Installing Transceivers and Optical Components on VSP Operating System Software Release 5.3 NN47227-301 Issue 09.
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Contents Chapter 1: Introduction............................................................................................................ 7 Purpose.................................................................................................................................. 7 Chapter 2: New in this document............................................................................................ 8 Release 5.3............................................................................................
Contents SFP+ labels.................................................................................................................... 44 General SFP+ specifications............................................................................................ 44 Supported SFP+ transceivers........................................................................................... 45 Chapter 8: QSFP+.............................................................................................................
Contents Glossary................................................................................................................................... 97 May 2017 Installing Transceivers and Optical Components on VOSS Comments on this document? infodev@avaya.
Chapter 1: Introduction Purpose This document provides installation instructions and technical specifications for the following: • Small Form Factor Pluggable (SFP) • Small Form Factor Pluggable plus (SFP+) • Quad Small Form Factor Pluggable plus (QSFP+) • Quad Small Form Factor Pluggable 28 (QSFP28) VOSS runs on the following product familes: • Avaya Virtual Services Platform 4000 Series • Avaya Virtual Services Platform 7200 Series • Avaya Virtual Services Platform 8000 Series Not all products support al
Chapter 2: New in this document The following sections detail what is new in Installing Transceivers and Optical Components on VSP Operating System Software, NN47227-301. Release 5.3 100 Gigabit Ethernet Quad Small Form Factor Pluggable 28 (QSFP28) transceivers and direct attach cables (DAC) VOSS 5.3 adds the 100GBASE-SR4 and 100GBASE-LR4 QSFP28 transceivers and QSFP28 100 Gigabit DACs.
Chapter 3: Safety and equipment care information This chapter contains important safety and regulatory information. Read this section before you install a transceiver. Fiber optic equipment care Use the information in this section to properly maintain and care for fiber optic equipment. Transceivers are static sensitive. Dust contamination can reduce the performance of optical parts in transceivers.
Safety and equipment care information Use the following precautions to avoid damaging the glass fiber: • Do not kink, knot, or vigorously flex the cable. • Do not bend the cable to less than a 40 mm radius. • Do not stand on fiber optic cable; keep the cable off the floor. • Do not pull fiber optic cable harder than you do a cable containing copper wire of comparable size. • Do not allow a static load of more than a few pounds on a section of the cable.
Cleaning single connectors Danger: Risk of eye injury When you inspect a connector, ensure that light sources are off. The light source in fiber optic cables can damage your eyes. • If you suspect only the possibility of dust particles, for example, if you leave a connector uncapped in a clean environment, use high-quality canned air or a reel cleaner, for example, a Cletop, to clean the connector. A reel cleaner is a good choice to ensure that no dust contaminates the connector.
Safety and equipment care information To avoid getting debris in your eyes, wear safety glasses when you work with the canned air duster. To avoid eye irritation on contact, wear safety glasses when you work with isopropyl alcohol. Procedure 1. Remove dust or debris by applying canned air to the cylindrical and end-face surfaces of the connector. 2. Gently wipe the cylindrical and end-face surfaces with a tissue dampened with optical-grade isopropyl alcohol. 3.
Cleaning receptacles To avoid getting debris in your eyes, wear safety glasses when you work with the canned air duster. To avoid eye irritation on contact, wear safety glasses when you work with isopropyl alcohol. Procedure 1. Remove or retract the shroud. On removable shroud connectors, hold the shroud on the top and bottom at the letter designation, apply medium pressure, and then pull it free from the connector body. Do not discard the shroud.
Safety and equipment care information Warning: Risk of equipment damage To avoid contamination, only clean optical ports if you see evidence of contamination or reduced performance exists, or during their initial installation. To prevent oil contamination of connectors, use only high-quality canned compressed air. Do not allow the air extension tube to touch the bottom of the optical port. Procedure 1.
Chapter 4: Supported transceiver, BOCs, and DACs information Supported transceivers The following sections show supported SFP, SFP+, QSFP+, and QSFP28 transceivers for VOSS. The tables display only transceivers that are currently supported and available in the price book. Not all Avaya Ethernet switching and routing products support all the transceivers listed in this section.
Supported transceiver, BOCs, and DACs information Model Description Minimum software version Part number VSP 4000 VSP 7200 VSP 8200 VSP 8400 1000BASE-T SFP Gigabit Ethernet, RJ–45 connector 3.0.0.0 4.2.1 4.0.0 4.2.0 AA1419043–E6 1000BASE-SX DDI SFP 850 nm, Gigabit Ethernet, duplex LC connector 3.0.0.0 4.2.1 4.0.0 4.2.0 AA1419048–E6 1000BASE-LX DDI SFP 1310 nm, Gigabit Ethernet, duplex LC connector 3.0.0.0 4.2.1 4.0.0 4.2.
