CD74HC75M96: High-Speed CMOS Logic Quad Bistable Transparent Latch from Texas Instruments

The CD74HC75M96 device is a high-speed CMOS logic quad bistable transparent latch designed and manufactured by Texas Instruments, a leader in semiconductor design and production. This integrated circuit is part of the 74HC family, known for its high-speed operation, which is comparable to the equivalent bipolar Schottky TTL while maintaining the CMOS low power dissipation.

The CD74HC75M96 features four independent latches with common control gates, making it a versatile component for a wide range of applications in digital systems. Each latch has its own Q and Q-bar outputs, which provide the inverted and non-inverted data states, respectively. The transparency of the latches allows data at the D-input to appear at the Q output while the latch-enable (LE) input is high. When LE is taken low, the Q output will remain at the level of the D input that was set up before the transition of LE from high to low.

The device also includes a clear (CLR) function that, when taken low, will reset all latches to a low state, overriding all other inputs. This function is particularly useful for initializing registers and flip-flop arrays in digital systems. The CD74HC75M96 operates at a wide voltage range from 2V to 6V, providing compatibility with a variety of logic levels and making it suitable for interfacing with both TTL and CMOS logic families.

Available in a compact SOIC-16 package, the CD74HC75M96 is optimized for high-density mounting and is widely used in applications such as data storage, register storage, and data manipulation. Its fast switching characteristics and low power consumption make it an excellent choice for portable devices, computing equipment, and other digital logic applications where power efficiency and speed are crucial.

With its robust design and proven reliability, the CD74HC75M96 from Texas Instruments is an essential component for engineers and designers looking to create efficient and high-performing digital circuits.