DS90CR288A [TI]

+3.3V 上升沿数据选通 LVDS 28 位频道链接接收器 - 85MHz;


型号：	DS90CR288A
厂家：	TEXAS INSTRUMENTS
描述：	+3.3V 上升沿数据选通 LVDS 28 位频道链接接收器 - 85MHz 驱动线路驱动器或接收器驱动程序和接口
文件：	总24页 (文件大小：1209K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

DS90CR287, DS90CR288A

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SNLS056G –OCTOBER 1999–REVISED MARCH 2013

DS90CR287/DS90CR288A +3.3V Rising Edge Data Strobe LVDS

28-Bit Channel Link - 85MHz

Check for Samples: DS90CR287, DS90CR288A

FEATURES

DESCRIPTION

The DS90CR287 transmitter converts 28 bits of

•

20 to 85 MHz Shift Clock Support

LVCMOS/LVTTL data into four LVDS (Low Voltage

Differential Signaling) data streams. A phase-locked

transmit clock is transmitted in parallel with the data

streams over a fifth LVDS link. Every cycle of the

transmit clock 28 bits of input data are sampled and

transmitted.

50% Duty Cycle on Receiver Output Clock

2.5 / 0 ns Set & Hold Times on TxINPUTs

Low Power Consumption

±1V Common-Mode Range (around +1.2V)

Narrow Bus Reduces Cable Size and Cost

Up to 2.38 Gbps Throughput

The DS90CR288A receiver converts the four LVDS

data streams back into 28 bits of LVCMOS/LVTTL

data. At a transmit clock frequency of 85 MHz, 28 bits

of TTL data are transmitted at a rate of 595 Mbps per

LVDS data channel. Using a 85 MHz clock, the data

throughput is 2.38 Gbit/s (297.5 Mbytes/sec).

Up to 297.5 Mbytes/sec Bandwidth

345 mV (typ) Swing LVDS Devices for Low EMI

PLL Requires no External Components

Rising Edge Data Strobe

This chipset is an ideal means to solve EMI and

cable size problems associated with wide, high-speed

TTL interfaces.

Compatible with TIA/EIA-644 LVDS Standard

Low Profile 56-Lead TSSOP Package

Block Diagram

Figure 1. DS90CR287

See Package Number DGG-56 (TSSOP)

Figure 2. DS90CR288A

See Package Number DGG-56 (TSSOP)

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.

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.

DS90CR287, DS90CR288A

SNLS056G –OCTOBER 1999–REVISED MARCH 2013

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Pin Diagram for TSSOP Packages

Figure 3. DS90CR287

Typical Application

Figure 4. DS90CR288A

Figure 5. DS90CR288A

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.

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Absolute Maximum Ratings⁽¹⁾⁽²⁾

Supply Voltage (V_CC

)

−0.3V to +4V

−0.5V to (V_CC+ 0.3V)

−0.3V to (V_CC+ 0.3V)

Continuous

CMOS/TTL Input Voltage

CMOS/TTL Output Voltage

LVDS Receiver Input Voltage

LVDS Driver Output Voltage

LVDS Output Short Circuit Duration

Junction Temperature

+150°C

Storage Temperature

−65°C to +150°C

+260°C

Lead Temperature (Soldering, 4 sec.)

Solder Reflow Temperature

Maximum Package Power Dissipation @ +25°C

TSSOP Package

DS90CR287

DS90CR288A

DS90CR287

DS90CR288A

1.63 W

1.61 W

Package Derating

ESD Rating

12.5 mW/°C above +25°C

12.4 mW/°C above +25°C

(HBM, 1.5kΩ, 100pF)

(EIAJ, 0Ω, 200pF)

> 7kV

> 700V

Latch Up Tolerance @ +25°C

> ±300mA

(1) “Absolute Maximum Ratings” are those values beyond which the safety of the device cannot be guaranteed. They are not meant to

imply that the device should be operated at these limits. “Electrical Characteristics” specify conditions for device operation.

(2) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and

specifications.

