Product Overview: HMC390LP4 from Analog Devices Inc.

The HMC390LP4 is a high-performance GaAs PHEMT MMIC Divide-by-4 Prescaler from Analog Devices Inc., which operates from 5 GHz to 15 GHz input frequency. This prescaler is an essential component in microwave frequency synthesizers, used to divide the frequency of the input signal to a lower frequency that can be used for various applications including phase-locked loops (PLLs), frequency synthesizers, and clock generation circuits. The HMC390LP4 is housed in a 4x4mm QFN leadless package, which makes it suitable for surface mount technology and ideal for integration into compact designs.

Key Features

• Wide Frequency Range: With an operational range of 5 GHz to 15 GHz, the HMC390LP4 is versatile and can be used in a broad spectrum of high-frequency applications.
• Low Power Consumption: The device is optimized for low power consumption, making it suitable for battery-powered and energy-efficient applications.
• High Isolation: Excellent input-to-output isolation is maintained, ensuring signal integrity and reducing the potential for feedback in the system.
• Robust Output Power: It delivers a consistent output power level, facilitating reliable performance in the downstream signal chain.

Applications

The HMC390LP4 is designed to cater to a wide array of high-frequency applications, including:

• Point-to-Point Radios
• Point-to-Multipoint Radios & VSAT
• Test Equipment & Sensors
• Military & Space
• Fixed Wireless Access
• Wireless Local Loop

Technical Specifications

Some of the key technical specifications of the HMC390LP4 include:

• Input Frequency Range: 5 - 15 GHz
• Output Frequency Range: 1.25 - 3.75 GHz
• Supply Voltage: +5V
• Output Power: +5 dBm typical
• Package: 4x4mm QFN leadless

The HMC390LP4 from Analog Devices Inc. stands out as a reliable and efficient solution for frequency division in high-frequency signal processing applications. Its combination of performance, efficiency, and compact form factor makes it a go-to choice for designers looking to maximize functionality while minimizing space and power requirements.