Microscope slide scanner. In an embodiment the microscope slide scanner comprises a single enclosure unit that includes at least one objective lens, at least one line scan camera, at least one communication port, and at least one processor. The line scan camera may be configured to capture image dat
Microscope slide scanner. In an embodiment the microscope slide scanner comprises a single enclosure unit that includes at least one objective lens, at least one line scan camera, at least one communication port, and at least one processor. The line scan camera may be configured to capture image data of a sample as a plurality of image stripes via the objective lens. The communication port provides communication over a network. The processor may align the plurality of image stripes into a contiguous image of at least a portion of the sample, and executes a web server that provides an operator interface over the network to one or more remote devices.
대표청구항▼
1. A system for acquiring a digital image of at least a portion of a microscope sample, the system comprising: a motorized stage configured to support a microscope sample and move the microscope sample at a substantially constant velocity;an illumination system configured to illuminate at least a po
1. A system for acquiring a digital image of at least a portion of a microscope sample, the system comprising: a motorized stage configured to support a microscope sample and move the microscope sample at a substantially constant velocity;an illumination system configured to illuminate at least a portion of the microscope sample;an objective lens positioned for viewing the illuminated portion of the microscope sample;a focus map having a plurality of focus points on the microscope sample;at least one line scan camera optically coupled with the objective lens, wherein the at least one line scan camera is configured to create a digital image strip of a portion of the microscope sample, and wherein the digital image strip is captured while the microscope sample is moving at substantially constant velocity;a focusing system configured to provide focus for the at least one line scan camera during creation of each digital image strip in accordance with the focus map;an image composer configured to align adjacent digital image strips into a contiguous digital image of at least a portion of the microscope sample; anda data storage area configured to store the contiguous digital image. 2. The system of claim 1, wherein the motorized stage comprises: a first motor configured to move the microscope sample in a first direction in a plane of the sample; anda second motor configured to move the microscope sample in a second direction in the plane of the sample, wherein the second direction is orthogonal to the first direction. 3. The system of claim 2, wherein the first motor is a servo motor. 4. The system of claim 1, wherein the at least one line scan camera receives a linear field of view of a portion of the microscope sample via the objective lens. 5. The system of claim 4, wherein the illumination system is configured to uniformly illuminate the linear field of view. 6. The system of claim 1, wherein the at least one line scan camera is configured to capture red, green, and blue color signals through discrete linear array sensors. 7. The system of claim 1, wherein the focusing system comprises a piezo positioner that is communicatively coupled to a piezo controller. 8. The system of claim 7, wherein the piezo controller and the piezo positioner are configured to adjust the focus for the line scan camera at least 10 times per second. 9. The system of claim 1, wherein the contiguous digital image is a diffraction-limited contiguous digital image. 10. The system of claim 1, wherein the at least one line scan camera comprises a time-delay-integration (TDI) array comprising a plurality of linear arrays. 11. A method for creating a digital image of a portion of a microscope sample, the method comprising: focusing a line scan camera on a plurality of focus points within a microscope sample, wherein the line scan camera has a linear field of view;creating a focus map based on the plurality of focus points;scanning a first strip of the microscope sample while the microscope sample is in motion by moving the microscope sample at substantially constant velocity relative to the line scan camera while the first strip is exposed to the linear field of view of the line scan camera during said motion, illuminating at least a portion of the first strip while the microscope sample is in said motion, and adjusting the focus of the line scan camera during said scanning in accordance with the focus map;storing a digital image of the first strip;scanning a substantially unscanned second strip of the microscope sample while the microscope sample is in motion by moving the microscope sample at substantially constant velocity relative to the line scan camera while the second strip is exposed to the linear field of view of the line scan camera during said motion, illuminating at least a portion of the second strip while the microscope sample is in said motion, and adjusting the focus of the line scan camera during said scanning;storing a digital image of the second strip; andcomposing the digital image of the first strip and the digital image of the second strip into a contiguous digital image. 12. The method of claim 11, wherein the focus map is non-planar. 13. The method of claim 11, wherein each movement of the microscope sample is carried out by a servo motor. 14. The method of claim 11, wherein each adjustment of the focus of the line scan camera is carried out by a piezo positioner communicatively coupled with a piezo controller. 15. The method of claim 11, wherein the digital image of the first strip has a first length and first width, wherein the digital image of the second strip has a second length and a second width, and wherein the first length and the second length are not equal. 16. The method of claim 15, wherein the first width and the second width are equal. 17. The method of claim 15, wherein the first width and the second width are not equal. 18. The method of claim 11, wherein the first strip comprises a first perimeter edge and an opposing perimeter edge, and wherein the first perimeter edge and the opposing perimeter edge are separated by at least 2 micrometers. 19. The method of claim 11, wherein the second strip comprises a first perimeter edge and an opposing perimeter edge, and wherein the first perimeter edge and the opposing perimeter edge are separated by at least 2 micrometers. 20. The method of claim 11, wherein the line scan camera comprises a time-delay-integration (TDI) array comprising a plurality of linear arrays.
