Manufacturer Part Number
NLV27WZ14DFT2G
Manufacturer
onsemi
Introduction
The NLV27WZ14DFT2G is a dual inverter logic gate with Schmitt Trigger input, designed for automotive applications, providing high noise immunity and stable output.
Product Features and Performance
Dual inverter logic gate with Schmitt Trigger input
Schmitt Trigger enhances noise immunity
Supports a wide voltage range from 1.65V to 5.5V
Low quiescent current of 1 µA maximizes power efficiency
Capable of handling output currents up to 32mA
Operates efficiently across a wide temperature range from -55°C to 125°C
Fast propagation delay of 4.9ns at 5V, 50pF load
Product Advantages
High noise immunity suitable for unstable environmental conditions
Low power consumption ideal for automotive applications
Flexible voltage support for varying system needs
Robust output driving capability
Suitable for extreme temperature operations
Key Technical Parameters
Voltage Supply: 1.65V ~ 5.5V
Current Quiescent (Max): 1 µA
Current Output High, Low: 32mA
Input Logic Level Low: 0.4V ~ 1.2V
Input Logic Level High: 1.8V ~ 3.6V
Max Propagation Delay: 4.9ns @ 5V, 50pF
Operating Temperature Range: -55°C ~ 125°C
Quality and Safety Features
AEC-Q100 qualified for automotive reliability and performance standards
Compatibility
Compatible with various logic systems due to its wide input logic level range
Application Areas
Automotive electronics
Signal processing
Communication systems
Embedded systems
Product Lifecycle
Obsolete status with potential alternatives available for replacement or upgrade
Several Key Reasons to Choose This Product
Exceptionally high reliability suitable for automotive applications where safety is crucial
Low power consumption aiding in better battery management in portable and automotive applications
High immune to noise, providing stable outputs in electrically noisy environments like automotive systems
Wide operating temperature makes it ideal for harsh environmental conditions
Quick response time with minimal propagation delay essential for real-time signal processing