SU1753489A1 - Optomechanical memory unit - Google Patents

Abstract

The invention relates to instrumentation, in particular to devices for recording or reproducing information. In order to improve the accuracy and reliability of recording and reproduction, a selector by level, three analog keys, three difference amplifiers and an analog adder are introduced into the device, the photodetector unit being in the form of one direct and offset relative to each other photodetectors, 4 Cp f-ly, 7 ill.

Description

The invention relates to devices for recording and / or reproducing information with the mutual relative movement of optical media and optical heads and can be used in information technology, for example, digital video recording devices, digital audio recording devices, and optical external computer storage devices.

A reader device from an optical recording medium containing an optically coupled radiation source, a beam splitter with a second optical output which couples the optical input of the photoreceiver node, and a focusing lens, as well as focusing and tracking drives, are connected to the electrical inputs of which are connected. management, respectively, autofocus and auto-tracking. In order to improve the accuracy and reliability of recording and / or reproduction in the presence of defects on the carrier, the error signals of the autofocusing and auto-tracking systems are limited.

The disadvantage of the analog is the low accuracy and reliability of recording and / or reproducing information, due to the fact that when limiting the signals of coordination of autofocusing systems and auto-tracking, the feedback loops (/) are opened and the tracking is stopped accordingly.

Closest to the proposed S technical entity is the method of suppressing the tracking error in a playback device from a disk, according to which in the device containing an optical VJ coupled three-beam radiation source (L beam splitter, with a second optical output,) which the photodetector unit uch. on the basis of a six-site photo-QQ receiver, and a focusing lens, as well as the focus watering and tracking of the track, the electrical inputs of which are connected to the auto-focus and auto-tracking control units, respectively. In this case, the six-site photodetector is made in the form of three photodetectors located on one straight line, each of which has its own reflected beam. The outermost photodetectors are single-slot, and the central one is four-plane. In order to increase the stability of the autofocus systems and

Auto-tracking loop gain in them decreases with increasing magnitude of the sum signal from the four sites of the central photodetector.

The disadvantage of the prototype is the low accuracy and reliability of recording and / or reproduction, due to the fact that the occurrence of defects in the recording layer decreases the tracking accuracy in autofocus and auto-tracking sections.

The aim of the invention is to improve the accuracy and reliability of recording and / or reproducing information.

FIG. 1 single autofocus system; in fig. 2 - auto tracking system; in fig. 3 - the same, the first option; in fig. 4 - the same, the second option; in FIG. 5 a level selector; in fig. 6 - the same, option; in fig. 7 shows the placement of the projections of four-field photodetectors on the tracks of the optical information carrier.

The autofocusing system (Fig. Includes an optically coupled three-beam radiation source 1 (for example, a diffraction grating laser or a line of semiconductor lasers), a beam splitter 2, with a second optical output conjugated by three straight-four photodetector 3 on one straight line -5, focusing lens 6 and movable optical information carrier 7 (disk, cylindrical, tape or other), Diagonally located first 8 and third 9 platforms of the first four-area photodetector 3 Linked to the inputs of the first analog adder 10, and diagonally located second 11 and fourth 12 platforms of the same photodetector 3 are connected to the inputs of the second adder 13. Diagonally located first 14 and third 15 platforms of the second four-site photodetector 4 are connected to the inputs of the third analog adder 16, and the second 17 and fourth 18 pads of the same four-site photodetector 4 are connected to the inputs of the fourth analog adder 19. Diagonally located first 20 and third 21 pads of the third four-square of the full-time photodetector 5 is connected to the inputs of the fifth analog adder 22, and the second 23 and fourth 24 pads of the same photodetector 5 are connected to the inputs of the sixth analog adder 25. The first 10, second 13, third 16, fourth 19, fifth 22 and sixth 25 analog adders can be made according to the current-voltage converter circuit. The outputs of the first 10 and second 13 analog adders through the seventh analog adder 26 are connected to the first input of the selector 27 by the level (Fig. 5 and 6). The outputs of the third 16 and fourth 19 analog adders through the eighth analog adder 28 are connected to the second input of the selector 27 level. The outputs of the 22 and sixth 25 analog adders through the ninth analog adder 29 are connected to the third input of the selector 27 by levels. In addition, the output of the first analog adder 10 is connected to one input of the first differential amplifier 30, to the other input of which the output of the second analog adder 13, the output of the third analog adder 16 is connected to one input of the second differential amplifier 31, to the other input of which is connected the output of the fourth analog adder 19. The output of the fifth analog adder 22 is connected It is connected to one input of the third differential amplifier 32, to the other input of which is connected the output of the sixth analog adder 25. The outputs of the first 30, second 31 and third 32 difference amplifiers are connected to the signal inputs of the first 33, second 34 and third 35 analog keys, respectively. The first, second and third outputs of the selector 27 are connected to the control inputs of the first 33, second 34 and third 35 analog switches respectively. The outputs of the first 33, second 34 and third 35 analog keys connected to the three inputs of the tenth of the analog adder 36,

