SFP-10GM-T-30 Data Sheet

03-12-2025 - SFP-10GM-T-30 Data Sheet 10M/100M/1G/2.5G/5G/10Gbps NBASE-T SFP Copper RJ-45 30m Transceiver SFP-10GM-T-30 SFP-10GM-T-30.png Application 10 Gigabit Ethernet over Category 6a/7 Cable Switch/Route to Switch/Route Link High Speed I/O for File Servers Features Supports XFI or SGMII to Copper Auto-negotiation 10G BASE-T operation in Host Systems with XFI Interface. 10G BASE-T supports Links up to 30m using Cat 6a/7 Cable. Power Consumption 2.5W MAX @ 30m 10/100/1000 BASE-T operation in Host Systems with SGMII Interface. 10/100/1000 BASE-T supports Links up to 100m using Cat 5 Cable or better Unshielded and Shielded cable support MDI/MDIX Crossover. 3.3V Single Power Supply. Hot-pluggable SFP Footprint. Fully Metallic Enclosure for Low EMI. Compact RJ-45 Connector Assembly Detailed Product Information in EEPROM Access to I²C -Wire Serial Bus Interface for Serial ID and PHY Register Access Compliant with SFF-8431 SFF-8432 and SFF-8472 Compliant with SFP MSA Compliant with IEEE 802.3-2012, IEEE 802.3az Compliant with FCC 47 CFR Part 15 Class B/EN55022 Class B Compliant with RoHs-6. Operation temperature range 0°C to 70°C Description The FS SFP-10GM-T-30 copper transceiver module is a high performance integrated duplex data link for bi-directional communication over copper cable. It is specifically designed for high speed communication links that require 10 Gigabit Ethernet over Cat7 cable at XFI to Copper Auto-negotiation mode. SFP-10GM-T-30 supports USXGMII to Copper Auto-negotiation mode. compliant with the Gigabit Ethernet and 1000BASE-T standards as specified in IEEE 802.3-2012 and IEEE 802.3ab, which supports 10/100/1000 Base-T Copper data- rate up to 100 meters reach over twisted-pair category 5 cable. The SFP-10GM-T-30 provides standard serial ID information compliant with SFP MSA, which can be accessed with address of A0h via the 2- wire serial CMOS EEPROM protocol. The physical IC can also be accessed via 2-wire serial bus at address ACh. The address of the PHY is 1010110x where x is the R/ W bit. The SFP-10GM-T-30 is a 10GBase-T auto-negotiation optical transceiver designed for operation in 10G SFP+ switch ports. This module does not support backward compatibility with 1G SFP ports - while physically insertable into 1G ports, link establishment will fail due to incompatible electrical signaling specifications. The device features multi-rate auto-negotiation capability, supporting speed adaptation across 10M/100M/1G/2 .5G/5G/10G operational modes, with the final link speed determined by the peer device' s capability. For 1G-T connectivity requirements, the SFP-GE-T (1GBase-T) module is recommended as the compatible alternative. Product Specifications I. SFP+ to Host Connector Pin Out Pin Signal Name Description MSA Note 1 VEET Transmitter ground (common with receiver ground) 2 TFAULT Transmitter Fault. Not supported,Grounded in module Note 1 3 TDIS Transmitter Disable - Module disables on high or open Note 2 4 MOD_DEF(2) Module Definition 2. Data line for Serial ID. Note 3 5 MOD_DEF(1) Module Definition 1. Clock line for Serial ID. Note 3 6 MOD_DEF(0) Module Definition 0. Grounded in module. Note 3 7 Rate Select No connection 8 LOS Loss of Signal - High Indicates Loss of Signal Note 4 9 VEER Receiver Ground (common with transmitter ground) 10 VEER Receiver Ground (common with transmitter ground) 11 VEER Receiver Ground(common with transmitter ground) 12 RD- Receiver Inverted DATA out. AC Coupled Note 5 13 RD+ Receiver Non-inverted DATA out. AC Coupled Note 5 14 VEER Receiver Ground (common with transmitter ground) 15 VCCR Receiver Power Supply Note 6 16 VCCT Transmitter Power Supply Note 6 17 VEET Transmitter Ground (Common with Receiver Ground) 18 TD+ Transmitter Non-Inverted DATA in. AC Coupled. Note 7 19 TD- Transmitter Inverted DATA in. AC Coupled. Note 7 20 VEET Transmitter Ground(common with receiver ground) Note: 1. TX Fault is not used and is always tied to ground. 