| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | Apparatus for controlling distance between cars | JP7962090 | 1990-03-28 | JPH03277988A | 1991-12-09 | KAJIWARA YASUNARI |
| PURPOSE: To certainly track the preceding car and to control the distance between cars by tracking an object while the image of the object in a window is caught by a tracking type range finder and calculating the positional shift corresponding to the object in the window of left and right image. CONSTITUTION: An object 9 is tracked while the image of the object 9 in a window formed in the taken image of an image sensor is caught through a pair of left and right optical systems by a tracking type range finder 21 and the distance up to the object 9 is measured from the positional shift corresponding to the object 9 in the window of the left and right images thereof. Range finders 22a, 22b as monitor means emit lights to detect the intruding car of a short distance. A control apparatus 4 allows a vehicle to run while holds the distance between cars corresponding to car speed on the basis of the signal from the range finder 21 and the signal from a car speed sensor 7. When there is an intruding vehicle 23, an alarm is issued at an early stage on the basis of the signals due to the range fingers 22a, 22b and a driver can certainly take a measure. COPYRIGHT: (C)1991,JPO&Japio | ||||||
| 42 | 자동차의 인테리어 트림 부분 상의 검출 범위 내의 물체를 검출하기 위한 검출 장치, 자동차 및 대응 방법 | KR1020157012022 | 2013-11-07 | KR101746308B1 | 2017-06-12 | 쿤츠다니엘; 쇼흐라르스; 시모니스칼; 윌트마르쿠스 |
| 본발명은자동차의인테리어트림부분(17) 상에서및/또는위에서, 인테리어트림부분내에형성된출구개구의영역내에위치된물체(16)를검출하기위한검출장치(1)에관한것이며, 여기서검출장치(1)는물체(16)가검출장치(1)의검출방향에서검출가능한검출범위(2)를갖고, 검출방향은출구개구의개구평면에적어도실질적으로평행하게연장된다. | ||||||
| 43 | 이형물 검출 시스템 및 검출 방법 | KR1020147029808 | 2013-03-25 | KR1020140147863A | 2014-12-30 | 짐달즈,데이비드 |
| 신체상의 은닉된 이형물을 검출하기 위한 시스템 및 방법은 전자기 송신기 및 전자기 수신기를 갖는 검출 탐침을 포함할 수 있다. 전자기 송신기는 전자기 펄스를 방출하게 형성되며, 전자기 수신기는 파형 윈도우 내에 지정된 시간에서 전자기 수신기로부터의 전자기 펄스를 샘플링하도록 형성된다. 전자기 펄스는 0.04 내지 4 THz 의 테라헤르츠 분광 영역에 걸쳐 있다. 또한, 시스템은 전자기 송신기 및 전자기 수신기에 연결된 광학 파이버를 가질 수도 있으며, 펨토초 레이저 펄스는 소스로부터 전자기 송신기 및 전자기 수신기로 광학 파이버에 의해 지향하게 된다.
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| 44 | 용기감지장치 및 이를 포함하는 수처리장치 | KR1020130063311 | 2013-06-03 | KR1020140087976A | 2014-07-09 | 단철순; 김기철; 정진규; 서혜민; 가진성; 박수용 |
| The present invention relates to a container sensing device and a water treatment apparatus having the same. The container sensing device according to an embodiment of the present invention includes a signal sensing unit which transmits a measurement signal at a pre-set incidence angle and receives a reflection signal, which is the measurement signal reflected from the surface of a container; and a control unit which determines whether the container exists at a pre-set position for receiving water, by using the measurement signal received by the signal sensing unit. | ||||||
| 45 | 영상 처리 장치 및 영상 처리 방법 | KR1020110079251 | 2011-08-09 | KR1020130017009A | 2013-02-19 | 하주영; 전해진; 송인택 |
| PURPOSE: An image processing device and an image processing method thereof are provided to freely place a first camera and a light source without physical restriction by correcting the distorted depth information. CONSTITUTION: A first camera(220) senses light reflected from a subject. A calculating unit(230) generates depth information from the sensed light. The calculating unit corrects the depth information based on one or more of the view angle of the first camera, a distance between a light source(210) and the first camera, and a distance between the light source and the subject calculated from the sensed light. [Reference numerals] (210) Light source; (220) First camera; (230) Calculating unit; (240) Memory unit | ||||||
| 46 | ATMOSPHERIC MEASUREMENT SYSTEM | PCT/US2010031965 | 2010-04-21 | WO2010124038A3 | 2011-02-17 | HAYS PAUL BYRON; JOHNSON DAVID KEITH; ZUK DAVID MICHAEL; LINDEMANN SCOTT KEVIN |
| A fringe pattern from an interferometer is imaged onto a digital micromirror device containing an array of micromirrors in an associated pattern of pixel mirror rotational states that provide for sampling the circular fringe pattern in cooperation with one or more associated photodetectors, so as to provide for generate a corresponding set of associated complementary signals. A plurality of different sets of associated complementary signals generated for a corresponding plurality of mutually independent associated patterns of pixel mirror rotational states are used to determine at least one metric associated with the circular fringe pattern. | ||||||
| 47 | VORRICHTUNG ZUM BERÜHRUNGSFREIEN BESTIMMEN DER GERADHEIT WENIGSTENS EINES LANGPRODUKTS UND VERFAHREN ZUM KALIBRIEREN EINER DERARTIGEN VORRICHTUNG | EP17737520.1 | 2017-06-30 | EP3443378A1 | 2019-02-20 | CARL, Daniel; JETTER, Volker; SCHMID-SCHIRLING, Tobias |
| 48 | BESTIMMUNG EINER ENTFERNUNGSINFORMATION FÜR EIN FAHRZEUG | EP14700979.9 | 2014-01-14 | EP2956799B1 | 2018-09-05 | WOHLENBERG, Stefan; MEINECKE, Marc-Michael; RUCHATZ, Thomas; EFFERTZ, Jan |
