10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
  • 10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
  • 10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
  • 10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
  • 10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
  • 10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km
  • 10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km

10G SFP+ BIDI 1490/1550nm&1550/1490nm 80km

ZBC3880-49/55、ZBC3880-55/49 series single mode transceiver is small form factor pluggable module for optical data communications such as 10G Ethernet. It is with the SFP+ 20-pin connector to allow hot plug capability. The ZBC3880-49/55、ZBC3880-55/49 module is designed for single mode fiber and operates at a nominal wavelength of 1490nm or 1550nm; The transmitter section uses a EML laser, which is class 1 laser compliant according to International Safety Standard IEC-60825. The receiver section consists of a APD photodiode integrated with a TIA. The transceiver designs are optimized for high perform -ance and cost effective to supply customers the best solutions for telecommunication.

Category:

SFP optical module

Product Details

Product Features

Supports 9.95 to 11.3Gb/s bit rates 

Simplex LC Connector

Hot pluggable SFP+ footprint

Cooled 1490nm EML transmitter, 1550nm APD receiver

Cooled 1550nm EML transmitter, 1490nm APD receiver

Applicable for 80km SMF connection

Low power consumption, < 1.5W

Digital Diagnostic Monitor Interface  

Optical interface compliant to IEEE 802.3ae 10GBASE-Z

Electrical interface compliant to SFF-8431  

Operating case temperature: 

Commercial: to 70 °C

  

Applications

10.3125Gbps Ethernet

10GBASE-LW at 9.953Gbps

Other optical link

 

Product Descriptions

ZBC3880-49/55ZBC3880-55/49 series single mode transceiver is small form factor pluggable module for optical data communications such as 10G Ethernet. It is with the SFP+ 20-pin connector to allow hot plug capability. The ZBC3880-49/55ZBC3880-55/49 module is designed for single mode fiber and operates at a nominal wavelength of 1490nm or 1550nm; The transmitter section uses a EML laser, which is class 1 laser compliant according to International Safety Standard IEC-60825. The receiver section consists of a APD photodiode integrated with a TIA. The transceiver designs are optimized for high perform -ance and cost effective to supply customers the best solutions for telecommunication.

 

Functional Diagram

        

                           

Absolute Maximum Ratings

Parameter

Symbol

Min.

Max.

Unit

Note

Supply Voltage

Vcc

-0.5

4.0

V

 

Storage Temperature

TS

-40

85

°C

 

Relative Humidity

RH

0

85

%

 

Note: Stress in excess of the maximum absolute ratings can cause permanent damage to the transceiver.

 

General Operating Characteristics

Parameter

Symbol

Min.

Typ

Max.

Unit

Note

Data Rate

DR

9.95

10.3125

11.3

Gb/s

 

Supply Voltage

Vcc

3.13

3.3

3.47

V

 

Supply Current

Icc5

 

 

450

mA

 

Operating Case Temp.

Tc

0

 

70

°C

 

 

Electrical Characteristics (TOP(C) = 0 to 70 , VCC = 3.13 to 3.47 V)

Parameter

Symbol

Min.

Typ

Max.

Unit

Note

Transmitter

Differential data input swing

VIN,PP

150

 

1200

mVpp

1

Transmit Disable Voltage

VD

VCC-0.8

 

Vcc

V

 

Transmit Enable Voltage

VEN

Vee

 

Vee+0.8

Input differential impedance

Rin

 

100

 

Ω

 

Receiver

Differential data output swing

Vout,pp

300

 

850

mVpp

2

Output rise time and fall time

Tr, Tf

28

 

 

Ps

3

LOS asserted

VLOS_F

VCC-0.8

 

Vcc

V

4

LOS de-asserted

VLOS_N

Vee

 

Vee+0.8

V

4

Notes:

1. Connected directly to TX data input pins. AC coupling from pins into laser driver IC.

2. Into 100Ω differential termination.

3. 20 – 80%. Measured with Module Compliance Test Board and OMA test pattern. Use of four 1’s and four 0’s sequence in the PRBS 9 is an acceptable alternative. 

4. LOS is an open collector output. Should be pulled up with 4.7kΩ – 10kΩ on the host board. Normal operation is logic 0; loss of signal is logic 1.

 

Optical Characteristics (TOP(C) = 0 to 70 ,VCC = 3.13 to 3.47 V)

Parameter

Symbol

Min.

Typ

Max.

