80%)
MIN
NOM
MAX
UNIT
Tf
CL=Ctrace = 5pF
0.75
ns
RGMII
RX Shift
Mode
DLL DLL_RX_DELAY_CTRL_SL=0(4)
0.330
0.650
0.970
ns
Delays
DLL DLL_RX_DELAY_CTRL_SL=1(4)
DLL DLL_RX_DELAY_CTRL_SL=2(4)
DLL DLL_RX_DELAY_CTRL_SL=3(4)
DLL DLL_RX_DELAY_CTRL_SL=4(4)
DLL DLL_RX_DELAY_CTRL_SL=5(4)
DLL DLL_RX_DELAY_CTRL_SL=6(4)
DLL DLL_RX_DELAY_CTRL_SL=7(4)
DLL DLL_RX_DELAY_CTRL_SL=8(4)
DLL DLL_RX_DELAY_CTRL_SL=9(4)
0.580
0.830
1.000
1.230
1.490
1.690
1.960
2.180
2.490
0.900
1.150
1.400
1.650
1.990
2.150
2.400
2.650
2.900
1.220
1470
ns
ns
ns
ns
ns
ns
ns
ns
ns
1.720
1.970
2.220
2.470
2.730
2.970
3.220
RGMII
Shift TX
Mode
Delays
DLL DLL_TX_DELAY_CTRL_SL=1(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=2(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=3(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=4(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=5(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=6(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=7(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=8(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=9(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=10(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=11(4) (7)
DLL DLL_TX_DELAY_CTRL_SL=12(4) (7)
0.08
0.27
0.51
0.75
0.94
1.18
1.37
1.61
1.85
2.04
2.28
2.52
0.25
0.49
0.73
0.97
1.21
1.45
1.69
1.93
2.17
2.42
2.65
2.9
0.38
0.67
0.91
1.15
1.44
1.68
1.98
2.22
2.46
2.75
2.99
3.23
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
25 MHz CRYSTAL REQUIREMENTS
Frequency
25
MHz
ppm
Ω
Frequency Tolerance and Stability Over temperature and aging
–100
45
100
50
Equivalent Series Resistance
OUTPUT CLOCK TIMING (CLKOUT)
Frequency
25
MHz
%
Duty Cycle ( With crystal attached)
55
2.5
5
Rise / Fall Time (10% - 90%)
ns
Jitter (RMS) (Slave Mode, MAC Iinterface : SGMII)
Jitter (RMS) (Master Mode, MAC Iinterface : SGMII)
Jitter (RMS) (Slave Mode, MAC Interface : RGMII)
Jitter (RMS) (Master Mode, MAC Interface : RGMII)
Sleep Entry and Wake-Up
ps
2.4
11
ps
ps
15
ps
Normal Mode,
MDI_Energy =
FALSE sleep_en =
TRUE
WAKE LOW to Sleep Entry; INH Transition LOW
64
85
us
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(1)
TEST
CONDITIONS
PARAMETER
MIN
NOM
MAX
UNIT
Normal Mode,
WAKE = LOW,
MDI_Energy =
FALSE
sleep_en = True to Sleep Entry; INH Transition LOW (master
mode)
5
85
us
Normal Mode,
WAKE = LOW,
MDI_Energy =
FALSE
sleep_en = True to Sleep Entry; INH Transition LOW (slave
mode)
5000
5
us
Normal Mode,
WAKE = LOW,
sleep_en = TRUE
MDI Energy Loss to Sleep Entry; INH Transition LOW
ms
Sleep Mode, WAKE
pin
Local Wake-Up Pulse Duration (on Wake pin)
80
µs
Send-S/Send-T pattern duration for wake up from MDI
Sleep Mode, Slave
1.25
ms
Sleep Mode, rising
edge of WAKE pin
to rising edge of
INH
Local Wake-Up; INH Transition HIGH
85
us
Tolerable differential noise level on MDI for PHY to stay in sleep
mode
Sleep Mode
Sleep Mode
200 mV pk-pk
mV pk-pk
Link-partner's VOD for valid wake-up (for 5m cable)
840
(1) Ensured by production test or characterization or design.
(2) No supply sequencing constraint across power rails
(3) In case OSC clock is delayed, additional reset is needed post Osc clock stablisation
(4) Refer register[0x0430] for programmability of RX and TX delay codes
(5) PHY provides internal delays on TX_CLK to TX_D[3:0] to add additional skew upto 2 ns. Refer to register[0x0430] for programmability
(6) Max rise/fall time of 8ns is supported for duty cycle of 40% to 55%. Max rise/fall time will be 6 ns for duty cycle of 40% to 60%
(7) Data for 1.8V VDDIO.
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7.7 Timing Diagrams
XI(crystal)
XI(oscillator)
T5.1
T5.2
VDDA
VDDIO/ VDD1P0/ Vsleep
MDC
tT5.5t
Bootstrap
Latch-in
tT5.6t
Active
I/O Pins
tT5.7t
+1
PAM3
0
(Master)
-1
Figure 7-1. Power Up Timing
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VVDD
XI
tT6.1t
Hardware
RESET_N
MDC
tT6.2t
tT6.3t
Bootstrap
Latch-in
Active
I/O Pins
tT6.4t
tT6.5t
+1
PAM3
0
(Master)
-1
Figure 7-2. Reset Timing
tTcyc
t
TX_CLK
Thold(shift)
TX_D[3:0]
Valid Data
Valid Data
Valid Data
Tsetup(shift)
TX_CTRL
TX_ER
TX_EN
TX_ER
TX_EN
Figure 7-3. RGMII Transmit Timing (Internal Delay Enabled)
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tTcyc
t
TX_CLK
TX_D[3:0]
TX_CTRL
Thold(align)
Valid Data
Valid Data
Valid Data
Tsetup(align)
TX_EN
TX_ER
TX_EN
TX_ER
Figure 7-4. RGMII Transmit Timing (Internal Delay Disabled)
tTcyc
t
RX_CLK
RX_D[3:0]
RX_CTRL
Tskew(shift)
Valid Data
Valid Data
Valid Data
Tskew(shift)
RX_DV
RX_ER
RX_DV
RX_ER
RX_DV
Figure 7-5. RGMII Receive Timing (Internal Delay Enabled)
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tTcyc
t
RX_CLK
RX_D[3:0]
RX_CTRL
Tskew(align)
Valid Data
Valid Data
RX_DV
RX_ER
RX_DV
Figure 7-6. RGMII Receive Timing (Internal Delay Disabled)
MDC
MDIO
MDIO
tT4.2t
tT4.3t
Valid Data
tT4.1t
Valid Data
Figure 7-7. Serial Management Timing
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7.8 LED Drive Characteristics
Figure 7-8. LED V vs I for 3.3V VDDIO
Figure 7-9. LED V vs I for 2.5V VDDIO
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8 Detailed Description
8.1 Overview
The DP83TG720R-Q1 is a 1000BASE-T1 automotive Ethernet Physical Layer transceiver. It is IEEE 802.3bp
compliant and AEC-Q100 qualified for automotive applications.
This device is specifically designed to operate at 1-Gbps speed while meeting stringent automotive EMC
requirements. The DP83TG720R-Q1 transmits PAM3 ternary symbols at 750-MBd over unshielded/shielded
single-twisted pair cable. It is designed for RGMII support in a single 36-pin VQFN wettable flank package.
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8.2 Functional Block Diagram
Figure 8-1. DP83TG720R-Q1 Functional Block Diagram
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8.3 Feature Description
8.3.1 Diagnostic Tool Kit
The DP83TG720R-Q1 diagnostic tool kit provides mechanisms for monitoring normal operation, device-level
debugging, system-level debugging, fault detection, and compliance testing. This tool kit includes a built-in
self-test with PRBS data, various loopback modes, Signal Quality Indicator (SQI), Time Domain Reflectometry
(TDR), voltage monitor, temperature monitor, electrostatic discharge monitor, and IEEE 802.3bp test modes.
8.3.1.1 Signal Quality Indicator
When the DP83TG720R-Q1 is active, the Signal Quality Indicator may be used to determine the quality of link
based on SNR readings made by the device.
SQI is derived based on the calculated SNR value and is presented as five level indication, where level of 4
ensures a BER better than 10-10
.
Note
Refer to DP83TG720: Configuring for Open Alliance Specification Compliance application note for
details on using SQI register for Open Alliance TC12 SQI tests.
8.3.1.2 Time Domain Reflectometry
Time domain reflectometry helps detecting and estimating the location of OPEN and SHORT faults along a
cable.
TDR is activated by setting bit[15] = 'b1 in the register[0x001E]. When TDR diagnostic process gets completed
successfully, Bit[1:0] of register[0x001E] will become 'b10. After this status change, TDR results can be read in
the register of following table.
Table 8-1. TDR Result Registers : 0x030F
Register Bits
Description
[1:0]
•
•
•
01 = TDR Activation
10 = TDR On
00,11 = TDR Not Available
[3:2]
[7:4]
Reserved
•
•
•
•
•
•
•
0011 = Short
0110 = Open
0101 = Noise
0111 = Cable OK
1000 = Test in progress; initial value with TDR ON
1101 = Test not possible (for example, noise, active link)
Other values are not valid
[13:8]
•
•
Fault distance = Value in decimal of [13:8]
'b111111 = Resolution not possible/out of distance
[15:14]
Reserved
Note
TDR should not be run if the link is already active. Running TDR on active line can make TDR fail and
also can result in disruption of link.
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8.3.1.3 Built-In Self-Test For Datapath
The DP83TG720R-Q1 incorporates a data-path’s Built-In-Self-Test (BIST) to check the PHY level and system
level data-paths. BIST has following integrated features which make the system level data transfer tests
(through-put etc) and diagnostics possible without relying on MAC or external data generator hardware/software.
1. Loopback modes
2. Data generator
a. Customizable MAC packets generator.
b. Transmitted packet counter.
c. PRBS stream generator.
3. Data checker
a. Received MAC packets error checker.
b. Received packet counter: Counts total packets received and packets received with errors.
c. PRBS lock and PRBS error checker.
8.3.1.3.1 Loopback Modes
Data
Generator
Data
Checker
MAC
Figure 8-2. All Loopbacks
There are several loopback options within the DP83TG720R-Q1. Enabling different loopback modes enables/
bypass different data-paths according to system verification requirements. Different loopbacks can be enabled
along-side following data generation options :
a. Inbuilt data-generator
b. External data-generator (on Ethernet cable or MAC side)
Following diagrams illustrate data-flow during different loopback options :
Data
Generator
Data
Checker
MAC
Figure 8-3. Analog Loopback With Inbuilt Data-Gen
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Data
Generator
Data
Checker
MAC
Figure 8-4. Analog Loopback With External Data-Gen
Data
Generator
Data
Checker
MAC
MAC
MAC
Figure 8-5. Digital Loopback With Inbuilt Data-Gen
Data
Generator
Data
Checker
Figure 8-6. Digital Loopback With External Data-Gen
Data
Generator
Data
Checker
Figure 8-7. PCS Loopback With Inbuilt Data-Gen
Data
Generator
Data
Checker
MAC
Figure 8-8. PCS Loopback With External Data-Gen
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Data
Generator
Data
Checker
MAC
Figure 8-9. xMII Loopback With External Data-Gen
Data
Generator
Data
Checker
MAC
Figure 8-10. xMII Reverse Loopback With External Data-Gen
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8.3.1.3.2 Data Generator
Data generator can be programmed to generate either user defined MAC packets or PRBS stream.
Following
parameters
of
generated
MAC
packets
can
be
configured
(refer
to
registers<0x061B>,register<0x061A> and register<0x0624> for required configuration):
•
•
•
•
•
Packet Length
Inter-packet gap
Defined number of packets to be sent or continuous transmission
Packet data-type: Incremental/Fixed/PRBS
Number of valid bytes per packet
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8.3.1.3.3 Programming Datapath BIST
Following register settings enable different loopbacks, data generation and data checker procedures:
Table 8-2. Datapath BIST Programming
Loopback
Mode
To enable loopback mode
To enable
data
To check in- To enable
coming MAC data
To check in- Other care-
coming
abouts
generator
packets
generator
PRBS status:
and checker: status
MAC packets
and checker: PRBS stream
PRBS stream
1
Analog
loopback
Step 1 : write :
reg[0x0620]
(1) = 1'b1
•
•
write : reg[0x0016]=0x0008
write: reg[0x0405]=0x2800
•
•
write :
•
•
•
read :
•
•
write :
•
•
Disconne
reg[0x061
9]=0x155
5
reg[0x063
C] for
reg[0x061
9]=0x055
7
ct the
cable/link-
partner.
Step 2 :
(15:0) of
total
•
read :
write :
write :
Generate
d data will
be going
to MAC
side, to
disable
MAC
reg[0x062
0](7:0) =
Number
of error
bytes
received
packets
count.
reg[0x062
4]=0x55B
F
reg[0x062
4]=0x55B
F
read :
reg[0x063
D] for
received.
•
read :
(31:16) of
total
side :
reg[0x062
0](8) (1
indicates
PRBS
write
received
packets
count.
reg[0x000
0]=0x054
0
data is
read :
coming in
and
reg[0x063
E] for
checker is
locked)
Packets
received
with CRC
errors
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Table 8-2. Datapath BIST Programming (continued)
Loopback
Mode
To enable loopback mode
To enable
data
To check in- To enable
coming MAC data
To check in- Other care-
coming
abouts
generator
packets
generator
PRBS status:
and checker: status
MAC packets
and checker: PRBS stream
PRBS stream
2
Digital loopback
Step 1 : write :
reg[0x0620][1]
= 1'b1
•
•
write : reg[0x0016] =
0x0004
•
•
write :
•
•
•
read :
•
•
write :
•
Generate
d data will
be going
to Cu
reg[0x061
9]=0x155
5
reg[0x063
C] =
reg[0x061
9]=0x055
7
write : reg[0x0800][11]=1
Step 2 :
[15:0] of
total
•
read :
cable
write :
write :
reg[0x062
0][7:0] =
Number
of error
bytes
received
packets
count.
side, to
disable
this
reg[0x062
4]=0x55B
F
reg[0x062
4]=0x55B
F
transmissi
on : write
reg[0x041
F] =
read :
reg[0x063
D]=
received.
•
read :
[31:16] of
total
0x1000
reg[0x062
0][8] (1
indicates
PRBS
received
packets
count.
•
Generate
d data will
be going
to MAC
side, to
disable
MAC
data is
read :
coming in
and
reg<0x06
3E> ->
checker is
locked)
Packets
received
with CRC
errors
side :
write
reg[0x000
0]=0x054
0
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Table 8-2. Datapath BIST Programming (continued)
Loopback
Mode
To enable loopback mode
To enable
data
To check in- To enable
coming MAC data
To check in- Other care-
coming
abouts
generator
packets
generator
PRBS status:
and checker: status
MAC packets
and checker: PRBS stream
PRBS stream
3
PCS loopback
Step 1 : write :
reg[0x0620][1]
= 1'b1
•
write : reg<0x0016> =
0x0001
•
•
write :
•
read :
•
•
write :
•
Generate
reg[0x061
9]=0x155
5
reg[0x063
C]= [15:0]
of total
reg[0x061
9]=0x055
7
d data will
be going
to Cu
Step 2 :
•
read :
received
packets
count.
cable
write :
write :
reg[0x062
0][7:0] =
Number
of error
bytes
side, to
disable
this
reg[0x062
4]=0x55B
F
reg[0x062
4]=0x55B
F
•
read :
transmissi
on : write
reg[0x041
F] =
reg[0x063
D]=
received.
[31:16] of
total
•
read :
0x1000
reg[0x062
0][8] (1
indicates
PRBS
received
packets
count.
•
Generate
d data will
be going
to MAC
side, to
disable
MAC
•
read :
data is
reg[0x063
E]=
coming in
and
Packets
received
with CRC
errors
checker is
locked)
side :
write
reg[0x000
0]=0x054
0
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Table 8-2. Datapath BIST Programming (continued)
Loopback
Mode
To enable loopback mode
To enable
data
To check in- To enable
coming MAC data
To check in- Other care-
coming
abouts
generator
packets
generator
PRBS status:
and checker: status
MAC packets
and checker: PRBS stream
PRBS stream
4
RGMII loopback
•
write : reg<0x0000> =
0x4140
•
•
Data is
•
•
Data can
be verified
at Rgmii
RX pins.
•
Data is
•
•
Not
•
Generate
d data will
be going
to Cu
generated
externally
at Rgmii
TX pins
generated
externally
at Rgmii
Tx pins.
applicable
as data is
external.
cable
Packet
errors can
additional
y be
PRBS
side, to
disable
this
Write :
reg[0x061
9]=
stream
checker
works
transmissi
on : write
reg[0x041
F] =
0x1004
checked
internally
by :
only with
internal
data
generator.
–
–
–
read :
reg[0x
063C
]=
0x1000
[15:0]
of
total
receiv
ed
packe
ts
count.
read :
reg[0x
063D]
=
[31:16
] of
total
receiv
ed
packe
ts
count.
read :
reg[0x
063E
]=
Packe
ts
receiv
ed
with
CRC
errors
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Table 8-2. Datapath BIST Programming (continued)
Loopback
Mode
To enable loopback mode
To enable
data
To check in- To enable
coming MAC data
To check in- Other care-
coming
abouts
generator
packets
generator
PRBS status:
and checker: status
MAC packets
and checker: PRBS stream
PRBS stream
5
SGMII loopback
•
write : reg[0x0000] =
0x4140
•
•
Data is
•
•
Data can
be verified
at Sgmii
•
Data is
•
•
Not
•
Generate
generated
externally
at Sgmii
TX pins
generated
externally
at Sgmii
Tx pins.
applicable
as data is
external.
d data will
be going
to Cu
RX pins.
cable
Packet
errors can
additional
y be
PRBS
side, to
disable
this
Write :
reg[0x061
9] =
stream
checker
works
transmissi
on : write
reg[0x041
F] =
0x1114
checked
internally
by :
only with
internal
data
generator.
–
–
–
read :
reg[0x
063C
]=
0x1000
[15:0]
of
total
receiv
ed
packe
ts
count.
read :
reg[0x
063D]
=
[31:16
] of
total
receiv
ed
packe
ts
count.
read :
reg[0x
063E]
=
Packe
ts
receiv
ed
with
CRC
errors
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Table 8-2. Datapath BIST Programming (continued)
Loopback
Mode
To enable loopback mode
To enable
data
To check in- To enable
coming MAC data
To check in- Other care-
coming
abouts
generator
packets
generator
PRBS status:
and checker: status
MAC packets
and checker: PRBS stream
PRBS stream
6
RGMII Reverse
loopback
Step 1 : write :
reg[0x0620][1]
= 1'b1
•
write : reg[0x0016] =
0x0010
•
•
write :
•
read :
•
•
write :
•
Generate
d data will
be going
to Cu
reg[0x061
9]=0x100
5
reg[0x063
C] =
reg[0x061
9]=0x055
7
Step 2 :
[15:0] of
total
•
read :
cable
write :
write :
reg[0x062
0][7:0] =
Number
of error
bytes
received
packets
count.
side, to
disable
this
reg[0x062
4]=0x55B
F
reg[0x062
4]=0x55B
F
transmissi
on : write
reg[0x041
F] =
•
read :
reg[0x063
D] =
received.
•
read :
[31:16] of
total
0x1000
reg[0x062
0][8] (1
indicates
PRBS
received
packets
count.
data is
•
read :
coming in
and
reg[0x063
E] =
checker is
locked)
Packets
received
with CRC
errors
7
SGMII Reverse
loopback
Step 1 : write :
reg[0x0620][1]
= 1'b1
•
write : reg[0x042C] =
0x0010
•
•
write :
•
read :
•
•
write :
•
Generate
d data will
be going
to Cu
reg[0x061
9]=0x1115
reg[0x063
C] for
reg[0x061
9]=0x055
7
Step 2 :
[15:0] of
total
write :
•
read :
cable
reg[0x062
4]=0x55B
F
write :
reg[0x062
0][7:0] for
Number
of error
bytes
received
packets
count.
side, to
disable
this
reg[0x062
4]=0x55B
F
transmissi
on : write
reg[0x041
F] =
•
read :
reg[0x063
D] for
received.
•
read :
[31:16] of
total
0x1000
reg[0x062
0][8] (1
indicates
PRBS
received
packets
count.
data is
•
read :
coming in
and
reg[0x063
E] for
checker is
locked)
Packets
received
with CRC
errors
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Note
Different MAC packet parameters can be further configured with register[0x061B] and register[0x0624]
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8.3.1.4 Temperature and Voltage Sensing
Temperature sensor of PHY can be used to give the indication of the temperature of the system and reading can
be taken on the fly by reading the temperature sensor output register.
Voltage sensor senses the voltage of all the supply pins: vdda, vddio and vdd1p0. Each pins active voltage can
be sensed by reading the corresponding voltage sensor output register.
All sensors are always active and monitor state machine polls the value of each sensor periodically. Monitor
state machine can be further programmed to give higher priority/sampling time to one sensor over another by
using MONITOR_CTRL_3 register.
Following software sequence can be used to read out any sensor's output:
•
•
•
Step1 : Program register[0x0467] = 0x6004 ; Initial configuration of monitors
Step 2 : Program register [0x046A] = 0x00A6 and then register [0x046A]=0x00A3; Refresh the monitors
Step 3 : Program register[0x0468] to select the corresponding sensor to be polled and read register [0x047B]
[14:7] for selected sensor's output code.
•
Step 4 : Feed the values of read sensor's output code (in decimal) in following equations to get the sensor's
output value in decimals. Refer to Sensor Select Table for required value of constants to be used in
equations :
– vdda_value = 3.3 + (vdda_output_code - vdda_output_mean_code)*slope_vdda_sensor
– vdd1p0_value = 1.0 + (vdd1p0_output_code - vdd1p0_ouput_mean_code)*slope_vdd1p0_sensor
– vddio_calculated = 3.3 + (vddio_ouput_code - vddio_output_mean_code)*slope_vddio_sensor
– temperature_calculated = 25 + (temperature_output_code -
temperature_output_mean_code)*slope_temperature_sensor
Table 8-3. Sensor Select Table
Register[0x0468]
Sensor Selected To Read-out
VDDA Voltage Sensor
VDD1P0 Voltage Sensor
VDDIO Voltage Sensor
Temperature Sensor
0x1920
0x2920
0x3920
0x4920
Table 8-4. Sensor's Constant Values
Constant
Value (in decimal)
vdda_output_mean_code
slope_vdda3p3_sensor
vdd1p0_output_mean_code
slope_vdd1p0_sensor
vddio_output_mean_code
slope_vddio_sensor
128
8.63014e-3
93
2.85714e-3
224
15.686e-3
161
temperature_output_mean_code
slope_temperature_sensor
1.5
Note
Accuracy of temperature sensor can be maximized (7.5degreeC), if customer can sample
"temperature_output_code" at 25C and use it as "temperature_output_mean_code".
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8.3.1.5 Electrostatic Discharge Sensing
Electrostatic discharge is a serious issue for electronic circuits and if not properly mitigated can create short-term
issues (signal integrity, link drops, packet loss) as well as long-term reliability faults. The DP83TG720R-Q1 has
robust integrated ESD circuitry and offers an ESD sensing architecture. ESD events can be detected on MDI
pins for further analysis and debug.
The ESD sensing tool is useful for both prototyping and end-applications. Additionally, the DP83TG720R-Q1
provides an interrupt status flag; when an ESD event is logged in the register<0x0442>. Hardware and software
resets are ignored by the ESDS register to prevent unwarranted clearing.
Table 8-5. ESD Sensing : Interrupt Setting and Count Reading
Function
Required Read/Write
Interrupt Enable
•
Write register<0x0012>[3] = 1
ESD Event Counter
•
•
Read register<0x0442>[14:9]
Value in decimal indicates the ESD strikes since power-up.
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8.3.2 Compliance Test Modes
The six test modes for the DP83TG720R-Q1 are compliant to IEEE 802.3bp, Sub-clause 97.5.2. Supported test
modes allow testing of the transmitter waveform Power Spectral Density (PSD) mask, distortion, MDI Master
jitter, MDI Slave jitter, droop, transmitter frequency, frequency tolerance, BER monitoring, return loss, and mode
conversion. Any of the three GPIOs can be used to output TX_TCLK for MDI Slave jitter measurement.
8.3.2.1 Test Mode 1
Test mode 1 tests the transmitter clock jitter when linked to a partner. In test mode 1, the DP83TG720R-Q1
PHYs are connected over link segment defined in section 97.6 within IEEE 802.3bp. TX_TCLK125 is a divided
clock derived from TX_TCLK, which is one sixth the frequency.
