82V2058DA [IDT]
PCM Transceiver, 1-Func, PQFP144, TQFP-144;型号: | 82V2058DA |
厂家: | INTEGRATED DEVICE TECHNOLOGY |
描述: | PCM Transceiver, 1-Func, PQFP144, TQFP-144 PC 电信 电信集成电路 |
文件: | 总53页 (文件大小:1175K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
OCTAL E1 SHORT HAUL
LINE INTERFACE UNIT
IDT82V2058
FEATURES
Low impedance transmit drivers with high-Z
Fully integrated octal E1 short haul line interface which
supports 120 Ω E1 twisted pair and 75 Ω E1 coaxial
applications
Selectable hardware and parallel/serial host interface
Local and Remote Loopback test functions
Selectable Single Rail mode or Dual Rail mode and AMI or
HDB3 encoder/decoder
Hitless Protection Switching (HPS) for 1 to 1 protection without
relays
Built-in transmit pre-equalization meets G.703
JTAG boundary scan for board test
3.3 V supply with 5 V tolerant I/O
Low power consumption
Selectable transmit/receive jitter attenuator meets ETSI CTR12/
13, ITU G.736, G.742 and G.823 specifications
SONET/SDH optimized jitter attenuator meets ITU G.783
mapping jitter specification
Operating temperature range: -40°C to +85°C
Available in 144-pin Thin Quad Flat Pack (TQFP) and 160-pin
Plastic Ball Grid Array (PBGA) packages
Green package options available
Digital/Analog LOS detector meets ITU G.775 and ETS 300 233
ITU G.772 non-intrusive monitoring for in-service testing for
any one of channel 1 to channel 7
FUNCTIONAL BLOCK DIAGRAM
One of Eight Identical Channels
LOS
LOSn
Detector
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
Slicer
RRINGn
AIS
Detector
Analog
Loopback
Peak
Detector
Digital
Loopback
Remote
Loopback
TTIPn
TCLKn
TDn/TDPn
BPVIn/TDNn
HDB3/AMI
Encoder
Line
Driver
Waveform
Shaper
Jitter
Attenuator
TRINGn
Transmit
All Ones
VDD IO
VDDT
VDDD
VDDA
Register
File
G.772
Monitor
Clock
Generator
Control Interface
JTAG TAP
Figure-1 Block Diagram
January 21, 2010
IDT and the IDT logo are trademarks of Integrated Device Technology, Inc.
1
DSC-6038/12
2010- Integrated Device Technology, Inc.
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
DESCRIPTION
The IDT82V2058 is a single chip, 8-channel E1 short haul PCM
transceiver with a reference clock of 2.048 MHz. The IDT82V2058
contains 8 transmitters and 8 receivers.
The IDT82V2058 offers hardware control mode and software control
mode. Software control mode works with either serial host interface or
parallel host interface. The latter works via an Intel/Motorola compatible
8-bit parallel interface for both multiplexed or non-multiplexed applica-
tions. Hardware control mode uses multiplexed pins to select different
operation modes when the host interface is not available to the device.
All the receivers and transmitters can be programmed to work either
in Single Rail mode or Dual Rail mode. HDB3 or AMI encoder/decoder is
selectable in Single Rail mode. Pre-encoded transmit data in NRZ
format can be accepted when the device is configured in Dual Rail
mode. The receivers perform clock and data recovery by using inte-
grated digital phase-locked loop. As an option, the raw sliced data (no
retiming) can be output on the receive data pins. Transmit equalization is
implemented with low-impedance output drivers that provide shaped
waveforms to the transformer, guaranteeing template conformance.
The IDT82V2058 also provides loopback and JTAG boundary scan
testing functions. Using the integrated monitoring function, the
IDT82V2058 can be configured as a 7-channel transceiver with non-
intrusive protected monitoring points.
The IDT82V2058 can be used for SDH/SONET multiplexers, central
office or PBX, digital access cross connects, digital radio base stations,
remote wireless modules and microwave transmission systems.
A jitter attenuator is integrated in the IDT82V2058 and can be
switched into either the transmit path or the receive path for all channels.
The jitter attenuation performance meets ETSI CTR12/13, ITU G.736,
G.742 and G.823 specifications.
PIN CONFIGURATIONS
BPVI3/TDN3
RCLK3
RD3/RDP3
CV3/RDN3
LOS3
RTIP3
RRING3
VDDT3
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
BPVI4/TDN4
RCLK4
RD4/RDP4
CV4/RDN4
LOS4
OE
CLKE
VDDT4
TTIP4
TRING4
GNDT4
RTIP4
RRING4
GNDT5
TRING5
TTIP5
VDDT5
RRING5
RTIP5
VDDT6
TTIP6
TRING6
GNDT6
RTIP6
RRING6
GNDT7
TRING7
TTIP7
VDDT7
RRING7
RTIP7
TTIP3
TRING3
GNDT3
RRING2
RTIP2
GNDT2
TRING2
TTIP2
VDDT2
RTIP1
RRING1
VDDT1
TTIP1
TRING1
GNDT1
RRING0
RTIP0
GNDT0
TRING0
TTIP0
VDDT0
MODE1
LOS0
CV0/RDN0
RD0/RDP0
RCLK0
BPVI0/TDN0
TD0/TDP0
IDT82V2058
(Top View)
LOS7
CV7/RDN7
RD7/RDP7
RCLK7
BPVI7/TDN7
Figure-2 TQFP144 Package Pin Assignment
2
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
A
B
C
D
E
F
G
H
J
K
L
M
N
P
RCLK TCLK RCLK TCLK
MC
1
LP
6
LP
7
TCLK RCLK TCLK RCLK
1
2
1
2
MCLK
VDDIO VDDD
7
7
6
6
1
1
0
0
RDP
7
TDP
7
RDP
6
TDP MODE MC
6
LP
0
LP
2
LP
5
MODE TDP
1
RDP
1
TDP
0
RDP
0
2
2
1
RDN
7
TDN
7
RDN
6
TDN
6
LOS
6
MC
3
MC
0
LP
1
LP
4
LOS
1
TDN
1
RDN
1
TDN
0
RDN
0
3
3
VDDT VDDT VDDT VDDT LOS
LP
3
LOS VDDT VDDT VDDT VDDT
4
A4 GNDIO GNDD
4
7
7
6
6
7
0
1
1
0
0
TRING TTIP TRING TTIP
TTIP TRING TTIP TRING
5
5
7
7
6
6
1
1
0
0
GNDT GNDT GNDT GNDT
GNDT GNDT GNDT GNDT
6
6
7
7
6
6
1
1
0
0
RTIP RRING RTIP RRING
RRING RTIP RRING RTIP
7
7
7
7
6
6
1
1
0
0
IDT82V2058
(Bottom View)
RTIP RRING RTIP RRING
RRING RTIP RRING RTIP
8
8
4
4
5
5
2
2
3
3
GNDT GNDT GNDT GNDT
GNDT GNDT GNDT GNDT
9
9
4
4
5
5
2
2
3
3
TRING TTIP TRING TTIP
TTIP TRING TTIP TRING
10
11
12
13
14
10
11
12
13
14
4
4
5
5
2
2
3
3
VDDT VDDT VDDT VDDT LOS
LOS VDDT VDDT VDDT VDDT
TMS GNDIO GNDA
MODE
CS
4
4
5
5
4
3
2
2
3
3
RDN
4
TDN
4
RDN
5
TDN
5
LOS
5
LOS
2
TDN
2
RDN
2
TDN
3
RDN
3
TDI
TRST
SCLK
0
RDP
4
TDP
4
RDP
5
TDP
5
TDP
2
RDP
2
TDP
3
RDP
3
CLKE TDO
IC
IC
RD
INT
RCLK TCLK RCLK TCLK
TCLK RCLK TCLK RCLK
OE
E
TCK VDDIO VDDA SDI
SDO
4
4
5
5
2
2
3
3
A
B
C
D
F
G
H
J
K
L
M
N
P
Figure-3 PBGA160 Package Pin Assignment
3
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
1
PIN DESCRIPTION
Table-1 Pin Description
Pin No.
Name
Type
Description
TQFP144 PBGA160
Transmit and Receive Line Interface
TTIP0
TTIP1
TTIP2
TTIP3
TTIP4
TTIP5
TTIP6
TTIP7
45
52
57
N5
L5
L10
N10
B10
D10
D5
64
117
124
129
136
TTIPn/TRINGn: Transmit Bipolar Tip/Ring for Channel 0~7
B5
Analog
Output
These pins are the differential line driver outputs. They will be in high-Z if pin OE is low or the correspond-
ing pin TCLKn is low (pin OE is global control, while pin TCLKn is per-channel control). In host mode, each
TRING0
TRING1
TRING2
TRING3
TRING4
TRING5
TRING6
TRING7
46
51
58
P5
M5
pin can be in high-Z by programming a ‘1’ to the corresponding bit in register OE(1)
.
M10
P10
A10
C10
C5
63
118
123
130
135
A5
RTIP0
RTIP1
RTIP2
RTIP3
RTIP4
RTIP5
RTIP6
RTIP7
48
55
60
P7
M7
M8
P8
A8
C8
C7
A7
67
120
127
132
139
Analog
Input
RTIPn/RRINGn: Receive Bipolar Tip/Ring for Channel 0~7
These pins are the differential line receiver inputs.
RRING0
RRING1
RRING2
RRING3
RRING4
RRING5
RRING6
RRING7
49
54
61
N7
L7
L8
N8
B8
D8
D7
B7
66
121
126
133
138
1. Register name is indicated by bold capital letter. For example, OE indicates Output Enable Register.
4
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
Transmit and Receive Digital Data Interface
TDn: Transmit Data for Channel 0~7
When the device is in Single Rail mode, the NRZ data to be transmitted is input on this pin. Data on TDn is
sampled into the device on the falling edges of TCLKn, and encoded by AMI or HDB3 line code rules
before being transmitted to the line.
TD0/TDP0
TD1/TDP1
TD2/TDP2
TD3/TDP3
TD4/TDP4
TD5/TDP5
TD6/TDP6
TD7/TDP7
37
30
80
73
108
101
8
N2
L2
L13
N13
B13
D13
D2
BPVIn: Bipolar Violation Insertion for Channel 0~7
Bipolar violation insertion is available in Single Rail mode 2 (see Table-2 on page 13 and Table-3 on page
14) with AMI enabled. A low-to-high transition on this pin will make the next logic one to be transmitted on
TDn the same polarity as the previous pulse, and violate the AMI rule. This is for testing.
1
B2
TDPn/TDNn: Positive/Negative Transmit Data for Channel 0~7
I
When the device is in Dual Rail Mode, the NRZ data to be transmitted for positive/negative pulse is input
on this pin. Data on TDPn/TDNn are sampled on the falling edges of TCLKn. The line code in dual rail
mode is as the follow:
BPVI0/TDN0
BPVI1/TDN1
BPVI2/TDN2
BPVI3/TDN3
BPVI4/TDN4
BPVI5/TDN5
BPVI6/TDN6
BPVI7/TDN7
38
31
79
N3
L3
L12
N12
B12
D12
D3
TDPn
TDNn
Output Pulse
Space
Negative Pulse
Positive Pulse
Space
72
0
0
1
1
0
1
0
1
109
102
7
144
B3
Pulling pin TDNn high for more than 16 consecutive TCLK clock cycles will configure the corresponding
channel into Single Rail mode 1 (see Table-2 on page 13 and Table-3 on page 14).
TCLKn: Transmit Clock for Channel 0~7
The clock of 2.048 MHz for transmit is input on this pin. The transmit data at TDn/TDPn or TDNn is sam-
pled into the device on the falling edges of TCLKn.
Pulling TCLKn high for more than 16 MCLK cycles, the corresponding transmitter is set in Transmit All
Ones (TAOS) state (when MCLK is clocked). In TAOS state, the TAOS generator adopts MCLK as the
clock reference.
If TCLKn is low, the corresponding transmit channel is set into power down state, while driver output ports
become high-Z.
Different combinations of TCLKn and MCLK result in different transmit mode. It is summarized as the fol-
lows:
TCLK0
TCLK1
TCLK2
TCLK3
TCLK4
TCLK5
TCLK6
TCLK7
36
29
81
74
107
100
9
N1
L1
MCLK
TCLKn
Transmit Mode
L14
N14
B14
D14
D1
Clocked
Clocked
Normal operation
Transmit All Ones (TAOS) signals to the line side in the corresponding
transmit channel.
I
Clocked High (≥ 16 MCLK)
Clocked Low (≥ 64 MCLK) The corresponding transmit channel is set into power down state.
Normal operation
TCLKn is clocked
TCLKn is high
(≥ 16 TCLK1)
TCLKn is low
(≥ 64 TCLK1)
2
B1
Transmit All Ones (TAOS) signals to the line side
in the corresponding transmit channel.
Corresponding transmit channel is set into power
down state.
High/Low TCLK1 is clocked
The receive path is not affected by the status of TCLK1. When MCLK
is high, all receive paths just slice the incoming data stream. When
MCLK is low, all the receive paths are powered down.
TCLK1 is unavail-
High/Low
able.
All eight transmitters (TTIPn & TRINGn) will be in high-Z.
5
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
RDn: Receive Data for Channel 0~7
In Single Rail mode, the received NRZ data is output on this pin. The data is decoded by AMI or HDB3 line
code rule.
RD0/RDP0
RD1/RDP1
RD2/RDP2
RD3/RDP3
RD4/RDP4
RD5/RDP5
RD6/RDP6
RD7/RDP7
40
33
77
P2
M2
M13
P13
A13
C13
C2
CVn: Code Violation for Channel 0~7
In Single Rail mode, the bipolar violation, code violation and excessive zeros will be reported by driving pin
CVn high for a full clock cycle. However, only bipolar violation is indicated when AMI decoder is selected.
70
111
104
5
RDPn/RDNn: Positive/Negative Receive Data for Channel 0~7
O
142
A2
In Dual Rail Mode with clock recovery, these pins output the NRZ data. A high signal on RDPn indicates
the receipt of a positive pulse on RTIPn/RRINGn while a high signal on RDNn indicates the receipt of a
negative pulse on RTIPn/RRINGn.
The output data at RDn or RDPn/RDNn are clocked out on the falling edges of RCLK when the CLKE input
is low, or are clocked out on the rising edges of RCLK when CLKE is high.
In Dual Rail Mode without clock recovery, these pins output the raw RZ sliced data. In this data recovery
mode, the active polarity of RDPn/RDNn is determined by pin CLKE. When pin CLKE is low, RDPn/RDNn
is active low. When pin CLKE is high, RDPn/RDNn is active high.
In hardware mode, RDn or RDPn/RDNn will remain active during LOS. In host mode, these pins will either
remain active or insert alarm indication signal (AIS) into the receive path, determined by bit AISE in regis-
ter GCF.
CV0/RDN0
CV1/RDN1
CV2/RDN2
CV3/RDN3
CV4/RDN4
CV5/RDN5
CV6/RDN6
CV7/RDN7
High-Z
41
34
76
P3
M3
M12
P12
A12
C12
C3
69
112
105
4
141
A3
RDn or RDPn/RDNn is set into high-Z when the corresponding receiver is powered down.
RCLK0
RCLK1
RCLK2
RCLK3
RCLK4
RCLK5
RCLK6
RCLK7
39
32
78
P1
M1
RCLKn: Receive Clock for Channel 0~7
In clock recovery mode, this pin outputs the recovered clock from signal received on RTIPn/RRINGn. The
received data are clocked out of the device on the rising edges of RCLKn if pin CLKE is high, or on falling
edges of RCLKn if pin CLKE is low.