The auto-tracking system (Fig. 2) includes optically coupled three-beam radiation source 37, a beam splitter 38, the second optical output of which couples the first 39, the second 40, and the third 41 four-site photodetectors, a focusing lens 42 and a movable optical information carrier 43. All four outputs of the first four-site photodetector 39 and adjacent two sites of the second four-site photodetector 40 are connected to the six inputs of the first analog adder

44. The four outputs of the third four-site photodetector 41 and two adjacent sites of the second four-site photodetector 40 are connected to the six inputs of the second analog adder

45, The outputs of the first 44 and second 45 analog adders are connected to two inputs of the differential amplifier 46.

The auto-tracking system (FIG. 3) includes optically coupled three-beam radiation source 47, a beam splitter 48, c

the second optical output of which couples are located on one straight first 49, second 50 and third 51 four-area photodetectors, a focusing lens 52 and a movable optical information carrier 53. The pads of the first four-site photodetector 49 connected in pairs in parallel to the tracks on the carrier 53 are connected respectively to the first 54 and second 55 analog adders. The platforms of the second four-site photodetector 50 connected in pairs in parallel to the tracks on the carrier 53 are connected to the third 56 and fourth 57 analog adders, respectively. The first 54, the second 55, the third 56, the fourth 57, the fifth 58 and the sixth 59 analog adders can be made according to the current-voltage converter circuit. The platforms of the third four-site photodetector 51, which are paired in parallel to the tracks on the carrier 53, are connected to the fifth 58 and sixth 58 analog adders, respectively. The outputs of the first 54 and sixth 59 analog adders are connected to two inputs of the first differential amplifier 60. The outputs of the second 55 and fifth 58 analog adders are connected to two inputs of the second differential amplifier 61, The outputs of the third 56 and fourth 57 analog adders are connected to two inputs of the third difference amplifier 62 The outputs of the first 60, second 61 and third 62 difference amplifiers are connected to the inputs of the fifth analog adder 63.

The auto-tracking system (Fig. 4) includes an optically coupled three-beam radiation source 64, a beam splitter 65, the second optical output of which couples the four-area photodetectors located on one straight first 66, the second 67 and the third 68, and a focusing lens 69 and movable optical information carrier 70. The outputs of all four sites of the first four-site photodetector 66 are connected to the four inputs of the first analog adder 71. The outputs of all four sites of the third four-site photoreceiver 68 are connected to four inputs of the second analog adder 72, Pairwise connected in parallel to the tracks on the carrier 70, the sites of the second photodetector 67 are connected respectively to the third 73 and fourth 74 analog adders. The first 71, the second 72, the third 73, and the fourth 74 analog adders can be made according to the current-voltage converter circuit. Outputs first71

and the second 72 analog adders are connected to the input of the first differential amplifier 75. The outputs of the third 73 and fourth 74 analog adders are connected to the inputs of the second differential amplifier 76 and the fifth analog adder 77. The outputs of the first 71, second 72 and fifth 77 analog adders are connected to three the inputs of the selector 78 by level. The two outputs of the selector 7, 8 are connected through a logic circuit OR 79 to the control input of the first analog switch 80, to the signal input of which the output of the first differential amplifier 75 is connected. The third output of the collector 78 is connected to the control input of the second analog switch 81, to the signal input of which the output of the second differential amplifier 76 is connected. Outputs of the first 80 and second 81 analog

0 keys are connected to the inputs of the sixth analog adder 82.

The level selector (27) 78 (FIG. 5) includes the first 83, the second 84, and the third 85 comparators with the first 86, the second 87, and the third 88, connected to their logic, NOT. The first input of the selector (27) 78 is connected to the non-inverting input of the first comparator 83, and the second input is connected to the inverting input

0 selector (27) 78. The second input of the selector (27) 78 is connected to the non-inverting input of the second comparator 84, and the third input of the selector (27) 78 to the inverting input. To a non-inverting input

5 of the third comparator 85, the third input of the selector (27) 78 is connected, and the first input of the selector (27) 78 is connected to the inverting input. The outputs of the first comparator 83 and the main circuit are connected to the first input of the selector (27) 78 through the first logic circuit 89 the NOT 88 logic circuit. To the second output of the selector (27) 78 via the second logic circuit 88. To the second output of the selector (27) 78, the outputs of the second comparator 87 and the first logic circuit HE 86 are connected to the third output circuit. selector (27) 78 through the third logic circuit And 91 connected outputs the third comparator 85 and the second logical scheme NOT.

