AD8153ACPZ_技术文档

3.2 Gbps

Single Buffered Mux/Demux Switch

AD8153

FEATURES

FUNCTIONAL BLOCK DIAGRAM

Single lane 2:1 mux/1:2 demux

3.2 Gbps to dc data rates

TRANSMIT

PRE-EMPHASIS

RECEIVE

EQUALIZATION

Compensates over 40 inches of FR4 at 3.2 Gbps through

Two levels of input equalization, or

Four levels of output pre-emphasis

Operates with ac- or dc-coupled differential I/O

Low deterministic jitter, typically 16 ps p-p

Low random jitter, typically 500 fs rms

On-chip terminations

INPUT A

INPUT B

EQ

OUTPUT C

RECEIVE

EQUALIZATION

OUTPUT A

OUTPUT B

INPUT C

EQ

Unicast or bicast on 1:2 demux function

Loopback capability on all ports

3.3 V core supply

Flexible I/O supply

Low power, typically 200 mW in basic configuration¹

32-lead LFCSP package

SEL

2:1 MULTIPLEXER/

1:2 DEMULTIPLEXER

TRANSMIT

PRE-EMPHASIS

BICAST

LB_A

LB_B

LB_C

CONTROL

LOGIC

MODE

RESETB

EQ_A/(SCL)

EQ_B/(SDA)

EQ_C

AD8153

PE_A/(I2C_A[0])

PE_B/(I2C_A[1])

PE_C/(I2C_A[2])

−40°C to +85°C operating temperature range

APPLICATIONS

Figure 1.

Low cost redundancy switch

SONET OC48/SDH16 and lower data rates

Gigabit Ethernet over backplane

Fibre Channel 1.06 Gbps and 2.12 Gbps over backplane

Serial RapidIO

PCI Express Gen 1

Infiniband over backplane

provide access to advanced features, such as additional pre-

emphasis settings and output disable. In mixed mode, the user

accesses the advanced features using I²C, but controls lane

switching using the external pins.

GENERAL DESCRIPTION

The AD8153 is an asynchronous, protocol agnostic, single-lane

2:1 switch with three differential CML inputs and three differential

CML outputs. The AD8159, another member of the Xstream

line of products, is suitable for similar applications that require

more than one lane.

The main application of the AD8153 is to support redundancy

on both the backplane side and the line interface side of a serial

link. The device has unicast and bicast capability, so it is capable

of supporting either 1 + 1 or 1:1 redundancy.

The AD8153 is optimized for NRZ signaling with data rates of

up to 3.2 Gbps per port. Each port offers two levels of input

equalization and four levels of output pre-emphasis.

Using a mixture of bicast and loopback modes, the AD8153 can

also be used to test high speed serial links by duplicating the

incoming data and transmitting it to the destination port and

test equipment simultaneously.

The device consists of a 2:1 multiplexer and a 1:2 demultiplexer.

There are three operating modes: pin mode, serial mode, and

mixed mode. In pin mode, lane switching, equalization, and

pre-emphasis are controlled exclusively using external pins. In

serial mode, an I²C interface is used to control the device and to

1

Two ports active with no pre-emphasis.

Rev. 0

Information furnished by Analog Devices is believed to be accurate and reliable. However, no

responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other

rights of third parties that may result from its use. Specifications subject to change without notice. No

license is granted by implication or otherwise under any patent or patent rights of Analog Devices.

Trademarks and registeredtrademarks arethe property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781.329.4700

Fax: 781.461.3113

www.analog.com

AD8153

TABLE OF CONTENTS

Features .............................................................................................. 1

Transmit Pre-Emphasis ............................................................. 14

I²C Serial Control Interface........................................................... 15

Register Set.................................................................................. 15

General Functionality................................................................ 15

I²C Data Write............................................................................. 16

I²C Data Read.............................................................................. 17

Applications Information.............................................................. 18

PCB Design Guidelines ................................................................. 19

Interfacing to the AD8153............................................................. 20

Termination Structures.............................................................. 20

Input Compliance....................................................................... 20

Output Compliance ................................................................... 21

Outline Dimensions....................................................................... 22

Ordering Guide .......................................................................... 22

Applications....................................................................................... 1

Functional Block Diagram .............................................................. 1

General Description......................................................................... 1

Revision History ............................................................................... 2

Specifications..................................................................................... 3

I²C Timing Specifications............................................................ 4

Absolute Maximum Ratings............................................................ 5

ESD Caution.................................................................................. 5

Pin Configuration and Function Descriptions............................. 6

Typical Performance Characteristics ............................................. 7

Theory of Operation ...................................................................... 13

Switch Configurations ............................................................... 13

Receive Equalization .................................................................. 14

REVISION HISTORY

4/07—Revision 0: Initial Version.

Rev. 0 | Page 2 of 24

AD8153

SPECIFICATIONS

V_CC= V_TTI= V_TTO= 3.3 V, V_EE= 0 V, R_L= 50 Ω, two outputs active with no pre-emphasis, data rate = 3.2 Gbps, ac-coupled, PRBS7 test

pattern, V_ID= 800 mV p-p, T_A= 25°C, unless otherwise noted.¹

Table 1.

