Maxim Integrated MAX2180ETG+ Low-Noise Amplifier

The MAX2180ETG+ from Maxim Integrated is a state-of-the-art low-noise amplifier (LNA) designed to optimize the performance of automotive remote keyless entry (RKE), garage door openers, and other low-frequency receiver applications. This versatile LNA is specifically engineered to operate within the 315MHz or 433.92MHz frequency bands, providing a robust solution for systems that require high sensitivity and reliability.

Key Features

• Operational frequency: 315MHz and 433.92MHz bands
• Low noise figure: Ensures clear signal reception and amplification
• High gain: Maximizes the received signal strength for improved system range
• Adjustable current and gain: Offers design flexibility to meet specific application needs
• Integrated shutdown feature: Provides power-saving capabilities for battery-operated devices
• Temperature range: -40°C to +125°C, suitable for harsh automotive environments
• Package: 24-pin TQFN with exposed pad for enhanced thermal performance

Applications

Designed with automotive and industrial applications in mind, the MAX2180ETG+ can be used in a variety of systems that require high-quality signal amplification, such as:

• Automotive RKE systems
• Garage door opener receivers
• Low-frequency ISM band applications
• Wireless security systems

Performance and Quality

The MAX2180ETG+ is built with Maxim Integrated's commitment to quality and performance. It offers a seamless integration for designers looking to enhance their receiver sensitivity without compromising on power consumption. The LNA's low noise figure and high gain attributes are pivotal in achieving long-range communication capabilities in various wireless applications. Additionally, the product's robust temperature range and integrated shutdown feature make it an excellent choice for energy-conscious designs that must operate reliably in fluctuating environmental conditions.

For detailed technical specifications, application notes, and design resources, visit Maxim Integrated's official website or contact their support team for assistance.