TPD-MR-04-36CDF5A [SOURCE]

Transponder, 1528nm Min, 1565nm Max, 9953Mbps(Tx), 9953Mbps(Rx), FC Connector, Panel Mount;


型号：	TPD-MR-04-36CDF5A
厂家：	SOURCE PHOTONICS, INC.
描述：	Transponder, 1528nm Min, 1565nm Max, 9953Mbps(Tx), 9953Mbps(Rx), FC Connector, Panel Mount 通信光纤
文件：	总12页 (文件大小：570K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

TPD-MR-04-XXXXXXXX

Features

Description



Compliant with the 300 pin SFF MSA

TPD-MR-04-XXXXX C-band DWDM 300 pin SFF

transponder is intended for DWDM system

applications with reaches of up to 40km, which

provide multi-rate from 9.95Gbps to 11.3Gbps.

Support multi-rate from 9.953Gb/s to 11.3Gbps

C-band DWDM laser and PIN/APD receiver

100GHz channel spacing

800ps/nm chromatic dispersion

16-bit parallel 622.08Mbps LVDS data interface

Compliant I2C MSA (Edition 4.0) interface for

monitoring/control

The transmitter converts the electrical data into

10Gbit/s optical signal, which uses externally EA

modulated laser with specified driving circuit.



Supply voltage: +5.0V, +3.3V, +1.8V

Operating case temperature: -5℃ to +70℃

At the receiving side, the incoming data stream is

received at 10Gb/s PIN/APD receiver, which

converts it into a 10Gb/s electrical data stream.

Applications



Metro and Long haul DWDM system

The MUX section multiplexes 16 parallel 622Mb/s

electrical channels into a 10Gb/s series data stream

and sent it to the transmitter. And the DEMUX

section demultiplexes the 10Gb/s electrical data

stream into 16 parallel 622Mb/s electrical channels.

The parallel data is sent out to and get from the

300-pin MSA (Multi Source Agreement) compliant

connector.

Forward Error Correction (FEC) system

Optical Transport Network (OTN) System

Standard

Compliant with 300-PIN MSA

Compliant with ITU-T G.691

Compliant with ITU-T G.959.1

Compliant with Telcordia GR-253

Compliant with OIF SFI-4 interface

Compliant with Telcordia GR-468-Core

Compliant with IEC-60825-1 Class Ⅰ

The transmitter and receiver reference clock rates

are selectable for divide by 16 or 64.

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Function Block Diagram

Figure 1, Function Block Diagram

Absolute Maximum Ratings

Table 1- Absolute Maximum Ratings

Parameter

Symbol

T_S

Min.

-40

-0.5

Max.

Unit

°C

Storage Temperature

V_cc

6.0

4.2

3.3

Supply Voltage

V_dd1

V_dd2

Operating Relative Humidity (non-condensing)

Electro-Static Discharge

ESD

500

Recommended Operating Conditions

Table 2 - Recommended Operating Conditions

Parameter

Symbol

Min.

-5

Typ.

Max.

Unit

°C

Operating Case Temperature

T_C

V_cc

4.75

3.13

1.71

5.0

3.3

1.8

5.25

3.46

1.89

Supply Voltage

V_dd1

V_dd2

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

I_cc

250

400

650

3.8

400

700

800

6.0

Supply Current

I_dd1

I_dd2

Power consumption

Power supply noise rejection

Bit Rate

mVp-p

Gbps

9.95

11.3

Optical Interface Characteristics

Table 3 - Optical Characteristics

Transmitter

Parameter

Symbol

Min.

Typical

Max.

Unit

Notes

λ_C

f_c

1528.773

1565.047

Wavelength Range

191.80

196.10

THz

dBm

GHz

Output Power

P_OUT

ΔP

-2

-0.5

0.5

-30

Output Power Stability

Output Power at laser disable

Channel Spacing

P_0UT-OFF

100

Wavelength Stability

Side Mode Suppression Ratio

Extinction Ratio

-100

8.2

100

SMSR

Chromatic Dispersion

Output Optical Eye

800

ps/nm

Compliant with Telcordia GR-253-CORE and ITU-T G.691

20kHz~80MHz

Jitter Generation

0.3

0.1

4MHz~80MHz

Receiver

Centre Wavelength

λ_C

1528

1565

-17

-24

-18

Receiver

P_IN

dBm

Sensitivity

APD

-25

-9

Receiver

P_IN-MAX

dBm

Overload

APD

Optical Path Penalty

Reflection of Receiver

Jitter Tolerance

-27

Compliant with Telcordia GR-253 and ITU-T G.825

Jitter Transfer

Notes:

1. The optical power is launched into SMF.

2. Measured with a NRZ PRBS 2³¹-1 test pattern @ 9.95328Gbps.

3. Measured with a NRZ PRBS 2³¹-1 test pattern @ 9.95328Gbps, BER ≤1×10^-12.

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Electrical Interface Characteristics

Table 4 - LVDS Input/Output Specification

Parameter

Input Differential Voltage

Input Differential impedance

Output Differential Voltage

Symbol

Min.