Unit

Note

Transmitter

Operating Wavelength

λ

1470

1490

1510

nm

 

1530

1550

1565

 

Ave. output power (Enabled)

PAVE

0

 

5

dBm

1

Side-Mode Suppression Ratio

SMSR

30

 

 

dB

 

Extinction Ratio

ER

9

 

 

dB

 

RMS spectral width

Δλ

 

 

1

nm

 

Rise/Fall time (20%~80%)

Tr/Tf

 

 

50

ps

 

Dispersion penalty

TDP

 

 

3.2

dB

 

Relative Intensity Noise

RIN

 

 

-128

dB/Hz

 

Output Optical Eye

Compliant with IEEE 0802.3ae

Receiver

Operating Wavelength

λ

1530

1550

1565

nm

 

1470

1490

1510

 

Receiver Sensitivity

PSEN1

 

 

-21

dBm

2

Overload

PAVE

 

 

-7

dBm

 

LOS Assert

Pa

-35

 

 

dBm

 

LOS De-assert

Pd

 

 

-23

dBm

 

LOS Hysteresis

Pd-Pa

0.5

 

 

dB

 

Notes:

1. Average power figures are informative only, per IEEE 802.3ae.

2. Measured with worst ER=9; BER<10-12; 231 – 1 PRBS ,under10.3125Gbps 

 

Pin Defintion And Functions

Pin

Symbol

Name/Description

1

VEET [1]

Transmitter Ground 

2

Tx_FAULT [2]

Transmitter Fault 

3

Tx_DIS [3]

Transmitter Disable. Laser output disabled on high or open 

4

SDA [2]

2-wire Serial Interface Data Line

5

SCL [2]

2-wire Serial Interface Clock Line 

6

MOD_ABS [4]

Module Absent. Grounded within the module 

7

RS0 

Rate Select 0

8

RX_LOS [2]

Loss of Signal indication. Logic 0 indicates normal operation

9

RS1 [5]

Rate Select 1 

10

VEER [1]

Receiver Ground 

11

VEER [1]

Receiver Ground 

12

RD-

Receiver Inverted DATA out. AC Coupled 

13

RD+

Receiver DATA out. AC Coupled 

14

VEER [1]

Receiver Ground 

15

VCCR

Receiver Power Supply 

16

VCCT

Transmitter Power Supply 

17

VEET [1]

Transmitter Ground 

18

TD+

Transmitter DATA in. AC Coupled 

19

TD-

Transmitter Inverted DATA in. AC Coupled 

20

VEET [1]

Transmitter Ground 

Notes: 

1.Module circuit ground is isolated from module chassis ground within the module. 

2.should be pulled up with 4.7k – 10k ohms on host board to a voltage between 3.15Vand 3.6V. 

3.Tx_Disable is an input contact with a 4.7 kΩ to 10 kΩ pullup to VccT inside the module. 

 4.Mod_ABS is connected to VeeT or VeeR in the SFP+ module. The host may pull this contact up to Vcc_Host with a resistor in the range 4.7 kΩ to10 kΩ.Mod_ABS is asserted “High” when the SFP+ module is physically absent from a host slot. 

 

Serial Interface for ID and Digital Diagnostic Monitor 

The ZBC3880-49/55ZBC3880-55/49 transceiver support the 2-wire serial communication protocol as defined in the SFP+ MSA. The standard SFPserial ID provides access to identification information that describes the transceiver’s capabilities, standard interfaces, manufacturer, and other information. Additionally, This SFP+ transceivers provide an enhanced digital diagnostic monitoring interface, which allows real-time access to device operating parameters such as transceiver temperature, laser bias current, transmitted optical power, received optical power and transceiver supply voltage. It also defines a sophisticated system of alarm and warning flags, which alerts end-users when particular operating parameters are outside of a factory set normal range.

The SFP MSA defines a 256-byte memory map in EEPROM that is accessible over a 2-wire serial interface at the 8 bit address 1010000X(A0h), so the originally monitoring interface makes use of the 8 bit address(A2h), so the originally defined serial ID memory map remains unchanged. The structure of the memory map is shown in Table1.

Table 1. Digital Diagnostic Memory Map (Specific Data Field Descriptions)

 

Digital Diagnostic Specifications

The ZBC3880-49/55ZBC3880-55/49 transceivers can be used in host systems that require either internally or externally calibrated digital diagnostics. 

Parameter

Symbol

Units

Min.

Max.

Accuracy

Note

Transceiver temperature

DTemp-E

ºC

-5

+75

±5ºC

1

Transceiver supply voltage

DVoltage

V

2.8

4.0

±3%

 

Transmitter bias current

DBias

mA

0

127

±10%

2

Transmitter output power

DTx-Power

dBm

-2

+7

±2dB

 

Receiver average input power

DRx-Power

dBm

-24

0

±2dB

 

Notes:

1. Internally measured

2. The accuracy of the Tx bias current is 10% of the actual current from the laser driver to the laser

 

Typical Interface Circuit

 

Recommended power supply filter

Note: 

Inductors with DC resistance of less than 1Ω should be used in order to maintain the required voltage at the SFP input pin with 3.3V supply voltage. When the recommended supply filtering network is used, hot plugging of the SFP transceiver module will result in an inrush current of no more than 30 mA greater than the steady state value

 

Package Dimensions 

 

Ordering Information

Part Number

Description

ZBC3880-49/55

SFP+Bidi,9.95 to 11.3Gb/s, 1490/1550nm,80km, 0~70

ZBC3880-55/49

SFP+Bidi,9.95 to 11.3Gb/s, 1550/1490nm, 80km, 0~70

Notes: When CWDM wavelengths, the wavelength spacling>20nm

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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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