Product Overview: MAX4001EUA+T from Maxim Integrated

The MAX4001EUA+T is a high-performance, low-power, precision current-sense amplifier from Maxim Integrated, a leader in analog and mixed-signal engineering. This innovative component is designed to provide accurate current measurement in a variety of applications such as battery management, portable devices, and power management systems. Its small size and efficiency make it an excellent choice for space-constrained applications that require precise monitoring of current flow.

Key Features

• High Accuracy: The MAX4001EUA+T offers a high level of accuracy in current sensing, which is critical for maintaining system reliability and performance.
• Low Power Consumption: With its low power requirements, this current-sense amplifier helps to extend battery life in portable applications, making it ideal for mobile devices and wireless sensors.
• Wide Input Common-Mode Range: The device is capable of operating over a wide common-mode voltage range, accommodating a variety of battery chemistries and configurations.
• Compact Package: The MAX4001EUA+T comes in a small 8-pin µMAX package, allowing for integration into designs where PCB real estate is at a premium.
• High-Side Current Sensing: This feature allows for the measurement of current in systems where the ground reference is not easily accessible, providing more flexibility in system design.

Applications

• Battery-powered devices
• Power management systems
• Portable consumer electronics
• Smart battery packs
• Overcurrent protection circuits

The MAX4001EUA+T is available in tape and reel packaging (denoted by the '+T'), facilitating automated assembly processes for high-volume production. It is designed to operate over the extended industrial temperature range, ensuring reliable performance in a wide array of environments.

With its combination of precision, low power consumption, and compact form factor, the MAX4001EUA+T from Maxim Integrated stands out as a superior choice for designers looking to implement accurate current sensing in their next project.