Patents by Inventor Thomas M. Hedges
Thomas M. Hedges has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 10180496Abstract: Laser radar systems include a pentaprism configured to scan a measurement beam with respect to a target surface. A focusing optical assembly includes a corner cube that is used to adjust measurement beam focus. Target distance is estimated based on heterodyne frequencies between a return beam and a local oscillator beam. The local oscillator beam is configured to propagate to and from the focusing optical assembly before mixing with the return beam. In some examples, heterodyne frequencies are calibrated with respect to target distance using a Fabry-Perot interferometer having mirrors fixed to a lithium aluminosilicate glass-ceramic tube.Type: GrantFiled: March 15, 2013Date of Patent: January 15, 2019Assignees: Nikon Corporation, Nikon Metrology NVInventors: Daniel G. Smith, Eric Peter Goodwin, Anthony R. Slotwinski, Mina A. Rezk, Alexander Cooper, Thomas M. Hedges
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Patent number: 10139492Abstract: Laser radar systems include a pentaprism configured to scan a measurement beam with respect to a target surface. A focusing optical assembly includes a corner cube that is used to adjust measurement beam focus. Target distance is estimated based on heterodyne frequencies between a return beam and a local oscillator beam. The local oscillator beam is configured to propagate to and from the focusing optical assembly before mixing with the return beam. In some examples, heterodyne frequencies are calibrated with respect to target distance using a Fabry-Perot interferometer having mirrors fixed to a lithium aluminosilicate glass-ceramic tube.Type: GrantFiled: February 27, 2017Date of Patent: November 27, 2018Assignee: Nikon CorporationInventors: Mina A. Rezk, Anthony R. Slotwinski, Daniel G. Smith, Eric Peter Goodwin, Alexander Cooper, Thomas M. Hedges
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Publication number: 20170168143Abstract: Laser radar systems include a pentaprism configured to scan a measurement beam with respect to a target surface. A focusing optical assembly includes a corner cube that is used to adjust measurement beam focus. Target distance is estimated based on heterodyne frequencies between a return beam and a local oscillator beam. The local oscillator beam is configured to propagate to and from the focusing optical assembly before mixing with the return beam. In some examples, heterodyne frequencies are calibrated with respect to target distance using a Fabry-Perot interferometer having mirrors fixed to a lithium aluminosilicate glass-ceramic tube.Type: ApplicationFiled: February 27, 2017Publication date: June 15, 2017Applicants: Nikon Corporation, Nikon Metrology NVInventors: Mina A. Rezk, Anthony R. Slotwinski, Daniel G. Smith, Eric Peter Goodwin, Alexander Cooper, Thomas M. Hedges
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Patent number: 9638799Abstract: Laser radar systems include a pentaprism configured to scan a measurement beam with respect to a target surface. A focusing optical assembly includes a corner cube that is used to adjust measurement beam focus. Target distance is estimated based on heterodyne frequencies between a return beam and a local oscillator beam. The local oscillator beam is configured to propagate to and from the focusing optical assembly before mixing with the return beam. In some examples, heterodyne frequencies are calibrated with respect to target distance using a Fabry-Perot interferometer having mirrors fixed to a lithium aluminosilicate glass-ceramic tube.Type: GrantFiled: March 15, 2013Date of Patent: May 2, 2017Assignees: Nikon Corporation, Nikon Metrology NVInventors: Eric Peter Goodwin, Daniel G. Smith, Alexander Cooper, Mina A. Rezk, Anthony R. Slotwinski, Thomas M. Hedges
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Patent number: 9618619Abstract: Laser radar systems include a pentaprism configured to scan a measurement beam with respect to a target surface. A focusing optical assembly includes a corner cube that is used to adjust measurement beam focus. Target distance is estimated based on heterodyne frequencies between a return beam and a local oscillator beam. The local oscillator beam is configured to propagate to and from the focusing optical assembly before mixing with the return beam. In some examples, heterodyne frequencies are calibrated with respect to target distance using a Fabry-Perot interferometer having mirrors fixed to a lithium aluminosilicate glass-ceramic tube.Type: GrantFiled: March 15, 2013Date of Patent: April 11, 2017Assignees: Nikon Corporation, Nikon Metrology NVInventors: Mina A. Rezk, Anthony R. Slotwinski, Daniel G. Smith, Eric Peter Goodwin, Alexander Cooper, Thomas M. Hedges