In data recovery mode, RCLKn is the output of an internal exclusive OR (XOR) which is connected with
RDPn and RDNn. The clock is recovered from the signal on RCLKn.
M14
P14
A14
C14
C1
O
71
110
103
6
High-Z
If Receiver n is powered down, the corresponding RCLKn is in high-Z.
143
A1
MCLK: Master Clock
This is an independent, free running reference clock. A clock of 2.048 MHz is supplied to this pin as the
clock reference of the device for normal operation.
In receive path, when MCLK is high, the device slices the incoming bipolar line signal into RZ pulse (Data
Recovery mode). When MCLK is low, all the receivers are powered down, and the output pins RCLKn,
RDPn and RDNn are switched to high-Z.
MCLK
I
10
E1
In transmit path, the operation mode is decided by the combination of MCLK and TCLKn (see TCLKn pin
description for details).
NOTE: Wait state generation via RDY/ACK is not available if MCLK is not provided.
LOS0
LOS1
LOS2
LOS3
LOS4
LOS5
LOS6
LOS7
42
35
75
K4
K3
LOSn: Loss of Signal Output for Channel 0~7
A high level on this pin indicates the loss of signal when there is no transition over a specified period of
time or no enough ones density in the received signal. The transition will return to low automatically when
there is enough transitions over a specified period of time with a certain ones density in the received sig-
nal. The LOS assertion and desertion criteria are described in 2.3.4 Loss of Signal (LOS) Detection.
K12
K11
E11
E12
E3
68
O
113
106
3
140
E4
6
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
Hardware/Host Control Interface
MODE2: Control Mode Select 2
The signal on this pin determines which control mode is selected to control the device:
MODE2
Low
Control Interface
Hardware Mode
VDDIO/2
High
Serial Host Interface
Parallel Host Interface
Hardware control pins include MODE[2:0], LP[7:0], CODE, CLKE, JAS and OE.
Serial host Interface pins include CS, SCLK, SDI, SDO and INT.
Parallel host Interface pins include CS, A[4:0], D[7:0], WR/DS, RD/R/W, ALE/AS, INT and RDY/ACK. The
device supports multiple parallel host interface as follows (refer to MODE1 and MODE0 pin descriptions
below for details):
I
MODE2
11
E2
(Pulled to
VDDIO/2)
MODE[2:0]
100
Host Interface
Non-multiplexed Motorola Mode Interface
Non-multiplexed Intel Mode Interface
Multiplexed Motorola Mode Interface
Multiplexed Intel Mode Interface
101
110
111
MODE1: Control Mode Select 1
In parallel host mode, the parallel interface operates with separate address bus and data bus when this pin
is low, and operates with multiplexed address and data bus when this pin is high.
In serial host mode or hardware mode, this pin should be grounded.
MODE1
I
I
43
88
K2
MODE0: Control Mode Select 0
In parallel host mode, the parallel host interface is configured for Motorola compatible hosts when this pin
is low, or for Intel compatible hosts when this pin is high.
MODE0/CODE
H12
CODE: Line Code Rule Select
In hardware control mode, the HDB3 encoder/decoder is enabled when this pin is low, and AMI encoder/
decoder is enabled when this pin is high. The selections affect all the channels.
In serial host mode, this pin should be grounded.
CS: Chip Select (Active Low)
In host mode, this pin is asserted low by the host to enable host interface. A high to low transition must
occur on this pin for each read/write operation and the level must not return to high until the operation is
over.
I
JAS: Jitter Attenuator Select
In hardware control mode, this pin globally determines the Jitter Attenuator position:
CS/JAS
87
J11
(Pulled to
VDDIO/2)
JAS
Low
Jitter Attenuator (JA) Configuration
JA in transmit path
VDDIO/2
High
JA not used
JA in receive path
7
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
SCLK: Shift Clock
In serial host mode, the signal on this pin is the shift clock for the serial interface. Data on pin SDO is
clocked out on falling edges of SCLK if pin CLKE is high, or on rising edges of SCLK if pin CLKE is low.
Data on pin SDI is always sampled on rising edges of SCLK.
ALE: Address Latch Enable
In parallel Intel multiplexed host mode, the address on AD[4:0] is sampled into the device on the falling
edges of ALE (signals on AD[7:5] are ignored). In non-multiplexed host mode, ALE should be pulled high.
SCLK/ALE/AS
I
86
J12
AS: Address Strobe (Active Low)
In parallel Motorola multiplexed host mode, the address on AD[4:0] is latched into the device on the falling
edges of AS (signals on AD[7:5] are ignored). In non-multiplexed host mode, AS should be pulled high.
NOTE: This pin is ignored in hardware control mode.
RD: Read Strobe (Active Low)
In parallel Intel multiplexed or non-multiplexed host mode, this pin is active low for read operation.
RD/R/W
I
85
J13
R/W: Read/Write Select
In parallel Motorola multiplexed or non-multiplexed host mode, the pin is active low for write operation and
high for read operation.
NOTE: This pin is ignored in hardware control mode.
SDI: Serial Data Input
In serial host mode, this pin input the data to the serial interface. Data on this pin is sampled on the rising
edges of SCLK.
WR: Write Strobe (Active Low)
In parallel Intel host mode, this pin is active low during write operation. The data on D[7:0] (in non-multi-
plexed mode) or AD[7:0] (in multiplexed mode) is sampled into the device on the rising edges of WR.
SDI/WR/DS
I
84
J14
DS: Data Strobe (Active Low)
In parallel Motorola host mode, this pin is active low. During a write operation (R/W = 0), the data on D[7:0]
(in non-multiplexed mode) or AD[7:0] (in multiplexed mode) is sampled into the device on the rising edges
of DS. During a read operation (R/W = 1), the data is driven to D[7:0] (in non-multiplexed mode) or AD[7:0]
(in multiplexed mode) by the device on the rising edges of DS.
In parallel Motorola non-multiplexed host mode, the address information on the 5 bits of address bus
A[4:0] are latched into the device on the falling edges of DS.
NOTE: This pin is ignored in hardware control mode.
SDO: Serial Data Output
In serial host mode, the data is output on this pin. In serial write operation, SDO is in high impedance for
the first 8 SCLK clock cycles and driven low for the remaining 8 SCLK clock cycles. In serial read opera-
tion, SDO is in high-Z only when SDI is in address/command byte. Data on pin SDO is clocked out of the
device on the falling edges of SCLK if pin CLKE is high, or on the rising edges of SCLK if pin CLKE is low.
SDO/RDY/ACK
O
83
K14
RDY: Ready Output
In parallel Intel host mode, the high level of this pin reports to the host that bus cycle can be completed,
while low reports the host must insert wait states.
ACK: Acknowledge Output (Active Low)
In parallel Motorola host mode, the low level of this pin indicates that valid information on the data bus is
ready for a read operation or acknowledges the acceptance of the written data during a write operation.
O
INT: Interrupt (Active Low)
INT
Open
Drain
82
K13
This is an open drain, active low interrupt output. Three sources may cause the interrupt . Refer to 2.18
Interrupt Handling for details.
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Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
LPn: Loopback Select 7~0
In hardware control mode, pin LPn configures the corresponding channel in different loopback mode, as
follows:
LPn
Low
VDDIO/2
High
Loopback Configuration
Remote Loopback
No loopback
LP7/D7/AD7
LP6/D6/AD6
LP5/D5/AD5
LP4/D4/AD4
LP3/D3/AD3
LP2/D2/AD2
LP1/D1/AD1
LP0/D0/AD0
28
27
26
25
24
23
22
21
K1
J1
J2
J3
J4
H2
H3
G2
Analog Loopback
I/O
Refer to 2.16 Loopback Mode for details.
High-Z
Dn: Data Bus 7~0
In non-multiplexed host mode, these pins are the bi-directional data bus.
ADn: Address/Data Bus 7~0
In multiplexed host mode, these pins are the multiplexed bi-directional address/data bus.
In serial host mode, these pins should be grounded.
MCn: Performance Monitor Configuration 3~0
In hardware control mode, A4 must be connected to GND. MC[3:0] are used to select one transmitter or
receiver of channel 1 to 7 for non-intrusive monitoring. Channel 0 is used as the monitoring channel. If a
transmitter is monitored, signals on the corresponding pins TTIPn and TRINGn are internally transmitted
to RTIP0 and RRING0. If a receiver is monitored, signals on the corresponding pins RTIPn and RRINGn
are internally transmitted to RTIP0 and RRING0. The monitored is then output to RDP0 and RDN0 pins.
In host mode operation, the signals monitored by channel 0 can be routed to TTIP0/RING0 by activating
the remote loopback in this channel. Refer to 2.19 G.772 Monitoring for more details.
Performance Monitor Configuration determined by MC[3:0] is shown below. Note that if MC[2:0] = 000, the
device is in normal operation of all the channels.
MC[3:0]
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
Monitoring Configuration
Normal operation without monitoring
Monitor Receiver 1
A4
12
13
14
15
16
F4
F3
F2
F1
G3
Monitor Receiver 2
Monitor Receiver 3
Monitor Receiver 4
Monitor Receiver 5
Monitor Receiver 6
Monitor Receiver 7
MC3/A3
MC2/A2
MC1/A1
MC0/A0
I
Normal operation without monitoring
Monitor Transmitter 1
Monitor Transmitter 2
Monitor Transmitter 3
Monitor Transmitter 4
Monitor Transmitter 5
Monitor Transmitter 6
Monitor Transmitter 7
An: Address Bus 4~0
When pin MODE1 is low, the parallel host interface operates with separate address and data bus. In this
mode, the signal on this pin is the address bus of the host interface.
OE: Output Driver Enable
OE
I
114
E14
Pulling this pin low can drive all driver output into high-Z for redundancy application without external
mechanical relays. In this condition, all other internal circuits remain active.
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IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
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Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
CLKE: Clock Edge Select
The signal on this pin determines the active edge of RCLKn and SCLK in clock recovery mode, or deter-
mines the active level of RDPn and RDNn in the data recovery mode. See 2.2 Clock Edges on page 14 for
details.
CLKE
I
115
E13
JTAG Signals
I
TRST: JTAG Test Port Reset (Active Low)
TRST
95
96
G12
F11
This is the active low asynchronous reset to the JTAG Test Port. This pin has an internal pull-up resistor
and it can be left open.
Pull-up
I
TMS: JTAG Test Mode Select
The signal on this pin controls the JTAG test performance and is clocked into the device on the rising
edges of TCK. This pin has an internal pull-up resistor and it can be left open.
TMS
Pull-up
I
TCK: JTAG Test Clock
This pin input the clock of the JTAG Test. The data on TDI and TMS are clocked into the device on the ris-
ing edges of TCK, while the data on TDO is clocked out of the device on the falling edges of TCK. This pin
should be connected to GNDIO or VDDIO pin when unused.
TCK
97
F14
TDO: JTAG Test Data Output
O
High-Z
I
This pin output the serial data of the JTAG Test. The data on TDO is clocked out of the device on the fall-
ing edges of TCK. TDO is a high-Z output signal. It is active only when scanning of data is out. This pin
should be left float when unused.
TDO
TDI
98
99
F13
F12
TDI: JTAG Test Data Input
This pin input the serial data of the JTAG Test. The data on TDI is clocked into the device on the rising
edges of TCK. This pin has an internal pull-up resistor and it can be left open.
Pull-up
Power Supplies and Grounds
3.3 V I/O Power Supply
17
92
G1
G14
VDDIO
GNDIO
-
-
18
91
G4
G11
I/O GND
VDDT0
VDDT1
VDDT2
VDDT3
VDDT4
VDDT5
VDDT6
VDDT7
44
53
56
N4, P4
L4, M4
L11, M11
N11, P11
A11, B11
C11, D11
C4, D4
3.3 V/5 V Power Supply for Transmitter Driver
All VDDT pins must be connected to 3.3 V or all VDDT must be connected to 5 V. It is not allowed to leave
any of the VDDT pins open (not-connected) even if the channel is not used.
65
-
116
125
128
137
A4, B4
GNDT0
GNDT1
GNDT2
GNDT3
GNDT4
GNDT5
GNDT6
GNDT7
47
50
59
N6, P6
L6, M6
L9, M9
N9, P9
A9, B9
C9, D9
C6, D6
A6, B6
62
-
-
Analog GND for Transmitter Driver
119
122
131
134
VDDD
VDDA
19
90
H1
H14
3.3 V Digital/Analog Core Power Supply
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Table-1 Pin Description (Continued)
Pin No.
Name
Type
Description
TQFP144 PBGA160
GNDD
GNDA
20
89
H4
H11
-
Digital/Analog Core GND
Others
93
94
G13
H13
IC: Internal Connection
Internal use. Leave it float for normal operation.
IC
O
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IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
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1
2
FUNCTIONAL DESCRIPTION
The Dual Rail interface consists of TDPn , TDNn, TCLKn, RDPn,
RDNn and RCLKn. Data transmitted from TDPn and TDNn appears on
TTIPn and TRINGn at the line interface; data received from the RTIPn
and RRINGn at the line interface are transferred to RDPn and RDNn
while the recovered clock extracting from the received data stream
outputs on RCLKn. In Dual Rail operation, the clock/data recovery mode
is selectable. Dual Rail interface with clock recovery shown in Figure-4
is a default configuration mode. Dual Rail interface with data recovery is
shown in Figure-5. Pin RDPn and RDNn, are raw RZ slice outputs and
internally connected to an EXOR which is fed to the RCLKn output for
external clock recovery applications.
2.1 OVERVIEW
The IDT82V2058 is a fully integrated octal short-haul line interface
unit, which contains eight transmit and receive channels for use in E1
applications. The receiver performs clock and data recovery. As an
option, the raw sliced data (no retiming) can be output to the system.
Transmit equalization is implemented with low-impedance output drivers
that provide shaped waveforms to the transformer, guaranteeing
template conformance. A selectable jitter attenuator may be placed in
the receive path or the transmit path. Moreover, multiple testing func-
tions, such as error detection, loopback and JTAG boundary scan are
also provided. The device is optimized for flexible software control
through a serial or parallel host mode interface. Hardware control is also
available. Figure-1 on page 1 shows one of the eight identical channels
operation.
In Single Rail mode, data transmitted from TDn appears on TTIPn
and TRINGn at the line interface. Data received from the RTIPn and
RRINGn at the line interface appears on RDn while the recovered clock
extracting from the received data stream outputs on RCLKn. When the
device is in single rail interface, the selectable AMI or HDB3 line
encoder/decoder is available and any code violation in the received data
will be indicated at the CVn pin. The Single Rail mode has 2 sub-modes:
Single Rail Mode 1 and Single Rail Mode 2. Single Rail Mode 1, whose
interface is composed of TDn, TCLKn, RDn, CVn and RCLKn, is real-
ized by pulling pin TDNn high for more than 16 consecutive TCLK
cycles. Single Rail Mode 2, whose interface is composed of TDn,
TCLKn, RDn, CVn, RCLKn and BPVIn, is realized by setting bit CRS in
2.1.1 SYSTEM INTERFACE
The system interface of each channel can be configured to operate
in different modes:
1. Single rail interface with clock recovery.
2. Dual rail interface with clock recovery.
3. Dual rail interface with data recovery (that is, with raw data
slicing only and without clock recovery).