Supported transceivers Model Description Minimum software version Part number VSP 4000 VSP 7200 VSP 8200 VSP 8400 °C to +85 °C) SFP+ 10GBASEER/EW SFP+ 40 km, 1550 nm SMF 3.0.0.0 4.2.1 4.0.0 4.2.0 AA1403013–E6 10GBASEZR/ZW SFP+ 70 km, 1550 nm SMF 3.0.0.0 N/A * 4.0.0 4.2.0 AA1403016–E6 10GBASE-LRM SFP+ 220 m, 1260 to 1355 nm; 1310 nm nominal MMF 3.0.0.0 4.0.0 4.2.
Supported transceiver, BOCs, and DACs information Table 3: QSFP+ transceivers Model Description Minimum software version Part number VSP 4000 VSP 7200 VSP 8200 VSP 8400 40GBASE-SR4 100 meters with 4x10GBASE-SR OM3 fiber cable QSFP+ 150 meters with OM4 fiber cable N/A 4.2.1 4.0.0 4.2.0 AA1404005–E6 40GBASE-LR4 QSFP+ 10 km N/A 4.2.1 4.0.0 4.2.0 AA1404001–E6 40GBASE-ER4 QSFP+ 40 km N/A 4.2.1 4.2.1 4.2.1 AA1404003–E6 * See the following warning.
Supported DACs and BOCs Model Description Minimum software version VSP 4000 VSP 7200 Part number VSP 8200 VSP 8400 (8404C only) 100 m with OM4 multimode fiber cable 100GBASE-LR4 up to 10 km N/A N/A N/A 5.3 AA1405001–E6 Supported DACs and BOCs The following tables list the supported direct attach cables (DAC) and breakout cables (BOC) for VOSS. Supported DACs The following tables show the supported direct attach cables (DAC) for VOSS.
Supported transceiver, BOCs, and DACs information Cable type Cable length Minimum software version VSP 4000 Part number VSP 7200 VSP 8200 VSP 8400 10GBASE-CX SFP+ 2pair twinaxial copper cable that plugs into the SFP+ socket and connects two 10 Gigabit ports. SFP+ DAC 7 5.1.1.2 meter 5.1.1.2 5.1.1.2 5.1.1.2 AA1403022–E6 10GBASE-CX SFP+ 2pair twinaxial copper cable that plugs into the SFP+ socket and connects two 10 Gigabit ports SFP+ DAC 10 meter 3.0.0 4.2.1 4.0.0 4.2.
Supported DACs and BOCs Cable type Cable length Minimum software version VSP 4000 VSP 7200 VSP 8200 VSP 8400 Active optical DAC 10 meter N/A 4.2.1 4.2.1 4.2.1 Part number AA1404028–E6 Important: Not all Avaya products support all cable lengths. QSFP28 to QSFP28 100 Gigabit direct attach cable specifications The QSFP28 to QSFP28 100 Gigabit direct attach cable (DAC) assembly directly connects two QSFP28 ports. For more information, see IEEE 802.3–2012 cable assembly specification standard.
Supported transceiver, BOCs, and DACs information QSFP+ breakout cable specifications This section provides a list of the supported breakout cables (BOC). QSFP+ to 4xSFP+ 10 Gigabit BOC The QSFP+ to 4xSFP+ 10 Gigabit BOC assembly directly connects one QSFP+ port to four SFP+ ports. Note: The Avaya VSP 4000 does not support 40 Gbps QSFP+ transceivers because the VSP 4000 devices do not have any QSFP+ ports.
Supported DACs and BOCs Table 6: QSFP+ to 4xSFP+ 10 Gigabit BOC (passive) Cable type Cable length Minimum software version VSP 4000 Part number VSP 7200 VSP 8200 VSP 8400 Passive copper breakout cable QSFP+ to 4.2.1 SFP+ DAC BOC 1 meter 4.2.1 4.2.0 4.2.0 AA1404033–E6 Passive copper breakout cable QSFP+ to 4.2.1 SFP+ DAC BOC 3 meter 4.2.1 4.2.0 4.2.0 AA1404035–E6 Passive copper breakout cable QSFP+ to 4.2.1 SFP+ DAC BOC 5 meter 4.2.1 4.2.0 4.2.
Chapter 5: Optical routing design Optical routing design The Avaya optical routing system uses coarse wavelength division multiplexing (CWDM) in a grid of eight optical wavelengths. Use the Avaya optical routing system to maximize bandwidth on a single optical fiber. This chapter provides optical routing system information that you can use to help design your network.
Optical routing design The Avaya optical routing system supports both ring and point-to-point configurations. The optical routing system includes the following parts: • CWDM SFPs • Optical add/drop multiplexers (OADM) • Optical multiplexer/demultiplexers (OMUX) • Optical shelf to house the multiplexers OADMs drop or add a single wavelength from or to an optical fiber. For the list of supported optical devices for the current release, see Supported optical devices on page 25.
Optical routing design Quad (4-channel) Small Form Factor Pluggable 28 (QSFP28) QSFP28 transceivers are hot-swappable data input and output components that allow 100 Gigabit Ethernet ports to link with other 100 Gigabit Ethernet ports. All Avaya QSFP28 transceivers use LC connectors and MPO/MTP connectors to provide precision keying and low interface losses. Note: QSFP28 transceivers are currently supported on the VSP 8404C chassis model only.
