子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | Direct Beam Solar Light System | US12622833 | 2009-11-20 | US20100067114A1 | 2010-03-18 | Laurence F. Kinney; William Ross McCluney; Gerald L. Cler; Jim Walsh; John Hutson |
| A direct beam solar lighting system for collecting and distributing sunlight into a room. The system includes a rotatable solar collector head to receive sunlight and to reflect the sunlight downward into a transition tube having a reflective interior surface. The light-concentrating transition tube reflects sunlight into a reflective light tube which directs the reflected sunlight through a plenum space into the room. The system includes a drive mechanism for rotating the rotatable solar collector, and a light fixture at end of the light tube to disburse said reflected sunlight onto a ceiling and a wall in the room. In an embodiment the system includes one or more homogenizing reflectors within the solar collector for collecting the sunlight and directing the sunlight more uniformly over the aperture of the transition tube. In an alternative embodiment, the solar collector includes a rotatable tiltable mirror for providing two-axis tracking. | ||||||
| 62 | SENSOR, SYSTEM, AND METHOD FOR AN ULTRAVIOLET LAMP SYSTEM | US11875363 | 2007-10-19 | US20090101829A1 | 2009-04-23 | James W. Schmitkons; James C. Smith; Paul Weyandt |
| A light sensor for an ultraviolet lamp system of the type having an electrodeless lamp excited by microwave energy includes a detector configured to detect light generated by the electrodeless lamp. An elongated channel is configured to be interposed between the detector and the electrodeless lamp. The elongated channel has a first aperture and a second aperture defined at opposing ends thereof. The first aperture is configured to receive light generated by the electrodeless lamp. The second aperture is positioned proximate the detector to transmit at least a portion of light received in the first aperture to the detector. | ||||||
| 63 | Method and apparatus for generating navigation data | US09124819 | 1998-07-29 | US06208937B1 | 2001-03-27 | James R. Huddle |
| The invention is a method and apparatus for generating navigation data. The method comprises the steps of (a) determining the position vector for one or more observation points in an earth-fixed reference frame and (b) determining either (1) the position vector for a target point in the earth-fixed reference frame from directions in either a model-based or a gravity-based reference frame from the one or more observation points to the target point or (2) the directions in either a model-based or a gravity-based reference frame from the one or more observation points to the target point from the position vector for the target point in the earth-fixed reference frame, the model-based reference frame having a vertical axis with a specified orientation with respect to a normal to an ellipsoidal model of the earth and having horizontal axes with specified orientations with respect to the earth-fixed reference, the gravity-based reference frame having a vertical axis with a specified orientation with respect to the gravity vector and having horizontal axes with specified orientations with respect to the earth-fixed reference frame. The apparatus for practicing the method for generating navigation data comprises an inertial navigation system, a GPS antenna and receiver, and direction-finding apparatus. | ||||||
| 64 | Passive vehicle presence detection system | US560052 | 1990-07-30 | US5166681A | 1992-11-24 | H. Werner Bottesch; David A. Freas |
