公开(公告)号：US6140648A

公开(公告)日：2000-10-31

申请号：US155498

申请日：1998-09-24

Applicant: Kazuo Tsukamoto ,  Koichi Iriyama

Inventor： Kazuo Tsukamoto ,  Koichi Iriyama

IPC: G01V8/20 ,  G01J1/02 ,  G01J1/42 ,  G01V8/10 ,  G08B13/19 ,  G08B13/191 ,  G08B13/18

CPC classification number: G08B13/19 ,  G01J1/4228 ,  G01V8/10 ,  G01J1/0403 ,  G01J1/0448 ,  Y10S250/01

Abstract: A compound-eye crime prevention sensor system is constructed which reliably distinguishes between a human being and a small animal irrespective of the distance from the detector. This system has a zone spacing changer, and when the detection zones A and B of the detector 1 are at the farthest point L in the trespassing subject detecting range, the spacing between the detection zones A and B is .theta.L and when the optical unit in the detector 1 is rotated to bring the detection zones to the position of a point S, the spacing .theta.S between the detection zones A and B is greater than the spacing .theta.L which results from adjusting the detection zones to the farthest point L.

Abstract translation: PCT No.PCT / JP98 / 00404 Sec。 371日期：1998年9月14日 102（e）1998年9月14日PCT PCT 1998年1月29日PCT公布。 公开号WO98 / 34085 日期1998年8月6日构建了一种可靠地区分人与小动物的复眼预防传感器系统，与传感器的距离无关。 该系统具有区间间隔改变器，当检测器1的检测区域A和B处于入侵检测范围内的最远点L时，检测区域A和B之间的间隔为θL，并且当光学单元 在检测器1旋转以使检测区域到达点S的位置时，检测区域A和B之间的间隔θS大于通过将检测区域调整到最远点L而产生的间隔θL。

公开(公告)号：US5122045A

公开(公告)日：1992-06-16

申请号：US698159

申请日：1991-05-09

Applicant: Yutaka Tomisawa ,  Toshikazu Fukuda ,  Kazuhiko Inoue

Inventor： Yutaka Tomisawa ,  Toshikazu Fukuda ,  Kazuhiko Inoue

IPC: H01L31/02 ,  H01L23/50 ,  H01L31/0203 ,  H01L43/00 ,  H01S5/022 ,  H05K3/34

CPC classification number: H01L33/62 ,  G01J1/0403 ,  H01L31/0203 ,  H01L33/54 ,  H01S5/02216 ,  H05K3/3426 ,  H01L2224/48091 ,  H01L2224/48247 ,  H01L2924/12041 ,  H01L2924/1305 ,  H01L2924/13091 ,  H01L2924/181 ,  H01S5/02228 ,  Y02P70/613 ,  Y10S425/228

Abstract: A mold for molding a semiconductor package including a semiconductor chip mounted on a lead frame, wherein a major surface of the semiconductor chip is inclined relative to a surface of the semiconductor package, the mold includes a first mold half including a first mold cavity having a first mold surface and at least four first side surfaces, a second mold half including a second mold cavity having a second main surface extending substantially parallel to the first main surface and at least four second side surfaces extending substantially perpendicular to the second main surface, and a portion for supporting the lead frame and the semiconductor chip in the first and second mold cavities and position the major surface of the semiconductor chip in an inclined position relative to the second main surface, wherein the portion for supporting and positioning includes a first mating surface on the first mold half inclined relative to the first main surface and a second mating surface on the second mold half inclined relative to the second main surface.

公开(公告)号：US3406294A

公开(公告)日：1968-10-15

申请号：US53072566

申请日：1966-02-28

Applicant: VOIGTLAENDER AG

Inventor： WALTER SWAROFSKY

IPC: G01J1/04 ,  G01J1/06

CPC classification number: G01J1/04 ,  G01J1/0266 ,  G01J1/0403 ,  G01J1/0448 ,  G01J1/06

公开(公告)号：US2178197A

公开(公告)日：1939-10-31

申请号：US23717638

申请日：1938-10-27

Applicant: BING JOSEPH M

Inventor： BING JOSEPH M

IPC: G01J1/04 ,  G01J1/06 ,  G01J1/42

CPC classification number: G01J1/04 ,  G01J1/0233 ,  G01J1/0403 ,  G01J1/044 ,  G01J1/06 ,  G01J1/4214

公开(公告)号：US11982763B2

公开(公告)日：2024-05-14

申请号：US17947915

申请日：2022-09-19

Applicant: Banner Engineering Corp.