Optical routing design minimum. Whether you require additional margin depends on the details, such as whether actual or specified transmitter power and receiver sensitivity are used. Avaya specifications represent worstcase values. The sum of margin, dispersion power penalty, and passive cable plant losses must be less than the available power budget.
Chapter 6: SFP This chapter provides installation procedures and specifications for Small Form Factor Pluggable (SFP) transceivers. SFP transceivers This section describes how to select and install Small Form Factor Pluggable (SFP) transceivers. Use an SFP transceiver for 1 Gigabit per second (Gbps) Ethernet connections. The Avaya VSP 8200 supports SFP transceivers on ports 1/1-1/40 and 2/1-2/40.
SFP transceivers negotiation enabled. If not, the link will not be established. Also note that because the SFP+ ports on the VSP 7254XSQ only support 1 and 10 Gbps speeds, the AA1419043-E6 1000BASE-T SFP will only operate at 1G speeds. Selecting an SFP Use an SFP transceiver to connect a device motherboard to a fiber optic or unshielded twisted pair network cable. Select the appropriate transceiver to provide the required reach. Procedure 1. Determine the required reach.
SFP Installing an SFP Install an SFP to provide an interface between the device and the network cable. Before you begin • Verify that the SFP is the correct model for your network configuration. • Before you install the fiber, ensure that the connector is clean. Danger: Risk of eye injury by laser Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables are connected to a light source.
SFP transceivers Job aid Depending on the transceiver manufacturer, the SFP transceiver can use different types of locking and extractor mechanisms. The following figure shows the typical mechanism used on SFP transceivers; other locking mechanisms exist although they are not shown here. In the following figure, the SFP transceiver uses the bore plug. Pull the bail to release the device. Removing an SFP Remove an SFP to replace it or to commission it elsewhere.
SFP Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables connect to a light source. Electrostatic alert: ESD can damage electronic circuits. Do not touch electronic hardware unless you wear a grounding wrist strap or other static-dissipating device. Procedure 1. Disconnect the network fiber optic cable from the SFP connector. 2.
SFP specifications SFP labels The Avaya label on a typical SFP transceiver contains an Avaya serial number, a bar code, a manufacturer code, an interface type, and a part number. Figure 4: SFP label General SFP specifications The following table describes general SFP specifications. Table 8: General SFP specifications Parameter Description Dimensions (H x W x D) 8.5 x 13.4 x 56.4 millimeters (0.33 x 0.53 x 2.22 inches), unless otherwise stated.
SFP Autonegotiation Use Autonegotiation to allow the device to automatically negotiate the best common data rate and duplex mode to use between two Autonegotiation-capable Ethernet devices. 1000BASE-T SFP specifications The 1000BASE-T SFP provides Gigabit Ethernet connectivity using a single eight-pin RJ-45 connector. The 1000BASE-T SFP only operates at 1 Gigabits per second (Gbps) speed. Operation at 100 or 10 Megabits per second (Mbps) speeds are not supported.
SFP specifications Parameter Specifications Receiver sensitivity –17 dBm Maximum receiver power 0 dBm 1000BASE-LX DDI SFP specifications This SFP transceiver provides 1000BASE-LX Gigabit Ethernet connectivity at 1310 nanometers (nm) using single mode or multimode optical fiber. The part number is AA1419049-E6. Table 11: 1000BASE-LX DDI SFP specifications Parameter Specifications Maximum electrical power consumption 1.
SFP The long wavelength optical transceivers used in these models provide variable distance ranges using single mode fiber optic cabling. You can use 1000BASE-BX SFP transceivers to double the number of your fiber links. For example, if you install 20 fiber pairs with 20 conventional ports connected, you can use 1000BASE-BX SFP transceivers to expand to 40 ports, using the same fiber. The following table provides the reach and part numbers for each mating pair.
SFP specifications Parameter Specification Maximum input power (maximum average receive power) –3.0 dBm 1000BASE-BX40 bidirectional SFP specifications The 1000BASE-BX40 SFP transceivers (part numbers AA1419076-E6 and AA1419077-E6) can attain a reach of up to 40 km. The minimum IL is 6 dB. The following table describes standards, connectors, cabling, and distances for the 1000BASEBX40 SFP transceiver.
SFP Parameter Specifications Connectors Duplex LC Cabling • 62.5 µm MMF optic cable • 50 µm MMF optic cable Distance • Up to 2 km using 500 MHz-km MMF optic cable Wavelength 1300 nm Link optical power budget 10 dB Transmitter characteristics Maximum launch power –14 dBm Minimum launch power –23.5 to –20 dBm Receiver characteristics Receiver sensitivity –33.
Chapter 7: SFP+ This chapter provides installation procedures and specifications for Small Form Factor Pluggable plus (SFP+) transceivers. SFP+ transceivers This section describes how to select and install Small Form Factor Pluggable plus (SFP+) transceivers. Use an SFP+ transceiver or direct attach cable for 10 Gigabit per second (Gbps) Ethernet connections. SFP+ transceivers are similar to SFP transceivers in physical appearance but SFP+ transceivers support 10 Gbps connections.
