ON Semiconductor MC74VHC08DTR2G - Quad 2-Input AND Gate

The MC74VHC08DTR2G is a high-speed CMOS device from ON Semiconductor that features a quad 2-input AND gate configuration. This integrated circuit is designed to operate with a power supply range of 2V to 5.5V, making it suitable for a wide range of applications, including battery-powered devices and portable electronics. The low power consumption and high noise immunity of CMOS technology, combined with the ability to drive 10 LSTTL loads, make this device a versatile choice for interfacing with both CMOS and LSTTL systems.

The MC74VHC08DTR2G offers significant advantages in terms of speed and power efficiency. Its propagation delay time is minimized, allowing for fast switching operations, which is critical in high-speed logic systems. Moreover, the device has a balanced propagation delay and transition times, which ensures reliable and consistent performance across all outputs.

This product is provided in a TSSOP-14 package, which is designed for space-saving on PCBs without compromising performance. The package is also RoHS compliant, adhering to environmental standards that restrict the use of hazardous substances in electronic components.

Key features of the MC74VHC08DTR2G include:

• Quad 2-input AND gate logic configuration
• Wide operating voltage range of 2V to 5.5V
• Low power consumption: ICC = 2µA maximum at TA = 25°C
• High noise immunity characteristic of CMOS technology
• Capability to drive 10 LSTTL loads
• Power down protection provided on inputs
• Low noise: VOLP = 0.8V maximum
• Pb-Free, Halogen Free, and RoHS compliant

The MC74VHC08DTR2G is ideal for use in a variety of logic functions where low power operation is required. It is commonly used in computing devices, data processing equipment, and other electronic systems where efficient logic operations are critical. With its robust design and compatibility with multiple logic families, this device from ON Semiconductor is a reliable choice for designers looking to enhance the performance of their digital systems.