8.3.2.2 Test Mode 2
Test mode 2 tests the transmitter MDI Master mode jitter. In test mode 2, the DP83TG720R-Q1 will transmit a
continuous pattern of three {+1} symbols followed by three {-1} symbols. The transmitted symbols are timed from
the 750-MHz source, which results in a 125-MHz signal.
8.3.2.3 Test Mode 4
Test mode 4 tests the transmitter distortion. In test mode 4, the DP83TG720R-Q1 will transmit the sequence of
symbols generated by Equation 1:
g(x) = 1 + x9 + x11
(1)
The bit sequences, x0n and x1n, are generated from combinations of the scrambler in accordance to and :
'x0n = Scrn[0]
(2)
(3)
(4)
x1n = Scrn[1] ^ Scrn[4]
x2n = Scrn[1] ^ Scrn[5]
Example streams of the 3-bit nibbles are shown in Table 8-6.
Table 8-6. Transmitter Test Mode 4 Symbol Mapping
x2n
0
x1n
x0n
T1n
T0n
-1
0
0
-1
0
0
1
0
-1
0
1
0
-1
0
0
1
1
-1
+1
0
1
0
0
+1
+1
+1
0
1
0
1
-1
1
1
0
+1
+1
1
1
1
8.3.2.4 Test Mode 5
Test mode 5 tests the transmitter PSD mask. In test mode 5, the DP83TG720R-Q1 will transmit normal Inter-
Frame IDLE PAM3 symbols.
8.3.2.5 Test Mode 6
Test mode 6 tests the transmitter droop. In test mode 6, the DP83TG720R-Q1 transmits fifteen {+1} symbols
followed by fifteen {-1} symbols with symbol transmission at 750-MHz. This 25-MHz pattern is repeated
continuously until the test mode is disabled.
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8.3.2.6 Test Mode 7
Test mode 7 enabled bit error rate measurement on a link segment. This mode uses zero data pattern on the
MDI to check BER by comparing an expected zero data pattern to any non-zero bit received. Error checking is
performed after FEC and 80B/81B decoding.
Table 8-7. Test Mode Register Setting
MMD
Register
Value
Test Mode
MMD1
0x0904
0x2000
Test Mode 1 : Tx_Tclk 125MHz is
routed to clkout pin.
MMD1
MMD1
MMD1F
MMD1
MMD1
MMD1
0x0904
0x0904
0x0453
0x0904
0x0904
0x0904
0x4000
0x8000
0x0019
0xA000
0xC000
0xE000
Test Mode 2
Test Mode 4 : Tx_Tclk 125MHz is
routed to clkout pin.
Test Mode 5
Test Mode 6
Test Mode 7
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8.4 Device Functional Modes
State Change #3
State Change #4
Normal
PHY Enabled
Sleep
State
Change #1
State
Change #2
Standby
PHY Disabled
RESET_N = HIGH
and
POR = complete
RESET_N = LOW
and Power-on
Power-on
Power-off
Reset
PHY Disabled
Power-off
PHY Disabled
Standby/Normal
From any state
Figure 8-11. PHY Operation State Diagram
8.4.1 Power Down
When VDDA3P3 or VDDIO or VDD1P0 is below the POR threshold, the DP83TG720R-Q1 is in a power-down
state. All digital IOs will remain in high impedance state and analog blocks are disabled. PMA termination is not
present when in power-down.
8.4.2 Reset
Reset is activated upon power-up, when RESET_N is pulled LOW (for the minimum reset pulse time) or if
hardware reset is initiated by setting bit[15] in the register[0x001F].
•
•
•
Digital state machine restarts after reset and all the register settings are cleared to the boot-up state.
25MHz clock on clkout pin will remain active during reset state also.
MDI/PMA will not have termination during reset state.
Note
Straps are re-latched only with pin reset and not by hardware reset through register (register
[0x001F] = x8000.
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8.4.3 Standby
The device (MDI Master mode or MDI Slave mode) automatically enters into standby post power-up and reset so
long that the device is bootstrapped for managed operation.
In standby, all PHY functions are operational except for PCS and PMA blocks. Link establishment is not possible
in standby and data cannot be transmitted or received. SMI functions are operational and register configurations
are maintained.
If the device is configured for autonomous operation through bootstrap setting, the PHY automatically switches
to normal operation once powered on and reset complete.
8.4.4 Normal
Normal mode can be entered from either autonomous or managed operation. When in autonomous operation,
the PHY will automatically try to establish link with a valid Link Partner once powered on.
In managed operation, SMI access is required to allow the device to exit standby; commands issued through
the SMI allow the device to exit standby and enables both the PCS and PMA blocks. All device features are
operational in normal mode.
Autonomous operation can be enabled through SMI access by setting bit[6] in register 0x18B.
8.4.5 Sleep
Once in sleep mode, all PHY blocks are disabled except for energy detection. All register configurations are
lost in sleep mode. No link can be established, data cannot be transmitted or received and SMI access is not
available when in sleep mode.
To use sleep mode of PHY refer to implementation highlighted in following figure.
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27
26
25
24
23
GND
5
22
21
20
19
VDDIO
TX_CLK
TX_CTRL
TX_D3
28
29
30
31
32
33
34
35
36
18
17
16
15
14
13
12
11
10
DNC
DNC
VDD1P0
Power Management
CLKOUT / GPIO_2
RX_CTRL
STRAP_1
TRD_M
Module
TX_D2
VDDA
_D1 / TX_P
_D0 / TX_M
VDDIO
Enable
Enable = 0 -> VDDIO, VDD1P0, VDDA -> Power
Enable = 1 -> VDDIO, VDD1P0, VDDA -> Power
TRD_P
0 / GPIO_0
MDIO
VDDASleep mode -> INH = 0
Out of sleep -> INH = 1 (3.3V)
INH
1
2
3
4
6
7
8
9
GND
Vsleep source = 3.3V;
Always on : Sleep or Functional mode
Figure 8-12. Required Implementation for Sleep Mode
Note
Phy will not go into sleep mode if supply sources are not disabled as per above figure.
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8.4.6 State Transitions
8.4.6.1 State Transition #1 - Standby to Normal
Autonomous Operation: The PHY will automatically transition to Normal state upon POR completion.
Managed Operation: The PHY will transition to Normal state out of Standby only after writing register <0x018C>
= 0x001.
8.4.6.2 State Transition #2 - Normal to Standby
The PHY can be forced back into Standby when in Normal state by writing register <0x018C> = 0x0010.
8.4.6.3 State Transition #3 - Normal to Sleep
Sleep state can be entered either locally (pin/register-write) or by remote link-partner.
Local sleep entry for Master mode phy :
•
•
Step 1 : Write bit[7] = 'b1 of register[0x018B].
Step 2 : Make "wake" pin low and hold it low for sleep mode.
Local sleep entry for Slave mode phy :
•
•
•
Step 1 : Write bit[8] = 'b0 of register[0x018B] register.
Step 2 : Write bit[7] = 'b1 of register[0x018B] register.
Step 3 : Make "wake" pin low and hold it low for sleep mode.
Remote sleep entry for Master mode phy :
Master mode phy can not be made to enter sleep mode by link-partner
Remote sleep entry for Slave mode phy :
•
•
•
Step 1 : Write bit[7] = 'b1 of register[0x018B] register.
Step 2 : Phy will go into sleep mode with loss of energy on line (when master will go quite : no data, no
send-s).This can be achieved by putting link-partner in managed mode (where device is not allowed to start
link-up sequence).
Note
Phy will go into sleep mode only if power supplies are disconnected using INH signal as shown in
figure Required Implementation for Sleep Mode.
8.4.6.4 State Transition #4 - Sleep to Normal
Sleep state can be exited either locally (pin/register-write) or by remote link-partner.
Local Sleep Exit
Local sleep exit for Master mode PHY by :
•
Making "wake" pin high (3.3V).
Local sleep exit for Slave mode PHY by :
Making "wake" pin high (3.3V).
•
Remote Sleep Exit
Device can be made to exit the sleep mode by link-partner by either of the following :
1. Remote sleep exit using Send-S symbols from link-partner.
2. Remote sleep exit using Send-T symbols from link-partner
Details of these procedures are in the following table :
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Table 8-8. Remote Sleep Exit Procedures
Method
Device
Mode
Procedure
Required Link-partner
Cabability
Using Send-S
Master
Step 1 : Start IEEE defined Send-S pattern from link-partner for
atleast 1.25ms.
Link-partner needs to have a
mode to send Send-S pattern
on demand in Slave mode
also.
Step 2 : Put link-partner in the normal mode to start the link-up.
Note : Link-partner with low VOD may limit the remote wake-up
upto a maximum of 5m cable.
One possible way is :
Step 1 : Put link-partner
in master mode for atleast
1.25ms.
Step 2 : Put link-partner in
normal mode to start the link-
up
Slave
Step 1 : Start IEEE defined Send-S pattern from link-partner for
atleast 1.25ms.
Any IEEE compliant link-
partner will work, as
Step 2 : Put link-partner in the normal mode to start the link-up.
Note : Link-partner with low VOD may limit the remote wake-up
upto a maximum of 5m cable.
master mode link-partner is
supposed to send Send-S
signals to start the link-up
Note : To keep the slave mode DP83TG720 in sleep mode, link-
partner can be put in managed mode (where device is not allowed
to start link-up sequence).
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Table 8-8. Remote Sleep Exit Procedures (continued)
Method
Device
Mode
Procedure
Required Link-partner
Cabability
Using Send-T
Master
Step 1 : Enable Send-T pattern on link-partner for atleast 1.25ms.
Step 2 : Put link-partner in the normal mode to start the link-up.
Link-partner needs to have a
mode to send Send-T pattern
on demand.
Swing during Send-T mode
at pins of link-partner should
be greater than 0.92V for
remote wake-up over 15m
cable. Link-partner with lower
VOD may limit the remote
wake-up to 5m cable.
DP83T720 as link-partner
can do the required with
following steps :
Step 1 : Enable
Send-T pattern on
DP83TG720 link-partner :
write reg[0x0405]=0x7400;
reg[0x0509]=0x4007 and
reg[0x0576]=0x0500
Step 2 : After 100ms
disable send-T pattern on
DP83TG720 link-partner :
write reg[0x0405]=x5800;
reg[0x0509]=0x4005 and
reg[0x0576]=0x0000
Slave
Step 1 : Enable Send-T pattern on link-partner for atleast 1.25ms.
Step 2 : Put link-partner in the normal mode to start the link-up.
Link-partner needs to have a
mode to send Send-T pattern
on demand.
Swing during Send-T mode
at pins of link-partner should
be greater than 0.92V for
remote wake-up over 15m
cable. Link-partner with lower
VOD may limit the remote
wake-up to 5m cable.
DP83T720 as link-partner
can do the required with
following steps :
Step 1 : Enable
Send-T pattern on
DP83TG720 link-partner :
write reg[0x0405]=0x7400;
reg[0x0509]=0x4007 and
reg[0x0576]=0x0500
Step 2 : After 100ms
disable send-T pattern on
DP83TG720 link-partner :
write reg[0x0405]=x5800;
reg[0x0509]=0x4005 and
reg[0x0576]=0x0000
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8.4.7 Media Dependent Interface
8.4.7.1 MDI Master and MDI Slave Configuration
MDI Master and MDI Slave are configured using either hardware bootstraps or through register access.
LED_0 controls the MDI Master and MDI Slave bootstrap configuration. By default, MDI Slave mode is
configured because there is an internal pulldown resistor on LED_0 pin. If MDI Master mode configuration
through hardware bootstrap is preferred, an external pullup resistor is required.
Additionally, bit[14] in the PMA_CTRL2 egister controls the MDI Master and MDI Slave configuration. When this
bit is set, MDI Master mode is enabled.
8.4.7.2 Auto-Polarity Detection and Correction
During the link training process, the DP83TG720R-Q1 as MDI receiver is able to detect polarity reversal and
automatically correct for the error. Both master and slave detects can do the required correction in the receiver
polarity.
Refer to register 0x055B to control the polarity of the PHY's transmitter as required by application. Transmitter
polarity can be controlled independent of the received polarity.
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8.4.8 MAC Interfaces
8.4.8.1 Reduced Gigabit Media Independent Interface
The DP83TG720R-Q1 also supports Reduced Gigabit Media Independent Interface (RGMII) as specified by
RGMII version 2.0. RGMII is designed to reduce the number of pins required to connect MAC and PHY. To
accomplish this goal, the control signals are multiplexed. Both rising and falling edges of the clock are used
to sample the control signal pin on transmit and receive paths. For 1-Gbps operation, RX_CLK and TX_CLK
operate at 125 MHz.
The RGMII signals are summarized in Table 8-9:
Table 8-9. RGMII Signals
FUNCTION
PINS
TX_D[3:0]
RX_D[3:0]
TX_CTRL
RX_CTRL
TX_CLK
Data Signals
Control Signals
Clock Signals
RX_CLK
TX_CLK
TX_CTRL
TX_D[3:0]
RX_CLK
PHY
MAC
RX_CTRL
RX_D[3:0]
25-MHz Crystal or
CMOS-level
Oscillator
Figure 8-13. RGMII Connections
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Table 8-10. RGMII Transmit Encoding
TX_CTRL
(POSITIVE EDGE)
TX_CTRL
(NEGATIVE EDGE)
TX_D[3:0]
DESCRIPTION
0
0
1
1
0
1
0
1
0000 through 1111
0000 through 1111
0000 through 1111
0000 through 1111
Normal Inter-Frame
Reserved
Normal Data Transmission
Transmit Error Propagation
Table 8-11. RGMII Receive Encoding
RX_CTRL
(POSITIVE EDGE)
RX_CTRL
(NEGATIVE EDGE)
RX_D[3:0]
DESCRIPTION
0
0
0
0
1
1
0
1
1
1
0
1
0000 through 1111
0000 through 1101
1110
Normal Inter-Frame
Reserved
False Carrier Indication
Reserved
1111
0000 through 1111
0000 through 1111
Normal Data Reception
Data Reception with Errors
The DP83TG720R-Q1 supports in-band status indication to help simplify link status detection. Inter-frame
signals on RX_D[3:0] pins as specified in Table 8-12.
Table 8-12. RGMII In-Band Status
RX_CTRL
RX_D3
RX_D[2:1]
RX_D0
RX_CLK Clock Speed:
00 = 2.5 MHz
0
Duplex Status:
0 = Half-Duplex
1 = Full-Duplex
Link Status:
0 = Link not established
1 = Valid link established
Note:
01 = 25 MHz
In-band status is only valid when
RX_CTRL is low
10 = 125 MHz
11 = Reserved
RGMII MAC Interface for Gigabit Ethernet has stringent timing requirements to meet system level performance.
To meet these timing requirements and to operate with different MACs over RGMII, it is advised to take the
following requirements into consideration when designing PCB. It is also recommended to check board level
signal integrity by using the DP83TG720 IBIS model.
RGMII-TX Requirements
•
•
•
RGMII TX signals should be routed on board with control impedance of 50Ohm +/-15%.
Max routing length should be limited to 5inch for better signal integrity performance.
Figure 8-14 shows a RGMII interface requirements for TX* signals. MAC RGMII driver output impedance
should be 50Ohm+/-20%.
•
•
Skew for all RGMII TX signals at TP2, in Figure 8-14, should be <±500ps.
Signal Integrity at TP1 and TP2, in Figure 8-14, should be verified with IBIS model simulation and ensured
conformance to following requirements:
– At TP2, signal should meet rise/fall time of 1ns (20-80%) of signal amplitude.
– Rise/fall time should be monotonic between VIH/VIL level at TP2.
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Trace characteristics:
Zo = 50Ω ( 15%)
Max. length < 5inch
TP2
TP1
MAC RGMII TX
PHY RGMII TX
Figure 8-14. RGMII TX Requirements
RGMII-RX Requirements
•
•
•
RGMII RX signals should be routed on board with control impedance of 50Ohm +/-15%.
Max routing length should be limited to 5inch for better signal integrity performance.
No damping resistors should be added at TP3/TP4, in Figure 8-15, as that will impact signal integrity of RX
signals.
•
•
Figure 8-15 shows a RGMII interface requirements for RX* signals. MAC RGMII driver output impedance
should be 50Ohm+/-20%.
Signal Integrity at TP3 and TP4, in Figure 8-15, should be verified with IBIS model simulation and ensured
conformance to following requirements:
– At TP4, signal should meet rise/fall time of 1ns (20-80%) of signal amplitude.
– Rise/fall time should be monotonic between VIH/VIL level at TP4.
Trace characteristics:
Zo = 50Ω ( 15%)
Max. length < 5inch
TP4
TP3
PHY RGMII RX
MAC RGMII RX
Figure 8-15. RGMII RX Requirements
Note
1. We recommend routing RGMII on buried traces to minimize EMC emissions.
2. Buried traces should be connected with via placement as close as possible to the PHY and MAC.
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8.4.9 Serial Management Interface
The Serial Management Interface provides access to the DP83TG720R-Q1 internal register space for status
information and configuration. The SMI is compatible with IEEE 802.3 clause 22. The implemented register
set consists of the registers required by the IEEE 802.3 plus several others to provide additional visibility and
controllability of the DP83TG720R-Q1.
The SMI includes the management clock (MDC) and the management input and output data pin (MDIO). MDC
is sourced by the external management entity, also called Station (STA). MDC is not expected to be continuous,
and can be turned off by the external management entity when the bus is idle.
MDIO is sourced by the external management entity and by the PHY. The data on the MDIO pin is latched on the
rising edge of the MDC. MDIO pin requires a pullup resistor (2.2 KΩ), which pulls MDIO high during IDLE and
turnaround.
Up to 9 DP83TG720R-Q1 PHYs can share a common SMI bus. To distinguish between the PHYs, a 3-bit
address is used. During power-up-reset, the DP83TG720R-Q1 latches the PHY_AD configuration pins to
determine its address.
The management entity must not start an SMI transaction in the first cycle after power-up-reset. To maintain
valid operation, the SMI bus must remain inactive at least one MDC cycle after hard reset is deasserted. In
normal MDIO transactions, the register address is taken directly from the management-frame reg_addr field,
thus allowing direct access to 32 16-bit registers (including those defined in IEEE 802.3 and vendor specific).
The data field is used for both reading and writing. The Start code is indicated by a <01> pattern. This pattern
makes sure that the MDIO line transitions from the default idle line state. Turnaround is defined as an idle
bit time inserted between the Register Address field and the Data field. To avoid contention during a read
transaction, no device may actively drive the MDIO signal during the first bit of turnaround. The addressed
DP83TG720R-Q1 drives the MDIO with a zero for the second bit of turnaround and follows this with the required
data.
For write transactions, the station-management entity writes data to the addressed DP83TG720R-Q1, thus
eliminating the requirement for MDIO Turnaround. The turnaround time is filled by the management entity by
inserting <10>.
Table 8-13. SMI Protocol Structure
SMI PROTOCOL
Read Operation
Write Operation
<idle> <start> <op code> <device address> <reg address> <turnaround> <data> <idle>
<idle><01><10><AAAAA><RRRRR><Z0><XXXX XXXX XXXX XXXX><idle>
<idle><01><01><AAAAA><RRRRR><10><XXXX XXXX XXXX XXXX><idle>
8.4.10 Direct Register Access
Direct register access can be used for the first 31 registers (0x0h through 0x1Fh).
8.4.11 Extended Register Space Access
The DP83TG720R-Q1 SMI function supports read and write access to the extended register set using registers
REGCR (0x000Dh) and ADDAR (0x000Eh) and the MDIO Manageable Device (MMD) indirect method defined in
IEEE 802.3ah Draft for Clause 22 for accessing the Clause 45 extended register set.
REGCR (0x000Dh) is the MDIO Manageable MMD access control. In general, register REGCR[4:0] is the device
address DEVAD that directs any accesses of ADDAR (0x000Eh) register to the appropriate MMD.
The DP83TG720R-Q1 supports 4 MMD device addresses. The 4 MMD register spaces are:
1. DEVAD[4:0] = 11111 (0x1F) is used for IEEE defined registers (0x00 to 0x1F) and vendor specific registers.
This register space is called MMD1F
2. DEVAD[4:0] = 00001 (0x01) is used for 1000BASE-T1 PMA MMD register accesses. This register space is
called MMD1.
3. DEVAD[4:0] = 00011 (0x03) is used for vendor specific registers. This register space is called MMD3
4. DEVAD[4:0] = 00111 (0x07) is used for vendor specific registers. This register space is called MMD7
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Table 8-14. MMD Register Space Division
MMD Register Space
MMD1F
Register Address Range
0x000 - 0x0EFD
MMD1
0x1000 - 0x1904
MMD3
0x3000 - 0x390D
0x7000 - 0x7200
MMD7
Note
For MMD1/3/7, most significant nibble of the register address is used to denote the respective
MMD space. This should be ignored during actual register access operation. For example to
access register 0x1904 use 0x0904 as the register address and x01 as the MMD.
All accesses through register REGCR and ADDAR must use the correct DEVAD. Transactions with other
DEVADs are ignored. REGCR[15:14] holds the access function: address (00), data with no post increment (01),
data with post increment on read and writes (10) and data with post increment on writes only (11).
•
ADDAR is the address and data MMD register. ADDAR is used in conjunction with REGCR to provide the
access to the extended register set. If register REGCR[15:14] is (00), then ADDAR holds the address of
the extended address space register. Otherwise, ADDAR holds the data as indicated by the contents of
its address register. When REGCR[15:14] is set to (00), accesses to register ADDAR modify the extended
register set address register. This address register must always be initialized in order to access any of the
registers within the extended register set.
•
•
When REGCR[15:14] is set to (01), accesses to register ADDAR access the register within the extended
register set selected by the value in the address register.
When REGCR[15:14] is set to (10), access to register ADDAR access the register within the extended
register set selected by the value in the address register. After that access is complete, for both reads and
writes, the value in the address register is incremented.
•
When REGCR[15:14] is set to (11), access to register ADDAR access the register within the extended
register set selected by the value in the address register. After that access is complete, for write access
only, the value in the address register is incremented. For read accesses, the value of the address register
remains unchanged.
The following sections describe how to perform operations on the extended register set using register REGCR
and ADDAR.
8.4.12 Write Address Operation
To set the address register:
1. Write the value 0x001F (address function field = 00, DEVAD = '11111') to register REGCR.
2. Write the register address to register ADDAR.
Subsequent writes to register ADDAR (step 2) continue to write the address register.
8.4.12.1 Example - Write Address Operation
For writing register addresses within MMD1 field:
1. Write the value 0x0001 (address function field = 00, DEVAD = '00001') to register REGCR.
2. Write the register address to register ADDAR.
8.4.13 Read Address Operation
To read the address register:
1. Write the value 0x001F (address function field = 00, DEVAD = '11111') to register REGCR.
2. Read the register address from register ADDAR.
Subsequent reads to register ADDAR (step 2) continue to read the address register.
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8.4.13.1 Example - Read Address Operation
For reading register addresses within MMD1 field:
1. Write the value 0x0001 (address function field = 00, DEVAD = '00001') to register REGCR.
2. Read the register address from register ADDAR.
8.4.14 Write Operation (No Post Increment)
To write a register in the extended register set:
1. Write the value 0x001F (address function field = 00, DEVAD = '11111') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x401F (data, no post increment function field = 01, DEVAD = '11111') to register REGCR.
4. Write the content of the desired extended register set to register ADDAR.
Subsequent writes to register ADDAR (step 4) continue to rewrite the register selected by the value in the
address register.
Note
Steps (1) and (2) can be skipped if the address register was previously configured.
8.4.14.1 Example - Write Operation (No Post Increment)
To write a register in the MMD1 extended register set:
1. Write the value 0x0001 (address function field = 00, DEVAD = '00001') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x4001 (data, no post increment function field = 01, DEVAD = '00001') to register REGCR.
4. Write the content of the desired extended register set to register ADDAR.
8.4.15 Read Operation (No Post Increment)
To read a register in the extended register set:
1. Write the value 0x001F (address function field = 00, DEVAD = '11111') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x401F (data, no post increment function field = 01, DEVAD = '11111') to register REGCR.
4. Read the content of the desired extended register set in register ADDAR.
Subsequent reads to register ADDAR (step 4) continue to reading the register selected by the value in the
address register.
Note
Steps (1) and (2) can be skipped if the address register was previously configured.
