.165 W RF Small Signal Field Effect Transistors (FET) 14

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Part	Manufacturer	Polarity or Channel Type	Configuration	Surface Mount	Maximum Power Dissipation (Abs)	Package Body Material	Transistor Application	Minimum DS Breakdown Voltage	Minimum Power Gain (Gp)	Terminal Form	Package Shape	Operating Mode	No. of Elements	Highest Frequency Band	No. of Terminals	Package Style (Meter)	Sub-Category	Field Effect Transistor Technology	Maximum Operating Temperature	Transistor Element Material	Terminal Finish	Maximum Drain Current (ID)	Terminal Position	JESD-30 Code	Case Connection	Qualification	Additional Features	JESD-609 Code	Maximum Time At Peak Reflow Temperature (s)	Peak Reflow Temperature (C)
NE3515S02-T1C-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON		.025 A	QUAD	R-PQMW-F4	SOURCE	Not Qualified			NOT SPECIFIED	NOT SPECIFIED
NE3515S02-T1D-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON		.025 A	QUAD	R-PQMW-F4	SOURCE	Not Qualified			NOT SPECIFIED	NOT SPECIFIED
NE3512S02-T1C-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	12.5 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	TIN BISMUTH	.015 A	QUAD	R-PQMW-F4		Not Qualified	LOW NOISE	e6
NE4210S01	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	UNSPECIFIED	AMPLIFIER	3 V	11 dB	GULL WING	ROUND	DEPLETION MODE	1	KU BAND	4	DISK BUTTON	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	NICKEL GOLD	.015 A	RADIAL	O-XRDB-G4	SOURCE	Not Qualified		e4
NE4210S01-T1B-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11 dB	GULL WING	UNSPECIFIED	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	GALLIUM ARSENIDE		.015 A	UNSPECIFIED	X-PXMW-G4	SOURCE	Not Qualified			NOT SPECIFIED	NOT SPECIFIED
NE4210S01-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11 dB	GULL WING	UNSPECIFIED	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	GALLIUM ARSENIDE	TIN BISMUTH	.015 A	UNSPECIFIED	X-PXMW-G4	SOURCE	Not Qualified		e6	NOT SPECIFIED	NOT SPECIFIED
NE4210S01-T1-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11 dB	GULL WING	UNSPECIFIED	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	GALLIUM ARSENIDE		.015 A	UNSPECIFIED	X-PXMW-G4	SOURCE	Not Qualified			NOT SPECIFIED	NOT SPECIFIED
NE3514S02-T1D-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	8 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	K BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	TIN BISMUTH	.015 A	QUAD	R-PQMW-F4		Not Qualified	LOW NOISE	e6
NE3512S02-T1D-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	12.5 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	TIN BISMUTH	.015 A	QUAD	R-PQMW-F4		Not Qualified	LOW NOISE	e6
NE3514S02-T1C-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	8 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	K BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	TIN BISMUTH	.015 A	QUAD	R-PQMW-F4		Not Qualified	LOW NOISE	e6
NE3511S02-T1C-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	12.5 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	TIN BISMUTH	.02 A	QUAD	R-PQMW-F4		Not Qualified		e6
NE3517S03-T1C-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11.5 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	K BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	GALLIUM ARSENIDE		.015 A	UNSPECIFIED	R-PXMW-F4		Not Qualified			NOT SPECIFIED	NOT SPECIFIED
NE3511S02-T1D-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	12.5 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	KU BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	SILICON	TIN BISMUTH	.02 A	QUAD	R-PQMW-F4		Not Qualified		e6
NE3517S03-T1D-A	Renesas Electronics	N-CHANNEL	SINGLE	YES	.165 W	PLASTIC/EPOXY	AMPLIFIER	3 V	11.5 dB	FLAT	RECTANGULAR	DEPLETION MODE	1	K BAND	4	MICROWAVE	Other Transistors	HETERO-JUNCTION	125 Cel	GALLIUM ARSENIDE		.015 A	UNSPECIFIED	R-PXMW-F4		Not Qualified			NOT SPECIFIED	NOT SPECIFIED

RF Small Signal Field Effect Transistors (FET)

RF Small Signal Bipolar Junction Transistors (BJT) are electronic devices used in low-power RF (radio frequency) applications to amplify and control small signals. They are commonly used in applications such as wireless communication, GPS, and radio broadcasting.

RF Small Signal BJTs are designed to handle low-power levels and operate at high frequencies, typically in the range of a few MHz to several GHz. They have a high gain and low noise figure, making them suitable for small signal amplification.

The RF Small Signal BJT consists of an emitter, base, and collector region, and works by controlling the flow of majority charge carriers (electrons or holes) between the emitter and collector through the base region. When a voltage is applied to the base-emitter junction, a small current flows through the base, allowing a larger current to flow from the emitter to the collector.

RF Small Signal Field Effect Transistors (FET) are electronic devices used in low-power RF (radio frequency) applications to amplify and control small signals. They are commonly used in applications such as wireless communication, GPS, and radio broadcasting.

RF Small Signal FETs are designed to handle low-power levels and operate at high frequencies, typically in the range of a few MHz to several GHz. They have a high gain and low noise figure, making them suitable for small signal amplification.

The RF Small Signal FET consists of a gate, source, and drain electrode, and works by controlling the flow of majority charge carriers (electrons or holes) between the source and drain regions through the gate electrode. When a voltage is applied to the gate electrode, it creates an electric field that modifies the conductivity of the channel, allowing current to flow between the source and drain.