DE1524739C3 - Circuit arrangement for generating clock pulses for controlling the processing of digital data stored on a magnetic tape - Google Patents

Description

The invention relates to a circuit arrangement for generating clock pulses for the Control of the processing of items lying on a magnetic tape at right angles to its direction of movement Digital data stored in memory locations, using one of those stored on the magnetic tape stored digital data reading reading device downstream clock-controlled buffer memory corresponding to the digital data read by the reading device from the magnetic tape Impulses can be emitted.

It is already an arrangement for eliminating skew effects in tape-shaped information storage media known (DE-AS 10 68 757). The relevant skew effects are eliminated in the process by means of control signals' - which of two spaced apart recording tracks of the Band can be derived. With the help of this known arrangement, however, non-clock pulses can be more predetermined Duration at different speeds of the tape-shaped information memory provided in each case be achieved.

There is also a multi-channel signal circuit known (DE-AS 10 81 501), in which the information in the form a sequence of pulse groups is transmitted and in which phase distortions between the simultaneously transmitted information pulses of a given group occur and the pulse groups to a Multiple input lines are received. There are also measures in this known arrangement taken to compensate for the phase distortions concerned; via the generation of clock pulses predetermined duration at different pulse repetition frequencies is nothing in this context known.

There is also a circuit arrangement for scanning recording media known (DE-AS 11 25 698),

on which characters in the form of bits are recorded in several parallel tracks Scanning device for each track of the recording medium, a buffer memory, an input counter, a comparison circuit and a common output counter is assigned to all tracks of the recording medium. Further measures are taken in this known circuit arrangement under consideration to the simultaneous Output of the bits of a character in several parallel tracks of the recording medium at the same time or not to be sensed at the same time. Any measures to generate of clock pulses of a predetermined duration even at different speeds of movement of the respective intended recording media are not met here either.

A circuit arrangement for obtaining discharge pulses from a recording medium in the case of skew compensation, finally, there is also

still in connection with the: use of a punched tape as a recording medium known (magazine "Electronics", VoI 32,16.12.59, pp. 72 to 75). In this context, too, however, nothing is known about the generation of clock pulses of a predetermined duration even when the punched tape moves at different speeds: ■ ^;

The invention is based on the object of using only one clock generator for generating clock pulses a predetermined duration, even with different magnetic tape speeds or pulse repetition frequencies get along.

The above-mentioned object is achieved with a circuit arrangement of the type mentioned at the beginning according to the invention in that a single, clock pulses of a predetermined duration at different Magnetic tape speeds emitting free-swinging pulse generator is provided on the output side is connected to a signal input of a blocking gate, the blocking input of which is connected to the outputs of the intermediate memory is connected via a control circuit, which, in the case of intermediate storage, is certain Pulses in the buffer emits a signal leading to the locking of the locking gate that a clock pulse generator circuit is connected to the output of the locking gate, each on its effective control by one of the pulses emitted by the locking gate towards a clock pulse specific Duration, and that the clock pulse g ^ ne- "" ~ " rator circuit is connected on the output side to the blocking input of said blocking gate. Through this the advantage is achieved that clock pulses of a predetermined duration also in a relatively simple manner different magnetic tape speeds can be generated without a separate Clock pulse track must be provided on the magnetic tape.

According to an advantageous embodiment of the invention, the control circuit contains an AND gate, which is connected to the outputs of individual intermediate storage levels of the intermediate storage. Through this there is the advantage of a relatively low circuit complexity for the control circuit.

According to a further advantageous embodiment of the invention, the clock pulse generator circuit is in the input circuit a pulse delay circuit is provided. This allows for a relatively simple Compensate for skew effects on the magnetic tape. Due to the delay time of the relevant Pulse delay circuit is namely achieved that the necessary occupancy at the time of query the buffer is guaranteed.

According to yet another advantageous embodiment of the invention, the output is the pulse delay circuit connected to the blocking input of the blocking gate. This has the advantage of that in a relatively simple manner during the delay period of the pulse delay circuit in question the delivery of clock pulses via said locking gate is blocked, so that the expiry of the relevant delay time is guaranteed.

According to yet another advantageous embodiment of the invention, the pulse delay circuit formed by a one-shot multivibrator, and the clock pulse generator circuit is formed by the trailing edges the pulses emitted by this monostable multivibrator can be controlled. This results in the advantage of one thing: especially: little circuitry Expenditure for the pulse delay circuit and the clock pulse generator circuit. ■■ · ..; . . · ■:. · ■.

According to yet another useful embodiment the invention is in. Input circle of Clock pulse generator circuit is another pulse delay circuit provided whose delay duration is greater than the .. delay duration of the said a pulse delay circuit; and a selection circuit is also provided through which one of the two pulse delay circuits between the output of the locking gate and the Input of the clock pulse generator circuit can be effectively switched. This has the advantage that on relatively simple way to compensate for skew effects at different magnetic tape speeds can be.

