DE3503232C2 - - Google Patents

Description

The invention relates to a method for control a tape with a magnetic layer, esp special of an audio or data tape, according to the Preamble of the first claim and one Device for this.

Such two or more lane tapes, which also as Logo tapes, logo magnetic tapes and data carriers are designated for a whole range of Tasks such as b. for process controls, learning devices, Data processing, building automation, regular Repetition of messages through loudspeakers and in Radio communications (aviation) and security Security can be used when using data in banking.  

For all of these uses, it is very important that absolutely no components of the data on the tape of the half lost because the starting point at through say controls etc. is set inaccurately. A such inaccuracy of adjusting the tape or Shift can arise for several reasons, though the tape is moved back and forth repeatedly. The Ver shift is often due to the fact that the reading of the accompanying magnetization is fast is dependent on the speed, the one that can be tapped at the reading head Tension to the speed of passing it moved data carrier behaves directly proportional. At the Starting and braking the belt becomes the signal Minimum speed required in the reading head either below or not yet reached. This leads to the information failures mentioned absolutely must be avoided. Eliminating the Like defects were previously very time consuming and ver got the help of an experienced professional on this Territory.

In DE-OS 28 32 337 an information record nation and information playback device with a mag netic recording tape shown on the magnetic recording tape additional identification signals are recorded. These different identification signals are different recording sections of the Recorded tape assigned. With slow tape feed for recording and playback of Infor the frequency spectrum of the identification signals below the audio frequency range of the information drawing and information display device. Of the recorded characteristic signals are in one Magnetic head corresponding to the identification signals and for Finding predetermined recording sections of the Recordable AC voltages induced.  

With this device, however, no rapid Correction or correction of the position of the read head regarding the tape.

From DE-OS 30 20 602 is a magnetic tape drawing system and a positioning arrangement, by means of which the identification of intermediate storage positions along a magnetic tape and from End positions of the magnetic tape is improved. Here the recording medium has a plurality of addressable record segments on what bit Representations of the digital signals with a first Save spatial bit density. Furthermore, intermediate data Set marker segments provided between neighboring data segments. Each of these last mentioned marker segments stores a Representation of a first predetermined pattern of digital bits with a second spatial bit density, the is smaller than the first spatial bit density. This tax The process is very complicated and not one rapid correction or correction of the position of the Read head suitable.

DE-OS 30 16 059 finally shows a volume job seeker for a tape with a magnetic Layer that has at least one soundtrack and one Tax lane is occupied. This band finder serves for quick search of any band location in any Running condition of the magnetic tape. This becomes one searching address on the tape and a running address the stopped band and the number of intervals of control signals according to the number of addresses between the two addresses mentioned by computing operation determined.  

Then the tape is run quickly and the Number of distances of the control signals with the number of the fast-moving addresses. I.e. in this case with control signals of constant frequency worked up or down, the Counting takes place by means of a counter circuit. Everything However, this writing gives no suggestion like one quick correction or correction of the position of the Reader head be made with respect to the tape should.

The object of the present invention is thus Creation of a procedure for Control of a tape with a magnetic layer, especially an audio or data tape, the one quick correction or correction of the position of the Read head with respect to the tape, as well as a Device for performing such a method.

The method and the device should be easy be operated so that little or practically none Operating experience or training is required.

Furthermore, the method and the device should be extremely be exact so there are absolutely no inaccuracies in the Control commands or messages can arise that Loss of information can be avoided completely.

A method in which the control signals on the control track in selected Ab have frequency or phase changes that lead to the generation of signals when recorded, which the counter circuit in a predetermined manner act upon. This behavior is extremely simple too handle as the frequency or phase changes are easy to recognize.  

With an appropriate device for implementation the procedure provides that the receipt of the Counter circuit with the output of an audio channel for ver an up or down count track of an audio part is bound that there is a phase detector, its input also with the output of the audio channel is connected and that the output of the phases detector at a preset input of the counter scarf device is connected.

Embodiments of the method according to the invention or of the device according to the invention are each in the dependent subclaims.

The solution found is simple in structure and enables a quick and safe correction of the on position of the tape. There is practically none Introduction to the operation of the device required.

The following is a performance example of the subject the invention explained in more detail with reference to the drawing. It shows

Fig. 1 is a graphical representation of the Frequenzver run the control or correction track to Be elevation of a shift,

Fig. 2 is a detailed graphical representation of an approach for accurate adjustment of the band,

Fig. 3 is a schematic diagram of a device for Sig nalbildung for the correction and

Fig. 4 is a block diagram of an apparatus for performing the method.

In Fig. 1, a frequency axis is shown, on which a sinusoidal signal of 100 Hz is recorded, which changes after every 1000 periods for 5 periods in a frequency of 150 Hz to generate a frequency jump at regular intervals. The difference between these two frequencies, ie 100 and 150 Hz, is used to generate a phase detector signal. The 150 Hz digits are to be regarded as synchronization points that count up and down a counter during fast winding up and down via the phase detector, exactly like the 100 Hz oscillation of the actual addressing. With the 100 Hz oscillation, the count of the band counter is increased, the phase detector signals of the 150 Hz oscillation being usable twice for a translated coarse count and / or for setting a part of the band counter.

