DE2529151C2 - Circuit for controlling the flow of digital data during transmission to and from magnetic tape - Google Patents

Description

criminator, which compares the frequency of the control oscillator with that of the pulse generator tracking the magnetic tape, and which produces an error signal that is fed back via a filter to the control oscillator so that the latter is adjusted with regard to the frequency of the signals it emits. The phase discriminator can be constructed from numerous individual stages that form a series circuit. The information read out by the read / write head or to be fed into it is expediently passed through a shift register, the number of stages of which corresponds to that of the phase discriminator, so that the throughput of the information to be extracted can be controlled with the aid of a corresponding number of cross connections from the phase discriminator.

On the special problems when starting the magnetic tape, when the writing process has to be suppressed until it has reached a prescribed drive speed ^; n of the German Offenlegungsschrift 20 27 799 not received.

From US Pat. No. 38 05 286 it is known to use a speedometer with the drive roller of the magnetic tape couple, which emits, for example, 500 pulses per revolution of the drive shaft to a counter, the Reaching a predetermined number, which is proportional to a starting length of the approaching magnetic tape, a Brings write permission signal, with the appearance of which the data signals to the read / write head be released.

If one assumes that the drive roller of the magnetic tape is accelerated constantly, the works Counter as a detector, which in Activity occurs that is reached after running through the start length.

From the publication: "IBM Technical Disclosure Bulletin", Volume 12, No. 7, (December 1969), pages 1006 and 1007, is the recording of digital data on magnetic tape at a constant density, but at known to a changing speed. The work area for recording and reading becomes thus extended to all speeds between the full drive speed of the Magnetic tape and half the drive speed are, at the same time the initially designated »gap between the blocks «can be reduced. The essential part of the applied circuit is a phase locked loop with a voltage controlled oscillator, a comparator and a filter. The comparator is controlled by a tachometer coupled with the drive roller of the magnetic tape Pulses are fed that not only increase the drive speed of the magnetic tape, but also the length play back that it goes through. Therefore there is the time interval between two successive speedometer pulses directly indicates the length by which the magnetic tape is advanced during this time interval will. The clock pulses from the voltage-controlled oscillator of the phase-locked loop is returned, it finds the Formation of an error signal takes place, which is sent via a filter to the control terminal of the voltage-controlled oscillator is applied, via whose output line write and clock pulses the write and read processes which are connected to the read / write head arranged on the magnetic tape.

In this known circuit, the frequency is

clock pulses fed back from the voltage-controlled oscillator to the comparator at approximately the frequency of the impulses coming from the speedometer. Once the data is recorded however in very high density should graze, the frequency of the clock pulses from the voltage-controlled oscillator differs strongly on the frequency of the speedometer pulses z. B. by a factor of 20 and more. To achieve the A comparison in the comparator would then be necessary to include a divider in the phase-locked loop which the clock pulses of the voltage controlled oscillator during their return to the comparator would have to be divided by a factor of 20. While in the case of registered mail such a measure appears feasible, it is not considered when reading out, because then a direct comparison between the data read out at the high frequency and that generated at the high frequency Clock pulses of the voltage controlled oscillator takes place while such a high frequency is not of the speedometer pulses can be reached.

The invention is based on the object of specifying means, of which the speedometer tapped information about the tape speed in addition to the synchronization of the reading speed the data bits can be used.

According to the invention, this object is achieved in that the output is in a second phase-fixed loop of a read clock pulse generating oscillator is connected to one input of a comparator whose other input is connected to the read circuit, and its output via a low-pass filter and a summing amplifier at the control input of the voltage controlled oscillator of the second phase-fixed Loop is connected that the summing amplifier as a second input signal from the Comparator running signals can be fed through the filter to the first phase-locked loop, and that when Reaching the specified fraction of the full drive speed while starting up a detector receiving the impulses from the tachometer, first the comparator, the filter and the voltage-controlled oscillator of the first phase-locked loop and then the comparator, the filter and the voltage controlled oscillator of the second phase-locked loop can be switched on.

