SFA-CL-24T-HP-CDE [SOURCE]

Transceiver, 1244.16Mbps(Tx), 2488.32Mbps(Rx), SC/APC Connector, Through Hole Mount, ROHS COMPLIANT PACKAGE;


型号：	SFA-CL-24T-HP-CDE
厂家：	SOURCE PHOTONICS, INC.
描述：	Transceiver, 1244.16Mbps(Tx), 2488.32Mbps(Rx), SC/APC Connector, Through Hole Mount, ROHS COMPLIANT PACKAGE 通信放大器 PC 光纤
文件：	总11页 (文件大小：763K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SFx-xx-24T-HP-CxE-xx

Integrated Diplexer Transceiver

Features

• Single Fiber, CWDM Integrated Diplexer Transceiver

• 2x5 SFF pinout

• 2x10 SFF pinout supports I C digital diagnostics

• Voice/Data FTTx ONT/ONU Applications

• 1244 Mbps Tx, 2488 Mbps Rx Asymmetric Data Rate

• 5 Wavelength Pairs Available

• Burst Mode Transmission

• TX Burst Mode Detection, TX-SD

• Commercial temperature

• 28 dB link budget; 20 km reach

• Compliant to IEC-60825 Class 1 laser diode

• SC/APC or SC/UPC fiber connector

• RoHS compliant

- Digital Transmitter: A CWDM laser diode is employed for upstream transmission at OC-24 (1244Mbps). The optical transmitter includes a back

facet photodetector to monitor laser power for APC control.

- Digital Receiver: An APD with TIA is employed for downstream data reception at OC-48 (2488Mbps). A post amplifier is also included for CML

output compatibility.

Lim

Amp

Rx Data

Section

TIA

1490nm APD

Receiver

WDM

1310nm Upstream

1490nm Downstream

LDD

Tx Data

Section

Diplexer

Optical

1310nm

Laser

Block

Diplexer Block Diagram

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

Absolute Maximum Ratings

Usage of this transceiver shall adhere to the following absolute maximum ratings. Stresses beyond those in Table 1 may cause permanent damage to

the unit. These are stress ratings only, and functional operation of the unit at these or any other conditions beyond those indicated in the operational

sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect unit reliability.

Table 1 - Absolute Maximum Ratings

Parameter

Minimum

Maximum

Unit/Conditions

Ambient Storage Temperature

Operating Temperature*

Operating Humidity Range

ESD Sensitivity (Human Body Model)

Lead Soldering Temperature

Vcc_Rx

-40

ºC

ºC, C-Temp

10%

90%

non-condensing

1000

260ºC

+4.2

10 sec

-0.4

Vcc_Tx

Vcc_Rx + 1

*Operating temperature minimum is ambient, maximum is module case temperature.

Module Characteristics

Table 2 - Module Characteristics

Parameter

Minimum

Typical

Maximum

Unit/Conditions

Tx to Rx Crosstalk

Total TX and RX Supply Current

-47

350

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

Functional Characteristics

The following tables list the performance specifications for the various functional blocks of the integrated optical transceiver module.

Table 3 – Digital Transmitter Specifications

Parameter

Operating Voltage

Minimum

Typical

Maximum

Unit

Notes

referenced to GND_Tx

3.14

3.30

3.46

Data Rate

1244.16

Mbps

dBm

Average Optical Output Power, P (BOL)

1.5

0.5

Average Optical Output Power, P (BOL)

Output Power at Transmit Off

Extinction Ratio

-40

PRBS 2²³-1, NRZ, 50% duty cycle

20% to 80%

Transmitter Output Eye

Optical Rise and Fall Time

G.984.2 Figure 3

250

1271

1291

1311

1331

1351

Center Wavelength

C-temp ±6.5nm

SMSR

Differential Input Voltage, V_in

200

1600

Vcc - (V_in/2) -

0.1

mVp-p TXD+/-. DC-coupled

GND_Tx +

Common-Mode Input Voltage

DC coupled

1.4

Tx Burst Enable Time

Tx Burst Disable Time

Jitter Generation

12.86

0.2

16 bits data @ 1244Mbps

4 kHz to 10 MHz

TX_DIS Input Low

TX_DIS Input High

TX_SD timing “D”

TX_SD timing “X”

0.8

2.0

Vcc_RX

1000

See figure 3

350

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

Refer to Figure 1 which schematically describes the high speed data inputs/outputs of the optical transceiver module.

