NL8700143A - OPTICAL CARD DEVICE FOR REGISTRATION AND / OR REPRODUCTION OF INFORMATION. - Google Patents

Description

863122 / AA / cd

Title; Optical card arrangement for recording and / or reproduction of information.

The invention relates to an optical charting device suitable for recording information on an optical chart and / or reproduction of information recorded thereon, and in particular to an optical charting device suitable for use as a miniaturized multi-application optical charting device .

An optical card device is used for recording information on a card by feeding light to its surface or for reading information already recorded on an IQ card, and has the property that the memory capacity of the device is ten to ten times larger is like an IC card. The development of an optical card device is thereby stimulated, so that this device displaces an IC card. In a known optical card device, a recording medium with a light source, such as a laser light source, is emitted beam mechanically sensed by the rotation and oscillation of a reflecting mirror for recording information bits on the recording medium or for reproduction of information recorded thereon, as described, for example, in Japanese Patent Application Laid-open No. 59542/1085 on April 5, 1985 entitled "Optical card apparatus for recording and / or reproducing information ".

In a known optical card apparatus in which the beam scanning is performed mechanically, the access time for the information or during a recording operation is determined by the natural frequency of a scanning exciter limiting access with high speed. In addition, this device has movable parts 30 which decrease the vibration resistance, life, and reliability of the device, make it complicated to build, and have large dimensions.

The object of the invention is to provide an optical card device with a high operating speed in the recording and / or reproduction of information.

A feature of the invention is that light-emitting elements of a recording and / or reading light source group for

$ 7 Λ Λ 4 τ χ '' v J i HO

* -¾ -2- recording and / or reproduction of information on an optical card, light-receiving elements of a photo-scanning group for monitoring and / or reading the information recorded on the optical card, lens elements of an intermediate light source group and the optical card mounted lens group for transmitting the light from the light-emitting elements to the optical card, and lens elements of a lens group arranged between the optical card and the photo scanning group for transmitting the light through the optical IQ card to the light receiving elements are arranged coaxially with each other in the direction of propagation of the light.

There, according to the invention, each element of the recording and / or reading light source group, the photo-scanning group, and the two lens groups coaxially opposite each other with respect to the direction of propagation. of the light through the optical card, the invention is suitable for recording and / or reproducing a variety of information at high speed without mechanical scanning of a light beam as with the known optical card device.

The invention will be elucidated with reference to the figures. In the figures shows; Fig. 1 is a block diagram of an embodiment of the device according to the invention, in which the relationship is shown between the recording and / or reading light sources, the optical card, the photo scanners and the control circuits thereof; fig. 2 shows a cross-section of an embodiment of the device according to the invention according to fig. 1; 3Q FIG. 3 is a partial sectional perspective view of a plane-emitting laser usable in accordance with the invention; Fig. 4 is a sectional view of a reading light-receiving element suitable for use in the invention; Fig. 5 shows an embodiment of a reading circuit in which the light-receiving elements of Fig. 4 are used; FIG. 6 is a diagram for explaining a function of recording, monitoring and reading information on the optical card, FIG. 6A being a. shows characteristic curve 4Q of a semiconductor laser for the driving current and its 8700143 e 4 -3 light power, Fig. 6B shows a time diagram of the light power of a semiconductor laser for emitting the light corresponding to the recording and reading-out of the information on the optical card, and Fig. 6C shows a time diagram of the photodiode current of the semiconductor laser when its monitoring takes place; Fig. 7 is a block diagram of another embodiment of the device according to the invention showing the relationship between the recording and reading light sources, the optical card, the photo scanners for monitoring and reading the data recorded on the optical card information, and its control chains; and FIG. 8 is a sectional view of the device shown in FIG. 7.

The recording and / or reading j.5 light source 1 shown in Figs. 1 and 2 preferably consists of a multilaser head consisting of a common substrate 11A, and nxm laser parts 11 arranged two-dimensionally on the common substrate 11A with a pitch of a few µm to a few tens µm, 2Q Each of these multilaser head-forming lasers 11 preferably has, for example, the construction of the semiconductor laser / light-emitting diode XX of the type emitting in one plane with coaxial crossover ( CTJl as described on pages 45 to 48 of March 1985 "Synthetic research relating to the foundation of optical computer" entitled "Fabrication and operation of 2D-arrayed CTJ type light emitting devices".

