Product Overview: 74LVT08DB - NXP Semiconductors

The 74LVT08DB is a high-performance, low-voltage, Quad 2-input AND gate integrated circuit (IC) produced by NXP Semiconductors. This IC is part of the LVT family, which is known for its low-voltage operation and tolerance to higher voltages. The 74LVT08DB is designed to operate at a nominal supply voltage of 3.3V but can handle 5V tolerant inputs, which makes it ideal for interfacing with 5V systems while maintaining a low-power 3.3V environment.

Key Features:

• Supply Voltage Range: 2.7V to 3.6V, with 5V tolerant inputs
• High-Speed Operation: Fast propagation delays, ensuring quick response times suitable for high-speed applications
• Drive Capability: Capable of driving 50Ω transmission lines
• Power Dissipation: Low-power consumption, which is crucial for battery-operated and power-sensitive applications
• Package: Available in a SSOP20 package, providing a compact footprint for space-constrained applications

Applications:

The 74LVT08DB is versatile and can be used in a wide range of applications such as:

• Computing systems
• Telecommunications
• Data processing
• Industrial controls
• Battery-powered devices

Quality and Reliability:

NXP Semiconductors is committed to delivering high-quality and reliable components. The 74LVT08DB is no exception, with its robust design and manufacturing process ensuring consistent performance and longevity in the field. It is also supported by NXP's rigorous testing and product validation, giving designers confidence in their choice of logic solutions.

Environmental Compliance:

The 74LVT08DB adheres to environmental standards and is compliant with RoHS (Restriction of Hazardous Substances), which ensures that it is free from specific hazardous materials commonly used in electronics and electrical equipment.

With its combination of high-speed operation, low-power consumption, and interface flexibility, the 74LVT08DB from NXP Semiconductors is an excellent choice for designers looking to optimize their digital logic operations while maintaining power efficiency and signal integrity.