The disclosure relates to a radar system comprising multiple synchronized transceivers. Example embodiments include a radar system (200, 300) comprising: a plurality of radar transceiver units (202a-c), each configured to operate according to a low frequency clock signal (204), and configured to generate an intermediate frequency signal (407) and a modulated high frequency signal (419) for transmitting and receiving radar signals; and a microcontroller unit (201) configured to provide control signals to each transceiver unit (202a-c) to synchronize operation thereof, wherein each radar transceiver unit (202a-c) is configured to provide received radar data (RX.sub.1-N) and a monitoring signal (203a-c) to the microcontroller unit (201), the monitoring signal (203a-c) derived by frequency dividing and combining the modulated high frequency signal and intermediate frequency signal, and wherein the microcontroller unit (201) is configured to derive and compensate for phase and frequency differences between the received radar data (RX.sub.1-N) from each transceiver (202a-c) based on the monitoring signals (203a-c) provided by each transceiver unit (202a-c).

An electronic control unit for radar sensors, in particular for driver assistance systems in motor vehicles, including an integrated component for generating and processing high-frequency signals, and a controller for controlling functions of this component, including monitoring functions for monitoring the operability of the radar sensor, characterized by an error injector integrated into the component for generating defined error conditions for a functional test of the monitoring functions.

A method includes generating a first radar signal in a transmission channel of a first radar chip based on an oscillator signal and emitting the first radar signal via a first antenna, wherein the first radar signal is modulated based on a synchronization signal used in the first radar chip, generating a second radar signal in a transmission channel of a second radar chip based on the oscillator signal and emitting the second radar signal via a second antenna, wherein the second radar signal is modulated based on a synchronization signal used in the second radar chip, receiving an RF sensor signal by means of a sensor circuit, wherein the RF sensor signal has a superposition of a portion of the power of the first radar signal and a portion of the power of the second radar signal, and determining a measurement signal that depends on the RF sensor signal.

An integrated circuit (IC) is provided with a plurality of diode based mm-wave peak voltage detectors (PVD)s. During a testing phase, a multi-point low frequency calibration test is performed on one or more of the PVDs to determine and store a set of alternating current (AC) coefficients. During operation of the IC, a current-voltage sweep is performed on a selected one of the PVDs to determine a process and temperature direct current (DC) coefficient. A peak voltage produced by the PVD in response to a high frequency radio frequency (RF) signal is measured to produce a first measured voltage. An approximate power of the RF signal is calculated by adjusting the first measured voltage using the DC coefficient and the AC coefficient.

The present invention is directed to an antenna system and a method that is configured to compute calibration element voltage gain patterns as functions of a digital antenna model and a plurality of complex beamformer voltages, determine calibration through path transfer functions from the plurality of complex voltages, and remove the calibration element voltage gain patterns from the calibration through path transfer functions to determine a beamforming network transfer function. The beamforming network transfer function and the far-field element voltage gain patterns are combined to obtain a system transfer function used to revise a calibration table.

A method is proposed for determining at least one calibration parameter for a radar system having a first radar transceiver and a second radar transceiver. The method includes performing a first calibration measurement and a second calibration measurement. The first calibration measurement and the second calibration measurement both include generating a first frequency-modulated oscillation signal and a second frequency-modulated oscillation signal, and combining the first oscillation signal received via the second terminal with the second oscillation signal, in order to generate a first difference signal for the first calibration measurement and a second difference signal for the second calibration measurement, both having a frequency difference between the first oscillation signal and the second oscillation signal. The method also includes determining the at least one calibration parameter based on the two difference signals generated for the first calibration measurement and for the second calibration measurement.

A level gauge for detecting process variables related to a distance to a surface of a content in a tank, includes a first and second functionally independent circuitry arrangements comprising transceiver circuitry and processing circuitry. The gauge further comprises a power divider providing isolation between signals having the same propagation mode, a single wire transmission line probe, and a matching arrangement providing an electrically matched connection between the electrical connection of a process seal and the single wire transmission line probe. A combination of a power divider with a matching arrangement allows multiple channels on one single wire transmission line probe.

In a radar system, a cancellation circuit is described for compensating for the effects of spillover between each transmitter and a receiver. The cancellation circuit is configured for applying cancellation signals to the receiver which are generated in a cancellation filter utilizing a primary impulse response characteristic corresponding to the spillover, a signal to be transmitted from each transmitter in the radar system, and a range profile output from the receiver. The cancellation circuit may also include a secondary impulse response characteristic module and a dithering module to improve the sensitivity of the receiver.

A transceiver includes a transmitter, a frequency synthesizer coupled to the transmitter, a receiver coupled to the frequency synthesizer and a voltage sensor; and a digital controller coupled to the voltage sensor, the receiver, and the transmitter, wherein based on a DC voltage measurement of an IF signal made by the voltage sensor, a relative phase adjustment occurs of a relative phase associated with a local oscillator (LO) port and a radio frequency (RF) port of the receiver.

A radar device for the transmission of a signal in a frequency band. The radar device includes a control means and an oscillator. The input of the oscillator is connected to the control means by means of a converter. The oscillator is controllable by means of the control means for the generation of the signal. The signal is generated by means of the oscillator and can be picked up on an output of the oscillator. The radar device also includes at least one transmission aerial for the transmission of the signal being present at the output of the oscillator. The transmission aerial is connected to the output of the oscillator. At least one receiver channel is provided for the reception of a received signal and for the processing of the received signal and for the transmission of the processed received signal to the control means. The receiver channel has at least one receiving aerial and a mixer for the mixing of the received signal with the signal which is present at the output of the oscillator. The mixer is connected to the output of the oscillator, and the output of the oscillator is connected to an input of a switchable amplifier and the amplifier provides a signal at the output and transmits it to the at least one mixer. A wattmeter is provided, which monitors the signal at the output of the amplifier and transmits it to the control means.