This laser 11 has a cylindrical projection in the middle portion of a flat unit 12 and is capable of emitting a laser beam as shown with an arrow from the free end portion of this projection as shown in Fig. 3. The flat unit 12 has a laminated structure consisting of a layer P-type GaAs 12D, a layer p-type GaAs 12A, a layer n-type A-GaAs 12B, a layer n-type 35 GaAs 12C with a layer of fastening wax Au / Ge-Au 13, which serves as a heat sink and is attached to the bottom portion of the flat unit 12, and a Cr-Au electrode 15,

A laser 11 to be fired is selected by a modulation chain in a coder 2Q in accordance with the register 3700143-4- *, r information supplied to the input terminal 1 connected to a microcomputer (not shown), the information corresponding to with the write current Iw shown in FIG. 6A, and the lasers 5 to be ignited and non-ignited are determined with 8-bit signals which are fed to a scanning circuit 10.

An electric current whose level exceeds a threshold value is then fed to a laser 11 to be ignited from a laser driving circuit in the sensing circuit 10.

When the write current Tw is fed to the laser diode 11, a write pulse 19 shown in Fig. 6B gives a light energy Pw to the laser diode 11,

The scanning circuit IQ for the lasers 11 may consist of a known suitable scanning circuit. For example, switching means of a so-called matrix system based on the group selection and individual selection, which will be referred to later with reference to Fig. 5, or selective ON-OFF control means for the switches connected in series with the lasers can be used .

2Q The laser light is detected as an output signal from a forward impedance monitor suitable for detecting the internal impedance in a laser or a monitoring photodiode 3 in a detection circuit 30 and is then fed back to the encoder 2Q 25 as monitoring information.

When the reading takes place with the laser diode 11, the reading current IR fed to the laser diode 11 may be smaller than the reading current Iw shown in Fig. 6A. Also, a light energy for reading the data to be recorded on the recording 3Q medium 5Q can be lights optical card 5 recorded information are smaller than the light energy Pw, The reading current 18 is therefore smaller than the writing pulse 19 as shown in Fig. 6B,

After the recording of the information on the recording medium 50 has taken place, the current detected by the monitoring and / or reading photodiode 3 is less than no recorded current 22 as shown. In Fig. 6C when the reading current IR to the laser diode 11 is fed,

The monitoring information is obtained by means of 4Q comparing means (not shown!) Which are coded at §700143 * -5-% in the encoder 2Q, when a comparison between the monitoring current 23 and the unrecorded current 22 is passed through the similar means is carried out.

When the difference between the unrecorded current 22 and the monitoring current 20 or IM becomes more than a predetermined value of I-1, a tracking command for W Λ registration information is received through a contact as shown in Fig. 1 and the lasers to be ignited are switched sequentially by the same procedure as explained above.

The optical card 5 is formed by attaching a recording medium 50 to the top surface of a plastic sheet forming a substrate. 51 and applying a transparent protective layer 52 to the outer surface 15 of the recording medium 5Q.

The recording medium 5Q can be formed by using an optical recording alloy exhibiting variations in transmittance and reflectivity to different temperature hysteresis, described in Example 2Q in Japanese Patent Application Laid-open No. 46339/1985. Instead of this alloy, a thin layer can be used with thermoformed pits and using an increase in the amount of scattered light from the light emitted from a light source. In addition to these materials, various other types of materials can be used comprising a material comprising the transformation of crystalline and amorphous phases, which has been recently studied, or a material that uses the variations of shape and volume, such as a bubble and a material 3Q with recesses and protrusions.

The recorded bits are read by a photo sensor group 3 and a detector circuit 3d, are detected by a contactor b shown in Fig. 1, are reproduced as information and are output from a display direction (not shown), via a microcomputer (not shown) connected output terminal Q performed.

The multi-laser head 1 used as the recording light source is installed with the holding plate 16. as shown in Fig. 2, pointing downwards, a multi-lens 6 via a spacer 40 piece 17 on the bottom of the holding plate 16 and above the 870 01 4 3 * * -6- optical card 5 is fitted.