2. TX Disable as described in the MSA is not applicable to the module, but is used for convenience as an input to reset the internal ASIC. This pin is pulled up within the module with a 4.7 Kohm resistor. Low (0–0.8 V): Transceiver on Between (0.8 V and 2.0 V): Undefined High (2.0–3.465 V): Transceiver in reset disable state Open: Transceiver in reset disable state 3. Mod-Def 0, 1, 2. These are the module definition pins. They should be pulled up with a 4.7-10 Kohm resistor on the host board to a supply less than VCCT+ 0.3 V or VCCR+ 0.3 V. Mod Def 0 is tied to ground to indicate that the module is present. Mod-Def 1 is clock line of two wire serial interface for optional serial ID. Mod-Def 2 is data line of two wire serial interface for optional serial ID. 4. This pin is open drain CMOS output signals. They should be pulled up with a 4.7-10 Kohm resistor on the host board to a supply less than VCCT + 0.3 V or VCCR + 0.3 V. (see Table 3. Low-Speed Signals, Electronic Characteristics) 5. RD-/+: These are the differential receiver outputs. They are ac coupled 100 ohm differential lines which should be terminated with 100 ohm differential at the user SerDes. The ac coupling is done inside the module and is thus not required on the host board. The voltage swing on these lines will be between 370 and 2000 mV differential (185 – 1000 mV single ended) when properly terminated. These levels are compatible with CML and LVPECL voltage swings. 6. VCCR and VCCT are the receiver and transmitter power supplies. They are defined as 3.3 V ± 5% at the SFP connector pin. The maximum supply current is about 300mA and the associated in-rush current will typically be no more than 30 mA above steady state after 500 nanoseconds. 7. TD-/+: These are the differential transmitter inputs. They are ac coupled differential lines with 100 ohm differential termination inside the module. The ac coupling is done inside the module and is thus not required on the host board. The inputs will accept differential swings of 500 – 2400 mV (250 –1200 mV single ended), though it is recommended that values between 500 and 1200 mV differential (250 – 600 mV single ended) be used for best EMI performance. These levels are compatible with CML and LVPECL voltage swings. II. SFP+ to Host Connector Pin Out and RJ45 Connector Diagram image.png Figure 1a. Diagram of Host Board Connector Block Pin Numbers and Names image.png Figure1b. MDI ( RJ 45 Jack) Pin Assignment III. Recommended Interface Circuit image.png Figure 2. Recommended Interface Circuit IV. Recommended Host Board Power Supply Circuit image.png Figure 3. Recommended Host Board Power Supply Circuit V. Power Supply Interface Electronic Characteristics The SFP-10GM-T-30 has an input voltage range of 3.3 V +/- 5%. The 4V maximum voltage is not allowed for continuous operation. Parameter Symbol Min Typ. Max Unit Notes/Conditions Supply Current ls 650 700 mA At 10GBase-t Cat 6a/7 30m 2.5W max power over full range of voltage and temperature. See caution note below 290 320 mA At 100Base-t Cat 5 100m over full range of voltage and temperature 330 360 mA At 10 Base-t Cat 5 100m over full range of voltage and temperature 430 470 mA At 1000Base-t Cat 5 100m over full range of voltage and temperature Input Voltage Vcc 3.135 3.3 3.465 V Referenced to GND Caution: Power consumption and surge current are higher than the specified values in the SFP MSA Vl. Low-Speed Signals MOD_DEF (1) (SCL) and MOD_DEF (2) (SDA) are open drain CMOS signals. Both MOD_ DEF (1) and MOD_DEF (2) must be pulled up to host_Vcc. Table 3. Low-Speed Signals, Electronic Characteristics Parameter Symbol Min. Max. Unit Note/Conditions SFP Output LOW VOL 0 0.5 V 4.7k to 10k pull-up to host_Vcc. SFP