The present embodiments relate to a radar signal processing apparatus and a signal processing method thereof in which an additional beamforming is performed by reflecting an angle of a target that is positioned in front of the vehicle or by reflecting a surrounding clutter situation thereof in order to thereby improve the performance of detecting the target in front of the vehicle. According to an embodiment, a radar signal processing apparatus may include: a transmitting unit configured to transmit radar signals forward from the vehicle; a receiving unit configured to receive reflected signals among the radar signals transmitted by the transmitting unit; and a signal processing unit configured to extract a target in front of the vehicle based on the signals received by the receiving unit, wherein the receiving unit receives the radar signals by using an antenna array including a plurality of receiving antennas, the signal processing unit integrates the signals received by the plurality of receiving antennas to perform the beamforming for obtaining a desired gain, and, if there is no target in the formed beams, determines the angle of the target in front of the vehicle in order to thereby perform the additional beamforming to match the determined target angle.

The present embodiments relate to a radar signal processing apparatus and a signal processing method thereof in which an additional beamforming is performed by reflecting an angle of a target that is positioned in front of the vehicle or by reflecting a surrounding clutter situation thereof in order to thereby improve the performance of detecting the target in front of the vehicle. According to an embodiment, a radar signal processing apparatus may include: a transmitting unit configured to transmit radar signals forward from the vehicle; a receiving unit configured to receive reflected signals among the radar signals transmitted by the transmitting unit; and a signal processing unit configured to extract a target in front of the vehicle based on the signals received by the receiving unit, wherein the receiving unit receives the radar signals by using an antenna array including a plurality of receiving antennas, the signal processing unit integrates the signals received by the plurality of receiving antennas to perform the beamforming for obtaining a desired gain, and, if there is no target in the formed beams, determines the angle of the target in front of the vehicle in order to thereby perform the additional beamforming to match the determined target angle.

A wireless ranging system generates, at a first device, a first plurality of counts, each of the first plurality of counts indicative of a transmit time of a corresponding packet, and further generates a second plurality of counts, each of the second plurality of counts indicative of a receive time of a corresponding packet. In response to a number of samples of the first plurality of counts exceeding a threshold, the system generates a plurality of timestamps based on the first plurality of counts and the second plurality of counts and generates a plurality of time-of-flight values based on the plurality of timestamps. Based on a combination of the plurality of the time-of-flight values, the wireless ranging system generates an effective time-of-flight value and identifies a distance between the first device and as second device based on the effective time-of-flight value.

A wireless ranging system generates, at a first device, a first plurality of counts, each of the first plurality of counts indicative of a transmit time of a corresponding packet, and further generates a second plurality of counts, each of the second plurality of counts indicative of a receive time of a corresponding packet. In response to a number of samples of the first plurality of counts exceeding a threshold, the system generates a plurality of timestamps based on the first plurality of counts and the second plurality of counts and generates a plurality of time-of-flight values based on the plurality of timestamps. Based on a combination of the plurality of the time-of-flight values, the wireless ranging system generates an effective time-of-flight value and identifies a distance between the first device and as second device based on the effective time-of-flight value.

Disclosed is a pulse radar apparatus including a clock generator generating a transmission clock signal, a reception clock signal, and a sensitivity adjustment interval signal, a transmitter radiating a transmission pulse based on the transmission clock signal, and a receiver receiving a first pulse and a second pulse, which are associated with the transmission pulse, with different sensitivities based on the reception clock signal and the sensitivity adjustment interval signal.

Disclosed is a pulse radar apparatus including a clock generator generating a transmission clock signal, a reception clock signal, and a sensitivity adjustment interval signal, a transmitter radiating a transmission pulse based on the transmission clock signal, and a receiver receiving a first pulse and a second pulse, which are associated with the transmission pulse, with different sensitivities based on the reception clock signal and the sensitivity adjustment interval signal.

A radar signal processing system with a self-interference cancelling function includes an analog front end (AFE) processor, an analog to digital converter (ADC), an adaptive interference canceller (AIC), and a digital to analog converter (DAC). The AFE processor receives an original input signal and generates an analog input signal. The ADC converts the analog input signal to a digital input signal. The AIC generates a digital interference signal digital interference signal by performing an adaptive interference cancellation process according to the digital input signal. The DAC converts the digital interference signal to an analog interference signal. Finally, the analog interference signal is fed back to the AFE and cancelled from the original input signal in the AFE processor while performing the front end process, reducing the interference of the static interference from the leaking of a close-by transmitter during the front end process.

A radar signal processing system with a self-interference cancelling function includes an analog front end (AFE) processor, an analog to digital converter (ADC), an adaptive interference canceller (AIC), and a digital to analog converter (DAC). The AFE processor receives an original input signal and generates an analog input signal. The ADC converts the analog input signal to a digital input signal. The AIC generates a digital interference signal digital interference signal by performing an adaptive interference cancellation process according to the digital input signal. The DAC converts the digital interference signal to an analog interference signal. Finally, the analog interference signal is fed back to the AFE and cancelled from the original input signal in the AFE processor while performing the front end process, reducing the interference of the static interference from the leaking of a close-by transmitter during the front end process.

A method for operating a stepped frequency radar system is disclosed. The method involves receiving digital frequency control signals that correspond to different frequencies of radio frequency (RF) signals, and performing stepped frequency scanning across a frequency range using at least one transmit antenna and a two-dimensional array of receive antennas and RF signals at the different frequencies that correspond to the digital frequency control signals.

A method for operating a stepped frequency radar system is disclosed. The method involves receiving digital frequency control signals that correspond to different frequencies of radio frequency (RF) signals, and performing stepped frequency scanning across a frequency range using at least one transmit antenna and a two-dimensional array of receive antennas and RF signals at the different frequencies that correspond to the digital frequency control signals.