The multi-lens 6 is, of course, formed with a pitch equal to that of the laser 11 and has lens portions 61 coaxial with the laser 11 and the multi-lens 6 positioned.

These are formed from a translucent base plate with suitable refractive index or a lens group consisting of a thin film formed on a substrate. Such a lens group is, for example, a micro lens group as shown in IQ Fig. 1 on page 29 of "4th topical meeting on gradient index optical imaging systems" of July 4-5, 1983 in International Conference Center Kobe, Kobe, Japan entitled "Simplified Ray Matrix or Distributed-Index Planar Microlens · ".

Below the multi-lens 6, a space is formed in which the optical card 5 is received and moved. The optical card 5 held in this space is shifted by a flexible cylindrical rotatable body 100 which is used to move the optical card 5 in the X-direction against the multi-lens 6.

Due to this arrangement, the light from the lasers 11 is concentrated through the lens portions of the multi-lens 6 and passed as light points with a diameter of a number of micrometers through the transparent substrate 51 of the optical card 25 to the recording medium 50,

The energy in the light points fed to the recording medium 5Q is then converted to heat and, for example, the reflectivity and transmittance of the portions of the recording medium 50 onto which the light 3Q falls change the change of the reflectivity or the transmittance of the recording medium 5Q by the. recording information is read out in the form of an electrical signal by a photo-scanning group 3 which will be explained later. As shown clearly in Fig. 2, the photo-scanning group 3 is in a reproduction and / or monitoring section on part of the bottom surface of the holding plate 16 is mounted and a multi-lens 8 is mounted on the bottom of the photo scanner group 3 and above the optical card 5.

4Q The multi-lens 8 is also formed with a pitch equal to 8700143 -7- to that of the photo scanner group 3 and has lens portions 81 positioned coaxially with the photosensors.

The optical card 5 held in a space below the multi-lens 8 is brought out of its bottom by a cylindrical rotatable body 101, which is used to insert the optical card 5 in the Y direction in the same manner as explained above against the bottom of the move multilens 8.

In the position in a space below the optical card 5 which is just below the laser diode group 1 as the recording and / or reading light source, a photo scanning group 3 is arranged as the reading and / or monitoring element with a pitch equal to that of the laser diode group 1 and the bottom of which is mounted against a housing 90, the photo scanners in this group 3 running coaxially with the light-emitting elements in the laser diode group 1,

The permeability of a recording portion on which the information bits are recorded in the manner explained above of the recording medium 50 differs from that 2Q of an unrecorded portion thereof. Therefore, when the light from the laser diode group 1 is concentrated by the lens group 6 and is fed to an information recording position on the recording medium 50, the amount of light passing through each information recording position differs depending on the presence of an information bit recorded therein.

Such transmitted light is concentrated on the photo scanner group 3 by the lens group 8, is converted into an electrical signal, is fed to the detection circuit 30 3G and is reproduced by the decoder 4Q.

An element in the photo scanner group 3 has a laminated structure as shown, for example, in Fig. 4. Reference numerals 301, 302 denote a photodiode pair consisting of silicon pin layers. A photodiode 301 is mounted thereon with a translucent electrode 303 of InO2 and the other photodiode 302 is coated with an opaque electrode 304 of aluminum.

Only the photodiode 301 absorbs light and the other photodiode is used as an insulated diode as will be explained hereinafter in the explanation of the circuit of FIG. 5, 5700143 * * -8-.

Reference numeral 305 denotes a common electrode consisting of a Cr film and reference numeral 306 denotes a SiO2 film for isolation of the translucent and the opaque electrodes 3Q3, 304 of the common electrode 305. All these layers are laminated on a glass substrate insulated substrate 309 formed.

This photodiode pair 301, 302 may consist of a required number of photodiode pairs. For example, when the photo diode pairs form a one-dimensional scanner, photo diodes can be arranged side by side in the width direction of the recording medium 50 formed on the optical card 5, the number of photo diodes corresponding to the number of information bits.

When it is necessary to increase the recording density, the elements in the photo scanner group 3 can be zig-zag arranged to reduce the distances between the adjacent photo scanners.

Much information can be written and read by forming a two-dimensional scanner group with 8 bits in the transverse or Y direction (width direction of the optical cardi and with bits in the longitudinal or Y direction (length direction of the optical card). the number of which is determined by the length of the recording medium 58. Next, a reading operation will be explained by the photo-raster scanner group 3 having the construction shown in FIG. 4 with reference to FIG.