8.4.15.1 Example - Read Operation (No Post Increment)
To read a register in the MMD1 extended register set:
1. Write the value 0x0001 (address function field = 00, DEVAD = '00001') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x4001 (data, no post increment function field = 01, DEVAD = '00001') to register REGCR.
4. Read the content of the desired extended register set in register ADDAR.
8.4.16 Write Operation (Post Increment)
To write a register in the extended register set with post increment:
1. Write the value 0x001F (address function field = 00, DEVAD = '11111') to register REGCR.
2. Write the desired register address to register ADDAR.
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3. Write the value 0x801F (data, post increment function field = 10, DEVAD = '11111') or the value 0xC01F
(data, post increment on writes function field = 11, DEVAD = '11111') to register REGCR.
4. Write the content of the desired extended register set to register ADDAR.
Subsequent writes to register ADDAR (step 4) write the next higher addressed data register selected by the
value of the address register; the address register is incremented after each access.
8.4.16.1 Example - Write Operation (Post Increment)
To write a register in the MMD1 extended register set with post increment:
1. Write the value 0x0001 (address function field = 00, DEVAD = '00001') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x8001 (data, post increment function field = 10, DEVAD = '00001') or the value 0xC001
(data, post increment on writes function field = 11, DEVAD = '00001') to register REGCR.
4. Write the content of the desired extended register set to register ADDAR.
8.4.17 Read Operation (Post Increment)
To read a register in the extended register set and automatically increment the address register to the next
higher value following the write operation:
1. Write the value 0x001F (address function field = 00, DEVAD = '11111') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x801F (data, post increment function field = 10, DEVAD = '11111') to register REGCR.
4. Read the content of the desired extended register set in register ADDAR.
Subsequent reads to register ADDAR (step 4) read the next higher addressed data register selected by the
value of the address register; the address register is incremented after each access.
8.4.17.1 Example - Read Operation (Post Increment)
To read a register in the MMD1 extended register set and automatically increment the address register to the
next higher value following the write operation:
1. Write the value 0x0001 (address function field = 00, DEVAD = '00001') to register REGCR.
2. Write the desired register address to register ADDAR.
3. Write the value 0x8001 (data, post increment function field = 10, DEVAD = '00001') to register REGCR.
4. Read the content of the desired extended register set in register ADDAR.
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8.5 Programming
8.5.1 Strap Configuration
The DP83TG720R-Q1 uses functional pins as strap options to place the device into specific modes of operation.
The values of these pins are sampled at power up and hardware reset (through either the RESET_N pin or
register access). The strap pins support 2-levels and 3-levels, which are described in greater detail below.
Configuration of the device may be done through strapping or through serial management interface.
Note
•
Because strap pins are functional pins after reset is deasserted, they should not be connected
directly to VCC or GND.
•
•
Pull up strap resistors are sufficient to enter different strap modes.
Pull down strap resistor can have application for LED pin straps. Refer to LED Configuration
section.
VDDIO
RH
Rpull-down
Figure 8-16. Strap Circuit
Table 8-15. Recommended 3-level Strap Resistor Ratios
IDEAL RH (kΩ)1
IDEAL RH (kΩ)2
IDEAL RH (kΩ)1
for VDDIO = 1.8V
MODE
for VDDIO = 3.3 V
for VDDIO = 2.5 V
1
2
3
OPEN
13
OPEN
12
OPEN
4
4.5
2
0.8
1. 10% resistor accuracy
2. 1% resistor accuracy
Table 8-16. Recommended 2-level Strap Resistor
MODE
IDEAL RH (kΩ)12
1
2
OPEN
2.49
1. 10% resistor accuracy
2. To gain more margin in customer application for 1.8V VDDIO, either 2.1K+/-10% pull-up can be used or
resistor accuracy of 2.49K resistor can be limited to 1%.
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The following table describes the DP83TG720R-Q1 configuration bootstraps:
Table 8-17. 2-level Bootstraps
PIN NAME
RX_D0
PIN NO.
26
STRAP MODE
1 (default)
2
STRAP FUNCTION
DESCRIPTION
MAC[0] = 0
MAC Interface Selection
[0]. Refer to Table 8-18 for
full description.
MAC[0] = 1
RX_D1
RX_D2
LED_0
LED_1
25
24
1
1 (default)
2
MAC[1] = 0
MAC[1] = 1
MAC Interface Selection
[1]. Refer to Table 8-18 for
full description.
1 (default)
2
MAC[2] = 0
MAC[2] = 1
MAC Interface Selection
[2]. Refer to Table 8-18 for
full description.
1 (default)
2
MS = 0
MS = 1
MDI Master Slave Select.
MS = 0 Slave
MS = 1 Master
6
1 (default)
2
AUTO = 0
AUTO = 1
Autonomous Disable
AUTO = 0 Autonomous
AUTO = 1 Managed
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Table 8-18. MAC Interface Selection Bootstraps
MAC[2]
MAC[1]
MAC[0]
DESCRIPTION
0
0
0
RESERVED
0
0
0
1
1
1
1
0
1
1
0
0
1
1
1
0
1
0
1
0
1
RESERVED
RESERVED
RESERVED
RGMII (Align Mode)
RGMII (TX Shift Mode)
RGMII (TX and RX Shift Mode)
RGMII (RX Shift Mode)
Table 8-19. 3-Level Bootstrap: PHY Address
RX_CTRL
STRAP MODE
STRP_1
STRAP MODE
PHY_AD[3:0]
DESCRIPTION
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
1
-
1
-
PHY Address: 0x0000 (0)
RESERVED
-
-
RESERVED
-
-
RESERVED
2
3
-
1
1
-
PHY Address: 0x0004 (4)
PHY Address: 0x0005 (5)
RESERVED
-
-
RESERVED
1
-
2
-
PHY Address: 0x0008 (8)
RESERVED
1
-
3
-
PHY Address: 0x000A (10)
RESERVED
2
3
2
3
2
2
3
3
PHY Address: 0x000C (12)
PHY Address: 0x000D (13)
PHY Address: 0x000E (14)
PHY Address: 0x000F (15)
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8.5.2 LED Configuration
The DP83TG720R-Q1 supports up to three configurable Light Emitting Diode (LED) pins: LED_0, LED_1, and
LED_2 (CLKOUT). Several functions can be multiplexed onto the LEDs for different modes of operation. LED
operations are selected using registers 0x0450 and 0x0451.
Note
CLKOUT has 25MHz clock output as default. If required, it can be configured to LED2 using register
0x0453.
Because the LED output pins are also used as strap pins, external components required for strapping and
the user must consider the LED usage to avoid contention. Specifically, when the LED outputs are used to
drive LEDs directly, the active state of each output driver is dependent on the logic level sampled by the
corresponding input upon power up or hardware reset.
Figure 8-17 shows the two proper ways of connecting LEDs directly to the DP83TG720R-Q1.
Pull-Down
VDDIO
Strap Pin
RCL
D1
RP
RP
D1
RCL
Pull-Up
Strap Pin
Figure 8-17. Example Strap Connections
8.5.3 PHY Address Configuration
The DP83TG720R-Q1 can be set to respond to any of 9 possible PHY addresses through bootstrap pins.
The PHY address is latched into the device upon power-up or hardware reset. Each DP83TG720R-Q1 or port
sharing PHY on the serial management bus in the system must have a unique PHY address. The DP83TG720R-
Q1 supports PHY address as described in Table 8-19.
By default, the DP83TG720R-Q1 will latch to a PHY address of 0 ([0000]). This address can be changed by
adding pullup resistors to bootstrap pins found in Table 8-17.
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8.6 Register Maps
8.6.1 Register Access Summary
There are two different methods for accessing registers within the field. Direct register access method is only
allowed for the first 31 registers (0x0h through 0x1Fh) of MMD1F register space. Registers beyond 0x1Fh must
be accessed by use of the Indirect Method (Extended Register Space) described in Section 8.4.11.
Table 8-20. MMD Register Space Division
MMD REGISTER SPACE
REGISTER ADDRESS RANGE
MMD1F
MMD1
MMD3
MMD7
0x000 - 0x0EFD
0x1000 - 0x1904
0x3000 - 0x390D
0x7000 - 0x7200
Table 8-21. Register Access Summary
REGISTER FIELD
REGISTER ACCESS METHODS
Direct Access
Indirect Access, MMD1F = '11111'
Example: to read register 0x17h in MMD1F field with no post increment
Step 1) write 0x1Fh to register 0xDh
0x0h through 0x1Fh
Step 2) write 0x17h to register 0xEh
Step 3) write 0x401Fh to register 0xDh
Step 4) read register 0xEh
Indirect Access, MMD1F = '11111'
Example: to read register 0x462h in MMD1F field with no post increment
Step 1) write 0x1Fh to register 0xDh
MMD1F Field
0x20h - 0xFFFh
Step 2) write 0x462h to register 0xEh
Step 3) write 0x401Fh to register 0xDh
Step 4) read register 0xEh
Indirect Access, MMD1 = '00001'
Example: to read register 0x7h in MMD1 field with no post increment
Step 1) write 0x1h to register 0xDh
MMD1 Field
0x0000h - 0x0FFFh
Step 2) write 0x7h to register 0xEh
Step 3) write 0x4001h to register 0xDh
Step 4) read register 0xEh
8.6.2 Register Map
Table 8-22. DP83TG720 Access Type Codes
Access Type
Read Type
R
Code
Description
R
Read
Write
Write Type
W
W
W0C
W
Write
0C
0 to clear
W0S
W
Write
0S
0 to set
WMC
W
W
W
W
W
Write with manual clear to default (refer to register description to
know about the clearing event)
WMC,0
WMC,1
WSC
Write with manual clear to 0 (refer to register description to know
about the clearing event)
Write with manual clear to 1 (refer to register description to know
about the clearing event)
Write with self clear to default (written value be cleared
automatically)
WSC,0
Write with self clear to 0
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Table 8-22. DP83TG720 Access Type Codes (continued)
Access Type
Code
Description
Reset or Default Value
-n
Value after reset or the default value
8.6.2.1 DP83TG720 Registers
Table 8-23 lists the DP83TG720 registers. All register offset addresses not listed in Table 8-23 should be
considered as reserved locations and the register contents should not be modified.
Table 8-23. DP83TG720 Registers
Offset
0h
Acronym
Register Name
Section
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
BMCR
1h
BMSR
2h
PHYID1
3h
PHYID2
Dh
REGCR
Eh
ADDAR
10h
MII_REG_10
MII_REG_11
MII_REG_12
MII_REG_13
MII_REG_16
MII_REG_18
MII_REG_19
MII_REG_1E
MII_REG_1F
C_AND_S_STATUS
PM_TOP_CFG
CLK_CTRL_CFG
LPS_CFG
11h
12h
13h
16h
18h
19h
1Eh
1Fh
180h
181h
182h
183h
18Bh
18Ch
18Eh
309h
30Ah
30Bh
30Eh
30Fh
405h
41Fh
428h
429h
42Ah
42Bh
42Ch
42Dh
42Eh
430h
LPS_CFG2
LPS_CFG3
LPS_STATUS
TDR_STATUS0
TDR_STATUS1
TDR_STATUS2
TDR_STATUS5
TDR_TC12
A2D_REG_05
A2D_REG_31
A2D_REG_40
A2D_REG_41
A2D_REG_42
A2D_REG_43
A2D_REG_44
A2D_REG_45
A2D_REG_46
A2D_REG_48
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Table 8-23. DP83TG720 Registers (continued)
Offset
442h
450h
451h
452h
453h
454h
455h
456h
457h
458h
459h
45Ah
45Dh
45Eh
466h
467h
468h
46Ah
47Bh
509h
50Ah
514h
515h
518h
519h
531h
543h
544h
545h
547h
548h
559h
55Ah
55Bh
55Ch
561h
573h
580h
581h
600h
601h
602h
608h
609h
60Ah
Acronym
Register Name
Section
A2D_REG_66
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
LEDS_CFG_1
LEDS_CFG_2
IO_MUX_CFG_1
IO_MUX_CFG_2
IO_CONTROL_1
IO_CONTROL_2
IO_CONTROL_3
IO_STATUS_1
IO_STATUS_2
IO_CONTROL_4
IO_CONTROL_5
SOR_VECTOR_1
SOR_VECTOR_2
REV_ID
MONITOR_CTRL1
MONITOR_CTRL2
MONITOR_CTRL4
MONITOR_STAT1
SYNC_LINK_CONTROL_CFG
BREAK_LINK_TIMER
LPS_CONTROL_1
LPS_CONTROL_2
MAXWAIT_TIMER
PHY_CTRL_1G
TEST_MODE
LINK_QUAL_1
LINK_QUAL_2
LINK_DOWN_LATCH_STAT
LINK_QUAL_3
LINK_QUAL_4
PMA_WATCHDOG
DATA_SCR_CFG
SYMB_POL_CFG
OAM_CFG
TEST_MEM_CFG
FORCE_CTRL1
MBIST_CTRL
MBIST_STAT
RGMII_CTRL
RGMII_FIFO_STATUS
RGMII_DELAY_CTRL
SGMII_CTRL_1
SGMII_EEE_CTRL_1
SGMII_STATUS
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Table 8-23. DP83TG720 Registers (continued)
Offset
60Bh
60Ch
60Dh
618h
619h
61Ah
61Bh
61Ch
61Dh
61Eh
620h
622h
623h
624h
625h
626h
627h
628h
629h
62Ah
638h
639h
63Ah
63Bh
63Ch
63Dh
63Eh
800h
871h
8ADh
8EDh
8EFh
8F0h
8F1h
8F2h
1000h
Acronym
Register Name
Section
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
SGMII_EEE_CTRL_2
SGMII_CTRL_2
SGMII_FIFO_STATUS
PRBS_STATUS_1
PRBS_CTRL_1
PRBS_CTRL_2
PRBS_CTRL_3
PRBS_STATUS_2
PRBS_STATUS_3
PRBS_STATUS_4
PRBS_STATUS_6
PRBS_STATUS_8
PRBS_STATUS_9
PRBS_CTRL_4
PRBS_CTRL_5
PRBS_CTRL_6
PRBS_CTRL_7
PRBS_CTRL_8
PRBS_CTRL_9
PRBS_CTRL_10
CRC_STATUS
PKT_STAT_1
PKT_STAT_2
PKT_STAT_3
PKT_STAT_4
PKT_STAT_5
PKT_STAT_6
DSP_REG_0
SQI_REG_1
SQI_1
SQI_2
SQI_3
SQI_4
SQI_5
SQI_6
PMA_PMD_CONTROL_1
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
1007h
1009h
100Bh
PMA_PMD_CONTROL_2
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
Go
Go
Go
PMA_PMD_TRANSMIT_DISABLE
PMA_PMD_EXTENDED_ABILITY2
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
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Table 8-23. DP83TG720 Registers (continued)
Offset
Acronym
Register Name
Section
1012h
PMA_PMD_EXTENDED_ABILITY
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
Go
1834h
1900h
1901h
1902h
1903h
1904h
3000h
3900h
3901h
3902h
3904h
3905h
3906h
3907h
3908h
3909h
390Ah
390Bh
PMA_PMD_CONTROL
PMA_CONTROL
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
PMA_STATUS
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
TRAINING
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
LP_TRAINING
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
TEST_MODE_CONTROL
PCS_CONTROL_COPY
PCS_CONTROL
First nibble (0x1) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
PCS_STATUS
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
PCS_STATUS_2
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
OAM_TRANSMIT
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
OAM_TX_MESSAGE_1
OAM_TX_MESSAGE_2
OAM_TX_MESSAGE_3
OAM_TX_MESSAGE_4
OAM_RECEIVE
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
OAM_RX_MESSAGE_1
OAM_RX_MESSAGE_2
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
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Table 8-23. DP83TG720 Registers (continued)
Offset
Acronym
Register Name
Section
390Ch
OAM_RX_MESSAGE_3
First nibble (0x3) in the register address is to indicated
MMD register space.
Go
For register access, ignore the first nibble.
390Dh
7200h
OAM_RX_MESSAGE_4
AN_CFG
First nibble (0x3) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
Go
Go
First nibble (0x7) in the register address is to indicated
MMD register space.
For register access, ignore the first nibble.
8.6.2.1.1 BMCR Register (Offset = 0h) [Reset = 40h]
BMCR is shown in Table 8-24.
Return to the Summary Table.
Table 8-24. BMCR Register Field Descriptions
Bit
Field
Type
Reset
Description
15
mii_reset
R/WMC
0h
1b = Digital in reset and all MII regs (0x0 - 0xF) reset to default 0b =
No reset
14
13
12
11
10
9
loopback
R/W
R
0h
0h
0h
0h
0h
0h
0h
0h
1h
0h
0h
1b = MII loopback 0b = No MII loopback
RESERVED
RESERVED
power_down
isolate
Reserved
R
Reserved
R/W
R/W
R
1b = Power down via register or pin 0b = Normal mode
1b = Isolate mode 0b = Normal mode
RESERVED
RESERVED
RESERVED
speed_sel_msb
RESERVED
RESERVED
Reserved
8
R
Reserved
7
R
Reserved
6
R
0b= Reserved 1b= 1000 Mb/s
Reserved
5
R
4-0
R
Reserved
8.6.2.1.2 BMSR Register (Offset = 1h) [Reset = 141h]
BMSR is shown in Table 8-25.
Return to the Summary Table.
Table 8-25. BMSR Register Field Descriptions
Bit
15
14
13
12
11
10
9
Field
Type
Reset
Description
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
extended_status
R
0h
R
0h
R
0h
R
0h
R
0h
R
0h
R
0h
8
R
1h
1b = Extended status information in Register 15 0b = No extended
status information in Register 15
7
unidirectional_ability
R
0h
Reserved
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Table 8-25. BMSR Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
6
preamble_supression
R
1h
1b = PHY will accept management frames with preamble
suppressed. 0b = PHY will not accept management frames with
preamble suppressed
5
4
3
2
1
0
aneg_complete
remote_fault
R
0h
0h
0h
0h
0h
1h
Reserved
R/W0C
R
Reserved
aneg_ability
Reserved
link_status
R/W0S
R/W0C
R
1b = link is up 0b = link down
Reserved
jabber_detect
extended_capability
1b = extended register capabilities 0b = basic register set capabilities
only
8.6.2.1.3 PHYID1 Register (Offset = 2h) [Reset = 2000h]
PHYID1 is shown in Table 8-26.
Return to the Summary Table.
Table 8-26. PHYID1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
oui_21_16
R
2000h
8.6.2.1.4 PHYID2 Register (Offset = 3h) [Reset = A284h]
PHYID2 is shown in Table 8-27.
Return to the Summary Table.
Table 8-27. PHYID2 Register Field Descriptions
Bit
15-10
9-4
Field
Type
Reset
28h
28h
4h
Description
oui_5_0
R
model_number
rev_number
R
3-0
R
8.6.2.1.5 REGCR Register (Offset = Dh) [Reset = 0h]
REGCR is shown in Table 8-28.
Return to the Summary Table.
Table 8-28. REGCR Register Field Descriptions
Bit
Field
Type
Reset
Description
15-14
Extended Register
Command
R/W
0h
00b = Address 01b = Data, no post increment 10b = Data, post
increment on read and write 11b = Data, post increment on write only
13-5
4-0
RESERVED
DEVAD
R
0h
0h
Reserved
R/W
8.6.2.1.6 ADDAR Register (Offset = Eh) [Reset = 0h]
ADDAR is shown in Table 8-29.
Return to the Summary Table.
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Table 8-29. ADDAR Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
Address/Data
R/W
0h
8.6.2.1.7 MII_REG_10 Register (Offset = 10h) [Reset = 4h]
MII_REG_10 is shown in Table 8-30.
Return to the Summary Table.
Table 8-30. MII_REG_10 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-11
RESERVED
signal_detect
descr_lock_bit
RESERVED
mii_int_bit
R
0h
Reserved
10
9
R/W0S
R/W0S
R
0h
1b = Channel ok is set 0b = Channel ok had been reset
1b = Descrambler is locked 0b = Descrmabler had been locked
Reserved
0h
8
0h
7
0h
1b = Interrupt pin had been set 0b = Interrupts pin not set
Reserved
6-4
3
RESERVED
mii_loopback
duplex_mode_env
RESERVED
link_status_bit
R
R
R
R
R
0h
0h
1b = MII loopback 0b = No MII loopback
1b = Full duplex 0b = Half duplex
Reserved
2
1h
1
0h
0
0h
1b = link is up 0b = link had been down
8.6.2.1.8 MII_REG_11 Register (Offset = 11h) [Reset = Ah]
MII_REG_11 is shown in Table 8-31.
Return to the Summary Table.
Table 8-31. MII_REG_11 Register Field Descriptions
Bit
Field
Type
Reset
Description
15
dis_clk_125
R/W
0h
1b = stop clk_125 to MAC on IEEE power save mode 0b = keep
clk_125 to MAC
14
13-12
11
10
9
power_save_mode_en
RESERVED
R/W
R
0h
0h
0h
0h
0h
0h
0h
0h
Reserved
sgmii_soft_reset
use_phyad0_as_isolate
channel_debug_mode
debug_mode
R/WSC
R/W
R/W
R/W
R
Reset SGMII
Use PHY ADDRESS 5b0 as isolate
Enable channel debug mode
Enable debug mode
Reserved
8
7
RESERVED
6
cfg_soft_reset_non_clear R/W
0b = 0x1F = 4000 is self clearing 1b = 0x1F = 4000 is non self
clearing
5-4
3
cfg_reset_time_sel
int_polarity
R/W
R/W
R/W
R/W
R
0h
1h
0h
1h
0h
00b = 120ns 01b = 32us 10b = 256us 11b = 1024us
1b = Active low 0b = Active high
2
force_interrupt
int_en
1b = Force interrupt pin 0b = Do not force interrupt pin
1b = Enable interrupts 0b = Disable interrupts
Reserved
1
0
RESERVED
8.6.2.1.9 MII_REG_12 Register (Offset = 12h) [Reset = 0h]
MII_REG_12 is shown in Table 8-32.
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Return to the Summary Table.
Table 8-32. MII_REG_12 Register Field Descriptions
Bit
15
14
13
12
11
10
9
Field
Type
Reset
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
Description
link_qual_int
energy_det_int
link_int
R
Link quality bad interrupt status
Energy det change interrupt status
Link status change interrupt status
Reserved
R
R
RESERVED
esd_int
R
R
ESD fault detected interrupt status
Training done interrupt status
Reserved
ms_train_done_int
RESERVED
RESERVED
link_qual_int_en
energy_det_int_en
link_int_en
R
R
8
R
Reserved
7
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Link quality bad interrupt enable
Energy det change interrupt enable
Link status change interrupt enable
Reserved
6
5
4
unused_int_3
esd_int_en
3
ESD fault detected interrupt enable
Training done interrupt enable
Reserved
2
ms_train_done_int_en
unused_int_2
unused_int_1
1
0
Reserved
8.6.2.1.10 MII_REG_13 Register (Offset = 13h) [Reset = 0h]
MII_REG_13 is shown in Table 8-33.
Return to the Summary Table.
Table 8-33. MII_REG_13 Register Field Descriptions
Bit
15
14
13
12
11
10
9
Field
Type
Reset
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
Description
under_volt_int
over_volt_int
R
Under volt interrupt status
Over volt interrupt status
Reserved
R
RESERVED
R
RESERVED
R
Reserved
over_temp_int
sleep_int
R
Over temp interrupt status
Sleep mode change interrupt status
Data polarity change interrupt status
Not one hot interrupt status
Under volt interrupt enable
Over volt interrupt enable
Reserved
R
pol_change_int
not_one_hot_int
under_volt_int_en
over_volt_int_en
unused_int_6
unused_int_5
over_temp_int_en
sleep_int_en
R
8
R
7
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
6
5
4
Reserved
3
Over temp interrupt enable
Sleep mode change interrupt enable
Data Polarity change interrupt enable
Not one hot interrupt enable
2
1
pol_change_int_en
not_one_hot_int_en
0
8.6.2.1.11 MII_REG_16 Register (Offset = 16h) [Reset = 0h]
MII_REG_16 is shown in Table 8-34.
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Return to the Summary Table.
Table 8-34. MII_REG_16 Register Field Descriptions
Bit
15-11
10
Field
Type
Reset
Description
RESERVED
prbs_sync_loss
RESERVED
core_pwr_mode
R
0h
Reserved
R/W0C
0h
1b = Prbs lock had been lost 0b = Prbs lock never lost
Reserved
9
R
R
0h
8
0h
1b = Core is is normal power mode 0b = Core is in power down or
sleep mode
7
cfg_dig_pcs_loopback
loopback_mode
R/W
R/W
0h
0h
PCS digital loopback
6-0
000001b = PCS loop 000010b = RS loop 000100b = Digital loop
001000B = Analog loop 010000b = Reverse loop
8.6.2.1.12 MII_REG_18 Register (Offset = 18h) [Reset = 8h]
MII_REG_18 is shown in Table 8-35.
