SCAN921025HSMX/NOPB [TI]

具有 IEEE 1149.1 测试访问的高温 20 至 80MHz 10 位串行器 | NZA | 49 | -40 to 125;


型号：	SCAN921025HSMX/NOPB
厂家：	TEXAS INSTRUMENTS
描述：	具有 IEEE 1149.1 测试访问的高温 20 至 80MHz 10 位串行器 \| NZA \| 49 \| -40 to 125 驱动测试接口集成电路驱动器
文件：	总30页 (文件大小：1042K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SCAN921025H, SCAN921226H

www.ti.com

SNLS185C –OCTOBER 2004–REVISED MAY 2013

SCAN921025H and SCAN921226H High Temperature 20-80 MHz 10 Bit Bus LVDS SerDes

with IEEE 1149.1 (JTAG) and at-speed BIST

Check for Samples: SCAN921025H, SCAN921226H

FEATURES

DESCRIPTION

The SCAN921025H transforms a 10-bit wide parallel

LVCMOS/LVTTL data bus into a single high speed

Bus LVDS serial data stream with embedded clock.

The SCAN921226H receives the Bus LVDS serial

data stream and transforms it back into a 10-bit wide

parallel data bus and recovers parallel clock.

•

High Temperature Operation to 125°C

•

IEEE 1149.1 (JTAG) Compliant and At-Speed

BIST Test Mode

•

Clock Recovery from PLL Lock to Random

Data Patterns

•

Ensured Transition Every Data Transfer Cycle

Both devices are compliant with IEEE 1149.1

Standard for Boundary Scan Test. IEEE 1149.1

features provide the design or test engineer access

via a standard Test Access Port (TAP) to the

backplane or cable interconnects and the ability to

verify differential signal integrity. The pair of devices

also features an at-speed BIST mode which allows

the interconnects between the Serializer and

Deserializer to be verified at-speed.

Chipset (Tx + Rx) Power Consumption < 600

mW (Typ) @ 80 MHz

•

Single Differential Pair Eliminates Multi-

Channel Skew

800 Mbps Serial Bus LVDS Data Rate (at 80

MHz Clock)

10-bit Parallel Interface for 1 Byte Data Plus 2

Control Bits

The SCAN921025H transmits data over backplanes

or cable. The single differential pair data path makes

PCB design easier. In addition, the reduced cable,

PCB trace count, and connector size tremendously

reduce cost. Since one output transmits clock and

data bits serially, it eliminates clock-to-data and data-

to-data skew. The powerdown pin saves power by

reducing supply current when not using either device.

Upon power up of the Serializer, you can choose to

activate synchronization mode or allow the

Deserializer to use the synchronization-to-random-

data feature. By using the synchronization mode, the

Deserializer will establish lock to a signal within

specified lock times. In addition, the embedded clock

ensures a transition on the bus every 12-bit cycle.

This eliminates transmission errors due to charged

cable conditions. Furthermore, you may put the

SCAN921025H output pins into tri-state to achieve a

high impedance state. The PLL can lock to

frequencies between 20 MHz and 80 MHz.

•

Synchronization Mode and LOCK Indicator

Programmable Edge Trigger on Clock

High Impedance on Receiver Inputs When

Power is Off

•

Bus LVDS Serial Output Rated for 27Ω Load

Small 49-Lead NFBGA Package

APPLICATIONS

•

Automotive

Industrial

Military/Aerospace

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of

Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

All trademarks are the property of their respective owners.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

SCAN921025H, SCAN921226H

SNLS185C –OCTOBER 2004–REVISED MAY 2013

www.ti.com

Block Diagram

Figure 1. Application

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SNLS185C –OCTOBER 2004–REVISED MAY 2013

Functional Description

The SCAN921025H and SCAN921226H are a 10-bit Serializer and Deserializer chipset designed to transmit

data over differential backplanes at clock speeds from 20 to 80 MHz. The chipset is also capable of driving data

over Unshielded Twisted Pair (UTP) cable.

The chipset has three active states of operation: Initialization, Data Transfer, and Resynchronization; and two

passive states: Powerdown and Tri-state. In addition to the active and passive states, there are also test modes

for JTAG access and at-speed BIST.

The following sections describe each operation and passive state and the test modes.

Initialization

Initialization of both devices must occur before data transmission begins. Initialization refers to synchronization of

the Serializer and Deserializer PLL's to local clocks, which may be the same or separate. Afterwards,

synchronization of the Deserializer to Serializer occurs.

Step 1: When you apply V_CCto both Serializer and/or Deserializer, the respective outputs enter tri-state, and on-

chip power-on circuitry disables internal circuitry. When V_CCreaches V_CCOK (2.5V) the PLL in each device

begins locking to a local clock. For the Serializer, the local clock is the transmit clock (TCLK) provided by the

source ASIC or other device. For the Deserializer, you must apply a local clock to the REFCLK pin.

The Serializer outputs remain in tri-state while the PLL locks to the TCLK. After locking to TCLK, the Serializer is

now ready to send data or SYNC patterns, depending on the levels of the SYNC1 and SYNC2 inputs or a data

stream. The SYNC pattern sent by the Serializer consists of six ones and six zeros switching at the input clock

rate.

Note that the Deserializer LOCK output will remain high while its PLL locks to the incoming data or to SYNC

patterns on the input.

Step 2: The Deserializer PLL must synchronize to the Serializer to complete initialization. The Deserializer will

lock to non-repetitive data patterns. However, the transmission of SYNC patterns enables the Deserializer to lock

to the Serializer signal within a specified time. See Figure 17.