A number of photodiode pairs 311, 3Q2 required in accordance with the dimensions of group 3Q are formed in a laminated state and connected in series with inverse polarity state between a contact of a block changeover switch Z and a contact of an individual changeover circuit -laar X.

35 The diode pairs are divided into a number of groups A, E, C ..., each consisting of the same pairs of diodes.

A terminal of each diode pair in each group is connected together and to the corresponding contacts of the changeover switch Z, the other terminals opposite the terminals of the diode pairs mentioned above are connected together and with the corresponding contacts of the changeover switch X.

These diode pairs are n.1. as connected in a matrix between the two switches X, Z.

First, the block A is connected to a power source VT therefor by energizing the block change switch Z and the other blocks B, C ... are grounded.

As shown in Fig. 1, the diode pairs in block A IQ from one end 111 to the other end 118 are successively selected by the individual switch switch X and are connected one at a time to a sense amplifier circuit R. During this period, the diode pairs other than the selected diode pairs are grounded by the individual changeover switch X. Likewise, the diode pairs in blocks B, C are successively selected from one end 121 to the other end 128 and from one end 131 to the other end 138, respectively.

When the light is supplied to the photodiode 301 2Q, it is turned on, so that the electric current from the power supply VT for the blocks passes through the block diode 302, the photodiode 301, the point D and the movable contact of the individual exchange switch X, so that the information is read,

The point D is also with the photodiodes in blocks B, C.

connected, but these blocks are not connected to the power source VT. In addition, no reading light is supplied to this photodiode, so that the electric current does not flow there »

As a result, only the information from the photodiode 301 of the block A connected to the point 3QD is read by the reading circuit R.

When the individual switching switch X is shifted to select the diode pairs in block A sequentially from right to left, the information in the 35 photodiodes is successively read.

Then, the blocks B, C are successively selected by the block change switch Z and the individual change switch X is energized in the same manner as before, the paired block diodes 3Q2 and photodiodes 3Q1 of 4Q being selected right to left to perform a 6750143-10 - scan operation.

The reading circuit R supplies an electrical signal indicating / whether or not a selected photodiode is receiving light.

With reference to Fig. 5, it is not always necessary to ground the blocks and photodiodes not selected by the changeover switches X, Z.

Although the toggle switch Z has been added to the embodiment of Fig. 5, it is possible to omit the toggle switch lü Z and connect the power source VT to all blocks A, B and C and to use the individual toggle switch X to ignite the ignition. controlling the photodiode 301 and 302 in the order 111 ... 118, 121 ... 128 and 131 ... 138 as shown in Fig. 1.

The diameter of the light for recording and / or reading information bits on an optical card, i.e. the diameter of the recording and / or reading laser beam, which is concentrated on the recording medium, is a few micrometers or very small. Therefore, to perform correct registration and / or read operations by feeding the light to a correct position in which the information is to be recorded and / or a correct position in which the information is registered, it is necessary to provide means for in a predetermined position on the housing 90. in fig. 2 stop and hold the optical card 5.

To meet this requirement, the prefills in the optical card 5 as shown in FIG. 1 formed guide grooves 55, 56 detected by photo scanners (not shown which are mounted 3 # opposite them in the housing 9Q, and the initial position adjustment of the optical card 5 is made when the card 5 is subjected to a signal for the results of this detection representative output signal is finely displaced.

Since this initial position setting operation is performed by the rotatable bodies 10Q and 101 for moving the optical card 5 in the X and X directions, a time duration of about Q is 1 sec. requires. However, once the initial adjustment of the relative positions of the optical card 4Q 5 and the multilaser head 1 and the photo scanner group 3 0700143 -11- is done, a required portion of the photo diode group or multilaser head can be electrically scanned based on the address information counted during the positioning operation, the registration of required information and the reading of a desired information bit can therefore take place in a very short period of time. Incidentally, the rotatable bodies 100 and 101 have coils attached to the holding plate 16 and indirectly to the housing in the middle portions of the rotatable bodies 10Q, 101 and have cylindrical IQ magnets covering the coils of the coil environment with suitable air gaps between turn the coils and magnets around the coils and cover them with rubber.