2
register e-CRS and bit SING in register e-SING. The difference
between them is that, in the latter mode bipolar violation can be inserted
via pin BPVIn if AMI line code is selected.
Each signal pin on system side has multiple functions depending on
which operation mode the device is in.
The configuration of the Hardware Mode System Interface is summa-
rized in Table-2. The configuration of the Host Mode System Interface is
summarized in Table-3.
1. The footprint ‘n’ (n = 0 - 7) indicates one of the eight channels.
2. The first letter ‘e-’ indicates expanded register.
One of Eight Identical Channels
LOS
LOSn
Detector
HDB3/
AMI
Decoder
CLK&Data
Recovery
(DPLL)
RTIPn
RCLKn
Jitter
Attenuator
Slicer
RDPn
RDNn
RRINGn
Peak
Detector
HDB3/
AMI
Encoder
TCLKn
TDPn
TDNn
TTIPn
Line
Driver
Waveform
Shaper
Jitter
Attenuator
TRINGn
Transmit
All Ones
Note: The grey blocks are bypassed and the dotted blocks are selectable.
Figure-4 Dual Rail Interface with Clock Recovery
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IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
One of Eight Identical Channels
LOS
LOSn
Detector
RCLKn
CLK&Data
Recovery
(DPLL)
HDB3/
AMI
Decoder
RTIPn
(RDP RDN)
Jitter
Attenuator
Slicer
RDPn
RRINGn
RDNn
Peak
Detector
HDB3/
AMI
Encoder
TCLKn
TDPn
TDNn
TTIPn
Line
Driver
Waveform
Shaper
Jitter
Attenuator
TRINGn
Transmit
All Ones
Note: The grey blocks are bypassed and the dotted blocks are selectable
Figure-5 Dual Rail Interface with Data Recovery
One of Eight Identical Channels
LOS
LOSn
Detector
HDB3/
AMI
Decoder
CLK&Data
Recovery
(DPLL)
RCLKn
RDn
CVn
RTIPn
Jitter
Attenuator
Slicer
RRINGn
Peak
Detector
HDB3/
AMI
Encoder
TCLKn
TDn
BPVIn/TDNn
TTIPn
Line
Driver
Waveform
Shaper
Jitter
Attenuator
TRINGn
Transmit
All Ones
Figure-6 Single Rail Mode
Table-2 System Interface Configuration (In Hardware Mode)
Pin MCLK
Clocked
Pin TDNn
High (≥ 16 MCLK)
Pulse
Interface
Single Rail Mode 1
Clocked
Dual Rail mode with Clock Recovery
Dual Rail mode with Data Recovery. Receive just slices the incoming data. Transmit is determined
by the status of TCLKn.
High
Low
Pulse
Pulse
Receiver is powered down. Transmit is determined by the status of TCLKn.
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Table-3 System Interface Configuration (In Host Mode)
Pin MCLK
Pin TDNn
CRSn in e-CRS
SINGn in e-SING
Interface
Clocked
Clocked
Clocked
High
Pulse
Pulse
0
0
0
0
1
0
Single Rail Mode 1
Single Rail Mode 2
Dual Rail mode with Clock Recovery
Dual Rail mode with Data Recovery. Receive just slices the incoming data. Transmit is
determined by the status of TCLKn.
Clocked
Pulse
1
0
Dual Rail mode with Data Recovery. Receive just slices the incoming data. Transmit is
determined by the status of TCLKn.
Receiver is powered down. Transmit is determined by the status of TCLKn.
High
Low
Pulse
Pulse
-
-
-
-
Table-4 Active Clock Edge and Active Level
Pin RDn/RDPn and CVn/RDNn
Clock Recovery
Pin CLKE
Pin SDO
Slicer Output
High
RCLKn
RCLKn
Active High
Active High
Active High
Active Low
SCLK
SCLK
Active High
Active High
Low
data recovery mode, the slicer output is sent to Clock and Data
Recovery circuit for abstracting retimed data and optional decoding. The
slicer circuit has a built-in peak detector from which the slicing threshold
is derived. The slicing threshold is default to 50% (typical) of the peak
value.
2.2 CLOCK EDGES
The active edge of RCLKn and SCLK are selectable. If pin CLKE is
high, the active edge of RCLKn is the rising edge, as for SCLK, that is
falling edge. On the contrary, if CLKE is low, the active edge of RCLK is
the falling edge and that of SCLK is rising edge. Pins RDn/RDPn, CVn/
RDNn and SDO are always active high, and those output signals are
clocked out on the active edge of RCLKn and SCLK respectively. See
Table-4 Active Clock Edge and Active Level on page 14 for details.
However, in dual rail mode without clock recovery, pin CLKE is used to
set the active level for RDPn/RDNn raw slicing output: High for active
high polarity and low for active low. It should be noted that data on pin
SDI are always active high and are sampled on the rising edges of
SCLK. The data on pin TDn/TDPn or BPVIn/TDNn are also always
active high but are sampled on the falling edges of TCLKn, despite the
level on CLKE.
Signals with an attenuation of up to 12 dB (from 2.4 V) can be recov-
ered by the receiver. To provide immunity from impulsive noise, the peak
detectors are held above a minimum level of 0.150 V typically, despite
the received signal level.
2.3.2 CLOCK AND DATA RECOVERY
The Clock and Data Recovery is accomplished by Digital Phase
Locked Loop (DPLL). The DPLL is clocked 16 times of the received
clock rate, i.e. 32.768 MHz in E1 mode. The recovered data and clock
from DPLL is then sent to the selectable Jitter Attenuator or decoder for
further processing.
2.3 RECEIVER
The clock recovery and data recovery mode can be selected on a per
channel basis by setting bit CRSn in register e-CRS. When bit CRSn is
defaulted to ‘0’, the corresponding channel operates in data and clock
recovery mode. The recovered clock is output on pin RCLKn and re-
timed NRZ data are output on pin RDPn/RDNn in dual rail mode or on
RDn in single rail mode. When bit CRSn is set to ‘1’, dual rail mode with
data recovery is enabled in the corresponding channel and the clock
recovery is bypassed. In this condition, the analog line signals are
converted to RZ digital bit streams on the RDPn/RDNn pins and inter-
nally connected to an EXOR which is fed to the RCLKn output for
external clock recovery applications.
In receive path, the line signals couple into RRINGn and RTIPn via a
transformer and are converted into RZ digital pulses by a data slicer.
Adaptation for attenuation is achieved using an integral peak detector
that sets the slicing levels. Clock and data are recovered from the
received RZ digital pulses by a digital phase-locked loop that provides
jitter accommodation. After passing through the selectable jitter attenu-
ator, the recovered data are decoded using HDB3 or AMI line code rules
and clocked out of pin RDn in single rail mode, or presented on RDPn/
RDNn in an undecoded dual rail NRZ format. Loss of signal, alarm indi-
cation signal, line code violation and excessive zeros are detected.
These various changes in status may be enabled to generate interrupts.
If MCLK is pulled high, all the receivers will enter the dual rail mode
with data recovery. In this case, register e-CRS is ignored.
2.3.1 PEAK DETECTOR AND SLICER
The slicer determines the presence and polarity of the received
pulses. In data recovery mode, the raw positive slicer output appears on
RDPn while the negative slicer output appears on RDNn. In clock and
14
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
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2.3.3 HDB3/AMI LINE CODE RULE
The configuration of the line code rule is summarized in Table-5.
Selectable HDB3 and AMI line coding/decoding is provided when the
device is configured in single rail mode. HDB3 rules is enabled by
setting bit CODE in register GCF to ‘0’ or pulling pin CODE low. AMI rule
is enabled by setting bit CODE in register GCF to ‘1’ or pulling pin CODE
high. The settings affect all eight channels.
2.3.4 LOSS OF SIGNAL (LOS) DETECTION
The Loss of Signal Detector monitors the amplitude and density of
the received signal on receiver line before the transformer (measured on
port A, B shown in Figure-10). The loss condition is reported by pulling
pin LOSn high. At the same time, LOS alarm registers track LOS condi-
tion. When LOS is detected or cleared, an interrupt will generate if not
masked. In host mode, the detection supports ITU G.775 and ETSI 300
233. In hardware mode, it supports the ITU G.775.
Individual line code rule selection for each channel, if needed, is
available by setting bit SINGn in register e-SING to ‘1’ (to activate bit
CODEn in register e-CODE) and programming bit CODEn to select line
code rules in the corresponding channel: ‘0’ for HDB3, while ‘1’ for AMI.
In this case, the value in bit CODE in register GCF or pin CODE for
global control is unaffected in the corresponding channel and only affect
in other channels.
Table-6 summarizes the conditions of LOS in clock recovery mode.
During LOS, the RDPn/RDNn continue to output the sliced data
when bit AISE in register GCF is set to ‘0’ or output all ones as AIS
(alarm indication signal) when bit AISE is set to ‘1’. The RCLKn is
replaced by MCLK only if the bit AISE is set.
In dual rail mode, the decoder/encoder are bypassed. Bit CODE in
register GCF, bit CODEn in register e-CODE and pin CODE are ignored.
Table-5 Configuration of the Line Code Rule
Hardware Mode
Host Mode
CODE
Line Code Rule
CODE in GCF
CODEn in e-CODE
SINGn in e-SING
Line Code Rule
0
0
1
1
0
1
0/1
0
0
1
0
1
1
1
All channels in HDB3
Low
All channels in HDB3
0/1
1
All channels in AMI
High
All channels in AMI
1
CHn in AMI
0
CHn in HDB3
Table-6 LOS Condition in Clock Recovery Mode
Standard
Signal on
LOSn
G.775
32
ETSI 300 233
Continuous Intervals
Amplitude(1)
2048 (1 ms)
LOS
Detected
High
below typical 200 mVp
below typical 200 mVp
12.5% (4 marks in a sliding 32-bit period) with no more 12.5% (4 marks in a sliding 32-bit period) with no more
Density
LOS
Cleared
than 15 continuous zeros
exceed typical 250 mVp
than 15 continuous zeros
exceed typical 250 mVp
Low
Amplitude(1)
1. LOS levels at device (RTIPn, RRINGn) with all ones signal. For more detail regarding the LOS parameters, please refer to Receiver Characteristics on page 42.
2.3.5 ALARM INDICATION SIGNAL (AIS) DETECTION
Alarm Indication Signal is available only in host mode with clock
recovery, as shown in Table-7.
determine whether excessive zeros and code violation are reported
respectively. When the device is configured in AMI decoding mode, only
bipolar violation can be reported.
The error detection is available only in single rail mode in which the
pin CVn/RDNn is used as error report output (CVn pin).
2.3.6 ERROR DETECTION
The device can detect excessive zeros, bipolar violation and HDB3
code violation, as shown in Figure-7 and Figure-8. All the three kinds of
errors are reported in both host mode and hardware mode with HDB3
line code rule used. In host mode, the e-CZER and e-CODV are used to
The configuration and report status of error detection are summa-
rized in Table-8.
Table-7 AIS Condition
ITU G.775
ETSI 300 233
(Register LAC defaulted to ‘0’)
(Register LAC set to ‘1’)
AIS Detected Less than 3 zeros contained in each of two consecutive 512-bit stream are received Less than 3 zeros contained in a 512-bit stream are received
AIS Cleared 3 or more zeros contained in each of two consecutive 512-bit stream are received 3 or more zeros contained in a 512-bit stream are received
15
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-8 Error Detection
Hardware Mode
Host Mode
Line Code CODVn in e-CODV CZERn in e-CZER
Line Code
Pin CVn Reports
Pin CVn Reports
Bipolar Violation
AMI
Bipolar Violation
AMI
-
-
0
0
1
1
0
1
0
1
Bipolar Violation + Code Violation
Bipolar Violation +
Code Violation
+ Excessive Zeros
Bipolar Violation + Code Violation + Excessive Zeros
Bipolar Violation
HDB3
HDB3
Bipolar Violation + Excessive Zeros
RCLKn
RTIPn
RRINGn
RDn
1
3
5
V
7
2
4
6
1
2
3
4
5
V
6
CVn
Bipolar Violation
Bipolar Violation detected
Figure-7 AMI Bipolar Violation
Code violation
RCLKn
RTIPn
RRINGn
RDn
1
3
5
4 consecutive zeros
2
4
V
V
6
1
2
3
4
5
6
CVn
Excessive zeros detected
Code violation detected
Figure-8 HDB3 Code Violation & Excessive Zeros
provided with a FIFO through which the data to be transmitted are
passing. A low jitter clock is generated by an integral digital phase-
locked loop and is used to read data from the FIFO. The shape of the
pulses should meet the E1 pulse template after the signal passes
through different cable lengths or types. Bipolar violation, for diagnosis,
can be inserted on pin BPVIn if AMI line code rule is enabled.
2.4 TRANSMITTER
In transmit path, data in NRZ format are clocked into the device on
TDn and encoded by AMI or HDB3 line code rules when single rail mode
is configured or pre-encoded data in NRZ format are input on TDPn and
TDNn when dual rail mode is configured. The data are sampled into the
device on falling edges of TCLKn. Jitter attenuator, if enabled, is
16
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
2.4.1 WAVEFORM SHAPER
For applications which require line synchronization, the line clock
needed to be extracted for the internal synchronization, the jitter attenu-
ator is set in the receive path. Another use of the jitter attenuator is to
provide clock smoothing in the transmit path for applications such as
synchronous/asynchronous demultiplexing applications. In these appli-
cations, TCLK will have an instantaneous frequency that is higher than
the nominal E1 data rate and in order to set the average long-term TCLK
frequency within the transmit line rate specifications, periods of TCLK
are suppressed (gapped).
E1 pulse template, specified in ITU-T G.703, is shown in Figure-9.
The device has built-in transmit waveform templates for cable of 75 Ω or
120 Ω.
The built-in waveform shaper uses an internal high frequency clock
which is 16XMCLK as the clock reference. This function will be
bypassed when MCLK is unavailable.
1.20
The jitter attenuator integrates a FIFO which can accommodate a
gapped TCLK. In host mode, the FIFO length can be 32 X 2 or 64 X 2
bits by programming bit JADP in GCF. In hardware mode, it is fixed to 64
X 2 bits. The FIFO length determines the maximum permissible gap
width (see Table-9 Gap Width Limitation). Exceeding these values will
cause FIFO overflow or underflow. The data is 16 or 32 bits’ delay
through the jitter attenuator in the corresponding transmit or receive
path. The constant delay feature is crucial for the applications requiring
“hitless” switching.
1.00
0.80
0.60
0.40
0.20
Table-9 Gap Width Limitation
0.00
FIFO Length
64 bit
Max. Gap Width
56 UI
-0.20
300
-300
-200
-100
0
100
200
Time (ns)
32 bit
28 UI
Figure-9 CEPT Waveform Template
2.4.2 BIPOLAR VIOLATION INSERTION
In host mode, bit JABW in GCF determines the jitter attenuator 3 dB
corner frequency (fc). In hardware mode, the fc is fixed to 1.7 Hz. Gener-
ally, the lower the fc is, the higher the attenuation. However, lower fc
comes at the expense of increased acquisition time. Therefore, the
optimum fc is to optimize both the attenuation and the acquisition time.
In addition, the longer FIFO length results in an increased throughput
delay and also influences the 3 dB corner frequency. Generally, it’s
recommended to use the lower corner frequency and the shortest FIFO
length that can still meet jitter attenuation requirements.
