DE1774795C3 - - Google Patents

Description

The invention relates to an arrangement for transmission of data stored phase-coded in a memory of a data processing system corresponding data signals from a reading device which reads the data from the memory and data pulses and emits phase pulses between at least some data pulses, to an evaluation device, wherein a control circuit fade-out pulses blocking the transmission of the phase pulses outputs whose pulse duration is less than the time interval between two successive data pulses is.

From British patent specification 1 010 f> 39, as Control circuit known as a delay hip-flop, that in one of its states the transmission of the the reading device emitted signals emits blocking masking pulses. The duration of each blanking pulse is less than the time interval between two successive data pulses and to three quarters this time interval is fixed.

L m when the time interval between successive data pulses is reduced to less than ah the pre-set duration of the blanking impulses to enable transmission of the data impulses, each blanking pulse can be terminated by a phase pulse that has occurred, so that ir > in okhen cases the fade-out pulse board is smaller than all the '.irestelite value is.

Pie known arrangement leaves a phase pulse je .: vh then happen when he is later than Dreivierii do normal time intervals one after the other the data pulse occurs. This case can be easy occur when the speed of the an de 1cn. MMDecrease in the direction of the accumulator moving past ^ Lid the data pulses are therefore temporally wide move apart.

ir. Recognition of these inadequacies iiegi d <l'.rtiiK-iina a] c task! «'Grund. dieeincangs cen; <niv

The arrangement should be designed so that even with larger data pulse intervals, the distance between the data pulses occurring phase pulses are reliably masked out.

This task is thereby accomplished according to the invention solved that the control circuit has a monostabibn multivibrator from the Datenimmilsen is triggered in its quasi-stable state, for the duration of its quasi-stable state the signaling impulse emits and in which the duration of its quasi-stable state depends on the amplitude of a on a control terminal of the multivibrator given DC voltage control signal depends, and that the The control circuit also has a control voltage generator connected to the multivibrator output It shows the voltage control signal generated such an amplitude that the temporal ratio of the duration of the quasi-stable state to the The period of the vlultivibrator determined by the data pulses remains constant, the duration of the quasi-stable state longer than the time interval of a third pulse to the following phase pulse. After the invention, the duration becomes of the blanking pulse continuously to a target value regulated by giving the control signal a constant ratio the duration of the unstable state of the multiwbrator to the period of the multivibrator determined by the triggering and therefore subject to fluctuations maintains. In the arrangement of the present invention, each is between data pulses , air-occurring phase impulse is reliably masked out, regardless of the fluctuations time interval of successive data pulses is subject.

Advantageous further developments of the concept of the invention are the subject of the subclaims.

The invention is illustrated below using an exemplary embodiment explained with reference to the drawings. It shows

F i g. 1 shows the block diagram of an inventive Arrangement,

F i g. 2 and 3 the electrical circuit diagram of the monovibrator and the control voltage generator.

F i g. 4 waveforms at different points in the circuits of Figures 1, 2 and 3,

1- i g. 5 is a graph of the changes in the temporal occurrence of the data pulses and phase pulses, the fluctuating tape transport speed and impulse accumulation are to be attributed.

In Fig. 1 are the points at which the in F i g. 4 shown pulse shapes occur, denoted by capital letters. According to FIG. 1, a magnetic tape 1 is guided past a reading head 2 by means not shown. The orientation of the magnetic flux shows the curve shape Λ of FIG. 1 for four bit lines on the surface of the band 1. 4. The data with the binary values "1100" are recorded on tape 1 in the form of "non-return-to-zero pulses" in a phase-coded manner. The boundaries of the bit cells are indicated by dashed lines 4, 5, 6, 7 and 8. The binary value "1" is stored as a negative-positive transition of the flow orientation in the middle of a bit cell and the binary value "0" is stored as a positive-negative transition of the flow orientation in the middle of a bit cell. The reading head 2, which responds to the flux reversals on the surface of the tape 1, is connected to the reading circuit 3. It is known that the reading head 2 generates an approximately sinusoidal signal, since each time the binary value recorded on the tape 1 changes, a phase shift occurs. In one channel, the reading circuit 3 generates unipolar pulses (Kuninform β, FIG. 4) which correspond to the positive peaks of the reading head signal. In the other channel, the reading circuit generates 3 unipolar2 pulses (waveform B ' in FIG. 4) which correspond to the negative peaks of the

ίο correspond to the read head signal.