Hereinafter, the information recording and reproduction operations for the apparatus of FIGS. 1 and 2 will be explained,

When the optical card 5 is placed in a predetermined space in the housing 9Q as shown in Fig. 2, the guide grooves 55, 56 are detected by the initial position adjustment photo sensor (not shown) and the initial position of the optical card set by a suitable fine drive means.

During this time, an output signal from the guide groove detector 56 is used for positioning the optical card in the Y direction in FIG. 1 and the output signals from the detectors for the guide groove 55, 56 for its positioning. X direction in the same drawing.

When the initial position setting operation in a recording mode has ended, the recording information 3Q (e.g. letter information is fed to an input terminal X. This recording information is converted in the encoder 2Q into, for example, 8-bit binary information and sent as parallel 8-bit information to the scan circuit 10.

The scan circuit 10 is capable of finding and determining a registration address on the optical disc 5, if necessary, and in accordance with the parallel 8-bit information supplies a control current to the respective laser in the multi-laser head for generating a registration 4Q and / or reading laser beam.

8700143 -12-

This recording laser beam 300 is detected by a monitoring photodiode 3 during monitoring of the recorded information on the optical card 5 and an output signal thereof is fed back to the detection circuit 30.

In the detection circuit 30, this output signal is converted into a binary signal which is sent back to the encoder 20 via the contact member a.

In the encoder 20, the binary signal returned to it is compared with the corresponding parallel 8-bit-1Q information. When they are equal, a next registration information is recorded and the same registration operation is repeated. If this equality is not achieved, a suitable indication or alarm can be given. When the device is in a reproduction mode, the laser diode 11 is energized after the initial position setting operation to generate the reading light and the 8-bit parallel information is read from the photo scanner group 3 in the detection circuit 30. This 8-bit information is sent to the decoder 40 and output as 2Q letters and symbols via the contactor b.

The relative position between the photo scanner group 3 and the photo card 5 is then shifted to the next recording position and / or reading position of the photo card 5 by the rotatable body 1 for moving the optical card 5 in the Y direction for repeating same registration and / or read operations.

Since the photodiode group 1 of FIG. 1 consists of many rows of photo scanners, the recording and / or reading speed can be increased over that of one row of photo scanners.

The above explanation is an example of the device having both the recording functions and the reproduction functions. In order to use this device only as a reading device, the surface of the photo-scanning group 3 shown in Figs. 1 and 2 can be enlarged to substantially the surface of the recording medium 5Q on the optical card 5.

It will be appreciated that when the area of the photo scanner group 3 is increased in this manner, a time-4Q duration is required to perform only an initial 870 01 4 5 "* µl.

-13- position setting operation at the time of insertion of an optical card can be set as access time and after the access time has elapsed, all registration information can be read with an electric scanning speed. The reading speed can thereby be increased to a speed determined by the electrical scanning speed.

In such an embodiment, the enlargement of the area of the photodiode group may hinder the reduction of the manufacturing cost of the device. However, the photodiode group using a thin layer of polysilicon can be obtained at a relatively low cost. It is expected that with a large increase in the surface area of a solar cell using the same amorphous silicon as in the photo diode group, the cost of the photo sensor group will also decrease further in the future.

Another embodiment is that in which 1 / 2-1 / 5 of the surface of the optical medium 5Q covering 2Q photodiode group is prepared, wherein the determination of the relative positions of the optical card 5 and the photodiode group 3 takes place 2-5 times mechanically.

What has been said above with respect to the enlargement of the surface area of the photodiode group 3 also applies in the case of the recording multilaser head 1. In the optical recording apparatus for recording only, the dimensions of the recording multilaser head 1 can be increased to substantially equal to or 1 / 5-1 / 6 of the dimensions of the recording medium 50. It will be appreciated that when the dimensions of the multilaser head 1 are increased in 3Q, the recording speed can be improved.

According to the invention, the light sources and photodiodes are arranged regularly and a required number of information bits are recorded and reproduced by substantially an electrical scanning operation. As a result, an optical device with a short access time and high recording and reproduction speeds can be obtained.

