Fiber Optics - Transceiver Modules

Image	Part Number	Description / PDF	Quantity	Rfq
	FTLX3813M333 Finisar Corporation	TXRX DWDM EML 100GHZ APD XFP	0
	FWLF-1519-7D-39 Finisar Corporation	TXRX CWDM SFP	0
	FTLX3813M347 Finisar Corporation	TXRX DWDM EML 100GHZ APD XFP	0
	FTL-1621-53 Finisar Corporation	TXRX GBIC CWDM APD 1530NM GREEN	0
	FWLF1631R50 Finisar Corporation	TXRX DWDM SFP 195.0THZ APD RCVR	0
	FWLF1632R43 Finisar Corporation	MOD TXRX 15XXNM 45CH DWDM SFP	0
	FTLX3613M315 Finisar Corporation	TXRX DWDM EML 100GHZ C-BAND XFP	0
	FWLF1631R44 Finisar Corporation	TXRX DWDM SFP 194.4THZ APD RCVR	0
	FWLF-1631-27 Finisar Corporation	TXRX DWDM SFP	0
	FWLF-1631-54 Finisar Corporation	TXRX DWDM SFP	0
	FTLX8570D3BCL Finisar Corporation	TXRX 850NM VCSEL PIN 10G SFP+	0
	FWLF1632R44 Finisar Corporation	MOD TXRX 15XXNM 45CH DWDM SFP	0
	FWLF1632R53 Finisar Corporation	MOD TXRX 15XXNM 45CH DWDM SFP	0
	FTLX3613M324 Finisar Corporation	TXRX DWDM EML 100GHZ C-BAND XFP	0
	FWLF1631R57 Finisar Corporation	TXRX DWDM SFP 195.7THZ APD RCVR	0
	FTLX3813M329 Finisar Corporation	TXRX DWDM EML 100GHZ APD XFP	0
	FWLF1631R58 Finisar Corporation	TXRX DWDM SFP 195.8THZ APD RCVR	0
	FTLX0071D4BNL Finisar Corporation	LASERWIRE TXRX SFP+ ADAPTER FEM	0
	FTLX3613M347 Finisar Corporation	TXRX DWDM EML 100GHZ C-BAND XFP	0
	FTLX3813M356 Finisar Corporation	TXRX DWDM EML 100GHZ APD XFP	0

Fiber Optics - Transceiver Modules

1. Overview

Fiber optic transceiver modules are compact devices that integrate optical transmitters and receivers to enable bidirectional data transmission over fiber optic cables. These modules convert electrical signals to optical signals (and vice versa) using laser diodes and photodetectors. They play a critical role in modern high-speed communication systems, supporting applications ranging from telecommunications to data center infrastructure. Their miniaturized design and standardized interfaces (e.g., SFP, QSFP) have revolutionized scalable network architecture deployment.

2. Main Types and Functional Classification

Type	Transmission Rate	Wavelength	Transmission Distance	Application Example
SFP	100Mbps-1Gbps	850nm(MMF)/1310nm(SMF)	550m-2km	Enterprise LAN switches
SFP+	1-10Gbps	1270-1330nm	100m-120km	10GbE data centers
QSFP	40Gbps	1270-1330nm	2km-2km	High-performance computing clusters
CFP	100Gbps-400Gbps	1270-1330nm	500m-120km	Long-haul optical transport
QSFP28	100Gbps	1270-1330nm	100m-2km	Cloud data center backbone

3. Structure and Components

A typical transceiver module consists of:

Optical sub-assembly (OSA) with TOSA (Transmitter Optical Sub-Assembly) and ROSA (Receiver Optical Sub-Assembly)
Electrical interface (e.g., LC, MPO connectors)
Digital diagnostic monitoring (DDM) circuitry
Thermal management components
Compliance with industry standards (IEEE 802.3, SFF-8431)

The housing provides EMI shielding and mechanical protection while maintaining hot-pluggable functionality.

4. Key Technical Specifications

Parameter	Description	Importance
Transmission Rate	Data throughput capacity (Gbps)	Determines network bandwidth
Optical Wavelength	Operating frequency (nm)	Matches fiber type and multiplexing scheme
Receiver Sensitivity	Minimum detectable optical power (dBm)	Impacts link budget and distance
Power Consumption	Operational energy usage (W)	Affects cooling requirements and costs
Operating Temperature	Functional range (-40 C to +85 C)	Determines environmental suitability

5. Application Fields

Key industries include:

Telecommunications (5G networks, metro access)
Data centers (switch interconnects, storage area networks)
Industrial automation (real-time sensor networks)
Medical imaging (high-resolution video transmission)
Aerospace (avionics data links)

Typical equipment: Cisco Catalyst switches, Huawei OptiX routers, InfiniBand HCAs.

6. Leading Manufacturers and Products

Manufacturer	Product Line	Key Features
Finisar	CFP2-100G-LR4	100Gbps, 2km reach, low power
Sumitomo Electric	QSFP-100G-ER4	40km transmission, DWDM support
Source Photonics	SFP28-25G-LR	25Gbps, 2km, CPRI applications
Lumentum	QSFP28-ZR	100Gbps, 80km, coherent optics

7. Selection Recommendations

Key considerations:

Match data rate requirements with protocol standards (Ethernet, Fibre Channel)
Evaluate fiber type compatibility (MMF/SMF) and connector types
Assess power budget and thermal management needs
Consider digital diagnostics for network monitoring
Verify compliance with industry standards
Plan for future scalability (e.g., 400G readiness)

Case study: Deploying QSFP28-100G-SR4 modules in a hyperscale data center achieved 50% lower latency compared to 40G solutions.

8. Industry Trends

Emerging developments:

Transition to 400G/800G modules using 100G per lane electrical interfaces
Adoption of silicon photonics for cost reduction
Integration of PAM4 modulation for higher spectral efficiency
Embedded optics in switch ASICs for reduced latency
Co-packaged optics for advanced thermal management
Increased focus on energy efficiency ( 2W per 100G lane)

Market forecasts predict a CAGR of 12.3% from 2023-2030, driven by AI/ML infrastructure demands.