Recommended Operating Conditions

Min

3.0

−10

Nom

3.3

Max

3.6

Units

Supply Voltage (V_CC

)

Operating Free Air Temperature (T_A)

Receiver Input Range

+25

+70

2.4

°C

Supply Noise Voltage (V_CC

)

100

mV_PP

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Electrical Characteristics⁽¹⁾

Over recommended operating supply and temperature ranges unless otherwise specified

Symbol

Parameter

Conditions

Min

Typ⁽²⁾Max

Units

LVCMOS/LVTTL DC SPECIFICATIONS

V_IH

V_IL

High Level Input Voltage

Low Level Input Voltage

High Level Output Voltage

Low Level Output Voltage

Input Clamp Voltage

Input Current

2.0

GND

2.7

V_CC

0.8

V_OH

V_OL

V_CL

I_IN

I_OH= −0.4 mA

I_OL= 2 mA

3.3

0.06

−0.79

+1.8

0.3

−1.5

+15

I_CL= −18 mA

V_IN= 0.4V, 2.5V or V_CC

V_IN= GND

μA

−10

I_OS

Output Short Circuit Current

V_OUT= 0V

−60

−120

LVDS DRIVER DC SPECIFICATIONS

V_OD

Differential Output Voltage

R_L= 100Ω

250

290

450

ΔV_OD

Change in V_ODbetween Complimentary

Output States

Offset Voltage⁽³⁾

V_OS

1.125

1.25

1.375

ΔV_OS

Change in V_OSbetween Complimentary

Output States

I_OS

I_OZ

Output Short Circuit Current

Output TRI-STATE Current

V_OUT= 0V, R_L= 100Ω

−3.5

−5

PWR DWN = 0V, V_OUT= 0V or V_CC

±1

±10

μA

LVDS RECEIVER DC SPECIFICATIONS

V_TH

V_TL

I_IN

Differential Input High Threshold

Differential Input Low Threshold

Input Current

V_CM= +1.2V

+100

μA

−100

V_IN= +2.4V, V_CC= 3.6V

V_IN= 0V, V_CC= 3.6V

±10

μA

TRANSMITTER SUPPLY CURRENT

I_CCTW

Transmitter Supply Current Worst Case

R_L= 100Ω,

C_L= 5 pF,

Worst Case Pattern

Figure 6, Figure 7

f = 33 MHz

(with Loads)⁽⁴⁾

f = 40 MHz

f = 66 MHz

f = 85 MHz

I_CCTZ

Transmitter Supply Current Power

Down⁽⁴⁾

PWR DWN = Low

Driver Outputs in TRI-STATE

under Powerdown Mode

μA

RECEIVER SUPPLY CURRENT

I_CCRWReceiver Supply Current Worst Case

C_L= 8 pF,

Worst Case Pattern

Figure 6, Figure 8

f = 33 MHz

f = 40 MHz

f = 66 MHz

f = 85 MHz

114

135

I_CCRZ

Receiver Supply Current Power Down

PWR DWN = Low

Receiver Outputs Stay Low during

Powerdown Mode

140

400

μA

(1) “Absolute Maximum Ratings” are those values beyond which the safety of the device cannot be guaranteed. They are not meant to

imply that the device should be operated at these limits. “Electrical Characteristics” specify conditions for device operation.

(2) Typical values are given for V_CC= 3.3V and T_A= +25°C.

(3) V_OSpreviously referred as V_CM

(4) Current into device pins is defined as positive. Current out of device pins is defined as negative. Voltages are referenced to ground

unless otherwise specified (except V_ODand ΔV_OD).

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SNLS056G –OCTOBER 1999–REVISED MARCH 2013

Transmitter Switching Characteristics

Over recommended operating supply and temperature ranges unless otherwise specified