The further phase-locked loop with the voltage-controlled oscillator, whose frequency is compared to the the file reading is captured from the tape controls the data retrieval circuit and will also switched on depending on a threshold value circuit. Your connection to this second loop is designed so that your voltage controlled oscillator a short period of time after the first voltage controlled oscillator is switched on, is also switched on. An error voltage that the Phase comparator is taken from the first phase-locked loop, the second becomes phase-locked Loop with its voltage controlled oscillator, whose frequency, if it is switched on, is instantly synchronized with the reading speed of the data bits.

An embodiment of the invention is shown in the drawing and will be described in detail below explained. It shows

F i g. 1 schematically shows the transport mechanism of a magnetic tape to which the invention is applied, FIG. 2 is a block diagram of the circuit according to FIG

Invention,

3 shows the block diagram of a detector 37 for perceiving a threshold value for the belt speed, which is applied in the circuit of Fig. 2, and

Fig. 4 several diagrams for illustration the operation of the circuit according to the invention.

The mechanism for transporting the tape, as shown in FIG. 1 two coils 10 and 11 on which a Magnetic tape 10a is unwound and wound, a drive roller 14 and a reversible motor 12 for Further conveyance of the magnetic tape 10a, next to which a read / write head 20 is arranged; further the magnetic tape 10a runs over an idle mechanism 19 and forms two slack loops 17 and 18. A circuit 21 is connected to the read / write head 20, of which the on a line 22 appearing data are recorded on the magnetic tape 10a, while that of this read data occur in a line 23. A shaft 16 is connected to the drive roller 14 Tachometer 15 coupled, which preferably works digitally and optically or magnetically. It delivers on one Line 24 pulse-shaped signals, the repetition rate of which is proportional to the speed of the drive roller 14 is.

The usual operation of the transport mechanism of FIG. 1 is as follows: Via a line 13 a start signal is sent to the motor 12, which excites it and thus the start-up of the drive roller 14 causes the magnetic tape 10a past the read / write head 20. The direction of movement is indicated by a , Forward "or" Reverse "signal set, which is also fed to the motor 12. As soon as the Movement of the magnetic tape 10a on the read / write head 20 begins, the loop 17 or 18 disappears, and the other increases accordingly. The respective length of the loops 17 and 18 is determined by Scanning devices (not shown) perceived which each have a motor (not shown), which adjusts the direction of rotation of the coil, as well as its speed so that the lengths of the Loops 17 and 18 are in a predetermined relationship to one another. After the magnetic tape 10a on its full speed is brought by it mi: with the help of the circuit 21 the data are read out or registered. This transport of the magnetic tape 10a is shown in the plots in FIGS. 4a and 4b made clear.

4a shows a cross section through the magnetic tape 10a, above which one direction of tape movement relative to the read / write head is indicated by an arrow. A point C is considered to be the position of the read / write head 20 relative to the stationary magnetic tape 10a. As soon as the start signal reaches the motor 12, the magnetic tape 10a is accelerated to its full speed, as shown in FIG. 4b by a line CB . At full speed, which is achieved at point B, a block of data in the magnetic tape can enrolled 10a einge-> or read from it. Thereafter, the motor 12 receives a stop signal, whereby the magnetic tape 10a is decelerated, like a line A-Cin of FIG . 4b indicates until it comes to a standstill at point C.

As can be readily seen, the accelerations or decelerations imposed on the motor 12 are increased when the width of the gap AB is reduced and / or the full speed of the magnetic tape 10a is increased. In the latter case, the motor 12 consumes significantly more current, and in addition the mechanical stresses to which the transport mechanism of the magnetic tape 10a itself is subject to increase.

