Ascent’s 100G ER1-30km SFP56-DD optical transceiver, SFP56-DD-ER30 is designed for using in 100-Gigabit Ethernet links up to 30km over Single-Mode Fiber (SMF). It is compliant with the SFP56-DD MSA, 100G Lambda 100G ER1-30 and CAUI-4 (no FEC). Digital diagnostics functions are available via the I2C interface, as specified by the SFP56-DD MSA. The module incorporates 1 channel optical signal, on 1311nm center wavelength, operating at 100Gbps data rate. This module can convert 2 channels of 53Gbps (PAM4) electrical input data to 1 channel of 100Gbps (PAM4) optical signal, and also can convert 1 channel of 100Gbps (PAM4) optical signal to 2 channels of 53Gbps (PAM) electrical output data. The optical interface uses a Duplex LC connector. The high performance cooled EML transmitter and high sensitivity PIN receiver provide superior performance for 100Gigabit Ethernet applications up to 30km links.
· Compliant to 100G Lambda MSA 100G ER1-30
· Full-duplex transceiver module
· 1x106.25Gb/s(PAM4) optical interface
· 2x53.125Gb/s(PAM4) electrical interface
· 106.25Gbps PAM4 based on a cooled EML TOSA transmitter
· 106.25Gbps PAM4 APD Receiver
· 3.5W maximum power consumption
· Hot-pluggable SFP56-DD form factor
· Maximum link length of 30km on G.652 SMF with KP-FEC
· Duplex LC receptacles
· Built-in digital diagnostic functions
· Operating case temperature range: 0 to 70°C
· Single 3.3V power supply
· RoHS compliant (lead free)
Absolute Maximum Ratings
Parameter | Symbol | Min. | Max. | Unit |
Supply Voltage | Vcc | -0.3 | 3.6 | V |
Input Voltage | Vin | -0.3 | Vcc+0.3 | V |
Storage Temperature | Ts | -20 | 85 | °C |
Case Operating Temperature | Tc | 0 | 70 | °C |
Humidity (non-condensing) | Rh | 5 | 85 | % |
Recommended Operating Conditions
Parameter | Symbol | Min. | Typ. | Max | Unit |
Supply Voltage | Vcc | 3.13 | 3.3 | 3.47 | V |
Operating Case Temperature | Tc | 0 | - | 70 | °C |
Data Rate Per Lane | fd | - | 106.25 | - | Gb/s |
Humidity | Rh | 5 | - | 85 | % |
Power Consumption | Pm | - | 3 | 3.5 | W |
Link Distance with G.652 | D | - | - | 30 | km |
Parameter | Symbol | Min. | Typ. | Max | Unit | Note |
Differential Input Impedance | Zin | 90 | 100 | 110 | ohm | |
Differential Output Impedance | Zout | 90 | 100 | 110 | ohm | |
Differential Input Voltage Amplitude | ΔVin | - | - | 1600 | mVp-p | 1 |
Differential Output Voltage Amplitude | ΔVout | - | - | 900 | mVp-p | 2 |
Optical Characteristics
Parameter | Symbol | Min. | Typ. | Max. | Unit | Note |
Transmitter | ||||||
Centre Wavelength | λc | 1304.5 | - | 1317.5 | nm | - |
Side-Mode Suppression Ratio | SMSR | 30 | - | - | dB | - |
Average Launch Power | Pout | 0 | - | 5.6 | dBm | - |
Transmitter and Dispersion Eye Closure(TDECQ) | TDECQ | - | - | 3.9 | dB | |
Extinction Ratio | ER | 5 | - | - | dB | - |
Average Launch Power of OFF transmitter | - | - | -30 | dB | - | |
Receiver | ||||||
Centre Wavelength | λc | 1304.5 | - | 1317.5 | nm | - |
Receiver Sensitivity in OMAouter | RXsen | - | - | -12.5 | dBm | 1 |
Average Receive Power | Pin | -14.7 | - | -3.4 | dBm | - |
Receiver Reflectance | - | - | -26 | dB | - | |
LOS Assert | - | -15.7 | - | dBm | - | |
LOS De-Assert – OMA | - | -13.7 | - | dBm | - | |
LOS Hysteresis | 0.5 | - | - | dB | - | |
Damage Threshold | -3 | dBm |
Parameter | Symbol | Min. | Max. | Unit | Note |
Temperature Monitor Absolute Error | DMI_Temp | -3 | +3 | °C | Over operating temperature range |
Supply Voltage Monitor Absolute Error | DMI _VCC | -0.1 | 0.1 | V | Over full operating range |
Channel RX Power Monitor Absolute Error | DMI_RX_Ch | -2 | 2 | dB | 1 |
Channel Bias Current Monitor | DMI_Ibias_Ch | -10% | 10% | mA | |
Channel TX Power Monitor Absolute Error | DMI_TX_Ch | -2 | 2 | dB | 1 |
Notes:
1. Due to measurement accuracy of different single mode fibers, there could be an additional +/-1 dB fluctuation, or a +/- 3 dB total accuracy.
2. Digital diagnostics functions are available via the I2C interface as specified by SFP-DD MIS. The SFP-DD MIS management memory is shown in below figure.
The Lower Memory Overview
Page 00h Memory Overview
Page 01h Memory Overview
3. Due to eight-bit addresses, This limits the management memory that can be directly accessed by the host to 256 bytes, which is divided in Lower Memory (addresses 00h through 7Fh) and Upper Memory (addresses 80h through FFh).
4. The addressing structure of the additional internal management memory1 is shown in below figure. The management memory inside the module is arranged as a unique and always host accessible address space of 128 bytes (Lower Memory)
and as multiple upper address subspaces of 128 bytes each (Pages), only one of which is selected as host visible in Upper Memory. A second level of Page selection is possible for Pages for which several instances exist (e.g. where a bank of
ages with the same Page number exists).
Page 13h Memory Overview
Page 14h Memory Overview
5. This structure supports a flat 256 byte memory for passive copper modules and permits timely access to addresses in the Lower Memory, e.g. Flags and Monitors.
Less time critical entries, e.g. serial ID information and threshold settings, are available with the Page Select function in the Lower Page. For more complex modules which require a larger amount of management memory the host needs to use
dynamic mapping of the various Pages into the host addressable Upper Memory address space, whenever needed.
6. The management memory map has been designed largely after the CMIS memory map where pages and banks are used in order to enable time critical interactions between host and module while expanding the memory size. This memory map
has been changed in order to accommodate just two electrical lanes and to limit the required memory. The single address approach is used as found in QSFP.
Regulatory Compliance
Ascent’s SFP56-DD-ER30 transceivers are Class 1 Laser Products. They meet the requirements of the following standards.
Feature | Standard |
Laser Safety | EC 60825-1:2014 (3rd Edition) EN 60825-2:2004+A1+A2 |
Electrical Safety | EN 62368-1: 2014 IEC 62368-1:2014 UL 62368-1:2014 |
Environmental protection | Directive 2011/65/EU with amendment(EU)2015/863 |
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