The user's application determines control of the SYNC1 and SYNC 2 pins. One recommendation is a direct

feedback loop from the LOCK pin. Under all circumstances, the Serializer stops sending SYNC patterns after

both SYNC inputs return low.

When the Deserializer detects edge transitions at the Bus LVDS input, it will attempt to lock to the embedded

clock information. When the Deserializer locks to the Bus LVDS clock, the LOCK output will go low. When LOCK

is low, the Deserializer outputs represent incoming Bus LVDS data.

Data Transfer

After initialization, the Serializer will accept data from inputs DIN0–DIN9. The Serializer uses the TCLK input to

latch incoming Data. The TCLK_R/F pin selects which edge the Serializer uses to strobe incoming data.

TCLK_R/F high selects the rising edge for clocking data and low selects the falling edge. If either of the SYNC

inputs is high for 5*TCLK cycles, the data at DIN0-DIN9 is ignored regardless of clock edge.

After determining which clock edge to use, a start and stop bit, appended internally, frame the data bits in the

embedded clock bits in the serial stream.

The Serializer transmits serialized data and clock bits (10+2 bits) from the serial data output (DO±) at 12 times

the TCLK frequency. For example, if TCLK is 80 MHz, the serial rate is 80 × 12 = 960 Mega-bits-per-second.

Since only 10 bits are from input data, the serial “payload” rate is 10 times the TCLK frequency. For instance, if

TCLK = 80 MHz, the payload data rate is 80 × 10 = 800 Mbps. The data source provides TCLK and must be in

the range of 20 MHz to 80 MHz nominal.

The Serializer outputs (DO±) can drive a point-to-point connection or in limited multi-point or multi-drop

backplanes. The outputs transmit data when the enable pin (DEN) is high, PWRDN = high, and SYNC1 and

SYNC2 are low. When DEN is driven low, the Serializer output pins will enter tri-state.

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When the Deserializer synchronizes to the Serializer, the LOCK pin is low. The Deserializer locks to the

embedded clock and uses it to recover the serialized data. ROUT data is valid when LOCK is low. Otherwise

ROUT0–ROUT9 is invalid.

The ROUT0-ROUT9 pins use the RCLK pin as the reference to data. The polarity of the RCLK edge is controlled

by the RCLK_R/F input. See Figure 14.

ROUT(0-9), LOCK and RCLK outputs will drive a maximum of three CMOS input gates (15 pF load) with a 80

MHz clock.

Resynchronization

When the Deserializer PLL locks to the embedded clock edge, the Deserializer LOCK pin asserts a low. If the

Deserializer loses lock, the LOCK pin output will go high and the outputs (including RCLK) will enter tri-state.

The user's system monitors the LOCK pin to detect a loss of synchronization. Upon detection, the system can

arrange to pulse the Serializer SYNC1 or SYNC2 pin to resynchronize. Multiple resynchronization approaches

are possible. One recommendation is to provide a feedback loop using the LOCK pin itself to control the sync

request of the Serializer (SYNC1 or SYNC2). Dual SYNC pins are provided for multiple control in a multi-drop

application. Sending sync patterns for resynchronization is desirable when lock times within a specific time are

critical. However, the Deserializer can lock to random data, which is discussed in the next section.

Random Lock Initialization and Resynchronization

The initialization and resynchronization methods described in their respective sections are the fastest ways to

establish the link between the Serializer and Deserializer. However, the SCAN921226H can attain lock to a data

stream without requiring the Serializer to send special SYNC patterns. This allows the SCAN921226H to operate

in “open-loop” applications. Equally important is the Deserializer's ability to support hot insertion into a running

backplane. In the open loop or hot insertion case, we assume the data stream is essentially random. Therefore,

because lock time varies due to data stream characteristics, we cannot possibly predict exact lock time.

However, please see Table 1 for some general random lock times under specific conditions. The primary

constraint on the “random” lock time is the initial phase relation between the incoming data and the REFCLK

when the Deserializer powers up. As described in the next paragraph, the data contained in the data stream can

also affect lock time.

If a specific pattern is repetitive, the Deserializer could enter “false lock” - falsely recognizing the data pattern as

the clocking bits. We refer to such a pattern as a repetitive multi-transition, RMT. This occurs when more than

one Low-High transition takes place in a clock cycle over multiple cycles. This occurs when any bit, except DIN

9, is held at a low state and the adjacent bit is held high, creating a 0-1 transition. In the worst case, the

Deserializer could become locked to the data pattern rather than the clock. Circuitry within the SCAN921226H

can detect that the possibility of “false lock” exists. The circuitry accomplishes this by detecting more than one

potential position for clocking bits. Upon detection, the circuitry will prevent the LOCK output from becoming

active until the potential “false lock” pattern changes. The false lock detect circuitry expects the data will

eventually change, causing the Deserializer to lose lock to the data pattern and then continue searching for clock

bits in the serial data stream. Graphical representations of RMT are shown in Figure 2. Please note that RMT

only applies to bits DIN0-DIN8.

Powerdown

When no data transfer occurs, you can use the Powerdown state. The Serializer and Deserializer use the

Powerdown state, a low power sleep mode, to reduce power consumption. The Deserializer enters Powerdown

when you drive PWRDN and REN low. The Serializer enters Powerdown when you drive PWRDN low. In

Powerdown, the PLL stops and the outputs enter tri-state, which disables load current and reduces supply

current to the milliampere range. To exit Powerdown, you must drive the PWRDN pin high.