Inventor： Timothy S. Gardner ,  Ilija Milosevic ,  Darin Dewayne Wampler ,  Jeremy Eickhoff

IPC: G01S7/481 ,  G01J1/02 ,  G01J1/04 ,  G01S17/48 ,  G02B7/02

CPC classification number: G01S7/4813 ,  G01J1/0252 ,  G01J1/0271 ,  G01J1/0403 ,  G01S17/48 ,  G02B7/022 ,  G02B7/028

Abstract: A sensor device has a metal sensor housing with a housing base coupled to a frame base of a metal optical frame. A device mounting plate is orthogonal to the frame base. A securing device secures an optical communication device to the device mounting plate. A barrel mounting channel has first and second sidewalls, each extending obliquely to the frame base and defining a linear translation pathway along the frame base for a metal lens barrel. A fastener secures the metal lens barrel to the first and second sidewalls. A glass lens is in contact with three protrusions extending outward from an inner annular surface of the lens barrel. The optical communication device is configured to be in optical communication with the lens and is secured in a particular position in a translation plane mutually defined by the device mounting plate and the optical communication device.

公开(公告)号：US11892348B2

公开(公告)日：2024-02-06

申请号：US17986662

申请日：2022-11-14

Applicant: NEXANS

Inventor： Emilie Chartier ,  Jérémy Amar ,  Morgan Printemps ,  Ludovic Quevillier ,  Aymeric Richard ,  Lucas Gillet ,  Emile Soulie

IPC: F16B7/04 ,  G01J1/04 ,  E04C3/08 ,  E04C3/04 ,  G01J1/42

CPC classification number: G01J1/0403 ,  E04C3/08 ,  F16B7/0406 ,  E04C2003/0495 ,  G01J2001/4266

Abstract: A system for stiffening a structure has at least one pair of tie rods (3), each tie rod (3) of the pair of tie rods (3) having a first end (4) fastened to the structure (2) and a second end (5), and at least one device (6) for tensioning the tie rods (3) having a deformable linking element (7) fastened to the second end (5) of each tie rod (3) so as to connect the tie rods (3). An actuator (10) is configured to deform the linking element (7) so as to make it pass from an inactive configuration in which the tie rods (3) are in a first state of tension to an active configuration in which the tie rods (3) are in a second state of tension, different than the first state of tension.

公开(公告)号：US11874162B2

公开(公告)日：2024-01-16

申请号：US17052686

申请日：2019-05-08

Applicant: KYOCERA Corporation

Inventor： Eri Takeuchi

IPC: G01J1/04 ,  G01J5/48 ,  G02B26/10

CPC classification number: G01J1/0477 ,  G01J1/0403 ,  G01J1/044 ,  G01J1/0414 ,  G01J5/48 ,  G02B26/108

Abstract: An electromagnetic wave detection apparatus 10 includes a first propagation unit 16, a second propagation unit 17, a first detector 19, and a second detector 20. The first propagation unit 16 propagates electromagnetic waves incident on a reference surface ss in a particular direction using each pixel px. The second propagation unit 17 includes a first surface s1, a second surface s2, a third surface s3, a fourth surface s4, a fifth surface s5, and a sixth surface s6. The first surface s1 propagates electromagnetic waves incident from a first direction in a second direction and propagates electromagnetic propagated in a third direction in a fourth direction. The second surface s2 separates electromagnetic waves propagated in the second direction d2 and propagate electromagnetic waves in a third direction d3 and a fifth direction d5. The first detector 19 detects electromagnetic waves emitted from the third surface s3. The second detector 20 detects electromagnetic waves emitted from the sixth surface s6.