Parameter

Conditions

Min

Typ

Max

Unit

DYNAMIC PERFORMANCE

Data Rate/Channel (NRZ)

Deterministic Jitter

Random Jitter

Propagation Delay

Lane-to-Lane Skew

Switching Time

DC

3.2

Gbps

ps p-p

fs

ps

Data rate = 3.2 Gbps, high EQ

RMS, high EQ

Input to output

16

500

640

55

5

ns

Output Rise/Fall Time

INPUT CHARACTERISTICS

Input Voltage Swing

Input Voltage Range

Input Capacitance

20% to 80%

85

ps

Differential

Common mode, V_ID= 800 mV p-p

200

V_EE+ 1.0

2000

V_CC+ 0.3

mV p-p

V

pF

2

OUTPUT CHARACTERISTICS

Output Voltage Swing

Output Voltage Range

Output Current

Differential, @ dc

Single-ended absolute voltage level

No pre-emphasis

700

V_cc− 1.6

800

900

V_cc+ 0.6

mV p-p

V

mA

pF

16

28

2

Output Current

Maximum pre-emphasis, all ports

Output Capacitance

TERMINATION CHARACTERISTICS

Resistance

Differential

100

0.1

Ω

Ω/°C

Temperature Coefficient

POWER SUPPLY

Operating Range

V_CC

V_TTI

V_TTO

V_EE= 0 V

3.0

3.3

V_CC

3.6

V

Supply Current

I_CC

I_I/O= I_TTO+ I_TTI

Two outputs active, no pre-emphasis, 400 mV I/O swings

(800 mV p-p differential)

27

26

31

32

35

39

mA

Supply Current

I_CC

I_I/O= I_TTO+ I_TTI

Three outputs active, maximum pre-emphasis, 400 mV

I/O swings (800 mV p-p differential)

53

74

58

84

63

95

mA

THERMAL CHARACTERISTICS

Operating Temperature Range

θ_JA

−40

+85

°C

°C/W

Still air

30.0

LOGIC INPUT CHARACTERISTICS

Input High (V_IH)

Input Low (V_IL)

2.4

V_EE

V_CC

0.8

V

¹V_ID: Input differential voltage swing.

Rev. 0 | Page 3 of 24

AD8153

I²C TIMING SPECIFICATIONS

SDA

t

BUF

r

t

HD;STA

SP

f

SU;DAT

t

f

t_LOW

t

r

SCL

t

SU;STO

t

HD;STA

SU;STA

t

HIGH

HD;DAT

S

Sr

P

S

Figure 2. I²C Timing Diagram

Table 2.

Parameter

SCL Clock Frequency

Hold Time for a Start Condition

Set-up Time for a Repeated Start Condition

Low Period of the SCL Clock

High Period of the SCL Clock

Data Hold Time

Symbol

f_SCL

Min

0

Max

Unit

kHz

μs

ns

μs

ns

pF

400+

–

300

–

7

t_HD;STA

t_SU;STA

t_LOW

t_HIGH

t_HD;DAT

t_SU;DAT

t_r

0.6

1.3

0.6

0

10

1

Data Set-Up Time

Rise Time for Both SDA and SCL

Fall Time for Both SDA and SCL

Set-Up Time for Stop Condition

Bus Free Time Between a Stop Condition and a Start Condition

Capacitance for Each I/O Pin

t_f

t_SU;STO

t_BUF

C_i

0.6

1

5

Rev. 0 | Page 4 of 24

AD8153

ABSOLUTE MAXIMUM RATINGS

Table 3.

Stresses above those listed under Absolute Maximum Ratings

may cause permanent damage to the device. This is a stress

rating only; functional operation of the device at these or any

other conditions above those indicated in the operational

section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect

device reliability.

Parameter

Rating

V_CCto V_EE

3.7 V

V_TTI

V_CC+ 0.6 V

V_TTO

V_CC+ 0.6 V

Internal Power Dissipation

Differential Input Voltage

Logic Input Voltage

Storage Temperature Range

Lead Temperature

Junction Temperature

4.1 W

2.0 V

V_EE− 0.3V < V_IN< V_CC+ 0.6 V

−65°C to +125°C

300°C

ESD CAUTION

150°C

Rev. 0 | Page 5 of 24

AD8153

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

VCC

VTTO

ONA

OPA

VTTI

INA

1

2

3

4

5

6

7

8

24 MODE

23 RESETB

22 SEL

21 BICAST

20 LB_A

19 LB_B

18 LB_C

17 EQ_A/(SCL)

PIN 1

INDICATOR

AD8153

TOP VIEW

IPA

VEE

NOTE

EPAD NEEDS TO BE ELECTRICALLY

CONNECTED TO VEE.

Figure 3. Pin Configuration

Table 4. Pin Function Descriptions

Pin No.

Mnemonic

Type

Power

I/O

Description

1, 9, 12

2

3

4

VCC

VTTO

ONA

OPA

Positive Supply.

Output Termination Supply.

High Speed Output Complement.

High Speed Output.

I/O

5

6

7

VTTI

INA

IPA

Power

I/O

Input Termination Supply.

High Speed Input Complement.

High Speed Input.

8, 32, EPAD

10

11

VEE

ONB

OPB

Power

I/O

Negative Supply.

High Speed Output Complement.

High Speed Output.

13

14

INB

IPB

I/O

High Speed Input Complement.

High Speed Input.

15

16

17

18

19

20

21

22

23

24

25

26

27

28

EQ_C

Control

I/O

Port C Input Equalization Control.

Port B Input Equalization Control/(I²C Data when MODE = 1).

Port A Input Equalization Control/(I²C Clock when MODE = 1).

Port C Loopback Enable.

Port B Loopback Enable.