According to yet another advantageous embodiment of the invention, the second pulse delay circuit is formed by a monostable multivibrator whose output is connected to the blocking input of the Lock gate is connected. This also results in the advantage of a particularly low circuitry Expenditure for the pulse delay circuit.

According to yet another advantageous embodiment of the invention, the clock pulse generator circuit contains a monostable multivibrator, each of which sends a clock pulse to the specific Duration gives. This has the advantage of a particularly low circuit complexity for the clock pulse generator circuit.

The invention is explained in more detail below with the aid of a drawing.

The arrangement shown in the drawing is used for reading on a magnetic tape in a row of digital data stored transversely to its direction of movement. That the In each case to be read digital data carrying magnetic tape is from a magnetic tape device 10 to a Read head assembly passed, one of the number of located on the magnetic tape in question Data tracks can contain the corresponding number of individual read heads. In the present case it is assume that the magnetic tape in question has three data tracks. This means that across that Magnetic tape movement direction provided on the respective magnetic tape three storage locations are. Read amplifiers 15 are connected downstream of the individual read heads of the read head arrangement mentioned, which amplify the data read from the magnetic tape. The sense amplifiers 15 are Read flip-flops 46, 47, 48 are connected downstream with one input each. The relevant reading flip-flops 46, 47, 48 give from their outputs the corresponding digital data read from the magnetic tape Signals. The aforementioned read flip-flops 46, 47, 48 are each with their other input to a Input terminal carrying clock pulses connected. With the help of clock pulses applied to this terminal the relevant flip-flops are reset.

The relevant read flip-flops 46, 47, 48 lead with their outputs to the inputs of an AND gate 50. To other inputs of this AND gate 50 gives an operating mode control logic circuit, not shown in any more detail in the drawing Command signals. Such command signals are the AND gate 50 via the input terminal

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Λ / 2 as well as supplied via the; OR gate 51: The OR gate 51 has the input terminal M4, Af3 and AfI ', each of the aforementioned operating mode control circuit can receive corresponding command signals supplied. The output of the AND gate 50 is connected to one input of an OR gate 53. To the other input of this OR gate. 53 is the output of a further OR gate 57 having a plurality of inputs connected. The output of the OR gate 53 leads to the blocking input of a blocking gate 55. With the signal input of this locking gate 55, a free-swinging pulse generator 28 is connected, which in the present case z. B. can oscillate with an oscillation frequency of 100 kHz. At the exit of the Lock gate 55 has a pulse shaper and amplifier circuit 58 connected to its input. To the The output of this pulse shaper and amplifier circuit 58 are two AND gates forming a selection circuit 60, 61 each connected to one input. The other entrance of this AND gates 60,61 are from the aforementioned mode control circuit Appropriate unlocking signals can be supplied. This will be explained in more detail below To be received.

Two monostable flip-flops 22, 23 with their respective inputs are connected to the outputs of the AND gates 60, 61 considered last. The input of the monostable multivibrator 22 is connected to the output of the AND gate 60 and the input of the monostable multivibrator 23 is connected to the output of the AND gate 61. Of these monostable flip-flops 22, 23, the monostable flip-flop 22 has a turnover time of z. B. 60 μ5εΰ; the monostable flip-flop 23, however, has a turnover time of z. B. 1000 μ5βο. It should be noted at this point that with the aid of these monostable flip-flops 22, 23, different skew effects present at different magnetic tape movement speeds can be taken into account. The outputs of the two monostable multivibrators 22, 23 are connected to the input of a further monostable multivibrator 64 via an OR gate 63. This monostable multivibrator 64 can have a reversing time of z. B. possess 25 μςεο. Reversal time is understood here to mean that time span during which the respective monostable multivibrator emits an output signal from its output. An amplifier 65 is connected with its input to the output of the last-mentioned monostable multivibrator 64. The aforementioned clock pulses can be picked up at the output of this amplifier 65.

Connecting lines lead from the amplifier 65 and from the outputs of the monostable multivibrators 22, 23 to the inputs of the OR gate 57 already mentioned at the beginning.