According to the invention, access to the information bits is improved by an electrical scanning operation and 4Q a mechanical scanning operation is omitted or an auxiliary 8700143-14 operation. As a result, the dimensions and vibration resistance of a scanning unit can be greatly reduced or improved, and a strong, compact and very reliable optical map device can be obtained, since the thickness of the spacer 16, the recording multi-laser head 1, the multi-lens 6, can be obtained. the optical card 5, the multi-lens 8 and the photo scanning group 3 are about 1.5 ram, 0.5 mm, 1 mm, 0.5 mm, 1 mm, respectively Q, 5 mm, the total thickness of the optical card layout. be made smaller than about-1Q spring 1 cm, The length of the longitudinal direction Y and the width X of the optical card can be made approximately 15 cm and 8 cm respectively, 7

The writing and reading speed of the information of IQ bits of the optical card 5 can take place in about 5 seconds,

In Figures 7 and 8, like reference numerals designate the same parts as in Figures 1 and 2.

The difference between the device shown in Figures 1 and 2 and the device shown in Figures 7 and 8 is that 2Q effects the former light emission for writing and reading the information from the recording medium 50 by the laser diode 11 and performs detection of the light for monitoring and reading information stored in the recording medium 50 by the photo scanner 3; 25 and the latter light emission effected to write and read the information from the recording medium 50 through the laser diode 11 and 21, respectively, and performs the light detection for monitoring and reading the information stored in the recording medium 5Q by the photo-3Q scanner 3 resp. 4,

According to FIGS. 7 and 8, a recording light source 2, which preferably consists of a multi-laser head, is mounted with the holding plate 16 facing down, and a multi-lens 7 via a spacer 17 on the bottom of the holding plate 16 and above. the optical card 5 is fitted,

The multilaser head 2 consists of a common substrate 2IA, and n x m laser pieces 21 die. be arranged two-dimensionally with a pitch of a few micrometers at a few tens of micrometers on the common 8700143 15 -15 substrate 2 IA.

The laser diode 2 is controlled by a scan circuit 60 connected to a trigger pulse circuit when the scan circuit 60 receives a command signal S.

5 The structure of the registration light source 1 and the

7 and 8, the monitoring photodiode 3 is similar to that shown in FIGS. 1 and 2, The structure of the reading light source 2, the multi-reading 7 and 9, and the reading light receiving element 4, as shown in the FIG. 7 and 8, is the same as the reading light source 1, the multi-lenses 6 and 8 and the reading light receiving element 3 as shown in Figures 1 and 2.

As a result of the aforementioned arrangement, the light from the lasers 21 is concentrated through the lens portions 61 of the multilenz 6 and passed as light points with a diameter of several micrometers through the transparent substrate 51 of the optical card 5 to the recording medium 50.

In the position in a space below the optical card 5, 20 just below the laser diode group 21, a photo-sensor group 4 is formed with a pitch equal to that of the laser diode group 21, the bottom of which is attached to a housing 90, wherein the photo-scanner in this group 4 runs coaxially with the light-emitting elements in the laser diode-group 21.

Light transmitted through the recording medium 50 is concentrated through each lens 91 of a lens group 9 on the photo-scanning group 4, converted into an electrical signal, fed to the detection circuit 70 and reproduced by a decoder 80, 3Q. The sequence of reading the for example, information recorded on the optical card 5 is output from 211 to 218, from 221 to 228 and from 231 to 238 as shown in Fig. 7, in the same manner as from 111 to 118, from 121 to 128, and from 131 to 138 as shown in fig. 1.

According to the embodiment shown in Figures 7 and 8, the same result as for Figures 1 and 2 can be obtained, since the function of the optical card arrangement shown in Figures 7 and 8 is the same as that in Figure 1. and 40 2 is shown. - Conclusions - 8700143 ί, Λ

Claims (12)

