Maxim Integrated MAX951EUA+T Precision Operational Amplifier

The MAX951EUA+T is a high-performance, low-power precision operational amplifier (op-amp) from Maxim Integrated, designed to offer exceptional accuracy and stability for a wide range of applications. This op-amp is particularly well-suited for battery-powered and portable devices due to its low voltage operation and power-saving features.

Featuring a single-supply voltage range from 2.7V to 7V, the MAX951EUA+T is versatile and can be integrated into various circuits without the need for dual supplies. This makes it an ideal choice for compact and simplified designs. With a quiescent current of just 750µA, it helps to extend battery life in portable applications, while still delivering the performance required for precise signal conditioning.

One of the standout features of the MAX951EUA+T is its integrated EMI (Electromagnetic Interference) rejection circuitry. This feature ensures that the op-amp performs reliably in environments with high levels of noise, making it suitable for industrial and automotive applications where electrical noise can be a significant issue.

The device offers a high gain-bandwidth product of 1MHz, which enables it to handle a broad range of frequencies with high fidelity. Additionally, with a low input bias current of 1nA and an offset voltage of just 100µV, the MAX951EUA+T provides high accuracy, making it an excellent choice for precision sensor amplification, data acquisition systems, and control loops.

The MAX951EUA+T is available in a compact 8-pin µMAX package, which is highly space-efficient and suitable for space-constrained applications. The temperature range of the device spans from -40°C to +85°C, ensuring reliable operation across a wide range of environmental conditions.

In summary, the Maxim Integrated MAX951EUA+T precision operational amplifier is a robust, low-power device that delivers high accuracy and EMI resistance, making it a top choice for designers who require a reliable op-amp for their precision applications.