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- SPT-XD(17-61)TG-40D 40km DWDM XFP Optical Transceiver
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- Fiber Optic Transceiver Module
- High Speed Cable
- Fiber Optical Cable
- Fiber Optical Patch Cords
- Splitter CWDM DWDM
- PON Solution
- FTTH Box ODF Closure
- PCI-E Network Card
- Network Cables
- Fiber Optical Adapter
- Fiber Optical Attenuator
- Fiber Media Converter
- PDH Multiplexers
- Protocol Converter
- Digital Video Multiplexer
- Fiber Optical Tools
- Compatible
SPT-XD(17-61)TG-40D 40km DWDM XFP Optical Transceiver
SPT-XD(17-61)TG-40D
40km DWDM XFP Optical Transceiver
Features
- Wavelength selectable to C-band ITU-T grid wavel
- Suitable for use in 100GHz channel spacing DWDM systems
- XFP MSA Rev 4.5 Compliant
- Data rate from 9.95Gbps to 11.3Gbps
- No Reference Clock required
- Cooled EML and PIN receiver
- link length up to 40km
- Low Power Dissipation 3.5W Maximum
- XFI and line side loopback Mode Supported
- -5ºC to 70ºC Operating Case Temperature
- Diagnostic Performance Monitoring of module temperature,
- Supply Voltages, laser bias current, transmit optical power, and receive optical power
- RoHS6 compliant (lead free)
Applications
- SONET OC-192&SDH STM 64 (with/without FEC)
- 10GBASE ER/EW (with/without FEC)
- 40km 10G Fiber Channel
- DWDM Networks
Description
DWDM XFP Transceiver exhibits excellent wavelength stability, supporting operation at 100GHz channel, cost effective module. It is designed for 10G DWDM SDH, 10GBASE-ER/EW and 10G Fiber-Channel applications.
The transceiver consists of two sections: The transmitter section incorporates a coded EML laser. And the receiver section consists of a PIN photodiode integrated with a TIA. All modules satisfy class I laser safety requirements. DWDM XFP transceiver provides an enhanced monitoring interface, which allows real-time access to device operating parameters such as transceiver temperature, laser bias current, transmitted optical power, and received optical power and transceiver supply voltage.
Module Block Diagram
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Absolute Maximum Ratings
|
Parameter |
Symbol |
Min |
Max |
Unit |
|
Supply Voltage1 |
Vcc3 |
-0.5 |
4.0 |
V |
|
Supply Voltage2 |
Vcc5 |
-0.5 |
6.0 |
V |
|
Supply Voltage3 |
Vcc2 |
-0.5 |
2 |
V |
|
Storage Temperature |
Tst |
-40 |
85 |
ºC |
Operating Conditions
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Supply Voltage1 |
Vcc3 |
3.13 |
3.3 |
3.47 |
V |
|
Supply current1 |
Icc3 |
- |
- |
750 |
mA |
|
Supply Voltage2 |
Vcc5 |
4.75 |
5 |
5.25 |
V |
|
Supply current2 |
Icc5 |
- |
- |
500 |
mA |
|
Supply Voltage3 |
Vcc2 |
1.71 |
1.8 |
1.89 |
V |
|
Supply current3 |
Icc2 |
- |
- |
750 |
mA |
|
Operating Case temperature |
Tca |
-5 |
- |
70 |
ºC |
|
Module Power Dissipation |
Pm |
- |
- |
3.5 |
W |
Transmitter Specifications –Optical
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Center Wavelength StartofLife[1] |
λc |
λc-25 |
λc |
λc+25 |
pm |
|
Center Wavelength Endoflife[1] |
λc |
λc-100 |
λc |
λc+100 |
pm |
|
Optical Transmit Power |
Po |
-1 |
- |
+2 |
dBm |
|
Optical Transmit Power (disabled) |
PTX_DIS |
- |
- |
-30 |
dBm |
|
Extinction Ratio |
ER |
8.2 |
- |
- |
dB |
|
Jitter Generation(P-P) |
JGP-P |
- |
- |
0.1 |
UI |
|
Jitter Generation (RMS) |
JGRMS |
- |
- |
0.01 |
UI |
|
Spectral Width(-20dB) |
Δλ20 |
- |
- |
0.3 |
nm |
|
Side Mode Suppression Ratio |
SMSR |
30 |
- |
- |
dB |
|
Dispersionpenalty (800ps/nm)[2] |
DP |
- |
- |
2 |
dB |
|
Relative Intensity Noise |
RIN |
- |
- |
-130 |
dB/Hz |
|
Eye Mask |
Compliant with ITU-TG.691 STM-64 eye mask |
||||
Notes:
1. Wavelength stability is achieved within 60 seconds (max) of power up.
2. BER=10 -12; PRBS 2 31-1@9.95Gbps.
Transmitter Specifications – Electrical
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Input differential impedance |
Rim |
- |
100 |
- |
Ω |
|
Differential data Input |
VtxDIFF |
120 |
- |
850 |
mV |
|
Transmit Disable Voltage |
VD |
2.0 |
- |
Vcc3+0.3 |
V |
|
Transmit Enable Voltage |
Ven |
0 |
- |
+0.8 |
V |
|
Transmit Disable Assert Time |
Vn |
- |
- |
10 |
us |
Receiver Specifications – Optical
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Input Operating Wavelength |
λ |
1260 |
- |
1600 |
nm |
|
Receiver sensitivity[1] |
Pavg |
- |
- |
-16 |
dBm |
|
Receiver sensitivity in 10.3Gbps(OMA)[1] |
Rsen1 |
- |
- |
-14.3 |
dBm |
|
Stressed receiver sensitivityin 10.3Gbps(OMA) |
Rsen2 |
- |
- |
-11.3 |
dBm |
|
Maximum Input Power |
RX-over load |
- |
- |
-1 |
dBm |
|
Reflectance |
Rrx |
- |
- |
-27 |
dB |
|
LOS Asserted |
Lsa |
-28 |
- |
- |
dBm |
|
LOS De-Asserted |
Lda |
- |
- |
-22 |
dBm |
|
LOS Hysteresis |
Lh |
0.5 |
- |
- |
dB |
Notes:
1. BER=10 -12; PRBS 2 31-1@9.95Gbps~11.3Gbps.
Receiver Specifications – Electrical
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Output differential impedance |
Rom |
- |
100 |
-- |
Ω |
|
Differential Output Swing |
Vout P-P |
350 |
- |
850 |
mV |
|
Rise/Fall Time[1] |
Tr/Tf |
24 |
- |
- |
ps |
|
Loss of Signal–Asserted |
VOH |
2 |
- |
Vcc3+0.3- |
V |
|
Loss of Signal–Negated |
VOL |
GND |
- |
GND+0.5 |
V |
Notes:
1. 20%-80%;
Mechanical Specifications
The mechanical components defined:
1. The module, clip and connector dimensions are constant for all applications. While the bezel, cage assembly, EMI gasket and heat sink can be designed and/or adjusted for the individual application.
2. The relatively small form factor of the XFP module combined with an adaptable heat sink option allows host system design optimization of module location, heat sink shape/dimension/fins design, and airflow control. The module can be inserted and removed from the cage with the heat sink and clip attached.
Ordering Information
|
Part Number |
Product Description |
|
SPT-XD(17-61)TG-40D |
XX=ITU Grid 17~61, 10Gbps, DWDM XFP 40km, with DDM, -5ºC~+70ºC |
E-mail:sales@sopto.com