Output HIGH VOH host_Vcc - 0.5 host_Vcc + 0.3 V 4.7k to 10k pull-up to host_Vcc. SFP Input LOW VIL 0 0.8 V 4.7k to 10k pull-up to Vcc. SFP Input HIGH VIH 2 Vcc + 0.3 V V 4.7k to 10k pull-up to Vcc. Vll. High-Speed Electrical Interface All high-speed signals are AC-coupled internally. Table 4. High-Speed Electrical Interface, Transmission Line-SFP+ Parameter Symbol Min Typ. Max Unit Notes/Conditions Line Frequency 10.3125 GHz XFI to Copper 1.25 GHz SGMII to Copper Tx Output Impedance Zout,TX 100 Ohm Differential Rx Input Impedance Zin,RX 100 Ohm Differential Table 5. High-Speed Electrical Interface, Host-SFP+ Parameter Symbol Min. Typical Max. Unit Note/Conditions Data Input: Transmitter Differential Input Voltage (TD +/-) Vinsing 500 800 1100 mV Data Output: Receiver Differential Output Voltage (RD +/-) Voutsing 500 800 1100 mV Rise/Fall Time Tr,Tf 25 47 psec 20%-80% Tx Input Impedance Zin 50 Ohm Single ended Rx Output Impedance Zout 50 Ohm Single ended Table 6. General Specifications General Specifications Parameter Symbol Min. Typical Max. Unit Note/Conditions Data Rate BR 10.3125 Gb/s IEEE 802.3 compatible. Cable Length L 30 m @10GBase-T .Category 6a/7 BER < 100 m @10/100/1000Base-T .Category 5 UTP. BER < Notes: 1. Automatic crossover detection is enabled. External crossover cable is not required. 2. 10GBASE-T operation requires the host system to have an XFI interface with no clocks. 3. 10/100/1000 BASE-T operation requires the host system to have an SGMII interface with no clocks. VIII. Environmental Specifications The SFP-10GM-T-30 has an range from 0°C to +70°C case temperature as specified in Table 7. Table 7. Environmental Specifications Parameter Symbol Min. Typical Max. Unit Notes/Conditions Operating Temperature Top 0 70 °C Case temperature Storage Temperature Tsto -40 85 °C Ambient temperature IX. Serial Communication Protocol Table 8. Specification Parameter Symbol Min. Typical Max. Unit Note/Conditions Clock Rate 100 200 Hz X. Serial ID Memory Contents: The HTSFP- XG – 1111TF provides standard serial ID information compliant with SFP MSA, which can be accessed with address of A0h via the 2-wire serial CMOS EEPROM protocol. Address Field Size (Byte) Name of Field Description and Contents Hex Base ID Fields 0 1 Identifier Type of Serial transceiver (SFP) 03 1 1 Ext. Identifier Extended identifier of type serial transceiver (MOD4) 04 2 1 Connector Code of optical connector type (Copper) 22 3-10 8 Transceiver 10G Base-XFI to Copper 10 00 00 00 00 00 00 00 11 1 Encoding 64B/66B 06 12 1 BR,Nominal Nominal baud rate, unit of 100 MBd 10.3125 GBd For 10GBase-T 67 13 1 Rate Identifier Type of rate select functionality (Unspecified) 00 14 1 Length (SMF 9um)-km Link length supported for single mode fiber, units of km 00 15 1 Length (SMF 9um) Link length supported for 9/125um fiber, units of 100m 00 16 1 Length (50um) Link length supported for 50/125um OM2 fiber, units of 10m 00 17 1 Length (62.5um) Link length supported for 62.5/125um OM1 fiber, units of 10m 00 18 1 Length (OM4 or copper cable) Link length supported for 50um OM4 fiber, units of 10m. Alternatively copper or direct attach cable, units of m. For copper links, this value specifies minimum link length (30m) supported by the transceiver while operating in compliance with applicable standards using copper cable. 1E 19 1 Length (OM3) Link length supported for 50 um OM3 fiber, units of 10 m 00 20-35 16 Vendor Name SFP vendor name (ASCII), "FS " 36 1 Transceiver Code for electronic or optical compatibility 00 37-39 3 Vendor OUI SFP vendor IEEE company ID, A value of all zero in the 3-byte field indicates that the Vendor OUI is unspecified. 