With the aid of the subject matter of the invention, the accelerations and decelerations to which the arrangement is subjected can be kept smaller if the data transmission takes place at a speed of the magnetic tape 10a which is only a given proportion, e.g. B. 50% of the aforementioned full speed is or exceeds. By defining this threshold value of the speed, as can be seen from FIG. 4c, smaller accelerations or decelerations are possible, as indicated by lines C-β 'and 4'-C, while the desired width of the gap AB between the data blocks is retained. Of course, according to the invention, the recording speed of the bits can also be modified in accordance with the tape speed, so that the requirement to maintain a constant bit sequence can also be met.

In Fig. 2 are a first phase-fixed oscillator 28 for controlling the writing speed of the bits and a second phase-fixed oscillator 27 for Control of the circuits for the recovery of the bits shown by a detector 37 of the Speed threshold value can be switched on.

Your internal structure is z. B. in US Pat. No. 3,577,132. The oscillator 28 includes, for. B. a voltage-regulated oscillator 32. its frequency is more different from that of its control input terminal Fault voltage is influenced by a phase

■ comparator 35, the z. B. in U.S. Patent 37 01 039 is explained, is derived via a low-pass filter 34 and an amplifier 33. The low-pass filter 34, preferably according to a Bessel structure, has a speed approximately equal to the pulse frequency of the tachometer 15 matching blocking frequency when the tachometer 15 operates at half the speed. the an input terminal of the phase comparator 35 is fed via the line 24 from the tachometer 15, while the other via a frequency divider 36 at the output terminal of the voltage controlled oscillator 32 is connected. In practice, the recording speed of the bits can be several times the frequency the speedometer exceed 15; therefore, the frequency divider 36 is the frequency of the voltage regulated Oscillator 32 is reduced to a value equal to the tachometer frequency at full belt speed is. When the normal signal frequency supplied by the tachometer 15 at full belt speed for example 32 kHz and the normal output frequency of the voltage controlled oscillator 32 640 kHz, the frequency divider 36 divides the latter by a factor of 20.

The structure of the second phase-fixed oscillator 27 is similar to the first oscillator 28 and therefore contains also a voltage-controlled oscillator 43 and a phase comparator 40, whose error signal a Low-pass filter 41 and a summing amplifier 42 connected downstream of this, whose Output terminal is connected to the control terminal of the voltage-regulated oscillator 43.

Also the phase comparator. 40 receives two signals similar to the phase comparator 35. One comes from the voltage-controlled oscillator 43, while

25 29

rend the other from a data output line 25a a decoder 25 is brought up to recover the data. The construction of the decoder 25 is selected depending on the structure of a shutter egg 30 to be used for the arrangement for recording the Data belongs to the magnetic tape 10a.

Although the structure of the two phase-fixed oscillators 27 and 28, viewed on the surface, almost is the same, there is at least one significant difference, namely the summing amplifier 42 of the oscillator 27, which takes the place of the amplifier 33. While the one input signal of the summing Amplifier 42 receives the error signal of the phase comparator 40 which is passed through the low-pass filter 41 is formed, the other input signal comes as an error signal of the phase comparator 35 via a low-pass filter 34 and 44, both of which are preferably constructed in the Bessel manner, and of which the latter has a slightly lower cutoff frequency than the former. The purpose of connecting the totalizing Amplifier 42 via the low-pass filters 34 and 44 to the phase comparator 35 will be explained below.

During operation, the phase-fixed oscillators 27 and 28 from the detector 37 of the Speed threshold value is switched on, which is connected to the speedometer 15 Coming line 24 and with its output terminals 45 and 46 to the phase comparators 35 and 40 lies. In this way he can perceive the speed of the magnetic tape 10a; if be one Reached a predetermined proportion of full speed, it is excited via its output terminals 45 and 46 the two phase-fixed oscillators 27 and 28. The output terminal 46 is for this purpose on the voltage-regulated Oscillator 32, connected to the low-pass filter 34 and to the phase comparator 35. The same applies to the output terminal 45, which is connected to the corresponding elements of the phase-fixed oscillator 27. the Connection of these output terminals 45 and 46 to the phase comparators 35 and 40 and to the low-pass filters 34 and 41 are used to set the initial conditions in these components during the connection to the voltage controlled oscillators 32 and 43 is provided so that the latter in one established phase state.