After the structure of the arrangement shown in the drawing has been explained in the foregoing to the extent necessary for an understanding of the present invention, the mode of operation of this arrangement will now be considered in more detail. In the absence of corresponding blocking signals, as can be supplied from the output of the AND gate 50 and the output of the OR gate 57, the blocking gate 55 transmits the 100 kHz pulses emitted by the 6s free-swinging pulse generator 28 to the pulse shaper connected downstream of it - And amplifier circuit 58 which, in response to such a control, emits an output pulse which is one of the inputs of the two AND gates 60, 61. Appropriate unlocking signals are fed to the other inputs of these two AND gates 60, 61 from the operating mode control circuit already mentioned. Unlocking signals are fed to the input HS of the AND gate 60 when the relevant magnetic tape, the data of which is to be read, is moved at a relatively high tape speed. In contrast, the input terminal HS 'is supplied with the AND gate 61 from the relevant operating mode control circuit when the relevant magnetic tape is moved at a relatively low tape speed. The unlocked AND gate of the two AND gates 60, 61 enables the downstream monostable flip-flop 22 or 23 to be controlled. The monostable multivibrator 64 in question emits an output pulse to the amplifier 65 during its own reversal time, which then emits a corresponding clock pulse. The arrangement comprising the monostable multivibrator 64 and the amplifier 65 connected downstream of it represents a clock pulse generator, which is connected downstream of the two monostable multivibrators 22, 23, each representing a pulse delay circuit. The transmission of the pulses emitted by the free-swinging pulse generator 28 via the blocking gate 55 is interrupted at least while a clock pulse is emitted from the output of the amplifier 65. As already mentioned, when a clock pulse occurs, the amplifier 65 sends a corresponding pulse via the OR gate 57 and the OR gate 53 to the blocking input of the blocking gate 55, which thus blocks. In a corresponding manner, however, the output pulse emitted by the respectively effective monostable multivibrator 22 or 23 can also be used for a corresponding blocking of the blocking gate 55, as is indicated in the drawing. In a similar way, the transmission of pulses emitted by the free-running pulse generator 28 via the blocking gate 55 is suppressed when a corresponding output signal is emitted by the AND gate 50. The AND gate 50 emits such an output signal each time a certain signal occurs at the output of the read flip-flops 46, 47, 48 if, in addition, from the aforementioned operating mode control circuit to the aforementioned terminals M2, A / 4, AO or AfI 'corresponding command signals are applied. In the case of the particular signal occurring at the 'outputs of the read flip-flops 46, 47, 48, it may be, for. B. be a synchronization signal that is stored in the same places on the magnetic tape. The signals emitted by the sense amplifiers 15 and stored in the read flip-flops 46, 47, 48 are in each case deleted by a clock pulse emitted from the output of the amplifier 65. For this purpose, the clock pulses are fed to all reset inputs of the relevant flip-flops 46, 47, 48. Only after the read flip-flops 46, 47, 48 have been reset can new signals be stored in the relevant flip-flops and taken from their outputs for further processing.

For this 1 wall

Claims (8)

Patent claims: 1. Circuit arrangement for generating clock pulses for controlling the processing from storage locations on a magnetic tape at right angles to its direction of movement digital data, using one of those stored on the magnetic tape digital data reading reading device downstream clock-controlled buffer memory the digital data read from the magnetic tape by the reading device, respectively corresponding pulses can be emitted, characterized in that a single clock pulse a predetermined duration at different magnetic tape speeds dispensing freely swinging Pulse generator (28) is provided, the output side at a signal input of a Blocking gate (55) is connected, the blocking input of which is connected to the outputs of the buffer (46, 47, 48) is connected via a control circuit (50, 53), which with intermediate storage of certain Pulses in the buffer store a signal which leads to the blocking of the blocking gate (55) emits that a clock pulse generator circuit (64, 65) is connected to the output of the locking gate (55) is, each on their effective control by one of the locking gate (55) emitted impulses towards a clock pulse outputs a certain duration, and that the clock pulse generator circuit (64, 65) on the output side with the Blocking input of said blocking gate (55) is connected. 2. Circuit arrangement according to claim 1, characterized in that the control circuit is an AND gate (50) that is sent to the outputs of individual intermediate storage levels of the intermediate storage (46,47,48) is connected. 3. Circuit arrangement according to claim 1 or 2, characterized in that the input circuit Clock pulse generator circuit (64, 65) a pulse delay circuit (22) is provided. 4. Circuit arrangement according to claim 3, characterized in that the output of the pulse delay circuit (22) is connected to the blocking input of the blocking gate (55). 5. Circuit arrangement according to claim 3 "or 4, characterized in that .that the pulse delay circuit (22) is formed by a monostable multivibrator and that the clock pulse generator circuit (64, 65) by the trailing edges of the respective output from this monostable multivibrator Impulse is controllable. 6. Circuit arrangement according to one of claims 3 to 5, characterized in that im Input circuit of the clock pulse generator circuit (64, 65) a further pulse delay circuit (23) is provided, the delay duration of which is greater than the delay duration of the aforementioned a pulse delay circuit (22), and that a selection circuit (60,61) is provided by each one of the two pulse delay circuits (22, 23) between the output of the Locking gate (55) and the input of the clock pulse generator circuit (64,65) can be effectively switched. 7. Circuit arrangement according to claim 6, characterized in that the second pulse delay circuit (23) is formed by a monostable multivibrator, the output of which connects to the blocking input of the locking gate (55) is connected. 8. Circuit arrangement according to one of claims 1 to 7, characterized in that the Clock pulse generator circuit (64, 65) contains a monostable multivibrator (64), which on its control each time emits a clock pulse of the specified duration.