200

Typical

Max.

Unit



Notes

V_ID

R_ID

V_OD

100

120

800

500

Output Differential impedance

Output Common Mode Voltage

Rise Time/Fall time

R_OD

V_CM

1.1

100

1.2

120

1.3

250



T_rise/fall

T_DC

Clock Signal Duty Cycle

Common Mode

Voltage

Differantial

Voltage

(V_ODor V_ID)

(V_CMIor V_CMD

)

Definition of Differantial Voltage Levels

Table 5 - LVTTL Input/Output Specification

Parameter

Input High Voltage

Symbol

Min.

2.0

Typical

Max.

V_dd1

0.8

Unit

Notes

V_IH

V_IL

Input Low Voltage

GND

Output High Voltage

Output Low Voltage

V_IH

V_IL

2.4

V_dd1

0.4

GND

Clock and Data Interfaces

Table 6 - Reference Clock characteristics

Transmitter

Parameter

Symbol

Min.

Typical

Max.

Unit

Notes

TxREFCLKP

TxREFCLKN

Frequency

155.52/622.08

MHz

Serial data-rate is 9.953Gbps

Frequency

tolerance

-100

+100

ppm

Rise/Fall time

Duty Cycle

Tr/Tf

T_DC

500

Receiver

RxREFCLKP

RxREFCLKN

Frequency

155.52/622.08

MHz

Serial data-rate is 9.953Gbps

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Frequency

tolerance

-100

+100

ppm

Rise/Fall time

Duty Cycle

Tr/Tf

T_DC

500

Table 7 - Transmitter/Receiver Parallel Data/Clock Interface

Parameter

Symbol

Level

Notes

Transmitter 16-bit parallel Date Input

TxDin[0:15]P/N

LVDS

TxDin0:LSB, TxDin15:MSB

Transmitter

Source

synchronous

TxPICLKP/N

LVDS

ParallelInput Clock

Transmitter Counter Clock

LVDS

TxPCLKP/N

Receiver 16-bit parallel Date Output

Receiver Source synchronous Parallel

Output Clock

RxDout[0:15]P/N

RxDout0:LSB, RxDout15:MSB

RxPOCLKP/N

LVDS

Table 8 - Transmitter/Receiver Parallel Data/Clock Timing

Transmitter Data/Clock Timing: SERDES Input Timing at SERDES pin

Parameter

Duty Cycle(T_W/T_O)

Symbol

T_DC

Min.

Typical

Max.

Unit

Notes

TxPICLK

TxDin

Rise and Fall time

Setup time

Tr/Tf

100

250

300

20 – 80%

Hold time

250

TxPICLKP

TxDin[0:15]P/N

Ts: Measuring from the LHS inner data eye to the immediate rising edge of clock pulse

Th: Measuring from the rising edge of clock pulse to the inner RHS of data eye

Receiver Data/Clock Timing: SERDES Output Timing at SERDES pin

RxPOCLK

RxDout

Duty Cycle(T_W/T_O)

Rise and Fall time

T_DC

Tr/Tf

100

250

200

20 – 80%

Data/Clock skew

Tcq_min,

Tcq_max

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

RxPOCLKP

Tcq_max

RxDout[0:15]P/N

Tcq_min

Table 9 - Monitor Clock

Parameter

Symbol

Level

Notes

Transmitter

The LVDS TxMCLK is either a 1/16 or 1/64 replica of the

clock used to time the serial data output. The rate of the

TxMCLK is always the same as that of the TxREFCLK

The LVDS RxMCLK is a 1/16 or 1/64 replica of the clock

recovered from the incoming data

monitor clock

TxMCLKP/N

LVDS

Receiver

RxMCLKP/N

LVDS

monitor clock

Digital Control Signal

Table 10 - Input Digital signals

Function

Module

Symbol

Level

Description

Module reset

Note

Reset both Tx and Rx section

(LVTTL with pull-up resistor)

MOD_RESET

LVTTL

RESET

Normal operation

Enable Loopback

Normal operation

Enable Loopback

Normal operation

Diagnostic

Loopback

DLOOPENB

LLOOPENB

(LVTTL with pull-up resistor)