Symbol

LLHT

Parameter

LVDS Low-to-High Transition Time Figure 7

Min

Typ⁽¹⁾

0.75

Max

1.5

Units

LHLT

LVDS High-to-Low Transition Time Figure 7

TxCLK IN Transition Time Figure 9

0.75

1.5

TCIT

1.0

−0.20

1.48

3.16

4.84

6.52

8.20

9.88

11.76

0.35T

2.5

6.0

TPPos0

TPPos1

TPPos2

TPPos3

TPPos4

TPPos5

TPPos6

TCIP

Transmitter Output Pulse Position for Bit0 Figure 19

Transmitter Output Pulse Position for Bit1

Transmitter Output Pulse Position for Bit2

Transmitter Output Pulse Position for Bit3

Transmitter Output Pulse Position for Bit4

Transmitter Output Pulse Position for Bit5

Transmitter Output Pulse Position for Bit6

TxCLK IN Period Figure 10

f = 85 MHz

0.20

1.88

3.56

5.24

6.92

8.60

10.28

1.68

3.36

5.04

6.72

8.40

10.08

TCIH

TxCLK IN High Time Figure 10

0.5T

0.65T

TCIL

TxCLK IN Low Time Figure 10

TSTC

TxIN Setup to TxCLK IN Figure 10

f = 85 MHz

THTC

TCCD

TPLLS

TPDD

TJIT

TxIN Hold to TxCLK IN Figure 10

TxCLK IN to TxCLK OUT Delay Figure 12

Transmitter Phase Lock Loop Set Figure 14

Transmitter Powerdown Delay Figure 17

TxCLK IN Cycle-to-Cycle Jitter (Input clock requirement)

T_A= 25°C, V_CC= 3.3V

3.8

6.3

100

(1) Typical values are given for V_CC= 3.3V and T_A= +25°C.

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Receiver Switching Characteristics

Over recommended operating supply and temperature ranges unless otherwise specified

Symbol

CLHT

Parameter

CMOS/TTL Low-to-High Transition Time Figure 8

CMOS/TTL High-to-Low Transition Time Figure 8

Receiver Input Strobe Position for Bit 0 Figure 20

Receiver Input Strobe Position for Bit 1

Receiver Input Strobe Position for Bit 2

Receiver Input Strobe Position for Bit 3

Receiver Input Strobe Position for Bit 4

Receiver Input Strobe Position for Bit 5

Receiver Input Strobe Position for Bit 6

RxIN Skew Margin⁽²⁾Figure 21

Min

Typ⁽¹⁾

Max

Units

μs

3.5

CHLT

1.8

RSPos0

RSPos1

RSPos2

RSPos3

RSPos4

RSPos5

RSPos6

RSKM

f = 85 MHz

0.49

2.17

3.85

5.53

7.21

8.89

10.57

290

11.76

0.84

2.52

4.20

5.88

7.56

9.24

10.92

1.19

2.87

4.55

6.23

7.91

9.59

11.27

f = 85 MHz

RCOP

RxCLK OUT Period Figure 11

6.5

RCOH

RCOL

RxCLK OUT High Time Figure 11

RxCLK OUT Low Time Figure 11

3.5

RSRC

RxOUT Setup to RxCLK OUT Figure 11

RxOUT Hold to RxCLK OUT Figure 11

3.5

RHRC

3.5

RCCD

RxCLK IN to RxCLK OUT Delay @ 25°C, V_CC= 3.3V⁽³⁾Figure 13

5.5

9.5

RPLLS

RPDD

Receiver Phase Lock Loop Set Figure 15

Receiver Powerdown Delay Figure 18

(1) Typical values are given for V_CC= 3.3V and T_A= +25°C.

(2) Receiver Skew Margin is defined as the valid data sampling region at the receiver inputs. This margin takes into account the transmitter

pulse positions (min and max) and the receiver input setup and hold time (internal data sampling window-RSPOS). This margin allows

LVDS interconnect skew, inter-symbol interference (both dependent on type/length of cable), and source clock (less than 150 ps).

(3) Total latency for the channel link chipset is a function of clock period and gate delays through the transmitter (TCCD) and receiver

(RCCD). The total latency for the 217/287 transmitter and 218/288A receiver is: (T + TCCD) + (2*T + RCCD), where T = Clock period.

