DE2150807B2 - ARRANGEMENT FOR SYNCHRONIZING THE MOVEMENT OF TWO STORAGE MEDIA TRANSPORTED BY TRANSPORT DEVICES - Google Patents

Description

The present invention relates to an arrangement m synchronizing the movement of two of Transport devices of transported storage media, the storage location signals and in a direction track carry recorded, pulse-shaped control signals serving for speed control, with a Counter, the up count input of which signals the movement of the first storage medium and whose countdown input signals the movement of the second storage medium can be supplied and of its counter reading characterizing a mutual incorrect positioning Setting the speed of the storage media above or below a target speed can be controlled The arrangement according to the invention is used below for the application of recording and Playback devices with magnetic tapes described. However, the invention is not limited to such Use cases limited. Rather, the arrangement according to the invention can also be used, for example, for Devices with disk-shaped magnetic recording media are used. That is special The arrangement according to the invention can be used in conjunction with devices in which the on the storage medium Information to be stored in the form of information units or information segments is processable, each segment on a designated by a memory location signal (address) Storage location recorded on the magnetic tape or is reproduced. An example of such a thing Operation of devices is the storage of visual information using video tape devices operated by the Applicant are produced. With such devices it is necessary to split a printed document on two or to store more video tapes such as a main tape and a file tape. One known possibility is to first save the document to a predetermined storage part on the To record the main tape, after which the same recording in a separate operation on one desired storage location of the video tape file. In the event of a possible synchronization a pair of transport devices, one carrying the main tape and the other carrying the file tape, such that these two recording operations can be carried out simultaneously, it is very much essential to provide time savings in terms of both equipment time and operator time.

Corresponding advantages are found in the reproduction of associated information segments from a large number of tape storage locations, with portions of the recorded information on different Tapes are stored, which in turn are each carried by a separate transport device. When playing back a set of associated information segments, it is necessary to adjust the playback speed one of the transport devices at a specific tape storage location at the playback speed another transport device at the selected location of that device to synchronize the assigned band. This enables the reproduction of information in a smooth take place continuously, d. H. the reproduction of the information appears as if it were composed of an and the same tape transport device would come.

Such a process differs from previously known complex techniques in which the Tapes on various transport devices to a predetermined point in the direction of movement in front of the

addressable storage locations are preset and one of the transport devices is initially synchronized and the associated information segment is reproduced, after which the second transport device is synchronized in order to reproduce the segment of information assigned to it. 3rd disadvantage Such synchronization consists in the fact that between the end of the first reproduced information segment and the beginning of the next information segment is a time delay. which is caused by the necessary transition in the synchronization of the first to the second Transport device is conditional. The advantages resulting from time-saving reasons result from this not only for video signal storage devices. Rather, the same advantages are also given in cases in which the signals are in digital form and in muttibit words (or in a similar form) to addressable Locations on the tape.

DT-PS 3 05 534 describes a device for absolute or relative synchronization of moving parts Systems in the form of two moving elements, for example a recording medium and an element, luf which the information recorded on the recording medium is to be displayed. Included markings, for example magnetic pulses, are recorded on each element. Through these markings the running speeds of the two elements can be synchronized with regard to amount and phase. In this previously known device, however, there is no possibility of the amount and phase of the Running speed in addition to running the synchronization process in such a way that certain ins Attached memory locations on both elements relative to one another in a desired position will.

From CH-PS 4 77 739 a numerical movement monitoring and control device has become known with which the movement of a tape, for example a roller-driven magnetic tape, as it can be used for data recording, can be monitored and controlled. The control of the movement of the magnetic tape is tailored to the case that a distance must be inserted between two successive data records, which indicates the end of one and the beginning of the next data record. Recording and reading devices for such tapes must then be able to stop within this gap and start again. To implement these tape running processes, a direction-sensitive pulse counter is provided in this known device, the pulses of which indicate the movements of the tape. An up / down counter, which is preceded by gap means for blocking the pulses _S5 , receives these pulses, with switching means being also provided, by means of which a conversion of the counter content into a signal proportional to the displacement of the medium is required. With such a device, however, only the _bo control of the movement of a magnetic tape is possible. A synchronization of the running of two magnetic tapes is not possible with this.

It is known per se from DT-PS 10 68 757 in an arrangement for eliminating skew effects in _{tape-shaped (} , ₅ gen information storage media, to form a measure for a tape skew caused by such effects that the displacement of marking pulse trains recorded on the two edges of the tape is analyzed, a counter provided in the arrangement being in the center position and being controlled by the pulses of one train in one direction and of the pulses of the second train in the other Direction counted, the counter reading identifying the offset.