In the detector 37 of the speed threshold value there are two monofiops 47 and 48 and two flip-flops 53 and 54 included. The line 24 coming from the tachometer 15 is located according to FIG. 3 in parallel on the two triggering inputs of the monofiops 47 and 48 and also on two logic elements 49 and 50, which are followed by the set and reset input terminals of the flip-flop 53, as well as two others Linking elements 51 and 52, on which the setting or. Reset input terminal of the second flip-flop 54 connected. The signals emitted by the monoflop 47 reach the second input terminal of the Links 49 and 50; the same applies to the monoflop 48 and the logic elements 51 and 52. As soon as the monoflop 47 is triggered, the logic element 49 receives a switch-on signal and the logic element 50 a blocking signal: the signal feed is in the inactive state of the monoflop 47 conversely, the monoflop 48 and the two link members 51 and 52 act in a corresponding manner Way together. The two monofiops 47 and 48 are shared by the trailing edge of the Line 24 triggered impulses coming from the tachometer 15; only the monoflop 48 remains set a little longer than the monoflop 47. In the In practice, the monostable multivibrator 48 remains set in its active state for a period approximately equal to that > Distance / wipe corresponds to the impulses of the tachometer 15 if the belt speed is half their full value. If the repetition period of the pulses emitted by the tachometer 15 is at the full tape speed is 30 msec, the excitation duration of the monoflop 48 would be about 60 msec fixed, while with the monoflop 47 this time span could be 50 msec.

The speed threshold detector 37 works as follows: The trailing edges of the

i "> line 24 occurring pulses from the tachometer 15 trigger the two monoflops 47 and 48, the Bring a switch-on signal to logic element 49 or 51 during its active period of time. Before however, the magnetic tape 10a is half its full

- "Speed reached is the distance between the The impulses of the speedometer 15 are so great that the two monofiops 47 and 48 are in their inactive state take in. In this case, the two logic elements 50 and 52 are excited so that the downstream

- ^ th flip-flops 53 and 54 remain in the reset state. As soon as the belt speed reaches 50% of its full value, the distance between the successive pulses of the tachometer 15 so far removed that they are at the set input terminal

S "of the link 51 arrive before the Monoflop 48 recovered. The logic element 51 allows the pulses from the tachometer 15 to be sent to the set input terminal of the flip-flop 54 go through, so that the output terminal 46 is activated, which in turn controls the phase-sensitive

'"■ first oscillator 28 switches on. In the case of a continuous As the belt speed increases, the interval between successive pulses of the Tachometer 15 so far that they arrive at the link 49 before the monoflop 47 recovers.

4Ί When this happens, flip-flop 53 is set and the Output terminal 45 energized, whereby the phase-fixed oscillator 27 is switched on. The two flip-flops 53 and 54 then remain set until the speedometer 15 falls below half the full value

'"' Tape speed reaches, whereby the flip-flops 53 and 54 are reset by the impulses now coming from the tachometer 15 through the logic elements Go through 50 and 52. When the flip-flops 53 and 54 are reset, the

> "phase-fixed oscillators 27 and 28 switched off, with which the transmission of the data stops.

In summary, the arrangement of FIG. 1 works. 2 when recording bits as follows: The motor 12 (FIG. 1) is given a start signal