When configured in Single Rail Mode 2 with AMI line code enabled,
pin TDNn/BPVIn is used as BPVI input. A low-to-high transition on this
pin inserts a bipolar violation on the next available mark in the transmit
data stream. Sampling occurs on the falling edges of TCLK. But in TAOS
(Transmit All Ones) with Analog Loopback and Remote Loopback, the
BPVI is disabled. In TAOS with Digital Loopback, the BPVI is looped
back to the system side, so the data to be transmitted on TTIPn and
TRINGn are all ones with no bipolar violation.
The output jitter meets ITU-T G.736, ITU-T G.742, ITU-T G.783 and
ETSI CTR 12/13.
2.5
JITTER ATTENUATOR
2.6 LINE INTERFACE CIRCUITRY
The jitter attenuator can be selected to work either in transmit path or
in receive path or not used. The selection is accomplished by setting pin
JAS in hardware mode or configuring bits JACF[1:0] in register GCF in
host mode, which affects all eight channels.
The transmit and receive interface RTIPn/RRINGn and TTIPn/
TRINGn connections provide a matched interface to the cable. Figure-
10 shows the appropriate external components to connect with the cable
for one transmit/receive channel. Table-10 summarizes the component
values based on the specific application.
17
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-10 External Components Values
Component
75 Ω Coax
9.5 Ω ± 1%
9.31 Ω ± 1%
120 Ω Twisted Pair
9.5 Ω ± 1%
RT
RR
Cp
15 Ω ± 1%
2200 pF
Nihon Inter Electronics - EP05Q03L, 11EQS03L,
EC10QS04, EC10QS03L;
D1 - D4
Motorola - MBR0540T1
One of Eight Identical Channels
1
A
1 kΩ
RR
2:1
•
•
•
•
•
RTIPn
0.22 µF
RX Line
RR
B
RRINGn
VDDT
D4
1 kΩ
1
2:1
VDDT
•
•
TTIPn
RT
D3
•
68 µF3
0.1 µF
VDDDn
Cp2
TX Line
VDDT
D2
GNDTn
TRINGn
•
·
RT
D1
NOTE:
1. Pulse T1124 transformer is recommended to be used in Standard (STD) operating temperature range (0°C to 70°C), while Pulse T1114
transformer is recommended to be used in Extended (EXT) operating temperature range is -40°C to +85°C. See Transformer Specifications Table for
details.
2. Typical value. Adjust for actual board parasitics to obtain optimum return loss.
3. Common decoupling capacitor for all VDDT and GNDT pins. One per chip.
Figure-10 External Transmit/Receive Line Circuitry
2.7 TRANSMIT DRIVER POWER SUPPLY
All transmit driver power supplies must be 5.0 V or 3.3 V.
Despite the power supply voltage, the 75 Ω/120 Ω lines are driven
through a pair of 9.5 Ω series resistors and a 1:2 transformer.
(1)
Table-11 Transformer Specifications
Electrical Specification @ 25°C
OCL @ 25°C (mH MIN) LL (µH MAX)
Part No.
Turns Ratio (Pri: sec ± 2%)
CW/W (pF MAX)
Receive Transmit Receive
.6 35 35
Package/Schematic
TOU/3
STD Temp. EXT Temp.
Transmit
1:2CT
Receive
1CT:2
Transmit
1.2
Receive
1.2
Transmit
.6
T1124
T1114
1. Pulse T1124 transformer is recommended to be used in Standard (STD) operating temperature range (0°C to 70°C), while Pulse T1114 transformer is recommended to be used in
Extended (EXT) operating temperature range is -40°C to +85°C.
2.8 POWER DRIVER FAILURE MONITOR
2.9 TRANSMIT LINE SIDE SHORT CIRCUIT FAILURE
DETECTION
A pair of 9.5 Ω serial resistors connect with TTIPn and TRINGn pins
and limit the output current. In this case, the output current is a limited
value which is always lower than the typical line short circuit current 180
mAp, even if the transmit line side is shorted.
An internal power Driver Failure Monitor (DFMON), parallel
connected with TTIPn and TRINGn, can detect short circuit failure
between TTIPn and TRINGn pins. Bit SCPB in register GCF decides
whether the output driver short circuit protection is enabled. When the
short circuit protection is enabled, the driver output current is limited to a
typical value: 180 mAp. Also, register DF, DFI and DFM will be available.
When DFMON will detect a short circuit, register DF will be set. With a
short circuit failure detected and short circuit protection enabled, register
DFI will be set and an interrupt will be generated on pin INT.
Refer to Table-10 External Components Values for details.
18
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
During Digital Loopback, the received signal on the receive line is still
monitored by the LOS Detector (See 2.3.4 Loss of Signal (LOS) Detec-
tion for details). In case of a LOS condition and AIS insertion enabled, all
ones signal will be output on RDPn/RDNn. With ATAO enabled, all ones
signal will be also output on TTIPn/TRINGn. AIS insertion can be
enabled by setting AISE bit in register GCF and ATAO can be enabled
by setting register ATAO (default disabled).
2.10 LINE PROTECTION
In transmit side, the Schottky diodes D1~D4 are required to protect
the line driver and improve the design robustness. In receive side, the
series resistors of 1 kΩ are used to protect the receiver against current
surges coupled in the device. The series resistors do not affect the
receiver sensitivity, since the receiver impedance is as high as 120 kΩ
typically.
2.16.2 ANALOG LOOPBACK
2.11 HITLESS PROTECTION SWITCHING (HPS)
By programming the bits of register ALB or pulling pin LPn high,
each channel of the device can be configured in Analog Loopback. In
this configuration, the data to be transmitted output from the line driver
are internally looped back to the slicer and peak detector in the receive
path and output on RCLKn, RDn/RDPn and CVn/RDNn. The data to be
transmitted are still output on TTIPn and TRINGn while the data
received on RTIPn and RRINGn are ignored. The LOS Detector (See
2.3.4 Loss of Signal (LOS) Detection for details) is still in use and moni-
tors the internal looped back data. If a LOS condition on TDPn/TDNn is
expected during Analog Loopback, ATAO should be disabled (default).
Figure-12 shows the process.
The IDT82V2058 transceivers include an output driver with high-Z
feature for E1 redundancy applications. This feature reduces the cost of
redundancy protection by eliminating external relays. Details of HPS are
described in relative Application Note.
2.12 SOFTWARE RESET
Writing register RS will cause software reset by initiating about 1 µs
reset cycle. This operation set all the registers to their default value.
2.13 POWER ON RESET
The TTIPn and RTIPn, TRINGn and RRINGn cannot be connected
directly to do the external analog loopback test. Line impedance loading
is required to conduct the external analog loopback test.
During power up, an internal reset signal sets all the registers to
default values. The power-on reset takes at least 10 µs, starting from
when the power supply exceeds 2/3 VDDA.
2.16.3 REMOTE LOOPBACK
2.14 POWER DOWN
By programming the bits of register RLB or pulling pin LPn low, each
channel of the device can be set in Remote Loopback. In this configura-
tion, the data and clock recovered by the clock and data recovery
circuits are looped to waveform shaper and output on TTIPn and
TRINGn. The jitter attenuator is also included in loopback when enabled
in the transmit or receive path. The received data and clock are still
output on RCLKn, RDn/RDPn and CVn/RDNn while the data to be trans-
mitted on TCLKn, TDn/TDPn and BPVIn/TDNn are ignored. The LOs
Detector is still in use. Figure-13 shows the process.
Each transmit channel will be powered down by pulling pin TCLKn
low for more than 64 MCLK cycles (if MCLK is available) or about 30 µs
(if MCLK is not available). In host mode, each transmit channel will also
be powered down by setting bit TPDNn in register e-TPDN to ‘1’.
All the receivers will be powered down when MCLK is low. When
MCLK is clocked or high, setting bit RPDNn in register e-RPDN to ‘1’ will
configure the corresponding receiver to be powered down.
2.15 INTERFACE WITH 5 V LOGIC
2.16.4 DUAL LOOPBACK
The IDT82V2058 can interface directly with 5 V TTL family devices.
The internal input pads are tolerant to 5 V output from TTL and CMOS
family devices.
Dual Loopback mode is set by setting bit DLBn in register DLB and
bit RLBn in register RLB to ‘1’. In this configuration, after passing the
encoder, the data and clock to be transmitted are looped back to
decoder directly and output on RCLKn, RDn/RDPn and CVn/RDNn. The
recovered data from RTIPn and RRINGn are looped back to waveform
shaper through JA (if selected) and output on TTIPn and TRINGn. The
LOS Detector is still in use. Figure-14 shows the process.
2.16 LOOPBACK MODE
The device provides four different diagnostic loopback configura-
tions: Digital Loopback, Analog Loopback, Remote Loopback and Dual
Loopback. In host mode, these functions are implemented by program-
ming the registers DLB, ALB and RLB respectively. In hardware mode,
only Analog Loopback and Remote Loopback can be selected by pin
LPn.
2.16.5 TRANSMIT ALL ONES (TAOS)
In hardware mode, the TAOS mode is set by pulling pin TCLKn high
for more than 16 MCLK cycles. In host mode, TAOS mode is set by
programming register TAO. In addition, automatic TAOS signals are
inserted by setting register ATAO when Loss of Signal occurs. Note that
the TAOS generator adopts MCLK as a timing reference. In order to
assure that the output frequency is within specified limits, MCLK must
have the applicable stability.
2.16.1 DIGITAL LOOPBACK
By programming the bits of register DLB, each channel of the device
can be configured in Local Digital Loopback. In this configuration, the
data and clock to be transmitted, after passing the encoder, are looped
back to Jitter Attenuator (if enabled) and decoder in the receive path,
then output on RCLKn, RDn/RDPn and CVn/RDNn. The data to be
transmitted are still output on TTIPn and TRINGn while the data
received on RTIPn and RRINGn are ignored. The Loss Detector is still in
use. Figure-11 shows the process.
The TAOS mode, the TAOS mode with Digital Loopback and the
TAOS mode with Analog Loopback are shown in Figure-15, Figure-16
and Figure-17.
19
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
One of Eight Identical Channels
LOS
LOSn
Detector
CLK&Data
RTIPn
RCLKn
RDn/RDPn
CVn/RDNn
Jitter
Attenuator
HDB3/AMI
Decoder
Recovery
(DPLL)
Slicer
RRINGn
Digital
Loopback
Peak
Detector
TTIPn
TCLKn
Jitter
Attenuator
HDB3/AMI
Encoder
Line
Driver
Waveform
Shaper
TDn/TDPn
TRINGn
BPVIn/TDNn
Transmit
All Ones
Figure-11 Digital Loopback
One of Eight Identical Channels
LOS
LOSn
Detector
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
Slicer
RRINGn
Analog
Loopback
Peak
Detector
TTIPn
TCLKn
TDn/TDPn
BPVIn/TDNn
HDB3/AMI
Encoder
Line
Driver
Waveform
Shaper
Jitter
Attenuator
TRINGn
Transmit
All Ones
Figure-12 Analog Loopback
One of Eight Identical Channels
LOS
LOSn
Detector
CLK&Data
Recovery
(DPLL)
RCLKn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
RDn/RDPn
Slicer
RRINGn
CVn/RDNn
Peak
Remote
Detector
Loopback
TCLKn
TDn/TDPn
BPVIn/TDNn
TTIPn
Line
Driver
Waveform
Shaper
HDB3/AMI
Encoder
Jitter
Attenuator
TRINGn
Transmit
All Ones
Figure-13 Remote Loopback
20
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
One of Eight Identical Channels
LOS
Detector
LOSn
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
Slicer
RRINGn
Peak
Detector
TTIPn
TCLKn
Line
Driver
Jitter
Attenuator
Waveform
Shaper
HDB3/AMI
Encoder
TDn/TDPn
TRINGn
BPVIn/TDNn
Transmit
All Ones
Figure-14 Dual Loopback
One of Eight Identical Channels
LOS
LOSn
Detector
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
Slicer
RRINGn
Peak
Detector
TTIPn
TCLKn
TDn/TDPn
BPVIn/TDNn
Line
Driver
HDB3/AMI
Encoder
Waveform
Shaper
Jitter
Attenuator
TRINGn
Transmit
All Ones
Figure-15 TAOS Data Path
One of Eight Identical Channels
LOS
LOSn
Detector
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
Slicer
RRINGn
Peak
Detector
TTIPn
TCLKn
TDn/TDPn
BPVIn/TDNn
Line
Driver
Jitter
Attenuator
Waveform
Shaper
HDB3/AMI
Encoder
TRINGn
Transmit
All Ones
Figure-16 TAOS with Digital Loopback
21
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
One of Eight Identical Channels
LOS
Detector
LOSn
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
HDB3/AMI
Decoder
Jitter
Attenuator
Slicer
RRINGn
Peak
Detector
TTIPn
TCLKn
TDn/TDPn
BPVIn/TDNn
Line
Driver
HDB3/AMI
Encoder
Waveform
Shaper
TRINGn
Transmit
All Ones
Figure-17 TAOS with Analog Loopback
2.17.1 PARALLEL HOST INTERFACE
2.17 HOST INTERFACE
The interface is compatible with Motorola and Intel host. Pins
MODE1 and MODE0 are used to select the operating mode of the
parallel host interface. When pin MODE1 is pulled low, the host uses
separate address bus and data bus. When high, multiplexed address/
data bus is used. When pin MODE0 is pulled low, the parallel host inter-
face is configured for Motorola compatible hosts. When pin MODE0 is
pulled high, the parallel host interface is configured for Intel compatible
hosts. See Table-1 Pin Description for more details. The host interface
pins in each operation mode is tabulated in Table-12:
The host interface provides access to read and write the registers in
the device. The interface consists of serial host interface and parallel
host interface. By pulling pin MODE2 to VDDIO/2 or high, the device can
be set to work in serial mode and in parallel mode respectively.
Table-12 Parallel Host Interface Pins
MODE[2:0]
Host Interface
Non-multiplexed Motorola interface
Non-multiplexed Intel interface
Multiplexed Motorola interface
Multiplexed Intel interface
Generic Control, Data and Output Pin
CS, ACK, DS, R/W, AS, A[4:0], D[7:0], INT
CS, RDY, WR, RD, ALE, A[4:0], D[7:0], INT
CS, ACK, DS, R/W, AS, AD[7:0], INT
CS, RDY, WR, RD, ALE, AD[7:0], INT
100
101
110
111
CS
SCLK
A1 A2 A3 A4 A5 A62 A72 D0 D1 D2 D3 D4 D5 D6 D7
1
SDI
R/W
Address/Command Byte
Input Data Byte
SDO
D0 D1 D2 D3 D4 D5 D6 D7
High Impedance
Driven while R/W=1
1. While R/W=1, read from IDT82V2058; While R/W=0, write to IDT82V2058.
2. Ignored.
Figure-18 Serial Host Mode Timing
2.17.2 SERIAL HOST INTERFACE
data byte (D7~D0), as shown in Figure-18. When bit R/W is set to ‘1’,
data is read out from pin SDO. When bit R/W is set to ‘0’, data on pin
SDI is written into the register whose address is indicated by address
bits A5~A1. See Figure-18 Serial Host Mode Timing.