In the case of an arrangement proposed in DT-OS 21 40 741 with earlier priority, synchronization is the movement of the recording medium of one magnetic tape device with the movement of another magnetic tape device possible. There is a synchronization in the sense that when the two run asynchronously Magnetic tapes an envisaged storage location on a magnetic tape at exactly the point in time in the Area of at least one magnetic head of this tape recorder can be brought when on the Another tape recorder is currently performing a specific recording or playback process will. However, the running speed of both devices is not synchronized at the same time changed.

A control system known from US-PS 34 00 317 for synchronizing the run of the Magnetic tapes of at least two magnetic tape devices work according to the master-slave principle. Be there when recording information on the magnetic tapes of the various magnetic tape devices in Control tracks recorded time code reference signals. During playback, the reference pulses of the Master device and those of the slave device into an up-down counter available for each device which is the number of reference pulses coming from the master device and the respective slave device compares with each other and increases the speed of the slave tapes as a function of this comparison or humiliated. With this synchronization, the magnetic tape does not run on the master device changed, only the run of the slave devices. The disadvantage here is that this synchronization is time-consuming because the run of the magnetic tape on the Master device remains fixed and only the run of the magnetic tape on the slave device changes is subjected.

The present invention is based on the object of providing an arrangement of the type in question specify with which a fast adjustment of the synchronous running of two recording media can be achieved is.

This object is achieved according to the invention in an arrangement of the type mentioned at the outset solved that the counter can be preset when a desired memory location occurs in a transport device is and the control signal pulses from this storage medium and after the occurrence of the desired Storage location of the other storage medium also counts these control signal pulses and that the speeds both transport devices at the same time, but in opposite directions depending on which the Incorrect positioning are characteristic of the meter reading.

In particular compared to the control system according to the aforementioned US-PS 34 00 317 results in the The arrangement according to the invention has the main advantage that the time it takes to synchronize two transport devices is required due to out-of-phase control compared to the synchronization of a slave device with a master device is smaller.

For example, when storing video images in a recording and reproducing device for documents, in which certain pages of a document are stored on one video tape and other pages of the same document on another video tape, the corresponding transport devices carrying these tapes must be synchronized with the correct ones Tape address locations possible so that the pages of the document can be reproduced in a continuous, uniform sequence. The two transport devices are synchronized by measuring the relative positions of the selected tape storage locations in each transport device and by accelerating one transport device while at the same time the other transport device is braked until the storage locations in question come into synchronization. At this point in time, the acceleration and deceleration of the running speeds are switched off and the speed of the phase of the transport devices is synchronized with a common reference signal. The up-down pulse counter is used to monitor the relative displacement of the tape storage locations under consideration. When the counter is preset to the central counting position, a circuit provided for this purpose detects the first predetermined storage location signal which is to be reproduced by the corresponding tape transport devices. Thereafter, control track signals from the associated tape are fed into one side of the up / down counter to initiate counting in one direction relative to the center count. When the predetermined memory location signal occurs from the second transport device, control track signals are passed from the associated tape to the other side of the up / down counter, so that a counteraction to the stored count associated with the first transport device occurs. The digital-to-analog converter responds to the current counting position of the counter and supplies an analog speed control signal, the amplitude and polarity of which is used for the simultaneous acceleration of a transport device and other deceleration of the transport device in such a way that the two tape storage locations under consideration come into synchronization. When the amplitude of this analog speed control signal decreases, indicating that the counter is approaching its center count, the speeds of the respective tape transport devices come closer to the normal or standard recording and playback speed accordingly assumes its central counting position, the speed control signals from the digital-to-analog converter are switched ineffective and the transport devices are controlled by a standard reference signal, the intended storage locations on the belts being correctly synchronized.

Refinements of the inventive concept are characterized in the subclaims

The invention is described below with reference to an embodiment shown in the figure of the drawing This figure shows a block diagram of the embodiment of the invention for ensuring the synchronization of a pair of record and playback transport devices on predetermined tapes.