"'"' supplied and with this the movement of the magnetic tape 10a initiated via the read / write head 20, with pulses from the tachometer 15 via the line 24 get into the detector 37 (FIG. 2) and the phase comparator 35. As soon as the speed of the speedometer 15 reached about half of their full value, whereby one can also choose another fraction of the full value, the detector 37 is activated via its output terminal 46 the phase comparator 35, the low-pass filter 34 and the voltage-controlled oscillator 32. Now the comparator 35 compares the pulse frequency of the speedometer pulses with that of the oscillator 32 output, divided frequency and produces an error voltage that is the difference between

corresponds to its two input frequencies. This error voltage runs through the low-pass filter 34 and the Amplifier 33 to the control terminal of the voltage-regulated oscillator 32, to the frequency of the oscillator 32 to be held on that of the speedometer 15. Of the output pulses of the oscillator 32 are the Data signals from the data source 29 at the right time via the locking icr 30 to the line 22 and thus supplied to the read / write circuits 21. This locking egg 30 is through a Write signal on a line 26 put into operation, so that the data from the circuits 21 on the Magnetic tape 10a can be recorded. At the end of the .Schreibvorganges the motor 12 receives a Sioppsignal, from which it is delayed and stopped. When the magnetic tape 10a slows down, it goes The writing process continues until the speedometer i5 has a speed drop below half of the full Value signaled. In this case the signal is removed from the output terminal 46 of the detector 37, whereby the phase-fixed oscillator 28 is switched off and the recording is stopped. From the seal egg 30, the data coming from the data source 29 are encrypted before they are on the magnetic tape 10a to be recorded.

During the reading process, the magnetic tape 10a is started in the same way as before described, and the fixed phase oscillator 28 operates in the same way; only the sealing egg 30 continues to be held inactive, so no signal passed to him on line 26. As soon as the magnetic tape 10a has a predetermined When it has reached a fraction of its full speed, the detector excites via its output terminal 45 the phase-fixed oscillator 27, so turns it on. From the read / write circuits 2! takes the Decoder 25 receives the data via line 23 and, after it has been decrypted, passes it on to line 25a one input terminal of the phase comparator 40, which belongs to the phase-fixed oscillator 27. in the The phase comparator 40 is the frequency output by the voltage-controlled oscillator 43 with the Frequency of the data signals coming from the decoder 25 compared, and there is an error signal that Via the low-pass filter 41 and the summing amplifier 42 to the control terminal of the oscillator 43 arrives so that the latter records the sequence of data pulses from the decoder 25.

Since the speed for retrieving the data from the magnetic tape 10a is also a function is the speed of the magnetic tape, a component of the tape speed becomes that of the phase comparator 40 obtained error voltage added in such a way that the phase comparator 35 output signal through the low-pass filters 34 and 44 of the second input terminal of the summing amplifier 42 is supplied. The output terminal of the latter is in turn connected to the Sieuerklemrne of the voltage controlled oscillator 43; in this way the frequency of this oscillator 43 will be of both its own phase comparator 40 as well as from the comparator 35 associated with the tachometer 15 influenced. The error voltage of the phase comparator 35 is developed at a point in time before the Output terminal 45 of the detector 37 is energized for the speed threshold value; if the Output terminal 45 is activated in order to switch on the phase-fixed oscillator 27, is therefore the voltage controlled oscillator 43 provides an instantaneous error voltage which it quickly adjusts to the Synchronized frequency of the data bits that come from the decoder 25 via the line 25a. In addition, the error voltage output by the phase comparator 35 is brought up from the phase-fixed oscillator 28 to the summing amplifier 42, that to the phase-fixed oscillator 27 heard that the latter is given a speed component so that he better the Changes in speed of the magnetic tape 10a can follow.

