The MC10H102FNR2 is a state-of-the-art integrated circuit from ON Semiconductor, designed to deliver exceptional performance for a variety of digital applications. This device is part of the renowned 10H series, which is known for its high-speed ECL logic family. The MC10H102FNR2 is specifically engineered as a quad 2-input NOR gate, making it a fundamental component in digital systems where logic operations are required.

Fabricated with advanced silicon-gate technology, the MC10H102FNR2 boasts impressive speed characteristics and a significant reduction in power consumption compared to its predecessors. This makes it an ideal choice for high-frequency environments and applications demanding low power usage without compromising on speed.

The device comes in a compact, surface-mount PLCC-20 package, which is suitable for densely packed PCB layouts, ensuring that space constraints do not limit the design capabilities. Its fully compatible ECL 10KH logic levels allow for easy interfacing with other ECL components, providing a seamless integration into existing systems or new designs.

Key Features:

• Logic Type: Quad 2-Input NOR Gate
• Operating Voltage: -4.94V to -5.46V
• Propagation Delay Time: 1.0ns at -5.2V
• Operating Temperature Range: 0°C to +85°C
• Mounting Type: Surface Mount
• Package / Case: PLCC-20

The MC10H102FNR2 is characterized by its differential inputs, which enhance noise immunity and enable the use of this device in noisy environments or for long-distance data transmissions. Additionally, the device includes features such as open-emitter outputs, allowing for wired-OR configurations and providing designers with the flexibility to create complex logic functions.

ON Semiconductor's commitment to quality ensures that the MC10H102FNR2 meets stringent industry standards for reliability and performance. Whether it's used in telecommunications, computing, instrumentation, or control systems, the MC10H102FNR2 from ON Semiconductor is a versatile and reliable choice for any designer looking to implement high-speed logic operations with precision and efficiency.