By pulling pin MODE2 to VDDIO/2, the device operates in the serial
host Mode. In this mode, the registers are accessible through a 16-bit
word which contains an 8-bit command/address byte (bit R/W and 5-
address-bit A1~A5, A6 and A7 bits are ignored) and a subsequent 8-bit
22
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
2.18.2 INTERRUPT ENABLE
2.18 INTERRUPT HANDLING
The IDT82V2058 provides a latched interrupt output (INT) and the
four kinds of interrupts are all reported by this pin. When the Interrupt
Mask register (LOSM, DFM and AISM) is set to ‘1’, the Interrupt Status
register (LOSI, DFI and AISI) is enabled respectively. Whenever there is
a transition (‘0’ to ‘1’ or ‘1’ to ‘0’) in the corresponding status register, the
Interrupt Status register will change into ‘1’, which means an interrupt
occurs, and there will be a high to low transition on INT pin. An external
pull-up resistor of approximately 10 kΩ is required to support the wire-
OR operation of INT. When any of the three Interrupt Mask registers is
set to ‘0’ (the power-on default value is ‘0’), the corresponding Interrupt
Status register is disabled and the transition on status register is
ignored.
2.18.1 INTERRUPT SOURCES
There are three kinds of interrupt sources:
1. Status change in register LOS. The analog/digital loss of signal
detector continuously monitors the received signal to update the
specific bit in register LOS which indicates presence or absence
of a LOS condition.
2. Status change in register DF. The automatic power driver circuit
continuously monitors the output drivers signal to update the
specific bit in register DFM which indicates presence or absence
of an output driver short circuit condition.
3. Status change in register AIS. The AIS detector monitors the
received signal to update the specific bit in register AIS which
indicates presence or absence of a AIS condition.
2.18.3 INTERRUPT CLEARING
When an interrupt occurs, the Interrupt Status registers: LOSI, DFI
and AISI, are read to identify the interrupt source. These registers will be
cleared to ‘0’ after the corresponding status registers: LOS, DF and AIS
are read. The Status registers will be cleared once the corresponding
conditions are met.
Interrupt Allowed
Pin INT is pulled high when there is no pending interrupt left. The
interrupt handling in the interrupt service routine is showed in Figure-19.
2.19 G.772 MONITORING
The eight channels of IDT82V2058 can all be configured to work as
regular transceivers. In applications using only seven channels (chan-
nels 1 to 7), channel 0 is configured to non-intrusively monitor any of the
other channels’ inputs or outputs on the line side. The monitoring is non-
intrusive per ITU-T G.772. Figure-20 shows the Monitoring Principle.
The receiver path or transmitter path to be monitored is configured by
pins MC[3:0] in hardware mode or by register PMON in host mode.
No
Interrupt Condition
Exist?
Yes
Read Interrupt Status Register
The monitored signal goes through the clock and data recovery
circuit of channel 0. The monitored clock can output on RCLK0 which
can be used as a timing interfaces derived from E1 signal. The moni-
tored data can be observed digitally at the output pins RCLK0, RD0/
RDP0 and RDN0. LOS detector is still in use in channel 0 for the moni-
tored signal.
Read Corresponding Status
Register
In monitoring mode, channel 0 can be configured in Remote Loop-
back. The signal which is being monitored will output on TTIP0 and
TRING0. The output signal can then be connected to a standard test
equipment with an E1 electrical interface for non-intrusive monitoring.
Service the Interrupt
Figure-19 Interrupt Service Routine
23
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Channel N ( 7 > N > 1 )
LOS
Detector
LOSn
HDB3/
AMI
Decoder
CLK&Data
Recovery
(DPLL)
RCLKn
RDn/RDPn
CVn/RDNn
RTIPn
Jitter
Attenuator
Slicer
RRINGn
Peak
Detector
HDB3/
AMI
Encoder
TTIPn
TCLKn
TDn/TDPn
BPVIn/TDNn
Jitter
Attenuator
Line
Driver
Waveform
Shaper
TRINGn
Transmit
All Ones
Channel 0
G.772
Monitor
LOS
Detector
LOS0
HDB3/
AMI
Decoder
CLK&Data
Recovery
(DPLL)
RCLK0
RD0/RDP0
CV0/RDN0
RTIP0
Jitter
Attenuator
Slicer
RRING0
Remote
Loopback
Peak
Detector
HDB3/
AMI
Encoder
TCLK0
TTIP0
Line
Driver
Waveform
Shaper
Jitter
Attenuator
TD0/TDP0
TRING0
BPVI0/TDN0
Transmit
All Ones
Figure-20 Monitoring Principle
24
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
The Register ADDP, addressed as 11111 or 1F Hex, switches
between primary registers bank and expanded registers bank.
3
PROGRAMMING INFORMATION
3.1 REGISTER LIST AND MAP
There are 21 primary registers (including an Address Pointer Control
Register and 8 expanded registers in the device).
By setting the register ADDP to ‘AAH’, the 5 address bits point to the
expanded register bank, that is, the expanded registers are available. By
clearing register ADDP, the primary registers are available.
Primary Registers, whose addresses are 10H, 11H, 16H to 1EH, are
reserved. Expanded registers, whose addresses are 08H to 1EH, are
used for test and must be set to ‘0’ (default).
Whatever the control interface is, 5 address bits are used to set the
registers. In non-multiplexed parallel interface mode, the five dedicated
address bits are A[4:0]. In multiplexed parallel interface mode, AD[4:0]
carries the address information. In serial interface mode, A[5:1] are used
to address the register.
Table-13 Primary Register List
Address
Register R/W
Explanation
Hex Serial Interface A7-A1 Parallel Interface A7-A0
ID
ALB
RLB
TAO
LOS
DF
LOSM
DFM
LOSI
DFI
R
Device ID Register
00
01
02
03
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
10
11
12
13
14
15
16
17
18
19
1A
1B
1C
1D
1E
XX00000
XX00001
XX00010
XX00011
XX00100
XX00101
XX00110
XX00111
XX01000
XX01001
XX01010
XX01011
XX01100
XX01101
XX01110
XX01111
XX10000
XX10001
XX10010
XX10011
XX10100
XX10101
XX10110
XX10111
XX11000
XX11001
XX11010
XX11011
XX11100
XX11101
XX11110
XXX00000
XXX00001
XXX00010
XXX00011
XXX00100
XXX00101
XXX00110
XXX00111
XXX01000
XXX01001
XXX01010
XXX01011
XXX01100
XXX01101
XXX01110
XXX01111
XXX10000
XXX10001
XXX10010
XXX10011
XXX10100
XXX10101
XXX10110
XXX10111
XXX11000
XXX11001
XXX11010
XXX11011
XXX11100
XXX11101
XXX11110
R/W Analog Loopback Configuration Register
R/W Remote Loopback Configuration Register
R/W Transmit All Ones Configuration Register
R
R
R/W LOS Interrupt Mask Register
R/W Driver Fault Interrupt Mask Register
R
R
W
R/W Performance Monitor Configuration Register
R/W Digital Loopback Configuration Register
R/W LOS/AIS Criteria Configuration Register
R/W Automatic TAOS Configuration Register
R/W Global Configuration Register
Loss of Signal Status Register
Driver Fault Status Register
LOS Interrupt Status Register
Driver Fault Interrupt Status Register
Software Reset Register
RS
PMON
DLB
LAC
ATAO
GCF
Reserved
OE
AIS
AISM
AISI
R/W Output Enable Configuration Register
R
R/W AIS Interrupt Mask Register
R
AIS Status Register
AIS Interrupt Status Register
Reserved
Address pointer control Register for switching between primary register bank and
expanded register bank
ADDP
R/W
1F
XX11111
XXX11111
25
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-14 Expanded (Indirect Address Mode) Register List
Address
Register R/W
Explanation
Hex Serial Interface A7-A1 Parallel Interface A7-A0
00
01
02
03
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
10
11
12
13
14
15
16
17
18
19
1A
1B
1C
1D
1E
XX00000
XX00001
XX00010
XX00011
XX00100
XX00101
XX00110
XX00111
XX01000
XX01001
XX01010
XX01011
XX01100
XX01101
XX01110
XX01111
XX10000
XX10001
XX10010
XX10011
XX10100
XX10101
XX10110
XX10111
XX11000
XX11001
XX11010
XX11011
XX11100
XX11101
XX11110
XXX00000
XXX00001
XXX00010
XXX00011
XXX00100
XXX00101
XXX00110
XXX00111
XXX01000
XXX01001
XXX01010
XXX01011
XXX01100
XXX01101
XXX01110
XXX01111
XXX10000
XXX10001
XXX10010
XXX10011
XXX10100
XXX10101
XXX10110
XXX10111
XXX11000
XXX11001
XXX11010
XXX11011
XXX11100
XXX11101
XXX11110
e-SING R/W
e-CODE R/W
e-CRS R/W
e-RPDN R/W
e-TPDN R/W
e-CZER R/W
e-CODV R/W
e-EQUA R/W
Single Rail Mode Setting Register
Encoder/Decoder Selection Register
Clock Recovery Enable/Disable Register
Receiver n Powerdown Enable/Disable Register
Transmitter n Powerdown Enable/Disable Register
Consecutive Zero Detect Enable/Disable Register
Code Violation Detect Enable/Disable Register
Enable Equalizer Enable/Disable Register
Test
Address pointer control register for switching between primary register bank
and expanded register bank
1F
XX11111
XXX11111
ADDP
R/W
26
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-15 Primary Register Map
Address
Register
R/W
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Default
00H
R
Default
ID 7
R
0
ID 6
R
0
ID 5
R
0
ID 4
R
1
ID 3
R
0
ID 2
R
0
ID 1
R
0
ID 0
R
0
ID
ALB
01H
R/W
Default
ALB 7
R/W
0
ALB 6
R/W
0
ALB 5
R/W
0
ALB 4
R/W
0
ALB 3
R/W
0
ALB 2
R/W
0
ALB 1
R/W
0
ALB 0
R/W
0
02H
R/W
Default
RLB 7
R/W
0
RLB 6
R/W
0
RLB 5
R/W
0
RLB 4
R/W
0
RLB 3
R/W
0
RLB 2
R/W
0
RLB 1
R/W
0
RLB 0
R/W
0
RLB
TAO
LOS
DF
03H
R/W
Default
TAO 7
R/W
0
TAO 6
R/W
0
TAO 5
R/W
0
TAO 4
R/W
0
TAO 3
R/W
0
TAO 2
R/W
0
TAO 1
R/W
0
TAO 0
R/W
0
04H
R
Default
LOS 7
R
0
LOS 6
R
0
LOS 5
R
0
LOS 4
R
0
LOS 3
R
0
LOS 2
R
0
LOS 1
R
0
LOS 0
R
0
05H
R
DF 7
R
DF 6
R
DF 5
R
DF 4
R
DF 3
R
DF 2
R
DF 1
R
DF 0
R
Default
0
0
0
0
0
0
0
0
06H
R/W
Default
LOSM 7
R/W
0
LOSM 6
R/W
0
LOSM 5
R/W
0
LOSM 4
R/W
0
LOSM 3
R/W
0
LOSM 2
R/W
0
LOSM 1
R/W
0
LOSM 0
R/W
0
LOSM
DFM
LOSI
DFI
07H
R/W
Default
DFM 7
R/W
0
DFM 6
R/W
0
DFM 5
R/W
0
DFM 4
R/W
0
DFM 3
R/W
0
DFM 2
R/W
0
DFM 1
R/W
0
DFM 0
R/W
0
08H
R
Default
LOSI 7
R
0
LOSI 6
R
0
LOSI 5
R
0
LOSI 4
R
0
LOSI 3
R
0
LOSI 2
R
0
LOSI 1
R
0
LOSI 0
R
0
09H
R
Default
DFI 7
R
0
DFI 6
R
0
DFI 5
R
0
DFI 4
R
0
DFI 3
R
0
DFI 2
R
0
DFI 1
R
0
DFI 0
R
0
0AH
W
RS 7
W
RS 6
W
RS 5
W
RS 4
W
RS 3
W
RS 2
W
RS 1
W
RS 0
W
RS
Default
1
1
1
1
1
1
1
1
0BH
R/W
Default
-
R/W
0
-
R/W
0
-
R/W
0
-
R/W
0
MC 3
R/W
0
MC 2
R/W
0
MC 1
R/W
0
MC 0
R/W
0
PMON
DLB
LAC
ATAO
GCF
0CH
R/W
Default
DLB 7
R/W
0
DLB 6
R/W
0
DLB 5
R/W
0
DLB 4
R/W
0
DLB 3
R/W
0
DLB 2
R/W
0
DLB 1
R/W
0
DLB 0
R/W
0
0DH
R/W
Default
LAC 7
R/W
0
LAC 6
R/W
0
LAC 5
R/W
0
LAC 4
R/W
0
LAC 3
R/W
0
LAC 2
R/W
0
LAC 1
R/W
0
LAC 0
R/W
0
0EH
R/W
Default
ATAO 7
R/W
0
ATAO 6
R/W
0
ATAO 5
R/W
0
ATAO 4
R/W
0
ATAO 3
R/W
0
ATAO 2
R/W
0
ATAO 1
R/W
0
ATAO 0
R/W
0
0FH
R/W
Default
-
R/W
0
AISE
R/W
0
SCPB
R/W
0
CODE
R/W
0
JADP
R/W
0
JABW
R/W
0
JACF 1
R/W
0
JACF 0
R/W
0
27
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-15 Primary Register Map (Continued)
Address
Register
R/W
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Default
12 Hex
R/W
Default
OE 7
R/W
0
OE 6
R/W
0
OE 5
R/W
0
OE 4
R/W
0
OE 3
R/W
0
OE 2
R/W
0
OE 1
R/W
0
OE 0
R/W
0
OE
AIS
13 Hex
R
Default
AIS 7
R
0
AIS 6
R
0
AIS 5
R
0
AIS 4
R
0
AIS 3
R
0
AIS 2
R
0
AIS 1
R
0
AIS 0
R
0
14 Hex
R/W
Default
AISM 7
R/W
0
AISM 6
R/W
0
AISM 5
R/W
0
AISM 4
R/W
0
AISM 3
R/W
0
AISM 2
R/W
0
AISM 1
R/W
0
AISM 0
R/W
0
AISM
AISI
15 Hex
R
Default
AISI 7
R
0
AISI 6
R
0
AISI 5
R
0
AISI 4
R
0
AISI 3
R
0
AISI 2
R
0
AISI 1
R
0
AISI 0
R
0
1F Hex
R/W
Default
ADDP 7
R/W
0
ADDP 6
R/W
0
ADDP 5
R/W
0
ADDP 4
R/W
0
ADDP 3
R/W
0
ADDP 2
R/W
0
ADDP 1
R/W
0
ADDP 0
R/W
0
ADDP
Table-16 Expanded (Indirect Address Mode) Register Map
Address
Register
R/W
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Default
00H
R/W
Default
01H
R/W
Default
02H
R/W
Default
SING 7
R/W
0
CODE 7
R/W
0
CRS 7
R/W
0
SING 6
R/W
0
CODE 6
R/W
0
CRS 6
R/W
0
SING 5
R/W
0
CODE 5
R/W
0
CRS 5
R/W
0
SING 4
R/W
0
CODE 4
R/W
0
CRS 4
R/W
0
SING 3
R/W
0
CODE 3
R/W
0
CRS 3
R/W
0
SING 2
R/W
0
CODE 2
R/W
0
CRS 2
R/W
0
SING 1
R/W
0
SING 0
R/W
0
CODE 0
R/W
0
CRS 0
R/W
0
e-SING
e-CODE
e-CRS
CODE 1 R/W
0
CRS 1
R/W
0
03H
R/W
Default
04H
R/W
Default
05H
R/W
Default
06H
R/W
Default
07H
R/W
Default
RPDN 7
R/W
0
TPDN 7
R/W
0
CZER 7
R/W
0
CODV 7
R/W
0
RPDN 6
R/W
0
TPDN 6
R/W
0
CZER 6
R/W
0
CODV 6
R/W
0
RPDN 5
R/W
0
TPDN 5
R/W
0
CZER 5
R/W
0
CODV 5
R/W
0
RPDN 4
R/W
0
TPDN 4
R/W
0
CZER 4
R/W
0
CODV 4
R/W
0
RPDN 3
R/W
0
TPDN 3
R/W
0
CZER 3
R/W
0
CODV 3
R/W
0
RPDN 2
R/W
0
TPDN 2
R/W
0
CZER 2
R/W
0
CODV 2
R/W
0
RPDN 1
R/W
0
TPDN 1
R/W
0
CZER 1
R/W
0
CODV 1
R/W
0
RPDN 0
R/W
0
TPDN 0
R/W
0
CZER 0
R/W
0
CODV 0
R/W
0
e-RPDN
e-TPDN
e-CZER
e-CODV
e-EQUA
EQUA 7
R/W
0
EQUA 6
R/W
0
EQUA 5
R/W
0
EQUA 4
R/W
0
EQUA 3
R/W
0
EQUA 2
R/W
0
EQUA 1
R/W
0
EQUA 0
R/W
0
1FH
R/W
Default
ADDP 7
R/W
0
ADDP 6
R/W
0
ADDP 5
R/W
0
ADDP 4
R/W
0
ADDP 3
R/W
0
ADDP 2
R/W
0
ADDP 1
R/W
0
ADDP 0
R/W
0
ADDP
28
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
3.2 REGISTER DESCRIPTION
3.2.1 PRIMARY REGISTERS
ID: Device ID Register (R, Address = 00H)
Symbol
Position Default
Description
An 8-bit word is pre-set into the device as the identification and revision number. This number is different with the functional
changes and is mask programmed.