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AC Timing Diagrams

Figure 6. “Worst Case” Test Pattern

Figure 7. DS90CR287 (Transmitter) LVDS Output Load and Transition Times

Figure 8. DS90CR288A (Receiver) CMOS/TTL Output Load and Transition Times

Figure 9. DS90CR287 (Transmitter) Input Clock Transition Time

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Figure 10. DS90CR287 (Transmitter) Setup/Hold and High/Low Times

Figure 11. DS90CR288A (Receiver) Setup/Hold and High/Low Times

Figure 12. DS90CR287 (Transmitter) Clock In to Clock Out Delay

Figure 13. DS90CR288A (Receiver) Clock In to Clock Out Delay

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Figure 14. DS90CR287 (Transmitter) Phase Lock Loop Set Time

Figure 15. DS90CR288A (Receiver) Phase Lock Loop Set Time

Figure 16. 28 Parallel TTL Data Inputs Mapped to LVDS Outputs

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Figure 17. Transmitter Powerdown Delay

Figure 18. Receiver Powerdown Delay

Figure 19. Transmitter LVDS Output Pulse Position Measurement

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Figure 20. Receiver LVDS Input Strobe Position

C—Setup and Hold Time (Internal data sampling window) defined by Rspos (receiver input strobe position) min and

max

Tppos—Transmitter output pulse position (min and max)

RSKM ≥ Cable Skew (type, length) + Source Clock Jitter (cycle to cycle)⁽¹⁾+ ISI (Inter-symbol interference)⁽²⁾

Cable Skew—typically 10 ps–40 ps per foot, media dependent

(1) Cycle-to-cycle jitter is less than 150ps at 85MHz.

(2) ISI is dependent on interconnect length; may be zero.

Figure 21. Receiver LVDS Input Skew Margin

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DS90CR287 DGG (TSSOP) Package PIN DESCRIPTION — Channel Link Transmitter

Pin Name

I/O No.

Description

TxIN

28 TTL level input.

TxOUT+

TxOUT−

TxCLK IN

Positive LVDS differential data output.

Negative LVDS differential data output.

TTL level clock input. The rising edge acts as data strobe. Pin name TxCLK IN. See APPLICATIONS

INFORMATION section.

TxCLK OUT+

TxCLK OUT−

PWR DOWN

Positive LVDS differential clock output.

Negative LVDS differential clock output.

TTL level input. Assertion (low input) TRI-STATES the outputs, ensuring low current at power down. See

APPLICATIONS INFORMATION section.

V_CC

Power supply pins for TTL inputs.

Ground pins for TTL inputs.

Power supply pin for PLL.

GND

PLL V_CC

PLL GND

LVDS V_CC

LVDS GND

Ground pins for PLL.

Power supply pin for LVDS outputs.

Ground pins for LVDS outputs.

DS90CR288A DGG (TSSOP) Package PIN DESCRIPTION — Channel Link Receiver

Pin Name

RxIN+

I/O No.

Description

Positive LVDS differential data inputs.

Negative LVDS differential data inputs.

RxIN−

RxOUT

28 TTL level data outputs.

RxCLK IN+

RxCLK IN−

RxCLK OUT

PWR DOWN

V_CC

Positive LVDS differential clock input.

Negative LVDS differential clock input.

TTL level clock output. The rising edge acts as data strobe. Pin name RxCLK OUT.

TTL level input. When asserted (low input) the receiver outputs are low.

Power supply pins for TTL outputs.

GND

Ground pins for TTL outputs.

PLL V_CC

Power supply for PLL.

PLL GND

LVDS V_CC

LVDS GND

Ground pin for PLL.

Power supply pin for LVDS inputs.

Ground pins for LVDS inputs.

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APPLICATIONS INFORMATION

The TSSOP version of the DS90CR287 and DS90CR288A are backward compatible with the existing 5V

Channel Link transmitter/receiver pair (DS90CR283, DS90CR284). To upgrade from a 5V to a 3.3V system the

following must be addressed:

1. Change 5V power supply to 3.3V. Provide this supply to the V_CC, LVDS V_CCand PLL V_CC

2. Transmitter input and control inputs except 3.3V TTL/CMOS levels. They are not 5V tolerant.

3. The receiver powerdown feature when enabled will lock receiver output to a logic low.

The Channel Link devices are intended to be used in a wide variety of data transmission applications. Depending

upon the application the interconnecting media may vary. For example, for lower data rate (clock rate) and

shorter cable lengths (< 2m), the media electrical performance is less critical. For higher speed/long distance

applications the media's performance becomes more critical. Certain cable constructions provide tighter skew