Return to the Summary Table.
Table 8-35. MII_REG_18 Register Field Descriptions
Bit
15
14
13
12
11
10
9
Field
Type
Reset
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
1h
0h
0h
0h
Description
ack_received_int
tx_valid_clr_int
RESERVED
R
Ack received interrupt status (OAM)
mr_tx_valid clear interrupt status (OAM)
Reserved
R
R
RESERVED
R
Reserved
por_done_int
no_frame_int
wake_req_int
lps_int
R
POR done interrupt status
No frame detect interrupt status
Wake request interrupt status
LPS interrupt status
R
R
8
R
7
ack_received_int_en
tx_valid_clr_int_en
RESERVED
R/W
R/W
R
Ack received interrupt enable (OAM)
mr_tx_valid clear interrupt enable (OAM)
Reserved
6
5
4
RESERVED
R
Reserved
3
por_done_int_en
no_frame_int_en
wake_req_int_en
lps_int_en
R/W
R/W
R/W
R/W
POR done interrupt enable
No frame detect interrupt enable
Wake request interrupt enable
LPS interrupt enable
2
1
0
8.6.2.1.13 MII_REG_19 Register (Offset = 19h) [Reset = X]
MII_REG_19 is shown in Table 8-36.
Return to the Summary Table.
Table 8-36. MII_REG_19 Register Field Descriptions
Bit
15-11
10
Field
Type
Reset
Description
RESERVED
dsp_energy_detect
RESERVED
SOR_PHYADDR
R
0h
Reserved
R
0h
DSP energy detected status
Reserved
9-5
R
0h
4-0
R
X
PHY ADDRESS latched from strap
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8.6.2.1.14 MII_REG_1E Register (Offset = 1Eh) [Reset = 0h]
MII_REG_1E is shown in Table 8-37.
Return to the Summary Table.
Table 8-37. MII_REG_1E Register Field Descriptions
Bit
15
14
13-2
1
Field
Type
R/WMC
R/W
R
Reset
Description
tdr_start
0h
1b = TDR start 0b = No TDR
cfg_tdr_auto_run
RESERVED
tdr_done
tdr_fail
0h
1b = TDR start automatically on link down 0b = TDR start manually
0h
Reserved
R
0h
TDR done status
TDR fail status
0
R
0h
8.6.2.1.15 MII_REG_1F Register (Offset = 1Fh) [Reset = 0h]
MII_REG_1F is shown in Table 8-38.
Return to the Summary Table.
Table 8-38. MII_REG_1F Register Field Descriptions
Bit
15
14
13
12-8
7
Field
Type
Reset
Description
sw_global_reset
digital_reset
sor_debug_option
tp_sel_1_9_5
standby_mode
R/WMC
R/WMC
R/W
0h
Hardware reset - Reset digital + register file
Soft reset - Reset only digital core
Use sw_global_reset as RESET pin source
Test port select[9:5] - Select module
Reserved
0h
0h
R/W
0h
R/W
0h
6
standby_mode_ch_sel_B_ R/W
An
0h
Reserved
5
RESERVED
tp_sel_1_4_0
R
0h
0h
Reserved
4-0
R/W
Test port select[4:0] - Select signals within module
8.6.2.1.16 C_AND_S_STATUS Register (Offset = 180h) [Reset = 0h]
C_AND_S_STATUS is shown in Table 8-39.
Return to the Summary Table.
Table 8-39. C_AND_S_STATUS Register Field Descriptions
Bit
15
14
13
12
11-8
7
Field
Type
Reset
Description
link_up
R
0h
link up defined by CnS
link_down
R
R
R
R
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
link down as defined by CnS
phy control in send data status
link status
phy_ctrl_send_data
link_status
pm_coded_state
sel_osc25_clk_n
pll_clk_sel
pm state
25MHz clock select
Pll clock select
6
5
pwr_seq_done
slave_ph1_done
channel_ok
Power seq done status
slave ph1 done status
channel okay status
Descrambler lock status
Local receiver status
4
3
2
descr_sync
1
loc_rcvr_status
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Table 8-39. C_AND_S_STATUS Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
0
rem_rcvr_status
R
0h
Remote receiver status
8.6.2.1.17 PM_TOP_CFG Register (Offset = 181h) [Reset = 440h]
PM_TOP_CFG is shown in Table 8-40.
Return to the Summary Table.
Table 8-40. PM_TOP_CFG Register Field Descriptions
Bit
15-12
11
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
RESERVED
R
0h
1h
0h
0h
1h
Reserved
10
cfg_lps_mac_pwrdn_en
RESERVED
R/W
R
Enable power down of mac inf during Low power mode
Reserved
9
8
cfg_lps_dbg_mode
cfg_lps_slp_rqst_to
R/W
R/W
LPS debug mode enable to reduce the sleep request timeout
7-6
Sleep rquest timer threshold. 2b00 = 0.4ms, 2b01 = 1ms, 2b10 =
4ms, 2b11 = 16ms
5-4
3
RESERVED
R
0h
0h
0h
Reserved
pll_gf_reset_reg
force_pll_gf_reset
R/W
R/W
1 = Reset is high 0 = Reset is low
2
1 = Force pll_clk mux reset to value defined in bit[8] 0 = Normal
mode
1
0
pll_clk_sel_reg
force_pll_ctrl
R/W
R/W
0h
0h
1: select PLL clock 0: select REF clock
1: force pll_clk_mux selec to value defined in Bit[2] 0: Do not force
pll_clk_mux select (Normal)
8.6.2.1.18 CLK_CTRL_CFG Register (Offset = 182h) [Reset = 0h]
CLK_CTRL_CFG is shown in Table 8-41.
Return to the Summary Table.
Table 8-41. CLK_CTRL_CFG Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
Reserved
14
R
R
R
R
0h
0h
0h
0h
Reserved
Reserved
Reserved
Reserved
13
12
11-0
8.6.2.1.19 LPS_CFG Register (Offset = 183h) [Reset = 0h]
LPS_CFG is shown in Table 8-42.
Return to the Summary Table.
Table 8-42. LPS_CFG Register Field Descriptions
Bit
15-8
7
Field
Type
Reset
Description
RESERVED
cfg_force_lps_st_en
cfg_force_lps_st
R
0h
Reserved
R/W
R/W
0h
Enable force lps state
Force lps state
6-0
0h
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8.6.2.1.20 LPS_CFG2 Register (Offset = 18Bh) [Reset = 0h]
LPS_CFG2 is shown in Table 8-43.
Return to the Summary Table.
Table 8-43. LPS_CFG2 Register Field Descriptions
Bit
15-9
8
Field
Type
Reset
Description
RESERVED
ed_en
R
0h
Reserved
R/W
0h
1b = Enable energy detection on MDI 0b = Disable energy detection
on MDI
7
6
sleep_en
R/W
0h
0h
1b = Allow PHY to enter sleep 0b = Do not allow PHY to enter sleep
cfg_auto_mode_en_strap R/WMC,1
LPS autonomous mode enable 1b = PHY enters normal mode on
power up 0b = PHY enters standby mode on power up
5
4
3
2
1
0
cfg_lps_mon_en_strap
cfg_lps_sleep_auto
cfg_lps_slp_confirm
cfg_lps_auto_pwrdn
cfg_lps_sleep_en
cfg_lps_sm_en
R/W
R/W
R/W
R/W
R/W
R/W
0h
0h
0h
0h
0h
0h
Reserved
Reserved
Reserved
Reserved
Reserved
8.6.2.1.21 LPS_CFG3 Register (Offset = 18Ch) [Reset = 0h]
LPS_CFG3 is shown in Table 8-44.
Return to the Summary Table.
Table 8-44. LPS_CFG3 Register Field Descriptions
Bit
15-8
7
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_lps_pwr_mode_7
cfg_lps_pwr_mode_6
cfg_lps_pwr_mode_5
cfg_lps_pwr_mode_4
cfg_lps_pwr_mode_3
cfg_lps_pwr_mode_2
cfg_lps_pwr_mode_1
cfg_lps_pwr_mode_0
R/WMC,0
R/WMC,0
R/WMC,0
R/WMC,0
R/WMC,0
R/WMC,0
R/WMC,0
R/WMC,0
0h
Reserved
6
0h
Reserved
5
0h
Reserved
4
0h
Set to enter standby mode
Reserved
3
0h
2
0h
Reserved
1
0h
Reserved
0
0h
Set to enter normal mode
8.6.2.1.22 LPS_STATUS Register (Offset = 18Eh) [Reset = 0h]
LPS_STATUS is shown in Table 8-45.
Return to the Summary Table.
Table 8-45. LPS_STATUS Register Field Descriptions
Bit
15-7
6-0
Field
Type
Reset
0h
0h
Description
Reserved
Observe LPS state : 0x2 = Standby mode 0x4 = Normal mode
RESERVED
status_lps_st
R
R
8.6.2.1.23 TDR_STATUS0 Register (Offset = 309h) [Reset = 0h]
TDR_STATUS0 is shown in Table 8-46.
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Return to the Summary Table.
Table 8-46. TDR_STATUS0 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
Description
peak1_loc
peak0_loc
R
0h
Peak 1 location in tap index
Peak 0 location in tap index
R
0h
8.6.2.1.24 TDR_STATUS1 Register (Offset = 30Ah) [Reset = 0h]
TDR_STATUS1 is shown in Table 8-47.
Return to the Summary Table.
Table 8-47. TDR_STATUS1 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
0h
0h
Description
Peak 3 location in tap index
Peak 2 location in tap index
peak3_loc
peak2_loc
R
R
8.6.2.1.25 TDR_STATUS2 Register (Offset = 30Bh) [Reset = 0h]
TDR_STATUS2 is shown in Table 8-48.
Return to the Summary Table.
Table 8-48. TDR_STATUS2 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
0h
0h
Description
Peak 0 amplitude in echo coeff
Peak 4 location in tap index
peak0_amp
peak4_loc
R
R
8.6.2.1.26 TDR_STATUS5 Register (Offset = 30Eh) [Reset = 0h]
TDR_STATUS5 is shown in Table 8-49.
Return to the Summary Table.
Table 8-49. TDR_STATUS5 Register Field Descriptions
Bit
15-5
4
Field
Type
Reset
Description
RESERVED
peak4_sign
peak3_sign
peak2_sign
peak1_sign
peak0_sign
R
0h
Reserved
R
R
R
R
R
0h
0h
0h
0h
0h
Peak 4 sign
Peak 3 sign
Peak 2 sign
Peak 1 sign
Peak 0 sign
3
2
1
0
8.6.2.1.27 TDR_TC12 Register (Offset = 30Fh) [Reset = 0h]
TDR_TC12 is shown in Table 8-50.
Return to the Summary Table.
Table 8-50. TDR_TC12 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-14
13-8
RESERVED
fault_loc
R
0h
Reserved
R
0h
See TC12
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Table 8-50. TDR_TC12 Register Field Descriptions (continued)
Bit
7-4
3-2
1-0
Field
Type
Reset
Description
See TC12
Reserved
See TC12
tdr_state
R
0h
RESERVED
tdr_activation
R
0h
R
0h
8.6.2.1.28 A2D_REG_05 Register (Offset = 405h) [Reset = 6400h]
A2D_REG_05 is shown in Table 8-51.
Return to the Summary Table.
Table 8-51. A2D_REG_05 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-10
ld_bias_1p0v_sl
R/W
19h
Bits to control the DAC current of LD and hence the swing. 001010b
= 400 001011b = 440 001100b = 480 001101b = 520 001110b =
560 001111b = 600 010000b = 640 010001b = 680 010010b = 720
010011b = 760 010100b = 800 010101b = 840 010110b = 880
010111b = 920 011000b = 960 011001b = 1000 011010b = 1040
011011b = 1080 011100b = 1120 011101b = 1160 011110b = 1200
9-0
RESERVED
R
0h
Reserved
8.6.2.1.29 A2D_REG_31 Register (Offset = 41Fh) [Reset = 0h]
A2D_REG_31 is shown in Table 8-52.
Return to the Summary Table.
Table 8-52. A2D_REG_31 Register Field Descriptions
Bit
15
14
13
12
11
10-7
6-3
2
Field
Type
Reset
Description
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
Reserved
R
R
R
R
R
R
R
R
R
0h
0h
0h
0h
0h
0h
0h
0h
0h
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
1
0
8.6.2.1.30 A2D_REG_40 Register (Offset = 428h) [Reset = 6000h]
A2D_REG_40 is shown in Table 8-53.
Return to the Summary Table.
Table 8-53. A2D_REG_40 Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RESERVED
SGMII_TESTMODE
RESERVED
R
0h
Reserved
14-13
12
R/W
R
3h
0h
0h
00b = 1000mV 01b = 1260mV 10b = 900mV 11b = 720mV
Reserved
11
SGMII_SOP_SON_SLEW R/W
_CTRL
0b = Fast SOP/SON rise/fall time 1b = Slow SOP/SON rise/fall time
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Table 8-53. A2D_REG_40 Register Field Descriptions (continued)
Bit
10
9-8
7
Field
Type
Reset
Description
Reserved
Reserved
Reserved
Reserved
Reserved
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
R
0h
R
0h
6-1
0
R
0h
R
0h
8.6.2.1.31 A2D_REG_41 Register (Offset = 429h) [Reset = 0h]
A2D_REG_41 is shown in Table 8-54.
Return to the Summary Table.
Table 8-54. A2D_REG_41 Register Field Descriptions
Bit
15-11
10
Field
Type
Reset
Description
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
Reserved
R
R
R
R
0h
0h
0h
0h
0h
Reserved
Reserved
Reserved
Reserved
9
8
7-2
1
SGMII_IO_LOOPBACK_E R/W
N
1b = Connects RX and TX signals internally to provide internal
loopback option without external components.
0
RESERVED
R
0h
Reserved
8.6.2.1.32 A2D_REG_42 Register (Offset = 42Ah) [Reset = 0h]
A2D_REG_42 is shown in Table 8-55.
Return to the Summary Table.
Table 8-55. A2D_REG_42 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
SGMII_CDR_TESTMODE R/W
_0
0h
SGMII RX CDR test mode
8.6.2.1.33 A2D_REG_43 Register (Offset = 42Bh) [Reset = 0h]
A2D_REG_43 is shown in Table 8-56.
Return to the Summary Table.
Table 8-56. A2D_REG_43 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
SGMII_CDR_TESTMODE R/W
_1
0h
SGMII RX CDR test mode
8.6.2.1.34 A2D_REG_44 Register (Offset = 42Ch) [Reset = 0h]
A2D_REG_44 is shown in Table 8-57.
Return to the Summary Table.
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Table 8-57. A2D_REG_44 Register Field Descriptions
Bit
15
14
13
12
11
10
9
Field
Type
Reset
Description
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
Reserved
R
0h
Reserved
R
0h
Reserved
R
0h
Reserved
R
0h
Reserved
R
0h
Reserved
R
0h
Reserved
8
R
0h
Reserved
7
R
0h
Reserved
6
R
0h
Reserved
5
R
0h
Reserved
4
SGMII_DIG_LOOPBACK_ R/W
EN
0h
1b = Loops back TX data to RX before the IO
3-1
0
RESERVED
RESERVED
R
R
0h
0h
Reserved
Reserved
8.6.2.1.35 A2D_REG_45 Register (Offset = 42Dh) [Reset = 0h]
A2D_REG_45 is shown in Table 8-58.
Return to the Summary Table.
Table 8-58. A2D_REG_45 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
SGMII_TESTOUT
R
0h
SGMII test mode output
8.6.2.1.36 A2D_REG_46 Register (Offset = 42Eh) [Reset = 0h]
A2D_REG_46 is shown in Table 8-59.
Return to the Summary Table.
Table 8-59. A2D_REG_46 Register Field Descriptions
Bit
15-12
11
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
sgmii_calib_watchdog_dis R/W
0h
0h
By default, SGMII calibration process has a watchdog timer. If
calibration is not ended till timer expires, then it is dsabled and
default value is taken. If this bit is set, then the calibration watchdog
timer is disabled.
10-9
sgmii_calib_watchdog_val R/W
Watchdog timer configuration for SGMII calibration sequence: 00 - If
not ended, calibration stops after 32us 01 - If not ended, calibration
stops after 48us 10 - If not ended, calibration stops after 64us 11 - If
not ended, calibration stops after 128us
8-7
6
sgmii_calib_avg
sgmii_do_calib
R/W
0h
0h
Number of repetitions of COMP_OFFSET_TUNE calibration (the
repetitions are for averaging): 00 - a single repetition 01 - 2
repetitions 10 - 4 repetitions 11 - 8 repetitions
R/WSC
SGMII start calibration command (mainly for debug) Please notice:
This register is WSC (write-self-clear) and not read-only!
5
4
3
SGMII_CDR_LOCK_SL
SGMII_MODE_force_en
R
0h
0h
0h
Indicates Sgmiis CDR lock status
R/W
SGMII_INPUT_TERM_EN R/W
_force_en
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Table 8-59. A2D_REG_46 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
2
SGMII_OUTPUT_EN_forc R/W
e_en
0h
1
0
SGMII_COMP_OFFSET_ R/W
TUNE_force_en
0h
0h
SGMII_DATA_SYNC_SL
R
8.6.2.1.37 A2D_REG_48 Register (Offset = 430h) [Reset = 960h]
A2D_REG_48 is shown in Table 8-60.
Return to the Summary Table.
Table 8-60. A2D_REG_48 Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RESERVED
RESERVED
RESERVED
DLL_EN
R
0h
Reserved
14
R
0h
0h
0h
9h
Reserved
Reserved
13
R
12
R/W
11-8
DLL_TX_DELAY_CTRL_S R/W
L
Refer to electrical specification for delay vs code information.
Refer to electrical specification for delay vs code information.
Reserved
7-4
3-0
DLL_RX_DELAY_CTRL_ R/W
SL
6h
0h
RESERVED
R
8.6.2.1.38 A2D_REG_66 Register (Offset = 442h) [Reset = 0h]
A2D_REG_66 is shown in Table 8-61.
Return to the Summary Table.
Table 8-61. A2D_REG_66 Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RESERVED
esd_event_count
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
Reserved
14-9
8
R
R
R
R
R
0h
0h
0h
0h
0h
Number gives the number of esd events on the copper channel
Reserved
Reserved
Reserved
Reserved
7-5
4
3-0
8.6.2.1.39 LEDS_CFG_1 Register (Offset = 450h) [Reset = 2610h]
LEDS_CFG_1 is shown in Table 8-62.
Return to the Summary Table.
Table 8-62. LEDS_CFG_1 Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RESERVED
R
0h
14
leds_bypass_stretching
leds_blink_rate
R/W
R/W
0h
2h
LED Signal Stretch
13-12
Blink Rate for the LED - 00b = 20Hz (50mSec) 01b = 10Hz
(100mSec) 10b = 5Hz (200mSec) 11b = 2Hz (500mSec)
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Table 8-62. LEDS_CFG_1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
11-8
led_2_option
R/W
6h
0000b = link OK 0001b = link OK + blink on TX/RX activity 0010b
= link OK + blink on TX activity 0011b = link OK + blink on RX
activity 0100b = link OK + 100Base-T1 Master 0101b = link OK +
100Base-T1 Slave 0110b = TX/RX activity with stretch option 0111b
= Reserved 1000b = Reserved 1001b = Link lost (remains on until
register 0x1 is read) 1010b = PRBS error latch until cleared by
0x620(1) 1011b = XMII TX/RX Error with stretch option
7-4
3-0
led_1_option
led_0_option
R/W
R/W
1h
0h
0000b = link OK 0001b = link OK + blink on TX/RX activity 0010b
= link OK + blink on TX activity 0011b = link OK + blink on RX
activity 0100b = link OK + 100Base-T1 Master 0101b = link OK +
100Base-T1 Slave 0110b = TX/RX activity with stretch option 0111b
= Reserved 1000b = Reserved 1001b = Link lost (remains on until
register 0x1 is read) 1010b = PRBS error (latch until cleared by
0x620(1) 1011b = XMII TX/RX Error with stretch option
0000b = link OK 0001b = link OK + blink on TX/RX activity 0010b
= link OK + blink on TX activity 0011b = link OK + blink on RX
activity 0100b = link OK + 100Base-T1 Master 0101b = link OK +
100Base-T1 Slave 0110b = TX/RX activity with stretch option 0111b
= Reserved 1000b = Reserved 1001b = Link lost (remains on until
register 0x1 is read) 1010b = PRBS error (latch until cleared by
0x620(1) 1011b = XMII TX/RX Error with stretch option
8.6.2.1.40 LEDS_CFG_2 Register (Offset = 451h) [Reset = 0h]
LEDS_CFG_2 is shown in Table 8-63.
Return to the Summary Table.
Table 8-63. LEDS_CFG_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
13-10
11-9
RESERVED
cfg_ieee_compl_sel
R
0h
Reserved
R/W
0h
Observe IEEE Compliance signals in LED_0_GPIO_0, when
LED_0_GPIO_CTRL= 'h5 as follows - 000b = loc_rcvr_status 001b
= rem_rcvr_status 010b = loc_snr_margin 011b = rem_phy_ready
100b = pma_watchdog_status 101b = link_sync_link_control
8
led_2_drv_en
R/W
0h
LED_2 Drive Enable, When set, drives the value as per
LED_2_DRV_VAL
7
6
5
led_2_drv_val
led_2_polarity
led_1_drv_en
R/W
R/W
R/W
0h
0h
0h
LED_2 Drive Value, when LED_2_DRV_EN is set
LED_2 polarity
LED_1 Drive Enable, When set, drives the value as per
LED_1_DRV_VAL
4
3
2
led_1_drv_val
led_1_polarity
led_0_drv_en
R/W
R/W
R/W
0h
0h
0h
LED_1 Drive Value, when LED_1_DRV_EN is set
LED_1 polarity
LED_0 Drive Enable, When set, drives the value as per
LED_0_DRV_VAL
1
0
led_0_drv_val
led_0_polarity
R/W
R/W
0h
0h
LED_0 Drive Value, when LED_0_DRV_EN is set
LED_0 polarity
8.6.2.1.41 IO_MUX_CFG_1 Register (Offset = 452h) [Reset = 0h]
IO_MUX_CFG_1 is shown in Table 8-64.
Return to the Summary Table.
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Table 8-64. IO_MUX_CFG_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
Reserved
Reserved
15-14
13-11
10-8
RESERVED
RESERVED
led_1_gpio_ctrl
R
0h
R
0h
R/W
0h
Controls the output of LED_1 IO - 000b = LED_1 (default: link OK +
blink on TX/RX activity) 001b = Reserved 010b = RGMII data match
indication 011b = Under-Voltage indication 100b = Interrupt 101b =
IEEE compliance signals 110b = constant 0 111b = constant 1
7-6
5-3
2-0
RESERVED
RESERVED
led_0_gpio_ctrl
R
0h
0h
0h
Reserved
Reserved
R
R/W
Controls the output of LED_0 IO: 000b = LED_0 (default: LINK)
001b = Reserved 010b = RGMII data match indication 011b = Under-
Voltage indication 100b = Interrupt 101b = IEEE compliance signals
(see 0x451[11:9]) 110b = constant 0 111b = constant 1
8.6.2.1.42 IO_MUX_CFG_2 Register (Offset = 453h) [Reset = 1h]
IO_MUX_CFG_2 is shown in Table 8-65.
Return to the Summary Table.
Table 8-65. IO_MUX_CFG_2 Register Field Descriptions
Bit
15-6
5-3
Field
Type
Reset
Description
RESERVED
clk_o_clk_source
R
0h
Reserved
R/W
0h
1h
Clock Observable in CLK_O pin - 000b = xi_osc_25m_1p0v_dl
(25MHz crystal output - from analog) 001b = Reserved 010b =
Reserved 011b = 125MHz clock 100b = 125MHz clock 101b =
Reserved 110b = Reserved 111b = Reserved
2-0
clk_o_gpio_ctrl
R/W
Controls the output of CLK_O IO - 000b = LED_2 (default: TX/RX
activity with stretch option(LED_2_OPTION=0x6) 001b = Clock out
(see 0x453[5:3]) 010b = RGMII data match indication 011b = Under-
Voltage indication 100b = constant 0 101b = constant 0 110b =
constant 0 111b = constant 1
8.6.2.1.43 IO_CONTROL_1 Register (Offset = 454h) [Reset = 0h]
IO_CONTROL_1 is shown in Table 8-66.