00 00 00 40-55 16 Vendor PN Part number provided by SFP vendor (ASCII) “SFP-10G-T-30” 48 54 53 46 50 2D 58 47 2D 31 31 31 31 54 46 20 56-59 4 Vendor rev Part number provided by SFP vendor (ASCII). A value of all zero in the 4-byte field indicates that the vendor revision is unspecified. (1.0 revision) 31 2E 30 20 60-61 2 Wavelength Laser wavelength (Passive/Active Cable Specification Compliance). A value of 00h for both A0h Byte 60 and Byte 61 denotes laser wavelength or cable specification compliance is unspecified. 00 00 62 1 Unallocated 00 63 1 CC_BASE Check code for Base ID Fields Least significant byte of Check sum of data in address 0 to 62 xx 63 1 CCID Least significant byte of Check sum of data in address 0-62 xx Extended ID Fields 64-65 2 Option Indicates which optional transceiver signals are implemented TX_DISABLE and RX_LOS are implemented 00 12 66 1 BR, max Upper bit rate margin, units of %. A value of 00h indicates that this field is not specified 67 1 BR, min Lower bit rate margin, units of % A value of 00h indicates that this field is not specified. 68-83 16 Vendor SN Serial number provided by vendor (ASCII) xx xx xx xx xx xx xx xx xx xx xx xx xx xx xx xx 84-91 8 Date code Manufacturing date code Year (2 bytes), Month (2 bytes), Day (2 bytes) vendor specific lot code, may be blank (2 bytes) xx xx xx xx xx xx xx xx 92 1 Diagnostic Monitoring Type Indicates which type of diagnostic monitoring is implemented (if any) in the transceiver 00 93 1 Enhanced Options Indicates which optional enhanced features are implemented (if any) in the transceiver 00 94 1 SFF-8472 Compliance Indicates which revision of SFF-8472 the transceiver complies with. A value of 00h indicates Digital diagnostic functionality not included or undefined. 00 95 1 CC_EX Check code for the extended ID Fields (addresses 64 to 94) xx Vendor Specific ID Fields 96-127 32 Vendor specific Vendor Specific EEPROM, all 00 128-255 128 Reserved Reserved for SFF-8079 all 00 XI. Mechanical Drawing image.png Figure 4. Mechanical Diagram of Copper SFP+ Test Center I. Compatibility Testing Each fiber optical transceiver has been tested in host device on site in FS Assured Program to ensure full compatibility with over 200 vendors. image.png Above is part of our test bed network equipment. For more information, please click the Test Bed PDF. It will be updated in real time as we expand our portfolio. II. Performance Testing Each fiber optical transceiver has been fully tested in FS Assured Program equipped with world's most advanced analytical equipment to ensure that our transceivers work perfectly on your device. image.png Order Information Part Number Description SFP-10GSR-85 10GBASE-SR SFP+ 850nm 300m DOM Transceiver SFP-10GLRM-31 10GBASE-LRM SFP+ 1310nm 220m DOM Transceiver SFP-10GLR-31 10GBASE-LR SFP+ 1310nm 10km DOM Transceiver SFP-10GER-55 10GBASE-ER SFP+ 1550nm 40km DOM Transceiver SFP-10GZR-55 10GBASE-ZR SFP+ 1550nm 80km DOM Transceiver SFP-10GZR100-55 10GBASE-ZR SFP+ 1550nm 100km DOM Transceiver SFP-10GMSR-85 Dual-Rate 1000BASE-SX and 10GBASE-SR SFP+ 850nm 300m DOM Transceiver SFP-10GMLR-31 Dual-Rate 1000BASE-LX and 10GBASE-LR SFP+1310nm 10km DOM Transceiver SFP-10G-T-30 10GBASE-T SFP+ Copper 30m RJ-45 Transceiver Module SFP-10GM-T-30 10M/100M/1G/2.5G/5G/10Gbps NBASE-T SFP+ Copper 30m RJ-45 Transceiver Module SFP-10G-T-30-RP 10GBASE-T SFP+ Copper 30m RJ-45 Transceiver Module with Reduced Power Consumption SFP-10G-T-30I 10GBASE-T SFP+ Copper 30m RJ-45 Industrial Transceiver Module SFP-10G-T-80 10GBASE-T SFP+ Copper 80m RJ-45 Transceiver Module SFP-10G-T-100 10GBASE-T SFP+ Copper 100m RJ-45 Transceiver Module Notes: 1. 10G SFP+ transceiver module is individually tested on coresponding equipment such as Cisco, Arista, Juniper, Dell, Brocade and other brands, and passes the monitoring of FS.COM intelligent quality control system.

Optical Transceiver Modules Quick Start Guide V3.0

02-12-2025 - For details, please click the attachment icon below to view or download for a good reading experience or resources.

