WO1980001216A1 - Magnetic tape recorder with quick access to recorded information - Google Patents

Abstract

The magnetic recorder with quick access to the desired information comprises an electric control device for controlling the unwinding of the tape which insures an optimum speed of the tape while taking into a count its mechanical resistance and engages the breaking means before reaching the information searched (4), taking into account the speed of the tape so as to stop it precisely at the desired information. A recording device (12) for the cassette of the recording support comprises the sensor and the adjusting element necessary for the control device.

Description

Tape device with random and quick access to all information stored on a magnetic information carrier

The invention relates to a tape device with random and fast access to any desired information, which is stored on a magnetic information carrier.

The accessibility at. Magnetic information carriers, which are designed as tapes of 100 and more meters in length, is a major problem in the known tape devices, which could only be solved to a certain extent with great mechanical and electronic effort. Furthermore, only magnetic tapes could be used, which are expensive due to their special properties. Random access cannot be guaranteed to full satisfaction with the known devices.

The object of the invention is not only to avoid the disadvantages mentioned, but also to create a tape device with random and quick access using simple components, these properties also being achieved when using normal, commercially available magnetic tapes which are arranged in cassettes, be guaranteed.

This task is solved by arranging the following components:

- Circuit for receiving signals representing the correct position of the information carrier in relation to magnetic interrogation heads, and for positioning the information carrier in one of its two initial positions;

- an input circuit for entering the position of the desired information; a position decoder for receiving signals representing the actual position of the information carrier;

- Servo circuits for controlling motors which move the information carrier past the magnetic interrogation heads;

- For each motor a tachogenerator for generating signals that show the speed of each. Represent motors;

- A logic circuit connected to the above-mentioned components, which, when the information carrier is in the correct position, relates to the magnetic interrogation heads and when it is started

Position controls the motors in such a way that the information carrier is moved past the magnetic interrogation heads at the optimum speed, taking into account its tensile strength, and the braking process is initiated before the desired information is reached, taking into account the speed, and overshoot in the target position is avoided.

An embodiment of the invention is explained in more detail with reference to the drawings. Show it:

Fig. 1 shows an embodiment of the electronic circuit and

Fig. 2 shows a perspective view of the receiving device for the magnetic tape stored in a cassette.