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Circuit for controlling the flow of digital data on and from a magnetic tape transmission taking place during startup at a given fraction of the full drive speed begins and during the stopping process up to this fraction continues, with a tachometer coupled to the drive roller of the magnetic tape, of which a number of pulses each proportional to the respective drive speed of the drive roller Time unit can be fed to one input of a comparator of a first phase-locked loop, in the voltage controlled oscillator generating the output of a write clock pulse with the the other input of the comparator is connected, the output of which passes through a low-pass filter at the control input of the voltage-controlled oscillator is connected, characterized in that in a second phase-locked loop (27) the Output of an oscillator (43) generating read clock pulses with one input of a comparator (40) is connected, the other input of which is connected to the reading circuit (25), and its Output via a low-pass filter (41) and a summing amplifier (42) at the control input the voltage-controlled oscillator (43) is connected to the second phase-locked loop (27), that the summing amplifier (42) as a second input signal from the comparator (35) via the Filters (34) to the first phase-locked loop (28) running signals can be fed, and that at Reaching the specified fraction of the full drive speed during start-up from a detector (37) receiving the pulses from the tachometer (15) first the comparator (35), the filter (34) and the voltage-controlled oscillator (32) of the first phase-locked loop (28) and then the comparator (40), the filter (41) and the voltage controlled oscillator (43) of the second phase-fixed loop (27) can be switched on. 2. Circuit according to claim 1, characterized characterized in that the detector (37) has two monoflops (47; 48) each in series with one Logic element (49; 51) and the set input terminal of a flip-flop (53; 54) that the Pulses from the tachometer (15) to both the monoflops (47; 48) and the two link elements (49, 51) can be fed, which let them pass through to the flip-flops (53, 54) as soon as the The tipping time of the respective monoflop (47, 48) is longer than the time interval between two pulses. and that the tipping times of the two monoflops (47, 48) are selected to be different. The invention relates to a circuit for controlling the digital data flow in the one and from one Magnetic tape transfer that takes place during startup at a given fraction of the time full drive speed begins and continues during the stopping process up to this fraction. with a tachometer coupled to the drive roller of the magnetic tape, of which one of the respective Drive speeds of the drive roller proportional number of pulses per unit of time to the one Input of a comparator of a first phase-locked loop can be fed, in which the output of a Voltage-controlled oscillator that generates write clock pulses with the other input of the comparator is connected, the output of which via a low-pass filter at the control input of the voltage-controlled oscillator connected. When recording or reading the digits, which are normally available as Bks, the tape can be set in motion and stopped again several times per second. During the start, writing or reading is suppressed until the tape has reached a certain speed. The same applies to a shutdown during the period in which the belt is slowing down. As a result of the suppression of the writing process when starting and stopping, an empty space is created between the data blocks recorded on the tape, which is also known as the "gap between the blocks" and has so far normally been 0.6 inches (approx. 16 mm) wide. Recently, a gap of 0.3 inches (about 8 mm) has been adopted. If the read / write head is in the middle of the gap when the tape is stopped, this small gap width means that only 0.15 inch (3.8 mm) is available to accelerate the tape until there is space for the next one DatenbJockes shows up. Accordingly, tape speeds of 300 in / sec (7.6 m / sec) are used, which ^{must be assigned an acceleration of 300,000 in / sec 2} (7.6 km / sec ² ) during start-up; when stopping, the delay is of the same order of magnitude. This in turn links motors for winding and unwinding the tape and drive circuits, which have an extremely high power consumption. In fact, the power consumption increases or decreases non-linearly with the acceleration or deceleration, which are dependent on the gap width and belt speed of the arrangement. Another requirement imposed on a tape recorder, which is related to the structure of the reading circuit, is that the data bits with a constant density of e.g. 6000 bits / inch (2360 bits / cm) must be recorded. However, if the tape system is designed to allow data transfer over a wide area of the Belt speeds can take place, are lower accelerations when starting and stopping or delays possible. The ability of an arrangement to transfer bits of data at reduced speeds to record and read, can thus help to reduce the mechanical stresses and the power consumption for the coil drive and the associated circuits can be reduced. From the German Offenlegungsschrift 20 27 799 is a device for recording and / or reading or known from a magnetic tape, from which any deviations from the regularity of the belt run-off are compensated. It contains a pulse generator, the pulse-shaped signals with an instantaneous frequency that corresponds to the actual running speed of the magnetic tape before Read / write head is proportional. This device also has a control oscillator which is pulse-shaped Outputs signals at a fixed reference frequency that is the mean frequency of the first pulse generator delivered signals, i.e. corresponds or proportionally to an average running speed of the magnetic tape is. The two pulse trains enter a phase dis-