SFP+ basic displays the corresponding vendor names instead of leaving the vendor name blank as in the releases prior to VOSS 4.2.1. • Avaya recommends the use of Avaya branded SFP and SFP+ transceivers as they have been through extensive qualification and testing. Avaya will not be responsible for issues related to non-Avaya branded SFP and SFP+ transceivers. Selecting an SFP+ Use an SFP+ transceiver for 10 Gigabit per second (Gbps) Ethernet connections over optical fiber.
SFP+ transceivers Before you begin Important: Do not install an SFP+ transceiver in an SFP slot. The two transceivers look the same but function differently. Ensure the slot is an SFP+ slot. • Verify that the SFP+ transceiver is the correct model for your network configuration. • Before you install the fiber, ensure that the connector is clean. Danger: Risk of eye injury by laser Fiber optic equipment can emit laser or infrared light that can injure your eyes.
SFP+ Example Job aid Depending on the transceiver manufacturer, the SFP+ transceiver uses bail-latch type of locking and extractor mechanism. The following figure shows typical mechanism used on SFP+ transceivers; other locking and extractor mechanisms exist. SFP+ transceivers are similar to SFP transceivers in physical appearance. In the following figure, the SFP+ transceiver still contains the bore plug. Pull the bail to release the device.
SFP+ specifications Danger: Risk of eye injury by laser Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables connect to a light source. Electrostatic alert: ESD can damage electronic circuits. Do not touch electronic hardware unless you wear a grounding wrist strap or other static-dissipating device. Procedure 1. Disconnect the network fiber optic cable from the SFP+ connector. 2.
SFP+ • Avaya recommends the use of Avaya branded SFP and SFP+ transceivers as they have been through extensive qualification and testing. Avaya will not be responsible for issues related to non-Avaya branded SFP and SFP+ transceivers. SFP+ labels The typical Avaya SFP+ transceiver has a label on the top and bottom or side of the transceiver. The following figures show example labels. Avaya does use alternate labels, depending on the size of the device and space available for label information.
SFP+ specifications Parameter Specifications Storage temperature –40 to 85 ºC Operating temperature 0 to 70 ºC for RoHS -E6 models up to 85 ºC for high temperature models Supported SFP+ transceivers The following section provides specifications for the supported SFP+ transceivers. 10GBASE-T SFP+ transceiver The 10GBASE-T SFP+ transceiver provides 10 Gigabit Ethernet connectivity using a single eight pin RJ-45 connector. The 10GBASE-T SFP+ only operates at 10 Gigabits per second (Gbps) speed.
SFP+ Parameter Specifications Maximum transmitter and dispersion penalty 3.2 dB at 10 km Transmitter characteristics Line rate (nominal 10GBASE-LR 10.3125 Gbps ±100 ppm (10 GbE) Average launch power –8.2 to 0.5 dBm Minimum launch power in OMA minus transmission and dispersion penalty (TDP) –6.2 dBm Minimum optical modulation amplitude –5.2 dBm Minimum extinction ratio 3.
SFP+ specifications Parameter Specifications Transmitter characteristics Line rate (nominal) 10GBASE-LR 10.3125 Gbps ±100 ppm (10 GbE) Average launch power –8.2 to 0.5 dBm Minimum launch power in OMA minus transmission and dispersion penalty (TDP) –6.2 dBm Minimum optical modulation amplitude –5.2 dBm Minimum extinction ratio 3.5 dB Maximum optical return loss tolerance –12 dB Maximum transmitter reflectance –12 dB Receiver characteristics Line rate (nominal) 10GBASE-LR 10.
SFP+ Parameter Specifications Minimum side mode suppression ratio 30 dB Minimum launch power in OMA minus transmission and dispersion penalty (TDP) –2.1 dBm Minimum optical modulation amplitude –1.7 dBm Maximum average launch power of OFF transmitter –30 dBm Minimum extinction ratio 3.0 dB Maximum RIN12OMA –128 dB/Hz Maximum optical return loss tolerance –21 dB Receiver characteristics Average receive power for BER 10-12 – 15.8 dBm to –1.0 dBm Maximum receive power for damage 4.
SFP+ specifications Parameter Specifications Line rate (64B/66B code) 10.3125 Gbps ± 100 parts per million (ppm) Center wavelength range 840 to 860 nanometers (nm), nominal 850 nm Distance Using 62.5 µm MMF optic cable: • 160 MHz-km fiber: 2 to 26 m • 200 MHz-km fiber: 2 to 33 m Using 50 µm MMF optic cable: • 400 MHz-km fiber: 2 to 66 m • 500 MHz-km fiber: 2 to 82 m • 2000 MHz-km fiber: 2 to 300 m • 4700 MHz-km fiber (OM4): 2 to 400 m Link optical power budget 7.
SFP+ Table 22: IEEE 802.3ae 10GBase–SR/SW SFP+ (0 °C to +85 °C) transceiver specifications Parameter Specifications Data rate 10 Gigabits per second (Gbps) Line rate (64B/66B code) 10.3125 Gbps ± 100 parts per million (ppm) Center wavelength range 840 to 860 nanometers (nm), nominal 850 nm Distance Using 62.