In the present case, a magnetic tape (not shown) with a recording format in which the information signals are contained in discrete groups or segments runs on each of the transport devices 1 and 2. Pre-recorded and addressable memory location signals are provided for these information segments. The transport devices can be operated in a search mode in order to bring the magnetic tape into a position suitable for recording or reproducing such a predetermined address. In the present exemplary embodiment of the invention, the grouped information is recorded by means of magnetic heads which rotate in a plane running transversely to the direction of tape movement, so that recording tracks are obtained which are transverse to the longitudinal direction of the tape. Each information segment may be, for example, one frame of video information correspond, in this case, each memory location a frame pulse and the beginning of the special video image is assigned to identifying image address, regardless of whether this memory location has been utilized or not. Furthermore, a control track running in its longitudinal direction is provided on the belt, which carries a periodic pulse signal. This control track signal is used to keep the speed of the transport device at a stationary predetermined value .
There is an up / down counter 11, which is controlled by a switching and detector circuit 21 belonging to the transport device 1 and a switching and detector circuit 22 belonging to the transport device 2, each of which sends control track pulses from the corresponding transport devices to various inputs of the counter 11. The counter 11 then assumes a counting position which is a measure of the phase difference between the selected memory locations present on the corresponding tapes.

The circuit 21 contains an image selection stage 23 which receives image address signals from the transport device 1 via a line 24. Upon the occurrence of the desired image address a frame pulse detector 26 and a preset input of the counter 11 to be driven 27 via an output line 28 of the selection stage 23rd As a result, the counter 11 assumes a counting position which is preferably in the vicinity of the middle value of the counting range. In this case the counter, which has a counting range of 64 bits, is set to a count of 31. The detector 26 responds to the next image pulse, whereby the beginning of the selected image coming from the belt of the transport device 1 is identified. The image pulses are sent from the transport device to the detector 26 via a line 29. Ok combination of the image selection stage 23 and the detector 26 is used to detect the beginning of de; desired image on the tape of the Transportvor direction 1; as a function of this acquisition process!

controls the detector 26 via an output line 31 to a gate 32, whereby via a line 34 of the dei Transport device 1 coming, with CT2 designated control signal pulses via the gate 32 to eini Up counting input 33 of the counter 11 given

i " . For the selected memory location or the image signal from the transport device 1, storage of the control track pulses ii results in the forward direction in the counter 11 starting from de

preset mean counter position a reference time.

The circle 22 , which is composed of similar components, causes a count of control signal pulses from this belt to start when a selected storage location signal or image from the tape occurs on the transport device 2. In this case, an image selection stage 36 detects the occurrence of the image address on a line 37 of the transport device 2 and controls an image pulse detector 36 via a line 39, which detects the first following image pulse delivered by the transport device 2 via a line 41. A gate 42 controlled by the detector 38 via a line 43 couples control signal pulses coming from the belt in transport direction 2 as a function of the image pulse belonging to the selected image area to a downward counting input 44 of the counter 11. These control signal pulses run via an output line 46 between the transport device 2 and an input of gate 42.

The selected image or the selected storage location from the transport device 1 therefore serves as a reference, wherein the counter 11 counts from the preset middle counting position in the forward direction until the desired memory location or the desired image address from the transport device 2 occurs. The control track pulses from the transport device 2 are then fed into the counter 11 at the input 44 fed in, so aass the counting sequence with which the counter 11 as a function of the control track signals from the transport device 1 continues to count, decrease or the counting direction is reversed. The instantaneous counting position of the counter 11 when the to the transport device occurs 2 belonging image pulse and following this image pulse therefore represents the phase or the position relation between the corresponding band image points.

A digital-to-analog converter is used to generate control signals as a function of the counting position of the counter 51, whereby the transport devices are in synchronization at the desired memory addresses to be brought. The converter 51 supplies an analog control signal at an output 53. This control signal has a magnitude which is the phase or position difference between the selected tape addresses is proportional and a polarity, which is a measure of the sense of direction in which this phase difference occurs. In other words, the polarity is a measure of whether the one belonging to the transport device 1 selected address leading or lagging the selected address belonging to the transport device 2 The analog control signal produced at output 23 is sent to one via separate signal paths 58 and 59 Speed control input 56 or 57 of the transport device 1 or 2 given. In one of these Signal paths a polarity or phase reversal is provided, so that the speeds of the transport devices be adjusted in opposite directions as a function of the output signal of the converter 51 can. As long as the selected tape storage locations of the transport devices 1 and 2 are not yet are synchronized, the transport speeds are determined by the output signal of the converter 51 im described sense regulated. If the synchronization condition is met, the speed control inputs become 56 and 57 disconnected from the output of the converter 51 and used for regulation on standard reference speed control loops 61 and 62 coupled In order to be able to carry out this transition in the control process, circuits 63 and 64 are provided which can be controlled by a synchronous detector 66 coupled to the output 53 with an input 67. The detector 66 detects an output signal at the output 53 of the size zero and controls as a function of which the circuits 63 and 64 on.

