DETERMINING A MAGNITUDE OF A COMPOSITE ZERO-FORCING EQUALIZER

Organization Name

Lenovo (Singapore) Pte. Ltd.

Inventor(s)

Colin D. Frank of Park Ridge IL (US)

DETERMINING A MAGNITUDE OF A COMPOSITE ZERO-FORCING EQUALIZER - A simplified explanation of the abstract

This abstract first appeared for US patent application 18563093 titled 'DETERMINING A MAGNITUDE OF A COMPOSITE ZERO-FORCING EQUALIZER

The abstract of this patent application describes a method for determining the magnitude of a composite zero-forcing equalizer by measuring frequency responses at antenna connectors and calculating the inverse of these responses.

• The method involves measuring the first frequency response at the first antenna connector and determining the first zero-forcing equalizer as the inverse of this response.
• It also includes measuring the second frequency response at the second antenna connector and determining the second zero-forcing equalizer as the inverse of this response.
• The magnitude of the composite zero-forcing equalizer is then calculated as the square root of a weighted combination of the squares of the magnitudes of the first and second equalizers.
• The weight applied for each antenna connector is based on the power measured at that connector.

Potential Applications: - This technology can be used in wireless communication systems to improve signal processing and data transmission. - It can enhance the performance of antennas in various devices such as smartphones, routers, and IoT devices.

Problems Solved: - This technology addresses the challenge of optimizing equalizers in wireless communication systems to improve signal quality and reliability.

Benefits: - Improved signal processing efficiency - Enhanced data transmission quality - Increased reliability of wireless communication systems

Commercial Applications: Title: Advanced Signal Processing Technology for Wireless Communication Systems This technology can be utilized in the telecommunications industry to enhance the performance of wireless networks, improve data transmission speeds, and optimize signal processing for better connectivity.

Questions about the technology: 1. How does this technology improve the performance of wireless communication systems? - This technology enhances signal processing efficiency and data transmission quality in wireless communication systems, leading to improved overall performance.

2. What are the potential applications of this technology beyond wireless communication systems? - This technology can also be applied in various devices such as smartphones, routers, and IoT devices to optimize antenna performance and improve signal processing.

Original Abstract Submitted

Apparatuses, methods, and systems are disclosed for determining a magnitude of a composite zero-forcing equalizer. One method includes measuring a first frequency response at a first antenna connector. The method includes determining a first zero-forcing equalizer for the first antenna connector as an inverse of the first frequency response. The method includes measuring a second frequency response at a second antenna connector. The method includes determining a second zero-forcing equalizer for the second antenna connector as an inverse of the second frequency response. The method includes determining a magnitude of a composite zero-forcing equalizer as a square root of a weighted combination of squares of magnitudes of the first zero-forcing equalizer and the second zero-forcing equalizer. A first weight applied for the first antenna connector is a square of a first power measured at the first antenna connector.