CH674681A5 - - Google Patents

Description

674 681

CLAIM

Optical card including:

a plurality of guide tracks,

a plurality of data tracks, each of which extends along a guide track,

a plurality of pairs of position information, each of said pairs of position information being written at each of the opposite ends of each of said data tracks.

DESCRIPTION

The invention relates to an optical card which can be used in particular, but not exclusively, by a method for detecting the position of an optical head in a recording-reproducing apparatus for recording or reproducing data on a recording medium of the card type (hereinafter referred to as the optical card) by using a light beam, that is to say a method for detecting the relative position relation of the optical head and the optical card, before that the recording or reproduction of data is carried out. A corresponding recording-reproduction apparatus is associated therewith. The recording-reproducing apparatus concerned is a device for performing either only a recording, or only a reproduction, or both of these operations.

In recent years, as the computer age has grown, attention has been focused on optical cards as a means of storing information. The main peculiarities of optical cards consist, compared with optical discs and optical tapes, in that they have the card type format which is easy to transport and handle and, compared with magnetic cards and IC cards (circuits integrated), in that they have a large storage capacity.

Now, in the recording-reproduction of data by a storage medium such as an optical card, the relation of relative position between the optical card and the optical head in the initial situation must be understood before the recording operation or can start. For example, in general, most recording-reproducing apparatus are in a form such that, before said operation starts, the information of the content area, which is established on the optical card and in which is written the situation of data or similar elements in the optical card, is read, then the operation is carried out on the basis of this information. Consequently, to shorten the time required for recording or reproducing data, it is necessary that after the optical card has been inserted in the device or when the recording or reproduction operation has to be resumed after having been interrupted, the relative position of the optical head and the optical card is adapted by a rapid movement to bring about a state in which the information from said content area can be reproduced. In this description, the position in which the optical head is positioned in such a situation relative to the optical card is called the standby position (home position) of the optical head.

A method exists for rapidly detecting the position of the optical head so as to make it capable of rapidly gaining a predetermined waiting position.

This method of detecting the position of an optical head in a recording-reproducing apparatus, for recording information on an optical card or reproducing the information recorded on the optical card, comprises the following steps:

transmission of instructions to the optical head for recording or reproducing, and displacement of the optical head relative to the optical card in the direction of the track of the optical card on the basis of said instruction and reading of the position information written on the optical card.

2

The object of the invention relates to an improved optical card, as described in the claim.

The invention will now be described in detail, by way of example, in conjunction with the appended drawing in which:

5 fig. 1 shows an embodiment of an optical card according to the present invention,

fig. 2 and 3 illustrate the detection method, and FIG. 4 is a block diagram of an embodiment of the recording-reproducing apparatus for an optical card, using the detection method.

Fig. 1 is a schematic view showing an embodiment of an optical card. We see in 1 the optical card, in 2 an area in which the data is recorded, and in 3a, 3b and 3c of the track units. The track unit as mentioned here is to be understood as a combination of the minimum necessary among the various tracks including, in addition to the data track on which data is written, a track for guidance allowing to perform on the card a reliable recording or reading of the data, and a clock track for the clock pulses.

Fig. 20 2 is a view for illustrating the detection method, using an optical card having a certain track unit. This certain track unit consists, as shown in fig. 2, in a guide track 11 and a data track 12. At the opposite ends of the data track 12 are areas 13 of data track identification, in which data track numbers are recorded. for the identification of data tracks.

Considering the initial state before the writing or reading of data is carried out, it is understood that a light spot 14a, for scanning the data track, and a light spot 15a, for scanning the data guide track, are generally located in any positions on the optical card. Subsequent to this state, the optical head of the apparatus, not shown, is moved in the direction from left to right, relative to FIG. 2 (direction of the movement of the track), and the functions of autofocusing and autogui-dage of the recording-reproducing apparatus are carried out so as to act by means of the reflected light of the spot beam 15a, whereby the light spot 14a for information and the light spot 15a for guidance are positioned on the nearest 40 information tracks 12a and guide track 11a respectively. The light spots 14a and 15a occupying these situations are indicated by the reference signs 14b and 15b respectively. Then, the light spots are moved and pass over the information track identification area, which results in the number 45 of information track 13a being read and that it becomes possible to know the relation of relative position between the optical head and the optical card at that time. Consequently, after the operation described above, the optical head can be easily moved to a desired track unit to accomplish recording or reading of data there. For example, it is thus possible to read the data track number and to know the relative position relationship between the optical head and the optical card. Therefore, after the operation described above, the optical head can be moved to a desired track unit to carry out the recording or reading of data therein in an easy manner. For example, the data track number is read and the relative position relationship between the optical head and the optical card is recognized, whereupon the mutual positional relationship is changed, so that the optical head comes to the area of contents and, in this waiting position, a new command is given.

