Maxim Integrated MAX961ESA+T - High-Speed, Low-Power Voltage Comparators

The MAX961ESA+T from Maxim Integrated is a state-of-the-art voltage comparator that combines high-speed operation with low-power consumption, making it an ideal choice for a wide range of applications. Designed for precision voltage comparison, this device is part of Maxim's renowned family of comparators that offer reliable performance in a compact package.

The MAX961ESA+T features a fast propagation delay of just 4ns at a 5mV overdrive, which is essential for high-speed signal processing applications. Despite its speed, the device maintains a low power draw, with a supply current of just 1mA. This efficiency makes it suitable for battery-powered and portable devices where power conservation is critical.

This comparator operates from a single +5V supply or dual ±5V supplies, offering flexibility in system design. The input voltage range extends from the negative supply rail to within 1.5V of the positive supply, giving designers a broad range to work with. The output stage is push-pull, which allows for a direct drive of TTL or CMOS logic levels without pull-up resistors, simplifying circuit design and reducing component count.

The MAX961ESA+T comes in a compact 8-pin SOIC package, which is ideal for space-constrained applications. Its small footprint does not compromise its performance, as it boasts a low input offset voltage of 3.5mV and a high input impedance, ensuring accurate and stable comparisons.

This product is designed for a variety of applications, including zero-crossing detectors, window comparators, ADCs, pulse, and square-wave shapers, as well as high-speed sampling circuits. With its robust design, the MAX961ESA+T is capable of withstanding ESD up to 2000V, providing additional reliability in harsh environments.

Overall, the Maxim Integrated MAX961ESA+T is a versatile, high-speed comparator that offers excellent performance in a small package, making it a top choice for designers looking to enhance the speed and efficiency of their electronic systems.