Return to the Summary Table.
Table 8-66. IO_CONTROL_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
io_control_1
R/W
0h
IO_CONTROL_1 : IO reflects the value written on this register when
enabled IO_OE_N_FORCE_CTRL=1 and IO_OE_N_VALUE=0 If
0 is written, IO will be forced to ouput LOW. If 1 is
written, IO will be forced to ouput HIGH. The following is
the bit position for pads. 0=LED_0_GPIO_0; 1=LED_1_GPIO_1;
2=CLKOUT_GPIO_2; 3=INT_N; 4=RESERVED; 5=RESERVED;
6=INH; 7=TX_CLK; 8=TX_CTRL; 9=TX_D0; 10=TX_D1; 11=TX_D2;
12=TX_D3; 13=RX_CLK; 14=RX_CTRL;15=RX_D0;
8.6.2.1.44 IO_CONTROL_2 Register (Offset = 455h) [Reset = 0h]
IO_CONTROL_2 is shown in Table 8-67.
Return to the Summary Table.
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Table 8-67. IO_CONTROL_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-14
13-9
RESERVED
cfg_other_impedance
R
0h
R/W
0h
Slew Rate Control for CLKOUT - 00000b = Default rise/fall time
00001b = Slower rise/fall time 00010b = Faster rise/fall time
8-7
pupd_value
R/W
0h
IO Test mode - pullup/pull down : 00b = No pull (HiZ) 01b = PullUP
10b = PullDown 11b = PullUp/PullDown (Both Enabled)
6
5
4
pupd_force_cntl
io_oe_n_value
R/W
R/W
R/W
0h
0h
0h
IO Test mode pull up/down override functional pull.
IO Test mode direction, related to IO_OE_N_FORCE_CTRL
io_oe_n_force_ctrl
IO Test mode (alternate to BSR). The IO direction is set by
IO_OE_N_VALUE and value is set by IO_CONTROL_1/2
3-0
io_control_2
R/W
0h
IO_CONTROL_2 : IO reflects the value written on this register when
enabled IO_OE_N_FORCE_CTRL=1 and IO_OE_N_VALUE=0 If 0
is written, IO will be forced to ouput LOW. If 1 is written, IO will
be forced to ouput HIGH. The following is the bit position for pads.
0=RX_D1; 1=RX_D2; 2=RX_D3; 3=STRP_1;
8.6.2.1.45 IO_CONTROL_3 Register (Offset = 456h) [Reset = 100h]
IO_CONTROL_3 is shown in Table 8-68.
Return to the Summary Table.
Table 8-68. IO_CONTROL_3 Register Field Descriptions
Bit
15-10
9-5
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_mac_rx_impedance
R/W
8h
0h
Slew Rate Control for RGMII pads - 01010b = Medium Slew (OA
tr/tf compliant, max tr/tf = 1ns) 01011b = Slowest Slew (For low
emissions, max tr/tf = 1.2ns) 01000b = Default mode (rgmii tr/tf
compliant, max tr/tf=750ps)
4-0
RESERVED
R
Reserved
8.6.2.1.46 IO_STATUS_1 Register (Offset = 457h) [Reset = 0h]
IO_STATUS_1 is shown in Table 8-69.
Return to the Summary Table.
Table 8-69. IO_STATUS_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
io_status_1
R
0h
IO_STATUS_1 : Register reflects the IO value, when enabled
IO_OE_N_FORCE_CTRL=1 and IO_OE_N_VALUE=1 If 0 is read,
IO is connected LOW at pin. If 1 is read, IO is connected
HIGH at pin. The following is the bit position for each
pad. 0=LED_0_GPIO_0; 1=LED_1_GPIO_1; 2=CLKOUT_GPIO_2;
3=INT_N; 4=RESERVED; 5=RESERVED; 6=INH; 7=TX_CLK;
8=TX_CTRL; 9=TX_D0; 10=TX_D1; 11=TX_D2; 12=TX_D3;
13=RX_CLK; 14=RX_CTRL;15=RX_D0;
8.6.2.1.47 IO_STATUS_2 Register (Offset = 458h) [Reset = 0h]
IO_STATUS_2 is shown in Table 8-70.
Return to the Summary Table.
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Table 8-70. IO_STATUS_2 Register Field Descriptions
Bit
15-4
3-0
Field
Type
Reset
Description
RESERVED
io_status_2
R
0h
R
0h
IO_STATUS_2 : Register reflects the IO value, when enabled
IO_OE_N_FORCE_CTRL=1 and IO_OE_N_VALUE=1 If 0 is read,
IO is connected LOW at pin. If 1 is read, IO is connected HIGH
at pin. The following is the bit position for each pad. 0=RX_D1;
1=RX_D2; 2=RX_D3; 3=STRP_1;
8.6.2.1.48 IO_CONTROL_4 Register (Offset = 459h) [Reset = 0h]
IO_CONTROL_4 is shown in Table 8-71.
Return to the Summary Table.
Table 8-71. IO_CONTROL_4 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
io_input_mode
R/W
0h
Each bit configures one pin into input mode as per mapping below
- 0=LED_0_GPIO_0; 1=LED_1_GPIO_1; 2=CLKOUT_GPIO_2;
3=INT_N; 4=TX_CLK; 5=TX_CTRL; 6=TX_D0; 7=TX_D1; 8=TX_D2;
9=TX_D3; 10=RX_CLK; 11=RX_CTRL;12=RX_D0; 13=RX_D1;
14=RX_D2; 15=RX_D3
8.6.2.1.49 IO_CONTROL_5 Register (Offset = 45Ah) [Reset = 0h]
IO_CONTROL_5 is shown in Table 8-72.
Return to the Summary Table.
Table 8-72. IO_CONTROL_5 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
io_output_mode
R/W
0h
Each bit configures one pin into output mode as per mapping below
- 0=LED_0_GPIO_0; 1=LED_1_GPIO_1; 2=CLKOUT_GPIO_2;
3=INT_N; 4=TX_CLK; 5=TX_CTRL; 6=TX_D0; 7=TX_D1; 8=TX_D2;
9=TX_D3; 10=RX_CLK; 11=RX_CTRL;12=RX_D0; 13=RX_D1;
14=RX_D2; 15=RX_D3
8.6.2.1.50 SOR_VECTOR_1 Register (Offset = 45Dh) [Reset = 0h]
SOR_VECTOR_1 is shown in Table 8-73.
Return to the Summary Table.
Table 8-73. SOR_VECTOR_1 Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RGMII_TX_SHIFT
RGMII_RX_SHIFT
SGMII_EN
R
0h
0x0 = TX shift disbaled 0x1 = TX shift enabled
14
R
R
R
R
R
0h
0h
0h
0h
0h
0x0 = RX shift disabled 0x1 = RX shift enabled
0x0 = SGMII disabled 0x1 = SGMII enabled
0x0 = RGMII disabled 0x1 = RGMII enabled
13
12
RGMII_EN
11-9
8-6
TEST_MODE
MAC_MODE
0x0 = SGMII 0x1 = Reserved 0x2 = Reserved 0x3 = Reserved 0x4 =
RGMII align 0x5 = RGMII TX shift 0x6 = RGMII TX and RX shift 0x7
= RGMII RX shift
5
MAS/SLV
R
0h
0x0 = Slave 0x1 = Master
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Table 8-73. SOR_VECTOR_1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
4-0
PHY_AD
R
0h
0x0 = PHY address 0 0x4 = PHY address 4 0x5 = PHY address 5
0x8 = PHY address 8 0xA = PHY address A 0xC = PHY address C
0xD = PHY address D 0xE = PHY address E 0xF = PHY address F
8.6.2.1.51 SOR_VECTOR_2 Register (Offset = 45Eh) [Reset = 0h]
SOR_VECTOR_2 is shown in Table 8-74.
Return to the Summary Table.
Table 8-74. SOR_VECTOR_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
0
AUTO/MANAGED
R
0h
0x0 = Autonomous mode enabled 0x1 = Managed mode enabled
8.6.2.1.52 REV_ID Register (Offset = 466h) [Reset = 0h]
REV_ID is shown in Table 8-75.
Return to the Summary Table.
Table 8-75. REV_ID Register Field Descriptions
Bit
15-4
3-0
Field
Type
Reset
Description
RESERVED
si_rev_id
R
0h
Reserved
R
0h
Internal revision ID
8.6.2.1.53 MONITOR_CTRL1 Register (Offset = 467h) [Reset = 12h]
MONITOR_CTRL1 is shown in Table 8-76.
Return to the Summary Table.
Table 8-76. MONITOR_CTRL1 Register Field Descriptions
Bit
15-8
7-6
Field
Type
Reset
Description
cfg_dc_offset_2c
cfg_cic_gain12_arith
cfg_cic_gain2
cfg_cic_gain1
R/W
0h
Analog control
R/W
R/W
R/W
0h
2h
2h
Analog control
Analog control
Analog control
5-3
2-0
8.6.2.1.54 MONITOR_CTRL2 Register (Offset = 468h) [Reset = 920h]
MONITOR_CTRL2 is shown in Table 8-77.
Return to the Summary Table.
Table 8-77. MONITOR_CTRL2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15
cfg_bypass_reset_sensor R/W
_val
0h
When cfg_bypass_fsm is 1, use this register to keep sensor in reset
14-12
11-9
8-6
cfg_rd_data
R/W
R/W
0h
4h
4h
4h
To read out monitor adc output through MDIO for debug
cfg_dec_factor_sensors
Analog control
Analog control
Analog control
cfg_dec_factor_gain_calib R/W
cfg_dec_factor_dc_calib R/W
5-3
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Table 8-77. MONITOR_CTRL2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
2-0
cfg_bypass_sel_num
R/W
0h
When cfg_bypass_fsm is 1, use this register to select the sensor
8.6.2.1.55 MONITOR_CTRL4 Register (Offset = 46Ah) [Reset = 94h]
MONITOR_CTRL4 is shown in Table 8-78.
Return to the Summary Table.
Table 8-78. MONITOR_CTRL4 Register Field Descriptions
Bit
15-9
8
Field
Type
Reset
Description
RESERVED
cfg_hist_clr
R
0h
RESERVED
R/W
0h
1h
CFG_HIST_CLR
7
cfg_discard_sample_num R/W
Number of samples to be discarded before starting averaging - 0b =
2 samples 1b = 4 samples
6
cfg_avg_sample_num
cfg_adc_clk_div
R/W
R/W
0h
1h
Number of samples for calculating the average before storing in
history - 0b = 2 samples 1b = 4 samples
5-4
Config options to select frequency of monitor adc clock - 00b =
12.5MHz 01b = 6.25MHz 10b = 3.125MHz 11b = Reserved
3
2
cfg_force_start
cfg_reset
R/W
R/W
0h
1h
Set to force start sensor monitor FSM even if link is not established
0b = Enable the monitor 1b = Monitor is held in reset state At any
point of time, if the signal is changed to 1, the module abruptly goes
to reset state
1
0
periodic
start
R/W
0h
0h
0b = Monitor is enabled only when start is set for one iteration 1b =
Monitor is enabled for periodic iteration
R/WSC
Start indication for sensor monitor FSM, self clearing
8.6.2.1.56 MONITOR_STAT1 Register (Offset = 47Bh) [Reset = 0h]
MONITOR_STAT1 is shown in Table 8-79.
Return to the Summary Table.
Table 8-79. MONITOR_STAT1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
stat_rd_data
R
0h
STAT_RD_DATA
8.6.2.1.57 SYNC_LINK_CONTROL_CFG Register (Offset = 509h) [Reset = 0h]
SYNC_LINK_CONTROL_CFG is shown in Table 8-80.
Return to the Summary Table.
Table 8-80. SYNC_LINK_CONTROL_CFG Register Field Descriptions
Bit
15-12
11
Field
Type
Reset
Description
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
R
0h
10
R
0h
9-2
1
R
0h
R
0h
0
R
0h
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8.6.2.1.58 BREAK_LINK_TIMER Register (Offset = 50Ah) [Reset = 1000h]
BREAK_LINK_TIMER is shown in Table 8-81.
Return to the Summary Table.
Table 8-81. BREAK_LINK_TIMER Register Field Descriptions
Bit
15-14
13
Field
Type
Reset
Description
RESERVED
RESERVED
R
0h
Reserved
R
0h
Reserved
12
cfg_fifo_reset_in_break_li R/W
nk
1h
Allow ADC FIFO to be in reset during break link timer
11
cfg_slave_send_s_32_mo R/W
de
0h
Enable mode where Slave PHY sends SEND_S signalling for a fixed
32 times once it has detected SEND_S Note : Should be enabled
only if 0x509[10] is not set
0h = Follow IEEE state machine
1h = Enable slave to send SEND_S 32 times
10-0
RESERVED
R
0h
Reserved
8.6.2.1.59 LPS_CONTROL_1 Register (Offset = 514h) [Reset = 8E3h]
LPS_CONTROL_1 is shown in Table 8-82.
Return to the Summary Table.
Table 8-82. LPS_CONTROL_1 Register Field Descriptions
Bit
15-12
11-9
8-6
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_tx_wake_cg
cfg_tx_sleep_cg
cfg_rx_wake_cg
cfg_rx_sleep_cg
R/W
R/W
R/W
R/W
4h
Control code to send on Tx for wake indication
Control code to send on Tx for sleep indication
Control code to expect on Rx for wake indication
Control code to expect on Rx for sleep indication
3h
5-3
4h
2-0
3h
8.6.2.1.60 LPS_CONTROL_2 Register (Offset = 515h) [Reset = 808h]
LPS_CONTROL_2 is shown in Table 8-83.
Return to the Summary Table.
Table 8-83. LPS_CONTROL_2 Register Field Descriptions
Bit
15
Field
Type
Reset
Description
RESERVED
cfg_wake_cg_cnt_th
R
0h
Reserved
14-8
R/W
8h
Number of continuous expected wake code groups required to
acknowledge and set LPS wake command received.
7
RESERVED
R
0h
8h
Reserved
6-0
cfg_sleep_cg_cnt_th
R/W
Number of continuous expected sleep code groups required to
acknowledge and set LPS sleep command received.
8.6.2.1.61 MAXWAIT_TIMER Register (Offset = 518h) [Reset = 17CEh]
MAXWAIT_TIMER is shown in Table 8-84.
Return to the Summary Table.
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Table 8-84. MAXWAIT_TIMER Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
cfg_maxwait_timer_init
R/W
17CEh
Maxwait timer value in us (value internally multiplied by 16)
8.6.2.1.62 PHY_CTRL_1G Register (Offset = 519h) [Reset = 3Dh]
PHY_CTRL_1G is shown in Table 8-85.
Return to the Summary Table.
Table 8-85. PHY_CTRL_1G Register Field Descriptions
Bit
15
14
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_phy_ctrl_fallback_on_ R/W
energy_lost_loc_rcvr
0h
0h
Allow phy control to go from TRAINING to COUNTDOWN to SILENT
on energy lost and loc_rcvr lock Note : Should be enabled only if
0x519[13] is disabled
13
cfg_phy_ctrl_fallback_on_ R/W
energy_lost
Allow phy control to go from TRAINING to COUNTDOWN to SILENT
on energy lost Note : Should be enabled only if 0x519[14] is disabled
12
11
10
9
cfg_bypass_dsp_reset
cfg_force_link_stat_val
cfg_force_link_stat
R/W
R/W
R/W
0h
0h
0h
0h
Bypass dsp reset from pcs
Forced link status value Valid only if 0x519[10] is set
Enable forcing link status value
cfg_link_control_override_ R/W
val
Override Value for link control (only valid is autoneg is enabled) Valid
only if 0x519[8] is set
8
cfg_link_control_override_ R/W
en
0h
Override Enable for link control (only valid is autoneg is enabled)
0h = Link_control override disbale
1h = Link_control override Eanable
7-0
cfg_minwait_timer_init
R/W
3Dh
Minwait timer value in us (value internally multiplied by 16)
8.6.2.1.63 TEST_MODE Register (Offset = 531h) [Reset = 0h]
TEST_MODE is shown in Table 8-86.
Return to the Summary Table.
Table 8-86. TEST_MODE Register Field Descriptions
Bit
15-9
8
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_test_mode4_tx_order R/W
0h
Order of symbols to be transmitted in Test mode 4
0h = T1 followed by T2
1h = T2 followed by T1
7-0
cfg_test_mode_7_data
R/W
0h
GMII data to transmit in Test mode 7
8.6.2.1.64 LINK_QUAL_1 Register (Offset = 543h) [Reset = 0h]
LINK_QUAL_1 is shown in Table 8-87.
Return to the Summary Table.
Table 8-87. LINK_QUAL_1 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
0h
0h
Description
Reserved
Link training time in ms (TC12)
RESERVED
link_training_time
R
R
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8.6.2.1.65 LINK_QUAL_2 Register (Offset = 544h) [Reset = 0h]
LINK_QUAL_2 is shown in Table 8-88.
Return to the Summary Table.
Table 8-88. LINK_QUAL_2 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
0h
0h
Description
Remote receiver time in ms (TC12)
Local receiver time in ms (TC12)
remote_receiver_time
local_receiver_time
R
R
8.6.2.1.66 LINK_DOWN_LATCH_STAT Register (Offset = 545h) [Reset = 0h]
LINK_DOWN_LATCH_STAT is shown in Table 8-89.
Return to the Summary Table.
Table 8-89. LINK_DOWN_LATCH_STAT Register Field Descriptions
Bit
15-6
5
Field
Type
Reset
Description
RESERVED
channel_ok_ll
R
0h
Reserved
R/W0C
0h
1b = Channel ok was never de-asserted 0b = Channel ok was de-
asserted
4
3
2
1
0
link_fail_inhibit_lh
send_s_sigdet_lh
hi_rfer_lh
R/W0C
R/W0C
R/W0C
R/W0S
R/W0S
0h
0h
0h
0h
0h
1b = Link fail inhibit assertion was reported 0b = Link fail inhibit
assertion was never reported
1b = Send s sigdet assertion was reported 0b = Send s sigdet
assertion was never reported
1b = High ri rfer assertion was reported 0b = High ri rfer assertion
was never reported
block_lock_ll
1b = Block lock de-assertion was never reported 0b = Block lock
de-assertion was never reported
pma_watchdog_ll
1b = Low pma watchdog was never reported 0b = Low pma watchdof
was reported
8.6.2.1.67 LINK_QUAL_3 Register (Offset = 547h) [Reset = 0h]
LINK_QUAL_3 is shown in Table 8-90.
Return to the Summary Table.
Table 8-90. LINK_QUAL_3 Register Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
0h
0h
Description
Link loss count since last power cycle (TC12)
Link fail without link loss count since last power cycle (TC12)
link_loss_cnt
link_fail_cnt
R
R
8.6.2.1.68 LINK_QUAL_4 Register (Offset = 548h) [Reset = 0h]
LINK_QUAL_4 is shown in Table 8-91.
Return to the Summary Table.
Table 8-91. LINK_QUAL_4 Register Field Descriptions
Bit
15-1
0
Field
Type
Reset
0h
0h
Description
Reserved
Communication ready status (TC12)
RESERVED
comm_ready
R
R
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8.6.2.1.69 PMA_WATCHDOG Register (Offset = 559h) [Reset = 51h]
PMA_WATCHDOG is shown in Table 8-92.
Return to the Summary Table.
Table 8-92. PMA_WATCHDOG Register Field Descriptions
Bit
15-7
6
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_pma_watchdog_force R/W
_val
1h
0h
1h
Force value for pma watchdog
Enable forcing pma watchdog
5
4
cfg_pma_watchdog_force R/W
_en
cfg_ieee_watchdog_en
R/W
1 : watchdog counters are started after link up 0: TBD
0h = TBD
1h = watchdog counters are started after link up
3-0
cfg_watchdog_cnt_clr_th R/W
1h
Number of 0, +1, -1 symbols to be seen in their respective watchdog
counter window to prevent them for asserting pma_watchdog_status
8.6.2.1.70 DATA_SCR_CFG Register (Offset = 55Ah) [Reset = 0h]
DATA_SCR_CFG is shown in Table 8-93.
Return to the Summary Table.
Table 8-93. DATA_SCR_CFG Register Field Descriptions
Bit
15
14-6
5
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_ecc_error
cfg_ecc_corrupt
cfg_rx_delay_data_scr
R/W
R/W
R/W
0h
0h
0h
9 bit error val xored to memory data input for ECC testing
Enable corruption of memory data for ECC testing
4
Delay generation of rx descrmabler symbols by 1 bit
0h = Do not delay generation of rx descrmabler symbols by 1 bit
1h = Delay generation of rx descrmabler symbols by 1 bit
3
2
cfg_tx_delay_data_scr
R/W
0h
0h
Delay generation of tx scrmabler symbols by 1 bit
0h = Do not delay generation of tx scrmabler symbols by 1 bit
1h = Delay generation of tx scrmabler symbols by 1 bit
cfg_rx_data_scr_order_inv R/W
cfg_tx_data_scr_order_inv R/W
Enable to generate rx descrambler symbols from S[0] instead of
S[14] Valid only if LPs 0x55A[1] is set (TI-TI link)
0h = Use S[14] as rx descrambler symbols
1h = Use S[0] as rx descrmabler symbols
1
0
0h
0h
Enable to generate tx scrambler symbols from S[0] instead of S[14]
Valid only if LPs 0x55A[2] is set (TI-TI link)
0h = Use S[14] as tx scrambler symbols
1h = Use S[0] as tx scrmabler symbols
cfg_data_scr_bypass
R/W
Bypass data scrmabler on Tx as well as Rx path
0h = Do not bypass data scramblers
1h = Bypass data scramblers
8.6.2.1.71 SYMB_POL_CFG Register (Offset = 55Bh) [Reset = 0h]
SYMB_POL_CFG is shown in Table 8-94.
Return to the Summary Table.
Table 8-94. SYMB_POL_CFG Register Field Descriptions
Bit
Field
Type
Reset
Description
15-5
RESERVED
R
0h
Reserved
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Table 8-94. SYMB_POL_CFG Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
4
cfg_slave_auto_pol_corre R/W
ction_en
0h
Correct tx polarity for slave based on received polarity
0h = Slave tx polarity independent of slave rx polarity
1h = Slave tx polarity to match received polarity
3
cfg_rx_symb_order_inv
R/W
0h
Order of received symbols S0 to S6 reversed to S6 to S0 Valid only if
LPs 0x55B[1] is set (TI-TI link)
0h = Order of received symbols S0 to S6 unchanged
1h = Order of received symbols S0 to S6 reversed to S6 to S0
2
1
cfg_rx_symb_pol_inv
R/W
R/W
0h
0h
Invert polarity of received symbols
0h = Unchanged polarity of received symbols
1h = Invert polarity of received symbols
cfg_tx_symb_order_inv
Order of transmit symbols S0 to S6 reversed to S6 to S0 Valid only if
LPs 0x55B[3] is set (TI-TI link)
0h = Order of transmit symbols S0 to S6 unchanged
1h = Order of transmit symbols S0 to S6 reversed to S6 to S0
0
cfg_tx_symb_pol_inv
R/W
0h
Invert polarity of transmit symbols
0h = Unchanged polarity of transmit symbols
1h = Invert polarity of transmit symbols
8.6.2.1.72 OAM_CFG Register (Offset = 55Ch) [Reset = 0h]
OAM_CFG is shown in Table 8-95.
Return to the Summary Table.
Table 8-95. OAM_CFG Register Field Descriptions
Bit
15-2
1
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_rx_oam_crc_data_in_ R/W
order
0h
Reverse order of data input to CRC checker in rx oam to MSB first
0h = Order of data input to CRC checker in rx oam is LSB first
1h = Order of data input to CRC checker in rx oam is MSB first
0
cfg_tx_oam_crc_data_in_ R/W
order
0h
Reverse order of data input to CRC calculator in tx oam to MSB first
0h = Order of data input to CRC calculator in tx oam is LSB first
1h = Order of data input to CRC calculator in tx oam is MSB first
8.6.2.1.73 TEST_MEM_CFG Register (Offset = 561h) [Reset = 17A0h]
TEST_MEM_CFG is shown in Table 8-96.
Return to the Summary Table.