The mode of operation of the invention is described with reference to FIG. 1. It is assumed that information block 95 is to be queried on the information carrier, which is designed as a magnetic tape in this exemplary embodiment. The magnetic tape, which can be 100 or more meters long, is wound on a spool and can be unwound from this spool onto another spool. The coils are not shown in FIG. 1. The desired information block is entered into the input circuit 2. If several information blocks are to be read, their identification number must also be entered in the input circuit 2. The so-called read command is also entered into this circuit. Further commands, such as tape speed during the read-out process or fast tape transport in the forward or backward direction or the start or end position of the tape or the like can also be entered if required. However, these commands are only implemented when the magnetic tape, which is arranged in a tape cassette, which in turn has been inserted in the receiving device 12, has been reported ready for operation. This is done by the circuit 6, which determines the correct position of the magnetic tape 1 to the interrogation heads 9 and 10 by means of the sensor 61 only indicated in FIG. 1 and by means of the sensor 62 only indicated whether the tape is in its initial or final position the cassette not drawn. If the belt is not in the start or end position, the circuit 6 gives a control signal via line 63 to one of the two motors 72 or 82, which brings the belt 1 into the start or end position. Only then does the circuit 6 give the signal to the logic circuit 5 via the same line 63 that the commands stored in the input circuit 2 can be processed. The processing takes place in such a way that the motors 72 and 82 for the two coils of the magnetic tape are controlled in a certain way via lines 74 and 84, digital / analog converters 7, 8 and servo circuits 71, 81. The motor that actuates the unwinding spool receives a certain braking torque and the motor that drives the winding spool of the magnetic tape receives a certain driving torque. These two are matched to one another in such a way that the magnetic tape 1 is moved past the two heads 9 and 10 at the maximum possible transport speed, the tensile strength of the mag gnetbandes 1 is taken into account. This consideration can take place either by entering the value of the tensile strength in the servo circuits 71, 81 which corresponds to the magnetic tape 1 currently being used. There is also the possibility that all the tensile strength values of the tapes 1 obtained commercially are entered in the linking circuit 5 and the linking circuit searches for the value peculiar to the respective tape. As soon as the tape 1 is moved past the magnetic heads 9 and 10, the position decoder 3 receives the position values of the tape relative to the interrogation head 9 via line 31. At this point it should be pointed out that the tape is divided into two tracks. The one track which faces the magnetic interrogation head 10 contains the information to be interrogated, which can be stored as speech, music or as information data. The other track contains the position data of the tape 1. This track faces the magnetic interrogation head 9. The position data can be represented, for example, by a sine wave stored in this track. Of course, other forms of vibration are also suitable for this purpose. As said, the actual position signals are sent via the interrogation head 9, the audio amplifier 91, line 31 to the position decoder, which is an up and down counter in this exemplary embodiment. These data are displayed in the display device 4 and pass through the intermediate circuit 41 (interface) via line 42 to the logic circuit 5. There they are compared with the desired target position information from the input circuit 2, which had been in the line 21 some time ago Logic circuit 5 was given. The logic circuit is therefore informed of the current distance of the tape to the desired target point. This information is processed in such a way that the corresponding motors 72 and 82 are rotated in terms of speed or ge via the lines 74, 78 and servo circuits 71, 81 speed controlled so that the braking process can be initiated at the right time. Another measure of what the logic circuit 5 requires for such a control is the real speed of the two motors. A tachometer generator 73 and 83 is therefore connected to each motor shaft. Via their lines 74, 84, these tachometer generators transmit the speed signals to the circuit 11, which adds the two signals and forms the average of this sum. Since analog voltage values are present on the lines 74 and 84, the circuit 11 also has an analog / digital converter, so that the output signals which reach the logic switch 5 via line 111 can be processed there as digital values. At this point it should be noted that the magnetic tape 1 is transported at the maximum possible speed, taking into account the tear resistance of the tape. The braking process is engaged in time so that the target position, ie in this case the desired information block 95, is in front of the magnetic interrogation head 10. An overshoot, as occurs in the known devices, is avoided in this way. The access to the individual desired information blocks that are stored on the magnetic tape 1 takes place within an optimally short time. As soon as the beginning of the desired information block is in front of the query head 10, the information can be queried via the audio amplifier 101 and line 102. In our example it was pointed out that the command to read out the information blocks had already been entered in input circuit 2. Another device which requires the information of these information blocks is connected to the terminal of line 102. This device can be, for example, a computer that needs this information for further processing. A display device can also be connected, which makes this information visible to a person. It is also possible to have a so-called audiovisual Connect the soldering device to this terminal. Such a learning device also has a viewing device. After the desired information has been queried via the query head 10, the next information block can be queried. This takes place immediately if the appropriate commands have already been entered in input circuit 2. For the sake of completeness, it should also be pointed out that the circuit 31 receives, via the line 32, display signals from the logic circuit 5 which indicate the current operating state of this logic circuit. For example, a lamp may light up in circuit 31, indicating that the embodiment of FIG. 1 is ready for the input of the corresponding commands into input circuit 2. Another lamp may light up in circuit 31 and indicate that the desired information is being received is brought up to the query head 10. There are many other display options that are known and are therefore not described in detail here. The exemplary embodiment of FIG. 1 can be modified in various components without the essential purpose of the invention as claimed in the main claim being changed.

