SU1137515A1 - Device for reproducing data from reflective medium - Google Patents

Abstract

Information reproducing apparatus C OTRAZHAKSHSCHGO carrier comprising optically coherent radiation source, a beam splitter, a quarter-wave plate, a lens element a variable-focal length, the focus sensor with photosensitive surface and a correction unit connected to the two electrodes of the element a variable-focal length, disposed on substrates and separated by an annular dielectric gasket, which is so that, in order to increase the autofocusing speed of the radiation, A DC amplifier is inserted in it, the input of which is connected to the output of the focusing sensor, and the output is connected to the input of the correction unit, the radiation source is located on the same optical ocrf with the focusing sensor, the photosensitive surface of which is perpendicular to the focal plane of the element with a variable focal length, one of the substrates of the element with a variable (L focal length is made elastic; go; and on its outer side there is a stripped electrode with a specular reflecting surface, while the quarter-wave lastinka disposed between used: source of radiation and a beam splitter. : ate a

Description

The invention relates to an instrument design, in particular, to devices for reproducing information recorded on optical reflecting media in analog and digital form. An optical information reproducing device is known, comprising a radiation source, a beam splitter, a lens located between the turns of a coil placed in a field permanent magnets, as well as a focus sensor, a lens position control unit relative to the disturbing medium, and an information signal extraction system 1 j. The disadvantage of this device is the complexity of the design and the low speed of the autofocus system. The closest to the proposed technical essence and the achieved result is a device containing an emitter on the optical axis, a beam splitter, a mirror, an element with a variable focal distance, a lens, a quarter-wave plate, and also a focusing sensor, whose input optically coupled to the beam splitter, and the output through the correction unit is connected to the input of an element with a variable focal length made of lenses with liquid crystal a 2j. A disadvantage of the known device is low reliability due to the use of an adjustable focal length lens with liquid crystals as an element with an increased temperature sensitivity, vibration sensitivity, in addition, the device requires high voltage for control, and also has a low speed and a narrow dynamic range, The purpose of the invention is to increase the speed of the autofocus of the radiation. To achieve the goal, a device for reproducing information from a reflective medium contains an optically matched source of radiation, a beam splitter, a quarter-wave plate, a lens, an element with a change in eFlJM focal length, a focus sensor with a photosensitive surface, and a correction unit connected to two electrodes of the element variable focal distance, spaced 5 on the substrates and separated by an annular dielectric gasket, is introduced. A DC amplifier, whose input is connected focus sensor output, and the output with the input of the correction unit, the radiation source is located on one optical axis with a focus sensor, the photosensitive surface of which is perpendicular to the focal plane of the element with a variable focal length, and one of the substrates of the element with a variable focal distance made elastic, and on its outer side is an electrode with a specularly reflective surface, with a quarter-wave plate located between the source. radiation and a beam splitter. Fig. 1 is a schematic diagram of the device; in fig. 2 structures of an element with a variable focal distance in the form of a mirror conductive membrane with an electrode; Fig. 3 is a plot of the displacement of the center of the membrane from the applied control voltage. The device (FIG. 1) contains a radiation source 1, a quarter-wave plate 2, a beam splitter 3, a variable focal length element 4, a lens 5, a focus sensor 6, a DC amplifier 7, a correction unit 8, and an optical medium 9. Execute. The element (FIG. 2) contains a substrate 10, an electrode P, an annular dielectric gasket 12 and a membrane 3. The device operates as follows. The light beam generated by the radiation source 1, after passing through the wavelet plate 2, is reflected by the beam splitter 3 to the element 4 with a changeable focal length, reflected from which the beam splitter 3 passes and is focused by the objective 5 on the surface of the reflecting optical medium 9.. The reflected beam from the surface of the carrier (and modulated by information) again passes the lens 5 and reflects the beam split 3 to the focus sensor 6, which debris holds an astigmatic lens and a four-element photodetector with an electronic system for extracting the information signal and the defocus signal (not shown) . The defocus signals correspond to the deviation of the information carrier 9 in one direction or another relative to the focal plane of the lens 5. Element 4 with an adjustable focal distance contains a non-conductive substrate 10 on which electrode 1.1 is deposited, as well as an annular dielectric gasket 12 with a diameter greater than the light diameter of the radiation beam reflected to the actuator by the beam splitter 3. On an annular dielectric gasket, 12 a conductive membrane is bendable flexible, the wound 13 is supported on a substrate The second electrode is applied with a specularly reflective surface. The substrate can be made of a polymeric material (for example, a collodion or lavsan 0.1–0.2 μm thick), element D is placed in the housing and protected from the membrane side by a transparent material. In the presence of a defocus signal voltage, a conductive membrane 1 under the action of electrostatic forces interacting with electrode 11 will be more or less attracted to it depending on the sign and magnitude of the defocus signal. In this case, the deformed membrane, is a parabolic sparkle, the focal length of which depends on the applied voltage. For example, if, as a result of vertical beats, the disk medium deviates down (up) relative to the {horizontal position (Fig. 1), the focus sensor 6 produces a negative (positive) signal, which through the correction unit 8 arrives at the element with variable focal distance. As a result, for small disc beats (1-200 µm), the potential between the membrane 13 and the electrode 11 decreases (increases) by an amount proportional to the displacement of the carrier 1 from the horizontal position. Therefore, the curvature of the parabolic surface of the membrane 13 under the action of attractive forces also decreases accordingly (increases). Following TejibHo, lens 5 will focus the light beam of the source 1 of cHOBia radiation onto carrier 9, namely above (below) relative to the initial position at the corresponding point. "(Fig. 3), the focusing sensor 6 is illuminated by radiation of a constant intensity that passes through the beam splitter directly from the source of radiation 1, and the bias voltage is produced by the amplifier 7 of direct current. In order to eliminate the interaction of the light beam emitted from the source 1 with the light beam reflected from the beam splitter 3, the quarter-wave plate 2 is located between the radiation source and the beam splitter, and the beam splitter is polarized. The proposed device allows you to increase the speed of the autofocusing system to 50 kHz with small vertical beats of the carrier due to the element with a variable focal distance in the form of a single inertia mirror membrane, does not require an increased voltage to control, compactly, technologically in production, because the actuator is implemented using integrated technology methods.

Claims (1)

'' DEVICE FOR PLAYING INFORMATION FROM A REFLECTING MEDIA, containing an optically matched radiation source, a beam splitter, a quarter-wave plate, a lens, an element with a variable focal length, a focus sensor with a photosensitive surface and a correction unit connected to two electrodes of the element with a variable focal length and located separated by a ring dielectric spacer, unlike with the fact that, in order to increase the speed of autofocusing of radiation, a direct current amplifier is connected, the input of which is connected to the output of the focusing sensor, and the output is connected to the input of the correction unit, the radiation source is located on the same optical axis * as the focusing sensor, whose photosensitive surface is perpendicular to the focal plane of the element with a variable focal length, one of which is the substrates of the element with a variable focal length are made up; it is a solid one, and on its outer side there is an electrode with a mirror-reflecting surface I, and a quarter-wave plate is located between the radiation source and the beam splitter.