Before valid data exchanges between the Serializer and Deserializer, you must reinitialize and resynchronize the

devices to each other. Initialization of the Serializer takes 510 TCLK cycles. The Deserializer will initialize and

assert LOCK high until lock to the Bus LVDS clock occurs.

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SNLS185C –OCTOBER 2004–REVISED MAY 2013

Tri-state

The Serializer enters tri-state when the DEN pin is driven low. This puts both driver output pins (DO+ and DO−)

into tri-state. When you drive DEN high, the Serializer returns to the previous state, as long as all other control

pins remain static (SYNC1, SYNC2, PWRDN, TCLK_R/F).

When you drive the REN pin low, the Deserializer enters tri-state. Consequently, the receiver output pins

(ROUT0–ROUT9) and RCLK will enter tri-state. The LOCK output remains active, reflecting the state of the PLL.

Table 1.

Random Lock Times for the SCAN921226H⁽¹⁾

80 MHz

Units

μs

Maximum

Mean

3.0

μs

Minimum

Conditions:

0.43

μs

PRBS 2¹⁵, V_CC= 3.3V

(1) Difference in lock times are due to different starting points in the data pattern with multiple parts.

Test Modes

In addition to the IEEE 1149.1 test access to the digital TTL pins, the SCAN921025H and SCAN921226H have

two instructions to test the LVDS interconnects. The first is EXTEST. This is implemented at LVDS levels and is

only intended as a go no-go test (e.g. missing cables). The second method is the RUNBIST instruction. It is an

"at-system-speed" interconnect test. It is executed in approximately 28mS with a system clock speed of 80MHz.

There are two bits in the RX BIST data register for notification of PASS/FAIL and TEST_COMPLETE. Pass

indicates that the BER (Bit-Error-Rate) is better than 10^-7.

An important detail is that once both devices have the RUNBIST instruction loaded into their respective

instruction registers, both devices must move into the RTI state within 4K system clocks (At a SCLK of 66Mhz

and TCK of 1MHz this allows for 66 TCK cycles). This is not a concern when both devices are on the same scan

chain or LSP, however, it can be a problem with some multi-drop devices. This test mode has been simulated

and verified using TI's SCANSTA111.

DIN0 Held Low-DIN1 Held High Creates an RMT Pattern

DIN4 Held Low-DIN5 Held High Creates an RMT Pattern

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DIN8 Held Low-DIN9 Held High Creates an RMT Pattern

Figure 2. RMT Patterns Seen on the Bus LVDS Serial Output

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

Absolute Maximum Ratings⁽¹⁾

Supply Voltage (V_CC

)

−0.3V to +4V

−0.3V to (V_CC+0.3V)

−0.3V to +3.9V

10mS

LVCMOS/LVTTL Input Voltage

LVCMOS/LVTTL Output Voltage

Bus LVDS Receiver Input Voltage

Bus LVDS Driver Output Voltage

Bus LVDS Output Short Circuit Duration

Junction Temperature

+150°C

Storage Temperature

−65°C to +150°C

+220°C

Lead Temperature

(Soldering, 4 seconds)

49L NFBGA

Maximum Package Power Dissipation Capacity

@ 25°C Package:

1.47 W

Package Derating:

49L NFBGA

11.8 mW/°C above +25°C

θ_ja

85°C/W

>2kV

HBM

ESD Rating

> 250V

(1) Absolute Maximum Ratings are those values beyond which the safety of the device cannot be ensured. They are not meant to imply that

the devices should be operated at these limits. The table of Electrical Characteristics specifies conditions of device operation.

Recommended Operating Conditions

Min

3.0

−40

Nom

3.3

Max

3.6

Units

Supply Voltage (V_CC

)

Operating Free Air Temperature (T_A)

Receiver Input Range

+25

+125

2.4

°C

Supply Noise Voltage (V_CC

)

100

mV_P-P

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SNLS185C –OCTOBER 2004–REVISED MAY 2013

Electrical Characteristics

Over recommended operating supply and temperature ranges unless otherwise specified.

Symbol

Parameter

Conditions

Min

Typ

Max

Units

SERIALIZER LVCMOS/LVTTL DC SPECIFICATIONS (apply to DIN0-9, TCLK, PWRDN, TCLK_R/F, SYNC1, SYNC2, DEN)

V_IH

V_IL

V_CL

I_IN

High Level Input Voltage

Low Level Input Voltage

Input Clamp Voltage

Input Current

2.0

V_CC

0.8

GND

I_CL= −18 mA

-0.86

±1

−1.5

+10

V_IN= 0V or 3.6V

−10

μA

DESERIALIZER LVCMOS/LVTTL DC SPECIFICATIONS (apply to pins PWRDN, RCLK_R/ F, REN, REFCLK = inputs; apply to pins

ROUT, RCLK, LOCK = outputs)

V_IH

V_IL

High Level Input Voltage

Low Level Input Voltage

Input Clamp Voltage

2.0

V_CC

0.8

GND

V_CL

I_IN

I_CL= −18 mA

−0.62

±1

−1.5

+15

V_CC

0.5

Input Current

V_IN= 0V or 3.6V

I_OH= −9 mA

−10

2.2

μA

V_OH

V_OL

I_OS

I_OZ

High Level Output Voltage

Low Level Output Voltage

Output Short Circuit Current

Tri-state Output Current

3.0

I_OL= 9 mA

GND

−15

−10

0.25

−47

±0.1

VOUT = 0V

−85

+10

μA

PWRDN or REN = 0.8V, V_OUT= 0V or VCC

SERIALIZER Bus LVDS DC SPECIFICATIONS (apply to pins DO+ and DO−)