The selector on the level (27) 78 (Fig. 6) includes the first 92 and second 93 comparators, to the outputs of which the first 94 and second 95 logical NOT circuits are connected, respectively. The first input of the selector (27) 78 is connected to the non-inverting input of the first comparator 92, and the second input of the selector (27) 78 is connected to the input of the second selector. The second input of the selector (27) 78 is connected to the non-inverting input of the second comparator 93, and the third input of the selector (27) 78. To the first output of the selector (27) 78 through the first logic circuit And the outputs of the first 92 and second 93 comparators are connected. To the third output of the selector (27) 78 through the third logic circuit AND 97 are connected the outputs of the first 94 and second 95 logical circuits NOT. To the second output of the selector (27) 78 is connected the output of the second logic circuit 98, to one input of which through the third logic circuit NOT 99 the output of the first logic circuit 96 and 96 is connected, and the output of the third logic circuit 97 is connected to the other input circuit 100. .

Optical-mechanical storage device operates as follows.

In the autofocusing system (FIG. 1), due to the presence in the optical path of a cylindrical lens (not shown) the beating of the optical information carrier 7 during its movement while recording or reproducing information is accompanied by a change in the shape of the incident on the first 3, second 4 and third 5 four-area photodetectors of rays . The ratio of the semi-axes of the light spot ellipse changes in the directions corresponding to the diagonal and four-site photodetectors 3-5. Therefore, the signals corresponding to the semiaxes of the ellipses are formed by the first 10, second 13, third 16, fourth 19, fifth 22 and sixth 25 analog adders connected to the corresponding diagonally combined sites of four-site photodetectors 3-5. And in the first 30, second 31, and third 32 difference amplifiers, signals are formed corresponding to the semi-axes of the ellipses of the light spot on the first 3, second 4, and third 5 photodetectors, i.e. the mismatch signals corresponding to the first, second and third beams. At the same time, in the seventh 26, eighth 28 and ninth 29 analog adders, signals are formed corresponding to the total illumination of the first 3, second 4 and third 5 photodetectors. Of these signals, the selector 27 determines the highest level and delivers a control signal to the control input of one of the analog switches 33-35. Therefore, the node (not shown) of the autofocus control through the tenth analog adder 36 passes the error signal corresponding to that of the three beams incident on the photodetector 3-5, which corresponds to the maximum sensitivity of the photo sensor of the error signal and, therefore, to the maximum loop gain i / highest accuracy of autofocus.

The system of auto-tracking (Fig. 2) works as follows. Due to the beating of the rotating information emitted by the information of the optical carrier 43 of the information emitted by the three-beam source 37, which are radiated by a three-beam source 37, the radiation is focused on information and

0 reference tracks can occupy a different position (Fig. 7 a, b). The error signal, which determines the position of the central beam relative to the monitored information track, is formed in the difference amplifier 46, the inputs of which are connected to the outputs of the analog adders 44 and 45. Thus, in the generation of the error signal according to this variant

0 three beams. The advantage of this variant is the highest sensitivity of the photosensor of the error signal, the disadvantage is the dependence of the sensitivity of the photosensor under any of the three beams.

5 The auto-tracking system (Fig. 3) implements the same as in FIG. 2, the error signal generation algorithm, using only other electronic components. Therefore, this option has the same advantages and disadvantages as the previous one.

The system of auto-tracking (Fig. 4) works as follows. In the first differential amplifier 75, a mismatch signal is formed, corresponding to the difference of the illuminations of the outer photodetectors (Fig. 7). In the second difference amplifier 76, an error signal is generated corresponding to the luminance difference.

0 sites of the central photodetector, adjacent to the left and right edges of the information track (Fig. 7). And in the selector 78, one of these two mismatch signals is selected by level. Moreover, the choice is made according to the results of comparing the magnitude of the signals at the output of the first 71, second 72, and that 77 adders, corresponding to the total luminance of the first 66, second 67, and third 68

0 photodetectors, on each of which a reflected beam falls, And if one of the extreme rays has the greatest intensity, to selector 78, on the level, unlocks the first analog key 80 and, therefore, 5 passes the error signal from the first analog output 82 through the sixth analog adder 75 difference amplifier. If the central beam has the greatest intensity, then

the signal generated in the selector 78 by

level, the second analog key 81 is unlocked and, therefore, the output of the mismatch signal generated by the second difference amplifier 76,

The selectors 27 and 78 level (Fig. 5) work as follows. The first comparator 83 compares the levels of unipolar signals at the first and second inputs. In the second comparator 84, the levels of unipolar signals at the second and third inputs are compared. In the third comparator 85, the levels of the unipolar signals at the first and third inputs are compared. At the output of the first logic circuit And 89, a signal is formed that corresponds to the condition

V1 (U1 U2) A (), which is executed when the signal at the first input is greatest. The output of the second logic circuit AND forms a signal corresponding to the condition

V2 (U1 U2) A (U2 U3), which is performed in the case where the signal at the second input is greatest. The output of the third logic circuit AND forms a signal corresponding to the condition

V3 (U2 U3) L (U3 U1), which is performed in the case where the signal at the third input is greatest.

