The 74AUP1T32GWH is a single Schmitt-trigger AND gate from Nexperia's AUP (Advanced Ultra-low Power) logic family. This gate is designed for low-power and low-voltage operation, making it suitable for portable and battery-powered applications. The device features a Schmitt-trigger input, which improves noise immunity and allows for slow or noisy input signals to be processed reliably.

Applications

• Level shifting
• Voltage translation
• Signal buffering
• Line driving
• General logic functions in portable devices
• Mobile phones and tablets
• Wearable technology
• Low power microcontrollers and microprocessors

Features

• Ultra-low power consumption: ICC = 0.9 μA (typical)
• Wide supply voltage range: 0.8 V to 3.6 V
• Schmitt-trigger inputs for enhanced noise immunity
• High noise immunity: typically 0.8 V
• Low input capacitance: CI = 1.5 pF (typical)
• ESD protection: HBM JESD22-A114F exceeds 2000 V, MM JESD22-A115-A exceeds 200 V
• Specified from -40 °C to +85 °C
• Leadless package: 6-pin leadless extremely thin small outline package (XSON6) with 0.5 mm pitch

Benefits

• Reduced power consumption extends battery life in portable devices.
• Improved noise immunity ensures reliable operation in noisy environments.
• Wide supply voltage range allows for flexible system design.
• Small package size saves board space.
• High ESD protection enhances device reliability during handling and assembly.

Additional Details

The 74AUP1T32GWH is available in a 6-pin XSON package. It is designed for operation over the -40°C to +85°C temperature range. The device is part of the AUP logic family, known for its ultra-low power consumption and excellent performance. The AND gate function performs the logical AND operation on the input signal, producing a high output only when both inputs are high. The Schmitt-trigger inputs allow the device to accept slowly changing or noisy input signals and produce clean, sharp output transitions. This is particularly useful in applications where noise is a concern or where input signals are not ideal.