Holography
Holography may be defined as lens-less three dimensional photography. In fact it is a method of recording and reconstruction an object in its entirety. This definition conforms to the choice of the word 'holography', derived from two words 'holes' (complete) and 'graphs' (writing). The underlying principle of holography were formulated by British Scientist Dennis Gabor in 1948, in an attempt to improve the resolving power of electron microscopes. However the practical development of optical holography and its numerical applications were made possible only after the advent of the laser. The reason for this is that holography is an interference based technique and requires highly coherent beam of light.
principle of holography
The basic principle of holography is to create the image using two simultaneous beams of light, that interfere with each other to form a complex image on a suitable photographic film. These two beams of lights are created by splitting a light source in two with one source reflecting light from the object to be photographed on the film and the other falling directly on it from the source. The image developed in this way is the hologram. The light source used for holography is usually a laser light.
When light from any source falls on the film hologram, it changes this light to reconstruct the light pattern of original object, creating a three dimensional image.
Holography operates in two stages namely recording and reconstruction. Recording is the process of making the hologram and reconstruction is the process of reading the hologram.
When light from any source falls on the film hologram, it changes this light to reconstruct the light pattern of original object, creating a three dimensional image.
Holography operates in two stages namely recording and reconstruction. Recording is the process of making the hologram and reconstruction is the process of reading the hologram.
(a) Recording of hologram
The recording of hologram is based on the phenomenon of interference. It requires a laser source, a plane mirror or beam splitter, an object and a photographic plate. A laser beam from the laser source is incident on a plane mirror or beam splitter. As the name suggests, the function of the beam splitter is to split the laser beam. One part of splitted beam, after reflection from the beam splitter, strikes on the photographic plate. This beam is called reference beam. While other part of splitted beam (transmitted from beam splitter) strikes on the photographic plate after suffering reflection from the various points of object. This beam is called object beam.
The object beam reflected from the object interferes with the reference beam when both the beams reach the photographic plate. The superposition of these two beams produces an interference pattern (in the form of dark and bright fringes) and this pattern is recorded on the photographic plate. The photographic plate with recorded interference pattern is called hologram. Photographic plate is also known as Gabor zone plate in honour of Denis Gabor who developed the phenomenon of holography.
Each and every part of the hologram receives light from various points of the object. Thus, even if hologram is broken into parts, each part is capable of reconstructing the whole object.
The object beam reflected from the object interferes with the reference beam when both the beams reach the photographic plate. The superposition of these two beams produces an interference pattern (in the form of dark and bright fringes) and this pattern is recorded on the photographic plate. The photographic plate with recorded interference pattern is called hologram. Photographic plate is also known as Gabor zone plate in honour of Denis Gabor who developed the phenomenon of holography.
Each and every part of the hologram receives light from various points of the object. Thus, even if hologram is broken into parts, each part is capable of reconstructing the whole object.
(b) Reading (Reconstruction) OF HOLOGRAM
In the reconstruction process, the hologram is illuminated by laser beam and this beam is called reconstruction beam. This beam is identical to reference beam used in construction of hologram.
The hologram acts a diffraction grating. This reconstruction beam will undergo phenomenon of diffraction during passage through the hologram. The reconstruction beam after passing through the hologram produces a real as well as virtual image of the object.
The hologram acts a diffraction grating. This reconstruction beam will undergo phenomenon of diffraction during passage through the hologram. The reconstruction beam after passing through the hologram produces a real as well as virtual image of the object.
One of the diffracted beams emerging from the hologram appears to diverge from an apparent object when project back. Thus, virtual image is formed behind the hologram at the original site of the object and real image in front of the hologram. Thus an observer sees light waves diverging from the virtual image and the image is identical to the object. If the observer moves round the virtual image then other sides of the object which were not noticed earlier would be observed. Therefore, the virtual image exhibits all the true three dimensional characteristics. The real image can be recorded on a photographic plate.
APPLICATION of holography
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