Port A Loopback Enable.

EQ_B/(SDA)

EQ_A/(SCL)

LB_C

LB_B

LB_A

BICAST

SEL

Bicast Enable.

A/B Select.

RESETB

MODE

PE_C/(I2C_A[2])

PE_B/(I2C_A[1])

ONC

Configuration Registers Reset.

Configuration Mode. 1 for Serial/Mixed Mode, 0 for Pin Mode.

Port C Pre-Emphasis Control/(I²C Slave Address Bit 2 when MODE = 1).

Port B Pre-Emphasis Control/(I²C Slave Address Bit 1 when MODE = 1).

High Speed Output Complement.

High Speed Output.

OPC

I/O

29

30

31

PE_A/(I2C_A[0])

INC

IPC

Control

I/O

Port A Pre-Emphasis Control/(I²C Slave Address Bit 0 when MODE = 1).

High Speed Input Complement.

High Speed Output.

Rev. 0 | Page 6 of 24

AD8153

TYPICAL PERFORMANCE CHARACTERISTICS

V_CC= V_TTI= V_TTO=3.3 V, V_EE= 0 V, R_L= 50 Ω, two outputs active with no pre-emphasis, high EQ, data rate = 3.2 Gbps, ac-coupled,

PRBS7 test pattern, V_ID= 800 mV p-p, T_A= 25°C, unless otherwise noted.

50Ω CABLES

2

INPUT

OUTPUT

DATA OUT

50Ω

HIGH-SPEED

SAMPLING

AD8153

AC COUPLED

EVALUATION

BOARD

PATTERN

GENERATOR

TP1

TP2

OSCILLOSCOPE

Figure 4. Standard Test Circuit (No Channel)

40ps/DIV

Figure 6. 3.2 Gbps Output Eye, No Channel

(TP2 from Figure 4)

Figure 5. 3.2 Gbps Input Eye

(TP1 from Figure 4)

Rev. 0 | Page 7 of 24

AD8153

50Ω CABLES

2

INPUT OUTPUT

PIN PIN

DATA OUT

FR4 TEST BACKPLANE

50Ω

HIGH-

SPEED

SAMPLING

OSCILLOSCOPE

DIFFERENTIAL

STRIPLINE TRACES

8mils WIDE, 8mils SPACE,

8mils DIELECTRIC HEIGHT

TRACE LENGTHS = 20 INCHES,

40 INCHES

AD8153

AC COUPLED

EVALUATION

BOARD

PATTERN

GENERATOR

TP1

TP2

TP3

40ps/DIV

REFERENCE EYE DIAGRAM AT TP1

Figure 7. Input Equalization Test Circuit

40ps/DIV

Figure 10. 3.2 Gbps Output Eye, 20 Inch FR4 Input Channel, High EQ

(TP3 from Figure 7)

Figure 8. 3.2 Gbps Input Eye, 20 Inch FR4 Input Channel

(TP2 from Figure 7)

40ps/DIV

Figure 11. 3.2 Gbps Output Eye, 40 Inch FR4 Input Channel, High EQ

(TP3 from Figure 7)

Figure 9. 3.2 Gbps Input Eye, 40 Inch FR4 Input Channel

(TP2 from Figure 7)

Rev. 0 | Page 8 of 24

AD8153

50Ω CABLES

2

INPUT OUTPUT

PIN PIN

DATA OUT

FR4 TEST BACKPLANE

50Ω

HIGH-

SPEED

SAMPLING

OSCILLOSCOPE

DIFFERENTIAL

STRIPLINE TRACES

8mils WIDE, 8mils SPACE,

8mils DIELECTRIC HEIGHT

TRACE LENGTHS = 20 INCHES,

40 INCHES

AD8153

AC COUPLED

EVALUATION

BOARD

PATTERN

GENERATOR

TP1

TP2

TP3

40ps/DIV

REFERENCE EYE DIAGRAM AT TP1

Figure 12. Output Pre-Emphasis Test Circuit

40ps/DIV

Figure 15. 3.2 Gbps Output Eye, 20 Inch FR4 Output Channel, PE = 2

(TP3 from Figure 12)

Figure 13. 3.2 Gbps Output Eye, Pre-Channel, PE = 2

(TP2 from Figure 12)

40ps/DIV

Figure 14. 3.2 Gbps Output Eye, Pre-Channel, PE = 3

(TP2 from Figure 12)

Figure 16. 3.2 Gbps Output Eye, 40 Inch FR4 Output Channel, PE = 3

(TP3 from Figure 12)

Rev. 0 | Page 9 of 24

AD8153

80

70

60

50

40

30

20

10

80

70

60

50

40

30

20

10

0

PE = 1

PE = 0

PE = 2

LOW EQ

PE = 3

HIGH EQ

0

10

20

30

40

0

10

20

30

40

FR4 INPUT CHANNEL LENGTH (IN)

FR4 OUTPUT CHANNEL LENGTH (IN)

Figure 17. Deterministic Jitter vs. FR4 Input Channel Length

Figure 20. Deterministic Jitter vs. FR4 Output Channel Length

80

20

15

10

SAMPLES: 557k

70

60

50

40

30

20

10

DETERMINISTIC JITTER

5

0

RANDOM JITTER

2.5

0

1.0

1.5

2.0

3.0

3.5

4.0

–2ps

–1ps

0.0s

1ps

2ps

DATA RATE (Gbps)