Regarding the response of the transport devices 1 and 2 to the counting state of the counter 11, this counter in the above sense initially in

ίο a mean counting position set, which in the present Case corresponds to the count 31. The digital-to-analog converter 51 is designed in such a way that it is at the output 53 an analog one. Output signal supplies the size of the Number of counts is proportional to which the

; 5 Count from the mean count with the value 31 deviates. The polarity of the signal at output 50 corresponds to the direction in which this count is related is offset to the middle count It is assumed, for example, that the pulse count in the counter U initially as a function of a selected image pulse from the belt of the transport device 1 and then as Function of a selected image pulse from the belt of the transport device 2 takes place. For the interval between these pulses the counter has 11 track pulse counts stored in the forward direction as a function of signals at the forward input 33 so that it by a certain number of counting positions from the middle counting position with the value 31 in the forward direction deviates when the image pulse belonging to the transport device 2 occurs. In this case the delivers Converter 51 a control signal with a size which the number of deviating from the mean counting Corresponds to counting positions and with a polarity which indicates that the desired tape storage location of the transport device 1 leads the selected tape storage location of the transport device 2. This analog control signal is via the circuit 58, which is used to carry out a polarity inversion includes an inverter amplifier 71 and a controlled one Gate 72 given to gate 56 of the transport device, whereby its transport speed to is reduced by an amount proportional to the amplitude of the control signal. The speed control takes place by means of a belt drive servo arrangement 73 which is contained in the transport device 1 and drives the magnetic storage tape. In this way, the phase or position of the selected Storage location of the transport device 1 as a function of the output signal of the converter 51 delayed

At the same time as the control signal is fed into the signal path 58 this signal is also fed into the signal path 59, but here none Polarity inversion takes place The signal path 59 contains an amplifier 76 (whose input and output

SS signal are in phase) and a controlled gate 77, which selectively couples the amplifier 76 to the input 57 of the transport device 2. The size of the control signal in signal path 59 is the same as in signal path 58, but the signal polarities are opposite. A tape drive servo arrangement 78 in the transport device 2 responds to the signal at the input 57 and accelerates the tape movement by an amount proportional to this signal. In this way, the belt speed in the transport device 2 is increased by the same amount by which the belt speed in the transport device 1 is reduced.
Due to the differential acceleration and

The braking of the transport device exceeds the Repetition frequency of the control track pulses from the transport device 2, which are sent to the reverse input 44 of the counter 11 are given soon the repetition frequency the control track pulses from the transport device 1, which are sent to the counter input 33. Therefore the momentary count of the counter 11 goes from their offset up counting position back to the middle counting position. Since the counting position changes, the size of the converter output signal at the signal output 53 goes to zero, so that the Differential acceleration and deceleration of transport devices 1 and 2 is gradually reduced, thereby making the tape speeds against the same standard recording and playback values and 89 and there with the pulse-shaped delivered by the corresponding transport devices Control signals CTl and CT2 is compared. The output signals at outputs 86 and 87 therefore regulate the transport devices 1 and 2 so that the corresponding belts at speeds are driven, in which the coming from them control track signals to the reference signal from the generator 96 are adapted.

Once the tapes are synchronized to the desired pair of tape addresses, they can

to forget.

It can happen that a rapid differential speed change in the transport devices leads to the fact that the belt speeds continue to be synchronized with this particular belt phase relationship operate. If you want to save other locations on the corresponding tapes to synchronize, the operations described above for the new addresses or image areas repeated.