SFP+ specifications Warning: Risk of BER increase For proper SFP+ transceiver operation, ensure that at least 11 dB of attenuation is present between the transmit and receive ports. The reach for this SFP+ transceiver is up to 70 km* at a wavelength of 1550 nm. Table 23: 10GBASE-ZR/ZW SFP+ specifications Parameter Specifications Line rate (nominal) 10GBASE-ZR 10.3125 Gbps ±100 ppm (10 GbE) Distance Up to 70 km * Link optical power budget 24 dB Dispersion power penalty 3.0 dB at 70 km (G.
SFP+ Table 24: 10GBASE-CX cables Cable length Part number 3 meter AA1403019-E6 5 meter AA1403020-E6 7 meter AA1403022-E6 10 meter AA1403018-E6 15 meter AA1403021-E6 10GBASE CWDM DDI SFP+ (40 km) specifications The following table lists the part numbers of the 10GBASE CWDM DDI SFP+ (40 km) with corresponding wavelengths.
SFP+ specifications Parameter Specifications Receiver characteristics: Wavelength (requirement) 1450 nm to 1620 nm Receiver sensitivity (unstressed), OMA –14.1 dBm, P_OMA IEEE 10GBASE-ER Stressed Rx Sensitivity –11.3 dBm, P_OMA Receiver overload –1 dBm, P_avg Receiver reflectance –26 dB Receiver damage threshold +4 dBm 10GBASE-LRM SFP+ specifications The 10GBASE-LRM SFP+ transceiver provides 10 GbE service at a wavelength of 1310 nm.
SFP+ Parameter Specifications Minimum extinction ratio 3.5 dB Optical return loss tolerance (minimum) –20 dB Receiver characteristics Receiver damage threshold 1.5 dBm Receiver reflectance (maximum) –12 dB For more information about the conditions used for the stressed receiver tests, and other information, see the IEEE 802.3–2012 standard. The following table (from IEEE 802.3–2012) describes the maximum channel insertion loss.
SFP+ specifications 10GBASE CWDM DDI SFP+ (70 km) specifications The following table lists the part numbers for the 10GBASE CWDM DDI SFP+ (70 km) transceivers with corresponding wavelengths. The reach for this SFP+ transceiver is up to 70 km* at a wavelength of 1551 nm.
SFP+ Parameter Specifications Rx sensitivity: Min Max Units back-to-back — –23 dBm with 70 km fiber — –21 dBm –19.3 dBm with 70 km fiber, OMA — Receiver overload –7 dBm, P_avg Receiver reflectance –27 dB Receiver damage threshold +5 dBm, P_avg 10GBASE-BX SFP+ specifications The 10GBASE-BX SFP+ provides 10 Gigabit Ethernet (GbE) service with single mode bidirectional transceivers.
SFP+ specifications Parameter Specifications Average receive power –14.4 to +0.5 dBm Maximum receiver sensitivity in OMA –12.6 dBm Maximum receiver reflectance –12 dB Stressed receiver sensitivity in OMA –10.3 dBm May 2017 Installing Transceivers and Optical Components on VOSS Comments on this document? infodev@avaya.
Chapter 8: QSFP+ This chapter provides installation procedures and specifications for 40 Gigabit Ethernet Quad Small Form Factor Pluggable plus (QSFP+) transceiver modules. QSFP+ transceivers This section describes how to select, install, and remove Quad (4-channel) Small Form Factor Pluggable plus (QSFP+) transceiver modules. Use a QSFP+ transceiver or breakout cable for 40 Gigabit per second (Gbps) Ethernet connections.
QSFP+ transceivers modules basic displays the corresponding vendor names instead of leaving the vendor name blank as in the releases prior to VOSS 4.2.1. • Avaya recommends the use of Avaya branded QSFP+ transceivers as they have been through extensive qualification and testing. Avaya will not be responsible for issues related to non-Avaya branded QSFP+ transceivers. Selecting a QSFP+ Use a QSFP+ transceiver for 40 Gigabit per second (Gbps) Ethernet connections over optical fiber.
QSFP+ Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables connect to a light source. Electrostatic alert: Risk of equipment damage ESD can damage electronic circuits. Do not touch electronic hardware unless you wear a grounding wrist strap or other static-dissipating device. Warning: Risk of equipment damage Only trained personnel can install this product.
QSFP+ transceiver specifications Removing a QSFP+ transceiver Remove a QSFP+ transceiver to replace it or to commission it elsewhere. Before you begin Danger: Risk of eye injury by laser Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables connect to a light source.
QSFP+ QSFP+ transceiver labels A label can be located on either the top or bottom of the typical Avaya QSFP+ transceiver. The following figure shows an example label. Avaya uses alternate labels, depending on the size of the device and space available for label information. Figure 7: 40GBASE–SR4 QSFP+ transceiver label example The following table identifies the numbered items in the preceding figure. Table 31: Figure notes for a 40GBASE–SR4 QSFP+ transceiver label 1. Avaya logo 2.