Figure 18. Jitter vs. Data Rate

Figure 21. Random Jitter Histogram, 3.2 Gbps

80

70

60

50

40

30

20

10

80

70

60

50

40

30

20

10

DETERMINISTIC JITTER

RANDOM JITTER

DETERMINISTIC JITTER

RANDOM JITTER

0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

1.8

2.0

0.8

1.3

1.8

2.3

2.8

3.3

3.8

DIFFERENTIAL INPUT SWING (V)

INPUT COMMON-MODE VOLTAGE (V)

Figure 19. Jitter vs. Differential Input Swing

Figure 22. Jitter vs. Input Common-Mode Voltage

Rev. 0 | Page 10 of 24

AD8153

80

70

60

50

40

30

20

10

80

70

60

50

40

30

20

10

0

DETERMINISTIC JITTER

RANDOM JITTER

DETERMINISTIC JITTER

RANDOM JITTER

0

3.0

3.1

3.2

3.3

(V)

3.4

3.5

3.6

2

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

V

VTTO (V)

CC

Figure 26. Jitter vs. Output Termination Voltage

Figure 23. Jitter vs. Core Supply Voltage

100

95

90

85

80

75

80

70

60

50

40

30

20

10

DETERMINISTIC JITTER

RANDOM JITTER

0

–40

–20

0

20

40

60

80

100

–40

–20

0

20

40

60

80

100

TEMPERATURE (°C)

Figure 27. Rise/Fall Time vs. Temperature

Figure 24. Jitter vs. Temperature

700

650

600

700

650

600

550

500

550

500

–40

–20

0

20

40

60

80

100

3.0

3.1

3.2

3.3

(V)

3.4

3.5

3.6

TEMPERATURE (°C)

V

CC

Figure 25. Propagation Delay vs. Core Supply Voltage

Figure 28. Propagation Delay vs. Temperature

Rev. 0 | Page 11 of 24

AD8153

1000

900

800

700

600

500

400

300

200

100

700

600

500

400

300

200

100

0

3.0

3.1

3.2

3.3

(V)

3.4

3.5

3.6

0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

V

DATA RATE (Gbps)

CC

Figure 30. Eye Height vs. Data Rate

Figure 29. Eye Height vs. Core Supply Voltage

Rev. 0 | Page 12 of 24

AD8153

THEORY OF OPERATION

The AD8153 consists of a 2:1 multiplexer and a 1:2 demultiplexer.

There are three operating modes: pin mode, serial mode, and

mixed mode. In pin mode, lane switching, equalization, and

pre-emphasis are controlled using external pins. In serial mode,

an I²C interface is used to control the device and to provide

access to advanced features, such as additional pre-emphasis

settings and output disable. In mixed mode, the user accesses

the advanced features using I²C but controls lane switching

using external pins.

side, the device relays received data on either Input Port A or Input

Port B to Output Port C, depending on the state of the SEL bit.

When bicast mode is off, the outputs of either Port A or Port B

are in an idle state. In the idle state, the output tail current is set

to 0, and the P and N sides of the lane are pulled up to the output

termination voltage through the on-chip termination resistors.

The device also supports loopback on all ports, illustrated in

Figure 31. Enabling loopback on any port overrides configurations

set by the BICAST and SEL control bits. Table 5 summarizes the

possible switch configurations.

SWITCH CONFIGURATIONS

On the demultiplexer side, the AD8153 relays received data on

Input Port C to Output Port A and/or Output Port B, depending

on the state of the BICAST and SEL bits. On the multiplexer

The AD8153 output disable feature can be used to force an

output into the idle (powered-down) state. This feature is only

accessible through the serial control interface.

OUTPUT A

1:2 DEMUX

INPUT C

PORT C LOOPLOCK

OUTPUT C

OUTPUT B

PORT A LOOPBACK

PORT B LOOPBACK

INPUT A

INPUT B

2:1 MUX

Figure 31. Loopback Configurations

Table 5. Switch Configurations

LB_A

LB_B

LB_C

SEL

0

1

0

X

1

0

1

0

1

X

0

1

0

BICAST

Output A

Output B

Idle

Input C

Idle

Input C

Input B

Idle

Output C

Input A

Input B

Input C

Input A

Input B

Input C

Input A

Input B

Input C

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

X

0

1

X

0

1

0

1

X

0

Input C

Idle

Input C

Idle

Input C

Idle

Input C

Idle

Input C

Input A

Input C

Idle

0

1

Rev. 0 | Page 13 of 24

AD8153

LB_A

LB_B

LB_C

SEL

X

1

0

1

BICAST

Output A

Input A

Output B

Input C

Input B

Output C

Input C

Input A

Input B

Input C

1

0

1

0

1

X

RECEIVE EQUALIZATION

TRANSMIT PRE-EMPHASIS

In backplane applications, the AD8153 needs to compensate for

signal degradation caused by long traces. The device supports

two levels of input equalization, configured on a per-port basis.

Table 6 summarizes the high-frequency asymptotic gain boost

for each setting.

Transmitter pre-emphasis levels can be set by pin control or

through the control registers when using the I²C interface. Pin

control allows two settings of PE. The control registers provide

two additional settings.

Table 7. Pre-Emphasis Settings

Table 6. Receive Equalization Settings

Serial Mode

Pin Mode

EQ_A/B/C

EQ Boost

PE_A/B/C Setting PE_A/B/C PE Boost (%) PE Boost (dB)

0

1

6 dB

12 dB

0

1

2

3

0

N/A

1

25

50

75

1.9

3.5

4.9

N/A

Rev. 0 | Page 14 of 24

AD8153

I²C SERIAL CONTROL INTERFACE

pins or the internal register set. The source of the control is

REGISTER SET

selected using the mask bits (Register 0x00). If a mask bit is set

to 0, the external pin acts as the source for that specific control.