10G-T Copper Transceiver Module FAQ

25-09-2025 - 10G-T Copper Transceiver Module FAQ Chapter 1. General FAQ 1.1 Does the 10G-T module support auto-negotiation for 1G/2.5G/5G speeds? The FS 10G-T module complies with the IEEE 802.3 standard. The model SFP-10GM-T-30 supports auto-negotiation at 100M/1G/2.5G/5G/10G speeds and is backward compatible with lower-speed ports. However, please note that speed downgrade performance can also depend on the specific mechanisms of the connected device. FS has a large test equipment environment that can generally simulate most scenarios. We strongly recommend that you consult FS Technical Suppor for a definitive answer regarding such speed negotiation issues. 1.2 What is the maximum transmission distance of a 10G-T module? On Cat6a/Cat7 twisted-pair cables, conventional 10G-T modules support 10GBASE-T transmission up to 30 meters. For distances exceeding this, we recommend using optical modules or DAC/AOC cables. FS also offers 10G-T modules with 80/100 meter transmission distances. 1.3 When should I choose a 10G-T module and when an optical module? If the existing network already has twisted-pair cabling (Cat6a/Cat7) and the link distance is less than 30 meters, 10G-T modules offer greater flexibility and lower cabling costs. If the link length exceeds 30 meters, or if higher power consumption/latency requirements are required, optical modules or DAC/AOC are recommended. 1.4 Are 10G-T modules hot-swappable? Yes. FS 10G-T modules comply with the SFP+ MSA standard and support online hot-swapping. Replacing them will not affect the normal operation of other ports. 1.5 What's the difference between the FS 10G-T module and a standard Gigabit electrical port module? The FS Gigabit electrical module (1000BASE-T SFP) supports a maximum rate of 1G only, with low power consumption, making it suitable for Gigabit access. The 10G-T module (e.g., SFP-10GM-T-30 supports multi-rate auto-negotiation from 1G to 10G) is ideal for future network upgrades, though it has relatively higher power consumption. 1.6 How to determine the number of 10G-T modules I should use? Determine the quantity based on your device's available SFP+ port count, existing cabling environment, and future bandwidth requirements. For short-distance connections to servers or storage equipment, 10G-T is recommended. For backbone networks or long-distance links, optical modules or DAC cables are recommended. Chapter 2. Deployment & Compatibility 2.1 Are FS 10G-T modules compatible with switches from brands like Cisco, HPE, and Arista? Yes. FS offers multi-vendor compatible versions that have undergone rigorous compatibility testing. You can verify compatibility for your specific device model using the lookup tool on the FS Compatibility Test. 2.2 If my device model isn't listed on the official website, can I still use the FS 10G-T module? Some devices may not be listed publicly, but FS can provide custom programming services to ensure compatibility with your device. Please Contact Us for more details. 2.3 Does the 10G-T module support standard SFP+ slots? Yes. The FS 10G-T module uses a standard SFP+ form factor and can be directly inserted into any port that complies with the SFP+ MSA standard. 2.4 Can 10G-T modules be used interchangeably with original optical modules or DACs? Yes. 10G-T modules can be used interchangeably with optical modules and DAC/AOC cables within the same switch without affecting normal communication. 2.5 Does migrating a 10G-T module between different devices require reconfiguration? No reconfiguration is required. The module's compatibility logic is stored in EEPROM, allowing for plug-and-play operation when inserted into compatible devices. 