Preston ; Jr. Kendall (4701 E. Glenn St. ; Bldg. 36 Tucson AZ), Apparatus and method for a multi-resolution electro-optical imaging, display and storage/retrieval system.
Yu Kenneth K. (Beaverton OR) Berglund C. Neil (Oregon City OR), Automated system for extracting design and layout information from an integrated circuit.
Conzola Vincent C. (Endwell NY) Rittenhouse Norman E. (Endicott NY) Solomon Jeffrey M. (Endicott NY) Toomey Thomas J. (Denver CO) Yablonsky Peter J. (Apalachin NY), Computer controlled, multiple angle illumination system.
Palcic Branko (6012 Adera Street Vancouver ; British Columbia CAX V6M 3J4) Jaggi Bruno (2180 Trafalgar Street Vancouver ; British Columbia CAX V6K 4M8) Nordin Jan (924 Leovista North Vancouver ; Brit, Dynamic microscope image processing scanner.
Truc James A. ; Peterson Doug ; Anderson James ; Ovsak Gregg J. ; McLean Rob ; Hogenson James A. ; Johnson Bradley ; Deutsch Dennis ; Wolter Peter, Film scanner.
Currin Bena L. (Pasadena CA) Abdel-Malek Aiman A. (Schenectady NY) Hartley Richard I. (Schenectady NY), Forming, with the aid of an overview image, a composite image from a mosaic of images.
Matsuda Shinya (Kyoto JPX) Fujii Shinichi (Amagasaki JPX), Image pickup apparatus for focusing an object image based on mirror reflected height of the object.
Worster Bruce W. ; Crane Dale E. ; Hansen Hans J. ; Fairley Christopher R. ; Lee Ken K., Laser imaging system for inspection and analysis of sub-micron particles.
Suita Makio (Kawasaki JPX) Kitajima Hironobu (Kawasaki JPX) Yamabe Masaki (Kawasaki JPX), Mark position detecting method and device for aligner and aligner having the device.
Bacus James V. ; Bacus James W., Method and apparatus for acquiring and reconstructing magnified specimen images from a computer-controlled microscope.
Fairley Christopher R. (San Jose CA) Thompson Timothy V. (San Jose CA) Lee Ken K. (Los Altos CA), Method and apparatus for automatic focusing of a confocal laser microscope.
Trulson Mark (Santa Clara CA) Stern David (Mountain View CA) Fiekowsky Peter (Los Altos CA) Rava Richard (Palo Alto CA) Walton Ian (Menlo Park CA) Fodor Stephen P. A. (Palo Alto CA), Method and apparatus for imaging a sample on a device.
Burt Peter J. ; Irani Michal ; Hsu Stephen Charles ; Anandan Padmanabhan ; Hansen Michael W., Method and apparatus for performing mosaic based image compression.
Jansson Peter A. (Hockessin DE) Rogers Wade T. (West Chester PA) Schwaber James S. (Wilmington DE), Method for operating a microscopical mapping system.
Tsai Bin-Ming Benjamin ; Pon Russell M., Optical inspection of a specimen using multi-channel responses from the specimen using bright and darkfield detection.
Jaggi Bruno (2180 Trafalgar Street Vancouver ; British Columbia CAX V6K 4M8) Deen Mohammed J. (School of Engineering Design ; Simon Fraser Univ. Burnaby ; B.C. CAX V5A 1S6) Palcic Branko (6012 Adera , Quantitative light microscope using a solid state detector in the primary image plane.
Pearson Eric C. (Waterloo CAX) Strauss Ronald E. (Kitchener CAX) Merchant David B. (Kitchener CAX) Houde Jacques S. (Waterloo CAX) Burjoski Joseph D. (Waterloo CAX) Lammers Scott G. (Kitchener CAX) P, Real-time line scan processor.
Crandall,Greg J.; Eichhorn,Ole; Olson,Allen H.; Soenksen,Dirk G., System and method for data management in a linear-array-based microscope slide scanner.
Crandall,Greg J.; Eichhorn,Ole; Olson,Allen H.; Soenksen,Dirk G., System and method for data management in a linear-array-based microscope slide scanner.
Burt Peter J. ; Irani Michal ; Hsu Stephen Charles ; Anandan Padmanabhan ; Hansen Michael W., System for automatically aligning images to form a mosaic image.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.