If a mask bit is set to 1, the associated internal register acts as

the source for that specific control. As an example, if Register 0x00

were set to the value 0x0C, the SEL and LB_C controls would

come from the internal register set (Bit 0 of Register 0x04 and Bit

3 of Register 0x03, respectively), and the BICAST, LB_A, and

LB_B controls would come from the external pins.

The AD8153 can be controlled in one of three modes: pin

mode, serial mode, and mixed mode. In pin mode, the AD8153

control is derived from the package pins, whereas in serial

mode a set of internal registers controls the AD8153. There is

also a mixed mode where switching is controlled via external

pins, and equalization and pre-emphasis are controlled via the

internal registers. The methods for writing data to and reading

data from the AD8153 are described in the I²C Data Write

section and the I²C Data Read section.

GENERAL FUNCTIONALITY

The mode is controlled via the MODE pin. To set the part in

pin mode, MODE should be driven low to VEE. When MODE

is driven high to VCC, the part is set to serial or mixed mode.

The AD8153 register set is controlled through a 2-wire I²C

interface. The AD8153 acts only as an I²C slave device. Therefore,

the I²C bus in the system needs to include an I²C master to

configure the AD8153 and other I²C devices that may be on the

bus. When the MODE pin is set to a Logic 1, data transfers are

controlled through the use of the two I²C wires: the input clock

pin, SCL, and the bidirectional data pin, SDA.

The AD8153 I²C interface can be run in the standard (100 kHz)

and fast (400 kHz) modes. The SDA line only changes value

when the SCL pin is low with two exceptions. To indicate the

beginning or continuation of a transfer, the SDA pin is driven

low while the SCL pin is high, and to indicate the end of a

transfer, the SDA line is driven high while the SCL line is high.

Therefore, it is important to control the SCL clock to only

toggle when the SDA line is stable unless indicating a start,

repeated start, or stop condition.

In pin mode, all controls are derived from the external pins. In

serial mode, each channel’s equalization and pre-emphasis are

controlled only through the registers, as described in Table 8.

Additionally, further functionality is available in serial mode as

each channel’s output can be enabled/disabled with the Output

Enable control bits, which is not possible in pin mode. To

change the switching in the AD8153 to serial mode, the mask

bits (Register 0x00) must be set to 1 by writing the value 0x1F to

this register, as explained in the following sections. Once all the

mask bits are set to 1, switching is controlled via the LB_A,

LB_B, LB_C, SEL, and BICAST bits in the register set.

In mixed mode, each channel’s equalization and pre-emphasis

are controlled through the registers as described above. The

switching, however, can be controlled using either the external

Table 8. Register Map

Address

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Default

00000000

(0x00)

00000000

(0x00)

BICAST MASK

SEL MASK

LB_C MASK

LB_B MASK

LB_A MASK

00000001

(0x01)

00000000

(0x00)

OUTPUT DISABLE A

OUTPUT DISABLE B

OUTPUT DISABLE C

LB_A

LB_B

LB_C

EQ_A

EQ_B

EQ_C

PE_A [1]

PE_B [1]

PE_C [1]

BICAST

PE_A [0]

PE_B [0]

PE_C [0]

SEL

00000010

(0x02)

00000000

(0x00)

00000011

(0x03)

00000000

(0x00)

0000100

(0x04)

00000000

(0x00)

Rev. 0 | Page 15 of 24

AD8153

10. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low) and continue with Step 2 in this

procedure to perform another write.

I²C DATA WRITE

To write data to the AD8153 register set, a microcontroller, or

any other I²C master, needs to send the appropriate control

signals to the AD8153 slave device. The steps that need to be

followed are listed below, where the signals are controlled by the

I²C master unless otherwise specified. A diagram of the procedure

is shown in Figure 32.

11. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low) and continue with Step 2 of the

read procedure (in the I²C Data Read section) to perform a

read from another address.

12. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low) and continue with step 8 of the

read procedure (in the I²C Data Read section) to perform a

read from the same address set in Step 5.

1. Send a start condition (while holding the SCL line high, pull

the SDA line low).

2. Send the AD8153 part address (seven bits) whose upper

four bits are the static value b1001 and whose lower three

bits are controlled by the input pins I2C_A[2:0]. This

transfer should be MSB first.

The AD8153 write process is shown in Figure 32. The SCL

signal is shown along with a general write operation and a

specific example. In the example, data 0x92 is written to

Address 0x6D of an AD8153 part with a part address of 0x4B.

The part address is seven bits wide and is composed of the

AD8153 static upper four bits (b1001) and the pin

programmable lower three bits (I2C_ADDR[2:0]). In this

example, the I2C_ADDR bits are set to b011. In Figure 32, the

corresponding step number is visible in the circle under the

waveform. The SCL line is driven by the I²C master and never

by the AD8153 slave. As for the SDA line, the data in the shaded

polygons is driven by the AD8153, whereas the data in the non-

shaded polygons is driven by the I²C master. The end phase case

shown is that of 9a.

3. Send the write indicator bit (0).

4. Wait for the AD8153 to acknowledge the request.

5. Send the register address (eight bits) to which data is to be

written. This transfer should be MSB first.

