| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 342194000 | Complex signal (in phase and quadrature) | 15 |
| 20090015464 | SPREAD SPECTRUM RADAR APPARATUS - A spread spectrum radar apparatus includes: a transmission unit which generates a spread signal that is a spectrum-spread signal, using a first oscillator signal, a second oscillator signal, and a transmission PN code, and which emits the spread signal as a detection radio wave; and a reception unit which receives, as a reception signal, the detection radio wave reflected from an object, and which generates an intermediate frequency signal by despreading the reception signal based on the first oscillator signal and a reception PN code obtained by delaying the transmission PN code. | 01-15-2009 |
| 20090085798 | METHOD AND SYSTEM FOR OBTAINING IN-PHASE AND QUADRATURE COMPONENTS OF A SIGNAL - A method of obtaining in-phase and quadrature phase components for a narrowband signal is provided. The method includes digitally sampling a narrowband signal at a digital sampling rate to obtain a number of data points. The method subtracts a first portion of the data points corresponding to a first half of one period of the signal from a second portion of the data points corresponding to a second half of the one period of the signal to obtain a number of output data points which is less than the number of data points obtained from sampling the narrowband signal. | 04-02-2009 |
| 20090091491 | RECEIVING DEVICE FOR SPREAD SPECTRUM RADAR APPARATUS - Provided is a receiving device that is used for a spread spectrum radar apparatus, receives a spectrum-spread signal, and obtains a precise radar spectrum, and includes: a despreading unit that (i) generates first and second despread signals that are generated by despreading a reception signal using a pseudo-noise code, the second despread signal passing through a transmission line carrying a current having a current value identical to a current value of a current carried by a transmission line through which the first despread signal passes, and (ii) includes a first transistor pair including first and second transistors having an identical characteristic, the first transistor outputting the first despread signal, and the second transistor outputting the second despread signal; and a quadrature demodulating unit that generates an in-phase signal and a quadrature signal by quadrature-demodulating the first despread signal and the second despread signal, respectively. | 04-09-2009 |
| 20090195442 | Method and Apparatus for Creating and Processing Universal Radar Waveforms - A new approach to radar imaging is described herein, in which radar pulses are transmitted with an uneven sampling scheme and subsequently processed with novel algorithms to produce images of equivalent resolution and quality as standard images produced using standard synthetic aperture radar (SAR) waveform and processing techniques. The radar data collected with these waveforms can be used to create many other useful products such as moving target indication (MTI) and high resolution terrain information (HRTI). The waveform and the correction algorithms described herein allow the algorithms of these other radar products to take advantage of the quality Doppler resolution. | 08-06-2009 |
| 20090207072 | QUADRATURE RADAR APPARATUS - A quadrature radar apparatus includes a quadrature signal generating unit, a plurality of coupler modules connected to the signal generating unit, an antenna unit receiving transmission signals from the coupler modules and a reception signal reflected from a target, one or more phase delay modules connected between one or more of the coupler modules and the antenna unit to delay the phases of the transmission and reception signals by 90 degrees, a leakage signal canceling unit combining the reception signals inputted from the antenna unit through the first and second coupler modules and removes the transmission leakage signal. | 08-20-2009 |
| 20100302092 | METHOD AND APPARATUS FOR CREATING AND PROCESSING UNIVERSAL RADAR WAVEFORMS - A new approach to radar imaging is described herein, in which radar pulses are transmitted with an uneven sampling scheme and subsequently processed with novel algorithms to produce images of equivalent resolution and quality as standard images produced using standard synthetic aperture radar (SAR) waveforms and processing techniques. The radar data collected with these waveforms can be used to create many other useful products such as moving target indication (MTI) and high resolution terrain information (HRTI). The waveform and the correction algorithms described herein allow the algorithms of these other radar products to take advantage of the quality Doppler resolution. | 12-02-2010 |
| 20120242538 | Radar sensor having two oscillators, two i/q transmit mixers, and two i/q receive mixers - A radar sensor for motor vehicles, having a transmitting part, which has two oscillators and a 90° phase shifter for generating a transmission signal, a first comparison signal, and a second comparison signal, which is phase shifted by 90° with respect to the first comparison signal, and a receiving part having an I mixer for mixing a received signal with the first comparison signal and a Q mixer for mixing the received signal with the second comparison signal, in which the transmitting part has a first transmit mixer, whose inputs are directly connected to the two oscillators, and a second transmit mixer, whose one input is directly connected to a first of the two oscillators and whose other input is connected via the phase shifter to the other oscillator. | 09-27-2012 |
| 20130044023 | Pseudosynchronizer for an Unsynchronized Bistatic Radar System - Methods and systems for post processing synchronization of bistatic radar data are disclosed. A transmitter is configured to transmit pulses at a first rate controlled by a first local oscillator. A receiver is configured to receive pulses at a second rate controlled by a second oscillator. A processing device is configured to synchronize, with respect to the first rate, in-phase quadrature data received from the receiver using a keystone formatting technique. | 02-21-2013 |
