Design of a space-qualified zoom lens for the space station mobile servicing system video camera

The paper discusses the possibility of testing and correcting calibration of a portable acceleration recorder under orbital flight conditions. This recorder in-cludes a 3-axis accelerometer. The most difficult stage of calibration tests is the determination of its scale factors. The main difficulty of calibration is the lack of special equipment on the space station. It is proposed to use a standard mass meter installed on the ISS for testing accelerometers. The algorithms considered in the paper use data of the motion of the mass meter platform and the video camera records processing in addition to the recorder readings. For testing the algorithms under earth conditions, recordings were made that simulate conditions of an orbital flight. The proposed algorithms showed 2 % error in determining the scale factors of the accelerometers.

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A new procedure for relocating mineral grains for microprobe analysis

Mineralogical Magazine ◽

10.1180/minmag.1995.059.395.07 ◽

1995 ◽

Vol 59 (395) ◽

pp. 221-228 ◽

Cited By ~ 1

Author(s):

P. J. Potts ◽

A. G. Tindle ◽

D. Stanford

Keyword(s):

Digital Image ◽

Microprobe Analysis ◽

Sample Surface ◽

Video Camera ◽

Calibration Procedure ◽

Zoom Lens ◽

Geological Samples ◽

Entire Sample ◽

Points Of Interest ◽

Flat Bed Scanner

AbstractA new procedure is described for locating mineral grains in geological samples prepared for microprobe analysis. This procedure uses a digital image of the entire sample surface to select points of interest. These features of interest must be visible in this external image. Once the sample is mounted on the specimen stage of the microprobe, the digital image is used as a ‘map’ to relocate minerals for analysis. The image can be recorded using either a video camera, fitted with a macro zoom lens, or a flat-bed scanner. A calibration procedure has been developed in which two indexing points are used to calculate the instrument stage coordinates from the pixel coordinates of the digital image. Following this calibration, the stage coordinates of any feature visible in the digital image can be displayed to facilitate rapid relocation. The procedure was evaluated by relocating magnetite grains visible in an optical image of a geological thin section. The repositioning accuracy in relocating 28 magnetite grains distributed over an area of about 20 × 30 mm was found to be 157 ± 102 µm (one standard deviation) from the video camera image and 48 ± 28 µm from a flat bed scanner image. The former image was thought to suffer from some optical distortion. The procedure may be applied to any microprobe instrument fitted with a digital x-y specimen stage. Future applications in relocating features visible in autoradiographs are currently being evaluated.

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Automatic radial distortion correction in zoom lens video camera

Journal of Electronic Imaging ◽

10.1117/1.3503524 ◽

2010 ◽

Vol 19 (4) ◽

pp. 043010 ◽

Cited By ~ 12

Author(s):

Daehyun Kim

Keyword(s):

Video Camera ◽

Distortion Correction ◽

Zoom Lens ◽

Radial Distortion

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International space station mobile servicing system robotic workstation displays and overlays

10.1117/12.277027 ◽

1997 ◽

Author(s):

Susan H. Burns

Keyword(s):

International Space Station ◽

Space Station ◽

International Space ◽

Station Mobile ◽

Robotic Workstation

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Zoom lens with aspherical plastic lenses for video camera

10.1117/12.137990 ◽

1992 ◽

Author(s):

Masahiko Yatsu ◽

Masaharu Deguchi ◽

Kenji Kobayashi ◽

Takesuke Maruyama

Keyword(s):

Video Camera ◽

Zoom Lens

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International Space Station Mobile Dosimetry Unit: A Comparison of Flight Measurements With Model Calculations

10.4271/2004-01-2277 ◽

2004 ◽

Cited By ~ 1

Author(s):

William Atwell ◽

Brandon Reddell ◽

Tsvetan Dachev ◽

Borislav Tomov

Keyword(s):

International Space Station ◽

Space Station ◽

Model Calculations ◽

International Space ◽

Station Mobile ◽

Flight Measurements

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Ratio imaging of intracellular ion concentration

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100130432 ◽

1992 ◽

Vol 50 (2) ◽

pp. 1160-1161

Author(s):

Stephen R. Bolsover

Keyword(s):

Individual Cell ◽

Video Camera ◽

Field Of View ◽

Ion Concentration ◽

Fluorescence Signal ◽

Ion Imaging ◽

Ratiometric Fluorescence ◽

Ratio Imaging ◽

The Mean ◽

The Many

The field of intracellular ion concentration measurement expanded greatly in the 1980's due primarily to the development by Roger Tsien of ratiometric fluorescence dyes. These dyes have many applications, and in particular they make possible to image ion concentrations: to produce maps of the ion concentration within living cells. Ion imagers comprise a fluorescence microscope, an imaging light detector such as a video camera, and a computer system to process the fluorescence signal and display the map of ion concentration.Ion imaging can be used for two distinct purposes. In the first, the imager looks at a field of cells, measuring the mean ion concentration in each cell of the many in the field of view. One can then, for instance, challenge the cells with an agonist and examine the response of each individual cell. Ion imagers are not necessary for this sort of experiment: one can instead use a system that measures the mean ion concentration in a just one cell at any one time. However, they are very much more convenient.

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High-resolution measurement of birefringent fine structure in living cells using a new polarized light microscope

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100136647 ◽

1995 ◽

Vol 53 ◽

pp. 54-55

Author(s):

Rudolf Oldenbourg

Keyword(s):

Light Microscope ◽

Fluorescent Dyes ◽

Polarized Light ◽

Processing System ◽

Video Camera ◽

Molecular Organization ◽

Computer Assisted ◽

Image Recording ◽

Birefringent Crystal ◽

Technological Advances

The recent renaissance of the light microsope is fueled in part by technological advances in components on the periphery of the microscope, such as the laser as illumination source, electronic image recording (video), computer assisted image analysis and the biochemistry of fluorescent dyes for labeling specimens. After great progress in these peripheral parts, it seems timely to examine the optics itself and ask how progress in the periphery facilitates the use of new optical components and of new optical designs inside the microscope. Some results of this fruitful reflection are presented in this symposium.We have considered the polarized light microscope, and developed a design that replaces the traditional compensator, typically a birefringent crystal plate, with a precision universal compensator made of two liquid crystal variable retarders. A video camera and digital image processing system provide fast measurements of specimen anisotropy (retardance magnitude and azimuth) at ALL POINTS of the image forming the field of view. The images document fine structural and molecular organization within a thin optical section of the specimen.

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