RU2011133280A - METHOD AND DEVICE FOR RECORDING MICROHOLOGRAMS - Google Patents

Abstract

1. A method for recording microholograms, which includes performing the following operations: - exposing a photosensitive material by means of an interference pattern formed by a reference beam from a laser source of coherent radiation and a signal beam from a laser source of coherent radiation; a source of incoherent radiation, characterized in that both of these operations are performed simultaneously. 2. The method according to claim 1, characterized in that the photopolymer, dichromated gelatin or galloid-silver emulsion is used as the photosensitive material. The method according to claim 1, further comprising modulating the intensity of the signal beam with a spatial light modulator. An optical device for recording microholograms, consisting of a laser source of coherent radiation, a source of incoherent radiation, an optical system for dividing the initial beam, an optical system for generating a signal beam, a spatial light modulator, a Fourier lens, an optical system for forming a reference beam, an optical system for generating radiation from a source of incoherent radiation, a photosensitive material, a mechanical positioning system, characterized in that it includes: a laser source of coherent radiation, made with the possibility of temporal modulation of the flux; a source of incoherent radiation, made with the possibility of temporal modulation of the radiation flux and operating

Claims (12)

1. The method of recording microholograms, which includes the following operations: - exhibiting a photosensitive material by means of an interference pattern formed by a reference beam from a laser source of coherent radiation and a signal beam from a laser source of coherent radiation; - increase the energy of the photosensitive material by additional exposure of the photosensitive material by radiation from a source of incoherent radiation; characterized in that both of these operations are performed simultaneously. 2. The method according to claim 1, characterized in that as a photosensitive material using a photopolymer, dichromated gelatin or a galloid-silver emulsion. 3. The method according to claim 1, characterized in that it further includes modulating the intensity of the signal beam with a spatial light modulator. 4. An optical device for recording holograms, consisting of a laser source of coherent radiation, an incoherent radiation source, an optical system for dividing the initial beam, an optical system for generating a signal beam, a spatial light modulator, Fourier Lenses, an optical system for generating a reference beam, an optical system for forming radiation from a source of incoherent radiation, a photosensitive material, a mechanical positioning system, characterized in that it includes yourself: a laser source of coherent radiation, configured to temporarily modulate the flow; a source of incoherent radiation, configured to temporarily modulate the radiation flux and operating synchronously with a laser source of coherent radiation; optical system for dividing the initial beam into signal and reference beams; an optical system for generating a signal beam and modulating it with a calculated image; spatial light modulator for modulating the signal beam with a recorded image; Fourier Lens, made with the possibility of focusing the incident modulated signal beam emerging from the spatial light modulator, in the plane of the photosensitive material; an optical system for forming a reference beam, performing the function of an optical delay line of a reference beam, shaping the reference beam in the plane of the photosensitive material and forming at a given point of the photosensitive material a uniformly bright light field; an optical system for generating radiation from an incoherent radiation source, configured to convert and direct radiation from an incoherent radiation source to a predetermined location; a photosensitive material configured to maintain a pattern of interference of the focused modulated signal and reference beams; a mechanical positioning system that controls the relative position of the photosensitive material and other elements of the device. 5. The optical device according to claim 4, characterized in that said incoherent radiation source, configured to temporarily modulate the flow and operating synchronously with a laser coherent radiation source, is made in the form of a laser radiation source with a spatial coherence length less than twice the thickness of the photosensitive material substrate and the radiation wavelength that matches the radiation wavelength of the laser source of coherent radiation. 6. The optical device according to claim 4, characterized in that the incoherent radiation source, configured to temporarily modulate the flow and operating synchronously with the laser source of coherent radiation, is made in the form of a laser radiation source with a low degree of spatial coherence and a radiation wavelength that does not match with a wavelength of radiation from a laser source of coherent radiation. 7. The optical device according to claim 4, characterized in that the incoherent radiation source, configured to temporarily modulate the flow and working synchronously with the laser source of coherent radiation, is made in the form of an LED radiation source that generates radiation in a wide wavelength range, including a wavelength radiation from a laser source of coherent radiation. 8. The optical device according to claim 4, characterized in that the incoherent radiation source, configured to temporarily modulate the flow and working synchronously with the laser source of coherent radiation, is made in the form of an LED radiation source that generates radiation in a wide wavelength range, not including a length radiation waves of a laser source of coherent radiation. 9. The optical device according to claim 4, characterized in that the optical system for generating radiation from an incoherent radiation source is configured in such a way as to introduce the generated incoherent radiation into the optical system to form a reference beam with the possibility of further propagation through the optical system together with the reference beam . 10. The optical device according to claim 4, characterized in that said optical system for generating radiation from an incoherent radiation source is configured in such a way as to introduce the generated non-coherent radiation into the optical system for generating a signal beam with the possibility of further propagation through the optical system for generating additional signal beam, in parallel with the signal beam. 11. The optical device according to claim 4, characterized in that the optical system for generating radiation from an incoherent radiation source is configured to introduce the generated incoherent radiation simultaneously into the optical system to form the reference beam and into the optical system to form the signal beam with the possibility of further propagation, through the optical system to form an additional reference beam, in parallel with the reference beam and through the optical system to form additional ADDITIONAL signal beam, in parallel with the signal beam. 12. The optical device according to claim 4, characterized in that the optical system for generating radiation from a source of non-coherent radiation is made in such a way as to direct the generated incoherent radiation to a given point of the photosensitive material.