BIDISFP 1.25GTX1310/RX1550 20KM
  • BIDISFP 1.25GTX1310/RX1550 20KM

BIDISFP 1.25GTX1310/RX1550 20KM

Up to 1.25Gb/s data links Single LC connector Hot-pluggable SFP footprint 1310nm FP laser transmitter 1490nm InGaAs PIN receiver RoHS compliant and Lead Free Up to 20km on 9/125um SMF Metal enclosure for lower EMI Single +3.3V power supply Low power dissipation <800mW Commercial and industrial Applications operating temperature optional SFP MSA SFF-8074i Compliant l

Category:

SFP optical module

Product Details

Product Features

Up to 1.25Gb/s data links 

Single LC connector 

Hot-pluggable SFP footprint 

1310nm FP laser transmitter 

1490nm InGaAs PIN receiver 

RoHS compliant and Lead Free 

Up to 20km on 9/125um SMF 

Metal enclosure for lower EMI 

Single +3.3V power supply 

Low power dissipation <800mW 

Commercial and industrial 

Applications operating temperature optional

SFP MSA SFF-8074i Compliant 

 

Applications

Gigabit Ethernet

1x Fibre Channel

 

General

BIDISFP 1.25GTX1310/RX1550 20KM  Small Form Factor Pluggable (SFP) transceivers are compatible with
the Small Form Factor Pluggable Multi-Sourcing Agreement (MSA). The SFP transceivers are high performance, cost effective modules supporting Gigabit Ethernet and 20km transmission distance with SMF. They are RoHS compliant and lead-free.

 

Product Selection

Part Number

 

Operating temperature

 

DDMI

BIDISFP 1.25GTX1310/RX1550 20KM

 

Commercial

 

No

BIDISFP 1.25GTX1310/RX1550 20KM

 

Commercial

 

Yes

BIDISFP 1.25GTX1310/RX1550 20KM

 

Industrial

 

No

BIDISFP 1.25GTX1310/RX1550 20KM

 

Industrial

 

Yes

 

Regulatory Compliance

ESD to the Electrical PINs: compatible with MIL-STD-883 Method 3015

ESD to the LC Receptacle: compatible with IEC 61000-4-2

Immunity compatible with IEC 61000-4-3

EMI compatible with FCC Part 15 Class B EN55022 Class B (CISPR 22B) VCCI Class B

Laser  Eye  Safety  compatible  with  FDA  21CFR  1040.10  and  1040.11  EN60950,  EN  (IEC) 60825-1,2

RoHs compliant with 2002/95/EC 4.1&4.2 2005/747/EC

Pin

Symbol

Name/Description

Ref.

1

VeeT

Transmitter Ground    (Common with Receiver Ground)

1

2

TX Fault

Transmitter Fault.

 

3

TX Disable

Transmitter Disable. Laser output disabled on high or open.

2

4

MOD_DEF(2)

Module Definition 2. Data line for Serial ID.

3

5

MOD_DEF(1)

Module Definition 1. Clock line for Serial ID.

3

6

MOD_DEF(0)

Module Definition 0. Grounded within the module.

3

7

Rate Select

No connection required

 

8

LOS

Loss of Signal indication. Logic 0 indicates normal operation.

4

9

VeeR

Receiver Ground (Common with Transmitter Ground)

1

10

VeeR

Receiver Ground (Common with Transmitter Ground)

1

11

VeeR

Receiver Ground (Common with Transmitter Ground)

1

12

RD-

Receiver Inverted DATA out.   AC Coupled

 

13

RD+

Receiver Non-inverted DATA out.    AC Coupled

 

14

VeeR

Receiver Ground (Common with Transmitter Ground)

1

15

VccR

Receiver Power Supply

 

16

VccT

Transmitter Power Supply

 

17

VeeT

Transmitter Ground (Common with Receiver Ground)

1

18

TD+

Transmitter Non-Inverted DATA in. AC Coupled.

 

19

TD-

Transmitter Inverted DATA in. AC Coupled.

 

20

VeeT

Transmitter Ground (Common with Receiver Ground)

1

Notes:

1.   Circuit ground is internally isolated from chassis ground.

2.   Laser output disabled on TX Disable >2.0V or open, enabled on TX Disable<0.8V.

3.   Should be pulled up with 4.7k - 10kohms on host board to a voltage between 2.0V and 3.6V. MOD_DEF(0) pulls line low to indicate module is plugged in.

4.   LOS  is  open collector output. Should be pulled up with 4.7k -  10kohms on host board to a voltage between 2.0V and 3.6V. Logic 0 indicates normal operation; logic 1 indicates loss of signal.

Pin-out of Connector Block on Host Board

 

 

Recommend Circuit Schematic

 

Absolute Maximum Ratings

Parameter

Symbol

Min

Typ

Max

Unit

Ref.

Maximum Supply Voltage

Vcc

-0.5

-

+4.0

V

 

Storage Temperature

TS

-40

-

+85

°C

 

Operating Humidity

RH

5

-

95

%

 

 

 

Recommended Operating Conditions

Parameter

Symbol

Min

Typ

Max

Unit

Ref.