QSFP+ transceiver specifications Table 32: General QSFP+ specifications Parameter Specification Dimensions (H x W x D) 8.5 x 18.35 x 72.4 mm (0.33 x 0.72 x 2.85 in.), unless otherwise stated. Note: The length of the pull tab latch varies depending on the vendor and the body, with a length of 125 to 132 mm (4.92 to 5.20 in.).
QSFP+ Parameter Specification Distance Up to: • 328 feet (100 meters) – with OM3 fiber cable. • 492 feet (150 meters) – with OM4 fiber cable. Transmitter characteristics Signaling rate, each lane 10.3125 Gbps RMS spectral width 0.65 nanometers maximum Average launch power, each lane Optical modulation amplitude (OMA), each lane Min Max Units –8.0 –1.0 dBm Min Max Units –5.6 3 dBm Maximum transmitter and dispersion penalty (TDP), each lane 3.
QSFP+ transceiver specifications Table 34: 40GBASE-SR4 4x10GBASE-SR extended reach specifications Parameter Specification Line rate 10.3125 Gbps Center wavelength range 840 to 860 nanometers Distance Up to: • up to 984 feet (300 meters) – with OM3 fiber cable. • up to 1312 feet (400 meters) – with OM4 fiber cable. Transmitter characteristics Signaling rate, each lane 10.3125 Gbps RMS spectral width 0.
QSFP+ For more information about the 40GBASE-LR4 transceiver, including test and measurement information, see the IEEE 802.3–2012 standard. Table 35: IEEE 802.3–2012 40GBASE-LR4 transceiver specifications Parameter Specification Distance Up to 10 kilometers Transmitter characteristics Line rate 10 Gbps Signaling rate, each lane 10GBase 10.3125 Gbps Data rate, total 40GBase 41.25 Gbps Lane wavelength ranges 1264.5 nanometers to 1277.5 nanometers 1284.5 nanometers to 1297.5 nanometers 1304.
QSFP+ transceiver specifications Parameter Specification Maximum receiver sensitivity in OMA, each lane at 10.3125 Gbps. –11.5 dBm Maximum receiver reflectance –26 dBm Stressed receiver sensitivity, each lane at 10.3125 Gbps. –9.6 dBm Receive input optical power (damage threshold per lane) 3.3 dBm 40GBASE-LM4 QSFP+ specifications This transceiver operates up to 80 meters on 50 µm MMF cable plant and is compliant with channel insertion loss specified in IEEE standard 802.
QSFP+ Parameter Specification Applicable cable plant Maximum insertion loss, including connectors 2.6 dB (OM3) or 2.9 dB (OM4) Minimum optical return loss 20 dB Maximum link distance 80 m Receiver characteristics Maximum average receive power, each lane 4.3 dBm Maximum input optical power Tolerates direct Tx to Rx connection Stressed receiver sensitivity –5.
QSFP+ transceiver specifications Maximum average optical power of OFF transmitter, each lane –30 dBm Launch power in OMA minus TDP, each lane, (min.) –0.5 dBm Minimum extinction ratio at 10.3125 Gbps 5.5 dB RIN20OMA (maximum) –128 dB/Hz Maximum optical return loss tolerance 20 dB Receiver characteristics Line rate 10 Gbps Signaling rate, each lane 10GBASE 10.3125 Gbps Damage threshold per lane (min.) 3.8 dBm Lane wavelength ranges 1264.5 nanometers to 1277.5 nanometers 1284.
QSFP+ Interoperation 40GBASE-ER4 and 40GBASE-LR4 QSFP+ transceivers can interoperate with a properlyengineered link. It requires the cabling (channel) characteristics for 40GBASE-LR4 to be met, with the exception of the maximum and minimum channel insertion loss values, as shown in the following table, for the two link directions separately. Direction Min. loss Max. loss Unit 40GBASE-LR4 transmitter to 40GBASEER4 receiver 7.5 14.2 dB 40GBASE-ER4 transmitter to 40GBASELR4 receiver 2.
Chapter 9: QSFP28 This chapter provides installation procedures and specifications for 100 Gigabit Ethernet Quad Small Form Factor Pluggable 28 (QSFP28) transceiver modules. QSFP28 transceivers This section describes how to select, install, and remove Quad (4-channel) Small Form Factor Pluggable 28 (QSFP28) transceiver modules. Use a QSFP28 transceiver for 100 Gigabit per second (Gbps) Ethernet connections over optical fiber.
QSFP28 Selecting a QSFP28 Use a QSFP28 transceiver to interface a port to a fiber optic cable. Depending on the product, you can obtain transceivers for cable distances of up to 10 km (for LR4 transceivers). QSFP28 to QSFP28 100 Gigabit passive copper direct attach cables (DAC) have a reach of up to 5 meters. QSFP28 to QSFP28 100 Gigabit active optical cables have a reach of 10 meters. About this task Select the appropriate transceiver to provide the required reach. Procedure 1.
QSFP28 transceivers Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables are connected to a light source. Electrostatic alert: ESD can damage electronic circuits. Do not touch electronic hardware unless you wear a grounding wrist strap or other static-dissipating device. Warning: Risk of equipment damage Transceivers are keyed to prevent incorrect insertion.