6. Wait for the AD8153 to acknowledge the request.

7. Send the data (eight bits) to be written to the register whose

address was set in Step 5. This transfer should be MSB first.

8. Wait for the AD8153 to acknowledge the request.

9. Send a stop condition (while holding the SCL line high, pull

the SDA line high) and release control of the bus.

It is important to note that the SDA line only changes when the

SCL line is low, except for the case of sending a start, stop, or

repeated start condition, Step 1 and Step 9 in this case.

SCL

ADDR

[2:0]

SDA

START FIXED PART ADDR

RW

REGISTER ADDR

ACK

DATA

ACK STOP

ACK

(GENERAL CASE)

SDA

(EXAMPLE)

1

2

3

4

5

6

7

8

9a

Figure 32. I²C Write Diagram

Rev. 0 | Page 16 of 24

AD8153

12. Acknowledge the data.

I²C DATA READ

13. Send a stop condition (while holding the SCL line high, pull

the SDA line high) and release control of the bus.

To read data from the AD8153 register set, a microcontroller, or

any other I²C master, needs to send the appropriate control

signals to the AD8153 slave device. The steps to be followed are

listed below, where the signals are controlled by the I²C master

unless otherwise specified. A diagram of the procedure can be

seen in Figure 33.

14. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low) and continue with Step 2 of the

write procedure (see the I²C Data Write section) to perform

a write.

1. Send a start condition (while holding the SCL line high, pull

the SDA line low).

15. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low) and continue with Step 2 of this

procedure to perform a read from another address.

2. Send the AD8153 part address (seven bits) whose upper

four bits are the static value b1001 and whose lower three

bits are controlled by the input pins I2C_ADDR[2:0]. This

transfer should be MSB first.

16. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low) and continue with Step 8 of this

procedure to perform a read from the same address.

3. Send the write indicator bit (0).

The AD8153 read process is shown in Figure 33. The SCL signal

is shown along with a general read operation and a specific

example. In the example, Data 0x49 is read from Address 0x6D

of an AD8153 part with a part address of 0x4B. The part address is

seven bits wide and is composed of the AD8153 static upper

four bits (b1001) and the pin programmable lower three bits

(I2C_ADDR[2:0]). In this example, the I2C_ADDR bits are set

to b011. In Figure 33, the corresponding step number is visible

in the circle under the waveform. The SCL line is driven by the

I²C master and never by the AD8153 slave. As for the SDA line,

the data in the shaded polygons is driven by the AD8153,

whereas the data in the nonshaded polygons is driven by the I²C

master. The end phase case shown is that of 13a.

4. Wait for the AD8153 to acknowledge the request.

5. Send the register address (eight bits) from which data is to

be read. This transfer should be MSB first. The register

address is kept in memory in the AD8153 until the part is

reset or the register address is written over with the same

procedure (Step 1 to Step 6).

6. Wait for the AD8153 to acknowledge the request.

7. Send a repeated start condition (while holding the SCL line

high, pull the SDA line low).

8. Send the AD8153 part address (seven bits) whose upper

four bits are the static value b1001 and whose lower three

bits are controlled by the input pins I2C_ADDR[1:0]. This

transfer should be MSB first.

It is important to note that the SDA line only changes when the

SCL line is low, except for the case of sending a start, stop, or

repeated start condition, as in Step 1, Step 7, and Step 13. In

Figure 33, A is the same as ACK in Figure 32. Equally, Sr

represents a repeated start where the SDA line is brought high

before SCL is raised. SDA is then dropped while SCL is still high.

9. Send the read indicator bit (1).

10. Wait for the AD8153 to acknowledge the request.

11. The AD8153 then serially transfers the data (eight bits) held

in the register indicated by the address set in Step 5.

SCL

ADDR

[2:0]

ADDR

[2:0]

SDA

R

FIXED PART

ADDR

FIXED PART

ADDR

A

START

REGISTER ADDR

A

6

DATA

A

STOP

13a

Sr

W

(GENERAL CASE)

SDA

(EXAMPLE)

1

2

3

4

5

7

8

9

10

11

12

Figure 33. I²C Read Diagram

Rev. 0 | Page 17 of 24

AD8153

APPLICATIONS INFORMATION

The main application of the AD8153 is to support redundancy

on both the backplane side and the line interface side of a serial

link. Figure 34 illustrates redundancy in a typical backplane

system. Each line card is connected to two switch fabrics

(primary and redundant). The device can be configured to

support either 1 + 1 or 1:1 redundancy.

Another application for the AD8153 is in test equipment for

evaluating high speed serial links. Figure 36 illustrates a

possible application of the AD8153 in a simple link tester.

PRIMARY

SWITCH

FABRIC

PHYSICAL

DIGITAL ENGINE

INTERFACE

AD8153

LINE CARDS

REDUNDANT

SWITCH

FABRIC

PHYSICAL

INTERFACE

DIGITAL ENGINE

AD8153

FABRIC CARDS

BACKPLANE

Figure 34. Switch Redundancy Application

SFP

CDR

PROCESSING

ENGINE/CROSSBAR/

BACKPLANE

CDR

AD8153

Figure 35. Line Interface Redundancy Application

DUT

CONNECTOR

AD8153

PROTOCOL

ANALYZER

FPGA

Figure 36. Test Equipment Application

Rev. 0 | Page 18 of 24

AD8153

PCB DESIGN GUIDELINES

Proper RF PCB design techniques must be used for optimal

performance.

