SFP+ 10G 1310nm 10KM
  • SFP+ 10G 1310nm 10KM

SFP+ 10G 1310nm 10KM

Duplex LC Connector Support hot-pluggable Metal with lower EMI Excellent ESD protection DFB Transmitter and PIN Receiver Distance up to 10Km on 9/125um SMF Single 3.3V power supply and Low power dissipation <1.2W GR-253-CORE compliant RoHS Compliant and Lead-Free Compliant with IEEE 802.3ae Compliant with SFP+ MSA: SFF-8431 Rev4.1 Compliant with SFF-8472 Rev11.0

Category:

SFP optical module

Product Details

Product Features

Duplex LC Connector

Support hot-pluggable

Metal with lower EMI

Excellent ESD protection

DFB Transmitter and PIN Receiver

Distance up to 10Km on 9/125um SMF

Single 3.3V power supply and Low power dissipation <1.2W

GR-253-CORE compliant

RoHS Compliant and Lead-Free 

Compliant with IEEE 802.3ae

Compliant with SFP+ MSA: SFF-8431 Rev4.1

Compliant with SFF-8472 Rev11.0

 

Applications

10GBASE-LR/LW

10G Fibre Channel

Other optical link

 

Product Selection

Part Number

Operating temperature

 

DDMI

 

SFP+ 10G 1310nm 10KM

Commercial

 

Yes

 

SFP+ 10G 1310nm 10KM

Industrial

 

Yes

 

 

Regulatory Compliance

ESD to the Electrical PINs: compatible with MIL-STD-883E Method 3015.7

ESD to the LC Receptacle: compatible with IEC 61000-4-2 GR-1089-CORE

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 Descriptions

Pin

Symbol

Name/Description

Ref.

1

VeeT

Transmitter Ground    (Common with Receiver Ground)

1

2

TX Fault

Transmitter Fault. LVTTL-O

2

3

TX Disable

Transmitter Disable. Laser output disabled on high or open. LVTTL-I

3

4

SDA

2-Wire Serial Interface Data Line(Same as MOD-DEF2 in INF-8074i). LVTTL-I/O

 

5

SCL

2-Wire Serial Interface Data Line(Same as MOD-DEF2 in INF-8074i). LVTTL-I

 

6

Mod_ABS

Module Absent, Connect to VeeT or VeeR in Module.

4

7

RS0

Rate Select 0, optionally controls SFP+ module receiver LVTTL-I

5

8

LOS

Loss of Signal indication. Logic 0 indicates normal operation. LVTTL-O

2

9

RS1

Rate Select 1, optionally controls SFP+ module transmitter. LVTTL-I

5

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. CML-O

 

13

RD+

Receiver Non-inverted DATA out.    AC Coupled. CML-O

 

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. CML- I

 

19

TD-

Transmitter Inverted DATA in. AC Coupled. CML- I

 

20

VeeT

Transmitter Ground (Common with Receiver Ground)

1

Notes:

1. The module signal ground contacts, VeeR and VeeT, should be isolated from the module case.

2. This contact is an open collector/drain output and should be pulled up to the Vcc_Host with  resistor in the range 4.7KΩ to 10KΩ . Pull ups can be connected to one or several power supplies, however the  host  board  design  shall ensure that  no  module  contact  has  voltage  exceeding  module VccT/R +0.5V.

3. Tx_Disable is an input contact with a 4.7KΩ to 10KΩ pull-up resistor to VccT inside module.

4. Mod_ABS is connected to VeeT or VeeR in the SFP+ module. The host may pull the contact up to Vcc_Host with a resistor in the range from 4.7KΩ to 10KΩ . Mod_ABS is asserted “High ” when the SFP+ module is physically absent from a host slot.

5. RS0 and RS1 are module inputs and are pulled low to VeeT with > 30  resistors in the module. RS0 optionally selects the optical receive signaling rate coverage. RS1 optionally selects the  optical transmit signaling rate coverage.

These contacts can also be used for RS0 and RS1 if implementing SFF8079. See SFF8079 for details. RS1 is commonly connected to VeeT or VeeR in the classic SFP modules. The host needs to ensure that it will not be damaged if this contact is connected to VeeT or VeeR in the module.

