Virtual property reporting for automatic structure detection
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-017/30
G06Q-050/16
G06K-009/00
출원번호
US-0840258
(2013-03-15)
등록번호
US-9753950
(2017-09-05)
발명자
/ 주소
Schultz, Stephen L.
Kennedy, David Arthur
Smyth, James
출원인 / 주소
Pictometry International Corp.
대리인 / 주소
Dunlap Codding, P.C.
인용정보
피인용 횟수 :
0인용 특허 :
126
초록▼
A computer system comprises a processor capable of executing processor executable code operably coupled with a non-transitory computer medium storing processor executable code, which when executed by the processor causes the processor to: (a) receive a first signal over a computer network, the first
A computer system comprises a processor capable of executing processor executable code operably coupled with a non-transitory computer medium storing processor executable code, which when executed by the processor causes the processor to: (a) receive a first signal over a computer network, the first signal indicative of a request for information about a target structure from a user; (b) in response to receiving the first signal, access a database including information about the target structure; and (c) transmit a second signal over the computer network indicative of a virtual property report for the target structure including at least one image of the target structure. The virtual property report may include information about a facet of the target structure facing a street, location of a main entrance of the target structure, location of a secondary entrance of the target structure, location of vehicle access to the target structure.
대표청구항▼
1. A computer system comprising at least one processor capable of executing processor executable code operably coupled with a non-transitory computer medium storing processor executable code, which when executed by the at least one processor causes the at least one processor to: receive a first sign
1. A computer system comprising at least one processor capable of executing processor executable code operably coupled with a non-transitory computer medium storing processor executable code, which when executed by the at least one processor causes the at least one processor to: receive a first signal over a computer network, the first signal indicative of a request for information about a target structure from a user;in response to receiving the first signal, access a database including information about the target structure;determine, using aerial imagery and at least one data set indicative of street files including information indicative of at least one of location of one or more street addresses of structures and location of one or more street, information indicative of orientation of one or more facet of the target structure relative to one or more street in the street files, the determination at least in part based on determining a center of the target structure, projecting a line connecting the center of the target structure to the location of the street address of the structure, and designating a facet of the target structure positioned between the center and the street with which the line intersects as a street-facing facet of the target structure;retrieve one or more image of the one or more facet of the target structure orientated toward the street; andtransmit a second signal over the computer network, the second signal indicative of a virtual property report for the target structure including the one or more image of the one or more facet of the target structure orientated toward the street. 2. The computer system of claim 1, wherein the processor executable code when executed by the at least one processor causes the processor to determine, using the aerial imagery and the at least one data set indicative of street files, information about one or more of: location of a main entrance of the target structure relative to the street, location of a secondary entrance of the target structure relative to the street, location of vehicle access to the target structure within the one or more image, and store the information in a database and associated with the target structure. 3. The computer system of claim 2, wherein the processor executable code for determining the information is organized to be executed by the at least one processor prior to executing the code to receive the first signal. 4. The computer system of claim 1, wherein prior to the step of receiving the first signal over the computer network, the processor executable code when executed by the at least one processor causes the at least one processor to receive a selection of one or more pixels within a displayed image of the target structure in which the one or more pixels have pixel coordinates, transform the pixel coordinates into real-world geographic coordinates, measure distances between the real-world coordinates, and store the measurements on a non-transitory computer readable medium within a database and associated with the target structure. 5. The computer system of claim 4, wherein the processor executable code when executed by the at least one processor causes the at least one processor to associate a label identifying the measurement with a particular measurement, and store the label with the measurement within the database and associated with the target structure. 6. The computer system of claim 5, wherein the label identifying the measurement is a particular field within the database. 7. The computer system of claim 5, wherein the label is selected from the group including orientation and area of a driveway depicted within the displayed image, size or area of a deck depicted within the displayed image, location and height of trees adjacent to the target structure, areas of windows of the target structure, area of a vertical or pitched surface on the target structure, a height of an eave of the target structure, a height of a chimney of the target structure, a distance to a church from the target structure. 