When using the arrangement according to the invention in the magnetic tape recorder with rotating scanning heads,

Run through synchronization state. In this case 20 for example in devices of the type mentioned above

Processing of video signals and certain digital signals is the longitudinal speed of the Tape is not necessarily related to the transmission sequence of the information signal that is on magnetic Transverse tracks or on tracks running at an angle to the longitudinal direction of the tape. In such devices, the function is so that the rotation of the transducer heads the signal transmission sequence determined for recording and playback,

Esl! Dnwi «igmoininenrdaB the counter 11 gradually in 30 while the one caused by the tape drive its middle counting position passes, so that the belt longitudinal speed of the belt only to one

"" correct phasing of the tape with respect to the rotating converter is used. Therefore, when the information signal is recorded in segments or fields, the tape must be set in a correct position in the direction of travel in front of the desired image address and then driven at a standard tape speed so that the desired Information signal corresponding magnetic coil

Input 56 as well as amplifier 76 and input 40 are in phase with the rotating heads. To this 57 is interrupted. Simultaneously with it being achieved is usually on a longitudinal one Gates 82 and 83 switched through, so that now the control track recorded a signal that the beginning of the Speed control inputs 56 and 57 at outputs indicating information segment, where da * band through 86 and 87 of phase comparison stages 88 and 89 only monitor this longitudinal control track be switched. The pair of gates 72 and 82 are 45 can be set correctly. That is the beginning of the

the transport device 2 then rushes ahead relative to the transport device 1. If this is the case, it works Counting position of the counter from the forward direction through the middle counting position in counting positions in reverse direction over so that the polarity of the speed control signal at output 63 through Zero goes and adopts the other polarity. This in turn results in a correct adjustment of the Transport speeds.

speeds slowly in a stable synchronicity State. The synchronous detector 66 detects the zero condition of the at its input 67 Output signal of the converter 51 and, as a function thereof, delivers a switching function signal to one Signal output 81. As a function of this state, the gates 72 and 77 are opened so that the Signal path between the amplifier 71 and the

by a logic control inverter 91, which is switched into the circuit of the gate 82, in opposite directions controlled (one gate open or closed while the other is closed or open). Correspondingly, a logic control inverter 92 is switched on in the circuit of the gate 83, which the Gates 77 and 83 controls in opposite directions as a function of the switching signal at output 83.

At the outputs 86 and 87 of the phase comparison stages 88 and 89 arise as a function of one of The signal indicating the addressed memory location can be an image pulse which marks the beginning of a video image identified. According to the invention, therefore, the tapes become synchronized with speeds driven, which with respect to the normal tape speed lead and lag, so that certain Information images or image locations out of phase are moved past the rotating head assembly. at Achieving the synchronization of the desired image

emem 55 addresses and when returning to a standard speed

The transverse information tracks come back again signals that allow the transport devices to be in phase with the rotating magnetic heads. So isi Nominal speed and nominal phase are then adjusted to ensure correct recording or playback Specifically, the generator 96 provides a reference signal information on the selected tape storage signal, this is possible on one input of each comparison stage 60.

1 Bbtt drawings

Claims (6)

Patent claims: 1. Arrangement for synchronizing the movement of two transported by transport devices Storage media, the memory section signals and recorded in a control track, for speed control carry serving pulse-shaped control signals, with a counter, whose up-counting input signals characterizing the movement of the first storage medium and its downward counting input signals characterizing the movement of the second storage medium can be supplied and from whose counter reading, which characterizes mutual incorrect positioning, determines the setting of the speed the storage media can be controlled above or below a target speed, thereby characterized in that the counter (II) when a desired memory location occurs in a Transport device (1) can be preset and the control signal pulses from this storage medium as well as after the occurrence of the desired memory of the other storage medium also counts these control signal pulses and that the speeds both transport devices (1, 2) at the same time but in opposite directions depending on the the counter reading characterizing the incorrect positioning can be regulated. 2. Arrangement according to claim 1, characterized in that the counter (11) when the desired memory location in the one transport device can be preset to a mean counter reading is and that the storage media at the middle count at the same speeds are regulated. 3. Arrangement according to claim 2, characterized in that a digital-to-analog converter is connected to the counter (11) (51) is connected, which converts the counter reading in the form of digital signals into a Analog signal transferred, the size and polarity of the deviation of the counter reading from corresponds to the mean count and that the speeds of the transport devices (1, 2) can be regulated as a function of the analog signal. 4. Arrangement according to claim 3, characterized in that that the analog signal on separate signal paths (58, 59) tape drive servo arrangements (73, 78) of the transport devices (1, 2) can be fed into one of the signal paths (58) Inverter (71) is connected. 5. Arrangement according to claim 2, characterized in that the transport devices (1, 2) at Occurrence of the middle counter reading with a speed of the storage media Reference timing signal can be synchronized. 6. Arrangement according to claim 5, characterized in that that a responsive to the middle count detector (66) at the middle Counter reading of the analog signal from the tape drive servo arrangements (73, 78) of the transport devices (1,2) switches off and the reference clock signal switches on.