Power Supply Voltage

Vcc

3.13

3.30

3.47

V

 

Power Supply Current

Icc

-

-

250

mA

 

Case Operating Temperature

Tc

0

-

+70

°C

1

TI

-40

-

+85

2

Data Rate(Gigabit Ethernet)

-

-

1.25

-

Gbps

 

9/125um G.652 SMF

Lmax

-

-

20

km

 

Notes:

1.   For commercial class product.

2.   For industrial class product.

 

 

Electrical Characteristics (TOP=25°C, Vcc=3.3Volts)

Parameter

Symbol

Min

Typ

Max

Unit

Ref.

Transmitter

Input differential impedance

Rin

-

100

-

Ω

1

Single ended data input swing

Vin, pp

250

-

1200

mV

 

TX Disable-High

-

Vcc – 1.3

-

Vcc

V

 

TX Disable-Low

-

Vee

-

Vee+ 0.8

V

 

TX Fault-High

-

Vcc-0.5

-

Vcc

V

 

TX Fault-Low

-

Vee

-

Vee+0.5

V

 

Receiver

Single ended data output swing

Vout, pp

300

400

800

mV

2

Data output rise time

tr

-

-

175

ps

3

Data output fall time

tf

-

-

175

ps

3

LOS-High

-

Vcc – 0.5

 

Vcc

V

 

LOS-Low

-

Vee

 

Vee+0.5

V

 

Notes:

1.   AC coupled.

2.    Into 100 ohm differential termination.

3.   20 – 80 %

 

Optical Characteristics (TOP=25°C, Vcc=3.3 Volts)

Parameter

Symbol

Min

Typ

Max

Unit

Ref.

Transmitter

Output Opt. Power

PO

-9

-

-3

dBm

1

Optical Wavelength

λ

1275

1310

1350

nm

 

Spectral Width

σ

-

-

3

nm

 

Optical Rise/Fall Time

tr/tf

-

-

260

ps

2

Total Jitter

TJ

-

-

200

ps

 

Optical Extinction Ratio

ER

9

-

-

dB

 

Receiver

RX Sensitivity @1.25 Gb/s

RSENS

-

-

-25

dBm

3, 4

Maximum Received Power

RXMAX

-2

-

-

dBm

 

Optical Center Wavelength

λC

1470

1490

1510

nm

 

LOS De-Assert

LOSD

-

-

-26

dBm

 

LOS Assert

LOSA

-40

-

-

dBm

 

LOS Hysteresis

-

0.5

-

5

dB

 

Notes:

1.   Class 1 Laser Safety.

2.   Unfiltered, 20-80%. Complies with Gigabit Ethernet eye masks when filtered.

3.   Measured with conformance signals defined in FC-PI-2 Rev. 10.0 specifications. 7                   -10

4.   Measured with PRBS 2 -1 at 10     BER.

 

Mechanical Specifications

SFP  Small  Form  Factor  Pluggable  (SFP)  transceivers  are  compatible  with  the dimensions defined by the SFP Multi-Sourcing Agreement (MSA).

 

EEPROM Information

EEPROM memory map specific data field description is as below:

Digital Diagnostic Monitoring Interface

Five  transceiver  parameter  values  are   monitored.  The  following  table  defines  the monitored parameter’s accuracy.

Parameter

Range

Accuracy

Calibration

Temperature

0 to +70°C (C)

±3°C

Internal

-40 to +85°C (I)

Voltage

2.97 to 3.63V

±3%

Internal

Bias Current

0 to 100mA

±10%

Internal

TX Power

-9 to -3dBm

±3dB

Internal

RX Power

-25 to -2dBm

±3dB

Internal

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FAQ

Listed below are answers to our most commonly asked questions. Don't see your question?Contact our customer service team. We would be glad to assist you.

What is an optical network terminal (ONT)? How does it differ from a regular modem?

An optical network unit (ONU) is an end device in a fiber optic network that converts optical signals transmitted via fiber optics into electrical signals (for use by routers, computers, and other devices), and vice versa.

What is the architecture of a fiber optic network (PON)?

Fiber optic networks typically use a passive optical network (PON) architecture, which is divided into three layers

What are the functions of the PON port and LAN port on an optical network terminal (ONT)?

PON port (fiber optic interface): Connects to the fiber optic cable entering the home and receives optical signals (usually SC/APC interface, blue square head).

Why does the optical network terminal need to register LOID/SN?

LOID (Logical Identifier) or SN (Serial Number) is the credential used by operators to bind user identities, and is used for OLT authentication of optical modems.

Optical modem dialing vs. router dialing: which is better?

Ordinary users: Optical modem dialing. Game/NAS users: Switch to bridge mode and dial up using a high-performance router.

How to determine whether the fiber optic signal is normal?

Check the optical modem indicator lights Log in to the optical modem management interface: Check the optical power (unit: dBm)

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