(matched electrical length between the conductors and pairs). Additional applications information can be found in

the following Interface Application Notes:

AN = ####

AN-1041 (SNLA218)

AN-1108(SNLA008)

AN-806 (SNLA026)

AN-905 (SNLA035)

AN-916 (SNLA219)

Topic

Introduction to Channel Link

Channel Link PCB and Interconnect Design-In Guidelines

Transmission Line Theory

Transmission Line Calculations and Differential Impedance

Cable Information

CABLES: A cable interface between the transmitter and receiver needs to support the differential LVDS pairs.

The 21-bit CHANNEL LINK chipset (DS90CR217/218A) requires four pairs of signal wires and the 28-bit

CHANNEL LINK chipset (DS90CR287/288A) requires five pairs of signal wires. The ideal cable/connector

interface would have a constant 100Ω differential impedance throughout the path. It is also recommended that

cable skew remain below 140ps (@ 85 MHz clock rate) to maintain a sufficient data sampling window at the

receiver.

In addition to the four or five cable pairs that carry data and clock, it is recommended to provide at least one

additional conductor (or pair) which connects ground between the transmitter and receiver. This low impedance

ground provides a common-mode return path for the two devices. Some of the more commonly used cable types

for point-to-point applications include flat ribbon, flex, twisted pair and Twin-Coax. All are available in a variety of

configurations and options. Flat ribbon cable, flex and twisted pair generally perform well in short point-to-point

applications while Twin-Coax is good for short and long applications. When using ribbon cable, it is

recommended to place a ground line between each differential pair to act as a barrier to noise coupling between

adjacent pairs. For Twin-Coax cable applications, it is recommended to utilize a shield on each cable pair. All

extended point-to-point applications should also employ an overall shield surrounding all cable pairs regardless

of the cable type. This overall shield results in improved transmission parameters such as faster attainable

speeds, longer distances between transmitter and receiver and reduced problems associated with EMS or EMI.

The high-speed transport of LVDS signals has been demonstrated on several types of cables with excellent

results. However, the best overall performance has been seen when using Twin-Coax cable. Twin-Coax has very

low cable skew and EMI due to its construction and double shielding. All of the design considerations discussed

here and listed in the supplemental application notes provide the subsystem communications designer with many

useful guidelines. It is recommended that the designer assess the tradeoffs of each application thoroughly to

arrive at a reliable and economical cable solution.

RECEIVER FAILSAFE FEATURE: These receivers have input failsafe bias circuitry to guarantee a stable

receiver output for floating or terminated receiver inputs. Under these conditions receiver inputs will be in a HIGH

state. If a clock signal is present, data outputs will all be HIGH; if the clock input is also floating/terminated, data

outputs will remain in the last valid state. A floating/terminated clock input will result in a HIGH clock output.

BOARD LAYOUT: To obtain the maximum benefit from the noise and EMI reductions of LVDS, attention should

be paid to the layout of differential lines. Lines of a differential pair should always be adjacent to eliminate noise

interference from other signals and take full advantage of the noise canceling of the differential signals. The

board designer should also try to maintain equal length on signal traces for a given differential pair. As with any

high-speed design, the impedance discontinuities should be limited (reduce the numbers of vias and no 90

degree angles on traces). Any discontinuities which do occur on one signal line should be mirrored in the other

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line of the differential pair. Care should be taken to ensure that the differential trace impedance match the

differential impedance of the selected physical media (this impedance should also match the value of the

termination resistor that is connected across the differential pair at the receiver's input). Finally, the location of

the CHANNEL LINK TxOUT/RxIN pins should be as close as possible to the board edge so as to eliminate

excessive pcb runs. All of these considerations will limit reflections and crosstalk which adversely effect high

frequency performance and EMI.

INPUTS: The TxIN and control pin inputs are compatible with LVTTL and LVCMOS levels. This pins are not 5V

tolerant.

