Manufacturer Part Number
SN74HCT04DBR
Manufacturer
Texas Instruments
Introduction
The SN74HCT04DBR is a high-speed CMOS logic Inverter integrated circuit from Texas Instruments. It features six independent Inverter circuits in a single package, providing a compact and efficient solution for various digital logic applications.
Product Features and Performance
Six independent Inverter circuits
Operates on a supply voltage range of 4.5V to 5.5V
Low quiescent current of 2 µA
Capable of sourcing and sinking up to 4mA of output current
Supports TTL and CMOS logic level compatibility
Fast propagation delay of 18ns at 5.5V and 50pF load capacitance
Wide operating temperature range of -55°C to 125°C
Surface mount 14-SSOP (0.209", 5.30mm Width) package
Product Advantages
High-speed CMOS logic for efficient digital signal processing
Compact 6-circuit design saves board space
Low power consumption for energy-efficient applications
Wide operating voltage and temperature range for versatile use
Key Reasons to Choose This Product
Proven reliability and performance from a trusted manufacturer, Texas Instruments
Versatile Inverter functionality for a wide range of digital logic applications
Excellent power efficiency and thermal capabilities
Small and space-saving surface mount package
Quality and Safety Features
Robust design and manufacturing processes for consistent quality
Compliance with industry standards and safety regulations
Compatibility
Compatible with TTL and CMOS logic families
Suitable for use in a variety of digital electronic systems and devices
Application Areas
Digital logic circuits
Signal conditioning and processing
Microcontroller and microprocessor-based systems
Industrial automation and control
Telecommunications equipment
Consumer electronics
Product Lifecycle
The SN74HCT04DBR is an active, in-production product from Texas Instruments. There are no immediate plans for discontinuation. Customers can contact our website's sales team for the latest product information and availability of any equivalent or alternative models.