QSFP28 Removing a QSFP28 transceiver Remove a QSFP 28 transceiver to replace it or to commission it elsewhere. Before you begin Danger: Risk of eye injury by laser Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into an optical fiber or connector port. Always assume that fiber optic cables are connected to a light source. Electrostatic alert: ESD can damage electronic circuits.
QSFP28 transceiver specifications QSFP28 transceiver labels A label can be located on either the top or bottom of the typical Avaya QSFP28 transceiver. The following figure shows an example label. Avaya uses alternate labels, depending on the size of the device and space available for label information. Figure 8: 100GBASE–SR4 QSFP28 transceiver label example The following table identifies the numbered items in the preceding figure. Table 38: Figure notes for a 100GBASE–SR4 QSFP28 transceiver label 1.
QSFP28 Table 39: General QSFP28 specifications Parameter Specification Dimensions (H x W x D) 8.5 x 18.35 x 72.4 mm (0.33 x 0.72 x 2.85 in.), unless otherwise stated. Note: The length of the pull tab latch varies depending on the vendor and the body, with a length of 125 to 132 mm (4.92 to 5.20 in.).
QSFP28 transceiver specifications Parameter Specification Transmitter and dispersion eye closure (TDEC), each lane (max) 4.3 dB Minimum launch power in OMA minus TDEC (min) –7.3 dBm Extinction ratio (min) 2 dB Optical return loss tolerance (max) 12 dB Receiver characteristics Signaling rate, each lane 25.78125 Gbps Average receive power, each lane –10.3 to 2.4 dBm Receive power in OMA, each lane (max) 3 dBm Receive input optical power (damage threshold per lane) 3.
QSFP28 Parameter Specification Optical Modulation Amplitude (OMA), each lane (min) –1.3 dBm Optical Modulation Amplitude (OMA), each lane (max) 4.5 dBm Average launch power of OFF transmitter, each lane (max) –30 dBm Extinction ratio (min) 4 dB RIN20OMA (max) –130 dB/Hz Optical return loss tolerance (max) 20 dB Receiver characteristics Line rate 100 Gbps Signaling rate, each lane 25.78125 Gbps Data rate 103.125 Gbps Lane wavelength (range) 1294.53 to 1296.59 nanometers 1299.02 to 1301.
Chapter 10: End of sale transceivers and cables This section contains a complete list of transceivers, BOCs, and DACs that have reached End of Sale. This list applies to all products. For more information about EOS transceivers and recommended replacements for your product or to determine existing availability for these transceivers, see Locating end of sale notices on page 79.
End of sale transceivers and cables Model Part number Date EOS Replacement 1000BASE-XD CWDM AA1419025-E5 to AA1419032-E5 June 30, 2012 1000BASE-ZX CWDM AA1419033-E5 to AA1419040-E5 June 30, 2012 — 1000BASE-XD DDI 1330 nm AA1419050-E6 September 30, 2014 — 1000BASE-XD DDI 1550 nm AA1419051-E6 September 30, 2014 AA1419057-E6 1000BASE-ZX DDI 1550 nm AA1419052-E6 September 30, 2014 AA1419065-E6 1000BASE- XD DDI 40 km AA1419053-E6 to AA1419060-E6 December 14, 2016 — 1000BASE-ZX DDI CWD
End of Sale DACs Model Part number Date EOS Replacement QSFP+ to QSFP+ DAC CABLE AA1403028-E6 June 2015 AA1404028-E6 AA1404030-E6 August 2016 — 10 meter (ACTIVE COPPER) QSFP+ to QSFP+ DAC CABLE 2 meter (PASSIVE COPPER) May 2017 Installing Transceivers and Optical Components on VOSS Comments on this document? infodev@avaya.
Chapter 11: Translations of safety messages Class A electromagnetic interference warning statement Warning: Risk of electromagnetic interference This device is a Class A product. Operation of this equipment in a residential area is likely to cause harmful interference, in which case users are required to take appropriate measures necessary to correct the interference at their own expense. Warning: AVERTISSEMENT Le périphérique est un produit de Classe A.
Electrostatic discharge warning statement Este dispositivo é um produto Classe A. Operar este equipamento em uma área residencial provavelmente causará interferência prejudicial; neste caso, espera-se que os usuários tomem as medidas necessárias para corrigir a interferência por sua própria conta. Warning: AVVISO Questo dispositivo è un prodotto di Classe A.
Translations of safety messages Electrostatic alert: AVVISO ELETTROSTATICO Le scariche elettrostatiche (ESD) possono danneggiare i circuiti elettronici. Non toccare i componenti elettronici senza aver prima indossato un braccialetto antistatico o un altro dispositivo in grado di dissipare l'energia statica. Laser eye safety danger statement Danger: Risk of eye injury by laser Fiber optic equipment can emit laser or infrared light that can injure your eyes.
Laser eye safety connector inspection danger statement O laser pode causar ferimentos no olho O equipamento de fibra ótica pode emitir laser ou luz infravermelha que pode causar danos a sua vista. Nunca olhe para dentro da fibra ótica ou da porta do conector. Tenha sempre em mente que os cabos de fibra ótica estão ligados a uma fonte de luz.
