A method for sampling an Ultra Wide Band signal comprising a step of prearranging a GPR antenna comprising at least one transmitter and one receiver, a variable-gain amplifier, or VGA, a A/D converter and a control unit. The method then comprises the steps of transmitting and receiving a primary Ultra Wide Band signal by the GPR antenna and sampling values of the primary signal relative to a first full-scale portion by the A/D converter. The method also comprises the steps of transmitting and receiving at least one secondary Ultra Wide Band signal by the GPR antenna, amplifying said or each secondary signal by the variable-gain amplifier, and sampling values of said or each secondary signal relative to full-scale portions different from the first portion by the A/D converter.

A method for sampling an Ultra Wide Band signal comprising a step of prearranging a GPR antenna comprising at least one transmitter and one receiver, a variable-gain amplifier, or VGA, a A/D converter and a control unit. The method then comprises the steps of transmitting and receiving a primary Ultra Wide Band signal by the GPR antenna and sampling values of the primary signal relative to a first full-scale portion by the A/D converter. The method also comprises the steps of transmitting and receiving at least one secondary Ultra Wide Band signal by the GPR antenna, amplifying said or each secondary signal by the variable-gain amplifier, and sampling values of said or each secondary signal relative to full-scale portions different from the first portion by the A/D converter.

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.

Example embodiments relate to radar transceivers. One embodiment includes a radar transceiver. The radar transceiver includes a chirp generator for generating a chirp having an initial frequency and a final frequency. The radar transceiver also includes a controllable variable gain amplifier having an input connected to an output of the chirp generator. Further, the radar transceiver includes a control unit connected to a control input on the chirp generator and to a control input on the controllable variable gain amplifier. The control unit is adapted to output a first control signal to the chirp generator such that the chirp generator starts generating the chirp. The control unit is also adapted to output a second control signal to the controllable variable gain amplifier such that the controllable variable gain amplifier starts increasing an amplification in the controllable variable gain amplifier from a first amplification level to a second amplification level.

Example embodiments relate to radar transceivers. One embodiment includes a radar transceiver. The radar transceiver includes a chirp generator for generating a chirp having an initial frequency and a final frequency. The radar transceiver also includes a controllable variable gain amplifier having an input connected to an output of the chirp generator. Further, the radar transceiver includes a control unit connected to a control input on the chirp generator and to a control input on the controllable variable gain amplifier. The control unit is adapted to output a first control signal to the chirp generator such that the chirp generator starts generating the chirp. The control unit is also adapted to output a second control signal to the controllable variable gain amplifier such that the controllable variable gain amplifier starts increasing an amplification in the controllable variable gain amplifier from a first amplification level to a second amplification level.

The disclosure relates to a radar control device and method. Specifically, according to the disclosure, a radar control device comprises a transceiver transmitting a first transmission signal, receiving a first reception signal reflected by an object, and mixing and transmitting the first transmission signal and a second transmission signal having a center frequency different from the first transmission signal based on the first transmission signal, a generator producing a discrete signal by passing the first transmission signal and the first reception signal through a mixer and sampling the first transmission signal and the first reception signal and generating a window for compensation based on a required time and a modulation band set in the second transmission signal, and a producer producing the compensation signal based on the discrete signal and the window for compensation.

The disclosure relates to a radar control device and method. Specifically, according to the disclosure, a radar control device comprises a transceiver transmitting a first transmission signal, receiving a first reception signal reflected by an object, and mixing and transmitting the first transmission signal and a second transmission signal having a center frequency different from the first transmission signal based on the first transmission signal, a generator producing a discrete signal by passing the first transmission signal and the first reception signal through a mixer and sampling the first transmission signal and the first reception signal and generating a window for compensation based on a required time and a modulation band set in the second transmission signal, and a producer producing the compensation signal based on the discrete signal and the window for compensation.

The present invention may provide a device and a method for detecting and diagnosing sleep apnea, which can accurately determine an apnea state by: extracting a respiration signal of an examinee from a received signal which is a reflection of an impulse signal emitted from at least one IR-UWB radar; setting a threshold value for determining an apnea state from changes in the deviation and interval between peaks of the extracted respiration signal; and comparing the set threshold value with the deviation between the peaks. Therefore, the sleep apnea can be accurately detected and diagnosed using a non-contact/noninvasive method, and thus inconvenience felt by the examinee can be reduced.

The present disclosure relates to a method for cancelling spillover in a MIMO radar system. The method comprises (i) transmitting and receiving a signal in a transmit-receive pair, the received signal including a spillover signal; (ii) routing a part of the transmitted signal of the transmit-receive pair to the received signal to increase the power level of the spillover signal; and (iii) cancelling the spillover signal and the part of the transmitted signal by a spillover cancellation subsystem associated with the transmit-receive pair. Because the part of the transmitted signal corresponds to the spillover signal, both of these signals may be added together to result in a combined signal having a high enough power level to improve the functioning of the spillover cancellation subsystem.