公开(公告)号：US20230184584A1

公开(公告)日：2023-06-15

申请号：US17986662

申请日：2022-11-14

Applicant: NEXANS

Inventor： Emilie CHARTIER ,  Jérémy AMAR ,  Morgan PRINTEMPS ,  Ludovic QUEVILLIER ,  Aymeric RICHARD ,  Lucas GILLET ,  Emile SOULIE

IPC: G01J1/04 ,  E04C3/08 ,  F16B7/04

CPC classification number: G01J1/0403 ,  E04C3/08 ,  F16B7/0406 ,  E04C2003/0495

Abstract: A system for stiffening a structure has at least one pair of tie rods (3), each tie rod (3) of the pair of tie rods (3) having a first end (4) fastened to the structure (2) and a second end (5), and at least one device (6) for tensioning the tie rods (3) having a deformable linking element (7) fastened to the second end (5) of each tie rod (3) so as to connect the tie rods (3). An actuator (10) is configured to deform the linking element (7) so as to make it pass from an inactive configuration in which the tie rods (3) are in a first state of tension to an active configuration in which the tie rods (3) are in a second state of tension, different than the first state of tension.

公开(公告)号：US20190137336A1

公开(公告)日：2019-05-09

申请号：US16237942

申请日：2019-01-02

Applicant: SPECTRAFY INC.

Inventor： VIKTAR TATSIANKOU ,  RICHARD BEAL

IPC: G01J3/36 ,  G01J1/04 ,  G01N21/31 ,  G01J3/02 ,  G01J1/06 ,  G01N21/53

CPC classification number: G01J3/36 ,  G01J1/0403 ,  G01J1/0411 ,  G01J1/0433 ,  G01J1/0474 ,  G01J1/0492 ,  G01J1/06 ,  G01J3/0202 ,  G01J3/0205 ,  G01J3/0208 ,  G01J3/0262 ,  G01J2001/0481 ,  G01J2001/061 ,  G01J2001/4266 ,  G01J2003/1213 ,  G01J2003/2806 ,  G01N21/31 ,  G01N21/538 ,  G01N2201/0616 ,  G01N2201/065

Abstract: Solar spectral irradiance (SSI) measurements are important for solar collector/photovoltaic panel efficiency and solar energy resource assessment as well as being important for scientific meteorological/climate observations and material testing research. To date such measurements have exploited modified diffraction grating based scientific instruments which are bulky, expensive, and with low mechanical integrity for generalized deployment. A compact and cost-effective tool for accurately determining the global solar spectra as well as the global horizontal or tilted irradiances as part of on-site solar resource assessments and module performance characterization studies would be beneficial. An instrument with no moving parts for mechanical and environment stability in open field, non-controlled deployments could exploit software to resolve the global, direct and diffuse solar spectra from its measurements within the 280-4000 nm spectral range, in addition to major atmospheric processes, such as air mass, Rayleigh scattering, aerosol extinction, ozone and water vapour absorptions.

公开(公告)号：US20180313693A1

公开(公告)日：2018-11-01

申请号：US15769601

申请日：2016-10-20

Applicant: SPECTRAFY INC.

Inventor： VIKTAR TATSIANKOU ,  RICHARD BEAL

IPC: G01J3/36 ,  G01J1/04 ,  G01J1/06 ,  G01J3/02

CPC classification number: G01J3/36 ,  G01J1/0403 ,  G01J1/0411 ,  G01J1/0474 ,  G01J1/0492 ,  G01J1/06 ,  G01J3/0202 ,  G01J3/0205 ,  G01J3/0208 ,  G01J3/0262 ,  G01J2001/061 ,  G01J2001/4266 ,  G01J2003/1213 ,  G01N21/31 ,  G01N21/538 ,  G01N2201/0616 ,  G01N2201/065

Abstract: Solar spectral irradiance (SSI) measurements are important for solar collector/photovoltaic panel efficiency and solar energy resource assessment as well as being important for scientific meteorological/climate observations and material testing research. To date such measurements have exploited modified diffraction grating based scientific instruments which are bulky, expensive, and with low mechanical integrity for generalized deployment. A compact and cost-effective tool for accurately determining the global solar spectra as well as the global horizontal or tilted irradiances as part of on-site solar resource assessments and module performance characterization studies would be beneficial. An instrument with no moving parts for mechanical and environment stability in open field, non-controlled deployments could exploit software to resolve the global, direct and diffuse solar spectra from its measurements within the 280-4000 nm spectral range, in addition to major atmospheric processes, such as air mass, Rayleigh scattering, aerosol extinction, ozone and water vapour absorptions.