| 49 | APPARATUS AND METHODS FOR DETECTION OF OBJECTS USING BROADBAND SIGNALS | EP16828414.9 | 2016-07-19 | EP3324913A1 | 2018-05-30 | RICHERT, Micah |
| Broadband signal transmissions may be used for object detection and/or ranging. Broadband transmissions may comprise a pseudo-random bit sequence or a bit sequence produced using, a random process. The sequence may be used to modulate transmissions of a given wave type. Various types of waves may be utilized, pressure, light, and radio waves. Waves reflected by objects within the sensing volume may be sampled. The received signal may be convolved with a time-reversed copy of the transmitted random sequence to produce a correlogram. The correlogram may be analyzed to determine range to objects. The analysis may comprise determination of one or more peaks/troughs in the correlogram. Range to an object may be determines based on a time lag of a respective peak. | ||||||
| 50 | BISTATIC SYNTHETIC APERTURE LADAR SYSTEM | EP13774589.9 | 2013-09-30 | EP2929368B1 | 2018-03-07 | HALMOS, Maurice, J. |
| In one aspect, ladar system includes a ladar transmitter system and a ladar receiver system configured to receive data from the transmitter. The ladar transmitter system and the ladar receiver system are disposed in a configuration forming a bistatic synthetic aperture ladar system. In one example, the ladar transmitter system is configured to be disposed in a vehicle and the ladar receiver system is configured to be stationary. | ||||||
| 51 | SYSTEM AND METHOD FOR TRACKING AND VAPORIZING OBJECTS IN SPACE | EP15191489.2 | 2015-10-26 | EP3163320B1 | 2017-12-13 | Fierlinger, Peter; Burkert, Andreas; Schoeller, Philipp A.; Plaul, Oliver |
| The invention relates to a method and system (100) for tracking objects (104) in space using a coherent light source located in space. The system may comprise a first optical system (102 and a second optical system (112), wherein the first optical system may be adapted to scan for objects and may be adapted to at least partially vaporize identified objects. The second optical system may be adapted to detect the objects when the first optical system scans for the objects. The system may be located in space having solar panels and a laser system comprising a free electron laser. | ||||||
| 52 | SYSTEM AND METHOD FOR TRACKING AND VAPORIZING OBJECTS IN SPACE | EP15191489 | 2015-10-26 | EP3163320A1 | 2017-05-03 | FIERLINGER PETER; BURKERT ANDREAS; SCHOELLER PHILIPP A; PLAUL OLIVER |
| The invention relates to a method and system (100) for tracking objects (104) in space using a coherent light source located in space. The system may comprise a first optical system (102 and a second optical system (112), wherein the first optical system may be adapted to scan for objects and may be adapted to at least partially vaporize identified objects. The second optical system may be adapted to detect the objects when the first optical system scans for the objects. The system may be located in space having solar panels and a laser system comprising a free electron laser. | ||||||
| 53 | TARGET DEVICE FOR USE IN OPTICAL DETECTION OF AN OBJECT | EP14814850.5 | 2014-12-17 | EP3084353A1 | 2016-10-26 | SEND, Robert; BRUDER, Ingmar; WONNEBERGER, Henrike |
| A target device (110) for use in optical detection of at least one object (112) is disclosed. The target device (110) is adapted for at least one of being integrated into the object (112), being held by the object (112) or being attached to the object (112). The target device (110) has at least one reflective element (114) for reflecting a light beam (118). The target device (110) further has at least one color conversion element (116), the color conversion element (116) being adapted to change at least one spectral property of the light beam (118) during reflecting the light beam (118). | ||||||
| 54 | SYSTEM AND METHOD OF TRACKING MULTIPLE TARGETS DESIGNATED BY PULSE-CODED LASERS | EP16162704.7 | 2016-03-29 | EP3073220A1 | 2016-09-28 | NAZEMI, Jonathan; ROZPLOCH, Robert |
A method of identifying at least one target (14a,14b) includes receiving a series of images over time of pulsed energy reflected from the at least one target (14a,14b), each image including a plurality of pulses related to different first and second pulse codes, detecting the pulses in an image of the received images, and outputting pulse detection information including XY coordinates and arrival time information associated with the respective detected pulses. The method further includes associating the pulse detection information with the first and second pulse codes based on the arrival time information, and generating output position information for the at least one target (14a,14b) in space that indicates output positions for the at least one target based on the XY coordinates and being associated with the corresponding first and second pulse codes.
