T FLIP-FLOP Latches & Flip-Flops 9

Reset All

Part	Manufacturer	Logic IC Type	Temperature Grade	Terminal Form	No. of Terminals	Package Code	Package Shape	Package Body Material	Surface Mount	No. of Functions	Maximum Frequency At Nominal Supply	Technology	No. of Bits	Packing Method	Nominal Supply Voltage / Vsup (V)	Power Supplies (V)	Package Style (Meter)	Package Equivalence Code	Sub-Category	Terminal Pitch	Maximum Operating Temperature	Trigger Type	Minimum Operating Temperature	Terminal Finish	Terminal Position	JESD-30 Code	Moisture Sensitivity Level (MSL)	Maximum Supply Voltage (Vsup)	Maximum Seated Height	Width	Qualification	Output Polarity	Minimum Supply Voltage (Vsup)	Maximum Power Supply Current (ICC)	JESD-609 Code	Maximum Time At Peak Reflow Temperature (s)	Peak Reflow Temperature (C)	Length	Family
HMC729LC3CRTR	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	QCCN	SQUARE	CERAMIC	YES	1	26000000000 Hz	BICMOS		TR		-3.3	CHIP CARRIER	LCC16,.12SQ,20	FF/Latches	.5 mm	85 Cel	POSITIVE EDGE	-40 Cel		QUAD	S-XQCC-N16					Not Qualified	COMPLEMENTARY							729
HMC679LC3CRTR	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	QCCN	SQUARE	CERAMIC	YES	1	26000000000 Hz	BICMOS		TR		-3.3	CHIP CARRIER	LCC16,.12SQ,20	FF/Latches	.5 mm	85 Cel	POSITIVE EDGE	-40 Cel		QUAD	S-XQCC-N16					Not Qualified
HMC749LC3CRTR	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	QCCN	SQUARE	CERAMIC	YES	1	26000000000 Hz	BICMOS	1	TR	3.3	3.3	CHIP CARRIER	LCC16,.12SQ,20	FF/Latches	.5 mm	85 Cel	POSITIVE EDGE	-40 Cel		QUAD	S-XQCC-N16		3.6 V		3 mm	Not Qualified	COMPLEMENTARY	3 V					3 mm	749
HMC679LC3C	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	HQCCN	SQUARE	CERAMIC, METAL-SEALED COFIRED	YES	1			1				CHIP CARRIER, HEAT SINK/SLUG			.5 mm	85 Cel	POSITIVE EDGE	-40 Cel	GOLD OVER NICKEL	QUAD	S-CQCC-N16			1.31 mm	3 mm	Not Qualified	COMPLEMENTARY			e4			3 mm	679
HMC729LC3CTR	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	HQCCN	SQUARE	CERAMIC, METAL-SEALED COFIRED	YES	1	26000000000 Hz	BICMOS	1	TR		-3.3	CHIP CARRIER, HEAT SINK/SLUG	LCC16,.12SQ,20	FF/Latches	.5 mm	85 Cel	POSITIVE EDGE	-40 Cel	GOLD OVER NICKEL	QUAD	S-CQCC-N16	3		1.31 mm	3 mm	Not Qualified	COMPLEMENTARY			e4	30	260	3 mm	729
HMC729LC3C	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	HQCCN	SQUARE	CERAMIC, METAL-SEALED COFIRED	YES	1			1				CHIP CARRIER, HEAT SINK/SLUG			.5 mm	85 Cel	POSITIVE EDGE	-40 Cel	GOLD OVER NICKEL	QUAD	S-CQCC-N16	3		1.31 mm	3 mm	Not Qualified	COMPLEMENTARY			e4	30	260	3 mm	729
HMC679LC3CTR	Analog Devices	T FLIP-FLOP	INDUSTRIAL	NO LEAD	16	HQCCN	SQUARE	CERAMIC, METAL-SEALED COFIRED	YES	1	26000000000 Hz	BICMOS	1	TR		-3.3	CHIP CARRIER, HEAT SINK/SLUG	LCC16,.12SQ,20	FF/Latches	.5 mm	85 Cel	POSITIVE EDGE	-40 Cel	GOLD OVER NICKEL	QUAD	S-CQCC-N16			1.31 mm	3 mm	Not Qualified	COMPLEMENTARY			e4			3 mm	679
UPG701P	Renesas Electronics	T FLIP-FLOP	MILITARY							1	5000000000 Hz	GAAS				-5.2		DIE OR CHIP	FF/Latches		125 Cel	MASTER-SLAVE	-65 Cel								Not Qualified			130 mA
UPG701B	Renesas Electronics	T FLIP-FLOP	MILITARY	FLAT	16	QFF	RECTANGULAR	CERAMIC	YES	1	5000000000 Hz	GAAS				-5.2	FLATPACK	QFL16,.15X.24,40	FF/Latches	1 mm	125 Cel	MASTER-SLAVE	-65 Cel	Tin/Lead (Sn/Pb)	QUAD	R-XQFP-F16					Not Qualified			130 mA	e0

Latches & Flip-Flops

Latches and flip-flops are two types of electronic circuits used in digital systems to store and manipulate digital data. They are both sequential logic circuits, meaning that they can store information and use that information to make decisions based on the previous state.

A latch is a type of digital circuit that can hold or "latch" a signal in its current state. It is a simple memory element that can store a single bit of information. A latch can be transparent or opaque, depending on its behavior when the clock signal is active. A transparent latch passes the input signal through to the output when the clock signal is active, while an opaque latch holds the input signal at the output when the clock signal is active.

Flip-flops are similar to latches but are more sophisticated and have additional control inputs. A flip-flop is a digital circuit that can store one bit of information and change its state based on the clock signal and input signals. Flip-flops can be edge-triggered or level-triggered, depending on how they respond to the clock signal. Edge-triggered flip-flops change their state at the rising or falling edge of the clock signal, while level-triggered flip-flops change their state continuously as long as the clock signal is active.

Flip-flops are classified into various types based on their behavior and the number of inputs. Some of the commonly used flip-flops include D flip-flops, JK flip-flops, T flip-flops, and SR flip-flops. D flip-flops have a single data input and a clock input and can store one bit of information. JK flip-flops have two inputs, J and K, and can store one bit of information. T flip-flops have a single input and can toggle between two states based on the clock signal. SR flip-flops have two inputs, S and R, and can store one bit of information.

Latches and flip-flops are used in various applications, including digital signal processing, memory systems, and control circuits. They are essential components of digital systems and can be found in many electronic devices, such as computers, mobile phones, and digital cameras.