Fiber Optics - Transmitters

Fiber Optics - Transmitters - Discrete

Part Number	Description / PDF	Quantity
AFBR-1539Z Broadcom	IC TXRX FIBER OPTIC	1730
AFBR-1529Z Broadcom	TX FIBER OPTIC DC-50MBD	348
SP000063802 Broadcom	TRANSMITTER DIODE FIBER OPTIC	0
HFBR-1415TZ Broadcom	XMITTER MINI HP FIB OPT ST PORT	0
AFBR-1541CZ Broadcom	TIL. 5MBAUD TX ROHS +95C	634
HFBR-1541ETZ Broadcom	TX OPT HIGH PERFORMANCE 5MBD	777
HFBR-1531ETZ Broadcom	TX OPT HIGH PERFORMANCE 5MBD	1012
HFBR-1533Z Broadcom	XMITTER FIBER OPTIC VERT 40KBD	0
HFBR-1402Z Broadcom	XMITTER FIBER OPTIC STD PWR SMA	252
HFBR-1414PTZ Broadcom	XMITTER FIBER OPTIC	411
HFBR-1412TMZ Broadcom	XMITTER FIBER OPTIC STD PWR ST	2779
HFBR-1424Z Broadcom	XMITTER MINI HP FIB OPT FC PORT	323
HFBR-1527Z Broadcom	FIBER OPTIC TX 125 MBD 650N	1623
AFBR-1521CZ Broadcom	FIBER OPTIC TX 5 MBD 650NM	5082
HFBR-1505AZ Broadcom	XMITTER FIBER OPTIC SMA SERCOS	400
HFBR-1412Z Broadcom	XMITTER FIBER OPTIC STD PWR ST	1048
HFBR-2532ETZ Broadcom	XMITTER FIBER OPTIC	337
AFBR-1644Z Broadcom	TRANSMITTER	509
HFBR-1415Z Broadcom	XMITTER MINI HP FIB OPT ST PORT	0
HFBR-1522ETZ Broadcom	FIBER OPTIC TRANSMITTER 660NM	304

Fiber Optics - Transmitters - Discrete

1. Overview

Discrete fiber optic transmitters are optoelectronic devices that convert electrical signals into optical signals through individual component packages. They serve as fundamental building blocks in fiber communication systems, enabling data transmission via modulated light waves. These transmitters play critical roles in telecommunications, data centers, and sensing applications due to their high bandwidth efficiency and electromagnetic interference immunity.

2. Major Types & Functional Classification

Type	Functional Characteristics	Application Examples
LED Transmitters	Low-cost, low-power, broad spectral width	Short-distance links ( 2km), premises networks
Laser Diodes (LD)	High power, narrow linewidth, high speed	Long-haul telecom, CATV systems
VCSELs	Low divergence beam, low power consumption	Data center interconnects (100G-400G)
Electro-absorption Modulated Lasers (EML)	Integrated modulation, low chirp	High-speed DWDM systems ( 100Gbps)

3. Structure & Components

Typical discrete transmitters consist of: (1) Light source (LED/LD/VCSEL chip), (2) Optical sub-assembly (OSA) with lens/filter, (3) Electrical interface (bonding wires/PCB), (4) Hermetic package (TO-can or surface-mount). Advanced designs integrate drivers/modulators in photonic integrated circuits (PICs).

4. Key Technical Specifications

Parameter	Significance
Wavelength (1270-1610nm)	Determines fiber transmission window and dispersion characteristics
Output Power (-20 to +20dBm)	Affects transmission distance and signal-to-noise ratio
Modulation Bandwidth (DC-67GHz)	Limits maximum data rate capability
Chirp Characteristics	Impacts dispersion penalty in high-speed systems
Operating Temperature (-40 to +85 C)	Determines environmental deployment flexibility

5. Application Domains

Primary industries include: Telecommunications (DWDM networks), Data Centers (QSFP modules), Cable TV (HFC networks), Industrial Sensing (strain/temperature monitoring). Typical equipment: Optical line terminals (OLTs), active optical cables (AOCs), OTDR test instruments.

6. Leading Manufacturers & Products

Vendor	Representative Product
II-VI Incorporated	100G CFP EML transmitter
Lumentum	Multi-junction VCSEL arrays
Finisar (II-VI)	TO-Can DFB lasers
Broadcom	Integrated TOSA assemblies
NeoPhotonics	High-power narrow-linewidth lasers

7. Selection Guidelines

Key considerations: (1) Match wavelength to system requirements (O-band/C-band), (2) Verify output power vs. link budget needs, (3) Ensure modulation bandwidth exceeds data rate requirements, (4) Evaluate thermal stability for operating environments, (5) Consider packaging form factor (TO/ROSA vs. SMT), (6) Balance cost/performance for volume deployments.

8. Industry Trends

Current development directions include: (1) 400G+ transmission through advanced modulation formats, (2) Silicon photonics integration for cost reduction, (3) Shortwave infrared (SWIR) sources for emerging applications, (4) AI-driven digital signal processing co-design, (5) Environmental compliance with RoHS/Green Photonics initiatives. Market growth in 5G fronthaul and automotive LiDAR applications is driving innovation in compact, low-power transmitters.