Line Loopback

Transmitter

Reset MUX

TxRESET

LVTTL

(LVTTL with pull-up resistor)

Normal operation

10.3G

0,0

0,1

1,0

1,1

11.1/11.3G

10.7G

Transmitter Bit

Rate Select

TxRATESEL1

TxRATESEL0

9.9G

Select

the

1/64 data-rate

frequency of

TxREFCLK

Enable internal

Line Timing

Enable/Disable

Laser

TxREFSEL

LVTTL

(LVTTL with pull-up resistor)

1/16 data-rate

Enable

TxLINETIMSEL LVTTL

(LVTTL with pull-up resistor)

Normal operation

Laser disabled

LsENABLE

LVTTL

(LVTTL with pull-down resistor)

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Internally TxFIFOERR is

MUX FIFO reset

connected to TxFIFORES,

TxFIFOERR will initiate a FIFO

reset

MUX

reset

FIFO

TxFIFORES

RxRESET

LVTTL

Normal operation

Receiver

(LVTTL with pull-up resistor)

Reset DEMUX

Normal operation

10.3G

Reset DEMUX

LVTTL

(LVTTL with pull-up resistor)

0,0

0,1

1,0

1,1

11.1/11.3G

10.7G

Receiver

Bit

RxRATESEL1

RxRATESEL0

Rate Select

9.9G

Select

the

1/64 data-rate

frequency of

RxREFCLK

RxREFSEL

RxMCLKSEL

RxLCKREF

LVTTL

(LVTTL with pull-down resistor)

(LVTTL with pull-up resistor)

1/16 data-rate

Select

the

1/64 data-rate

1/16 data-rate

frequency of

RxMCLK

Lock

Lock to RxREFCLK

Normal operation

RxPOCLK to

RxREFCLK

Mutes

the

Mutes the

RxDOUT[0:15]

Normal operation

RxMUTEDOUT LVTTL

Mutes

the

Mutes the RxMCLK

Normal operation

receiver output RxMUTEMCLK LVTTL

monitor clock

Mutes receiver

Mutes the

RxPOCLK

parallel output

RxMUTEPOCLK LVTTL

(LVTTL with pull-up resistor)

clock

Normal operation

RxPOCLK

Digital Alarm Signal

Table 11 - Alarms Digital signals

Function

Symbol

Level

Description

Note

Any alarm from

both transmitter

and receiver

Indicates

all

Activation Time: 10ms

Deactivation Time: 10ms

ALMINT

LVTTL

alarm active

Normal operation

Transmitter

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Alarm active

Loss of transmitter PLL lock

Activation Time: 10ms

Loss of Tx PLL

lock

TxLOCKERR LVTTL

Normal operation

Deactivation Time: 10ms

Alarm active

(FIFO overflow)

Normal operation

Alarm active

Internally TxFIFOERR is connected to

TxFIFORES,

MUX FIFO error TxFIFOERR LVTTL

Alarm when laser bias changes by a

factor of 2 from beginning of life

Activation Time: 10 ms

(laser bias

Laser bias out

LsBIASALM LVTTL

of range

current alarm)

Normal operation

Deactivation Time: 10 ms

Laser

Laser temperature 5°C from nominal,

Activation Time : 10ms

Alarm active

Normal operation

Alarm active

temperature out LsTEMPALM LVTTL

of range

Deactivation Time : 10ms

Laser

output

Output power degrades 3dB below the

BOL Activation Time : 10ms

Deactivation Time : 10ms

power out of LsPOWALM LVTTL

range

Normal operation

Alarm from

transmitter

Activation Time: 10 ms;

Deactivation Time: 10 ms

Tx alarms

TxALMINT

LVTTL

Normal operation

Receiver

Loss of Rx PLL

lock

Alarm active

Normal operation

Alarm active

Activation Time: 10ms

RxLOCKERR LVTTL

Deactivation Time: 20ms

Loss of receiver

Activation Time: <10ms

average power RxPOWALM LVTTL

alarm

Deactivation Time: <10ms

Normal operation

Alarm active

Loss of receiver

Activation Time: 10 ms;

Deactivation Time: 10 ms

RxSIGALM

LVTTL

a.c.power alarm

Rx alarms

Normal operation

Alarm from

Activation Time: 10 ms;

Deactivation Time: 10 ms

Receiver

RxALMINT

LVTTL

Normal operation

Analog Monitoring Signal

Table 12 - Monitor Signals

Transmitter

Symbol

Function

Min.