UNUSED INPUTS: All unused inputs at the TxIN inputs of the transmitter may be tied to ground or left no

connect. All unused outputs at the RxOUT outputs of the receiver must then be left floating.

TERMINATION: Use of current mode drivers requires a terminating resistor across the receiver inputs. The

CHANNEL LINK chipset will normally require a single 100Ω resistor between the true and complement lines on

each differential pair of the receiver input. The actual value of the termination resistor should be selected to

match the differential mode characteristic impedance (90Ω to 120Ω typical) of the cable. Figure 22 shows an

example. No additional pull-up or pull-down resistors are necessary as with some other differential technologies

such as PECL. Surface mount resistors are recommended to avoid the additional inductance that accompanies

leaded resistors. These resistors should be placed as close as possible to the receiver input pins to reduce stubs

and effectively terminate the differential lines.

DECOUPLING CAPACITORS: Bypassing capacitors are needed to reduce the impact of switching noise which

could limit performance. For a conservative approach three parallel-connected decoupling capacitors (Multi-

Layered Ceramic type in surface mount form factor) between each V_CCand the ground plane(s) are

recommended. The three capacitor values are 0.1 μF, 0.01 μF and 0.001 μF. An example is shown in Figure 23.

The designer should employ wide traces for power and ground and ensure each capacitor has its own via to the

ground plane. If board space is limiting the number of bypass capacitors, the PLL V_CCshould receive the most

filtering/bypassing. Next would be the LVDS V_CCpins and finally the logic V_CCpins.

Figure 22. LVDS Serialized Link Termination

Figure 23. CHANNEL LINK

Decoupling Configuration

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CLOCK JITTER: The CHANNEL LINK devices employ a PLL to generate and recover the clock transmitted

across the LVDS interface. The width of each bit in the serialized LVDS data stream is one-seventh the clock

period. For example, a 85 MHz clock has a period of 11.76 ns which results in a data bit width of 1.68 ns.

Differential skew (Δt within one differential pair), interconnect skew (Δt of one differential pair to another) and

clock jitter will all reduce the available window for sampling the LVDS serial data streams. Care must be taken to

ensure that the clock input to the transmitter be a clean low noise signal. Individual bypassing of each V_CCto

ground will minimize the noise passed on to the PLL, thus creating a low jitter LVDS clock. These measures

provide more margin for channel-to-channel skew and interconnect skew as a part of the overall jitter/skew

budget.

INPUT CLOCK: The input clock should be present at all times when the part in enabled. If the clock is stopped,

the PWR DOWN pin should be asserted to disable the PLL. Once the clock is active again, the part can then be

enabled. Do not enable the part without a clock present.

COMMON-MODE vs. DIFFERENTIAL MODE NOISE MARGIN: The typical signal swing for LVDS is 300 mV

centered at +1.2V. The CHANNEL LINK receiver supports a 100 mV threshold therefore providing approximately

200 mV of differential noise margin. Common-mode protection is of more importance to the system's operation

due to the differential data transmission. LVDS supports an input voltage range of Ground to +2.4V. This allows

for a ±1.0V shifting of the center point due to ground potential differences and common-mode noise.

TRANSMITTER INPUT CLOCK: The transmitter input clock must always be present when the device is enabled

(PWR DOWN = HIGH). If the clock is stopped, the PWR DOWN pin must be used to disable the PLL. The PWR

DOWN pin must be held low until after the input clock signal has been reapplied. This will ensure a proper device

reset and PLL lock to occur.

POWER SEQUENCING AND POWERDOWN MODE: Outputs of the CHANNEL LINK transmitter remain in TRI-

STATE until the power supply reaches 2V. Clock and data outputs will begin to toggle 10 ms after V_CChas

reached 3V and the Powerdown pin is above 1.5V. Either device may be placed into a powerdown mode at any

time by asserting the Powerdown pin (active low). Total power dissipation for each device will decrease to 5 μW

(typical).

The transmitter input clock may be applied prior to powering up and enabling the transmitter. The transmitter

input clock may also be applied after power up; however, the use of the PWR DOWN pin is required. Do not

power up and enable (PWR DOWN = HIGH) the transmitter without a valid clock signal applied to the TxCLK IN

pin.