FIG. 2 shows a perspective view of the receiving device 12, which was only shown in broken lines in FIG. 1. The motors 72, 82, the tachometer generators 73, 83, the two tape heads 9, 10, the cassette of the magnetic tape 1 and the position decoder 6 with its sensors 61, 62 are located in this receiving device. The two are on the base plate 120 of the receiving device 12 Motors 72, 82 indicated, which drive the drive cams 74 and 84. As will be explained in more detail later, the cassette in which the magnetic tape is located is placed with its spools on these drive cams 74 and 84. A third drive motor 130 is provided beneath the base plate 120, which continuously drives the capstan shaft 135 via a belt drive 132 driving speed. The other components of FIG. 1 are attached below the base plate 120. Above the base plate 120 are the pin 136, which is pressed down by inserting the cassette onto the base plate 120 and actuates the sensor 61. As a result, the signal is sent to the position decoder 6 of FIG. 1 that a cassette has been properly inserted into the receiving device 12 of FIG. 2. The mode of operation of the receiving device of FIG. 2 is described in more detail below. It is located as a so-called drawer element in a slide-in housing. The slide-in housing is shown in Fig. 2 not drawn. If the receiving device 12 is to be loaded with a magnetic tape cassette, it is pulled out of the plug-in housing. The handle 136 is only shown schematically. The individual components on the base plate 120 of the receiving device 12 are in the arrangement shown. This means that the magnetic cassette has not yet been inserted. Thus, the two heads 9 and 10 with their parallel guides 140, 141, 142 are at rest. In other words, the sound heads 9 and 10 are pushed back until they stop. If the cassette is now inserted, the pin 136 is pressed down and gives a signal via line 61 that the cassette is inserted. Furthermore, the capstan shaft 135 and the photo element 138 of the light barrier 139 engage in the housing of the cassette. The light barrier 139 is connected to the position decoder 6 via the line 62 and, as already discussed in connection with FIG. 1, sends the signal to the position decoder 6, which indicates whether the tape in the cassette has its initial or final state. For the sake of completeness, it should be pointed out that the two recesses 150 in the base plate 120 are provided for further light barriers which determine the respective thickness of the tape roll on the winding side or unwinding side and corresponding signals give the position decoder 6. These two light barriers are not shown in FIG. 2, since they are normally arranged below the base plate 120. It is now assumed that the holding device 12 is inserted into the slide-in housing (not shown) by means of the handle 137. The insertion direction is assumed to the rear according to FIG. 2. Shortly before the insertion movement has ended, ie for the last 2 cm, the parallel guides 140 are moved to the right against the force of their springs 141 by an end stop of the insertion housing. This follows the movement of the heads 9 and 10 in the direction of the magnetic tape. At the same time, the pin 134 moves to the right. As a result of this shift to the right, the brake of the magnetic tape in the cassette is released. At this point, it should be pointed out that a magnetic tape brake is provided in the cassette, which responds automatically when the cassette is removed from the receiving device 12. The brake is only released when the pin 134 is moved to the right as a result of the insertion movement. If the receiving device 12 is now fully inserted into the slide-in housing, the rear edge of the base plate 120 actuates a switch 160. This switch closes the circuit of the line 61. This excites the magnet 161, which produces a magnetic locking of the base plate 120. Furthermore, by closing switch 160, a signal is generated via line 61 to position decoder 6, which indicates that the entire recording device 12, including magnetic tape, is ready. The processes already described in connection with FIG. 1, such as fast forward, fast reverse, can now be carried out with particularly fast access. If the magnetic tape is to be interrogated by the sound head 10, the magnetic tape is pressed onto the capstan shaft 135 by means of the pressure roller 121. The pressure mechanism, which consists of a lever 122 and a spring 123, is under one half of the base plate 120 actuated magnets. The third motor 130 has been in operation for a long time. As already mentioned, the capstan shaft 135 is driven synchronously by the motor 130 via the belt drive 132, so that the magnetic tape is moved from one side (cam 74) to the other side (cam 84) at a constant speed. If the magnetic tape is to be replaced, a release button, not shown, is actuated. The result of this is that the magnet 161 is interrupted via a parallel switch (not shown). The springs 141 of the parallel guides 140 of the audio heads 9, 10 now have so much force that the base plate 120 is moved out of the slide-in housing to the right. At the same time, the heads 9, 10 withdraw from the tape. The cassette brake is brought into effect again by the movement of the pin 134. The cassette can now be removed from the holding device by hand. If another cassette is inserted, the same procedure is carried out as already described.

Claims

PATENT CLAIMS Tape device with random and quick access to any desired information that is stored on a magnetic information carrier, characterized by the following components: - Circuit (6) for receiving signals representing the correct position of the information carrier (1) relative to magnetic interrogation heads (9, 10) and for positioning the information carrier in one of its two initial positions; - an input circuit (2) for entering the position of the desired information; - a position decoder (3) for receiving signals representing the actual position of the information carrier; - Servo circuits (71, 81) for controlling motors (72, 82) which move the information carrier (1) past the magnetic interrogation heads (9, 10); - for each motor (72, 82) a tachometer generator (73, 83) for generating signals representing the speed of each motor; - A linkage circuit (5) connected to the above-mentioned components, which, when the information carrier (1) is in the correct position relative to the magnetic interrogation heads (9, 10) and in its initial position, controls the motors (72, 82) in such a way that the information carrier at optimal speed considering its tensile strength is moved past the magnetic interrogation heads, and the braking process before reaching the desired information taking into account the Ge speed is initiated, and an overshoot in the target position is avoided. 2. Tape device according to claim 1, characterized in that the position decoder (3) receives the position signals coming from the interrogation head (9) and the position of the information carrier (1) from this read head (9) on the logic circuit and optionally on a display device (41) gives. 3. Tape device according to claim 2, characterized in that the position decoder (3) is designed as an up and down counter. 4. Tape device according to claim 2, characterized in that the position decoder (3) is designed as an address encoder. 5. Tape device according to claim 1, characterized in that a receiving device (12) for the information carrier (1) contains a base plate (120) on which the motors (72, 82), the servo circuits (71, 81), the tachometer generators (73 , 83) and the sound heads (9, 10) are arranged. 6. Tape device according to claim 5, characterized in that the sound heads (9, 10) by means of a parallel guide (140, 141, 142) on the base plate (120) of the receiving device (12) are attached. 7. Tape device according to claim 5, characterized in that the base plate (120) of the receiving device (12) contains a mechanical member (134), the movement of which releases a locking device of the magnetic tape. 8. Tape device according to claim 5, characterized in that the base plate (120) of the receiving device (12) is held in its operating position by a magnetic device (161).