The pulse trains B and B ' of FIG. 4 show that some of the output pulses, here called data pulses, directly indicate the binary value which was recorded in the associated bit cells on the magnetic tape 1 through the channel in which they occur; other pulses, here called phase pulses, result from the special nature of the phase coding technology and do not directly indicate the binary value that was recorded in the bit cell. Thus, pulses 11, 12, 13 and 14 are data pulses, and pulses 15 and 16 are phase pulses. The Dalen impulses occur at regular intervals, a data impulse appears in exactly one bit cell, and in each column there is exactly one data impulse. The phase pulse. ' on the other hand occur irregularly. If the sinusoidal signal output by the reading head 2 experiences a phase shift, no phase pulse is generated. As a result of the accumulation of pulses, the interval between a data pulse and the immediately following phase pulse and the interval between successive data pulses are sometimes subject to change. The more slowly occurring changes in the tape transport speed wedge do not have any great influence on the change in the interval / wiper of a data pulse and the immediately following phase pulse or on the interval between successive data pulses. Over a longer period of time, however, the changes in the tape transport speed cause a significant time shift in the occurrence of the data and phase pulses. Among other things, the changes in the tape transport speed occur more slowly than the changes due to the accumulation of pulses, they can also be compensated more easily.

The change in the temporal occurrence of the data and phase pulses is shown in FIG. 5 shown; on the Abs / issenachse is the time span of a bit cell at different tape transport speeds, and the point in time is on the ordinate axis the occurrence of the data and phase pulses in a bit cell. One recognizes that of the impulse accumulation attributable inaccuracy in the timing of the phase and data pulses different tape transport speeds to be expected in a given arrangement. The data pulses appear within the boundary 28 and the phase pulses appear within the boundary 29. There is a clear dividing line between the two areas, so that in each case can separate between data pulses and phase pulses. If z. B. the belt speed is so high, that the time span corresponding to a bit cell is 17 microseconds, the phase pulses occur 8 to 10.4 microseconds after the end of the previous data pulse, and the data pulses appear 13.75 to 19.75 microseconds after the previous data pulse has hit.

According to FIG. 1 the impulses from channel B accumulate are basically already at the

through an AND gate 27 to an OR gate 9,. ,. ,,, .. ...... M ..., ·., ·.

. _{,,,,,.,, D,,} u · ·. appropriate selection of the ratio ■ _ ■ taken into account,

where it is combined with the pulses from channel B ^e ρ ^b

The AND gate 27 is open as long as so that each data triggered by a data pulse can be read from the tape 1. The grain 5 erase pulse with certainty within the time interval binary pulses (curve C in Fig. 4) serve as between the following phase pulse and the post-trigger pulse for the monovibrator 10. Each data-following data pulse ends. As a result, the safety pulse switches the monovibrator 10 from its set so that in any case the stable state in its quasi-stable state extends behind the phase pulses for a sufficient length of time, a period of time which is on the one hand shorter than the inter-10 without the subsequent data pulse to overlap, vall between successive data pulses In the illustration of FIG. 5 Is the described and, on the other hand, longer than the interval between the control of the monovibrator 10, the erasing pulses, a data pulse and the following phase pulse. always at a point between the boundaries 28. The output of the monovibrator 10 is shown in curves D and 29, which correspond to the data pulses and phase pulses in FIG. 4 shown. In its qm.si-stable state 15, the monovibrator generates impulses at its output for all values of the belt transport speed. Line 22 shows the point in time whose duration is denoted by M in curve D. Termination of the erase pulses. The working period of the monovibrator 10, at the beginning of each data block on the magnet, which is equal to the interval between successive bands 1, before the data is a particular series of binary data pulses, is indicated by P in curve D. 20 values recorded in order to synchronize the functioning of the mono-The pulses generated by the monovibrator 10 in its quasi-stable vibrator 10 with the occurrence of the data pulses state serve as erasing pulses, initially to synchronize. This special series, which the phase pulses in the signal generated by the reading circuit 3, referred to by those skilled in the art as the preface, must mask out. For this purpose, the output must be long enough to produce the rest in the control circuit comprising the monovibrator 10 with an input of an AND 25 monovibrator 10 and the control voltage generator element 23 and an input of an AND element 24 21. Linked to the foreword. The from the reading circuit 3 in one consists of a fixed number of binary zeros. Channel generated pulses are on the other So all data pulses appear on the input of the AND gate 23 and those of the read channel B ', and all phase pulses appear on the circuit 3 on the other channel generated pulses 30 channel B. When on The beginning of each block with which the other input of the AND element 24 begins reading the foreword is given. It can be seen from curves B, B ' and D that flip-flop 26 is in such a state that the AND-erase pulses from one end of each data element 27 are closed. Therefore, only data pulses appear up to a point in time beyond the immediate pulse at the output of the OR gate 9. After the phase pulse that follows, extend. This prevents the transmission of the specified number of data pulses required for the transmission of the phase pulses through the gates 23 and 24, setting the idle state in the control circuit. As a result, the data is sufficient and is registered by a counter 25, pulses through the gates 23 and 24 into other parts 19, the counter 25 generates a pulse which switches the flip-flop 26 of the data processing system without the phase pulses. The AND gate 27 is thereby transmitted open (curves O "and H, Fig. 4). This data 40 and transmits pulses from the channel B; it remains open for a long time through the channel in which they occur. until the data block has been read completely from binary values, ie the ones recorded on tape 1. Then, after a mark on the binary information, tape 1, the flip-flop 26 and the counter 25 as pre-The duration of the erase pulses and the period of preparation for the next data block back-monovibrator 10 depend on changes in the 45 switched.

