68 Power Management ICs 15

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Part	Manufacturer	Other IC type	Temperature Grade	No. of Terminals	Package Code	Package Shape	Surface Mount	Package Body Material	Maximum Supply Current (Isup)	No. of Functions	No. of Channels	Technology	Terminal Form	Nominal Supply Voltage (Vsup)	Power Supplies (V)	Package Style (Meter)	Package Equivalence Code	Sub-Category	Terminal Pitch	Maximum Operating Temperature	Minimum Operating Temperature	Terminal Position	JESD-30 Code	Moisture Sensitivity Level (MSL)	Maximum Supply Voltage (Vsup)	Maximum Seated Height	Width (mm)	Qualification	Minimum Supply Voltage (Vsup)	Additional Features	Maximum Time At Peak Reflow Temperature (s)	Peak Reflow Temperature (C)	Length	Adjustable Threshold
71M6531F-IM/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	VQCCN	SQUARE	YES	UNSPECIFIED	12 mA	1	1		NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
BD71837AMWV-E2	ROHM	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HVQCCN	SQUARE	YES	UNSPECIFIED	.295 mA	1	16		NO LEAD	5 V		CHIP CARRIER, HEAT SINK/SLUG, VERY THIN PROFILE	LCC68,.32SQ,16		.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		5.5 V	1 mm	8 mm		2.7 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	YES
73S1210F-68IMR/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HQCCN	SQUARE	YES	UNSPECIFIED		1	1	CMOS	NO LEAD	3.3 V		CHIP CARRIER, HEAT SINK/SLUG			.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
71M6531F-IMR/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	VQCCN	SQUARE	YES	UNSPECIFIED	12 mA	1	1		NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
78M6612-IMR/F/P	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HVQCCN	SQUARE	YES	PLASTIC/EPOXY	7.7 mA	1	1	CMOS	NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-PQCC-N68		3.6 V	.85 mm	8 mm	Not Qualified	3 V	SEATED HGT-NOM			8 mm	YES
78M6612-IM/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HVQCCN	SQUARE	YES	PLASTIC/EPOXY	7.7 mA	1	1	CMOS	NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-PQCC-N68	3	3.6 V	.85 mm	8 mm	Not Qualified	3 V	SEATED HGT-NOM			8 mm	YES
78M6612-IM/F/P	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HVQCCN	SQUARE	YES	PLASTIC/EPOXY	7.7 mA	1	1	CMOS	NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-PQCC-N68		3.6 V	.85 mm	8 mm	Not Qualified	3 V	SEATED HGT-NOM			8 mm	YES
71M6531D-IMR/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	VQCCN	SQUARE	YES	UNSPECIFIED	12 mA	1	1		NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
73S1210F-68IM/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HQCCN	SQUARE	YES	UNSPECIFIED		1	1	CMOS	NO LEAD	3.3 V		CHIP CARRIER, HEAT SINK/SLUG			.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
73S1209F-68IM/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HQCCN	SQUARE	YES	UNSPECIFIED		1	1	CMOS	NO LEAD	3.3 V		CHIP CARRIER			.5 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V		8 mm	Not Qualified	2.7 V	CAN ALSO OPERATES AT 4.75 TO 6 V SUPPPLY	NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
78M6612-IMR/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HVQCCN	SQUARE	YES	PLASTIC/EPOXY	7.7 mA	1	1	CMOS	NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-PQCC-N68	3	3.6 V	.85 mm	8 mm	Not Qualified	3 V	SEATED HGT-NOM			8 mm	YES
71M6531D-IM/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	VQCCN	SQUARE	YES	UNSPECIFIED	12 mA	1	1		NO LEAD	3.3 V	3.3	CHIP CARRIER	LCC68,.32SQ,16	Other Analog ICs	.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V		NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
73S1209F-68IMR/F	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HQCCN	SQUARE	YES	UNSPECIFIED		1	1	CMOS	NO LEAD	3.3 V		CHIP CARRIER			.5 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V		8 mm	Not Qualified	2.7 V	CAN ALSO OPERATES AT 4.75 TO 6 V SUPPPLY	NOT SPECIFIED	NOT SPECIFIED	8 mm	NO
73S1210F-68IMR/F/P	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HQCCN	SQUARE	YES	UNSPECIFIED		1	1	CMOS	NO LEAD	3.3 V		CHIP CARRIER, HEAT SINK/SLUG			.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V				8 mm	NO
73S1210F-68IM/F/P	Maxim Integrated	POWER SUPPLY MANAGEMENT CIRCUIT	INDUSTRIAL	68	HQCCN	SQUARE	YES	UNSPECIFIED		1	1	CMOS	NO LEAD	3.3 V		CHIP CARRIER, HEAT SINK/SLUG			.4 mm	85 Cel	-40 Cel	QUAD	S-XQCC-N68		3.6 V	.8 mm	8 mm	Not Qualified	3 V				8 mm	NO

Power Management ICs

Power Management ICs (PMICs) are electronic components that are used to regulate and manage the power supply in electronic systems. They are used to optimize power usage, reduce power consumption, and increase battery life in portable devices.

PMICs typically include a range of components such as voltage regulators, power switches, and battery management circuits. Voltage regulators are used to maintain a stable voltage output despite fluctuations in the input voltage or load. Power switches are used to control the flow of power in a circuit, and battery management circuits are used to monitor and manage the charging and discharging of batteries.

PMICs are used in a wide range of applications, including mobile phones, laptops, tablets, and other portable devices. They are also used in automotive electronics, power supplies, and industrial automation systems. PMICs play a critical role in managing power consumption in electronic systems, reducing energy waste and extending battery life.

One of the key advantages of PMICs is their ability to provide multiple functions in a single package, reducing the number of components needed in a system and simplifying design. They also help to improve system reliability by protecting against overvoltage, overcurrent, and overtemperature conditions.