Table 8-96. TEST_MEM_CFG Register Field Descriptions
Bit
Field
Type
Reset
Description
15-13
12-6
RESERVED
R
0h
Reserved
cfg_wait_time_xcorr_wen R/W
5Eh
Wait timer after TX_SEND_S after which testmem is written on
energy fall Note : Valid only if 0x561[3] is set
5
4
cfg_xcorr_dbg_sel R/W
1h
0h
0b = Select xcorr from aligned detector to write to test mem 1b =
Select xcorr from shifted detector to write to test mem Note : Valid
only if 0x561[3] is set
cfg_send_s_infinite_loop R/W
cfg_xcorr_dbg_test_mem R/W
enable transmitting infinite send_s sequence. For send_s debug.
Valid only in master and when 0x56A[15] is set.
0h = disable infinte send_s mode
1h = enable infinite send_s mode
3
0h
enabled xcorr debug for send_s. Valid only if 0x561[0] is 1b0
0h = Normal send_s debug. Refer to 0x561[1]
1h = Enabled xcorr debug
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Table 8-96. TEST_MEM_CFG Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
2
cfg_ecc_en
R/W
0h
Enable ECC logic for RS decoder memory
0h = ECC encoding/decoding is disabled
1h = ECC encoding/decoding is enabled
1
0
cfg_test_mem_sigdet_deb R/W
ug
0h
0h
Enable sidget debug mode in test mem send s mode Valid only if
0x561[0] is 1b0
0h = Test mem written in send s mode only on state transition
1h = Enable sigdet debug mode in test mem send s mode
cfg_pcs_test_mem_mode R/W
Choose send s or train rx test mem mode
0h = Send s info on test mem
1h = Train rx info on test mem
8.6.2.1.74 FORCE_CTRL1 Register (Offset = 573h) [Reset = 0h]
FORCE_CTRL1 is shown in Table 8-97.
Return to the Summary Table.
Table 8-97. FORCE_CTRL1 Register Field Descriptions
Bit
15-9
8
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_force_link_sync_state R/W
_en
0h
0h
Force link sync state enable
Force link sync state value
7-0
cfg_force_link_sync_state R/W
_val
8.6.2.1.75 MBIST_CTRL Register (Offset = 580h) [Reset = 0h]
MBIST_CTRL is shown in Table 8-98.
Return to the Summary Table.
Table 8-98. MBIST_CTRL Register Field Descriptions
Bit
15-7
6
Field
Type
Reset
Description
RESERVED
dftreadb_0
dftreada_0
test_resume_h
rst_l
R
0h
Reserved
R/W
R/W
R/W
R/W
R/W
R/W
R/W
0h
0h
0h
0h
0h
0h
0h
5
4
3
2
test_h
1
tmb_0
0
tma_0
8.6.2.1.76 MBIST_STAT Register (Offset = 581h) [Reset = 0h]
MBIST_STAT is shown in Table 8-99.
Return to the Summary Table.
Table 8-99. MBIST_STAT Register Field Descriptions
Bit
15-3
2
Field
Type
Reset
Description
RESERVED
fail_h_0
tst_done
R
0h
Reserved
R
0h
1
R
0h
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Table 8-99. MBIST_STAT Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
0
start_retention_h
R
0h
8.6.2.1.77 RGMII_CTRL Register (Offset = 600h) [Reset = 120h]
RGMII_CTRL is shown in Table 8-100.
Return to the Summary Table.
Table 8-100. RGMII_CTRL Register Field Descriptions
Bit
15-10
9-7
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
rgmii_rx_half_full_th
rgmii_tx_half_full_th
rgmii_tx_if_en
R/W
R/W
R/W
2h
2h
0h
RGMII RX sync FIFO half full threshold
RGMII TX sync FIFO half full threshold
6-4
3
RGMII enable bit Default from strap
0h = RGMII disable
1h = RGMII enable
2
1
0
invert_rgmii_txd
invert_rgmii_rxd
sup_tx_err_fd
R/W
R/W
R/W
0h
0h
0h
Invert RGMII Tx wire order - full swap [3:0] to [0:3]
0h = Keep RGMII Tx wire order same - [3:
1h = Invert RGMII Tx wire order - [3:
Invert RGMII Rx wire order - full swap [3:0] to [0:3]
0h = Keep RGMII Rx wire order same - [3:
1h = Invert RGMII Rx wire order - [3:
1: suppress tx_err in full duplex mode when tx_en set to zero 0:
allow tx_err assertion to PHY when tx_en set to zero (this bit can
disable the TX_ERR indication input)
0h = allow tx_err assertion to PHY when tx_en set to zero
1h = suppress tx_err in full duplex mode when tx_en set to zero
8.6.2.1.78 RGMII_FIFO_STATUS Register (Offset = 601h) [Reset = 0h]
RGMII_FIFO_STATUS is shown in Table 8-101.
Return to the Summary Table.
Table 8-101. RGMII_FIFO_STATUS Register Field Descriptions
Bit
15-4
3
Field
Type
Reset
Description
RESERVED
rgmii_rx_af_full_err
R
0h
Reserved
R/W0C
0h
RGMII RX fifo full error
0h = No empty fifo error
1h = RGMII TX full error has been indicated
2
1
0
rgmii_rx_af_empty_err
rgmii_tx_af_full_err
R/W0C
R/W0C
R/W0C
0h
0h
0h
RGMII RX fifo empty error
0h = No empty fifo error
1h = RGMII RX empty error has been indicated
RGMII TX fifo full error
0h = No empty fifo error
1h = RGMII TX full error has been indicated
rgmii_tx_af_empty_err
RGMII TX fifo empty error
0h = No empty fifo error
1h = RGMII TX empty error has been indicated
8.6.2.1.79 RGMII_DELAY_CTRL Register (Offset = 602h) [Reset = 0h]
RGMII_DELAY_CTRL is shown in Table 8-102.
Return to the Summary Table.
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Table 8-102. RGMII_DELAY_CTRL Register Field Descriptions
Bit
15-2
1
Field
Type
Reset
Description
RESERVED
rx_clk_sel
R
0h
Reserved
R/W
0h
In RGMII mode, Enable or disable the internal delay for RXD wrt
RX_CLK (use this mode when RGMII_RX_CLK and RGMII_RXD are
aligned). The delay magnitude can be configured by programming
register 0x430[7:4]
0h = clock and data are aligned
1h = clock on PIN is delayed by 90 degrees relative to RGMII_RX
data
0
tx_clk_sel
R/W
0h
In RGMII mode, Enable or disable the internal delay for TXD wrt
TX_CLK (use this mode when RGMII_TX_CLK and RGMII_TXD are
aligned). The delay magnitude can be configured by programming
register 0x430[11:8]
0h = clock and data are aligned
1h = clock is internally delayed by 90 degrees
8.6.2.1.80 SGMII_CTRL_1 Register (Offset = 608h) [Reset = 7Bh]
SGMII_CTRL_1 is shown in Table 8-103.
Return to the Summary Table.
Table 8-103. SGMII_CTRL_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15
sgmii_tx_err_dis
R/W
0h
1 = Disable SGMII TX Error indication 0 = Enable SGMII TX Error
indication
0h = Enable SGMII TX Error indication
1h = Disable SGMII TX Error indication
14
cfg_align_idx_force
cfg_align_idx_value
R/W
R/W
0h
0h
Force word boundray index selection
13-10
when cfg_align_idx_force = 1 This value set the iword boundray
index
9
8
cfg_sgmii_en
R/W
R/W
R/W
R/W
0h
0h
0h
3h
SGMII enable bit Default from strap
0h = SGMII disable
1h = SGMII enable
cfg_sgmii_rx_pol_invert
cfg_sgmii_tx_pol_invert
serdes_tx_bits_order
SGMII RX bus invert polarity
0h = Polarity not inverted
1h = SGMII RX bus invert polarity
7
SGMII TX bus invert polarity
0h = Polarity not inverted
1h = SGMII TX bus invert polarity
6-5
SERDES TX bits order (input to digital core) : 00 - MSB-first in every
SERDES data (10 bits) , 1st SERDES data goes to LSB of comma
detects 20bits bus (default) 01 - LSB-first in every SERDES data (10
bits) , 1st SERDES data goes to LSB of comma detects 20bits bus
10 - MSB-first in every SERDES data (10 bits) , 1st SERDES data
goes to MSB of comma detects 20bits bus 11 - LSB-first in every
SERDES data (10 bits) , 1st SERDES data goes to MSB of comma
detects 20bits bus
0h = MSB-first in every SERDES data (10 bits) , 1st SERDES data
goes to LSB of comma detects 20bits bus (default)
1h = LSB-first in every SERDES data (10 bits) , 1st SERDES data
goes to LSB of comma detects 20bits bus
2h = MSB-first in every SERDES data (10 bits) , 1st SERDES data
goes to MSB of comma detects 20bits bus
3h = LSB-first in every SERDES data (10 bits) , 1st SERDES data
goes to MSB of comma detects 20bits bus
4
serdes_rx_bits_order
R/W
1h
SERDES RX bits order (output of digital core) : 0 - MSB-first 1 -
LSB-first (reversed order)
0h = MSB-first
1h = LSB-first (reversed order)
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Table 8-103. SGMII_CTRL_1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
3
cfg_align_pkt_en
R/W
1h
For aligning the start of read out TX packet (towards serializer) w/
tx_even pulse. To sync with the Code_Group/OSET FSM code slots.
Default is 1, when using 0 we go back to Gemini code
2-1
sgmii_autoneg_timer
mr_an_enable
R/W
R/W
1h
1h
Selects duration of SGMII Auto-Negotiation timer: 00: 1.6ms 01: 2us
10: 800us 11: 11ms
0h = 1.6ms
1h = 2us
2h = 800us
3h = 11ms
0
1 = Enable SGMII Auto-Negotaition 0 = Disable SGMII Auto-
Negotiation
0h = Disable SGMII Auto-Negotiation
1h = Enable SGMII Auto-Negotaition
8.6.2.1.81 SGMII_EEE_CTRL_1 Register (Offset = 609h) [Reset = 6318h]
SGMII_EEE_CTRL_1 is shown in Table 8-104.
Return to the Summary Table.
Table 8-104. SGMII_EEE_CTRL_1 Register Field Descriptions
Bit
15-11
10-6
5-1
Field
Type
R/W
R/W
R/W
Reset
Description
cfg_tx_tr_timer_val
cfg_tx_tq_timer_val
cfg_tx_ts_timer_val
Ch
Ch
Ch
0
cfg_support_non_eee_ma R/W
c_sgmii_en
0h
special mode to support non sgmii eee mac in eee mode in the phy
8.6.2.1.82 SGMII_STATUS Register (Offset = 60Ah) [Reset = 0h]
SGMII_STATUS is shown in Table 8-105.
Return to the Summary Table.
Table 8-105. SGMII_STATUS Register Field Descriptions
Bit
15-13
12
Field
Type
Reset
Description
RESERVED
sgmii_page_received
R
0h
Reserved
R
R
R
0h
0h
0h
Indicates that a new auto neg page was received
0h = No new auto neg page received
1h = A new auto neg page received
11
10
link_status_1000bx
mr_an_complete
sgmii link status
0h = SGMII link down
1h = SGMII link up
sgmii autoneg complete indication
0h = SGMII autoneg not completed
1h = SGMII autoneg completed
9
8
cfg_align_en
R
R
0h
0h
word boundary FSM - align indication
cfg_sync_status
word boundary FSM - sync status indication
0h = sync not achieved
1h = sync achieved
7-4
3-0
cfg_align_idx
cfg_state
R
R
0h
0h
word boundary index selection
word boundary FSM state
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8.6.2.1.83 SGMII_EEE_CTRL_2 Register (Offset = 60Bh) [Reset = 5h]
SGMII_EEE_CTRL_2 is shown in Table 8-106.
Return to the Summary Table.
Table 8-106. SGMII_EEE_CTRL_2 Register Field Descriptions
Bit
15-4
3-0
Field
Type
Reset
0h
5h
Description
RESERVED
cfg_rx_quiet_timer_val
R
Reserved
R/W
8.6.2.1.84 SGMII_CTRL_2 Register (Offset = 60Ch) [Reset = 1Bh]
SGMII_CTRL_2 is shown in Table 8-107.
Return to the Summary Table.
Table 8-107. SGMII_CTRL_2 Register Field Descriptions
Bit
15-9
8
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
sgmii_signal_detect_force R/W
_val
0h
0h
SGMII cdr lock force value
SGMII cdr lock force enable
7
sgmii_signal_detect_force R/W
_en
6
mr_restart_an
tx_half_full_th
rx_half_full_th
R/WSC,0
0h
3h
3h
Restart sgmii autonegotiation
5-3
2-0
R/W
R/W
SGMII TX sync FIFO half full threshold
SGMII RX sync FIFO half full threshold
8.6.2.1.85 SGMII_FIFO_STATUS Register (Offset = 60Dh) [Reset = 0h]
SGMII_FIFO_STATUS is shown in Table 8-108.
Return to the Summary Table.
Table 8-108. SGMII_FIFO_STATUS Register Field Descriptions
Bit
15-4
3
Field
Type
Reset
Description
RESERVED
sgmii_rx_af_full_err
R
0h
Reserved
R/W0C
0h
SGMII RX fifo full error
0h = No error indication
1h = SGMII RX fifo full error has been indicated
2
1
0
sgmii_rx_af_empty_err
sgmii_tx_af_full_err
R/W0C
R/W0C
R/W0C
0h
0h
0h
SGMII RX fifo empty error
0h = No error indication
1h = SGMII RX fifo empty error has been indicated
SGMII TX fifo full error
0h = No error indication
1h = SGMII TX fifo full error has been indicated
sgmii_tx_af_empty_err
SGMII TX fifo empty error
0h = No error indication
1h = SGMII TX fifo empty error has been indicated
8.6.2.1.86 PRBS_STATUS_1 Register (Offset = 618h) [Reset = 0h]
PRBS_STATUS_1 is shown in Table 8-109.
Return to the Summary Table.
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Table 8-109. PRBS_STATUS_1 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
Description
RESERVED
prbs_err_ov_cnt
R
0h
Reserved
R
0h
Holds number of error counter overflow that received by the PRBS
checker. Value in this register is locked when write is done to register
prbs_status_6 bit[0] or bit[1]. Counter stops on 0xFF. Note: when
PRBS counters work in single mode, overflow counter is not active
8.6.2.1.87 PRBS_CTRL_1 Register (Offset = 619h) [Reset = 574h]
PRBS_CTRL_1 is shown in Table 8-110.
Return to the Summary Table.
Table 8-110. PRBS_CTRL_1 Register Field Descriptions
Bit
15-14
13
Field
Type
Reset
Description
RESERVED
cfg_pkt_gen_64
send_pkt
R
0h
Reserved
R/W
0h
0h
Reserved
12
R/WMC,0
Enables generating MAC packet with fix/incremental data w CRC
(pkt_gen_en has to be set and cfg_pkt_gen_prbs has to be clear)
Cleared automatically when pkt_done is set
0h = Stop MAC packet
1h = Transmit MAC packet w CRC
11
RESERVED
R
0h
5h
Reserved
10-8
cfg_prbs_chk_sel
R/W
000 : Checker receives from RGMII TX 001 : Checker receives
SGMII TX 101 : Checker receives from Cu RX
0h = Checker receives from RGMII TX
1h = Checker receives SGMII TX
5h = Checker receives from Cu RX
7
RESERVED
R
0h
7h
Reserved
6-4
cfg_prbs_gen_sel
R/W
000 : PRBS transmits to RGMII RX 001 : PRBS transmits to SGMII
RX 101 : PRBS transmits to Cu TX
0h = PRBS transmits to RGMII RX
1h = PRBS transmits to SGMII RX
5h = PRBS transmits to Cu TX
3
cfg_prbs_cnt_mode
R/W
0h
1 = Continuous mode, when one of the PRBS counters reaches
max value, pulse is generated and counter starts counting from zero
again 0 = Single mode, When one of the PRBS counters reaches
max value, PRBS checker stops counting.
0h = Single mode, When one of the PRBS counters reaches max
value, PRBS checker stops counting.
1h = Continuous mode, when one of the PRBS counters reaches
max value, pulse is generated and counter starts counting from zero
again
2
1
cfg_prbs_chk_enable
cfg_pkt_gen_prbs
R/W
R/W
1h
0h
Enable PRBS checker xbar (to receive data) To be enabled for
counters in 0x63C, 0x63D, 0x63E to work
0h = Disable PRBS checker
1h = Enable PRBS checker
If set: (1) When pkt_gen_en is set, PRBS packets are generated
continuously (3) When pkt_gen_en is cleared, PRBS RX checker is
still enabled If cleared: (1) When pkt_gen_en is set, non - PRBS
packet is generated (3) When pkt_gen_en is cleared, PRBS RX
checker is disabled as well
0h = Stop PRBS packet
1h = Transmit PRBS packet
0
pkt_gen_en
R/W
0h
1 = Enable packet/PRBS generator 0 = Disable packet/PRBS
generator
0h = Disable packet/PRBS generator
1h = Enable packet/PRBS generator
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8.6.2.1.88 PRBS_CTRL_2 Register (Offset = 61Ah) [Reset = 5DCh]
PRBS_CTRL_2 is shown in Table 8-111.
Return to the Summary Table.
Table 8-111. PRBS_CTRL_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
cfg_pkt_len_prbs
R/W
5DCh
Length (in bytes) of PRBS packets and MAC packets w CRC
8.6.2.1.89 PRBS_CTRL_3 Register (Offset = 61Bh) [Reset = 7Dh]
PRBS_CTRL_3 is shown in Table 8-112.
Return to the Summary Table.
Table 8-112. PRBS_CTRL_3 Register Field Descriptions
Bit
15-8
7-0
Field
Type
Reset
0h
7Dh
Description
Reserved
Inter-packet gap (in bytes) between packets
RESERVED
cfg_ipg_len
R
R/W
8.6.2.1.90 PRBS_STATUS_2 Register (Offset = 61Ch) [Reset = 0h]
PRBS_STATUS_2 is shown in Table 8-113.
Return to the Summary Table.
Table 8-113. PRBS_STATUS_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
prbs_byte_cnt
R
0h
Holds number of total bytes that received by the PRBS checker.
Value in this register is locked when write is done to register
prbs_status_6 bit[0] or bit[1]. When PRBS Count Mode set to zero,
count stops on 0xFFFF
8.6.2.1.91 PRBS_STATUS_3 Register (Offset = 61Dh) [Reset = 0h]
PRBS_STATUS_3 is shown in Table 8-114.
Return to the Summary Table.
Table 8-114. PRBS_STATUS_3 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
prbs_pkt_cnt_15_0
R
0h
Bits [15:0] of number of total packets received by the PRBS checker
Value in this register is locked when write is done to register
prbs_status_6 bit[0] or bit[1]. When PRBS Count Mode set to zero,
count stops on 0xFFFFFFFF
8.6.2.1.92 PRBS_STATUS_4 Register (Offset = 61Eh) [Reset = 0h]
PRBS_STATUS_4 is shown in Table 8-115.
Return to the Summary Table.
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Table 8-115. PRBS_STATUS_4 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
prbs_pkt_cnt_31_16
R
0h
Bits [31:16] of number of total packets received by the PRBS
checker Value in this register is locked when write is done to register
prbs_status_6 bit[0] or bit[1]. When PRBS Count Mode set to zero,
count stops on 0xFFFFFFFF
8.6.2.1.93 PRBS_STATUS_6 Register (Offset = 620h) [Reset = 0h]
PRBS_STATUS_6 is shown in Table 8-116.
Return to the Summary Table.
Table 8-116. PRBS_STATUS_6 Register Field Descriptions
Bit
15-13
12
Field
Type
Reset
Description
RESERVED
pkt_done
R
0h
Reserved
R
0h
0h
Set when all MAC packets w CRC are transmitted
0h = MAC packet transmission in progress
1h = MAC packets transmission completed
11
10
9
pkt_gen_busy
prbs_pkt_ov
prbs_byte_ov
prbs_lock
R
1 = Packet generator is in process 0 = Packet generator is not in
process
0h = Packet generator is not in process
1h = Packet generator is in process
R
R
R
R
0h
0h
0h
0h
If set, packet counter reached overflow Overflow is cleared when
PRBS counters are cleared - done by setting bit #1 of prbs_status_6
0h = No overflow
1h = Packet counter overflow
If set, bytes counter reached overflow Overflow is cleared when
PRBS counters are cleared - done by setting bit #1of prbs_status_6
0h = No overflow
1h = byte counter overflow
8
1 = PRBS checker is locked sync) on received byte stream 0 =
PRBS checker is not locked
0h = PRBS checker is not locked
1h = PRBS checker is locked sync) on received byte stream
7-0
prbs_err_cnt
Holds number of errored bits received by the PRBS checker Value
in this register is locked when write is done to bit[0] or bit[1] When
PRBS Count Mode set to zero, count stops on 0xFF Notes: Writing
bit 0 generates a lock signal for the PRBS counters. Writing bit 1
generates a lock and clear signal for the PRBS counters
8.6.2.1.94 PRBS_STATUS_8 Register (Offset = 622h) [Reset = 0h]
PRBS_STATUS_8 is shown in Table 8-117.
Return to the Summary Table.
Table 8-117. PRBS_STATUS_8 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pkt_err_cnt_15_0
R
0h
Bits [15:0] of number of total packets with error received by the
PRBS checker Value in this register is locked when write is done to
register prbs_status_6 bit[0] or bit[1]. When PRBS Count Mode set to
zero, count stops on 0xFFFFFFFF
8.6.2.1.95 PRBS_STATUS_9 Register (Offset = 623h) [Reset = 0h]
PRBS_STATUS_9 is shown in Table 8-118.
Return to the Summary Table.
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Table 8-118. PRBS_STATUS_9 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pkt_err_cnt_31_16
R
0h
Bits [31:16] of number of total packets with error received by the
PRBS checker Value in this register is locked when write is done to
register prbs_status_6 bit[0] or bit[1]. When PRBS Count Mode set to
zero, count stops on 0xFFFFFFFF
8.6.2.1.96 PRBS_CTRL_4 Register (Offset = 624h) [Reset = 5511h]
PRBS_CTRL_4 is shown in Table 8-119.
Return to the Summary Table.
Table 8-119. PRBS_CTRL_4 Register Field Descriptions
Bit
15-8
7-6
Field
Type
Reset
Description
cfg_pkt_data
cfg_pkt_mode
R/W
55h
Fixed data to be sent in Fix data mode
R/W
R/W
0h
2h
2b00 - Incremental 2b01 - Fixed 2b1x - PRBS
0h = Incremental
1h = Fixed
5-3
cfg_pattern_vld_bytes
Number of bytes of valid pattern in packet (Max - 6)
0h = 0 bytes
1h = 1 bytes
2h = 2 bytes
3h = 3 bytes
4h = 4 bytes
5h = 5 bytes
6h = 6 bytes
7h = 6 bytes
2-0
cfg_pkt_cnt
R/W
1h
000b = 1 packet 001b = 10 packets 010b = 100 packets 011b =
1000 packets 100b = 10000 packets 101b = 100000 packets 110b =
1000000 packets 111b = Continuous packets
0h = 1 packet
1h = 10 packets
2h = 100 packets
3h = 1000 packets
4h = 10000 packets
5h = 100000 packets
6h = 1000000 packets
7h = Continuous packets
8.6.2.1.97 PRBS_CTRL_5 Register (Offset = 625h) [Reset = 0h]
PRBS_CTRL_5 is shown in Table 8-120.
Return to the Summary Table.
Table 8-120. PRBS_CTRL_5 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pattern_15_0
R/W
0h
Bits 15:0 of pattern
8.6.2.1.98 PRBS_CTRL_6 Register (Offset = 626h) [Reset = 0h]
PRBS_CTRL_6 is shown in Table 8-121.
Return to the Summary Table.
Table 8-121. PRBS_CTRL_6 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pattern_31_16
R/W
0h
Bits 31:16 of pattern
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8.6.2.1.99 PRBS_CTRL_7 Register (Offset = 627h) [Reset = 0h]
PRBS_CTRL_7 is shown in Table 8-122.
Return to the Summary Table.
Table 8-122. PRBS_CTRL_7 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pattern_47_32
R/W
0h
Bits 47:32 of pattern
8.6.2.1.100 PRBS_CTRL_8 Register (Offset = 628h) [Reset = 0h]
PRBS_CTRL_8 is shown in Table 8-123.
Return to the Summary Table.
Table 8-123. PRBS_CTRL_8 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pmatch_data_15_0
R/W
0h
Bits 15:0 of Perfect Match Data - used for DA (destination address)
match
8.6.2.1.101 PRBS_CTRL_9 Register (Offset = 629h) [Reset = 0h]
PRBS_CTRL_9 is shown in Table 8-124.
Return to the Summary Table.