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Patent number: 6662103Abstract: A method and system allows conversion of three-dimensional data from a default coordinate frame to an arbitrary user-selected coordinate frame. The method includes obtaining position data in a default coordinate frame and transforming the data into an alternate coordinate frame defined by the user. The alternate coordinate frame can be defined by allowing the user to select a plane, an origin, and an axis, using any desired coordinate system and in any desired orientation. The transformed data allows presentation of position measurements in a form that is relevant to the user's specific application.Type: GrantFiled: March 21, 2000Date of Patent: December 9, 2003Assignee: ARC Second Inc.Inventors: Jeffrey F. Skolnick, Edward R. Barrientos, Sean M. Beliveau, Thomas M. Hedges, Eric J. Lundberg, Edmund S. Pendleton, Roger Wells
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Patent number: 6630993Abstract: Positions can be precisely and accurately fixed instantaneously within a three-dimensional workspace. A system of two or more transmitters each continuously sweep the workspace with two fanned laser beams which are preferably about 90 degrees apart on the rotational axis of the transmitter. A receiving instrument includes, preferably, two light detectors which detect the time at which each fanned laser beam is incident thereon. The light detectors also detect a synchronization pulse from each transmitter that is emitted once per revolution. Beams from different transmitters are differentiated by different rotational speeds and, therefore, different beam incidence cycles. Because three intersecting planes uniquely define a point in three-dimensional space, by detecting at least three of the fan beams from the transmitters, the receiving instrument can calculate its position in the workspace. A Quick Calc setup procedure allows the use to define a desired coordinate system within the workspace.Type: GrantFiled: March 21, 2000Date of Patent: October 7, 2003Assignee: ARC Second Inc.Inventors: Thomas M. Hedges, Scott C. Casteel, Andrew Dornbusch, Doug Gaff, Edmund S. Pendleton, Michael J. Sobel, Frey Wain
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Patent number: 6621565Abstract: An optical transmitter for use in position location or position measurement systems includes (i) an assembly including two optical sources that generate two optical beams which diverge in known ways in a first and second plane, respectively, and are narrow in the orthogonal planes, (ii) a power source which provides power to the assembly to rotate it at a constant angular velocity or with a previously known pattern of velocities through each complete rotation of the assembly, and (iii) a signaling unit that emits a synchronization signal at a specific rotational position of the assembly. The optical transmitter can be used in systems for determining points, lines, planes, distances, areas, volumes, azimuth, elevation, range, angles, or any other positional or spatial variable. The optical transmitter has wide application in, for example, surveying, construction, and the creation of virtual or real environments.Type: GrantFiled: September 10, 2001Date of Patent: September 16, 2003Assignee: Arc Second Inc.Inventors: Timothy Pratt, Scott C. Casteel, Thomas M. Hedges, Donald Todd
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Patent number: 6618133Abstract: An improved, low-cost optical transmitter and method useful in a three-dimensional measurement system wherein a plurality of operational parameters of said transmitter are calibrated during manufacture/assembly process to generate unique calibration data for each optical transmitter including data defining angles of each transmitter's first and second radiant fan beams and the angle between the beams when the transmitter is leveled for operation in the system and wherein a detector/receiver in the system distinguishes between radiant beams from a plurality of individual transmitters operable within a given measurement field as a function of the selectively alterable rotational velocity calibration data for each of said transmitters and wherein said angular calibration data for each transmitter is operationally available to each detector/receiver operable in the system.Type: GrantFiled: July 26, 2002Date of Patent: September 9, 2003Assignee: Arc Second, Inc.Inventors: Thomas M. Hedges, Scott Casteel, Thomas Cuff, Timothy Pratt, Rick Slater, Donald Todd
