The NXP 74AUP1G34GX/S500125 is a high-performance, single buffer/inverter gate that operates on a very low power supply range. This advanced ultra-low-power integrated circuit is part of NXP's AUP (Advanced Ultra-low Power) family, designed to provide optimal performance in power-sensitive applications.

Key Features:

• Power Supply Range: The device is designed to operate on a power supply range of 0.8V to 3.6V, making it highly versatile for various low-voltage applications.
• Low Static Power Consumption: With a static power consumption of just 0.9 μA at 3.3V, the 74AUP1G34GX/S500125 is an ideal choice for battery-operated and power-conscious designs.
• High-Speed Operation: Despite its low-power design, the device does not compromise on speed, offering typical t_pd of 3.5 ns at V_CC = 3.3V, C_L = 15 pF.
• Low Noise Overshoot and Undershoot: This product exhibits minimal noise overshoot and undershoot, which is crucial for maintaining signal integrity in sensitive applications.
• ESD Protection: The 74AUP1G34GX/S500125 includes input and output ESD protection exceeding 3.8 kV HBM (Human Body Model), ensuring robustness and reliability in harsh environments.
• Temperature Range: The device is operational over a wide temperature range, from -40°C to +125°C, suitable for industrial applications.

Applications:

The 74AUP1G34GX/S500125 is well-suited for a variety of applications where power efficiency is critical. These include:

• Smartphones and portable electronics
• Wearable technology
• Medical devices
• Energy management systems
• IoT devices

Package Information:

The NXP 74AUP1G34GX/S500125 comes in an ultra-small, leadless XSON6 package with a 0.8 mm pitch, which is ideal for space-constrained applications. The package dimensions are 1.0 x 1.45 x 0.5 mm, contributing to its ease of integration into compact system designs.

Overall, the NXP 74AUP1G34GX/S500125 offers an excellent balance of low power consumption, high performance, and small form factor, making it a top choice for designers looking to optimize their circuit designs for power efficiency and space savings.