The CHANNEL LINK chipset is designed to protect itself from accidental loss of power to either the transmitter or

receiver. If power to the transmit board is lost, the receiver clocks (input and output) stop. The data outputs

(RxOUT) retain the states they were in when the clocks stopped. When the receiver board loses power, the

receiver inputs are shorted to V_CCthrough an internal diode. Current is limited (5 mA per input) by the fixed

current mode drivers, thus avoiding the potential for latchup when powering the device.

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Figure 24. Single-Ended and Differential Waveforms

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SNLS056G –OCTOBER 1999–REVISED MARCH 2013

REVISION HISTORY

Changes from Revision F (March 2013) to Revision G

Page

•

Changed layout of National Data Sheet to TI format .......................................................................................................... 16

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Product Folder Links: DS90CR287 DS90CR288A

PACKAGE OPTION ADDENDUM

www.ti.com

18-Oct-2013

PACKAGING INFORMATION

Orderable Device

DS90CR287MTD

Status Package Type Package Pins Package

Eco Plan

Lead/Ball Finish

MSL Peak Temp

Op Temp (°C)

-10 to 70

Device Marking

Samples

Drawing

Qty

(1)

(2)

(6)

(3)

(4/5)

ACTIVE

TSSOP

NFBGA

DGG

TBD

Call TI

CU SN

Call TI

DS90CR287MTD

DS90CR287MTD/NOPB

DS90CR287MTDX/NOPB

DS90CR287SLC/NOPB

ACTIVE

NRND

DGG

NZC

Green (RoHS

& no Sb/Br)

Level-2-260C-1 YEAR

Level-4-260C-72 HR

-10 to 70

DS90CR287MTD

1000

360

Green (RoHS

& no Sb/Br)

-10 to 70

DS90CR287MTD

Green (RoHS SNAGCU | SNAGCU

& no Sb/Br)

DS90CR287

SLC

DS90CR288AMTD

DS90CR288AMTD/NOPB

DS90CR288AMTDX

ACTIVE

TSSOP

DGG

TBD

Call TI

CU SN

Call TI

CU SN

Call TI

-10 to 70

DS90CR288AMTD

Green (RoHS

& no Sb/Br)

Level-2-260C-1 YEAR

Call TI

DS90CR288AMTD

1000

TBD

DS90CR288AMTD

DS90CR288AMTDX/NOPB

Green (RoHS

& no Sb/Br)

Level-2-260C-1 YEAR

DS90CR288AMTD

⁽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⁾Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that

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

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

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

Addendum-Page 1

PACKAGE OPTION ADDENDUM

www.ti.com

18-Oct-2013

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

value exceeds the maximum column width.

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

26-Mar-2013

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

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

(mm) W1 (mm)

DS90CR287MTDX/NOPB TSSOP

DS90CR288AMTDX TSSOP

DGG

1000

330.0

24.4

8.6

14.5

1.8

12.0

24.0

DS90CR288AMTDX/NOP TSSOP

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

26-Mar-2013

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

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

DS90CR287MTDX/NOPB

DS90CR288AMTDX

TSSOP

DGG

1000

367.0

45.0

DS90CR288AMTDX/NOPB

Pack Materials-Page 2

MECHANICAL DATA

NZC0064A

SLC64A (Rev C)

www.ti.com

MECHANICAL DATA

MTSS003D – JANUARY 1995 – REVISED JANUARY 1998

DGG (R-PDSO-G**)

PLASTIC SMALL-OUTLINE PACKAGE

48 PINS SHOWN

0,27

0,17

0,08

0,50

6,20

6,00

8,30

7,90

0,15 NOM

Gage Plane

0,25

0°–8°

0,75

0,50

Seating Plane

0,10

0,15

0,05

1,20 MAX

PINS **

DIM

A MAX

12,60

12,40

14,10

13,90

17,10

16,90

A MIN

4040078/F 12/97

NOTES: A. All linear dimensions are in millimeters.

B. This drawing is subject to change without notice.

C. Body dimensions do not include mold protrusion not to exceed 0,15.

D. Falls within JEDEC MO-153

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DS90CR288A [TI]

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