0.47

Typ.

0.5

Max.

Unit

Normalized laser power monitor voltage BOL

Laser power monitor voltage slope

0.53

LsPOWMON

0.25 V change for 50% power variation

Laser bias monitor voltage offset

0.2

mV/mA

LsBIASMON

LsTEMPMON

Laser bias monitor voltage slope

2.5

2.6

Normalized laser temperature Monitor voltage

2.4

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Laser temperature monitor voltage slop

Normalized laser wavelength monitor voltage

Laser temperature monitor voltage slop

mV/℃

1.25

200

LsWAVEMON

mV/GHz

Receiver

Input optical power monitor voltage PIN

0.8

1.0

V/mW

slope

APD

RxPOWMON

Input optical power monitor error

-2

I2C Serial Interface

Table 13 – I2C Interface

Function

Symbol

Level

Description

Note

I2C address input for module

addressing (LSB)

(LVTTL with pull-down

resistor)

I2CAD0

LVTTL

I2C address input for module

addressing

(LVTTL with pull-down

resistor)

I2C Address

I2CAD1

I2CAD2

I2C address input for module

addressing (MSB)

(LVTTL with pull-down

resistor)

Open

collector

Open

I2C clock input/output for

remote access

I2C Clock

I2C Data

I2CCLOCK

I2CDATA

N/A

I2C data input/output for

remote access

collector

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Pin Definitions

Table 15 - Pin Function Definitions

GND

+1.8V

GND

+5V

NUC

FFU

RxDout12P

RxDout12N

GND

RxDout8P

RxDout8N

GND

RxDout4P

RxDout4N

GND

FFU

GND

RxDout0P

RxDout0N

GND

+1.8V

GND

RxRATESEL0 RxRATESEL1

FFU

RxPOWMON

+3.3V

I2CAD0

GND

+3.3V

NUC

GND

RxDout13P

RxDout13N

GND

RxDout9P

RxDout9N

GND

RxDout5P

RxDout5N

RxDout1P

RxDout1N

GND

+3.3V

GND

RxRESET

+3.3V

NUC

DLOOPENB

GND

RxPOWALM

+3.3V

I2CAD1

GND

GND RxMUTE Dout

FFU

RxDout14P

RxDout14N

GND

RxDout10P

RxDout10N

GND

RxDout6P

GND

RxDout2P

RxDout2N

GND

+3.3V

FFU

GND

+3.3V

GND

RxDout6N

GND

9 RxMUTEPOCLK

NUC

FFU

NUC

I2CAD2

GND

RxLCKREF

GND

NUC

GND

RxDout15P

RxDout15N

GND

NUC

RxDout11P

RxDout11N

GND

RxDout7P

RxDout7N

GND

RxDout3P

RxDout3N

GND

NUC

GND

NUC

GND

12 RxMUTEMCLK

NUC

FFU

RxSIGALM

NUC

MOD RESET

GND

RxMCLKSEL

GND

NUC

FFU

GND

FFU

RxPOCLKP

RxPOCLKN

GND

RxMCLKP

RxMCLKN

GND

RxREFCLKP

RxREFCLKN

GND

RxALMINT

NUC

GND

FFU

NUC

GND

15 I2CCLOCK

ALM INT

GND

RxREFSEL

+1.8V

FFU

RxLOCKERR

GND

+5V

TxALMINT

FFU

TxDin12P

TxDin12N

GND

TxDin8P

TxDin8N

GND

TxDin4P

TxDin4N

GND

TxDin0P

TxDin0N

GND

+1.8V

GND

I2CDATA

+3.3V

NUC

FFU

LsBIASMON

+3.3V

LsPOWMON

GND

NUC

FFU

GND

TxDin13P

TxDin13N

GND

TxDin9P

TxDin9N

GND

TxDin5P

TxDin5N

GND

TxDin1P

TxDin1N

GND

FFU

GND

+3.3V

GND

21 TxRATESEL0 TxRATESEL1

FFU

LsENABLE

+3.3V

LsTEMPMON GND

NUC

+3.3V

FFU

GND

TxDin14P

TxDin14N

GND

TxDin10P

TxDin10N

GND

TxDin6P

TxDin6N

GND

TxDin2P

TxDin2N

GND

+3.3V

GND

TxRESET

NUC

FFU

LsBIASALM

NUC

FFU

NUC

GND

TxDin15P

TxDin15N

GND

TxDin11P

TxDin11N

GND

TxDin7P

TxDin7N

GND

TxDin3P

TxDin3N

GND

NUC

GND

NUC

GND

27 TxFIFORES

NUC

LLOOPENB

GND

LsTEMPALM

NUC

FFU

TxPICLKSEL

GND

NUC

LsWAVEMON

FFU

TxPICLKP

TxPICLKN

GND

TxPCLKP

TxPCLKN

GND

TxMCLKP

TxMCLKN

GND

TxREFCLKP

TxREFCLKN

GND

NUC

GND

30 TxFIFOERR

NUC

TxLINETIMESEL

TxREFSEL

LsPOWALM

TxLOCKERR

FFU: Reserved For Future Use

NUC: No Use Connection

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Mechanical Diagram

The mechanical design diagram is shown in Figure 2.