2.6 If I encounter compatibility issues, does FS provide technical support? Yes. FS offers 24/7 technical support and compatibility assurance. If your device is unusable due to compatibility issues, we support returns, exchanges, or customized solutions. Please contact FS Technical Suppor when you require any assistance. Chapter 3. Power Consumption 3.1 What is the typical power consumption of the FS 10G-T module? The typical power consumption of FS 10G-T modules generally ranges from 1.5W to 2.5W, with specific values depending on the model and transmission distance. For example, the SFP-10G-T-30-RP consumes approximately 1.5W, while the SFP-10G-T-100 and SFP-10G-T-30 models consume about 1.8W and 2.5W respectively. It is recommended to verify your equipment's power budget before purchase. 3.2 Why do 10G-T modules consume more power than optical modules? 10GBASE-T technology requires complex signal encoding, high-speed electrical-optical-electrical conversion, and the driving of Cat.5e/6 cables within the module. Consequently, its power consumption is higher than that of optical modules which perform direct photoelectric conversion. 3.3 Will high power consumption affect device stability? Generally not. As long as the device has good heat dissipation (fans and smooth airflow), and the module power consumption is within the design range of the switch or server, it will not affect operational stability. 3.4 Will the device overheat if multiple 10G-T modules are installed at full capacity? Generally, if the overall heat dissipation design is appropriate, it won't. However, for devices with high port density, a mixed deployment (partially using optical modules or DACs) is recommended to reduce the overall heat load. 3.5 How can I reduce the power consumption impact of 10G-T modules? Power consumption can be reduced through the following methods: ① Choose the appropriate cabling method, prioritizing DAC/AOC for short distances; ② Control the usage ratio, using 10G-T at key access layers; ③ Ensure that the equipment has good heat dissipation and air duct design. 3.6 Do FS 10G-T modules meet energy efficiency or power saving standards? FS modules comply with the IEEE 802.3az Energy Efficient Ethernet (EEE) standard and automatically reduce power consumption when the link is idle or under low load. Chapter 4. Application & Support 4.1 Is one end of the 10G-T module an optical or electrical port? How do I connect it? One end of the module has a standard SFP+ connector (for plugging into a switch/server), and the other end has an RJ45 electrical port (for connecting to a Cat6a/Cat7 twisted pair cable). 4.2 Can the 10G-T module be used with regular network cables (Cat5e/Cat6)? Yes, but the speed and distance will be limited. Cat6 supports a maximum of approximately 10G/30m, while Cat5e generally only stably supports 1G. Cat6a/Cat7 is recommended. 4.3 How can I confirm that the 10G-T modules are working properly across multiple devices? You can confirm this using the following methods: ① Observe whether the switch port indicator is on; ② Check the link status and speed on the device management interface; ③ Use tools such as iPerf to test network connectivity and bandwidth. 4.4 Can the 10G-T module be used in a PoE (Power over Ethernet) environment? Yes. PoE power is supplied by the switch's RJ45 port. The 10G-T module is only responsible for data transmission and does not affect PoE power supply. 4.5 What should I do if my 10G-T module isn't recognized by my device? You can troubleshoot by following these steps: ① Verify the module model is compatible with the device; ② Test with a different network cable; ③ Insert the module into a different port or device to verify it works properly; ④ Contact FS Technical Support to request a replacement or re-program the compatibility information, if necessary.

Part Number Change Notice for 10G Cable & Transceiver Modules

