Tin/Lead (Sn/Pb) Fiber Optics - Transceivers 12

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Part	Manufacturer	Fiber Optic Type	Mounting Feature	Maximum Supply Voltage	Terminal Finish	Maximum Operating Temperature	Minimum Operating Temperature	Rx Data Rate	Tx Data Rate	Emitter or Detector Type	Fiber Type	Nominal Optical Power Output	Connection Type	Nominal Supply Voltage	Body Length/Diameter	Body Width	Package Style (Meter)	Sub-Category	Body Height	Nominal Operating Wavelength	Minimum Supply Voltage	Minimum Operating Wavelength	Communication Standard	Maximum Operating Wavelength	Minimum Return Loss	Additional Features	JESD-609 Code	Built-in Features	Sensitivity Level
SBL51414A	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT	2 V	Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		1300 nm							e0
SBL81314A	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT	2 V	Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		1300 nm							e0
SPFBFT302	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT	5.5 V	Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		650 nm							e0
SBH51414A	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT	2 V	Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		1300 nm							e0
SBM82314X	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT		Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		1590 nm							e0
SBL51214N	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT	2 V	Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		1270 nm							e0
SBM81314A	Infineon Technologies	TRANSCEIVER	THROUGH HOLE MOUNT	2 V	Tin/Lead (Sn/Pb)	85 Cel	-40 Cel											Fiber Optic Transceivers		1300 nm							e0
HFBR-53A3VEM	Broadcom	TRANSCEIVER	BOARD/PANEL MOUNT	3.47 V	Tin/Lead (Sn/Pb)	70 Cel	0 Cel			LASER DIODE, PIN PHOTODIODE	50/125, 62.5/125, MMF	.199 mW	SC CONNECTOR	3.3 V	39.6 mm	29.6 inch		Fiber Optic Transceivers	10.2 mm	850 nm	3.14 V	770 nm		860 nm	12 dB	1 X 9 ARRAY	e0	AMPLIFIER
HFBR-57L5AP	Broadcom	TRANSCEIVER	BOARD/PANEL MOUNT	3.63 V	Tin/Lead (Sn/Pb)	75 Cel	-10 Cel	1250 Mbps	1250 Mbps				LC CONNECTOR	3.3 V	55.2 mm	13.4 inch		Fiber Optic Transceivers	8.5 mm	850 nm	2.97 V	830 nm	GBE	860 nm	12 dB	MSA-SFF-8472, SFF-8074I	e0	AMPLIFIER	-17 dBm
HFBR-5730L	Broadcom	TRANSCEIVER		3.46 V	Tin/Lead (Sn/Pb)	70 Cel	0 Cel	1062 Mbps	1062 Mbps	LASER	50/125, 62.5/125, MMF		LC CONNECTOR	3.3 V	56.4 mm	13.4 inch		Fiber Optic Transceivers	8.5 mm	845 nm	3.13 V	830 nm		860 nm	12 dB		e0	AMPLIFIER
HFBR-5730LP	Broadcom	TRANSCEIVER		3.46 V	Tin/Lead (Sn/Pb)	70 Cel	0 Cel	1062 Mbps	1062 Mbps	LASER	50/125, 62.5/125, MMF		LC CONNECTOR	3.3 V	56.4 mm	13.4 inch		Fiber Optic Transceivers	8.5 mm	845 nm	3.13 V	830 nm		860 nm	12 dB		e0	AMPLIFIER
HFBR-5923AL	Broadcom	TRANSCEIVER	THROUGH HOLE MOUNT	3.465 V	Tin/Lead (Sn/Pb)	70 Cel	0 Cel	2125 Mbps	2125 Mbps	LASER	50/125, 62.5/125, MMF	.2344 mW	LC CONNECTOR	3.3 V	48.19 mm	15.05 inch	DIP		10.8 mm	850 nm	3.135 V	830 nm	GBE	860 nm	12 dB	OPTICAL OUTPUT POWER FOR THE FIBER TYPE 62.5/125 IS 0.2398 MW	e0

Fiber Optics - Transceivers

Fiber optic transceivers are electronic devices that are used in fiber optic communication systems to transmit and receive optical signals. They are designed to both transmit and receive data over a fiber optic network, allowing for two-way communication between devices.

Fiber optic transceivers typically consist of a transmitter, a receiver, and control circuitry. The transmitter converts electrical signals into optical signals, which are then transmitted over the fiber optic cable. The receiver converts the incoming optical signal into an electrical signal, which is then processed by the control circuitry.

Fiber optic transceivers use different technologies to transmit and receive optical signals, including:

1. Direct modulation: Direct modulation uses an LED or laser diode to directly modulate the optical signal in response to an electrical signal.

2. External modulation: External modulation uses an electro-optic modulator to modulate the optical signal in response to an electrical signal.

3. Coherent detection: Coherent detection uses a local oscillator to synchronize the optical signal with a reference signal, enabling precise phase and amplitude measurements of the optical signal.

Fiber optic transceivers 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.