Product Overview: 74HCT4015N,112 from NXP Semiconductors
The 74HCT4015N,112 is a high-quality integrated circuit produced by NXP Semiconductors, a renowned leader in the electronics industry. This device is part of the 74HCT series, which is compatible with TTL levels and known for its high-speed CMOS technology. The 74HCT4015N,112 is a dual 4-stage serial shift register that offers a wide range of applications in digital systems.
Key Features
- Type: Dual 4-stage serial shift register
- Logic Family: HCT
- Operating Voltage: 4.5V to 5.5V
- Logic Case Style: DIP
- No. of Pins: 16
- Propagation Delay: 29ns
- Output Current: 5.2mA
- Operating Temperature Range: -40°C to +125°C
Product Description
The 74HCT4015N,112 features two separate serial-input, parallel-output registers that share a common clock. Data is shifted on the positive-going transitions of the clock. Users can utilize the clear input to reset the shift register stages to the low state, which is particularly useful in various control applications.
Its DIP (Dual In-line Package) form factor allows for easy insertion into standard breadboards and sockets, making it ideal for prototyping and educational purposes. The device's pin configuration is designed to be simple and straightforward, ensuring ease of integration into existing and new circuits.
With its robust operating temperature range, the 74HCT4015N,112 is suitable for use in challenging environmental conditions, ensuring reliable performance in both commercial and industrial applications. Its fast propagation delay is beneficial for high-speed operations, while the low output current allows for better power efficiency.
Applications
The 74HCT4015N,112 is versatile and can be used in various digital applications such as:
- Serial-to-parallel data conversion
- Data processing
- Control systems
- Communication systems
- Instrumentation
With its reliability and NXP's commitment to quality, the 74HCT4015N,112 is an excellent choice for designers and engineers looking to implement a serial shift register in their digital logic applications.