ID[7:0]
ID.7-0
10H
ALB: Analog Loopback Configuration Register (R/W, Address = 01H)
Symbol
Position Default
Description
Description
0 = Normal operation. (Default)
1 = Analog Loopback enabled.
ALB[7:0]
ALB.7-0
00H
RLB: Remote Loopback Configuration Register (R/W, Address = 02H)
Symbol
Position Default
0 = Normal operation. (Default)
1 = Remote Loopback enabled.
RLB[7:0]
RLB.7-0
00H
TAO: Transmit All Ones Configuration Register (R/W, Address = 03H)
Symbol
Position Default
Description
Description
Description
Description
Description
Description
0 = Normal operation. (Default)
1 = Transmit all ones.
TAO[7:0]
TAO.7-0
00H
LOS: Loss of Signal Status Register (R, Address = 04H)
Symbol
Position Default
0 = Normal operation. (Default)
1 = Loss of signal detected.
LOS[7:0]
LOS.7-0
00H
DF: Driver Fault Status Register (R, Address = 05H)
Symbol
Position Default
0 = Normal operation. (Default)
1 = Driver fault detected.
DF[7:0]
DF.7-0
00H
LOSM: Loss of Signal Interrupt Mask Register (R/W, Address = 06H)
Symbol
Position Default
0 = LOS interrupt is not allowed. (Default)
1 = LOS interrupt is allowed.
LOSM[7:0]
LOSM.7-0
00H
DFM: Driver Fault Interrupt Mask Register (R/W, Address = 07H)
Symbol
Position Default
0 = Driver fault interrupt not allowed. (Default)
1 = Driver fault interrupt allowed.
DFM[7:0]
DFM.7-0
00H
LOSI: Loss of Signal Interrupt Status Register (R, Address = 08H)
Symbol
Position Default
0 = (Default). Or after a LOS read operation.
1 = Any transition on LOSn (Corresponding LOSMn is set to ‘1’).
LOSI[7:0]
LOSI.7-0
00H
29
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
DFI: Driver Fault Interrupt Status Register (R, Address = 09H)
Symbol
Position Default
Description
0 = (Default). Or after a DF read operation.
1 = Any transition on DFn (Corresponding DFMn is set to ‘1’).
DFI[7:0]
DFI.7-0
00H
RS: Software Reset Register (W, Address = 0AH)
Symbol
Position Default
Description
Writing to this register will not change the content in this register but initiate a 1 µs reset cycle, which means all the registers
in the device are set to their default values.
RS[7:0]
RS.7-0
FFH
PMON: Performance Monitor Configuration Register (R/W, Address = 0BH)
Symbol
Position
Default
Description
0 = Normal operation. (Default)
1 = Reserved.
-
PMON.7-4
0000
0000 = Normal operation without monitoring (Default)
0001 = Monitor Receiver 1
0010 = Monitor Receiver 2
0011 = Monitor Receiver 3
0100 = Monitor Receiver 4
0101 = Monitor Receiver 5
0110 = Monitor Receiver 6
0111 = Monitor Receiver 7
MC[3:0]
PMON.3-0
0000
1000 = Normal operation without monitoring
1001 = Monitor Transmitter 1
1010 = Monitor Transmitter 2
1011 = Monitor Transmitter 3
1100 = Monitor Transmitter 4
1101 = Monitor Transmitter 5
1110 = Monitor Transmitter 6
1111 = Monitor Transmitter 7
DLB: Digital Loopback Configuration Register (R/W, Address = 0CH)
Symbol
Position
Default
Description
Description
0 = Normal operation. (Default)
1 = Digital Loopback enabled.
DLB[7:0]
DLB.7-0
00H
LAC: LOS/AIS Criteria Configuration Register (R/W, Address = 0DH)
Symbol
Position
Default
0 = G.775 (Default)
1 = ETSI 300 233
LAC[7:0]
LAC.7-0
00H
ATAO: Automatic TAOS Configuration Register (R/W, Address = 0EH)
Symbol
Position
Default
Description
0 = No automatic transmit all ones. (Default)
1 = Automatic transmit all ones to the line side during LOS.
ATAO[7:0]
ATAO.7-0
00H
30
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
GCF: Global Configuration Register (R/W, Address = 0FH)
Symbol
Position
Default
Description
0 = Normal operation.
1 = Reserved.
-
GCF.7
0
0 = AIS insertion to the system side disabled on LOS.
1 = AIS insertion to the system side enabled on LOS.
0 = Short circuit protection is enabled.
1 = Short circuit protection is disabled.
0 = HDB3 encoder/decoder enabled.
1 = AMI encoder/decoder enabled.
Jitter Attenuator Depth Select
0 = 32-bit FIFO (Default)
AISE
SCPB
CODE
GCF.6
GCF.5
GCF.4
0
0
0
JADP
JABW
GCF.3
GCF.2
0
1 = 64-bit FIFO
Jitter Transfer Function Bandwidth Select
0 = 1.7 Hz
0
1 = 6.6 Hz
Jitter Attenuator Configuration
00 = JA not used. (Default)
01 = JA in transmit path
JACF[1:0]
GCF.1-0
00
10 = JA not used.
11 = JA in receive path
OE: Output Enable Configuration Register (R/W, Address = 12H)
Symbol
Position Default
Description
Description
Description
Description
0 = Transmit drivers enabled. (Default)
1 = Transmit drivers in high-Z.
OE[7:0]
OE.7-0
00H
AIS: Alarm Indication Signal Status Register (R, Address = 13H)
Symbol
Position Default
0 = Normal operation. (Default)
1 = AIS detected.
AIS[7:0]
AIS.7-0
00H
AISM: Alarm Indication Signal Interrupt Mask Register (R/W, Address = 14H)
Symbol
Position Default
0 = AIS interrupt is not allowed. (Default)
1 = AIS interrupt is allowed.
AISM[7:0]
AISM.7-0
00H
AISI: Alarm Indication Signal Interrupt Status Register (R, Address = 15H)
Symbol
Position Default
0 = (Default), or after an AIS read operation
1 = Any transition on AISn. (Corresponding AISMn is set to ‘1’.)
AISI[7:0]
AISI.7-0
00H
ADDP: Address Pointer Control Register (R/W, Address = 1F H)
Symbol
Position Default
Description
Two kinds of configuration in this register can be set to switch between primary register bank and expanded register bank.
When power up, the address pointer will point to the top address of primary register bank automatically.
00H = The address pointer points to the top address of primary register bank (default).
ADDP[7:0]
ADDP.7-0
00H
AAH = The address pointer points to the top address of expanded register bank.
31
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
3.2.2 EXPANDED REGISTER DESCRIPTION
e-SING: Single Rail Mode Setting Register (R/W, Expanded Address = 00H)
Symbol
Position Default
Description
0 = Pin TDNn selects single rail mode or dual rail mode. (Default)
1 = Single rail mode enabled (with CRSn=0)
SING[7:0]
SING.7-0
00H
e-CODE: Encoder/Decoder Selection Register (R/W, Expanded Address = 01H)
Symbol Position Default
Description
CODEn selects AMI or HDB3 encoder/decoder on a per channel basis with SINGn = 1 and CRSn = 0.
0 = HDB3 encoder/decoder enabled. (Default)
CODE[7:0] CODE.7-0
00H
1 = AMI encoder/decoder enabled.
e-CRS: Clock Recovery Enable/Disable Selection Register (R/W, Expanded Address = 02H)
Symbol
Position Default
Description
0 = Clock recovery enabled. (Default)
1 = Clock recovery disabled.
CRS[7:0]
CRS.7-0
00H
e-RPDN: Receiver n Powerdown Register (R/W, Expanded Address = 03H)
Symbol
Position Default
Description
0 = Normal operation. (Default)
1 = Receiver n is powered down.
RPDN[7:0]
RPDN.7-0
00H
e-TPDN: Transmitter n Powerdown Register (R/W, Expanded Address = 04H)
Symbol
Position Default
Description
0 = Normal operation. (Default)
TPDN[7:0]
TPDN.7-0
00H
1 = Transmitter n is powered down(1) (the corresponding transmit output driver enters a low power high-Z mode).
1. Transmitter n is powered down when either pin TCLKn is pulled low or TPDNn is set to ‘1’
e-CZER: Consecutive Zero Detect Enable/Disable Register (R/W, Expanded Address = 05H)
Symbol
Position Default
Description
0 = Excessive zeros detect disabled. (Default)
1 = Excessive zeros detect enabled for HDB3 decoder in single rail mode.
CZER[7:0]
CZER.7-0
00H
e-CODV: Code Violation Detect Enable/Disable Register (R/W, Expanded Address = 06H)
Symbol
Position Default
Description
0 = Code Violation Detect enable for HDB3 decoder in single rail mode. (Default)
1 = Code Violation Detect disabled.
CODV[7:0] CODV.7-0
00H
e-EQUA: Receive Equalizer Enable/Disable Register (R/W, Expanded Address = 07H)
Symbol
Position Default
Description
0 = Normal operation. (Default)
EQUA[7:0]
EQUA.7-0
00H
1 = Equalizer in Receiver n is enabled, which can improve the receive performance when transmission length is more than
200 m.
32
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
The JTAG boundary scan registers includes BSR (Boundary Scan
Register), IDR (Device Identification Register), BR (Bypass Register)
and IR (Instruction Register). These will be described in the following
pages. Refer to Figure-21 for architecture.
4
IEEE STD 1149.1 JTAG TEST
ACCESS PORT
The IDT82V2058 supports the digital Boundary Scan Specification
as described in the IEEE 1149.1 standards.
4.1 JTAG INSTRUCTIONS AND INSTRUCTION REG-
ISTER (IR)
The IR with instruction decode block is used to select the test to be
executed or the data register to be accessed or both.
The boundary scan architecture consists of data and instruction
registers plus a Test Access Port (TAP) controller. Control of the TAP is
achieved through signals applied to the TMS and TCK pins. Data is
shifted into the registers via the TDI pin, and shifted out of the registers
via the TDO pin. JTAG test data are clocked at a rate determined by
JTAG test clock.
The instructions are shifted in LSB first to this 3-bit register. See
Table-17 Instruction Register Description on page 34 for details of the
codes and the instructions related.
Digital output pins
Digital input pins
parallel latched output
BSR (Boundary Scan Register)
MUX
IDR (Device Identification Register)
BR (Bypass Register)
TDI
TDO
IR (Instruction Register)
Control<6:0>
TMS
TAP
Select
TRST
(Test Access Port)
Controller
High-Z Enable
TCK
Figure-21 JTAG Architecture
33
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-17 Instruction Register Description
IR Code
Instruction
Comments
The external test instruction allows testing of the interconnection to other devices. When the current instruction is the
EXTEST instruction, the boundary scan register is placed between TDI and TDO. The signal on the input pins can be
sampled by loading the boundary scan register using the Capture-DR state. The sampled values can then be viewed by
shifting the boundary scan register using the Shift-DR state. The signal on the output pins can be controlled by loading
patterns shifted in through input TDI into the boundary scan register using the Update-DR state.
000
Extest
The sample instruction samples all the device inputs and outputs. For this instruction, the boundary scan register is placed
between TDI and TDO. The normal path between IDT82V2058 logic and the I/O pins is maintained. Primary device
inputs and outputs can be sampled by loading the boundary scan register using the Capture-DR state. The sampled val-
ues can then be viewed by shifting the boundary scan register using the Shift-DR state.
100
Sample/Preload
The identification instruction is used to connect the identification register between TDI and TDO. The device's identifica-
tion code can then be shifted out using the Shift-DR state.
110
111
Idcode
Bypass
The bypass instruction shifts data from input TDI to output TDO with one TCK clock period delay. The instruction is used
to bypass the device.
4.2.2 BYPASS REGISTER (BR)
Table-18 Device Identification Register Description
The BR consists of a single bit. It can provide a serial path between
the TDI input and TDO output, bypassing the BSR to reduce test access
times.
Bit No.
0
Comments
Set to ‘1’
4.2.3 BOUNDARY SCAN REGISTER (BSR)
1~11
12~27
28~31
Producer Number
Part Number
Device Revision
The BSR can apply and read test patterns in parallel to or from all the
digital I/O pins. The BSR is a 98 bits long shift register and is initialized
and read using the instruction EXTEST or SAMPLE/PRELOAD. Each
pin is related to one or more bits in the BSR. Please refer to Table-19 for
details of BSR bits and their functions.
4.2 JTAG DATA REGISTER
4.2.1 DEVICE IDENTIFICATION REGISTER (IDR)
The IDR can be set to define the producer number, part number and
the device revision, which can be used to verify the proper version or
revision number that has been used in the system under test. The IDR is
32 bits long and is partitioned as in Table-18. Data from the IDR is
shifted out to TDO LSB first.
Table-19 Boundary Scan Register Description
Bit No.
0
1
2
3
4
5
6
7
Bit Symbol
POUT0
PIN0
POUT1
PIN1
POUT2
PIN2
POUT3
PIN3
POUT4
PIN4
POUT5
PIN5
POUT6
PIN6
POUT7
PIN7
Pin Signal
LP0
Type
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
Comments
LP0
LP1
LP1
LP2
LP2
LP3
LP3
LP4
LP4
LP5
LP5
LP6
LP6
LP7
LP7
8
9
10
11
12
13
14
15
34
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-19 Boundary Scan Register Description (Continued)
Bit No.
Bit Symbol
Pin Signal
Type
Comments
Controls pins LP[7:0].
16
PIOS
N/A
-
When ‘0’, the pins are configured as outputs. The output values to the pins are set in POUT 7~0.
When ‘1’, the pins are high-Z. The input values to the pins are read in PIN 7~0.
