CASCADED RADAR SYSTEM WITH TRANSMITING-VEHICLE REFLECTION MITIGATION

Organization Name

NXP B.V.

Inventor(s)

Cristian Pavao Moriera of Frouzins (FR)

Julien Orlando of Toulouse (FR)

CASCADED RADAR SYSTEM WITH TRANSMITING-VEHICLE REFLECTION MITIGATION - A simplified explanation of the abstract

This abstract first appeared for US patent application 18598525 titled 'CASCADED RADAR SYSTEM WITH TRANSMITING-VEHICLE REFLECTION MITIGATION

The patent application describes a system and method for processing radar signals in a vehicle.

• First radar signal transmitted by a first transmitter with a first local oscillator signal.
• First received radar signal processed using a second local oscillator signal to generate a processed radar signal.
• Fast Fourier transform executed on the processed radar signal to generate a frequency-domain output signal.

Potential Applications: - Automotive radar systems - Collision avoidance systems - Autonomous driving technology

Problems Solved: - Enhancing radar signal processing accuracy - Improving vehicle safety measures

Benefits: - Increased accuracy in radar signal processing - Enhanced safety features in vehicles

Commercial Applications: Title: Advanced Radar Signal Processing System for Vehicles This technology can be utilized in the automotive industry for developing advanced radar systems for vehicles, enhancing safety features, and improving collision avoidance capabilities.

Questions about Radar Signal Processing: 1. How does the use of different local oscillator signals improve radar signal processing accuracy? - The use of different local oscillator signals allows for better processing of radar signals by offsetting frequencies to enhance accuracy.

2. What are the key benefits of executing a fast Fourier transform on processed radar signals? - Executing a fast Fourier transform helps generate a frequency-domain output signal, providing valuable insights into the radar data for further analysis and decision-making.

Original Abstract Submitted

A system and method for processing radar signals is presented. A first transmitted radar signal is transmitted by a first transmitter using a first local oscillator signal having a first frequency. The first transmitter is coupled to a structure of a vehicle. A first received radar signal is received using a first receiver. The first received radar signal is processed using a second local oscillator signal having a second frequency to generate a processed radar signal. The second frequency is offset from the first frequency by a predetermined offset value. An output signal is generated by executing a fast Fourier transform on the processed radar signal to generate a frequency-domain output signal.