1. Optical card device in which a recording medium is scanned with a beam emitted by a light source for recording information bits on the recording medium and / or reproduction of the information recorded thereon characterized by a group of one-dimensionally or two-dimensionally arranged recording medium. and / or reading light sources (111, means (100,101}) for holding the optical card (5) in a recording and / or reading position relative to IQ of the light sources (111, a group of one-dimensionally or two-dimensionally arranged first lenses (611 for concentrating the light from the sources (11). At the recording and / or reading position on the recording medium (501 in the optical card 15 (5), each light source of the group of light sources (111 and each lens of the group of first lenses (611 each are arranged opposite each other along the same longitudinal direction of the group of light sources and the group of lenses (61)., means (10,20 / 301 for electrically controlling the light from the light sources (III, a group of one-dimensionally or two-dimensionally arranged photo-scanners for monitoring and / or detecting the information recorded on the recording medium (5Q, J_, a group of one dimensionally or two-dimensionally arranged second lenses (81) for concentrating the light transmitted from the optical card (5) to the photo scanner (3) corresponding to each information recorded on the recording medium (50), and means (40) for reading the recorded information from the photo scanners (3), 2. Optical card device in which a recording medium is scanned with a beam emitted for a light source for recording information bits on the recording medium and / or reproduction of the information recorded thereon characterized by a group of one-dimensional or two-dimensional rank 8700143 -17- suitable recording light sources (11), a group of one-dimensionally or two-dimensionally arranged reading light sources (21), means (100/101) for holding the optical card (5) in a recording and / or reading position relative to both kinds of light sources (11, 21), a group of one-dimensionally or two-dimensionally arranged first lenses (61) for concentrating the light from the recording light sources (11) at the recording position on the recording medium ( 50) in the optical card (5), each light source of the recording light sources (11) and each lens of the first lenses (61) individually opposed to each other are arranged along the same longitudinal direction of the group of registration light sources (11) and the group of lenses (61), a group of one-dimensionally or two-dimensionally arranged third lenses (71) for concentrating the light from the reading light sources (21) at the reading position of the recording medium (50) in the optical card (5), and each 2Q light source of the recording light sources (21) and each lens of the third lenses (71) are arranged opposite each other along the same direction of the group of reading light sources (21) and the group of third lenses (71), means (10, 20, 30) for electrically controlling the light from the registration light sources (11), a group of one-dimensionally or two-dimensionally arranged first photos- scanners (3) for monitoring the information recorded on the recording medium (50), a group of one-dimensional or two-dimensional grade-3Q arranged second photo scanners (4) for detecting the recordings recorded on the recording medium (50) first information, a group of one-dimensionally or two-dimensionally arranged second lenses (81) for concentrating first light transmitted by the optical card (5) to the first photo scanner (3) corresponding to each on the recording medium ( 50) recorded information, a group of one-dimensionally or two-dimensionally arranged fourth lenses (91) for concentrating second through the optical card (5) to the second photo scanners (4). 4Q transmitted light corresponding to each information recorded on the recording medium (50), and means (70, 80) for reading the recorded data from the second photo scanners (4) information. Optical card device according to claim 1, characterized in that the recording and / or reading light sources (11) comprise semiconductor laser beam sources. Optical card arrangement according to claim 1, characterized in that the recording and / or reading light sources (11) comprise semiconductor laser beam sources of the type emitting a plane in IQ with coaxial crossover. Optical card device according to claim 1, characterized in that the photo scanners (3) comprise light-emitting diodes. Optical card device according to claim 1, characterized in that the first and second lenses (61, 81) comprise lens group plates formed on flat translucent plates, respectively. Optical card device according to claim 1, characterized in that the optical card (5) comprises a transparent 2Q substrate (51) with a recording medium (50) attached to the top surface of the substrate (51) and a protective layer ( 52) covers the recording medium (50). Optical card device according to claim 2, characterized in that the recording light sources (11) and the reading light sources (21) comprise semiconductor laser beam sources, respectively. Optical card arrangement according to claim 2, characterized in that the recording light sources (11) and the reading 3Q light sources (21) comprise semiconductor laser beam sources of the type emitting in one plane with coaxial crossover. Optical card device according to claim 2, characterized in that the first and second photo scanners (3,4) comprise 35 light-emitting diodes, Optical card device according to claim 2, characterized in that the first, second, third and fourth lenses comprise 8700143% · 19 -19- (61, 71, 8J, 91) lens group plates formed on flat translucent plates, respectively. Optical card device according to claim 2, characterized in that the optical card (5) comprises a translucent substrate (51), a recording medium (50) being mounted on the top surface of the substrate (51) and a protective plate ( 52) covers the recording medium (50). A a. 00143