Patent application number | Description | Published |
20080278370 | RF-FRONTEND FOR A RADAR SYSTEM - An RF front-end includes an input configured to receive an oscillator signal, and an antenna port configured to transmit a transmission signal and receive a reception signal from an antenna. The RF front-end further includes a mixer having an RF-input configured to receive the reception signal, an oscillator input configured to receive a modified oscillator signal, and an output. The mixer is configured to mix the received signal into an intermediate frequency band or a base band using the oscillator signal. Also included is a directional coupler connected to the antenna port, the input for the oscillator signal, and the mixer. The coupler is configured to couple the oscillator signal as a transmission signal to the antenna via the antenna port, and couple the reception signal from the antenna to the RF-input of the mixer. Also included is a first phase shifter or a second phase shifter. The first phase shifter is configured to regulate a phase of the transmission signal, and the second phase shifter is configured to regulate a phase of the oscillator signal to form the modified oscillator signal supplied to the oscillator input of the mixer. | 11-13-2008 |
20080287085 | RF front-end for a radar system - An RF sender/receiver front-end is disclosed comprising a terminal for receiving an oscillator signal, at least one distribution unit for distributing the oscillator signal into different signal paths, two or more mixer-arrangements for sending a transmit-signal or for receiving an receive-signal, where each mixer-arrangement comprises a mixer and an amplifier for amplifying the oscillator signal and generating the transmit-signal. | 11-20-2008 |
20090189801 | RF-front-end for a radar system - An RF sender/receiver front-end is disclosed comprising a terminal for receiving an oscillator signal, at least one distribution unit for distributing the oscillator signal into different signal paths, two or more mixer-arrangements for sending a transmit-signal or for receiving an receive-signal, where each mixer-arrangement comprises a mixer and an amplifier for amplifying the oscillator signal and generating the transmit-signal. | 07-30-2009 |
20100093293 | RF Circuit with Improved Antenna Matching - In one embodiment, RF front-end circuit includes a tunable matching network having an input coupled to an RF interface port, a directional coupler with a first connection coupled to an RF input of a mixer, a second connection coupled to an RF signal generation port, and a third connection coupled to an output of the tunable matching network. The directional coupler is configured to direct a signal from the RF signal generation port to the tunable matching network and to direct a signal from the tunable matching network port to the RF port of the mixer. The RF front-end circuit also has a tunable matching network control unit coupled to the tunable matching network. The control unit is configured to optimize an impedance match between the RF interface port and the output of the tunable matching network. | 04-15-2010 |
20100225374 | LOW NOISE MIXER - One embodiment relates to a mixer for providing a mixed output signal. The mixer includes a radio-frequency (RF) stage, first and second power dividers, and first and second frequency-conversion stages. The RF stage includes a first differential pair. The first power divider is coupled to a first transistor of the first differential pair, and the second power divider is coupled to a second transistor of the first differential pair. The first frequency-conversion stage, which is adapted to provide a first converted-frequency signal, includes a second differential pair coupled to the second power divider and a third differential pair coupled to the first power divider. The second frequency-conversion stage, which is adapted to provide a second converted-frequency signal, includes a fourth differential pair coupled to the second power divider and a fifth differential pair coupled to the first power divider. Other techniques are also provided. | 09-09-2010 |
20110234292 | LOW NOISE MIXER - One embodiment relates to a mixer for providing a mixed output signal. The mixer includes a radio-frequency (RF) stage, first and second power dividers, and first and second frequency-conversion stages. The RF stage includes a first differential pair. The first power divider is coupled to a first transistor of the first differential pair, and the second power divider is coupled to a second transistor of the first differential pair. The first frequency-conversion stage, which is adapted to provide a first converted-frequency signal, includes a second differential pair coupled to the second power divider and a third differential pair coupled to the first power divider. The second frequency-conversion stage, which is adapted to provide a second converted-frequency signal, includes a fourth differential pair coupled to the second power divider and a fifth differential pair coupled to the first power divider. Other techniques are also provided. | 09-29-2011 |
