2.4 V Fiber Optics - Transmitters 4
| Part | RoHS | Manufacturer | Fiber Optic Type | Mounting Feature | Maximum Supply Voltage | Terminal Finish | Maximum Operating Temperature | Minimum Operating Temperature | Emitter or Detector Type | Spectral Width | Fiber Type | Transmission Type | No. of Channels | Nominal Optical Power Output | Connection Type | Nominal Supply Voltage | Supply Current | Body Length/Diameter | Body Width | Rise Time | Package Style (Meter) | Sub-Category | Body Height | Nominal Operating Wavelength | Minimum Supply Voltage | Minimum Operating Wavelength | Communication Standard | Maximum Operating Wavelength | Data Rate | Maximum Fall Time | Minimum Return Loss | Additional Features | JESD-609 Code | Built-in Features |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Broadcom |
TRANSMITTER |
THROUGH HOLE MOUNT |
2.4 V |
MATTE TIN |
70 Cel |
0 Cel |
LED |
POF |
DIGITAL |
.107 mW |
2.1 V |
18.8 mm |
10.2 inch |
Fiber Optic Emitters |
7.62 mm |
650 nm |
1.8 V |
640 nm |
660 nm |
125 Mbps |
OPTICAL OUTPUT POWER FOR HCS FIBER TYPE: 0.0446 |
e3 |
|||||||||||
|
Broadcom |
TRANSMITTER |
THROUGH HOLE MOUNT |
2.4 V |
Tin/Lead (Sn/Pb) |
70 Cel |
0 Cel |
LED |
POF |
ANALOG |
.501 mW |
2.1 V |
18.3 mm |
10.2 inch |
Fiber Optic Emitters |
19.6 mm |
650 nm |
1.8 V |
640 nm |
660 nm |
125 Mbps |
e0 |
AMPLIFIER |
||||||||||||
|
Broadcom |
TRANSMITTER |
THROUGH HOLE MOUNT |
2.4 V |
Tin/Lead (Sn/Pb) |
70 Cel |
0 Cel |
LED |
POF |
ANALOG |
.501 mW |
2.1 V |
19.6 mm |
10.2 inch |
Fiber Optic Emitters |
7.6 mm |
650 nm |
1.8 V |
640 nm |
660 nm |
125 Mbps |
e0 |
AMPLIFIER |
||||||||||||
|
|
Broadcom |
TRANSMITTER |
THROUGH HOLE MOUNT |
2.4 V |
TIN |
70 Cel |
0 Cel |
LED |
POF |
DIGITAL |
.107 mW |
2.1 V |
18.3 mm |
7.62 inch |
Fiber Optic Emitters |
18.8 mm |
650 nm |
1.8 V |
640 nm |
660 nm |
125 Mbps |
OPTICAL OUTPUT POWER FOR HCS FIBER TYPE: 0.0446 |
e3 |
Fiber optic transmitters are electronic devices that are used in fiber optic communication systems to convert electrical signals into optical signals. They are designed to transmit the optical signal over a fiber optic cable to carry information over long distances.
Fiber optic transmitters use different technologies to generate the optical signal, including light-emitting diodes (LEDs) and laser diodes. LEDs are typically used for short-distance communication, while laser diodes are used for long-distance communication.
Fiber optic transmitters typically consist of a semiconductor material that generates photons when an electrical current is passed through it. The photons are emitted as light, which is then transmitted through the fiber optic cable to carry information over long distances.
Fiber optic transmitters come in different configurations and designs, depending on the application and the required performance. They can be integrated into a fiber optic network or mounted in a separate enclosure, depending on the application and the space available.