V_OD

Output Differential Voltage

(DO+)–(DO−)

RL = 27Ω, Figure 18

200

290

ΔV_OD

V_OS

Output Differential Voltage Unbalance

Offset Voltage

1.3

1.05

1.1

4.8

ΔV_OS

I_OS

Offset Voltage Unbalance

D0 = 0V, DIN = High,PWRDN and DEN =

2.4V

Output Short Circuit Current

−56

−90

I_OZ

I_OX

Tri-state Output Current

Power-Off Output Current

PWRDN or DEN = 0.8V, DO = 0V or VCC

VCC = 0V, DO=0V or 3.6V

−10

−20

±1

+10

+30

μA

DESERIALIZER Bus LVDS DC SPECIFICATIONS (apply to pins RI+ and RI−)

VTH

VTL

I_IN

Differential Threshold High Voltage

Differential Threshold Low Voltage

−12

±1

+50

μA

VCM = +1.1V

−50

−10

V_IN= +2.4V, V_CC= 3.6V or 0V

V_IN= 0V, V_CC= 3.6V or 0V

+10

Input Current

±0.05

μA

SERIALIZER SUPPLY CURRENT (apply to pins DVCC and AVCC)

I_CCD

Serializer Supply Current

Worst Case

RL = 27Ω

f = 20 MHz

f = 80 MHz

105

2.0

Figure 3

I_CCXD

Serializer Supply Current Powerdown PWRDN = 0.8V, f = 80MHz

0.2

DESERIALIZER SUPPLY CURRENT (apply to pins DVCC and AVCC)

I_CCR

Deserializer Supply Current

Worst Case

C_L= 15 pF

Figure 4

f = 20 MHz

f = 80 MHz

100

120

I_CCXR

Deserializer Supply Current

Powerdown

PWRDN = 0.8V, REN = 0.8V

0.36

1.0

SCAN CIRCUITRY DC SPECIFICATIONS, SERIALIZER AND DESERIALIZER (applies to SCAN pins as noted)

V_IH

V_IL

V_CL

I_IH

V_CC= 3.0 to 3.6V, pins TCK, TMS, TDI, and

TRST

High Level Input Voltage

Low Level Input Voltage

Input Clamp Voltage

2.0

V_CC

0.8

V_CC= 3.0 to 3.6V, pins TCK, TMS, TDI, and

TRST

GND

V_CC= 3.0V, I_CL= −18 mA, pins TCK, TMS,

TDI, and TRST

−0.85

−1.5

+10

V_CC= 3.6V, V_IN= 3.6V, pins TCK, TMS, TDI,

and TRST

Input Current

μA

I_IL

V_CC= 3.6V, V_IN= 0.0V, TCK Input

-10

-1

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Electrical Characteristics (continued)

Over recommended operating supply and temperature ranges unless otherwise specified.

Symbol

I_ILR

Parameter

Conditions

Min

-20

2.2

Typ

Max

Units

V_CC= 3.6V, V_IN= 0V, pins TMS, TDI, and

TRST

Input Current

-10

μA

V_OH

V_OL

I_OS

High Level Output Voltage

Low Level Output Voltage

Output Short Circuit Current

Tri-state Output Current

V_CC= 3.0V, I_OH= −12 mA, TDO output

V_CC= 3.0V, I_OL= 12 mA, TDO output

V_CC= 3.6V, V_OUT= 0.0V, TDO output

PWRDN or REN = 0.8V, V_OUT= 0V or VCC

2.6

0.3

-90

0.5

-120

+10

-15

μA

I_OZ

−10

Serializer Timing Requirements for TCLK

Over recommended operating supply and temperature ranges unless otherwise specified.

Symbol

t_TCP

Parameter

Conditions

Min

12.5

0.4T

Typ

Max

Units

Transmit Clock Period

Transmit Clock High Time

Transmit Clock Low Time

TCLK Input Transition Time

50.0

0.6T

t_TCIH

t_TCIL

t_CLKT

t_JIT

0.5T

(RMS)

TCLK Input Jitter

150

Serializer Switching Characteristics

Over recommended operating supply and temperature ranges unless otherwise specified.

Symbol

Parameter

Conditions

Min

Typ

Max

Units

t_LLHT

Bus LVDS Low-to-High

Transition Time

0.2

0.4

R_L= 27Ω

C_L=10pF to GND

Figure 5⁽¹⁾

t_LHLT

Bus LVDS High-to-Low

Transition Time

0.25

0.4

t_DIS

t_DIH

DIN (0-9) Setup to TCLK R_L= 27Ω,

C_L=10pF to GND

DIN (0-9) Hold from TCLK

4.0

Figure 8

t_HZD

t_LZD

t_ZHD

t_ZLD

DO ± HIGH to

Tri-state Delay

DO ± LOW to Tri-state

Delay

R_L= 27Ω,

C_L=10pF to GND

Figure 9⁽²⁾

DO ± Tri-state to HIGH

Delay

DO ± Tri-state to LOW

Delay

6.5

t_SPW

t_PLD

t_SD

SYNC Pulse Width

Serializer PLL Lock Time

Serializer Delay

5*t_TCP

510*t_TCP

t_TCP+ 1.0

-330

R_L= 27Ω

Figure 11

513*t_TCP

t_TCP+ 3.5

140

R_L= 27Ω, Figure 12

t_TCP+ 2.5

t_DJIT

20MHz

80MHz

R_L= 27Ω,

C_L=10pF

to GND⁽³⁾

Deterministic Jitter

Random Jitter

-130

-40

+60

t_RJIT

ps (RMS)

(1) t_LLHTand t_LHLTspecifications are Guaranteed By Design (GBD) using statistical analysis.