17
18
19
20
21
22
TCLK1
TDP1
TDN1
RCLK1
RDP1
RDN1
TCLK1
TDP1
TDN1
RCLK1
RDP1
RDN1
I
I
I
O
O
O
Controls pin RDP1, RDN1 and RCLK1.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
23
HZEN1
N/A
-
24
25
26
27
28
29
30
LOS1
TCLK0
TDP0
TDN0
RCLK0
RDP0
RDN0
LOS1
TCLK0
TDP0
TDN0
RCLK0
RDP0
RDN0
O
I
I
I
O
O
O
Controls pin RDP0, RDN0 and RCLK0.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
31
HZEN0
N/A
-
32
33
34
35
36
LOS0
MODE1
LOS3
RDN3
RDP3
LOS0
MODE1
LOS3
RDN3
RDP3
O
I
O
O
O
Controls pin RDP3, RDN3 and RCLK3.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
37
HZEN3
N/A
-
38
39
40
41
42
43
44
RCLK3
TDN3
TDP3
TCLK3
LOS2
RDN2
RDP2
RCLK3
TDN3
TDP3
TCLK3
LOS2
RDN2
RDP2
O
I
I
I
O
O
O
Controls pin RDP2, RDN2 and RCLK2.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
45
HZEN2
N/A
-
46
47
48
49
50
51
RCLK2
TDN2
TDP2
TCLK2
INT
RCLK2
TDN2
TDP2
TCLK2
INT
O
I
I
I
O
O
ACK
ACK
Control pin ACK.
When ‘0’, the output is enabled on pin ACK.
When ‘1’, the pin is high-Z.
52
SDORDYS
N/A
-
53
54
55
56
WRB
RDB
ALE
DS
R/W
ALE
CS
I
I
I
I
CSB
35
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-19 Boundary Scan Register Description (Continued)
Bit No.
57
58
Bit Symbol
MODE0
TCLK5
TDP5
Pin Signal
MODE0
TCLK5
TDP5
Type
I
I
Comments
59
I
60
TDN5
TDN5
I
61
62
63
RCLK5
RDP5
RDN5
RCLK5
RDP5
RDN5
O
O
O
Controls pin RDP5, RDN5 and RCLK5.
64
HZEN5
N/A
-
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
65
66
67
68
69
70
71
LOS5
TCLK4
TDP4
TDN4
RCLK4
RDP4
RDN4
LOS5
TCLK4
TDP4
TDN4
RCLK4
RDP4
RDN4
O
I
I
I
O
O
O
Controls pin RDP4, RDN4 and RCLK4.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
72
HZEN4
N/A
-
73
74
75
76
77
78
LOS4
OE
CLKE
LOS7
RDN7
RDP7
LOS4
OE
CLKE
LOS7
RDN7
RDP7
O
I
I
O
O
O
Controls pin RDP7, RDN7 and RCLK7.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
79
HZEN7
N/A
-
80
81
82
83
84
85
86
RCLK7
TDN7
TDP7
TCLK7
LOS6
RDN6
RDP6
RCLK7
TDN7
TDP7
TCLK7
LOS6
RDN6
RDP6
O
I
I
I
O
O
O
Controls pin RDP6, RDN6 and RCLK6.
When ‘0’, the outputs are enabled on the pins.
When ‘1’, the pins are high-Z.
87
HZEN6
N/A
-
88
89
90
91
92
93
94
95
96
97
98
RCLK6
TDN6
TDP6
TCLK6
MCLK
MODE2
A4
A3
A2
A1
A0
RCLK6
TDN6
TDP6
TCLK6
MCLK
MODE2
A4
A3
A2
A1
A0
O
I
I
I
I
I
I
I
I
I
I
36
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
instruction registers. The value shown next to each state transition in
this figure states the value present at TMS at each rising edge of TCK.
Refer to Table-20 for details of the state description.
4.3 TEST ACCESS PORT CONTROLLER
The TAP controller is a 16-state synchronous state machine. Figure-
22 shows its state diagram A description of each state follows. Note that
the figure contains two main branches to access either the data or
Table-20 TAP Controller State Description
State
Description
In this state, the test logic is disabled. The device is set to normal operation. During initialization, the device initializes the instruction register
with the IDCODE instruction.
Regardless of the original state of the controller, the controller enters the Test-Logic-Reset state when the TMS input is held high for at least 5
rising edges of TCK. The controller remains in this state while TMS is high. The device processor automatically enters this state at power-up.
Test Logic Reset
Run-Test/Idle
This is a controller state between scan operations. Once in this state, the controller remains in the state as long as TMS is held low. The
instruction register and all test data registers retain their previous state. When TMS is high and a rising edge is applied to TCK, the controller
moves to the Select-DR state.
This is a temporary controller state and the instruction does not change in this state. The test data register selected by the current instruction
retains its previous state. If TMS is held low and a rising edge is applied to TCK when in this state, the controller moves into the Capture-DR
state and a scan sequence for the selected test data register is initiated. If TMS is held high and a rising edge applied to TCK, the controller
moves to the Select-IR-Scan state.
Select-DR-Scan
In this state, the Boundary Scan Register captures input pin data if the current instruction is EXTEST or SAMPLE/PRELOAD. The instruction
does not change in this state. The other test data registers, which do not have parallel input, are not changed. When the TAP controller is in
this state and a rising edge is applied to TCK, the controller enters the Exit1-DR state if TMS is high or the Shift-DR state if TMS is low.
Capture-DR
Shift-DR
In this controller state, the test data register connected between TDI and TDO as a result of the current instruction shifts data on stage toward
its serial output on each rising edge of TCK. The instruction does not change in this state. When the TAP controller is in this state and a rising
edge is applied to TCK, the controller enters the Exit1-DR state if TMS is high or remains in the Shift-DR state if TMS is low.
This is a temporary state. While in this state, if TMS is held high, a rising edge applied to TCK causes the controller to enter the Update-DR
state, which terminates the scanning process. If TMS is held low and a rising edge is applied to TCK, the controller enters the Pause-DR
state. The test data register selected by the current instruction retains its previous value and the instruction does not change during this state.
Exit1-DR
The pause state allows the test controller to temporarily halt the shifting of data through the test data register in the serial path between TDI
and TDO. For example, this state could be used to allow the tester to reload its pin memory from disk during application of a long test
sequence. The test data register selected by the current instruction retains its previous value and the instruction does not change during this
state. The controller remains in this state as long as TMS is low. When TMS goes high and a rising edge is applied to TCK, the controller
moves to the Exit2-DR state.
Pause-DR
Exit2-DR
This is a temporary state. While in this state, if TMS is held high, a rising edge applied to TCK causes the controller to enter the Update-DR
state, which terminates the scanning process. If TMS is held low and a rising edge is applied to TCK, the controller enters the Shift-DR state.
The test data register selected by the current instruction retains its previous value and the instruction does not change during this state.
The Boundary Scan Register is provided with a latched parallel output to prevent changes while data is shifted in response to the EXTEST
and SAMPLE/PRELOAD instructions. When the TAP controller is in this state and the Boundary Scan Register is selected, data is latched into
the parallel output of this register from the shift-register path on the falling edge of TCK. The data held at the latched parallel output changes
only in this state. All shift-register stages in the test data register selected by the current instruction retain their previous value and the instruc-
tion does not change during this state.
Update-DR
This is a temporary controller state. The test data register selected by the current instruction retains its previous state. If TMS is held low and
a rising edge is applied to TCK when in this state, the controller moves into the Capture-IR state, and a scan sequence for the instruction reg-
ister is initiated. If TMS is held high and a rising edge is applied to TCK, the controller moves to the Test-Logic-Reset state. The instruction
does not change during this state.
Select-IR-Scan
Capture-IR
Shift-IR
In this controller state, the shift register contained in the instruction register loads a fixed value of ‘100’ on the rising edge of TCK. This sup-
ports fault-isolation of the board-level serial test data path. Data registers selected by the current instruction retain their value and the instruc-
tion does not change during this state. When the controller is in this state and a rising edge is applied to TCK, the controller enters the Exit1-
IR state if TMS is held high, or the Shift-IR state if TMS is held low.
In this state, the shift register contained in the instruction register is connected between TDI and TDO and shifts data one stage towards its
serial output on each rising edge of TCK. The test data register selected by the current instruction retains its previous value and the instruction
does not change during this state. When the controller is in this state and a rising edge is applied to TCK, the controller enters the Exit1-IR
state if TMS is held high, or remains in the Shift-IR state if TMS is held low.
37
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
Table-20 TAP Controller State Description (Continued)
State
Description
This is a temporary state. While in this state, if TMS is held high, a rising edge applied to TCK causes the controller to enter the Update-IR
state, which terminates the scanning process. If TMS is held low and a rising edge is applied to TCK, the controller enters the Pause-IR state.
The test data register selected by the current instruction retains its previous value and the instruction does not change during this state.
Exit1-IR
The pause state allows the test controller to temporarily halt the shifting of data through the instruction register. The test data register selected
by the current instruction retains its previous value and the instruction does not change during this state. The controller remains in this state as
long as TMS is low. When TMS goes high and a rising edge is applied to TCK, the controller moves to the Exit2-IR state.
Pause-IR
Exit2-IR
This is a temporary state. While in this state, if TMS is held high, a rising edge applied to TCK causes the controller to enter the Update-IR
state, which terminates the scanning process. If TMS is held low and a rising edge is applied to TCK, the controller enters the Shift-IR state.
The test data register selected by the current instruction retains its previous value and the instruction does not change during this state.
The instruction shifted into the instruction register is latched into the parallel output from the shift-register path on the falling edge of TCK.
When the new instruction has been latched, it becomes the current instruction. The test data registers selected by the current instruction
retain their previous value.
Update-IR
1
Test-logic Reset
0
0
1
1
1
Run Test/Idle
Select-DR
0
Select-IR
0
1
1
Capture-DR
0
Capture-IR
0
0
0
Shift-DR
1
Shift-IR
1
1
1
0
Exit1-DR
0
Exit1-IR
0
0
Pause-DR
1
Pause-IR
1
0
0
Exit2-DR
1
Exit2-IR
1
Update-DR
Update-IR
0
0
1
1
Figure-22 JTAG State Diagram
38
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
ABSOLUTE MAXIMUM RATING
Symbol
Parameter
Min
Max
Unit
VDDA, VDDD
VDDIO0, VDDIO1
VDDT0-7
-0.5
-0.5
4.0
4.0
7.0
5.5
V
V
V
V
Core Power Supply
I/O Power Supply
-0.5
Transmit Power Supply
GND-0.5
Input Voltage, any digital pin
VDDA+ 0.5
VDDD+ 0.5
V
V
Input Voltage(1), RTIPn pins and RRINGn pins
GND-0.5
2000
Vin
ESD Voltage, any pin(2)
V
Transient Latch-up Current, any pin
100
10
mA
mA
mA
W
-10
Iin
Input Current, any digital pin(3)
DC Input Current, any analog pin(3)
Maximum Power Dissipation in package
Case Temperature
±100
1.6
Pd
Tc
Ts
120
+150
°C
°C
-65
Storage Temperature
CAUTION: Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied. Exposure to absolute maximum rat-
ing conditions for extended periods may affect device reliability.
1. Referenced to ground
2. Human body model
3. Constant input current
RECOMMENDED OPERATING CONDITIONS
Symbol
Parameter
Min
Typ
Max
Unit
VDDA, VDDD
VDDIO
3.13
3.13
3.3
3.3
3.47
3.47
V
V
Core Power Supply
I/O Power Supply
Transmitter Supply
3.3 V
VDDT
3.13
4.75
-40
3.3
5.0
25
3.47
5.25
85
V
V
5 V
TA
RL
°C
W
Ambient Operating Temperature
25
Output load at TTIPn pins and TRINGn pins
Average Core Power Supply Current(1)
I/O Power Supply Current(2)
IVDD
IVDDIO
IVDDT
40
15
60
25
mA
mA
Average transmitter power supply current, E1 mode(1), (3)
125
220
100
200
mA
mA
mA
mA
75 Ω
50% ones density data:
100% ones density data:
50% ones density data:
100% ones density data:
120 Ω
1. Maximum power and current consumption over the full operating temperature and power supply voltage range. Includes all channels.
2. Digital output is driving 50 pF load, digital input is within 10% of the supply rails.
3. Power consumption includes power absorbed by line load and external transmitter components.
39
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
POWER CONSUMPTION
Symbol
Parameter
Min
Typ
Max(1)(2)
Unit
E1, 3.3 V, 75 Ω Load
50% ones density data:
100% ones density data:
-
-
612
1050
-
mW
mW
1125
E1, 3.3 V, 120 Ω Load
50% ones density data:
-
-
526
880
-
mW
mW
100% ones density data:
940
E1, 5.0 V, 75 Ω Load
50% ones density data:
100% ones density data:
-
-
835
1510
-
mW
mW
1610
E1, 5.0 V, 120 Ω Load
50% ones density data:
100% ones density data:
-
-
710
1240
-
mW
mW
1330
1. Maximum power and current consumption over the full operating temperature and power supply voltage range. Includes all channels.
2. Power consumption includes power absorbed by line load and external transmitter components.
DC CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
VIL
Input Low Level Voltage
1
3
-- VDDIO-0.2
V
V
MODE2, JAS and LPn pins
All other digital inputs pins
0.8
VIM
VIH
Input Mid Level Voltage
MODE2, JAS and LPn pins
Input High Voltage
2
1
3
1
--
-- VDDIO+0.2
-- VDDIO
2
3 VDDIO-0.2
V
2
--
3 VDDIO+ 0.2
MODE2, JAS and LPn pins
V
2.0
All other digital inputs pins
Output Low level Voltage(1) (Iout = 1.6 mA)
V
V
VOL
VOH
0.4
Output High level Voltage(1) (Iout = 400 µA)
2.4
VDDIO
V
VMA
IH
Analog Input Quiescent Voltage (RTIPn/RRINGn pin while floating)
Input High Level Current (MODE2, JAS and LPn pin)
Input Low Level Current (MODE2, JAS and LPn pin)
1.33
1.4
1.47
50
V
µA
µA
IL
50
II
Input Leakage Current
TMS, TDI and TRST pins
All other digital input pins
50
10
µA
µA
-10
-10
150
IZL
High-Z Leakage Current
10
µA
kΩ
ZOH
Output High-Z on TTIPn pins and TRINGn pins
1. Output drivers will output CMOS logic levels into CMOS loads.
40
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
TRANSMITTER CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Output Pulse Amplitudes(1)
75 Ω load
Vo-p
2.14
2.7
2.37
3.0
2.6
3.3
V
V
120 Ω load
Vo-s
Zero (space) Level
75 Ω load
-0.237
-0.3
0.237
0.3
V
V
120 Ω load
-1
+1
%
mV
ns
Transmit Amplitude Variation with supply
200
256
1.05
Difference between pulse sequences for 17 consecutive pulses
Output Pulse Width at 50% of nominal amplitude
Ratio of the amplitudes of Positive and Negative Pulses at the center of the pulse interval
Transmit Return Loss(2)
TPW
RTX
232
244
0.95
15
15
15
dB
dB
dB
51 kHz – 102 kHz
102 kHz – 2.048 MHz
2.048 MHz – 3.072 MHz
75 Ω
15
15
15
dB
dB
dB
51 kHz – 102 kHz
102 kHz – 2.048 MHz
2.048 MHz – 3.072 MHz
120 Ω
JTXP-P
Td
Intrinsic Transmit Jitter (TCLK is jitter free, JA enabled)
20 Hz – 100 kHz
0.050
U.I.
