Product Overview: 74LVC1G07GF/S500

The 74LVC1G07GF/S500 is a high-performance, single-buffer gate with open-drain output, brought to you by NXP Semiconductors. This device is designed to operate from 1.65 V to 5.5 V, making it suitable for a wide range of applications in modern mixed-voltage systems. It is a part of the 74LVC family, which is renowned for its low-voltage operation and low power consumption.

Key Features

• Compatibility: Interface capability with systems ranging from 1.65V to 5.5V, without the need for external level shifters.
• High-Speed: Offers a propagation delay (t_pd) of only 3.7 ns, ensuring swift signal processing for critical applications.
• Low Power: A low quiescent current and reduced power consumption make it ideal for battery-operated and power-sensitive devices.
• Flexible Design: The open-drain output allows for wired-OR logic configurations, providing designers with additional flexibility.
• Robustness: It features an input hysteresis which enhances noise immunity and allows for a stable output.
• Temperature Range: Operational across a broad temperature range from -40°C to +125°C, suitable for industrial applications.

Applications

The 74LVC1G07GF/S500 is versatile in its applications, including but not limited to:

• Level shifting in multi-voltage systems
• Line driving with open-drain outputs
• Bus and logic signal buffering
• Power management systems
• Computing and telecom infrastructure

Quality and Reliability

NXP Semiconductors is committed to delivering products that meet the highest standards of quality and reliability. The 74LVC1G07GF/S500 is no exception, with rigorous testing and quality controls to ensure consistent performance and dependability in your electronic systems.

Packaging and Ordering Information

The device is available in a lead-free, 6-pin SOT363 (SOT363-3) package, ensuring a compact footprint for space-constrained applications. The ordering code for this product is 74LVC1G07GF/S500, which is supplied in tape and reel packaging to facilitate automated assembly processes.