Table 8-124. PRBS_CTRL_9 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pmatch_data_31_16
R/W
0h
Bits 31:16 of Perfect Match Data - used for DA (destination address)
match
8.6.2.1.102 PRBS_CTRL_10 Register (Offset = 62Ah) [Reset = 0h]
PRBS_CTRL_10 is shown in Table 8-125.
Return to the Summary Table.
Table 8-125. PRBS_CTRL_10 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
pmatch_data_47_32
R/W
0h
Bits 47:32 of Perfect Match Data - used for DA (destination address)
match
8.6.2.1.103 CRC_STATUS Register (Offset = 638h) [Reset = 0h]
CRC_STATUS is shown in Table 8-126.
Return to the Summary Table.
Table 8-126. CRC_STATUS Register Field Descriptions
Bit
15-2
1
Field
Type
Reset
0h
0h
Description
RESERVED
rx_bad_crc
R
Reserved
R
CRC error indication in packet received on Cu RX
0h = No CRC error
1h = CRC error
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Table 8-126. CRC_STATUS Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
0
tx_bad_crc
R
0h
CRC error indication in packet transmitted on Cu TX
0h = No CRC error
1h = CRC error
8.6.2.1.104 PKT_STAT_1 Register (Offset = 639h) [Reset = 0h]
PKT_STAT_1 is shown in Table 8-127.
Return to the Summary Table.
Table 8-127. PKT_STAT_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
tx_pkt_cnt_15_0
0h
Lower 16 bits of Tx packet counter Note : Register is cleared when
0x39, 0x3A, 0x3B are read in sequence
8.6.2.1.105 PKT_STAT_2 Register (Offset = 63Ah) [Reset = 0h]
PKT_STAT_2 is shown in Table 8-128.
Return to the Summary Table.
Table 8-128. PKT_STAT_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
tx_pkt_cnt_31_16
0h
Upper 16 bits of Tx packet counter Note : Register is cleared when
0x39, 0x3A, 0x3B are read in sequence
8.6.2.1.106 PKT_STAT_3 Register (Offset = 63Bh) [Reset = 0h]
PKT_STAT_3 is shown in Table 8-129.
Return to the Summary Table.
Table 8-129. PKT_STAT_3 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
tx_err_pkt_cnt
0h
Tx packet w error (CRC error) counter Note : Register is cleared
when 0x39, 0x3A, 0x3B are read in sequence
8.6.2.1.107 PKT_STAT_4 Register (Offset = 63Ch) [Reset = 0h]
PKT_STAT_4 is shown in Table 8-130.
Return to the Summary Table.
Table 8-130. PKT_STAT_4 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
rx_pkt_cnt_15_0
0h
Lower 16 bits of Rx packet counter Note : Register is cleared when
0x3C, 0x3D, 0x3E are read in sequence
8.6.2.1.108 PKT_STAT_5 Register (Offset = 63Dh) [Reset = 0h]
PKT_STAT_5 is shown in Table 8-131.
Return to the Summary Table.
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Table 8-131. PKT_STAT_5 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
rx_pkt_cnt_31_16
0h
Upper 16 bits of Rx packet counter Note : Register is cleared when
0x3C, 0x3D, 0x3E are read in sequence
8.6.2.1.109 PKT_STAT_6 Register (Offset = 63Eh) [Reset = 0h]
PKT_STAT_6 is shown in Table 8-132.
Return to the Summary Table.
Table 8-132. PKT_STAT_6 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
rx_err_pkt_cnt
0h
Rx packet w error (CRC error) counter Note : Register is cleared
when 0x3C, 0x3D, 0x3E are read in sequence
8.6.2.1.110 DSP_REG_0 Register (Offset = 800h) [Reset = 0h]
DSP_REG_0 is shown in Table 8-133.
Return to the Summary Table.
Table 8-133. DSP_REG_0 Register Field Descriptions
Bit
15
14
13
12
11
10
9
Field
Type
Reset
Description
RESERVED
RESERVED
RESERVED
RESERVED
cfg_deq_bypass
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
R
0h
Reserved
R
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
0h
Reserved
Reserved
Reserved
R
R
R/W
R
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
R
8
R
7
R
6
R
5
R
4
R
3
R
2
R
1
R
0
R
8.6.2.1.111 SQI_REG_1 Register (Offset = 871h) [Reset = 0h]
SQI_REG_1 is shown in Table 8-134.
Return to the Summary Table.
Table 8-134. SQI_REG_1 Register Field Descriptions
Bit
7-5
4
Field
Type
Reset
Description
worst_sqi_out
RESERVED
0h
3 bit Worst SQI since last read (see SQI mapping above)
Reserved
R
0h
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Table 8-134. SQI_REG_1 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
3-1
sqi_out
R
0h
3 bit SQI - (mse here refers to Mean Square Error 0x875[9:0]) 0b000
= MSE > 102 0b001 = 81 < MSE ≤102 0b010 = 65 < MSE ≤ 81
0b011 = 51 < MSE ≤ 65 0b100 = 41 < MSE ≤ 51 0b101 = 32 < MSE
≤ 41 0b110 = 25 < MSE ≤ 32 0b111 = MSE ≤ 25
0
RESERVED
R
0h
Reserved
8.6.2.1.112 SQI_1 Register (Offset = 8ADh) [Reset = 3051h]
SQI_1 is shown in Table 8-135.
Return to the Summary Table.
Table 8-135. SQI_1 Register Field Descriptions
Bit
Field
Type
R/W
R/W
Reset
Description
15-12
11-10
cfg_hist_1_2
cfg_acc_window_sel
3h
Hysteresis between SQI value 1 and 2
0h
Accumulator window select - 00b = 90us 01b = 180us 10b = 360us
11b = 720us
9-0
cfg_sqi_th_1_2
R/W
51h
Threshold between SQI value 1 and 2
8.6.2.1.113 SQI_2 Register (Offset = 8EDh) [Reset = 3041h]
SQI_2 is shown in Table 8-136.
Return to the Summary Table.
Table 8-136. SQI_2 Register Field Descriptions
Bit
15-12
11-10
9-0
Field
Type
R/W
R
Reset
Description
cfg_hist_2_3
RESERVED
cfg_sqi_th_2_3
3h
Hysteresis between SQI value 2 and 3
Reserved
0h
R/W
41h
Threshold between SQI value 2 and 3
8.6.2.1.114 SQI_3 Register (Offset = 8EFh) [Reset = 3033h]
SQI_3 is shown in Table 8-137.
Return to the Summary Table.
Table 8-137. SQI_3 Register Field Descriptions
Bit
15-12
11-10
9-0
Field
Type
R/W
R
Reset
Description
cfg_hist_3_4
RESERVED
cfg_sqi_th_3_4
3h
Hysteresis between SQI value 3 and 4
Reserved
0h
R/W
33h
Threshold between SQI value 3 and 4
8.6.2.1.115 SQI_4 Register (Offset = 8F0h) [Reset = 3029h]
SQI_4 is shown in Table 8-138.
Return to the Summary Table.
Table 8-138. SQI_4 Register Field Descriptions
Bit
Field
Type
R/W
R
Reset
Description
15-12
11-10
cfg_hist_4_5
RESERVED
3h
Hysteresis between SQI value 4 and 5
Reserved
0h
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Table 8-138. SQI_4 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
9-0
cfg_sqi_th_4_5
R/W
29h
Threshold between SQI value 4 and 5
8.6.2.1.116 SQI_5 Register (Offset = 8F1h) [Reset = 2020h]
SQI_5 is shown in Table 8-139.
Return to the Summary Table.
Table 8-139. SQI_5 Register Field Descriptions
Bit
15-12
11-10
9-0
Field
Type
R/W
R
Reset
Description
cfg_hist_5_6
RESERVED
cfg_sqi_th_5_6
2h
Hysteresis between SQI value 5 and 6
Reserved
0h
R/W
20h
Threshold between SQI value 5 and 6
8.6.2.1.117 SQI_6 Register (Offset = 8F2h) [Reset = 2019h]
SQI_6 is shown in Table 8-140.
Return to the Summary Table.
Table 8-140. SQI_6 Register Field Descriptions
Bit
15-12
11-10
9-0
Field
Type
R/W
R
Reset
Description
cfg_hist_6_7
RESERVED
cfg_sqi_th_6_7
2h
Hysteresis between SQI value 6 and 7
Reserved
0h
R/W
19h
Threshold between SQI value 6 and 7
8.6.2.1.118 PMA_PMD_CONTROL_1 Register (Offset = 1000h) [Reset = 0h]
PMA_PMD_CONTROL_1 is shown in Table 8-141.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-141. PMA_PMD_CONTROL_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15
pma_reset_2
R
0h
1 = PMA/PMD reset 0 = Normal operation Note - RW bit, self
clearing Note - 0x1 added in [15:12] to differentiate
0h = Normal operation
1h = PMA/PMD reset
14-12
11
RESERVED
R
R
0h
0h
Reserved
cfg_low_power_2
1 = Low-power mode 0 = Normal operation Note - RW bit Note - 0x1
added in [15:12] to differentiate
0h = Normal operation
1h = Low-power mode
10-0
RESERVED
R
0h
Reserved
8.6.2.1.119 PMA_PMD_CONTROL_2 Register (Offset = 1007h) [Reset = 3Dh]
PMA_PMD_CONTROL_2 is shown in Table 8-142.
Return to the Summary Table.
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First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-142. PMA_PMD_CONTROL_2 Register Field Descriptions
Bit
15-6
5-0
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_pma_type_selection
R/W
3Dh
BASE-T1 type selection for device Note - 0x1 added in [15:12] to
differentiate
3Dh = BASE-T1 type selection for device
8.6.2.1.120 PMA_PMD_TRANSMIT_DISABLE Register (Offset = 1009h) [Reset = 0h]
PMA_PMD_TRANSMIT_DISABLE is shown in Table 8-143.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-143. PMA_PMD_TRANSMIT_DISABLE Register Field Descriptions
Bit
15-1
0
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
cfg_transmit_disable_2
R
0h
1 = Transmit disable 0 = Normal operation Note - RW bit Note - 0x1
added in [15:12] to differentiate
0h = Normal operation
1h = Transmit disable
8.6.2.1.121 PMA_PMD_EXTENDED_ABILITY2 Register (Offset = 100Bh) [Reset = 800h]
PMA_PMD_EXTENDED_ABILITY2 is shown in Table 8-144.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-144. PMA_PMD_EXTENDED_ABILITY2 Register Field Descriptions
Bit
15-12
11
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
base_t1_extended_abilitie
s
R
1h
1 = PMA/PMD has BASE-T1 extended abilities listed in register 1.18
0 = PMA/PMD does not have BASE-T1 extended abilities Note - 0x1
added in [15:12] to differentiate
0h = PMA/PMD does not have BASE-T1 extended abilities
1h = PMA/PMD has BASE-T1 extended abilities listed in register
1.18
10-0
RESERVED
R
0h
Reserved
8.6.2.1.122 PMA_PMD_EXTENDED_ABILITY Register (Offset = 1012h) [Reset = 2h]
PMA_PMD_EXTENDED_ABILITY is shown in Table 8-145.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-145. PMA_PMD_EXTENDED_ABILITY Register Field Descriptions
Bit
Field
Type
Reset
Description
15-2
RESERVED
R
0h
Reserved
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Table 8-145. PMA_PMD_EXTENDED_ABILITY Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
1
mr_1000_base_t1_ability
R
1h
1 = PMA/PMD is able to perform 1000BASE-T1 0 = PMA/PMD is
not able to perform 1000BASE-T1 Note - 0x1 added in [15:12] to
differentiate
0h = PMA/PMD is not able to perform 1000BASE-T1
1h = PMA/PMD is able to perform 1000BASE-T1
0
mr_100_base_t1_ability
R
0h
1 = PMA/PMD is able to perform 100BASE-T1 0 = PMA/PMD is
not able to perform 100BASE-T1 Note - 0x1 added in [15:12] to
differentiate
0h = PMA/PMD is not able to perform 100BASE-T1
1h = PMA/PMD is able to perform 100BASE-T1
8.6.2.1.123 PMA_PMD_CONTROL Register (Offset = 1834h) [Reset = 8000h]
PMA_PMD_CONTROL is shown in Table 8-146.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-146. PMA_PMD_CONTROL Register Field Descriptions
Bit
15
14
Field
Type
Reset
Description
RESERVED
cfg_master_slave_val
R
1h
Reserved
R/W
0h
1 = Configure PHY as MASTER 0 = Configure PHY as SLAVE Note -
0x1 added in [15:12] to differentiate
0h = Configure PHY as SLAVE
1h = Configure PHY as MASTER
13-4
3-0
RESERVED
RESERVED
R
R
0h
0h
Reserved
Reserved
8.6.2.1.124 PMA_CONTROL Register (Offset = 1900h) [Reset = 0h]
PMA_CONTROL is shown in Table 8-147.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-147. PMA_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
15
pma_reset
R
0h
1 = PMA/PMD reset 0 = Normal operation Note - RW bit, self
clearing Note - 0x1 added in [15:12] to differentiate
0h = Normal operation
1h = PMA/PMD reset
14
cfg_transmit_disable
R
0h
1 = Transmit disable 0 = Normal operation Note - RW bit Note - 0x1
added in [15:12] to differentiate
0h = Normal operation
1h = Transmit disable
13-12
11
RESERVED
R
R
0h
0h
Reserved
cfg_low_power
1 = Low-power mode 0 = Normal operation Note - RW bit Note - 0x1
added in [15:12] to differentiate
0h = Normal operation
1h = Low-power mode
10-0
RESERVED
R
0h
Reserved
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8.6.2.1.125 PMA_STATUS Register (Offset = 1901h) [Reset = 900h]
PMA_STATUS is shown in Table 8-148.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-148. PMA_STATUS Register Field Descriptions
Bit
15-12
11
Field
Type
Reset
Description
RESERVED
oam_ability
R
0h
Reserved
R
1h
1 = PHY has 1000BASE-T1 OAM ability 0 = PHY does not
have 1000BASE-T1 OAM ability Note - 0x1 added in [15:12] to
differentiate
0h = PHY does not have 1000BASE-T1 OAM ability
1h = PHY has 1000BASE-T1 OAM ability
10
9
eee_ability
R
R
0h
0h
1 = PHY has EEE ability 0 = PHY does not have EEE ability Note -
0x1 added in [15:12] to differentiate
0h = PHY does not have EEE ability
1h = PHY has EEE ability
receive_fault_ability
1 = PMA/PMD has the ability to detect a fault condition on the
receive path 0 = PMA/PMD does not have the ability to detect a
fault condition on the receive path Note - 0x1 added in [15:12] to
differentiate
0h = PMA/PMD does not have the ability to detect a fault condition
on the receive path
1h = PMA/PMD has the ability to detect a fault condition on the
receive path
8
low_power_ability
R
1h
1 = PMA/PMD has low-power ability 0 = PMA/PMD does not have
low-power ability Note - 0x1 added in [15:12] to differentiate
0h = PMA/PMD does not have low-power ability
1h = PMA/PMD has low-power ability
7-3
2
RESERVED
R
R
0h
0h
Reserved
receive_polarity
1 = Receive polarity is reversed 0 = Receive polarity is not reversed
Note - 0x1 added in [15:12] to differentiate
0h = Receive polarity is not reversed
1h = Receive polarity is reversed
1
0
receive_fault
R
0h
0h
1 = Fault condition detected 0 = Fault condition not detected Note -
0x1 added in [15:12] to differentiate
0h = Fault condition not detected
1h = Fault condition detected
pma_receive_link_status_l R/W0S
l
1 = PMA/PMD receive link up 0 = PMA/PMD receive link down Note -
0x1 added in [15:12] to differentiate
0h = PMA/PMD receive link down
1h = PMA/PMD receive link up
8.6.2.1.126 TRAINING Register (Offset = 1902h) [Reset = 2h]
TRAINING is shown in Table 8-149.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-149. TRAINING Register Field Descriptions
Bit
Field
Type
Reset
Description
15-11
10-4
RESERVED
cfg_training_user_fld
R
0h
Reserved
R/W
0h
7-bit user defined field to send to the link partner Note - 0x1 added in
[15:12] to differentiate
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Table 8-149. TRAINING Register Field Descriptions (continued)
Bit
3-2
1
Field
Type
Reset
Description
RESERVED
cfg_oam_en
R
0h
Reserved
R/W
1h
1 = 1000BASE-T1 OAM ability advertised to link partner 0 =
1000BASE-T1 OAM ability not advertised to link partner Note - 0x1
added in [15:12] to differentiate
0h = 1000BASE-T1 OAM ability not advertised to link partner
1h = 1000BASE-T1 OAM ability advertised to link partner
0
cfg_eee_en
R/W
0h
1 = EEE ability advertised to link partner 0 = EEE ability not
advertised to link partner Note - 0x1 added in [15:12] to differentiate
0h = EEE ability not advertised to link partner
1h = EEE ability advertised to link partner
8.6.2.1.127 LP_TRAINING Register (Offset = 1903h) [Reset = 0h]
LP_TRAINING is shown in Table 8-150.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-150. LP_TRAINING Register Field Descriptions
Bit
Field
Type
Reset
Description
15-11
10-4
RESERVED
lp_training_user_fld
R
0h
Reserved
R
0h
7-bit user defined field received from the link partner Note - 0x1
added in [15:12] to differentiate
3-2
1
RESERVED
lp_oam_adv
R
R
0h
0h
Reserved
1 = Link partner has 1000BASE-T1 OAM ability 0 = Link partner
does not have 1000BASE-T1 OAM ability Note - 0x1 added in
[15:12] to differentiate
0h = Link partner does not have 1000BASE-T1 OAM ability
1h = Link partner has 1000BASE-T1 OAM ability
0
lp_eee_adv
R
0h
1 = Link partner has EEE ability 0 = Link partner does not have EEE
ability Note - 0x1 added in [15:12] to differentiate
0h = Link partner does not have EEE ability
1h = Link partner has EEE ability
8.6.2.1.128 TEST_MODE_CONTROL Register (Offset = 1904h) [Reset = 0h]
TEST_MODE_CONTROL is shown in Table 8-151.
Return to the Summary Table.
First nibble (0x1) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
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Table 8-151. TEST_MODE_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
15-13
cfg_test_mode
R/W
0h
111b = Test mode 7 110b = Test mode 6 101b = Test mode 5 100b
= Test mode 4 011b = Reserved 010b = Test mode 2 001b = Test
mode 1 000b = Normal (non-test) operation Note - 0x1 added in
[15:12] to differentiate
0h = Normal (non-test) operation
1h = Test mode 1
2h = Test mode 2
3h = Reserved
4h = Test mode 4
5h = Test mode 5
6h = Test mode 6
7h = Test mode 7
12-0
RESERVED
R
0h
Reserved
8.6.2.1.129 PCS_CONTROL_COPY Register (Offset = 3000h) [Reset = 0h]
PCS_CONTROL_COPY is shown in Table 8-152.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-152. PCS_CONTROL_COPY Register Field Descriptions
Bit
Field
Type
Reset
Description
15
pcs_reset_2
R
0h
1 = PCS reset 0 = Normal operation Note - RW bit, self clear bit Note
- 0x3 added in [15:12] to differentiate
0h = Normal operation
1h = PCS reset
14
mmd3_loopback_2
RESERVED
R
R
0h
0h
1 = Enable loopback mode 0 = Disable loopback mode Note - RW bit
Note - 0x3 added in [15:12] to differentiate
0h = Disable loopback mode
1h = Enable loopback mode
13-0
Reserved
8.6.2.1.130 PCS_CONTROL Register (Offset = 3900h) [Reset = 0h]
PCS_CONTROL is shown in Table 8-153.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-153. PCS_CONTROL Register Field Descriptions
Bit
Field
Type
Reset
Description
15
pcs_reset
R
0h
1 = PCS reset 0 = Normal operation Note - RW bit, self clear bit Note
- 0x3 added in [15:12] to differentiate
0h = Normal operation
1h = PCS reset
14
mmd3_loopback
RESERVED
R
R
0h
0h
1 = Enable loopback mode 0 = Disable loopback mode Note - RW bit
Note - 0x3 added in [15:12] to differentiate
0h = Disable loopback mode
1h = Enable loopback mode
13-0
Reserved
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8.6.2.1.131 PCS_STATUS Register (Offset = 3901h) [Reset = 0h]
PCS_STATUS is shown in Table 8-154.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-154. PCS_STATUS Register Field Descriptions
Bit
15-12
11
Field
Type
Reset
Description
RESERVED
tx_lpi_received_lh
R
0h
Reserved
R/W0C
0h
1 = Tx PCS has received LPI 0 = LPI not received Note - 0x3 added
in [15:12] to differentiate
0h = LPI not received
1h = Tx PCS has received LPI
10
9
rx_lpi_received_lh
tx_lpi_indication
rx_lpi_indication
pcs_fault
R/W0C
0h
0h
0h
0h
1 = Rx PCS has received LPI 0 = LPI not received Note - 0x3 added
in [15:12] to differentiate
0h = LPI not received
1h = Rx PCS has received LPI
R
R
R
R
1 = Tx PCS is currently receiving LPI 0 = PCS is not currently
receiving LPI Note - 0x3 added in [15:12] to differentiate
0h = PCS is not currently receiving LPI
1h = Tx PCS is currently receiving LPI
8
1 = Rx PCS is currently receiving LPI 0 = PCS is not currently
receiving LPI Note - 0x3 added in [15:12] to differentiate
0h = PCS is not currently receiving LPI
1h = Rx PCS is currently receiving LPI
7
1 = Fault condition detected 0 = No fault condition detected Note -
0x3 added in [15:12] to differentiate
0h = No fault condition detected
1h = Fault condition detected
6-3
2
RESERVED
0h
0h
Reserved
pcs_receive_link_status_ll R/W0S
1 = PCS receive link up 0 = PCS receive link down Note - 0x3 added
in [15:12] to differentiate
0h = PCS receive link down
1h = PCS receive link up
1-0
RESERVED
R
0h
Reserved
8.6.2.1.132 PCS_STATUS_2 Register (Offset = 3902h) [Reset = 0h]
PCS_STATUS_2 is shown in Table 8-155.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-155. PCS_STATUS_2 Register Field Descriptions
Bit
15-11
10
Field
Type
Reset
Description
RESERVED
R
0h
Reserved
pcs_receive_link_status
R
0h
1 = PCS receive link up 0 = PCS receive link down Note - 0x3 added
in [15:12] to differentiate
0h = PCS receive link down
1h = PCS receive link up
9
hi_rfer
R
0h
1 = PCS reporting a high BER 0 = PCS not reporting a high BER
Note - 0x3 added in [15:12] to differentiate
0h = PCS not reporting a high BER
1h = PCS reporting a high BER
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Table 8-155. PCS_STATUS_2 Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
8
block_lock
R
0h
1 = PCS locked to received blocks 0 = PCS not locked to received
blocks Note - 0x3 added in [15:12] to differentiate
0h = PCS not locked to received blocks
1h = PCS locked to received blocks
7
6
hi_rfer_lh
R/W0C
R/W0S
0h
0h
0h
1 = PCS has reported a high BER 0 = PCS has not reported a high
BER Note - 0x3 added in [15:12] to differentiate
0h = PCS has not reported a high BER
1h = PCS has reported a high BER
block_lock_ll
ber_count
1 = PCS has block lock 0 = PCS does not have block lock Note - 0x3
added in [15:12] to differentiate
0h = PCS does not have block lock
1h = PCS has block lock
5-0
BER counter Note - 0x3 added in [15:12] to differentiate
8.6.2.1.133 OAM_TRANSMIT Register (Offset = 3904h) [Reset = 0h]
OAM_TRANSMIT is shown in Table 8-156.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-156. OAM_TRANSMIT Register Field Descriptions
Bit
Field
Type
Reset
Description
15
mr_tx_valid
R/WMC,0
0h
This bit is used to indicate message data in registers 3.2308.11:8,
3.2309, 3.2310, 3.2311, and 3.2312 are valid and ready to be loaded.