Diplexer

Module

Ω

100

Tx Data

Tx_ENB

100

Ω

Differential

Transmission Line

For CML

Tx/Rx Data

LDD/Post amp.

µF

0.1 F

Rx Data

0.1 F

µF

100

ΩDifferential

Transmission Line

Figure 1 - Schematic representation of the module high speed inputs/outputs

Table 4 – Digital Receiver Specifications

Parameter

Operating Voltage

Minimum

Typical

Maximum

Unit

Notes

referenced to GND_RX

3.14

3.30

3.46

Data Rate

2488.32

Mbps

1451

1471

Operational Wavelength Range

1491

1511

1531

Received Optical Power, BOL

Received Optical Power, EOL

Data Output Rise and Fall Time

Signal Detect Assertion Level

Signal Detect De-Assertion Level

Signal Detect Hysteresis

-28.0

-27.0

-8

dBm

PRBS 2²³-1, 50% duty cycle

20% to 80%

160

-31

dBm

Transition during increasing light

Transition during decreasing light

-45

0.5

300

Differential Output Voltage

1200

CML output, ac coupled (0.1µF)

LVTTL with internal 4.7kΩ pull up

resistor. Asserts HIGH when input

data amplitude is above threshold.

LVTTL. De-asserts LOW when input

data amplitude is below threshold .

2x10 only

Signal Detect Output HIGH Voltage

2.4

Signal Detect Output LOW Voltage

0.6

RSSI Range

-28

-3

-8

dBm

RSSI Accuracy

2x10 only

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

Table 5 - Microcontroller Specifications

Parameter

Minimum

Typical

Maximum

Unit

Notes

Operating Voltage

3.14

3.30

3.46

LVTTL, open collector serial data line from the I²C

bus to the on board Microcontroller. 100kbps max.

data rate.

SDA^a

LVTTL, open collector serial clock line from the I²C

bus to the on board Microcontroller.

SCL^b

Reset hold^c

LVTTL input, internal 50kΩ pull-up. Active Low

I²C SDA and SCL must be open collector or open drain connections.

Clock stretching, as per paragraph 13.2 of the I²C Bus Standard, must be implemented to operate correctly.

Please see Table 6 and the timing diagram in Figure 2 below for the recommended system start-up sequence.

Table 6 – Suggested Start-up Sequence

Step

Action

Power up the host system, with the RESET pin pulled to ground via a ≤4.7kΩ resistor.

Drive the RESET pin LOW.

Ensure power to the unit is on.

Drive the RESET pin HIGH to release the unit to become operational.

Read byte A2.6E several times. There will be a NACK until the processor is booted, followed by a 01 (DATA READY BAR)

until the A2D data is ready, followed by 00 (assuming TXDIS and TXFAIL are inactive).

The unit is now ready for normal operation.

Figure 2 - Recommended transceiver module start-up sequence

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

Fig 3 TX_SD Timing Diagram

2x5 Pin Definitions

Refer to Table 7 for a description of the function of each I/O pin.

Table 7 - Module Pin Definitions

Pin Number

Label

GND_RX

Vcc_RX

Definition

Digital Rx Ground

Digital Rx Vcc

Signal Detect output, pull up internally. Asserts high when input optical power level is above

threshold

RxD-

RxD+

RX data bar output, CML. 50Ω terminated to Vcc and AC coupled to module output (0.1µF)

RX data output, CML. 50Ω terminated to Vcc and AC coupled to module output (0.1µF)

Digital Tx Vcc

Vcc_TX

GND_TX

TX_DIS

TxD+

Digital Tx Ground

Tx Disable, LVTTL Input (1=TX OFF, 0=TX ON)

Tx data input, CML. Internally DC coupled. 100Ω differential termination.

Tx data bar input, CML. Internally DC coupled. 100Ω differential termination.

TxD-

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

2x10 Pin Definitions

Refer to Table 8 for a description of the function of each I/O pin.