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Patent number: 6545751Abstract: An improved low cost theodolite position measurement system and process which is particularly useful in enabling a single operator to conveniently set up the system and calculate elevation (el) and azimuth (az) angle data. Only a single optical transmitter is positioned within a predetermined workspace thus significantly decreasing equipment costs and setup time. The single transmitter is positioned and leveled at a predetermined point in the workspace. In operation the single rotatably mounted transmitter head illuminates the workspace volume with a pair of spaced apart precalibrated fan beams which sweep the space and a periodically emitted reference strobe pulse. At least one optical receiver is selectively positionable within said workspace so that during each revolution of said single transmitter head said receiver receives a first position strike and a second position strike of said fan beams.Type: GrantFiled: February 26, 2001Date of Patent: April 8, 2003Assignee: Arc Second, Inc.Inventors: Sean Beliveau, Edward R. Barrientos, Yvan Beliveau, Thomas M. Hedges, Eric J. Lundberg, Edmund S. Pendleton, Timothy Pratt, Rick Slater, Michael J. Sobel
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Patent number: 6535282Abstract: An improved three-dimensional position detector and measurement system includes one or more transmitters that each transmit planar light beams and a strobe pulse and a receiver that responds to illumination from the beams and the strobe. The receiver in the system includes calibration logic for executing a quadratic mathematical algorithm to uniquely characterize said planar beams of each of said optical transmitters active in said measurement field. In one embodiment, the quadratic mathematical algorithm uses cones to represent the scan path of the planar beams.Type: GrantFiled: October 30, 2001Date of Patent: March 18, 2003Assignee: Arc Second, Inc.Inventors: Thomas M. Hedges, Hiro Takagi, Timothy Pratt, Michael J. Sobel
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Patent number: 6519029Abstract: An improved, low-cost optical transmitter and method useful in a three-dimensional measurement system wherein a plurality of operational parameters of said transmitter are calibrated during manufacture/assembly process to generate unique calibration data for each optical transmitter including data defining angles of each transmitter's first and second radiant fan beams and the angle between the beams when the transmitter is leveled for operation in the system and wherein a detector/receiver in the system distinguishes between radiant beams from a plurality of individual transmitters operable within a given measurement field as a function of the selectively alterable rotational velocity calibration data for each of said transmitters and wherein said angular calibration data for each transmitter is operationally available to each detector/receiver operable in the system.Type: GrantFiled: March 21, 2000Date of Patent: February 11, 2003Assignee: Arc Second, Inc.Inventors: Thomas M. Hedges, Scott Casteel, Thomas Cuff, Timothy Pratt, Rick Slater, Donald Todd
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Publication number: 20030025902Abstract: An improved, low-cost optical transmitter and method useful in a three-dimensional measurement system wherein a plurality of operational parameters of said transmitter are calibrated during manufacture/assembly process to generate unique calibration data for each optical transmitter including data defining angles of each transmitter's first and second radiant fan beams and the angle between the beams when the transmitter is leveled for operation in the system and wherein a detector/receiver in the system distinguishes between radiant beams from a plurality of individual transmitters operable within a given measurement field as a function of the selectively alterable rotational velocity calibration data for each of said transmitters and wherein said angular calibration data for each transmitter is operationally available to each detector/receiver operable in the system.Type: ApplicationFiled: July 26, 2002Publication date: February 6, 2003Inventors: Thomas M. Hedges, Scott Casteel, Thomas Cuff, Timothy Pratt, Rick Slater, Donald Todd
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Publication number: 20020154294Abstract: An improved three-dimensional position detector and measurement system includes one or more transmitters that each transmit planar light beams and a strobe pulse and a receiver that responds to illumination from the beams and the strobe. The receiver in the system includes calibration logic for executing a quadratic mathematical algorithm to uniquely characterize said planar beams of each of said optical transmitters active in said measurement field. In one embodiment, the quadratic mathematical algorithm uses cones to represent the scan path of the planar beams.Type: ApplicationFiled: October 30, 2001Publication date: October 24, 2002Inventors: Thomas M. Hedges, Hiro Takagi, Timothy Pratt, Michael J. Sobel