(2) Because the Serializer is in tri-state mode, the Deserializer will lose PLL lock and have to resynchronize before data transfer.

(3) t_DJITspecifications are Guaranteed By Design using statistical analysis.

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Deserializer Timing Requirements for REFCLK

Over recommended operating supply and temperature ranges unless otherwise specified.

Symbol

t_RFCP

Parameter

REFCLK Period

Conditions

Min

12.5

Typ

Max

50.0

Units

t_RFDC

REFCLK Duty Cycle

t_RFCP

t_TCP

Ratio of REFCLK to TCLK

REFCLK Transition Time

105

t_RFTT

Deserializer Switching Characteristics

Over recommended operating supply and temperature ranges unless otherwise specified.

Symbol

Parameter

Conditions

Pin/Freq.

Min

Typ

Max

Units

t_RCP

Receiver out Clock

Period

t_RCP= t_TCP

Figure 12

RCLK

12.5

50.0

t_CLH

t_CHL

t_DD

CMOS/TTL Low-to-High

Transition Time

1.2

1.1

Rout(0-9),

LOCK,

RCLK

CL = 15 pF

Figure 6

CMOS/TTL High-to-Low

Transition Time

All Temp, All Freq

Room Temp, 3.3V

1.75*t_RCP+1.25

1.75*t_RCP+2.25

1.75*t_RCP+5.0

1.75*t_RCP+8.5

1.75*t_RCP+8.0

Deserializer Delay

Figure 13

20MHz

80MHz

t_ROS

RCLK

20MHz

0.4*t_RCP

0.5*t_RCP

ROUT Data Valid before

RCLK

Figure 14

RCLK

80MHz

0.35*t_RCP

t_ROH

20MHz

80MHz

-0.4*t_RCP

-0.35*t_RCP

-0.5*t_RCP

ROUT Data Valid after

RCLK

t_RDC

t_HZR

t_LZR

RCLK Duty Cycle

3.5

HIGH to Tri-state Delay

LOW to Tri-state Delay

Tri-state to HIGH Delay

Tri-state to LOW Delay

2.8

μs

2.8

Figure 15

Rout(0-9)

t_ZHR

t_ZLR

4.2

t_DSR1

Deserializer PLL Lock

Time from PWRDWN

(with SYNCPAT)

20MHz

80MHz

1.7

1.0

2.5

μs

Figure 16

t_DSR2

20MHz

80MHz

0.65

0.29

1.5

0.8

μs

Deserializer PLL Lock

time from SYNCPAT

Figure 17⁽¹⁾

t_ZHLK

Tri-state to HIGH Delay

(power-up)

LOCK

3.7

t_RNMI-R

VCC = 3.15 to 3.6V

VCC = 3.0V

+335

+215

80MHz

20MHz

80MHz

20MHz

Ideal Noise Margin Right

Figure 21

t_RNMI-L

VCC = 3.15 to 3.6V

VCC = 3.0V

-395

-520

-1

Ideal Noise Margin Left

Figure 21

(1) For the purpose of specifying deserializer PLL performance, tDSR1 and tDSR2 are specified with the REFCLK running and stable, and

with specific conditions for the incoming data stream (SYNCPATs). It is recommended that the derserializer be initialized using either

t_DSR1timing or t_DSR2timing. t_DSR1is the time required for the deserializer to indicate lock upon power-up or when leaving the power-

down mode. Synchronization patterns should be sent to the device before initiating either condition. t_DSR2is the time required to indicate

lock for the powered-up and enabled deserializer when the input (RI+ and RI-) conditions change from not receiving data to receiving

synchronization patterns (SYNCPATs).

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SCAN Circuitry Timing Requirements

Symbol

Parameter

Conditions

Min

Typ

Max

Units

f_MAX

Maximum TCK Clock

Frequency

25.0

50.0

MHz

t_S

TDI to TCK, H or L

TMS to TCK, H or L

TCK Pulse Width, H or L

TRST Pulse Width, L

1.0

2.0

2.5

1.5

10.0

2.5

t_H

t_S

R_L= 500Ω, C_L= 35 pF

t_H

t_W

t_REC

Recovery Time, TRST to

TCK

2.0

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AC Timing Diagrams and Test Circuits

Figure 3. “Worst Case” Serializer ICC Test Pattern

Figure 4. “Worst Case” Deserializer ICC Test Pattern

Figure 5. Serializer Bus LVDS Output Load and Transition Times

Figure 6. Deserializer CMOS/TTL Output Load and Transition Times

Figure 7. Serializer Input Clock Transition Time

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Timing shown for TCLK_R/F = LOW

Figure 8. Serializer Setup/Hold Times

Figure 9. Serializer Tri-state Test Circuit and Timing

Figure 10. Serializer PLL Lock Time, and PWRDN Tri-state Delays

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Figure 11. SYNC Timing Delays

Figure 12. Serializer Delay

Figure 13. Deserializer Delay

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Timing shown for RCLK_R/F = LOW

Duty Cycle (t_RDC) =

Figure 14. Deserializer Data Valid Out Times

Figure 15. Deserializer Tri-state Test Circuit and Timing

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Figure 16. Deserializer PLL Lock Times and PWRDN Tri-state Delays

Figure 17. Deserializer PLL Lock Time from SyncPAT

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V_OD= (DO⁺)–(DO⁻).