Figure 2, Mechanical Diagram

Ordering Information

Part No.

Product Description

C-band DWDM Wavelength, 9.95~11.3Gbps, 40km, PIN receiver, 10G SFF 300pin,

LC connector, -5°C~+70°C,

TPD-MR-04-XXCDL5A

C-band DWDM Wavelength, 9.95~11.3Gbps, 40km, APD receiver, 10G SFF

300pin, LC connector, -5°C~+70°C,

TPD-MR-04-XXCDL5B

TPD-MR-04-XXCDS5A

TPD-MR-04-XXCDS5B

TPD-MR-04-XXCDF5A

TPD-MR-04-XXCDF5B

C-band DWDM Wavelength, 9.95~11.3Gbps, 40km, PIN receiver, 10G SFF 300pin,

SC connector, -5°C~+70°C,

C-band DWDM Wavelength, 9.95~11.3Gbps, 40km, APD receiver, 10G SFF

300pin, SC connector, -5°C~+70°C,

C-band DWDM Wavelength, 9.95~11.3Gbps, 40km, PIN receiver, 10G SFF 300pin,

FC connector, -5°C~+70°C,

C-band DWDM Wavelength, 9.95~11.3Gbps, 40km, APD receiver, 10G SFF

300pin, FC connector, -5°C~+70°C,

Note: XX is from 18 (191.80THz) to 61(196.10THz)，100GHz spacing.

DS-5229 Rev 00 2010-07-02

TPD-MR-04-XXXXXXXX

Warnings

Handling Precautions: This device is susceptible to damage as a result of electrostatic discharge (ESD). A

static free environment is highly recommended. Follow guidelines according to proper ESD procedures.

Laser Safety: Radiation emitted by laser devices can be dangerous to human eyes. Avoid eye exposure to

direct or indirect radiation.

Legal Notice

IMPORTANT NOTICE!

All information contained in this document is subject to change without notice, at Source Photonics’s sole and

absolute discretion. Source Photonics warrants performance of its products to current specifications only in

accordance with the company’s standard one-year warranty; however, specifications designated as

“preliminary” are given to describe components only, and Source Photonics expressly disclaims any and all

warranties for said products, including express, implied, and statutory warranties, warranties of

merchantability, fitness for a particular purpose, and non-infringement of proprietary rights. Please refer to the

company’s Terms and Conditions of Sale for further warranty information.

Source Photonics assumes no liability for applications assistance, customer product design, software

performance, or infringement of patents, services, or intellectual property described herein. No license, either

express or implied, is granted under any patent right, copyright, or intellectual property right, and Source

Photonics makes no representations or warranties that the product(s) described herein are free from patent,

implantation or other life support applications where malfunction may result in injury or death to persons.

Source Photonics customers using or selling products for use in such applications do so at their own risk and

agree to fully defend and indemnify Source Photonics for any damages resulting from such use or sale.

THE INFORMATION CONTAINED IN THIS DOCUMENT IS PROVIDED ON AN “AS IS” BASIS. Customer

agrees that Source Photonics is not liable for any actual, consequential, exemplary, or other damages arising

directly or indirectly from any use of the information contained in this document. Customer must contact

Source Photonics to obtain the latest version of this publication to verify, before placing any order, that the

information contained herein is current.

Contact

U.S.A Headquaters

20550 Nordhoff Street

Chatsworth, CA 91311

USA

China

Taiwan

Building #2&5, West Export Processing

Zone No. 8 Kexin Road, Hi-Tech Zone

Chengdu, 611731, China

Tel: +86-28-8795-8788Fax:

+86-28-8795-8789

9F, No 81, Shui Lee Rd.

Hsinchu, Taiwan, R.O.C.

Tel: +886-3-5169222

Fax: +886-3-5169213

Tel: +1-818-773-9044

Fax: +1-818-773-0261

DS-5229 Rev 00 2010-07-02

TPD-MR-04-36CDF5A [SOURCE]

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