| A passive optical system (POS) is disclosed for detecting the presence of an object, such as a vehicle, in one or more areas of surveillance. The system includes one or more sensor tubes, each having one or more photosensitive devices arranged interiorly at one end and an opening in a wall at the other end, capable of focusing light rays emanating from a specific area of surveillance. Variations in the light rays caused by an object moving into or out of the area of surveillance cause corresponding fluctuations of the light rays impinging on the photosensitive devices, which, in turn, produce variation in a signal. The signal may be utilized to inform the driver of the host vehicle of a nearby vehicle or, when the POS is connected into a cruise control system, to manipulate the host vehicle, accordingly. | ||||||
| 65 | Early ballistic missile detection system | US398296 | 1973-09-13 | US5053622A | 1991-10-01 | Bernard V. Kessler |
| This invention relates to an optical detection of ballistics device using satellites emitting beams of neutral molecules in a specified direction. Intense optical radiation will be reflected off insulated surfaces of nose cones and detected by narrow band optical filters on the satellite. | ||||||
| 66 | Optical system | US856874 | 1977-12-02 | US4199256A | 1980-04-22 | Ragnar Forshufvud; Arnold Johansson |
| An optical system for determining the angular deviation of a movable object from a pre-selected target, wherein an objective lens projects an image of the target in a first focal plane and projects an image of the movable object in a further focal plane. A prism divides the images, with the target image being tramsmitted to an ocular and the movable object image being transmitted to a detector. | ||||||
| 67 | Alignment theodolite | US78688959 | 1959-01-14 | US3079835A | 1963-03-05 | SOL SAPERSTEIN |
| 68 | Atomic burst locators | US67741457 | 1957-08-09 | US2925498A | 1960-02-16 | LOCONTI JOSEPH D; DAVIES JOHN M; STUART HUNTER ARCHIBALD; COLES HAROLD W; ALTAMURA MARIO R |
| 69 | Position indicator | US37445353 | 1953-08-14 | US2906883A | 1959-09-29 | HANSEN WILBUR W |
| 70 | Sighting device for following aerial targets | US3333535 | 1935-07-26 | US2105985A | 1938-01-18 | KARL PAPELLO |
| 71 | Method and instrument for determining the position of targets emitting short flashesof light | US55593031 | 1931-08-08 | US1921630A | 1933-08-08 | ROBERT MECHAU |
| 72 | Reflecting-prism. | US1910540076 | 1910-01-25 | US1044102A | 1912-11-12 | STRAUBEL RUDOLF |
| 73 | Range-finder. | US1912694715 | 1912-05-02 | US1032986A | 1912-07-16 | BOYUM JOHN S |
| 74 | Coincidence-telemeter. | US1909470595 | 1909-01-04 | US940137A | 1909-11-16 | EPPENSTEIN OTTO |
| 75 | Apparatus for measuring distances of distant objects. | US1902130975 | 1902-11-12 | US738155A | 1903-09-08 | BROWN THOMAS D; HAUSE GEORGE W; HAUSE JOSEPH H |
| 76 | 観測支援装置、観測支援方法、及び観測支援プログラム | JP2014098109 | 2014-05-09 | JP2015214247A | 2015-12-03 | 森岡 朋也; 山田 隆弘; 星野 智裕 |
| 【課題】視野が所定の大きさよりも狭い観測機器によっても、全軌道の推定に必要な情報を取得する。 【解決手段】観測支援装置2は、1度に観測可能な視野内において検出された移動物体の座標を特定する位置特定部501と、特定された座標に基づいて、視野内における移動物体の予測軌道を算出する軌道推定部502とを具備する。軌道推定部502は、予測軌道を用いて、視野の外側における移動物体の位置の推定に必要な情報を取得する。 【選択図】図4 |
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| 77 | System for measuring the position and movement of the object | JP2013553950 | 2012-02-17 | JP2014511480A | 2014-05-15 | ギート・ファンデンホート; パトリック・ブランケール; ハンス・ティールマンス |
| 本発明は、測定容積内の対象(20)の位置を測定するシステム(100)に関し、光学的角度測定デバイスに関して測定容積内の対象の方位角および仰角を測定するように構成された、静的光学系とともに配設された、光学的角度測定デバイス(50)と、測定容積内の対象(20)の範囲を測定するように構成された、静的コンポーネントとともに配設された、範囲測定デバイス(70)と、を備える。 さらに、本発明は、システムの使用および測定方法に関する。 | ||||||
| 78 | JPH0425440Y2 - | JP12711489 | 1989-10-30 | JPH0425440Y2 | 1992-06-17 | |
| 79 | Hikarikakudokenshutsusochi | JP792983 | 1983-01-20 | JPH0237995B2 | 1990-08-28 | ARAI SATOSHI |
| 80 | Gazooomehyobunrikairo | JP962383 | 1983-01-24 | JPH0236194B2 | 1990-08-15 | NAKAJIMA YOSHIMOTO |
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