Differential output signal is shown as (DO+)–(DO−), device in Data Transfer mode.

Figure 18. V_ODDiagram

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APPLICATION INFORMATION

USING THE SCAN921025H AND SCAN921226H

The Serializer and Deserializer chipset is an easy to use transmitter and receiver pair that sends 10 bits of

parallel LVTTL data over a serial Bus LVDS link up to 800 Mbps. An on-board PLL serializes the input data and

embeds two clock bits within the data stream. The Deserializer uses a separate reference clock (REFCLK) and

an onboard PLL to extract the clock information from the incoming data stream and then deserialize the data.

The Deserializer monitors the incoming clock information, determines lock status, and asserts the LOCK output

high when loss of lock occurs.

POWER CONSIDERATIONS

An all CMOS design of the Serializer and Deserializer makes them inherently low power devices. In addition, the

constant current source nature of the Bus LVDS outputs minimizes the slope of the speed vs. I_CCcurve of

conventional CMOS designs.

POWERING UP THE DESERIALIZER

The SCAN921226H can be powered up at any time by following the proper sequence. The REFCLK input can be

running before the Deserializer powers up, and it must be running in order for the Deserializer to lock to incoming

data. The Deserializer outputs will remain in tri-state until the Deserializer detects data transmission at its inputs

and locks to the incoming data stream.

TRANSMITTING DATA

Once you power up the Serializer and Deserializer, they must be phase locked to each other to transmit data.

Phase locking occurs when the Deserializer locks to incoming data or when the Serializer sends patterns. The

Serializer sends SYNC patterns whenever the SYNC1 or SYNC2 inputs are high. The LOCK output of the

Deserializer remains high until it has locked to the incoming data stream. Connecting the LOCK output of the

Deserializer to one of the SYNC inputs of the Serializer will ensure that enough SYNC patterns are sent to

achieve Deserializer lock.

The Deserializer can also lock to incoming data by simply powering up the device and allowing the “random lock”

circuitry to find and lock to the data stream.

While the Deserializer LOCK output is low, data at the Deserializer outputs (ROUT0-9) is valid, except for the

specific case of loss of lock during transmission which is further discussed in the RECOVERING FROM LOCK

LOSS section below.

NOISE MARGIN

The Deserializer noise margin is the amount of input jitter (phase noise) that the Deserializer can tolerate and still

reliably receive data. Various environmental and systematic factors include:

Serializer: TCLK jitter, V_CCnoise (noise bandwidth and out-of-band noise)

Media: ISI, Large V_CMshifts

Deserializer: V_CCnoise

RECOVERING FROM LOCK LOSS

In the case where the Deserializer loses lock during data transmission, up to 3 cycles of data that were

previously received can be invalid. This is due to the delay in the lock detection circuit. The lock detect circuit

requires that invalid clock information be received 4 times in a row to indicate loss of lock. Since clock

information has been lost, it is possible that data was also lost during these cycles. Therefore, after the

Deserializer relocks to the incoming data stream and the Deserializer LOCK pin goes low, at least three previous

data cycles should be suspect for bit errors.

The Deserializer can relock to the incoming data stream by making the Serializer resend SYNC patterns, as

described above, or by random locking, which can take more time, depending on the data patterns being

received.

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HOT INSERTION

All the BLVDS devices are hot pluggable if you follow a few rules. When inserting, ensure the Ground pin(s)

makes contact first, then the VCC pin(s), and then the I/O pins. When removing, the I/O pins should be

unplugged first, then the VCC, then the Ground. Random lock hot insertion is illustrated in Figure 22.

PCB CONSIDERATIONS

The Bus LVDS Serializer and Deserializer should be placed as close to the edge connector as possible. In

multiple Deserializer applications, the distance from the Deserializer to the slot connector appears as a stub to

the Serializer driving the backplane traces. Longer stubs lower the impedance of the bus, increase the load on

the Serializer, and lower the threshold margin at the Deserializers. Deserializer devices should be placed much

less than one inch from slot connectors. Because transition times are very fast on the Serializer Bus LVDS

outputs, reducing stub lengths as much as possible is the best method to ensure signal integrity.

TRANSMISSION MEDIA

The Serializer and Deserializer can also be used in point-to-point configuration of a backplane, through a PCB

trace, or through twisted pair cable. In point-to-point configuration, the transmission media need only be

terminated at the receiver end. Please note that in point-to-point configuration, the potential of offsetting the

ground levels of the Serializer vs. the Deserializer must be considered. Also, Bus LVDS provides a +/− 1.2V

common mode range at the receiver inputs.

FAILSAFE BIASING FOR THE SCAN921226H

The SCAN921226H has an improved input threshold sensitivity of +/− 50mV versus +/− 100mV for the

DS92LV1210 or DS92LV1212. This allows for greater differential noise margin in the SCAN921226H. However,

in cases where the receiver input is not being actively driven, the increased sensitivity of the SCAN921226H can

pickup noise as a signal and cause unintentional locking. For example, this can occur when the input cable is

disconnected.