The  SFP+  module  provides  two  inputs  RS0  and  RS1  that  can  optionally  be  used for  rate selection. RS0 controls the receive path signalling rate capability, and RS1 controls the transmit path signalling rate capability. The host and module may choose to use either, both, or none of these functions. Because contact 9 in the classic SFP INF-8074i is connected to VeeR, an SFP+ host utilizing RS1 must provide short circuit protection.

This  rate  select  functionality  can  also  be  controlled  by  software  as  defined  by  SFF-8472. Optionally the rate select methods of Part 2 of SFF-8079 may be used instead of the method described  here  by  setting  the  management  declaration  bit  (A0h  byte  93  bit  2)  to   1,  see SFF-8472.

Parameter

State

Conditions

RS0

Low

Rx signally rate less than or equal to 4.25GBd.

High

Rx signally rate great than 4.25GBd.

RS1

Low

Tx signally rate less than or equal to 4.25GBd.

High

Tx signally rate great than 4.25GBd.

 

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

-

-

350

mA

 

Case Operating Temperature

Tc

-5

-

+70

°C

2

Tc

-40

-

+85

°C

3

Data Rate

-

9.95

10.3

10.5

Gbps

 

9/125um G.652 SMF

Lmax

-

-

10

km

 

 

Electrical Characteristics

Parameter

Symbol

Min

Typ

Max

Unit

Ref.

Transmitter

Differential data input swing

Vin,pp

120

600

850

mV

 

Input differential impedance

Zin

90

100

110

Ω

 

TX Disable-High

-

2.0

-

Vcc+0.3

V

 

TX Disable-Low

-

Vee-0.3

-

0.8

V

 

TX Fault-High

-

2.0

-

Vcc+0.3

V

 

TX Fault-Low

-

Vee-0.3

-

0.8

V

 

Receiver

Differential data output swing

Vout, pp

300

600

850

mV

 

Output Differential Impedance

Zin

90

100

110

Ω

 

LOS-High

-

2.0

 

Vcc+0.3

V

 

LOS-Low

-

Vee-0.3

 

0.8

V

 

 

Optical Characteristics

Parameter

Symbol

Min

Typ

Max

Unit

Ref.

Transmitter

Output Opt. Power

AOP

-6

-

+0.5

dBm

1

Optical modulation amplitude

P(OMA)

-5.2

-2

 

dBm

 

Extinction Ratio

ER

3.5

-

-

dB

 

Transmitter and Dispersion Penalty

TDP

-

-

3.2

dB

 

Average Launch power of OFF TX

Poff

-

-

-30

dBm

 

Optical Wavelength

λ

1260

1310

1355

nm

 

Side mode Suppression Ratio

SMSR

30

 

 

dB

 

Optical Return Loss Tolerance

ORLT

 

 

12

dB

 

Relative Intensity Noise

RIN

-

-

-128

dB/Hz

 

Transmitter Reflectance

-

-

-

-12

dB

 

Eye Diagram

Compatible with IEEE 802.3-2005

 

Receiver

Receiver Sensitivity

PIN

-

-

-14.4

dBm

1

Overload

 

0.5

-

-

dBm

1

Receiver Reflectance

-

-

-

-12

dB

 

Optical Center Wavelength

λC

1260

-

1610

nm

 

Los Assert

 

-30

-

-

dBm

 

Los De-assert

 

-

-

-15

dBm

 

Los hysteresis

 

0.5

-

5

dB

 

Notes:

1.   BER  10-12  @PRBS231-1 at 10.3125Gb/s.

2.   For the APSP31B33CDL10

3.   For the APSP31B33IDL10

 

Mechanical Specifications

EEPROM Information

EEPROM memory map specific data field description is as below:


 

igital Diagnostic Monitoring Interface

The digital diagnostic monitoring interface also defines another 256-byte memory map in

EEPROM, which makes use of the 8 bit address 1010001X (A2h). The monitoring specification of this product is described in this table.

Parameter

Range

Accuracy

Calibration

Temperature

-5 to +85°C

±3°C

Internal (note 1)

-40 to +95°C

±3°C

Internal (note 2)

Voltage

2.97 to 3.63V

±3%

Internal

Bias Current

0 to 100mA

±10%

Internal

TX Power

-6 to +0.5dBm

±2dB

Internal

RX Power

-14.4 to 0.5dBm

±2dB

Internal

Notes:

1. For the APSP31B33CDL10

2. For the APSP31B33IDL10

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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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