Translations of safety messages Danger: PERIGO Risco de ferimento nos olhos Ao inspecionar um conector, verifique se as fontes luminosas estão desligadas. A fonte luminosa usada nos cabos de fibra ótica pode causar danos a seus olhos. Danger: PERICOLO Rischio di lesioni agli occhi Quando si esamina un connettore, assicurarsi che le sorgenti di luce siano spente. La sorgente di luce utilizzata nei cavi a fibre ottiche potrebbero danneggiare gli occhi.
Optical fiber damage warning statement arbeiten. Zum Schutz vor Augenirritationen tragen Sie eine Schutzbrille, wenn Sie mit Isopropanol arbeiten. Danger: PELIGRO Riesgo de lesiones Cuando inspeccione un conector, controle que las fuentes de luz estén apagadas. La fuente de luz que utilizan los cables de fibra óptica puede ocasionar daños en la vista. Cuando trabaje con el pulverizador de aire envasado, utilice gafas de seguridad para evitar el ingreso de residuos en los ojos.
Translations of safety messages Warning: AVERTISSEMENT Risques d'endommagement de l'équipement N'exercez pas de pression sur les câbles de fibres optiques. Ne placez pas de câbles de fibres optiques dans la même caisse ou dans le même fourreau que des câbles électriques lourds car leur poids risquerait de les endommager. Warning: WARNUNG Risiko von Geräteschäden Das Glasfaserkabel darf nicht zerdrückt werden.
Optical fiber connector damage warning statement To prevent further contamination, clean fiber optic equipment only when you see evidence of contamination. To prevent contamination, cover the optical ports of all active devices with a dust cap or optical connector. To avoid the transfer of oil or other contaminants from your fingers to the end face of the ferrule, handle connectors with care.
Translations of safety messages Warning: AVISO Risco de danos ao equipamento Para evitar contaminação futura, limpe o equipamento ótico apenas quando houver evidência de contaminação. Para evitar a contaminação, verifique se as portas óticas de todos os dispositivos ativos estão cobertas com uma proteção contra pó ou conector ótico. Para evitar a transferência de óleo ou outro agente contaminador de seus dedos para a extremidade final da ponteira, manuseie os conectores com cuidado.
SFP damage warning statement Die SFPs sind so konstruiert, dass ein falsches Einsetzen verhindert wird. Lässt sich ein SFP auch auf Druck hin nicht einsetzen, versuchen Sie nicht, es gewaltsam einzusetzen, sondern drehen Sie es um, und setzen Sie es erneut ein. Warning: ADVERTENCIA Riesgo de daños en los equipos Los módulos SFP cuentan con cuñas que no permiten insertarlos de forma incorrecta. Si el módulo SFP opone resistencia a la presión, no lo fuerce; gírelo e insértelo nuevamente.
Chapter 12: Resources Support Go to the Avaya Support website at http://support.avaya.com for the most up-to-date documentation, product notices, and knowledge articles. You can also search for release notes, downloads, and resolutions to issues. Use the online service request system to create a service request. Chat with live agents to get answers to questions, or request an agent to connect you to a support team if an issue requires additional expertise.
Searching a documentation collection About this task Videos are available on the Avaya Support website, listed under the video document type, and on the Avaya-run channel on YouTube. Procedure • To find videos on the Avaya Support website, go to http://support.avaya.com and perform one of the following actions: - In Search, type Avaya Mentor Videos to see a list of the available videos. - In Search, type the product name. On the Search Results page, select Video in the Content Type column on the left.
Resources • Case-Sensitive • Include Bookmarks • Include Comments 6. Click Search. The search results show the number of documents and instances found. You can sort the search results by Relevance Ranking, Date Modified, Filename, or Location. The default is Relevance Ranking. Subscribing to e-notifications Subscribe to e-notifications to receive an email notification when documents are added to or changed on the Avaya Support website.
Subscribing to e-notifications 6. Click OK. 7. In the PRODUCT NOTIFICATIONS area, click Add More Products. 8. Scroll through the list, and then select the product name. 9. Select a release version. 10. Select the check box next to the required documentation types. May 2017 Installing Transceivers and Optical Components on VOSS Comments on this document? infodev@avaya.
Resources 11. Click Submit. May 2017 Installing Transceivers and Optical Components on VOSS Comments on this document? infodev@avaya.
Glossary attenuation The decrease in signal strength in an optical fiber caused by absorption and scattering. Avaya command line interface (ACLI) A textual user interface. When you use ACLI, you respond to a prompt by typing a command. After you enter the command, you receive a system response. bit error rate (BER) The ratio of the number of bit errors to the total number of bits transmitted in a specific time interval.
Glossary media A substance that transmits data between ports; usually fiber optic cables or category 5 unshielded twisted pair (UTP) copper wires. metropolitan area network (MAN) A broadband network that covers an area larger than a Local Area Network. multimode fiber (MMF) A fiber with a core diameter larger than the wavelength of light transmitted that you can use to propagate many modes of light. Commonly used with LED sources for low speed and short distance lengths.