| 20130106648 | SHORT-RANGE HOMODYNE RADAR SYSTEM | 05-02-2013 |
| 20130120186 | DELAY LOCKED LOOP - A method for providing a plurality of narrow pulses is provided. A first pulse having a first width is received by a delay line having a plurality of delay cells. This first pulse has a first width. In response to this first pulse, a plurality of second pulses is generated by the delay line, where each second pulse has a second width that is less than the first width. First and second delay pulses are also generated by the delay line, and a delay for each delay cell in the delay line can then be adjusted if a rising edge of the second delay pulse is misaligned with a falling edge of the first delay pulse. | 05-16-2013 |
| 20130293411 | PHASED-ARRAY RECEIVER, RADAR SYSTEM AND VEHICLE - A phased-array receiver comprises a plurality of analog beamforming receive channels, each comprising an antenna element arranged to receive a radio frequency signal and a channel output arranged to provide an analog channel output signal. At least one of the plurality of analog beamforming receive channels comprises an in-phase downconversion mixing circuit connected to the antenna element and a local oscillator source and arranged to provide a downconverted in-phase signal to a phase rotation circuit, and a quadrature downconversion mixing circuit connected to the antenna element and the local oscillator source and arranged to provide a downconverted quadrature signal to the phase rotation circuit. The phase rotation circuit is arranged to provide to the channel output a phase-shifted analog output signal generated from the downconverted in-phase signal and the downconverted quadrature signal. | 11-07-2013 |
| 20150369903 | ACTIVE IQ AND QUADRATURE GENERATOR FOR HIGH FREQUENCY APPLICATIONS - An active I/Q generator circuit comprises an input node for receiving a reference oscillation signal. The circuit has an I-output and a Q-output for respectively outputting an I-signal and a Q-signal. A first active component is electrically coupled to the input node and arranged to amplify the reference oscillation signal and to output an amplified reference oscillation signal. A second active component is electrically coupled to the first active component to receive the amplified reference oscillation signal. The second active component is arranged to generate, based on the amplified reference oscillation signal, an in-phase signal and a, with respect to the in-phase signal, phase shifted signal, the second active component electrically coupled to the in-phase signal output for providing the in-phase signal and electrically coupled to the quadrature-phase output for providing the phase-shifted signal. | 12-24-2015 |
| 20150378008 | RADAR APPARATUS MOUNTED ON A VEHICLE - A radar apparatus which includes a transmitting unit, a receiving unit, an I signal generating circuit, a Q signal generating circuit, a peak detecting circuit, a target detecting unit, and a distortion judging unit. The transmitting unit transmits a radar wave which is frequency-modulated along a time axis in a specified cycle, and the receiving unit receives an incoming wave which is a reflected wave of the radar wave transmitted by the transmitting means and amplifies it in an amplifier. The I signal generating circuit generates an I signal which is a real number component of a beat signal by mixing the incoming wave received and amplified by the receiving means with the radar wave transmitted by the transmitting unit. The Q signal generating circuit generates a Q signal which is an imaginary number component of a beat signal by mixing the incoming wave received and amplified by the receiving unit with the radar wave transmitted by the transmitting unit with a phase being shifted by π/2 [rad]. | 12-31-2015 |
| 20160077195 | Radar imaging via spatial spectrum measurement and MIMO waveforms - The proposed MIMO radar imaging method takes advantages of measurement techniques of spatial frequency components of an RF area image from radar returns. To minimize size, weight and power (SW&P), minimum redundancy arrays (MRAs) for both Tx and Rx with unique geometries are proposed. MIMO waveforms are utilized to index the radiated illuminations to a targeted area in the forms of 1-D spatial frequency components. Consequently, the corresponding radar returns from the targeted field of view (FOV) are captured by the Rx MRA. With the knowledge of uniquely designed MRA array geometries, virtual beams are synthesized in Rx processor; usually one Tx and many contiguous Rx fan beams. These virtual beams may be dynamically “moved” to different beam positions. The elongated beam direction for Tx fan beam and that for Rx fan beams are perpendicular to one another. Thus intersections of the Tx fan-beam and many Rx fan-beams are the very areas of radar returns. We refer those areas as virtual beam crosses. Conventional range and Doppler gating processing shall then be applied to the beam crosses concurrently. Radar return pixel-by-pixel within various beam crosses are measured individually. Radar images can then be synthesized. | 03-17-2016 |
| 20160131741 | APPARATUS AND METHOD FOR FORMING BEAM FOR PROCESSING RADAR SIGNAL - An apparatus and method for forming a beam for processing a radar signal is provided. In order to form a beam, by processing signals that are received through a plurality of antennas, a first symbol signal and a second symbol signal, which are complex signals are generated. The first and second symbol signals include a plurality of symbols that are arranged in an antenna array order. By applying a weight value on each antenna basis and a window coefficient for windowing processing to sequentially input each symbol of the first and second symbol signals, and by accumulating on a beam basis to generate, a beam symbol signal is generated. | 05-12-2016 |
