Knowledge Base Wiki

Search for LIMS content across all our Wiki Knowledge Bases.

Type a search term to find related articles by LIMS subject matter experts gathered from the most trusted and dynamic collaboration tools in the laboratory informatics industry.

Comparison of two imaging modalities—optical tomography (A, C) and computed tomography (B, D)—as applied to a Lego minifigure

Imaging is the representation or reproduction of an object's form; especially a visual representation (i.e., the formation of an image).

Imaging technology is the application of materials and methods to create, preserve, or duplicate images.

Imaging science is a multidisciplinary field concerned with the generation, collection, duplication, analysis, modification, and visualization of images,[1] including imaging things that the human eye cannot detect. As an evolving field it includes research and researchers from physics, mathematics, electrical engineering, computer vision, computer science, and perceptual psychology.

Imagers are imaging sensors.

Imaging chain

The foundation of imaging science as a discipline is the "imaging chain" – a conceptual model describing all of the factors which must be considered when developing a system for creating visual renderings (images). In general, the links of the imaging chain include:

  1. The human visual system. Designers must also consider the psychophysical processes which take place in human beings as they make sense of information received through the visual system.
  2. The subject of the image. When developing an imaging system, designers must consider the observables associated with the subjects which will be imaged. These observables generally take the form of emitted or reflected energy, such as electromagnetic energy or mechanical energy.
  3. The capture device. Once the observables associated with the subject are characterized, designers can then identify and integrate the technologies needed to capture those observables. For example, in the case of consumer digital cameras, those technologies include optics for collecting energy in the visible portion of the electromagnetic spectrum, and electronic detectors for converting the electromagnetic energy into an electronic signal.
  4. The processor. For all digital imaging systems, the electronic signals produced by the capture device must be manipulated by an algorithm which formats the signals so they can be displayed as an image. In practice, there are often multiple processors involved in the creation of a digital image.
  5. The display. The display takes the electronic signals which have been manipulated by the processor and renders them on some visual medium. Examples include paper (for printed, or "hard copy" images), television, computer monitor, or projector.

Note that some imaging scientists will include additional "links" in their description of the imaging chain. For example, some will include the "source" of the energy which "illuminates" or interacts with the subject of the image. Others will include storage and/or transmission systems.

Subfields

Subfields within imaging science include: image processing, computer vision, 3D computer graphics, animations, atmospheric optics, astronomical imaging, biological imaging, digital image restoration, digital imaging, color science, digital photography, holography, magnetic resonance imaging, medical imaging, microdensitometry, optics, photography, remote sensing, radar imaging, radiometry, silver halide, ultrasound imaging, photoacoustic imaging, thermal imaging, visual perception, and various printing technologies.

Methodologies

Examples

False-color image from a thermographic camera

Imaging technology materials and methods include:

See also

References

  1. ^ Joseph P. Hornak, Encyclopedia of Imaging Science and Technology (John Wiley & Sons, 2002) ISBN 9780471332763
  2. ^ Kaboutari, Keivan; Önder Tetik, Ahmet; Ghalichi, Elyar; Soner Gözü, Mehmet; Zengin, Reyhan; Güneri Gençer, Nevzat (2019). "Data acquisition system for MAET with magnetic field measurements". Physics in Medicine & Biology. 64 (11): 115016. Bibcode:2019PMB....64k5016K. doi:10.1088/1361-6560/ab1809. PMID 30970342. S2CID 108294047.

Further reading

  • Harrison H. Barrett and Kyle J. Myers, Foundations of Image Science (John Wiley & Sons, 2004) ISBN 0471153001
  • Ronald N. Bracewell, Fourier Analysis and Imaging (Kluwer Academic, 2003) ISBN 0306481871
  • Roger L. Easton, Jr., Fourier Methods in Imaging (John Wiley & Sons, 2010) ISBN 9780470689837 DOI 10.1002/9780470660102
  • Robert D. Fiete, Modeling the Imaging Chain of Digital Cameras (SPIE Press, 2010) ISBN 9780819483393