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| 55 | ATMOSPHERIC MEASUREMENT SYSTEM | EP13858158.2 | 2013-10-11 | EP2926164A1 | 2015-10-07 | RICHEY, Charles, J.; JOHNSON, David, Keith; ZUK, David, Michael |
| An apparatus that measures atmospheric conditions upstream of a position at which the apparatus is located relative to a wind direction; comprising: at least one substantially coherent energy source operatively connected to emit at least a first energy beam upstream of the apparatus position relative to a wind direction; a first LIDAR sensor operatively connected to detect scattered energy from the first energy beam directed upstream of the apparatus position; and a processing circuit that generates data on the atmospheric conditions upstream of the apparatus position in response to the scattered energy detected by the first LIDAR sensor, wherein the at least one substantially coherent energy source is operatively connected to emit the first energy beam along a plurality of lines of sight upstream of the apparatus position, at least one of the plurality of lines of sight being non-coplanar with the other lines of sight such that the processing circuit generates three-dimensional data on the atmospheric conditions upstream of the apparatus position. | ||||||
| 56 | SYSTEM AND METHOD TO DETECT ANOMALIES | EP13764203.9 | 2013-03-25 | EP2828682A1 | 2015-01-28 | ZIMDARS, David |
| A system and method for detecting anomalies concealed upon a person may include a detection probe having an electromagnetic transmitter and an electromagnetic receiver. The electromagnetic transmitter is configured to emit electromagnetic pulses, while the electromagnetic receiver is configured to sample electromagnetic pulses from the electromagnetic receiver at specified times within a waveform window. The electromagnetic pulses may span the terahertz spectral region of 0.04 to 4 THz. The system may also have optical fibers connected to the electromagnetic transmitter and electromagnetic receiver, wherein femtosecond laser pulses are directed from a source to the electromagnetic transmitter and the electromagnetic receiver by the optical fibers. | ||||||
| 57 | ATMOSPHERIC MEASUREMENT SYSTEM AND METHOD | EP11857829 | 2011-02-02 | EP2671103A4 | 2015-01-21 | TCHORYK PETER JR; ZUK DAVID MICHAEL; JOHNSON DAVID KEITH; RICHEY CHARLES J; TAYEBATI PARVIZ |
| One of first and second beams (28) of corresponding first and second light (13) are projected into an atmosphere (20) and at least one physical property of the atmosphere (20) is detected from the interference pattern (47) generated from the resulting scattered light (30). The first and second beams (20) are selected responsive to either a detected signal-to-noise ratio (SNR) or a detected aerosol-to-molecular ratio (AMR). The wavelength (740) of the first light (13) provides for either molecular or aerosol scattering, whereas the wavelength (738) of the second light (13) provides for primarily only aerosol scattering. In accordance with a second aspect, scattered light (30) from one or more beams (28) of substantially monochromatic light (13) projected into the atmosphere (20) and received from a plurality of interaction regions (17) or measurement volumes (52) provides for determining wind power (P*) within a region of the atmosphere (20). | ||||||
| 58 | ATMOSPHERIC MEASUREMENT SYSTEM | EP10805082 | 2010-07-29 | EP2460034A4 | 2014-10-29 | TCHORYK PETER JR; RICHEY CHARLES J; HAYS PAUL BYRON; JOHNSON DAVID KEITH; ZUK DAVID MICHAEL |
| A magnitude and direction, or a measure responsive thereto, of a velocity (V) of a first portion (17) of an atmosphere (20) are determined from at least first and second portions of scattered light (30) generated along a common beam of light (28) within the first portion (17) of the atmosphere (20) and received along linearly independent directions at locations that are relatively remote with respect to one another, at least one of which is relatively remote from a source (11) of the beam of light (28). | ||||||
| 59 | RANGE IMAGING LIDAR | EP10806774.5 | 2010-05-15 | EP2430392A2 | 2012-03-21 | HAYS, Paul Byron; JOHNSON, David Keith; ZUK, David Michael |
| Light scattered by a portion of a fluid medium illuminated by a beam of substantially monochromatic light is received within a field-of-view nominally along an axis oriented in a different direction relative to the beam and processed by an interferometer to generate a corresponding fringe pattern that is detected and processed to generate at least one measure of the fluid medium at a plurality of different ranges. | ||||||
| 60 | ON-BOARD LIGHT SOURCE BASED GAIN CORRECTION FOR SEMI-ACTIVE LASER SEEKERS | EP06760137.7 | 2006-05-18 | EP1883786A2 | 2008-02-06 | SCHORR, David; ALEXANDER, William, C. |
| The invention provides a method and apparatus for correcting for gain changes in detectors in a guided vehicle. In one version of the invention, an on board light source is used to generate a reference set of detector gains, which are stored in computer memory. The on board light source is then pulsed at subsequent times and the signals generated by the detectors are compared to the reference set of detector gains to determine whether any gains have changed. | ||||||
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