External resistors can be added to the receiver circuit board to prevent noise pick-up. Typically, the non-inverting

receiver input is pulled up and the inverting receiver input is pulled down by high value resistors. the pull-up and

pull-down resistors (R₁and R₂) provide a current path through the termination resistor (R_L) which biases the

receiver inputs when they are not connected to an active driver. The value of the pull-up and pull-down resistors

should be chosen so that enough current is drawn to provide a +15mV drop across the termination resistor.

Please see Figure 19 for the Failsafe Biasing Setup.

USING t_DJITAND t_RNMTO VALIDATE SIGNAL QUALITY

The parameter t_RNMis calculated by first measuring how much of the ideal bit the receiver needs to ensure

correct sampling. After determining this amount, what remains of the ideal bit that is available for external

sources of noise is called t_RNM. t_RNMincludes transmitter jitter.

Please refer to Figure 20 and Figure 21 for a graphic representation of t_DJITand t_RNM. Also, for a more detailed

explanation of t_RNM, please see the Application Note titled 'How to Validate BLVDS SER/DES Signal Integrity

Using an Eye Mask' (SNLA053).

The vertical limits of the mask are determined by the SCAN921226H receiver input threshold of +/− 50mV.

Figure 19. Failsafe Biasing Setup

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Figure 20. Deterministic Jitter and Ideal Bit Position

t_RNMI-Lis the ideal noise margin on the left of the figure, it is a negative value to indicate early with respect to ideal.

t_RNMI-Ris the ideal noise margin on the right of the above figure, it is a positive value to indicate late with respect to

ideal.

Figure 21. Ideal Deserializer Noise Margin (t_RNMI) and Sampling Window

Figure 22. Random Lock Hot Insertion

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Pin Diagrams

Figure 23. SCAN921025HSM - Serializer (Top View)

Figure 24.

Figure 25. SCAN921226HSM - Deserializer (Top View)

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Serializer Pin Descriptions

Pin Name

I/O

Ball Id.

Description

DIN

A3, B1, C1, D1, Data Input. LVTTL levels inputs. Data on these pins are loaded into a 10-bit

D2, D3, E1, E2, input register.

F2, F4

TCLKR/F

Transmit Clock Rising/Falling strobe select. LVTTL level input. Selects

TCLK active edge for strobing of DIN data. High selects rising edge. Low

selects falling edge.

DO+

DO−

DEN

+ Serial Data Output. Non-inverting Bus LVDS differential output.

− Serial Data Output. Inverting Bus LVDS differential output.

Serial Data Output Enable. LVTTL level input. A low puts the Bus LVDS

outputs in tri-state.

PWRDN

Powerdown. LVTTL level input. PWRDN driven low shuts down the PLL

and tri-states outputs putting the device into a low power sleep mode.

TCLK

SYNC

Transmit Clock. LVTTL level input. Input for 20MHz – 80MHz system clock.

A4, B3

Assertion of SYNC (high) for at least 1024 synchronization symbols to be

transmitted on the Bus LVDS serial output. Synchronization symbols

continue to be sent if SYNC continues to be asserted. TTL level input. The

two SYNC pins are ORed.

DVCC

DGND

C3, C4, E5

Digital Circuit power supply.

A1, C2, F5, E6, Digital Circuit ground.

AVCC

AGND

TDI

A5, A6, B4, B7, Analog power supply (PLL and Analog Circuits).

B5, B6, C6, E7, Analog ground (PLL and Analog Circuits).

Test Data Input to support IEEE 1149.1. There is an internal pullup resistor

that defaults this input to high per IEEE 1149.1.

TDO

TMS

Test Data Output to support IEEE 1149.1

Test Mode Select Input to support IEEE 1149.1. There is an internal pullup

resistor that defaults this input to high per IEEE 1149.1.

TCK

Test Clock Input to support IEEE 1149.1

TRST

Test Reset Input to support IEEE 1149.1. There is an internal pullup resistor

that defaults this input to high per IEEE 1149.1.

N/C

N/A

A2, A7, B2, C5, Leave open circuit, do not connect

D4, F6, G6, G7

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Deserializer Pin Descriptions

Pin Name

I/O

Ball Id.

Description

ROUT

A5, B4, B6, C4, Data Output. ±9 mA CMOS level outputs.

C7, D6, F5, F7,

G4, G5

RCLKR/F

Recovered Clock Rising/Falling strobe select. TTL level input. Selects

RCLK active edge for strobing of ROUT data. High selects rising edge. Low

selects falling edge.

RI+

+ Serial Data Input. Non-inverting Bus LVDS differential input.

RI−

− Serial Data Input. Inverting Bus LVDS differential input.

PWRDN

Powerdown. TTL level input. PWRDN driven low shuts down the PLL and

tri-states outputs putting the device into a low power sleep mode.

LOCK

LOCK goes low when the Deserializer PLL locks onto the embedded clock

edge. CMOS level output. Totem pole output structure, does not directly

support wired OR connections.

RCLK

REN

Recovered Clock. Parallel data rate clock recovered from embedded clock.

Used to strobe ROUT, CMOS level output.

Output Enable. TTL level input. When driven low, tri-states ROUT0–ROUT9

and RCLK.

DVCC

DGND

AVCC

AGND

A7, B7, C5, C6, Digital Circuit power supply.

A1, A6, B5, D7, Digital Circuit ground.

E4, E7, G3

B1, C2, F1, F2, Analog power supply (PLL and Analog Circuits).

