The 74HCT147N,652 is a high-speed Si-gate CMOS device from NXP Semiconductors, renowned for its robust performance and reliability. This integrated circuit is specifically designed to provide priority encoding of 10 input lines to 4 output lines, making it an ideal choice for a variety of digital applications where encoding is required.

Key Features

• Input Levels: Accepts inputs from TTL levels, which makes it compatible with a wide range of digital systems.
• Output Capability: Capable of driving 15 LSTTL loads, ensuring strong signal transmission and the ability to drive multiple devices.
• Power Consumption: Features a balanced power consumption with a typical low power dissipation of 40 µA, making it suitable for power-sensitive applications.
• High Noise Immunity: The device boasts a noise immunity consistent with standard HCT logic levels, providing stable operation in noisy environments.
• Priority Encoding: Provides priority to the highest-order input line, ensuring clear and concise encoding for digital signal processing.

Applications

The 74HCT147N,652 is versatile and can be used in various applications, including:

• Computer systems for address decoding
• Control systems for sequence encoding
• Communication systems for channel selection
• Industrial electronics where signal prioritization is necessary

Product Specifications

The 74HCT147N,652 operates within a standard temperature range and comes in a DIP-16 (Dual In-line Package) form factor, which is suitable for through-hole mounting. This package allows for easy integration into a variety of circuit boards. The device is also characterized by its fast propagation delay, ensuring quick response times in high-speed digital circuits.

Quality and Reliability

NXP Semiconductors is committed to delivering high-quality products, and the 74HCT147N,652 is no exception. It undergoes rigorous testing and quality assurance measures to ensure it meets the industry standards for performance and reliability. Customers can trust this product to perform consistently over its intended lifecycle.