8. The computer system of claim 1, wherein the processor executable code when executed by the at least one processor causes the at least one processor to analyze a parcel database to determine an identity of neighboring parcels either adjacent to the target structure or within a predefined radius of the target structure, and to make available to a user information related to neighboring parcels when accessing information indicative of the target structure. 9. The computer system of claim 8, wherein the processor executable code when executed by the at least one processor causes the at least one processor to identify ownership or residency of neighboring parcels and to store a link within the database to information indicative of the owners or residents of neighboring parcels. 10. The computer system of claim 8, wherein the processor executable code when executed by the at least one processor causes the at least one processor to identify social media information of owners or residents of neighboring parcels and to store information within the database indicative of the social media information of the owners or residents of the neighboring parcels. 11. A computer system comprising at least one processor capable of executing processor executable code operably coupled with a non-transitory computer medium storing processor executable code, which when executed by the at least one processor causes the at least one processor to: receive a first signal over a computer network, the first signal indicative of a request for information about a target structure from a user;in response to receiving the first signal, access a database including multiple aerial images of the target structure;automatically identify an aerial image depicting a facet of the target structure that faces a street from the multiple aerial images by: accessing from the data set indicative of street files a file identifying the street;projecting a line through at least a portion of a facet of the target structure to the street; andidentifying the facet that the line is projected through as the facet of the target structure that faces the street;retrieve the aerial image depicting the facet of the target structure that faces a street; andtransmit a second signal over the computer network, the second signal indicative of the aerial image of the target structure depicting the facet of the target structure that faces the street. 12. The computer system of claim 11, wherein the processor executable code causes the processor to transmit a sequence of third signals depicting the multiple aerial images following the transmission of the second signal. 13. The computer system of claim 11, wherein the processor executable code further causes the at least one processor to identify a rear facet of the target structure as a facet that is positioned at about 180° relative to the facet of the target structure that faces the street. 14. The computer system of claim 11, wherein the processor executable code further causes the at least one processor to determine, using aerial imagery and at least one data set indicative of street files, information indicative of elements of the target structure facing the street, including information about one or more of: a facet of the target structure facing a street, location of a main entrance of the target structure relative to the street, location of a secondary entrance of the target structure relative to the street, location of vehicle access to the target structure within the aerial image depicting the facet of the target structure that faces the street. 15. The computer system of claim 11, wherein projecting a line through at least a portion of a facet of the target structure to the street further comprises projecting a line connecting a center of the target structure to a known location of a street address of the target structure.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (126)
Szeliski Richard ; Shum Heung-Yeung, 3-dimensional image rotation method and apparatus for producing image mosaics.
Harkless Lloyd B. (Londonderry NH) McCracken William L. (Wayland MA) Colosimo Joseph A. (Lexington MA), Apparatus for selectively viewing either of two scenes of interest.
Lareau Andre G. ; Beran Stephen R. ; James Brian ; Quinn James P. ; Lund John, Autonomous electro-optical framing camera system with constant ground resolution, unmanned airborne vehicle therefor, and methods of use.
Hedges Thomas M. (Great Falls VA) Weir David G. (Ormond Beach FL) Speasl Jerry A. (Pleasanton CA), Direct digital airborne panoramic camera system and method.
Lareau Andre G. ; Bennett Russell A. ; Beran Steven R. ; Bown Michael ; Hines George, Electro-optical imaging array and camera system with pitch rate image motion compensation.
Lareau Andre G. ; Bennett Russell A. ; Beran Steven R. ; Bown Michael ; Hines George, Electro-optical imaging array and camera system with pitch rate image motion compensation which can be used in an airpl.
Lareau Andre G. (Bloomingdale IL) Beran Stephen R. (Mount Prospect IL) Lund John A. (McHenry IL) Pfister William R. (Schaumburg IL), Electro-optical imaging array with motion compensation.
Lareau Andre G. ; James Brian ; Pfister William R. ; Jerkatis Kenneth J. ; Beran Stephen R. ; Bennett Russell A., Electro-optical imaging detector array for a moving vehicle which includes two axis image motion compensation and trans.
Myrick E. L. (Merritt Island FL), Geographical surveying using cameras in combination with flight computers to obtain images with overlaid geographical co.
Parulski Kenneth A. (Rochester NY) Hamel Robert H. (Walworth NY) Acello John J. (East Rochester NY), Hand-manipulated electronic camera tethered to a personal computer.