20140187170 | System and Method for Testing a Radio Frequency Integrated Circuit - In an embodiment, a method of testing a radio frequency integrated circuit (RFIC) includes generating high frequency test signals using the on-chip test circuit, measuring signal levels using on-chip power detectors, and controlling and monitoring the on-chip test circuit using low frequency signals. The RFIC circuit is configured to operate at high frequencies, and an on-chip test circuit that includes frequency generation circuitry configured to operate during test modes. | 07-03-2014 |
Patent application number | Description | Published |
20090023405 | RF Front-End Circuitry with Reduced DC Offset - An RF front-end circuit includes a directional coupler, a mixer, and a reflection circuit. The directional coupler is adapted to receive an antenna signal and an oscillator signal. The mixer is coupled to the directional coupler to receive the antenna signal and is further adapted to receive a mixer signal and to generate an output signal related to the antenna signal and the mixer signal. The reflection circuit is coupled to the directional coupler to receive the oscillator signal and is adapted to reflect at least a portion of the oscillator signal to the mixer via the directional coupler to counteract a parasitic portion of the oscillator signal received at the mixer. | 01-22-2009 |
20100312518 | Integrated Circuit Arrangement - An integrated circuit arrangement has a signal input | 12-09-2010 |
20120229330 | RF Circuit with Improved Antenna Matching - In one embodiment, RF front-end circuit includes a tunable matching network having an input coupled to an RF interface port, a directional coupler with a first connection coupled to an RF input of a mixer, a second connection coupled to an RF signal generation port, and a third connection coupled to an output of the tunable matching network. The directional coupler is configured to direct a signal from the RF signal generation port to the tunable matching network and to direct a signal from the tunable matching network port to the RF port of the mixer. The RF front-end circuit also has a tunable matching network control unit coupled to the tunable matching network. The control unit is configured to optimize an impedance match between the RF interface port and the output of the tunable matching network. | 09-13-2012 |
20120326919 | RADAR SENSOR HAVING INTERFERENCE SIGNAL COMPENSATION - Radar sensor having a mixer for mixing a received signal with a reference signal and having a device for compensating interference signals which would overload the mixer, wherein the device for compensating the interference signals has an adjustable reflection point at the reference input of the mixer. | 12-27-2012 |
20130070868 | Low-Loss, Broad Band, LC I/Q Phase Shifter - Some embodiments relate to a phase shifter that includes an I/Q phase shifter and at least one LC balun. Compared to conventional phase shifters, phase shifter has primarily only LC components, thereby limiting losses relative to conventional solutions. In one embodiment, for example, a phase shifter shows a large bandwidth at 77 GHz center frequency (e.g., 1 dB amplitude error bandwidth is approximately 40 GHz; 1° phase error bandwidth is about 16.5 GHz). The inductors included in phase shifter, in contrast to the quarter wave transmission lines used in conventional phase shifters, reduces chip area compared with conventional solutions. In some embodiments, an emitter follower helps to provide a relatively constant output that is largely independent of temperature, input power, VCC, manufacturing variation, and so on. | 03-21-2013 |
20130088383 | Automotive Radar Transmitter Architecture - One embodiment of the present invention relates to a radar transmitter comprised within a single integrated chip substrate, which is capable of continuous beam steering of a transmitted radar beam as well as an option to change the physical position of the origin of the transmit radar beam. The radar transmitter has a signal generator that generates an RF signal. The RF signal is provided to a plurality of independent transmission chains, which contain independently operated vector modulators configured to introduce an individual phase adjustment to the high frequency input signal to generate separate RF output signals. A control unit is configured to selectively activate a subset of (e.g., two or more) the independent transmission chains. By activating the subset of independent transmission chains to generate RF output signals with separate phases, a beam steering functionality is enabled. Furthermore, the subset defines a changeable position of the transmitted radar beam. | 04-11-2013 |