The selectors 27 and 28 level (Fig. 6) works as follows. In the first comparator 92, unipolar signals are compared in magnitude at the first and second inputs. In the second comparator, the signals at the second and third inputs are compared in magnitude. At the output of the first logic circuit 96, a signal is formed that corresponds to the condition

V1 (U1 U2) A (U2 U3), which is performed in the case where the signal at the first input is the highest. At the output of the second logic circuit 98, a signal is formed, corresponding to

V2 (U1 U2) (U2 (U1 U2 (U2 U3),

which is performed in the case where the signal at the second input is greatest. And finally, at the output of the third logic circuit AND 97, a signal is formed that corresponds to the condition

V3 (U1 U2) A (U2 U3), which is performed in the case where the signal at the third output is greatest.

Claims (3)

Claims 1, An optomechanical memory device containing optically coupled three-beam radiation source, a beam splitter with a second optical output which couples the optical input of the photoreceiving unit, and a focusing lens, as well as a focusing and tracking drives that have control nodes connected to their electrical inputs respectively, autofocusing and autotracking, characterized in that, in order to increase the accuracy and reliability of recording and reproducing information, a level selector is introduced into it, three analogs the output key, three differential amplifiers and an analog adder, while the photodetector unit is made up of tracks located on one straight and offset from each other across half of the recording step of three four-area photodetectors, and the diagonally combined photosensitive pads of each four-area photodetector are connected respectively to three differential amplifiers that are connected via three analog switches to an analog adder connected to the input of the autofocus control unit; When in use, to the control inputs of analog switches connected to three outputs of the level selector to the three inputs of which are connected three analog adder, each of which is connected to the four photosensitive area of its photodetector. 2. The device according to claim 1, characterized in that a differential amplifier is connected to the input of the auto-tracking control unit, two inputs of which are connected to analog adders, each of which is connected to the outputs of four photosensitive areas of one of the four most extreme photodetectors and two adjacent photosensitive areas of the four central area - photo detector. 3. The device according to claim 1, that is, so that the four photosensitive sites of each of the extreme four-way photodetectors are connected respectively to the inputs of the first and second analog adders, the outputs of which are connected to the input of the first differential the amplifier, and the photosensitive areas of the central four-area photodetector adjacent to the extreme four-site photoreceivers are connected in pairs to the third and fourth analog adders, whose outputs are connected to the inputs of the fifth analog adder and the second differential amplifier, the outputs of the first, second and fifth analog adders are connected to three selector inputs by level, two outputs of which are connected through the logic circuit OR to the control input of the first analog switch, and the third output of the selector level is connected to the control input of the second analog switch, the output of the first differential amplifier is connected to the signal input of the first analog switch, the output of the second analog switch is connected to the signal input of the second analog switch first differential amplifier, the outputs of the first and second analog switches are connected to two inputs of the sixth analog adder, and the output of the latter is connected to the input of the auto-tracking control node. 4, The device according to PP, 1 and 3, is of such kind that the level selector contains three comparators, the non-inverting input of the first of which is combined with the first input of the selector, and the inverting input is combined with the second input the selector, the non-inverting input of the second comparator is combined with the second input of the selector, and the inverting input is combined with the third input of the selector, the non-inverting input of the third comparator is combined with the third input of the selector, and the inverting input is combined with the first input of the selector, first, second and third logical kie schemes NOT connected respectively to the outputs of the first, second, third comparators, as well as the first, second and third logic circuits AND, and the inputs of the first comparator and the third logical circuit NOT are connected to the inputs of the first logic circuit 4 the outputs of the second comparator and the first logic circuit is NOT; the outputs of the third comparator and the second logic circuit are NOT connected to the inputs of the third logic circuit AND. 5. The device according to PP. 1 and 3, that is, so that the level selector contains the first and second comparators, the non-inverting input of the first of which is combined with the first input of the selector, and the inverting input is combined with the second the input of the selector, the non-inverting input of the second comparator is combined with the second input of the selector, and the inverting input is combined with the third input of the selector, the first and second logical circuits are NOT connected respectively to the outputs of the first and second comparators, and the first and second to the inputs of the first logic circuit AND the outputs of the first and second comparators are connected, to the inputs of the third logic circuit AND the outputs of the first and second logic circuits are NOT, and to the inputs of the second logic circuit And outputs the first and third logical circuits AND are connected respectively via the third and fourth logical circuits NOT.  FIG. 2 (-Rig. 3 CJejfc6L FIG 4 FIG. five 1753489 eL. g. - Fig 6 FIG. 7 I / I // / V V. l /, /  /