Table 8 - Module Pin Definitions

Pin Number

Label

Definition

No User Connection

Digital Rx ground

GND_RX

Digital Rx ground

Reserved, No User Connection

Digital Rx Ground

GND_RX

Vcc_RX

Digital Rx Vcc

Signal Detect output, pull up internally (4.7kΩ). Asserts high when input optical power level is above

threshold

RxD-

RxD+

RX data bar output, CML. 50Ω terminated to Vcc and AC coupled to module output (0.1µF)

RX data output, CML. 50Ω terminated to Vcc and AC coupled to module output (0.1µF)

Digital Tx Vcc

Vcc_TX

GND_TX

TX_DIS

TxD+

Digital Tx Ground

Tx Disable, LVTTL Input (1=TX OFF, 0=TX ON), internal 47kΩ pull-up.

Tx data input, CML. Internally DC coupled. 100Ω differential termination.

Tx data bar input, CML. Internally DC coupled. 100Ω differential termination.

Digital Tx Ground

TxD-

GND_TX

SCL

I2C Clock input

SDA

I2C Data input/output

TX_Fault

TX_SD

TX Fault Alarm, LVTTL, TX Fault state=High, TX Normal state=Low.

TX Signal Detect, TX Active state=High. See TX_SD diagram.

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

SFF 2x5 Package Diagram

Pin 1

Pin 5

0.400±0.01 [10.16±0.254]

Pin 10

Pin 6

Bottom View

39.37±1.97 [1000±50]

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

SFF 2x10 Package Diagram

Pin 10

0.400±0.01 [10.16±0.254]

Pin 20

Pin 11

Bottom View

39.37±1.97 [1000±50]

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

Ordering Information

Table 9 - Ordering Information

TX & RX Wavelength

Design

Customer

Specific

Connector

Temperature Range

Digital Diagnostic

(nm)

Revision

-24T-HP-

-xx

C = Commercial Temp

A = APC

U = UPC

AJ = 1271 & 1451

N = Non-Diagnostic

D = Diagnostic

(0 to 70°C)

BK = 1291 & 1471

CL = 1311 & 1491

DM = 1331 & 1511

EN = 1351 & 1531

Example: SFA-CL-24T-HP-CDE = Transceiver with APC connector, TX=1311nm, RX=1491nm, Commercial Temp, Diagnostic.

Table 10 - Device Handling/ESD Protection

The devices are static sensitive and may easily be damaged if care is not taken during handling. The following handling practices are

recommended.

Devices should be handled on benches with conductive and grounding surfaces.

All personnel, test equipment and tools shall be grounded.

Do not handle the devices by their leads.

Store devices in protective foam or carriers.

Avoid the use of non-conductive plastics, rubber, or silk in the area where the devices are handled

All modules shall be packaged in materials that are anti-static to protect against adverse electrical environments.

Avoid applications of any voltage higher than maximum rated voltages to this part. For proper operation, any VIN or VOUT should be

constrained to the range GND ≤ (VIN or VOUT) ≤ VCC. Unused inputs must always be tied to an appropriate logic voltage (e.g.

either GND or VCC). Unused outputs must be left open.

DS-6027 Rev 01

SFx-xx-24T-HP-CxE-xx

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’ 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, copyright, or intellectual property

rights. Products described in this document are NOT intended for use in 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.

All information contained in this document is subject to change without notice. The products described in this document are NOT

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

The information contained in this document does not affect or change Source Photonics product specifications or warranties. Nothing in

this document shall operate as an express or implied license or indemnity under the intellectual property rights of Source Photonics or

third parties. All information contained in this document was obtained in specific environments, and is presented as an illustration. The

results obtained in other operating environments may vary.

THE INFORMATION CONTAINED IN THIS DOCUMENT IS PROVIDED ON AN ”AS IS” BASIS. In no event will Source Photonics be

liable for damages arising directly from any use of the information contained in this document.

Contact

OURCE PHOTONICS

20550 NORDHOFF

ST.

CHATSWORTH, CA 91311

sales@sourcephotonics.com

Tel: 818-773-9044 Fax: 818-576-9486

Or visit our website: http://www.sourcephotonics.com

DS-6027 Rev 01

SFA-CL-24T-HP-CDE [SOURCE]

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