Transmission Lines

Use of 50 Ω transmission lines is required for all high frequency

input and output signals to minimize reflections. It is also

necessary for the high speed pairs of differential input traces to

be matched in length, as well as the high speed pairs of differential

output traces, to avoid skew between the differential traces.

Power Supply Connections and Ground Planes

Use of one low impedance ground plane is recommended. The

VEE pins should be soldered directly to the ground plane to

reduce series inductance. If the ground plane is an internal

plane and connections to the ground plane are made through

vias, multiple vias can be used in parallel to reduce the series

inductance. The exposed pad should be connected to the VEE

plane using plugged vias so that solder does not leak through

the vias during reflow.

Soldering Guidelines for Chip Scale Package

The lands on the 32-lead LFCSP are rectangular. The printed

circuit board pad for these should be 0.1 mm longer than the

package land length and 0.05 mm wider than the package land

width. The land should be centered on the pad. This ensures

that the solder joint size is maximized. The bottom of the chip

scale package has a central exposed pad. The pad on the printed

circuit board should be at least as large as this exposed pad. The

user must connect the exposed pad to VEE using plugged vias

so that solder does not leak through the vias during reflow. This

ensures a solid connection from the exposed pad to VEE.

Use of a 10 μF electrolytic capacitor between VCC and VEE is

recommended at the location where the 3.3 V supply enters the

PCB. It is recommended that 0.1 μF and 1 nF ceramic chip

capacitors be placed in parallel at each supply pin for high

frequency power supply decoupling. When using 0.1 μF and 1 nF

ceramic chip capacitors, they should be placed between the IC

power supply pins (VCC, VTTI, VTTO) and VEE, as close as

possible to the supply pins.

By using adjacent power supply and GND planes, excellent high

frequency decoupling can be realized by using close spacing

between the planes. This capacitance is given by

C_PLANE= 0.88ε_rA/d (pF)

where:

ε_ris the dielectric constant of the PCB material.

A is the area of the overlap of power and GND planes (cm²).

d is the separation between planes (mm).

For FR4, ε_r= 4.4 and 0.25 mm spacing, C ~15 pF/cm².

Rev. 0 | Page 19 of 24

AD8153

INTERFACING TO THE AD8153

TERMINATION STRUCTURES

AC Coupling

One way to simplify the input circuit and make it compatible

with a wide variety of driving devices is to use ac coupling. This

has the effect of isolating the dc common-mode levels of the

driver and the AD8153 input circuitry. AC coupling requires a

capacitor in series with each single-ended input signal, as shown

in Figure 39. This should be done in a manner that does not

interfere with the high speed signal integrity of the PCB.

To determine the best strategy for connecting to the high speed

pins of the AD8153, the user must first be familiar with the on-

chip termination structures. The AD8153 contains two types of

these structures: one type for input ports and one type for output

ports (see Figure 37 and Figure 38).

VCC

V

CC

TTI

CC

VTTI

55Ω

50Ω

55Ω

C

P

IP

IN

IPX

INX

C

N

1173Ω

VEE

AD8153

VEE

DRIVER

Figure 37. Receiver Simplified Diagram

Figure 39. AC-Coupling Input Signal of AD8153

When ac coupling is used, the common-mode level at the input

of the device is equal to V_TTI. The single-ended input signal

swings above and below V_TTIequally. The user can then use

the specifications in Table 1 to determine the input signal swing

levels that satisfy the input range of the AD8153.

VCC

VTTO

50Ω

OPX

ONX

If dc coupling is required, determining the input common-

mode level is less straightforward because the configuration of

the driver must also be considered. In most cases, the user

would set V_TTIon the AD8153 to the same level as the driver

output termination voltage. This prevents a continuous dc

current from flowing between the two supply nets. As a

practical matter, both devices can be terminated to the same

physical supply net.

V

IP

IN

I

T

VEE

Figure 38. Transmitter Simplified Diagram

Consider the following example: a driver is dc-coupled to the

input of the AD8153. The AD8153 input termination voltage

(V_TTI) and the driver output termination voltage (V_TTOD) are both

set to the same level; that is, V_TTI= V_TTOD= 3.3 V. If an 800 mV

differential p-p swing is desired, the total output current of the

driver is 16 mA. At balance, the output current is divided evenly

between the two sides of the differential signal path, 8 mA to each

side. This 8 mA of current flows through the parallel combina-

tion of the 55 Ω input termination resistor on the AD8153 and

the 50 Ω output termination resistor on the driver, resulting in a

common-mode level of

For input ports, the termination structure consists of two 55 Ω

resistors connected to a termination supply and an 1173 Ω

resistor connected across the differential inputs, the latter being

a result of the finite differential input impedance of the equalizer.

For output ports, there are two 50 Ω resistors connected to the

termination supply. Note that the differential input resistance

for both structures is the same, 100 Ω.

INPUT COMPLIANCE

The range of allowable input voltages is determined by the

fundamental limitations of the active input circuitry. This range

of signals is normally a function of the common-mode level of

the input signal, the signal swing, and the supply voltage. For a

given input signal swing, there is a range of common-mode

voltages that keeps the high and low voltage excursions within

acceptable limits. Similarly, for a given common-mode input

voltage, there is a maximum acceptable input signal swing.

There is also a minimum signal swing that the active input

circuitry can resolve reliably. The specifications are found in

Table 1.

