SU1153353A1 - Device for reproducing information from disk optic medium - Google Patents

Abstract

DEVICE (reproducing information from DISKOYUGO optical recording medium, comprising: sequentially set on an optical axis of the radiation source, soglasuitsuyu lens, a polarization beam splitter, a quarter-wave plate, a movable mirror and lens, and the photodetecting system is optically conjugated with a polarizing beam splitter, wherein that, in order to improve quality by eliminating interference noise, an additional quarter-wave plate was inserted into it, which ene between the radiation source and the matching lens, wherein its main directions are inclined at 45 to the main plane of polarization beam-splitting element. Pb /

Description

1 The device relates to the reproduction of information by optical media and can be used in laser video and audio players. A device for reproducing information is known, containing a polarizing beam-splitting element, a movable mirror and a quarter-wave plate, a movable mirror and a lens, as well as a photodetector node fl3. The device has an interference noise that occurs as a result of changing the state of polarization of the carrier of information, which reduces the quality of reproducible information. The closest in technical essence and the achieved result to the suspect is a device containing an optically conjugated radiation source, a weakening element, a matching lens, a polarizing beam-splitting element, a movable mirror, a quarter-wave plate, an objective lens and a photo-receiving unit 2. The introduction of a attenuator allows a partial reduction of the interference noise, but this also leads to a reduction in the information signal by as many times as the interference noise decreases, which reduces the reliability of the device. The purpose of the invention is to enhance the caustic by eliminating interference noise. This goal is achieved by the fact that a device for reproducing information from a disk optical carrier, containing a radiation source, successively installed on the optical axis, a matching lens, a polarizing beam-splitting element, a quarter-wave plate, a moving mirror and an objective, and a photodetector system optically conjugated with the field a beam-splitting element, an additional quarter-wave plate is inserted, which is installed between the radiation source and the matching lens, this is its main directions are inclined at 45 to the main plane of polarization beam-splitting element. 3i In FIG. 1 shows a diagram of the device; Fig. 2 illustrates the change in the state of polarization of the radiation as it passes to the carrier; in fig. 3 a change in the polarization state of the radiation reflected from the carrier; Fig. 4 illustrates the change in the polarization state of the radiation reflected from the radiation source. The device contains a source of radiation I, an additional quarter-wave plate 2, a mirror 3, a matching lens 4, a polarization beam-splitting element 5, a quarter-wave plate 6, a movable mirror 7, a movable lens 8, an information carrier 9 and a photodetector system 10. FIG. The 2–4 arrows with the feathers and the letter V indicate the direction of radiation propagation, the arrows without feathers and the letters EO, E, E and E indicate the direction of polarization of the radiation coming from the source separated by the beam-splitting element reflected by the information carrier and passing to the photodetector and source radiation, respectively. I, the device works as follows. The linearly polarized beam E of the radiation source 1 falls on an additional quarter-wave plate 2, where it acquires circular polarization E (FIG. 2}. Then it reflects from mirror 3, passes the matching lens 4 and falls on the polarization beam-splitting element 5 (FIG. 1) The beam is divided into two linearly polarized beams with equal intensities E, one of which (with vertical polarization) is reflected, and the other (with horizontal) passes further (Fig. 2). Thus, half of the radiation power is lost. source IR radiation with circular polarization, then after an additional quarter-wave plate 2, the radiation has horizontal polarization, which will be completely ignored by the polarization beam-splitting element 5, i.e. there will be no power loss. The radiation with horizontal polarization passed the polarization beam-splitting element 5 falls on a quarter-wave plate 6, where it is converted into radiation, polarized in a circle. Further, the radiation is reflected from the movable mirror 7 and is focused under the movable lens -8 onto the carrier 9. The carrier-modulated lens 8, modulated by the carrier information, is reflected from the mirror 7 and hits the quarter-wave plate 6. In the absence of depolarization of the carrier radiation and if the radiation fell on a quarter-wave plate in parallel, the polarization of the radiation transmitted by the quarter-wave plate 6 from the information carrier 9 would be strictly vertical and the radiation would be completely reflected by the polarization light However, these conditions are not fulfilled and, along with vertical polarization E, after the quarter-wave plate 6, there is a small component with horizontal component polarization E2 (Fig. 3). The vertical polarization component E is reflected by the polarization beam-splitting element to the photoreceiver system 10, and the horizontal polarization component E passes through the polarization light-dividing element, the matching lens A, is reflected from the mirror 3 and 3.4 falls on an additional quarter-wave plate 2, the radiation with horizontal polarization is converted into radiation with circular polarization (Fig. 3) and falls on the output mirror of the radiation source 1 (laser). Due to the low intensity of the radiation and the high reflection coefficient of the mirror, the intensity does not increase, the reflected radiation has circular polarization. After the passage of the additional quarter-wave plate 2, the polarization of the radiation becomes vertical (Fig. 4). The radiation is then reflected from the mirror 3, passes the matching lens 4 and is reflected by the polarization beam-splitting element. Thus, this radiation is prevented from entering the photoreceiver system, and therefore the possibility of interference noise is excluded. The device allows to increase the quality of reproduced information by eliminating interference noise, while the radiation power is either attenuated by two times (the radiation source with linear polarization) or not attenuated (the radiation source with circular polarization).

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Claims (1)

DEVICE FOR PLAYING INFORMATION FROM A DISK OPTICAL MEDIA, containing a radiation source sequentially mounted on the optical axis, a matching lens, a polarization beam splitter, a quarter-wave plate, a movable mirror and a lens, and a photodetector system that is optically paired with a polarization beam splitter that In order to improve quality by eliminating interference noise, an additional quarter-wave plate is inserted into it, which is installed len between the radiation source and the matching lens, while its main directions make an angle of 45 ° with the main plane of the polarizing beam splitting element.