STMicroelectronics M74HC132M1TR Quad 2-Input NAND Schmitt Trigger

The STMicroelectronics M74HC132M1TR is a high-speed CMOS Quad 2-Input NAND Schmitt Trigger designed to operate from 2 V to 6 V, making it suitable for a wide range of applications in the consumer, automotive, and industrial markets. This integrated circuit is part of the HC family, which is well-known for its robustness and compatibility with TTL logic levels.

Key Features

• Logic Type: Quad 2-Input NAND Schmitt Trigger, providing a stable output even with slow input transition rates.
• Operating Voltage: Flexible operating voltage range of 2 V to 6 V, accommodating various logic levels and power requirements.
• High Noise Immunity: Enhanced noise immunity thanks to the Schmitt trigger action at all inputs.
• Low Power Consumption: Balanced propagation delays and low quiescent current make it an energy-efficient choice.
• High-Speed Operation: Fast response time with a typical propagation delay of 8 ns at Vcc = 4.5 V, ensuring quick signal processing.
• Output Drive Capability: Capable of driving up to 10 LSTTL loads, which allows for flexibility in interfacing with other logic families.
• Pin and Function Compatible: Direct replacement for other standard logic products, simplifying design upgrades and system maintenance.
• Packaging: Supplied in a space-saving and environmentally friendly SO-14 package, ideal for compact circuit designs.

Applications

The M74HC132M1TR is versatile and can be used in a range of applications, including:

• Wave and pulse shapers
• Astable multivibrators
• Monostable multivibrators
• Logic level converters for interfacing different voltage levels
• Glitch-free clock distribution networks
• Automotive systems requiring high noise immunity

Quality and Reliability

STMicroelectronics is committed to delivering high-quality products. The M74HC132M1TR is rigorously tested to ensure reliable performance in a wide range of environmental conditions. It is also compliant with the RoHS directive, making it an environmentally responsible choice for electronic designs.