220 W RF Power Bipolar Junction Transistors (BJT) 7

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Part	Manufacturer	Polarity or Channel Type	Configuration	Surface Mount	Nominal Transition Frequency (fT)	Maximum Power Dissipation (Abs)	Maximum Collector Current (IC)	Package Body Material	Transistor Application	Minimum Power Gain (Gp)	Terminal Form	Package Shape	No. of Elements	Highest Frequency Band	No. of Terminals	Package Style (Meter)	Sub-Category	Maximum Power Dissipation Ambient	Minimum DC Current Gain (hFE)	Maximum Operating Temperature	Maximum Collector-Base Capacitance	Transistor Element Material	Maximum Collector-Emitter Voltage	Terminal Finish	Terminal Position	JESD-30 Code	Moisture Sensitivity Level (MSL)	Case Connection	Qualification	Additional Features	JESD-609 Code
MSC1090M	Microsemi	NPN	SINGLE	YES	1025 MHz	220 W	5.52 A	PLASTIC/EPOXY	AMPLIFIER		FLAT	ROUND	1	L BAND	2	FLANGE MOUNT	Other Transistors		15	200 Cel		SILICON	65 V	TIN LEAD	DUAL	O-PDFM-F2		BASE	Not Qualified	HIGH RELIABILITY, WITH EMITTER BALLASTING RESISTORS	e0
2SC2782	Toshiba	NPN	SINGLE	YES		220 W	20 A	CERAMIC, METAL-SEALED COFIRED	AMPLIFIER	6.4 dB	FLAT	ROUND	1	VERY HIGH FREQUENCY BAND	6	FLANGE MOUNT	Other Transistors	220 W	10	175 Cel	320 pF	SILICON	16 V		UNSPECIFIED	O-CXFM-F6			Not Qualified
AM0912-080	STMicroelectronics	NPN	SINGLE	YES		220 W	7 A	CERAMIC, METAL-SEALED COFIRED	SWITCHING	8.4 dB	FLAT	RECTANGULAR	1	L BAND	2	FLANGE MOUNT	Other Transistors		20	250 Cel		SILICON			DUAL	R-CDFM-F2		BASE	Not Qualified
SD4100	STMicroelectronics	NPN	SINGLE	YES		220 W	16 A	CERAMIC, METAL-SEALED COFIRED	AMPLIFIER		FLAT	RECTANGULAR	1	ULTRA HIGH FREQUENCY BAND	4	FLANGE MOUNT	Other Transistors		25	200 Cel		SILICON	32 V	NICKEL	DUAL	R-CDFM-F4		EMITTER	Not Qualified
BLV861	NXP Semiconductors	NPN	COMMON EMITTER, 2 ELEMENTS	YES		220 W	15 A	CERAMIC, METAL-SEALED COFIRED	AMPLIFIER	8.5 dB	FLAT	RECTANGULAR	2	ULTRA HIGH FREQUENCY BAND	4	FLANGE MOUNT	Other Transistors	220 W	30	200 Cel		SILICON	30 V		DUAL	R-CDFM-F4	1	EMITTER	Not Qualified	HIGH RELIABILITY, WITH POLYSILICON EMITTER BALLASTING RESISTORS
BLV25	NXP Semiconductors	NPN	SINGLE	YES	600 MHz	220 W	17.5 A	CERAMIC, METAL-SEALED COFIRED	AMPLIFIER	10 dB	FLAT	ROUND	1	VERY HIGH FREQUENCY BAND	6	FLANGE MOUNT	Other Transistors	220 W	15	200 Cel		SILICON	33 V		UNSPECIFIED	O-CXFM-F6		ISOLATED	Not Qualified	HIGH RELIABILITY, DIFFUSED EMITTER BALLASTING RESISTORS
2SC2782A	Toshiba	NPN	SINGLE	YES		220 W	20 A	CERAMIC, METAL-SEALED COFIRED	AMPLIFIER		FLAT	ROUND	1	VERY HIGH FREQUENCY BAND	6	FLANGE MOUNT	Other Transistors		10	175 Cel	320 pF	SILICON	16 V		UNSPECIFIED	O-CXFM-F6			Not Qualified

RF Power Bipolar Junction Transistors (BJT)

RF Power Bipolar Junction Transistors (BJT) are electronic devices used in high-frequency RF (radio frequency) applications to amplify and control high-power signals. They are commonly used in applications such as broadcasting, radar, and satellite communications.

RF Power BJTs are designed to handle high-power levels and operate at high frequencies, typically in the range of a few MHz to several GHz. They have a low on-resistance and high gain, making them suitable for high-power amplification.

The RF Power 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 current flows through the base, allowing a larger current to flow from the emitter to the collector.

RF Power BJTs are available in various types and configurations, including NPN and PNP bipolar transistors, and can handle power levels ranging from a few watts to several kilowatts. They are subject to various standards and regulations, such as JEDEC (Joint Electron Device Engineering Council) and RoHS (Restriction of Hazardous Substances), to ensure their safety and performance.

Proper selection and use of RF Power BJTs are critical to ensure optimal performance, reliability, and compatibility with other components in the circuit. RF Power BJTs are often used in conjunction with other components, such as filters and matching networks, to form complete RF power amplification circuits.