60 The means for giving a command to start the relative movement in the runway direction in order to know the positional relationship between the optical card and the optical head may, for example, use a signal from a sensor to confirm that the card optical has reached a predetermined position, these 65 means can also include a manual signal given by the operator. As shown in fig. 2, the data track identification areas are established on the two opposite sides of the data track, which makes it possible to read the

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674 681

data track number by relative movement of the optical head and the optical card either from right to left or from left to right.

As appears from the description given above, the access to the optical head is carried out by a simple system. In addition, these means may be suitable for a plurality of types of optical cards in which the shapes of the track units are the same, but differ from each other as to the position and the size of the data area. 2 shown in fig. 1.

Fig. 3 is a view which illustrates the method using an optical card having track units as shown in FIG. 2. In fig. 3, the elements functionally similar to those of FIG. 2 are designated by the same reference signs. The difference between this embodiment and that shown in fig. 2 is that, in FIG. 3, there is a plurality of light spots 14a for the data. In fig. 3 also, the two light spots 14a for the data and the light spot 15a for the guidance are, in the initial state, in any positions on the optical card. However, by the same operation which was previously described, the light spots 14a for the data can be positioned on the closest data tracks 12a and 12b respectively, and the light spot 15a for the guidance can be positioned on the track 15 for guidance, which results in that the two data track numbers 13a and 13b can be read simultaneously. Thus, in addition to the advantages mentioned above, it is possible to read the two data track numbers 13a and 13b and to compare them, which not only makes it possible to know the position of the optical head, but also provides the possibility of know the direction in which the runway unit to which you wish to access is located in the next state. This possibility offers a very useful practical effect, because it allows the optical card, such as that shown in fig. 1, either inserted into the optical recording-reproducing apparatus with either its A side or its B side in front.

Although the foregoing description has been provided in connection with the type in which the optical head is moved, the optical cards can of course also be read in the direction of the track movement. Similarly with regard to the specific means for performing the functions of autofocusing and autoguiding, the method of the critical angle, the method of the "knife edge", the method by astigmatism, etc., are known in as regards autofocusin, while the three-beam method, the push-pull method, the heterodyne method, etc., are known for autogui-dage, each of the above-mentioned methods being applicable. In addition, although the foregoing description has been made in consideration of the use of data track numbers, it is also possible to establish and use a guide track number corresponding to the guide track. to detect the position of the optical head.

Fig. 4 is a diagram showing an embodiment of the recording-reproduction apparatus on an optical card, using the detection method described.

In fig. 4, we see at 21 a sensor for mechanical or electrical detection of the insertion of an optical card 1 into the apparatus, at 22 a DC motor control, at 23 a DC motor for moving in the runway directions of the card (the directions of the bilateral arrow), a table (not shown) supporting on it the optical card 1, and we still see at 24 an optical head for applying three beams of light to the optical card under conditions such than those allowed in fig. 3. The construction of this optical head is similar to that of an optical head used with a conventional optical disc, except that there is a diffraction grating to separate the light beam from a light source in three light beams, the description of the detailed construction of this device is therefore not necessary here. In fig. 4, block 25 represents a circuit for reproducing the information recorded on the tracks from a signal read by the optical head, as described in substance in conjunction with FIGS. 2 and 3, while there is a comparator at 26, at 27 a pulse operating circuit, at 28 an establishment circuit for establishing in which position the optical head is located and must be subsequently relatively moved on the optical card, the reference sign 29 designating an electric motor control, and the sign 30 designating a pulse motor for moving the optical head 24 relative to the optical card 1.

When it detects the insertion of an optical card 1, the sensor 21 20 delivers a detection signal to the motor control DC22 and, on the basis of this signal, this control 22 drives the motor DC23 so that it moves optical card 1 in the direction of movement of the runway. Simultaneously with this, on the basis of another detection signal from the sensor 21, the optical head 24 reads the information on two tracks on the optical card 1, at a time at which the functions of auto-focusing and of autoguiding. From this reproduction signal, the reproduction circuit 25 identifies the track number of each track and the information is delivered to the comparator 26. When it receives the result of the pro-comparison 30 coming from the comparator 26, the pulse operating circuit 27 supplies the pulse motor control 29 with a signal corresponding to the next track to which the optical head must access, the value established by the setting circuit 28 being taken as a reference and the pulse motor control 29 driving the pulse motor 30, so that the optical head 24 accesses a predetermined track.

By the construction described above, it is possible to implement the detection method. In the description provided in connection 4 (j with fig. 4, an example has been shown in which the insertion of the optical card into the device is detected to cause the start of a series of operations, but this way to do is in no way restrictive. It is noted in particular that this method is naturally applicable also to the case in which an optical card 45 is already inserted in the device, a recording or reproduction of data has already taken place, and the The operation was interrupted for some time, whereupon the recording or reproduction should start again.

The details and effects of the detector have been described above with reference to the drawing, by way of example. Before the data is written to or read from the optical card, the optical card and the optical head are moved relatively to each other in the direction of movement of the data track, and then the relative positional relationship between them, that is to say between the optical card and 55 the optical head, which makes it possible to carry out a rapid shift towards the next operation.

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2 sheets of drawings