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Publication number: 20020008870Abstract: An improved low cost theodolite position measurement system and process which is particularly useful in enabling a single operator to conveniently set up the system and calculate elevation (el) and azimuth (az) angle data. Only a single optical transmitter is positioned within a predetermined workspace thus significantly decreasing equipment costs and setup time. The single transmitter is positioned and leveled at a predetermined point in the workspace. In operation the single rotatably mounted transmitter head illuminates the workspace volume with a pair of spaced apart precalibrated fan beams which sweep the space and a periodically emitted reference strobe pulse. At least one optical receiver is selectively positionable within said workspace so that during each revolution of said single transmitter head said receiver receives a first position strike and a second position strike of said fan beams.Type: ApplicationFiled: February 26, 2001Publication date: January 24, 2002Inventors: Sean Beliveau, Edward R. Barrientos, Yvan Beliveau, Thomas M. Hedges, Eric J. Lundberg, Edmund S. Pendleton, Timothy Pratt, Rick Slater, Michael J. Sobel
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Publication number: 20020005944Abstract: An optical transmitter for use in position location or position measurement systems includes (i) an assembly including two optical sources that generate two optical beams which diverge in known ways in a first and second plane, respectively, and are narrow in the orthogonal planes, (ii) a power source which provides power to the assembly to rotate it at a constant angular velocity or with a previously known pattern of velocities through each complete rotation of the assembly, and (iii) a signaling unit that emits a synchronization signal at a specific rotational position of the assembly. The optical transmitter can be used in systems for determining points, lines, planes, distances, areas, volumes, azimuth, elevation, range, angles, or any other positional or spatial variable. The optical transmitter has wide application in, for example, surveying, construction, and the creation of virtual or real environments.Type: ApplicationFiled: September 10, 2001Publication date: January 17, 2002Inventors: Timothy Pratt, Scott C. Casteel, Thomas M. Hedges, Donald Todd
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Patent number: 5999211Abstract: An improved airborne, direct digital panoramic camera system and method in which an in-line electro-optical sensor eliminates the need for photographic film and film transport apparatus normally associated with prior art airborne reconnaissance cameras and yet still retains the very high image resolution quality which is so important in intelligence operations and commercial geographic information systems (GIS), mapping and other remote sensing applications. The present invention provides a simpler, more efficient and less costly panoramic camera by utilizing a lens in conjunction with the electro-optical line array sensor wherein the lens can be simpler and less expensive than a framing camera because it essentially requires quality focus in only one dimension and by eliminating the burden and delay necessitated in film processing and development.Type: GrantFiled: October 28, 1996Date of Patent: December 7, 1999Assignee: ImageAmerica, Inc.Inventors: Thomas M. Hedges, David G. Weir, Jerry A. Speasl
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Patent number: 5604534Abstract: An airborne direct digital panoramic camera system and method in which an in-line electro-optical sensor eliminates the need for photographic film and film transport apparatus normally associated with prior art airborne reconnaissance cameras and yet still retains the very high image resolution quality which is so important in intelligence operations and commercial geographic information systems (GIS), mapping and other remote sensing applications. The system provides a simpler, more efficient and less costly panoramic camera by utilizing a lens in conjunction with the electro-optical line array sensor wherein the lens can be simpler and less expensive than a framing camera because it essentially requires quality focus in only one dimension and by eliminating the burden and delay necessitated in film processing and development.Type: GrantFiled: May 24, 1995Date of Patent: February 18, 1997Assignee: Omni Solutions International, Ltd.Inventors: Thomas M. Hedges, David G. Weir, Jerry A. Speasl