Product Overview: NL27WZ07DTT1G from ON Semiconductor

The NL27WZ07DTT1G is a high-performance, dual buffer gate integrated circuit from ON Semiconductor, renowned for its low power consumption and high-speed operation. This advanced CMOS device is designed to meet the rigorous requirements of today's sophisticated digital electronics. The NL27WZ07DTT1G is a perfect choice for various applications, including portable devices, computing, and high-speed data processing systems.

Key Features

• High-Speed Operation: With a propagation delay of only 2.6ns at a 5V supply, the NL27WZ07DTT1G ensures swift data processing and signal transmission, making it ideal for high-speed applications.
• Low Power Consumption: This device is optimized for low-power operations, which is critical for battery-powered and energy-sensitive applications.
• Wide Operating Voltage Range: It operates over a voltage range of 1.65V to 5.5V, providing design flexibility for interfacing with both 3.3V and 5V systems.
• High Drive Output: The outputs can drive up to 24mA, allowing for direct driving of LEDs or other high-drain components without additional buffer stages.
• Compact Package: Housed in a space-saving SC-88 (SOT-363) package, the NL27WZ07DTT1G is suitable for use in space-constrained applications.

Applications

The NL27WZ07DTT1G is versatile and can be used in numerous applications, including:

• Smartphones and Tablets
• Laptops and Desktop Computers
• Portable Gaming Devices
• Data Communication Equipment
• Signal Conditioning

Quality and Reliability

ON Semiconductor is committed to high standards of quality and reliability in all their products. The NL27WZ07DTT1G is no exception, manufactured using robust silicon gate CMOS technology, and it is guaranteed to meet the stringent requirements of industrial and commercial applications. With its excellent performance and proven reliability, the NL27WZ07DTT1G from ON Semiconductor is an excellent choice for designers looking to enhance the efficiency and performance of their digital systems.