28-08-2025 - Part Number Change Notice for 10G Cable & Transceiver Modules FS announces a part number change for the optical modules and cables listed below. This is solely a product part number change announcement - functionality remains completely unaffected when using the new part numbers. The updated numbering system is designed to streamline the customer ordering process. 1. Direct Attach Cables (DACs) & Active Optical Cables (AOCs) Former Part Number Upgraded Part Number Date SFPP-PCxx (0.5m-7m) SFP-10G-PCxxx (0.5m-7m) April 15, 2024 SFPP-ACxx (1m-10m) SFP-10G-ACxxx (1m-10m) SFPP-AOxx (1m-30m) SFP-10G-AOxxx (1m-30m) SFPP-AOxx-I (1m-70m) SFP-10G-AOxxx-I (1m-70m) XFP-PC02 (2m) XFP-10G-PC02 2. SFP+/XFP Modules (Fiber & Copper) Former Part Number Upgraded Part Number Date SFP-10GSR-85 (300m) SFP-10GSR-85 August 10, 2024 SFP-10GSR-85 (300m, Dual-Rate) SFP-10GMSR-85 SFP-10GSR-85-I (300m, Dual-Rate) SFP-10GMSR-85-I SFP-10GLR-31 (20km) SFP-10GELR-31 SFP-10GLR-31 (20km, Ind) SFP-10GELR-31-I SFP-10GLR-31 (10km, Dual-Rate) SFP-10GMLR-31 SFP-10GLR-31 (10km, Dual-Rate, Ind) SFP-10GMLR-31-I SFP-1/10GLR20-I (20km, Ind) SFP-10GMELR-31-I SFP-10GLRM-31 (2km, SMF) SFP-10GLRL-31 SFP-10GZRC-55 (100km) SFP-10GZR100-55 SFP-10GZRC-55-I (100km) SFP-10GZR100-55-I SFP-10GZRC-120 (120km) SFP-10GZR120-55 SFP-10G-T (30m) SFP-10G-T-30 SFP-10G-T (80m) SFP-10G-T-80 SFP-10G-T100 (100m) SFP-10G-T-100 SFP-10G-T-I (30m) SFP-10G-T-30I SFP-10GM-T (30m) SFP-10GM-T-30 XFP-10GZRC-55 (100km) XFP-10GZR100-55 3. Loopback Modules Former Part Number Upgraded Part Number Date 10GSFP-LPM SFP-LOOP-10G August 10, 2024 4. SFP+ Modules (BIDI) Former Part Number Upgraded Part Number Date SFP-10G-BX (1270nm-TX/1330nm-RX 10km) SFP-10G23-BX10 February 20, 2025 SFP-10G-BX (1330nm-TX/1270nm-RX 10km) SFP-10G32-BX10 SFP-10G-BX (1270nm-TX/1330nm-RX 20km) SFP-10G23-BX20 SFP-10G-BX (1330nm-TX/1270nm-RX 20km) SFP-10G32-BX20 SFP-10G-BX40 (1270nm-TX/1330nm-RX 40km) SFP-10G23-BX40 SFP-10G-BX40 (1330nm-TX/1270nm-RX 40km) SFP-10G32-BX40 SFP-10G-BX60 (1270nm-TX/1330nm-RX 60km) SFP-10G23-BX60 SFP-10G-BX60 (1330nm-TX/1270nm-RX 60km) SFP-10G32-BX60 SFP-10G-BX80 (1490nm-TX/1550nm-RX 80km) SFP-10G45-BX80 SFP-10G-BX80 (1550nm-TX/1490nm-RX 80km) SFP-10G54-BX80 SFP-10G-BX100 (1490nm-TX/1550nm-RX 100km) SFP-10G45-BX100 SFP-10G-BX100 (1550nm-TX/1490nm-RX 100km) SFP-10G54-BX100 SFP-10G-BX-I (1270nm-TX/1330nm-RX 10km, Ind) SFP-10G23-BX10-I SFP-10G-BX-I (1330nm-TX/1270nm-RX 10km, Ind) SFP-10G32-BX10-I SFP-10G-BX-I (1270nm-TX/1330nm-RX 20km, Ind) SFP-10G23-BX20-I SFP-10G-BX-I (1330nm-TX/1270nm-RX 20km, Ind) SFP-10G32-BX20-I SFP-10G-BX40-I (1270nm-TX/1330nm-RX 40km, Ind) SFP-10G23-BX40-I SFP-10G-BX40-I (1330nm-TX/1270nm-RX 40km, Ind) SFP-10G32-BX40-I SFP-10G-BX60-I (1270nm-TX/1330nm-RX 60km, Ind) SFP-10G23-BX60-I SFP-10G-BX60-I (1330nm-TX/1270nm-RX 60km, Ind) SFP-10G32-BX60-I SFP-10G-BX80-I (1490nm-TX/1550nm-RX 80km, Ind) SFP-10G45-BX80-I SFP-10G-BX80-I (1550nm-TX/1490nm-RX 80km, Ind) SFP-10G54-BX80-I XFP-10G-BX (1270nm-TX/1330nm-RX 10km) XFP-10G23-BX10 XFP-10G-BX (1330nm-TX/1270nm-RX 10km) XFP-10G32-BX10 XFP-10G-BX (1270nm-TX/1330nm-RX 20km) XFP-10G23-BX20 XFP-10G-BX (1330nm-TX/1270nm-RX 20km) XFP-10G32-BX20 XFP-10G-BX40 (1270nm-TX/1330nm-RX 40km) XFP-10G23-BX40 XFP-10G-BX40 (1330nm-TX/1270nm-RX 40km) XFP-10G32-BX40 XFP-10G-BX60 (1270nm-TX/1330nm-RX 60km) XFP-10G23-BX60 XFP-10G-BX60 (1330nm-TX/1270nm-RX 60km) XFP-10G32-BX60 XFP-10G-BX80 (1270nm-TX/1330nm-RX 80km) XFP-10G23-BX80 XFP-10G-BX80 (1330nm-TX/1270nm-RX 80km) XFP-10G32-BX80 Customer Impact of Change and Recommended Action: No functional changes - There is no change to the fit or function of the products. Customers may receive either label until the old inventory is depleted. No action required - No action is needed by customers. Questions? - Please Contact Us for any questions or concerns.