Transmit Path Delay (JA is disabled)
8
3
U.I.
U.I.
Single Rail
Dual Rail
Line Short Circuit Current(3)
ISC
180
mAp
1. Measured at the line output ports
2. Test at IDT82V2058 evaluation board
3. Measured on device, between TTIPn and TRINGn
41
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
RECEIVER CHARACTERISTICS
Symbol
Parameter
Permissible Cable Attenuation (@1024 kHz)
Min
Typ
Max
Unit
ATT
IA
15
dB
Vp
dB
%
Input Amplitude
0.1
-15
0.9
Signal to Interference Ratio Margin(1)
Data Decision Threshold (refer to peak input voltage)
Data Slicer Threshold
SIR
SRE
50
150
mV
Analog Loss Of Signal(2)
Declare/Clear:
120/150
12.5
200/250
280/350
0.0625
mVp
Allowable consecutive zeros before LOS
G.775:
ETSI 300 233:
LOS Reset
Clock Recovery Mode
32
2048
% ones
U.I.
JRXp-p
JTRX
Peak to Peak Intrinsic Receive Jitter (JA disabled)
Jitter Tolerance
1 Hz – 20 Hz
20 Hz – 2.4 kHz
18 kHz – 100 kHz
18.0
1.5
0.2
U.I.
U.I.
U.I.
kΩ
ZDM
ZCM
RRX
Receiver Differential Input Impedance
120
Receiver Common Mode Input Impedance to GND
10
kΩ
Receive Return Loss
51 kHz – 102 kHz
20
20
20
dB
dB
dB
102 kHz – 2.048 MHz
2.048 MHz – 3.072 MHz
Receive Path Delay
Dual rail
3
8
U.I.
U.I.
Single rail
1. Per G.703, O.151 @ 6 dB cable attenuation
2. Measured on device, between RTIP and RRING, all ones signal.
JITTER ATTENUATOR CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
f-3dB
Jitter Transfer Function Corner Frequency (–3 dB)
Host mode: 32/64 bit FIFO
JABW = 0:
1.7
6.6
1.7
Hz
Hz
Hz
JABW = 1:
Hardware mode
Jitter Attenuator(1)
-0.5
-0.5
+19.5
+19.5
dB
dB
dB
dB
@ 3 Hz
@ 40 Hz
@ 400 Hz
@ 100 kHz
td
Jitter Attenuator Latency Delay
16
32
U.I.
U.I.
32 bit FIFO:
64 bit FIFO:
Input Jitter Tolerance before FIFO Overflow Or Underflow
32 bit FIFO:
64 bit FIFO:
Output Jitter in Remote Loopback(2)
28
56
U.I.
U.I.
U.I.
0.11
1. Per G.736, see Figure-38 on page 52.
2. Per ETSI CTR12/13 output jitter.
42
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
TRANSCEIVER TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
2.048
MHz
ppm
%
MCLK Frequency
MCLK Tolerance
MCLK Duty Cycle
-100
40
100
60
Transmit path
2.048
MHz
ppm
%
TCLK Frequency
-50
10
40
40
+50
90
TCLK Tolerance
TCLK Duty Cycle
t1
t2
ns
Transmit Data Setup Time
Transmit Data Hold Time
ns
1
µs
Delay Time of OE Low to Driver High-Z
Delay Time of TCLK Low to Driver High-Z
40
44
48
µs
Receive path
Clock Recovery Capture Range(1)
RCLK Duty Cycle(2)
RCLK Pulse Width(2)
± 80
50
ppm
%
40
457
203
203
5
60
519
285
285
30
t4
t5
t6
488
244
244
ns
ns
ns
ns
ns
ns
ns
RCLK Pulse Width Low Time
RCLK Pulse Width High Time
Rise/Fall Time(3)
t7
t8
t9
200
200
200
244
244
244
Receive Data Setup Time
Receive Data Hold Time
RDPn/RDNn Pulse Width (MCLK = High)(4)
1.
Relative to nominal frequency, MCLK = ± 100 ppm
2. RCLK duty cycle widths will vary depending on extent of received pulse jitter displacement. Maximum and minimum RCLK duty cycles are for worst case jitter conditions (0.2 UI dis-
placement for E1 per ITU G.823).
3.
For all digital outputs. C load = 15 pF
4. Clock recovery is disabled in this mode.
43
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
TCLKn
t1
t2
TDn/TDPn
BPVIn/TDNn
Figure-23 Transmit System Interface Timing
t4
RCLKn
t6
t7
t5
t8
RDn/RDPn
(CLKE = 1)
CVn/RDNn
t7
t8
RDn/RDPn
(CLKE = 0)
CVn/RDNn
Figure-24 Receive System Interface Timing
44
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
JTAG TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Comments
t1
t2
200
ns
TCK Period
TMS to TCK setup Time
TDI to TCK Setup Time
50
50
ns
t3
t4
TCK to TMS Hold Time
TCK to TDI Hold Time
ns
ns
100
TCK to TDO Delay Time
t1
TCK
t2
t3
TMS
TDI
t4
TDO
Figure-25 JTAG Interface Timing
45
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
PARALLEL HOST INTERFACE TIMING CHARACTERISTICS
INTEL MODE READ TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Comments
(1)
t1
t2
Active RD Pulse Width
Active CS to Active RD Setup Time
Inactive RD to Inactive CS Hold Time
Valid Address to Inactive ALE Setup Time (in Multiplexed Mode)
Invalid RD to Address Hold Time (in Non-Multiplexed Mode)
Active RD to Data Output Enable Time
Inactive RD to Data High-Z Delay Time
Active CS to RDY delay time
Inactive CS to RDY High-Z Delay Time
Inactive RD to Inactive INT Delay Time
Address Latch Enable Pulse Width (in Multiplexed Mode)
Address Latch Enable to RD Setup Time (in Multiplexed Mode)
Address Setup time to Valid Data Time (in Non-Multiplexed Mode)
Inactive RD to Active RDY Delay Time
Active RD to Active RDY Delay Time
Inactive ALE to Address Hold Time (in Multiplexed Mode)
90
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
t3
0
t4
5
t5
0
t6
7.5
7.5
6
15
15
12
12
20
t7
t8
t9
6
t10
t11
t12
t13
t14
t15
t16
10
0
18
10
30
5
32
15
85
1. The t1 is determined by the start time of the valid data when the RDY signal is not used.
46
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
t2
t3
CS
t1
RD
ALE(=1)
t13
t5
ADDRESS
A[4:0]
t6
t7
DATA OUT
D[7:0]
t14
t8
t9
RDY
t15
t10
INT
Figure-26 Non-Multiplexed Intel Mode Read Timing
t2
t3
CS
RD
t1
t11
t4
t12
t13
ALE
t16
t6
t7
ADDRESS
DATA OUT
AD[7:0]
t14
t8
t9
RDY
t15
t10
INT
Figure-27 Multiplexed Intel Mode Read Timing
47
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
INTEL MODE WRITE TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Comments
(1)
t1
t2
Active WR Pulse Width
Active CS to Active WR Setup Time
Inactive WR to Inactive CS Hold Time
Valid Address to Latch Enable Setup Time (in Multiplexed Mode)
Invalid WR to Address Hold Time (in Non-Multiplexed Mode)
Valid Data to Inactive WR Setup Time
Inactive WR to Data Hold Time
Active CS to Inactive RDY Delay Time
Active WR to Active RDY Delay Time
Inactive WR to Inactive RDY Delay Time
Invalid CS to RDY High-Z Delay Time
Address Latch Enable Pulse Width (in Multiplexed Mode)
Inactive ALE to WR Setup Time (in Multiplexed Mode)
Inactive ALE to Address hold time (in Multiplexed Mode)
Address setup time to Inactive WR time (in Non-Multiplexed Mode)
90
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
t3
0
t4
5
t5
2
t6
5
t7
10
6
t8
12
85
15
12
t9
30
10
6
t10
t11
t12
t13
t14
t15
10
0
5
5
1. The t1 can be 15 ns when RDY signal is not used.
CS
t2
t1
t3
WR
ALE(=1)
t15
ADDRESS
t5
A[4:0]
D[7:0]
t6
t7
WRITE DATA
t10
t8
t11
RDY
t9
Figure-28 Non-Multiplexed Intel Mode Write Timing
t2
t3
CS
t1
WR
t12
t4
t13
ALE
t14
t6
t7
ADDRESS
t8
WRITE DATA
AD[7:0]
RDY
t11
t9
t10
Figure-29 Multiplexed Intel Mode Write Timing
48
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
MOTOROLA MODE READ TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Comments
(1)
t1
t2
Active DS Pulse Width
Active CS to Active DS Setup Time
Inactive DS to Inactive CS Hold Time
Valid R/W to Active DS Setup Time
90
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
t3
0
t4
0
t5
Inactive DS to R/W Hold Time
0.5
5
t6
Valid Address to Active DS Setup Time (in Non-Multiplexed Mode)
Active DS to Address Hold Time (in Non-Multiplexed Mode)
Active DS to Data Valid Delay Time (in Non-Multiplexed Mode)
Active DS to Data Output Enable Time
Inactive DS to Data High-Z Delay Time
Active DS to Active ACK Delay Time
Inactive DS to Inactive ACK Delay Time
Inactive DS to Invalid INT Delay Time
Active AS to Active DS Setup Time (in Multiplexed Mode)
t7
10
20
7.5
7.5
30
10
t8
35
15
15
85
15
20
t9
t10
t11
t12
t13
t14
5
1. The t1 is determined by the start time of the valid data when the ACK signal is not used.
CS
t4
t5
t3
R/W
t2
t1
DS
ALE(=1)
t6
t7
ADDRESS
A[4:0]
D[7:0]
t10
t8
t9
DATA OUT
t12
ACK
INT
t11
t13
Figure-30 Non-Multiplexed Motorola Mode Read Timing
CS
t2
t4
t14
t3
t5
R/W
t1
DS
AS
t8
t9
t10
t6
t7
ADDRESS
t11
DATA OUT
AD[7:0]
t12
ACK
INT
t13
Figure-31 Multiplexed Motorola Mode Read Timing
49
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
MOTOROLA MODE WRITE TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Comments
(1)
t1
t2
Active DS Pulse Width
90
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Active CS to Active DS Setup Time
Inactive DS to Inactive CS Hold Time
Valid R/W to Active DS Setup Time
Inactive DS to R/W Hold Time
Valid Address to Active DS Setup Time (in Non-Multiplexed Mode)
Valid DS to Address Hold Time (in Non-Multiplexed Mode)
Valid Data to Inactive DS Setup Time
Inactive DS to Data Hold Time
Active DS to Active ACK Delay Time
Inactive DS to Inactive ACK Delay Time
Active AS to Active DS (in Multiplexed Mode)
Inactive DS to Inactive AS Hold Time ( in Multiplexed Mode)
t3
0
t4
10
0
t5
t6
10
10
5
t7
t8
t9
10
30
10
0
t10
t11
t12
t13
85
15
15
1. The t1 can be 15ns when the ACK signal is not used.
CS
t4
t5
t3
R/W
t2
t1
DS
ALE(=1)
t6
t7
ADDRESS
A[4:0]
D[7:0]
t8
t9
WRITE DATA
t11
t10
ACK
Figure-32 Non-Multiplexed Motorola Mode Write Timing
CS
t2
t4
t3
t5
t13
R/W
t1
DS
t12
AS
t8
t9
t6
t7
ADDRESS
WRITE DATA
AD[7:0]
t10
t11
ACK
Figure-33 Multiplexed Motorola Mode Writing Timing
50
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
SERIAL HOST INTERFACE TIMING CHARACTERISTICS
Symbol
Parameter
Min
Typ
Max
Unit
Comments
t1
t2
SCLK High Time
25
25
10
50
50
5
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
SCLK Low Time
t3
Active CS to SCLK Setup Time
Last SCLK Hold Time to Inactive CS Time
CS Idle Time
t4
t5
t6
SDI to SCLK Setup Time
t7
SCLK to SDI Hold Time
5
t8
Rise/Fall Time (any pin)
100
50
t9
SCLK Rise and Fall Time
SCLK to SDO Valid Delay Time
t10
t11
25
35
Load = 50 pF
SCLK Falling Edge to SDO High-Z Hold Time (CLKE = 0) or CS Rising
Edge to SDO High-Z Hold Time (CLKE = 1)
100
ns
CS
t4
t5
t3 t1
t2
SCLK
SDI
t6
t7
t7
MSB
LSB
LSB
CONTROL BYTE
DATA BYTE
Figure-34 Serial Interface Write Timing
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
SCLK
t10
t4
CS
t11
SDO
0
1
2
3
4
5
6
7
Figure-35 Serial Interface Read Timing with CLKE = 0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
5
15
16
t4
SCLK
CS
t10
t11
SDO
0
1
2
3
4
6
7
Figure-36 Serial Interface Read Timing with CLKE = 1
51
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
JITTER TOLERANCE PERFORMANCE
3
1 10
100
18 UI @ 1.8 Hz
G.823
10
IDT82V2058
1.5 UI @ 20 Hz
1
1.5 UI @ 2.4
kHz
0.2 UI @ 18 kHz
0.1
3
4
5
1
10
100
1 10
1 10
1 10
Frequency (Hz)
Test condition: PRBS 2^15-1; Line code rule HDB3 is used.
Figure-37 Jitter Tolerance Performance
JITTER TRANSFER PERFORMANCE
0.5 dB @ 3 Hz
0
0.5 dB @ 40 Hz
-19.5 dB @
400 Hz
-20
-19.5 dB @ 20 kHz
G.736
f3dB = 6.5 Hz
IDT82V2058
-40
-60
f3dB = 1.7 Hz
3
4
5
1
10
100
110
1 10
1 10
Frequency (Hz)
Test condition: PRBS 2^15-1; Line code rule HDB3 is used.
Figure-38 Jitter Transfer Performance
52
IDT82V2058 OCTAL E1 SHORT HAUL LINE INTERFACE UNIT
INDUSTRIAL TEMPERATURE RANGES
ORDERING INFORMATION
XXXXXXX
Device Type
XX
Package
X
Process/
Temperature
Range
Industrial (-40 °C to +85 °C)
Blank
BB
Plastic Ball Grid Array (PBGA, BB160)
BBG Green Plastic Ball Grid Array (PBGA, BBG160)
DA Thin Quad Flatpack (TQFP, DA144)
DAG Green Thin Quad Flatpack (TQFP, DAG144)
82V2058 E1 Short Haul LIU
DATASHEET DOCUMENT HISTORY
11/04/2001
11/20/2001
11/28/2001
11/29/2001
12/05/2001
01/24/2002
02/21/2002
03/25/2002
04/17/2002
05/07/2002
01/15/2003
04/12/2005
09/14/2009
01/21/2010
pgs. 2, 3, 10, 17
pgs. 5, 6, 11, 13, 16, 17, 24, 26, 31, 38, 39, 40, 50
pgs. 5, 24, 26, 31
pgs. 5
pgs. 9
pgs. 2, 3, 9, 14, 39, 40
pgs. 14, 16, 41
pgs. 1, 2, 52
pgs. 17
pgs. 14, 44, 45, 48
pgs. 1, 52
pgs. 1, 5 to 8, 10, 11, 14, 15, 18, 19, 29, 30, 40 to 43, 47 to 53
pg. 40
pg. 8
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IDT and the IDT logo are trademarks of Integrated Device Technology, Inc.
53
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