A4, B2, F3, F4, Analog ground (PLL and Analog Circuits).

REFCLK

TDI

Use this pin to supply a REFCLK signal for the internal PLL frequency.

Test Data Input to support IEEE 1149.1. There is an internal pullup resistor

that defaults this input to high per IEEE 1149.1.

TDO

TMS

Test Data Output to support IEEE 1149.1

Test Mode Select Input to support IEEE 1149.1. There is an internal pullup

resistor that defaults this input to high per IEEE 1149.1.

TCK

Test Clock Input to support IEEE 1149.1

TRST

Test Reset Input to support IEEE 1149.1. There is an internal pullup resistor

that defaults this input to high per IEEE 1149.1.

N/C

N/A

A2, C3, D4, E3 Leave open circuit, do not connect

SPACER

Deserializer Truth Table

INPUTS

OUTPUTS

PWRDN

H⁽⁴⁾

REN

ROUT [0:9]⁽¹⁾

LOCK⁽²⁾

RCLK⁽³⁾⁽¹⁾

Active

(1) ROUT and RCLK are tri-stated when LOCK is asserted High.

(2) LOCK Active indicates the LOCK output will reflect the state of the Deserializer with regard to the selected data stream.

(3) RCLK Active indicates the RCLK will be running if the Deserializer is locked. The Timing of RCLK with respect to ROUT is determined

by RCLK_R/F.

(4) During Power-up.

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REVISION HISTORY

Changes from Revision B (May 2013) to Revision C

Page

•

Changed layout of National Data Sheet to TI format. ......................................................................................................... 22

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PACKAGE OPTION ADDENDUM

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10-Dec-2020

PACKAGING INFORMATION

Orderable Device

Status Package Type Package Pins Package

Eco Plan

Lead finish/

Ball material

MSL Peak Temp

Op Temp (°C)

Device Marking

Samples

Drawing

Qty

416

(1)

(2)

(3)

(4/5)

(6)

SCAN921025HSM

SCAN921025HSM/NOPB

SCAN921025HSMX/NOPB

SCAN921226HSM

NRND

NFBGA

NZA

Non-RoHS &

Non-Green

Call TI

-40 to 125

SCAN921025

HSM

ACTIVE

NRND

NZA

RoHS & Green

SNAGCU

Call TI

Level-4-260C-72 HR

Call TI

SCAN921025

HSM

NZA

2000 RoHS & Green

SCAN921025

HSM

NZA

416

Non-RoHS &

Non-Green

SCAN921226

HSM

SCAN921226HSM/NOPB

ACTIVE

NZA

RoHS & Green

SNAGCU

Level-4-260C-72 HR

SCAN921226

HSM

⁽¹⁾The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

⁽²⁾RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance

do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may

reference these types of products as "Pb-Free".

RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.

Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based

flame retardants must also meet the <=1000ppm threshold requirement.

⁽³⁾MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

⁽⁴⁾There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

⁽⁵⁾Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation

of the previous line and the two combined represent the entire Device Marking for that device.

(6)

Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two

lines if the finish value exceeds the maximum column width.

Addendum-Page 1

PACKAGE OPTION ADDENDUM

www.ti.com

10-Dec-2020

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

Addendum-Page 2

PACKAGE MATERIALS INFORMATION

www.ti.com

23-Jun-2023

TAPE AND REEL INFORMATION

REEL DIMENSIONS

TAPE DIMENSIONS

Reel

Diameter

Cavity

A0 Dimension designed to accommodate the component width

B0 Dimension designed to accommodate the component length

K0 Dimension designed to accommodate the component thickness

Overall width of the carrier tape

P1 Pitch between successive cavity centers

Reel Width (W1)

QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE

Sprocket Holes

Q1 Q2

Q3 Q4

Q1 Q2

Q3 Q4

User Direction of Feed

Pocket Quadrants

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

SCAN921025HSMX/

NOPB

NFBGA

NZA

2000

330.0

16.4

7.3

2.1

12.0

16.0

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

23-Jun-2023

TAPE AND REEL BOX DIMENSIONS

Width (mm)

*All dimensions are nominal

Device

Package Type Package Drawing Pins

NFBGA NZA 49

SPQ

Length (mm) Width (mm) Height (mm)

356.0 356.0 35.0

SCAN921025HSMX/NOPB

2000

Pack Materials-Page 2

PACKAGE MATERIALS INFORMATION

www.ti.com

23-Jun-2023

TRAY

L - Outer tray length without tabs

KO -

Outer

tray

height

W -

Outer

tray

width

Text

P1 - Tray unit pocket pitch

CW - Measurement for tray edge (Y direction) to corner pocket center

CL - Measurement for tray edge (X direction) to corner pocket center

Chamfer on Tray corner indicates Pin 1 orientation of packed units.

*All dimensions are nominal

Device

Package Package Pins SPQ Unit array

Max

matrix temperature

(°C)

L (mm)

Name

Type

(mm) (µm) (mm) (mm) (mm)

SCAN921025HSM

NZA

NFBGA

416

13 X 32

150

322.6 135.9 7620

9.4

11.8 11.55

SCAN921025HSM/

NOPB

SCAN921226HSM

NZA

NFBGA

416

13 X 32

150

322.6 135.9 7620

9.4

11.8 11.55

SCAN921226HSM/

NOPB

Pack Materials-Page 3

MECHANICAL DATA

NZA0049A

SLC49A (Rev B)

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SCAN921025HSMX/NOPB [TI]

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