Fiber Optics - Transmitters - Discrete

Mfr Part #	Quantity Available	UnitPrice	Packaging	Product Status	Wavelength	Spectral Bandwidth	Voltage - Forward (Vf) (Typ)	Current - DC Forward (If) (Max)	Voltage - DC Reverse (Vr) (Max)	Capacitance	Connector Type
HFBR-1521Z XMITTER FIBER OPTIC 600NM 5MBD Broadcom Limited	21	$14.60	Tube	Active	660nm	-	2.02V	80 mA	5 V	86 pF	Versatile Link
HFBR-1414TZ XMITTER FIBER OPTIC HIGH PWR ST Broadcom Limited	12	$27.03	Bulk	Active	820nm	-	1.7V	100 mA	1.8 V	55 pF	ST
HFBR-1528Z XMITTER FIBER OPTIC 600NM 10MBD Broadcom Limited	43	$18.81	Bulk	Active	600nm	-	2.02V	80 mA	5 V	-	Versatile Link

What are Transmitters - Discrete?

Transmitters - Discrete

Transmitters - Discrete are essential components in the fiber optics industry, responsible for converting electrical signals into optical signals for transmission through fiber optic cables. These devices operate by modulating a light source, typically a laser diode or light-emitting diode (LED), to encode data onto a light beam. The light is then transmitted through optical fibers to a receiver, where it is converted back into an electrical signal. This process allows for high-speed data transmission over long distances with minimal signal loss, making discrete transmitters a cornerstone of modern communication networks.

Types of Transmitters - Discrete

Laser Diode Transmitters

Laser diode transmitters are known for their high power output and narrow spectral width, making them ideal for long-distance communication and high-speed data transmission. They are commonly used in telecommunications and data centers where bandwidth and distance are critical factors.

LED Transmitters

LED transmitters are typically used for short-distance communication due to their broader spectral width and lower power output compared to laser diodes. They are cost-effective and suitable for applications where high precision is not required, such as local area networks (LANs) and consumer electronics.

Vertical-Cavity Surface-Emitting Lasers (VCSELs)

VCSELs offer a balance between performance and cost, providing moderate power output with a relatively narrow spectral width. They are often used in data communication applications, including Ethernet and Fibre Channel networks, where moderate distances and speeds are sufficient.

How to choose Transmitters - Discrete?

When selecting a discrete transmitter, several key parameters must be considered:

Wavelength: Choose a wavelength that matches the fiber type and application requirements, typically 850 nm, 1310 nm, or 1550 nm.
Output Power: Ensure the transmitter provides sufficient power for the required transmission distance without exceeding the fiber's damage threshold.
Data Rate: Select a transmitter capable of supporting the desired data rate, considering future scalability needs.
Modulation Format: Determine the appropriate modulation format based on the application, such as NRZ, PAM4, or others.
Reliability and Quality: Evaluate the supplier's reputation, product certifications, and warranty offerings to ensure long-term reliability.

Environmental factors such as temperature range, humidity, and potential exposure to dust or chemicals should also be considered. Installation requirements, including connector types and compatibility with existing infrastructure, are crucial for seamless integration.

Applications of Transmitters - Discrete

Telecommunications

In the telecommunications industry, discrete transmitters are used to facilitate long-distance voice and data communication. They enable high-speed internet services, mobile network backhaul, and international data links, ensuring reliable and efficient data transfer across continents.

Data Centers

Data centers rely on discrete transmitters for high-speed data transfer between servers, storage systems, and networking equipment. These transmitters support the growing demand for cloud computing and big data analytics by providing fast and reliable connectivity.

Broadcasting

In broadcasting, discrete transmitters are used to distribute high-definition video and audio signals over fiber optic networks. They ensure minimal signal degradation and latency, providing viewers with high-quality content delivery.

Medical Imaging

Medical imaging systems utilize discrete transmitters to transmit high-resolution images and data from diagnostic equipment to display monitors and storage systems. This ensures accurate and timely diagnosis and treatment planning.

Industrial Automation

In industrial automation, discrete transmitters are employed to connect sensors, controllers, and actuators over fiber optic networks. They provide robust and interference-free communication in harsh environments, enhancing process control and efficiency.