This bit shall self-clear when registers are loaded by the state
machine. 1 = Message data in registers are valid 0 = Message data
in registers are not valid Note - 0x3 added in [15:12] to differentiate
0h = Message data in registers are not valid
1h = Message data in registers are valid
14
13
mr_tx_toggle
R
0h
0h
Toggle value to be transmitted with message. This bit is set by the
state machine and cannot be overridden by the user. Note - 0x3
added in [15:12] to differentiate
mr_tx_received
This bit shall self clear on read. 1 = 1000BASE-T1 OAM message
received by link partner 0 = 1000BASE-T1 OAM message not
received by link partner Note - 0x3 added in [15:12] to differentiate
0h = 1000BASE-T1 OAM message not received by link partner
1h = 1000BASE-T1 OAM message received by link partner
12
mr_tx_received_toggle
mr_tx_message_num
R
0h
0h
Toggle value of message that was received by link partner Note - 0x3
added in [15:12] to differentiate
11-8
R/W
User-defined message number to send Note - 0x3 added in [15:12]
to differentiate
7-4
3
RESERVED
mr_rx_ping
R
R
0h
0h
Reserved
Received PingTx value from latest good 1000BASE-T1 OAM frame
received Note - 0x3 added in [15:12] to differentiate
2
mr_tx_ping
R/W
0h
Ping value to send to link partner Note - 0x3 added in [15:12] to
differentiate
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Table 8-156. OAM_TRANSMIT Register Field Descriptions (continued)
Bit
Field
Type
Reset
Description
1-0
mr_tx_snr
R
0h
00 = PHY link is failing and will drop link and relink within 2 ms to 4
ms after the end of the current 1000BASE-T1 OAM frame. 01 = LPI
refresh is insufficient to maintain PHY SNR. Request link partner to
exit LPI and send idles (used only when EEE is enabled). 10 = PHY
SNR is marginal. 11 = PHY SNR is good. Note - 0x3 added in [15:12]
to differentiate
0h = PHY link is failing and will drop link and relink within 2 ms to 4
ms after the end of the current 1000BASE-T1 OAM frame.
1h = LPI refresh is insufficient to maintain PHY SNR. Request link
partner to exit LPI and send idles (used only when EEE is enabled).
2h = PHY SNR is marginal.
3h = PHY SNR is good.
8.6.2.1.134 OAM_TX_MESSAGE_1 Register (Offset = 3905h) [Reset = 0h]
OAM_TX_MESSAGE_1 is shown in Table 8-157.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-157. OAM_TX_MESSAGE_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_tx_message_15_0
R/W
0h
Message octet 1/0. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.135 OAM_TX_MESSAGE_2 Register (Offset = 3906h) [Reset = 0h]
OAM_TX_MESSAGE_2 is shown in Table 8-158.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-158. OAM_TX_MESSAGE_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_tx_message_31_16
R/W
0h
Message octet 3/2. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.136 OAM_TX_MESSAGE_3 Register (Offset = 3907h) [Reset = 0h]
OAM_TX_MESSAGE_3 is shown in Table 8-159.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-159. OAM_TX_MESSAGE_3 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_tx_message_47_32
R/W
0h
Message octet 5/4. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
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8.6.2.1.137 OAM_TX_MESSAGE_4 Register (Offset = 3908h) [Reset = 0h]
OAM_TX_MESSAGE_4 is shown in Table 8-160.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-160. OAM_TX_MESSAGE_4 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_tx_message_63_48
R/W
0h
Message octet 7/6. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.138 OAM_RECEIVE Register (Offset = 3909h) [Reset = 0h]
OAM_RECEIVE is shown in Table 8-161.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-161. OAM_RECEIVE Register Field Descriptions
Bit
Field
Type
Reset
Description
15
mr_rx_lp_valid
R
0h
This bit is used to indicate message data in registers 3.2313.11:8,
3.2314, 3.2315, 3.2316, and 3.2317 are stored and ready to be read.
This bit shall self clear when register 3.2317 is read. 1 = Message
data in registers are valid 0 = Message data in registers are not valid
Note - 0x3 added in [15:12] to differentiate
0h = Message data in registers are not valid
1h = Message data in registers are valid
14
mr_rx_lp_toggle
R
0h
Toggle value received with message Note - 0x3 added in [15:12] to
differentiate
13-12
11-8
RESERVED
R
R
0h
0h
Reserved
mr_rx_lp_message_num
Message number from link partner Note - 0x3 added in [15:12] to
differentiate
7-2
1-0
RESERVED
R
R
0h
0h
Reserved
mr_rx_lp_SNR
00 = Link partner link is failing and will drop link and relink within 2
ms to 4 ms after the end of the current 1000BASE-T1 OAM frame.
01 = LPI refresh is insufficient to maintain link partner SNR. Link
partner requests local device to exit LPI and send idles (used only
when EEE is enabled). 10 = Link partner SNR is marginal. 11 = Link
partner SNR is good Note - 0x3 added in [15:12] to differentiate
0h = Link partner link is failing and will drop link and relink within 2
ms to 4 ms after the end of the current 1000BASE-T1 OAM frame.
1h = LPI refresh is insufficient to maintain link partner SNR. Link
partner requests local device to exit LPI and send idles (used only
when EEE is enabled).
2h = Link partner SNR is marginal.
3h = Link partner SNR is good
8.6.2.1.139 OAM_RX_MESSAGE_1 Register (Offset = 390Ah) [Reset = 0h]
OAM_RX_MESSAGE_1 is shown in Table 8-162.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
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Table 8-162. OAM_RX_MESSAGE_1 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_rx_lp_message_15_0
R
0h
Message octet 1/0. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.140 OAM_RX_MESSAGE_2 Register (Offset = 390Bh) [Reset = 0h]
OAM_RX_MESSAGE_2 is shown in Table 8-163.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-163. OAM_RX_MESSAGE_2 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_rx_lp_message_31_16 R
0h
Message octet 3/2. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.141 OAM_RX_MESSAGE_3 Register (Offset = 390Ch) [Reset = 0h]
OAM_RX_MESSAGE_3 is shown in Table 8-164.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-164. OAM_RX_MESSAGE_3 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_rx_lp_message_47_32 R
0h
Message octet 5/4. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.142 OAM_RX_MESSAGE_4 Register (Offset = 390Dh) [Reset = 0h]
OAM_RX_MESSAGE_4 is shown in Table 8-165.
Return to the Summary Table.
First nibble (0x3) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
Table 8-165. OAM_RX_MESSAGE_4 Register Field Descriptions
Bit
Field
Type
Reset
Description
15-0
mr_rx_lp_message_63_48
0h
Message octet 7/6. LSB transmitted first. Note - 0x3 added in [15:12]
to differentiate
8.6.2.1.143 AN_CFG Register (Offset = 7200h) [Reset = 0h]
AN_CFG is shown in Table 8-166.
Return to the Summary Table.
First nibble (0x7) in the register address is to indicated MMD register space. For register access, ignore the first
nibble.
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Table 8-166. AN_CFG Register Field Descriptions
Bit
15-1
0
Field
Type
Reset
Description
RESERVED
mr_main_reset
R
0h
Reserved
R/WSC
0h
1 = Reset link sync/autoneg Note - RW bit Note - Added 7 to [15:12]
to differentiate
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9 Application and Implementation
Note
Information in the following applications sections is not part of the TI component specification,
and TI does not warrant its accuracy or completeness. TI’s customers are responsible for
determining suitability of components for their purposes, as well as validating and testing their design
implementation to confirm system functionality.
9.1 Application Information
The DP83TG720R-Q1 is a single-port 1-Gbps Automotive Ethernet PHY. It supports IEEE 802.3bp and allows
for connections to an Ethernet MAC through RGMII. When using the device for Ethernet applications, it is
necessary to meet certain requirements for normal operation. The following subsections are intended to assist in
appropriate component selection and required connections.
9.2 Typical Applications
DC
Blocking
TX_CLK
CMC
4
4
TRD_P
TRD_M
TX_D[3:0]
TX_CTRL
Automotive
Connector
ESD
RX_CLK
(optional)
CM
Termination
RX_D[3:0]
RX_CTRL
VDDIO
Media Access Controller
DP83TG720R-Q1
MDIO
MDC
MDI
Coupling
ESD
Shunt
WAKE
INT
GND
Figure 9-1. Typical Application (RGMII)
Table 9-1. Recommended Components for MDI Network
Design Parameter
Value
DC Blocking Capacitors 1
Common-Mode Choke
0.1 μF
Murata :DLW32MH101XT2
Common Mode Termination Resistors 1
MDI Coupling Capacitor
ESD Shunt
1 kΩ
4.7 nF
100 kΩ
1. 1% tolerance components are recommended for margins over spec of return loss and mode conversion.
9.2.1 Design Requirements
For these typical applications, use the following as input parameters:
Table 9-2. Design Parameters
DESIGN PARAMETER
VDDIO
EXAMPLE VALUE
1.8 V, 2.5 V, or 3.3 V
10 nF, 100 nF
De-Coupling Capacitors VDDIO (pin 34)
De-Coupling Capacitors VDDIO (pin 22)
Combined Ferrite Bead for VDDIO
10 nF, 100 nF, 2.2uF
BLM18HE102SN1
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Table 9-2. Design Parameters (continued)
DESIGN PARAMETER
EXAMPLE VALUE
VDDA
3.3 V
De-Coupling Capacitors VDDA (pin 11)
Ferrite Bead for VDDA
10 nF, 100 nF, 2.2uF
BLM18KG601SH1
1 V
VDD1p0
De-Coupling Capacitors VDD1P0 (pin 9)
De-Coupling Capacitors VDDA (pin 21)
Combined Ferrite Bead for VDD1P0
Vsleep
10 nF, 100 nF, 2.2uF
10 nF, 100 nF, 2.2uF
BLM18KG601SH1
3.3 V
DC Blocking Capacitors (1)
0.1 μF
Common-Mode Choke
Murata :DLW32MH101XT2
Common Mode Termination Resistors(1)
MDI Coupling Capacitor
ESD Shunt
1 kΩ
4.7 nF
100 kΩ
25-MHz
Reference Clock
(1) 1% tolerance components are recommended to improve return loss and mode conversion
measurements.
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10 Power Supply Recommendations
The DP83TG720R-Q1 is capable of operating with a wide range of IO supply voltages (3.3 V, 2.5 V, or 1.8
V). No power supply sequencing is required. The recommended power supply de-coupling network is shown in
following figure :
Board-supply :
min decap
Pins
Phy[s Supply BOM
=
34
10nF
10nF
100nF
100nF
Ferrite
vddio
>=1uF
22
>= 2.2uF
21
9
10nF
10nF
100nF
100nF
>= 2.2uF
>= 2.2uF
Ferrite
vdd1p0
>=1uF
Ferrite
vdda3p3
11
10nF
100nF
>= 2.2uF
>=1uF
vsleep
7
>=1uF
Figure 10-1. Recommended Supply De-Coupling Network (if sleep mode is used in the application)
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Board-supply :
min decap
Pins
Phy[s Supply BOM
=
34
10nF
10nF
100nF
100nF
Ferrite
vddio
>=1uF
22
>= 2.2uF
21
9
10nF
10nF
100nF
100nF
>= 2.2uF
>= 2.2uF
Ferrite
vdd1p0
>=1uF
Ferrite
vdda3p3
11
10nF
100nF
>= 2.2uF
>=1uF
7
Figure 10-2. Recommended Supply De-Coupling Network (if sleep mode is not used in application)
Table 10-1. Recommended Components for Power Network
Design Parameter
Value
VDDIO
1.8 V, 2.5 V, or 3.3 V
10 nF, 100 nF
De-Coupling Capacitors VDDIO (pin 34)
De-Coupling Capacitors VDDIO (pin 22)
Combined Ferrite Bead for VDDIO
10 nF, 100 nF, 2.2uF
BLM18HE102SN1
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Table 10-1. Recommended Components for Power Network (continued)
Design Parameter
Value
VDDA
3.3 V
De-Coupling Capacitors VDDA (pin 11)
Ferrite Bead for VDDA
VDD1p0
10 nF, 100 nF, 2.2uF
BLM18KG601SH1
1 V
De-Coupling Capacitors VDD1P0 (pin 9)
De-Coupling Capacitors VDDA (pin 21)
Combined Ferrite Bead for VDD1P0
Vsleep
10 nF, 100 nF, 2.2uF
10 nF, 100 nF, 2.2uF
BLM18KG601SH1
3.3 V
Note
For recommendation on LDOs for VDD1p0 and Vsleep, please refer to the DP83TC811, DP83TG730
Rollover Document application report.
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11 Compatibility with TI's 100BT1 PHY
Following table shows pin comparison between DP83TC811 and DP83TG720. Pins highlighted in bold need
attention while designing a common board for both 100BT1 and 1000BT1 PHY. 100BT1 and 1000BT1 PHY's
different BOM requirements can also be taken care by a common board.
Details and recommendation for common board design can be found in DP83TC811, DP83TG720 Rollover
Document application report.
Table 11-1. Pin Comparison Table
Pin No.
1
DP83TC811
DP83TG720
MDC
MDC
2
INT_N
RESET_N
XO
INT_N
RESET_N
XO
3
4
5
XI
XI
6
LED_1
EN
LED_1
VSLEEP
WAKE
VDD1P0
INH
7
8
WAKE
DNC
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
INH
VDDA
TRD_P
TRD_M
RX_ER
RX_DV
CLKOUT
TCK
VDDA
TRD_P
TRD_M
STRP1
RX_CTRL
CLKOUT
DNC
TDO
DNC
TMS
DNC
TCK
DNC
DNC
VDD1P0
VDDIO
RX_D3
RX_D2
RX_D1
RX_D0
RX_CLK
TXCLK
TX_CTRL
TX_D3
TX_D2
TX_D1
TX_D0
VDDIO
LED_0
MDIO
VDDIO
RX_D3
RX_D2
RX_D1
RX_D0
RX_CLK
TXCLK
TX_EN
TX_D3
TX_D2
TX_D1
TX_D0
TX_ER
LED_0
MDIO
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12 Layout
12.1 Layout Guidelines
12.1.1 Signal Traces
PCB traces are lossy and long traces can degrade signal quality. Traces should be kept short as possible.
Unless mentioned otherwise, all signal traces should be 50-Ω, single-ended impedance. Differential traces
should be 50-Ω single-ended and 100-Ω differential. Take care to ensure impedance is controlled throughout.
Impedance discontinuities will cause reflections leading to emissions and signal integrity issues. Stubs should be
avoided on all signal traces, especially differential signal pairs.
Figure 12-1. Differential Signal Trace Routing
Within the differential pairs, trace lengths should be run parallel to each other and matched in length. Matched
lengths minimize delay differences, avoiding an increase in common mode noise and emissions. Length
matching is also important for MAC interface connections. All transmit signal traces should be length matched to
each other and all receive signal traces should be length matched to each other.
Ideally, there should be no crossover or vias on signal path traces. Vias present impedance discontinuities and
should be minimized when possible. Route trace pairs on the same layer. Signals on different layers should not
cross each other without at least one return path plane between them. Differential pairs should always have
a constant coupling distance between them. For convenience and efficiency, TI recommends routing critical
signals first (that is, MDI differential pairs, reference clock, and MAC IF traces).
12.1.2 Return Path
A general best practice is to have a solid return path beneath all signal traces. This return path can be
a continuous ground or DC power plane. Reducing the width of the return path can potentially affect the
impedance of the signal trace. This effect is more prominent when the width of the return path is comparable to
the width of the signal trace. Breaks in return path between the signal traces should be avoided at all cost. A
signal crossing a split plane may cause unpredictable return path currents and could impact signal quality and
result in emissions issues.
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Figure 12-2. Power and Ground Plane Breaks
12.1.3 Physical Medium Attachment
There must be no metal running beneath the common-mode choke. CMCs can inject noise into metal beneath
them, which can affect the emissions and immunity performance of the system. Because the DP83TG720R-Q1
is a voltage mode line driver, no external termination resistors are required. The ESD shunt and MDI coupling
capacitor should be connected to ground. Ensure that the common mode termination resistors are 1% tolerance
or better to improve differential coupling.
12.1.4 Metal Pour
All metal pours that are not signals or power must be tied to ground. There must be no floating metal in the
system, and there must be no metal between differential traces.
12.1.5 PCB Layer Stacking
To meet signal integrity and performance requirements, minimum four-layer PCB is recommended. However, a
six-layer PCB and above should be used when possible.
Figure 12-3. Recommended PCB Layer Stack-Up
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13 Device and Documentation Support
13.1 Receiving Notification of Documentation Updates
To receive notification of documentation updates, navigate to the device product folder on ti.com. Click on
Subscribe to updates to register and receive a weekly digest of any product information that has changed. For
change details, review the revision history included in any revised document.
13.2 Support Resources
TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight
from the experts. Search existing answers or ask your own question to get the quick design help you need.
Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do
not necessarily reflect TI's views; see TI's Terms of Use.
13.3 Trademarks
TI E2E™ is a trademark of Texas Instruments.
All trademarks are the property of their respective owners.
13.4 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled
with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric changes could cause the device not to meet its published
specifications.
13.5 Glossary
TI Glossary
This glossary lists and explains terms, acronyms, and definitions.
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14 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left navigation.
14.1 Package Option Addendum
14.1.1 Packaging Information
Packag
Status Packag
Packag Eco Plan
e Qty
Lead/Ball
Finish(4)
MSL Peak
Temp (3)
Op Temp
(°C)
Orderable Device
e
Pins
Device Marking(5) (6)
(1)
(2)
e Type
Drawing
EARLY
SAMPL VQFN
E
PDP83TG720SWCST
Q1
RHA
36
250
RoHS
NiPdAu
MSL3-260C
-40 to 125
DP83TG720RWRHAT ACTIV
Q1
VQFN
VQFN
RHA
RHA
36
36
250
RoHS
RoHS
NiPdAu
NiPdAu
MSL3-260C
MSL3-260C
-40 to 125
-40 to 125
720R
720R
E
DP83TG720RWRHAR ACTIV
Q1
2500
E
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using
this part in a new design.
PRE_PROD Unannounced device, not in production, not available for mass market, nor on the web, samples not available.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
space
(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please
check http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS
requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where
designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the
die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free
(RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb)
based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
space
(3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
space
(4) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line.
Lead/Ball Finish values may wrap to two lines if the finish value exceeds the maximum column width.
space
(5) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device
space
(6) Multiple Device markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will
appear on a device. If a line is indented then it is a continuation of the previous line and the two combined represent the entire Device
Marking for that device.
Important Information and Disclaimer: The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI
bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information.
Efforts are underway to better integrate information from third parties. TI has taken and continues to take reasonable steps to provide representative
and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. TI and TI suppliers
consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
Copyright © 2021 Texas Instruments Incorporated
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DP83TG720R-Q1
SNLS603B – DECEMBER 2020 – REVISED MARCH 2021
www.ti.com
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to
Customer on an annual basis.
14.1.2 Tape and Reel Information
REEL DIMENSIONS
TAPE DIMENSIONS
K0
P1
W
B0
Reel
Diameter
Cavity
A0
A0 Dimension designed to accommodate the component width
B0 Dimension designed to accommodate the component length
K0 Dimension designed to accommodate the component thickness
Overall width of the carrier tape
P1 Pitch between successive cavity centers
W
Reel Width (W1)
QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE
Sprocket Holes
Q1 Q2
Q3 Q4
Q1 Q2
Q3 Q4
User Direction of Feed
Pocket Quadrants
Reel
Diameter
(mm)
Reel
Width W1
(mm)
Package
Type
Package
Drawing
A0
(mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
(mm)
Pin1
Quadrant
Device
Pins
SPQ
PDP83TG720SWCSTQ
1
VQFN
VQFN
VQFN
RHA
36
36
36
250
250
Call TI
180
Call TI
16.4
Call TI
6.3
Call TI
6.3
Call TI
1.1
Call TI
12
Call TI
16
Call TI
Q2
DP83TG720RWRHATQ
1
RHA
DP83TG720RWRHAR
Q1
RHA
2500
330
16.4
6.3
6.3
1.1
12
16
Q2
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TAPE AND REEL BOX DIMENSIONS
Width (mm)
H
W
L
Device
Package Type
Package Drawing Pins
SPQ
250
Length (mm) Width (mm)
Height (mm)
DP83TG720RWRHATQ1
DP83TG720RWRHARQ1
VQFN
VQFN
RHA
RHA
36
36
210
367
185
367
35
35
2500
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PACKAGE OUTLINE
RHA0036A
VQFN - 1 mm max height
S
C
A
L
E
2
.
0
0
0
PLASTIC QUAD FLATPACK - NO LEAD
6.1
5.9
B
A
PIN 1 INDEX AREA
6.1
5.9
0.1 MIN
(0.13)
A
-
A
4
0
.
0
0
0
SECTION A-A
TYPICAL
1.0
0.8
C
SEATING PLANE
0.08 C
0.05
0.00
2X
4
SYMM
(0.2) TYP
EXPOSED
THERMAL PAD
18
10
9
19
(0.16)
TYP
A
A
SYMM
37
2X
4
3.7 0.1
32X 0.5
PIN 1 ID
1
27
0.31
0.19
36X
36
28
0.5
0.1
C A B
36X
0.3
0.05
4225089/A 06/2019
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. The package thermal pad must be soldered to the printed circuit board for thermal and mechanical performance.
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EXAMPLE BOARD LAYOUT
RHA0036A
VQFN - 1 mm max height
PLASTIC QUAD FLATPACK - NO LEAD
(
3.7)
SYMM
SEE SOLDER MASK
DETAIL
36
28
36X (0.6)
27
36X (0.25)
1
(1.6)
TYP
32X (0.5)
(0.625)
TYP
37
SYMM
(R0.05) TYP
(5.8)
(
0.2) TYP
VIA
19
9
10
18
(0.625) TYP
(1.6) TYP
(5.8)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE: 15X
0.07 MIN
ALL AROUND
0.07 MAX
ALL AROUND
METAL UNDER
SOLDER MASK
METAL EDGE
EXPOSED METAL
SOLDER MASK
OPENING
EXPOSED
METAL
SOLDER MASK
OPENING
NON SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK DEFINED
SOLDER MASK DETAILS
4225089/A 06/2019
NOTES: (continued)
4. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
number SLUA271 (www.ti.com/lit/slua271).
5. Vias are optional depending on application, refer to device data sheet. If any vias are implemented, refer to their locations shown
on this view. It is recommended that vias under paste be filled, plugged or tented.
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EXAMPLE STENCIL DESIGN
RHA0036A
VQFN - 1 mm max height
PLASTIC QUAD FLATPACK - NO LEAD
(1.25)
TYP
36
28
36X (0.6)
27
36X (0.25)
1
32X (0.5)
(1.25) TYP
(5.8)
SYMM
37
(R0.05) TYP
9
19
9X ( 1.05)
10
18
SYMM
(5.8)
SOLDER PASTE EXAMPLE
BASED ON 0.125 MM THICK STENCIL
SCALE: 15X
EXPOSED PAD 37
72% PRINTED SOLDER COVERAGE BY AREA UNDER PACKAGE
4225089/A 06/2019
NOTES: (continued)
6. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
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PACKAGE OPTION ADDENDUM
www.ti.com
2-Apr-2021
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
DP83TG720RWRHARQ1
DP83TG720RWRHATQ1
ACTIVE
ACTIVE
VQFN
VQFN
RHA
RHA
36
36
2500 RoHS & Green
250 RoHS & Green
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
720R
720R
NIPDAU
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
2-Apr-2021
Addendum-Page 2
IMPORTANT NOTICE AND DISCLAIMER
TI PROVIDES TECHNICAL AND RELIABILITY DATA (INCLUDING DATASHEETS), DESIGN RESOURCES (INCLUDING REFERENCE
DESIGNS), APPLICATION OR OTHER DESIGN ADVICE, WEB TOOLS, SAFETY INFORMATION, AND OTHER RESOURCES “AS IS”
AND WITH ALL FAULTS, AND DISCLAIMS ALL WARRANTIES, EXPRESS AND IMPLIED, INCLUDING WITHOUT LIMITATION ANY
IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF THIRD
PARTY INTELLECTUAL PROPERTY RIGHTS.
These resources are intended for skilled developers designing with TI products. You are solely responsible for (1) selecting the appropriate
TI products for your application, (2) designing, validating and testing your application, and (3) ensuring your application meets applicable
standards, and any other safety, security, or other requirements. These resources are subject to change without notice. TI grants you
permission to use these resources only for development of an application that uses the TI products described in the resource. Other
reproduction and display of these resources is prohibited. No license is granted to any other TI intellectual property right or to any third party
intellectual property right. TI disclaims responsibility for, and you will fully indemnify TI and its representatives against, any claims, damages,
costs, losses, and liabilities arising out of your use of these resources.
TI’s products are provided subject to TI’s Terms of Sale (https:www.ti.com/legal/termsofsale.html) or other applicable terms available either
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applicable warranties or warranty disclaimers for TI products.IMPORTANT NOTICE
Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright © 2021, Texas Instruments Incorporated
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