FIG. 2 shows a frequency axis to explain the mode of operation of FIG. 1. At count 0, the counter begins to count the continuous 100 Hz oscillation, which changes to 150 Hz at the 500th oscillation, so that the phase detector registers a frequency jump. It begins with the integration of a DC signal, the fault response in the event of a frequency jump being a DC ramp which, for example, exceeds a threshold value after five oscillations and generates a pulse in a downstream pulse shaper. The runtime to be taken into account depending on the degree of accuracy or the geometric inaccuracy of an increase of five pulses on a scale compressed by a factor of 0.66 was disregarded here in favor of a simpler representation. The pulse from the pulse shaper now sets the last three decades of the counter to 505. The recurring 100 Hz frequency now causes a further increase in the count of the counter up to the next orientation mark at the 1500th oscillation, which causes the counter to be synchronized to the value 1505. However, this also corresponds to the actual meter reading if no shift has occurred. In the event of a shift, the counter corrects this deviation by the three decades set to the value 505 mentioned in this example. The structure of this synchronization pulse requires five full periods in order to develop the full, desired effect. However, this is the reason why the counter is finally set to the value 505.

In this example, the processed signal from the Phase detector as a set pulse in the tape counter used that with it in the last three decades of  The fixed value 505 is loaded. That looks then in three simulated cases:

In case a), the tape counter monitoring the audio part has somewhat forward and is reset and controlled accordingly now with corrected value the following logic for Control of the belt motors. This is a synchronization by setting to a value that is within a desired one Accuracy range. In case b) the counter has one small wake and is set by the impulse on the forced correct value. In case c) is the band position just right so that the counter setting only causes the correctness of the meter reading to be confirmed becomes.

This example shows that the frequency marks each in the middle of a section of 1000 on top of each other following periods are arranged, but also others Possibilities exist. However, it is recommended this Marks between and not at the 1000 crossings to be determined.

The synchronization marks are here at intervals of 100 Periods equidistantly built into the counting frequency and each cause a correction of the counter reading within two brands, e.g. B. plus / minus 500 periods. Outside In this area the counter loses orientation. in the Normal operation can deviate larger than 500 periods  however do not occur. At a running speed of Band of 4.75 cm / sec corresponds to 100 periods approximately 47.5 mm Strip length, so that this results in a position inaccuracy of approx. pulse / minus 1 mm arises, which is very practical good accuracy value.

The evaluation of the frequency marks is shown schematically in FIG. 3. A phase detector 17 receives a sequence of a sinusoidal oscillation of 100/150 Hz as signal d 1 from the audio part of the device and a sequence of constant sinusoidal oscillation as signal d 2 from a further source, not specified. A downstream pulse shaper 18 generates a set pulse at a specific threshold value, which sets the last three decades of the counter to a specific value.

In the block diagram of FIG. 4 is a circuit unit 10 with a microprocessor, the necessary RAM / ROM memories and interfaces is shown to the servo part of the tape recorder. This unit 10 controls the tape device according to information from various accesses and also from a counter 11 with a display 12 and a connection. The counter 11 is driven from the audio part 15 via a line 16 with the 100/150 Hz frequency discussed above. On the one hand, the counter is increased or decreased by the individual periods of the 100 Hz oscillation, but also by the few, here five 150 Hz oscillations in the up / down mode in succession, and on the other hand, the last three decades are reduced to one by a setting pulse fixed value that takes into account the five 150 Hz oscillations. The set pulse is processed by a phase detector 17 which is controlled by the audio part 15 and which, according to FIG. 3, accumulates a signal from the five oscillations of the 150 Hz frequency, which signal is used to trigger a set pulse. The respective counter reading is processed in the usual way by the processor part. In Fig. 4 are insignificant circuit parts, such as. B. "Cassette inserted", "Cassette drawer closed", omitted. The main purpose of this figure is to show how the device is connected to a microprocessor tape controller. The basic structure of this device can be seen from FIG. 3.

Claims (8)

1. A method for controlling a tape with a magnetic layer, in particular an audio or data tape, with at least two mutually coordinated tracks, one of which is used to control the other, the control track with control signals of constant frequency or phase for opening - or down counting of a counter circuit is occupied, characterized in that the control signals on the control track at selected intervals have frequency or phase changes which, when detected, lead to the generation of signals which strike the counter circuit in a predetermined manner. 2. The method according to claim 1, characterized in that that the frequency and phase change when moving Band in time and geometric with the band at rest is arranged equidistant. 3. The method according to claim 1 or 2, characterized records that as signals for up or down count a sine and cosine counter circuit Signals are used to generate a Frequency or phase jump continuously into one pass another frequency or phase. 4. The method according to claim 3, characterized in that the frequency change in a range of 1.3 up to 2.0 times the fundamental frequency and 0.8 to 0.4 is carried down and that the changed Frequency during 3 to 10 periods before the re Setting the original frequency upright is obtained.   5. Device for carrying out the method according to at least one of claims 1 to 4, characterized in that the input of the counter circuit ( 11 ) is connected to the output of an audio channel for an up or down count track of an audio part ( 15 ) that a phase detector ( 17 ) is present, the input of which is also connected to the output of the phase detector ( 17 ) at a preset input of the counter circuit ( 11 ). 6. The device according to claim 5, characterized in that a pulse shaper circuit ( 18 ) between the output of the phase detector ( 17 ) and the setting input of the counter circuit ( 11 ) is arranged. 7. The device according to claim 5 or 6, characterized in that the phase detector ( 17 ) is part of a phase-locked control circuit (PLL). 8. The device according to claim 7, characterized characterized that a voltage controlled Oszil lator (VCO) in the control circuit (PLL) on the Counter frequency on for counting up and down represents is.