Chang Chi S. (Endicott) Hoffarth Joseph G. (Binghamton) Markovich Voya R. (Endwell) Snyder Keith A. (Vestal) Wiley John P. (Vestal NY), High density circuit board and method of making same.
Szeliski Richard ; Shum Heung-Yeung, Image mosaic construction system and apparatus with patch-based alignment, global block adjustment and pair-wise motion-based local warping.
von Braun Heiko S. (Tankenrain Salzgruben 2 Weilheim D-8120 DEX), Large-scale mapping of parameters of multi-dimensional structures in natural environments.
Abel Robert J. (Newark CA) MacDonald Michael C. (San Jose CA) Wang Peter S. (Cupertino CA), Mapping and analysis system for precision farming applications.
Lachinski Theodore M. (Andover MN) Ptacek Louis S. (Mound MN) Blais Paul M. (St. Paul MN) Boggs Stephen (Fridley MN) Longfellow John W. (St. Paul MN) Setterholm Jeffrey M. (Lakeville MN), Method and apparatus for collecting and processing visual and spatial position information from a moving platform.
Rahmes,Mark; Karp,John; Smith,Anthony; Connetti, Jr.,Stephen, Method and apparatus for enhancing a digital elevation model (DEM) for topographical modeling.
Kumar, Rakesh; Hsu, Stephen Charles; Hanna, Keith; Samarasekera, Supun; Wildes, Richard Patrick; Hirvonen, David James; Klinedinst, Thomas Edward; Lehman, William Brian; Matei, Bodgan; Zhao, Wenyi; L, Method and apparatus for performing geo-spatial registration of imagery.
Lareau Andre G. (Bloomingdale IL) Willey Gilbert W. (Arlington Heights IL) Bennett Russell A. (McHenry IL) Beran Stephen R. (Mount Prospect IL), Method and camera system for step frame reconnaissance with motion compensation.
Kumar Rakesh ; Hanna Keith James ; Bergen James R. ; Anandan Padmanabhan ; Irani Michal, Method and system for image combination using a parallax-based technique.
Cherepenin Vladimir Alexeevich,RUX ; Korjenevsky Alexandr Vladimirovich,RUX ; Kultiasov Yury Sergeevich,RUX, Method for producing a tomographic image of the body and electric impedance tomograph.
Bakewell,Charles Adams, Mobile enforcement platform with aimable violation identification and documentation system for multiple traffic violation types across all lanes in moving traffic, generating composite display images and data to support citation generation, homeland security, and monitoring.
Wight Ralph H. (Northport NY) Wolfe Gregory J. (Port Jefferson Station NY), Nonlinear scanning to optimize sector scan electro-optic reconnaissance system performance.
Heitzman Edward F. (6 Moores Mill Rd. Pennington NJ 08534) Heitzman Edward J. (6 Moores Mill Rd. Pennington NJ 08534), Real time video data acquistion systems.
Kamel Ahmed A. (Sunnyvale CA) Graul Donald W. (San Mateo CA) Savides John (Los Altos Hills CA) Hanson Charles W. (Mountain View CA), Satellite camera image navigation.
Gruber,Michael A.; Leberl,Franz W.; Ponticelli,Martin, Self-calibrating, digital, large format camera with single or multiple detector arrays and single or multiple optical systems.
Selk Kenneth Charles (Hermosa Beach CA) Hirsch Harold J. (Encino CA) Canyon James Carl (Torrance CA) Gower Frederick M. (Manhattan Beach CA), Shielded multilayer printed wiring board, high frequency, high isolation.
Imai Hitoshi (Yokohama JPX) Sugiura Muneharu (Tokyo JPX) Hoashi Katsutoshi (Yokohama JPX), Stereo image forming apparatus having a light deflection member in each optical path.
Olsen Steven L. (Salt Lake City UT) Petrick William R. (Salt Lake City UT) Stodt John A. (Salt Lake City UT), Survey system and method for real time collection and processing of geophysicals data using signals from a global positi.
Olsen Steven L. (Salt Lake City UT) Petrick William R. (Salt Lake City UT) Stodt John A. (Salt Lake City UT), Survey system for collection and real time processing of geophysical data.
Cooper Roger D. (Roatan Tower Court Lubenham Market Harborough Leciester LE16 954 GBX), Video signal processing apparatus for producing a composite signal for simultaneous display of data and video informatio.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.