V

_TTI− 8 mA × (50 Ω || 55 Ω) = V_TTI− 209 mV

The user can then determine the allowable range of values for V_TTI

that meets the input compliance range based on an 800 mV p-p

differential swing.

Rev. 0 | Page 20 of 24

AD8153

Table 9 shows an example calculation of the output levels for the

typical case, where V_CC= V_TTO= 3.3 V, with 50 Ω far-end

terminations to a 3.3 V supply.

OUTPUT COMPLIANCE

Figure 40 is a graphical depiction of the single-ended waveform

at the output of the AD8153. The common-mode level (V_OCM

)

and the amplitude (V_OSE) of this waveform are a function of the

output tail current (I_T), the output termination supply voltage

(V_TTO), the topology of the far-end receiver, and whether ac- or

dc-coupling is used. Keep in mind that the output tail current

varies with the pre-emphasis level. The user must ensure that

the high (V_H) and low (V_L) voltage excursions at the output are

within the single-ended absolute voltage range limits as

V

TTO

V

H

V

OCM

V

OSE-DC

V

OSE-BOOST

V

L

~320ps

specified in Table 1. Failure to understand the implications of

output signal levels and the choice of ac- or dc-coupling may

lead to transistor saturation and poor transmitter performance.

Figure 40. Single-Ended Output Waveform

Table 9. Output Voltage Levels

DC-Coupled

AC-Coupled

PE Setting

I_T(mA)

16

20

24

28

V_OSE-DC(mV p-p)

V_OSE-BOOST(mV p-p)

V_OCM(V)

3.1

3.05

3

V_H(V)

3.3

V_L(V)

2.9

2.8

2.7

2.6

V_OCM(V)

2.9

2.8

2.7

2.6

V_H(V)

3.1

3.05

3

V_L(V)

2.7

2.55

2.4

0

1

2

3

400

500

600

700

2.95

2.25

Table 10. Symbol Definitions

Symbol

Formula

Definition

V_OSE-DC

Single-ended output voltage swing after settling

I_{T PE=0}× 25Ω

V_OSE-BOOST

Boosted single-ended output voltage swing

I_T×25Ω

V_OCM(dc-coupled)

Common-mode voltage when the output is dc-coupled

I_T

V_TTO

−

×25Ω

×50Ω

2

I_T

2

V_OCM(ac-coupled)

Common-mode voltage when the output is ac-coupled

V_H

V_L

High single-ended output voltage excursion

Low single-ended output voltage excursion

V_OCM+ V_OSE-BOOST/2

V_OCM- V_OSE-BOOST/2

Rev. 0 | Page 21 of 24

AD8153

OUTLINE DIMENSIONS

5.00

BSC SQ

0.60 MAX

PIN 1

INDICATOR

25

32

1

24

0.50

BSC

PIN 1

INDICATOR

TOP

VIEW

2.85

2.70 SQ

2.55

*

4.75

BSC SQ

EXPOSED

PAD

(BOT TOM VIEW)

0.50

0.40

0.30

17

16

8

9

0.20 MIN

3.50 REF

0.80 MAX

1.00

0.85

0.80

12° MAX

0.65 TYP

0.05 MAX

0.02 NOM

0.30

0.25

0.18

SEATING

PLANE

COPLANARITY

0.08

0.20 REF

COMPLIANT TO JEDEC STANDARDS MO-220-VHHD-2

*

THE AD8153 HAS A CONDUCTIVE HEAT SLUG TO HELP DISSIPATE HEAT AND ENSURE RELIABLE OPERATION OF

THE DEVICE OVER THE FULL INDUSTRIAL TEMPERATURE RANGE. THE SLUG IS EXPOSED ON THE BOTTOM OF

THE PACKAGE AND ELECTRICALLY CONNECTED TO V . IT IS RECOMMENDED THAT NO PCB SIGNAL

EE

TRACES OR VIAS BE LOCATED UNDER THE PACKAGE THAT COULD COME IN CONTACT WITH THE CONDUCTIVE

SLUG.

Figure 41. 32-Lead Lead Frame Chip Scale Package [LFCSP_VQ]

5 mm × 5 mm Body, Very Thin Quad

(CP-32-8)

Dimensions shown in millimeters

ORDERING GUIDE

Model

AD8153ACPZ¹

Temperature Range

Package Description

Package Option

CP-32-8

−40°C to +85°C

32-Lead Lead Frame Chip Scale Package [LFCSP_VQ]

Evaluation Board

AD8153ACPZ-RL7¹−40°C to +85°C

AD8153-EVALZ¹

¹Z = RoHS Compliant Part.

Rev. 0 | Page 22 of 24

AD8153

NOTES

Rev. 0 | Page 23 of 24

AD8153

NOTES

registered trademarks are the property of their respective owners.

D06393-0-4/07(0)

Rev. 0 | Page 24 of 24


型号：	AD8153ACPZ
厂家：	ADI
描述：	3.2 Gbps Single Buffered Mux/Demux Switch 3.2 Gbps的一个缓冲器，复用器/解复用器开关解复用器开关 ATM集成电路 SONET集成电路 SDH集成电路电信集成电路电信电路异步传输模式
文件：	总24页 (文件大小：719K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

AD8153ACPZ [ADI]

相关型号：

AD8153ACPZ-RL7

AD8153_07

AD8155

AD8155-EVALZ

AD8155ACPZ

AD8155ACPZ-R7

AD8156

AD8156-EVALZ

AD8156ABCZ

AD8158

AD8158-EVALZ

AD8158ACPZ