Maxim Integrated MAX1104EUA+ Product Overview

The MAX1104EUA+ is a high-performance, low-power, 14-bit analog-to-digital converter (ADC) from Maxim Integrated, designed to deliver precision and efficiency for a wide range of applications. This compact ADC comes in an 8-pin µMAX package, making it ideal for space-constrained applications without compromising on functionality.

With its advanced design, the MAX1104EUA+ offers an impressive sampling rate of up to 200ksps (kilo-samples per second), allowing for accurate and rapid conversion of analog signals to digital data. This makes it suitable for use in medical instruments, industrial control systems, and data acquisition devices where precise measurements are critical.

Key Features

• High Resolution: The device boasts a 14-bit resolution, providing fine detail in the digital representation of the analog input signal.
• Single-Supply Operation: It operates from a single 2.7V to 3.6V power supply, simplifying power management in embedded systems.
• Low Power Consumption: The MAX1104EUA+ is designed for low-power operation, consuming just 1.1mA at the full sampling rate, which is ideal for battery-powered and portable devices.
• Internal Reference: An integrated reference voltage simplifies the design by eliminating the need for external components.
• Flexible Input Range: The input range is programmable, allowing users to optimize the converter for their specific signal levels.
• No Pipeline Delay: The ADC features no pipeline delay, also known as latency, which is crucial for control loop and real-time applications.

Applications

The versatility of the MAX1104EUA+ makes it an excellent choice for a variety of applications, including:

• Portable Instrumentation
• Data Acquisition Systems
• Medical Devices
• Industrial Process Control
• Battery-Powered Devices

In summary, the MAX1104EUA+ from Maxim Integrated is a robust and precise ADC offering high resolution and speed in a small package, making it a top choice for designers seeking to balance performance with space and power constraints.