Tape transport speed down to get the correct F i g. 2 shows the circuit of the monovibrator 10. Phase relationship with the read signal to be maintained- The transistors 30 and 31, their emitters to earth keep. The period of the monovibrator 10 will be there, serve as switching elements of the monovibrator 10. set by that he is through the trailing edge of the collectors of transistors 30 and 31 are with Data pulses is triggered. The width of the erasure 50 of a positive voltage source 32 over the load pulses is set by a control circuit. To this end, resistors 33 and 34 are connected. A resistor 35 the output of the monovibrator 10 is on a represents the cross connection from the collector of the Control voltage generator 21 given, the one to transistor 31 to the base of transistor 30, the ratio of the duration of the quasi-stable state during a capacitor 36 and one with it in

. ". ,, j", ■ .. M .55 series connected diode 37 a cross connection of

to the penode _{duration of the Monovbrator p} proport. o the ^ "^ ^ _Transislors ^ _{to the Bas} J _des

nale DC control voltage generated. Those from the gene transistor 31 represent. The collector of the tran-

Rator 21 generated control DC voltage is buffered, sistor 30 is at a predetermined, adjustable

so that the mean voltage aui the monovibrator 10 voltage is determined by an arrangement that has a

to control the duration of its quasi-stable supply 60 transistor 38 with a grounded collector umabt. the

Status is given. When the tape transport resistor 39 between the voltage source 32 and

speed changes, the quasi-stable depends on the base of the transistor 38 and the eintlloare

State of monovibrator 10 continuously thereafter resistor 40 between the base of transistor jrs 38

■ j "j., ._ ,. . M. . . ui -u. n · and earth together represent a voltage divider.

off so that the ratio “remains constant. The . ~, _. . , "·. j- ·. j

• P 65 The emitter of transistor 38 is directly connected to the

The collector of transistor 30 is connected to undesired consequences of the accumulation of pulses. The Grouc

largely exhausted, so that the circle on it of the predetermined clamping potential at the collector

does not respond. The adverse consequences of the pulse of the transistor 30, which the duration of the quasi-stanilcr

Is influenced by the setting of the variable resistor 40 is determined.

The trigger pulses occurring at point C are transmitted to the base of transistor 3 via a conventional diode 45 and a storage diode 46! given. A resistor 47 is located between the junction of the diodes 45 and 46 and the voltage source 32. The output stage of the mono-vibration is formed by a transistor 48 with a grounded emitter. The collector of transistor 31 is connected to the base of transistor 48 via a resistor 49. A resistor 50 is located between the collector of the transistor 48 and the voltage source 32. Furthermore, a diode 51 is connected between the collector of the transistor 48 and the junction point of the diodes 46 and the resistor 47. The output voltage of the monovibrator is available at the load resistor 52, which is between the point D (collector of the transistor 48) and ground. The period of time during which the monovibrator remains in its quasi-stable state after the trigger pulse at point C is controlled by the voltage appearing at point F , from which a line leads via a resistor 53 to the connection point between capacitor 36 and diode 37.

When the monovibrator is in its steady state, transistor 31 is saturated. As a result, its collector is essentially at ground potential, and the transistor 30 is blocked because of the cross-connection via the resistor 35. Since the transistor 48 is also blocked in the output stage. there is a high positive potential at point D. The capacitor 36 is charged in the stable state, so that a voltage gradient between the collector of the transistor 30 and the base of the transistor 31 is present. After the trigger pulse appears at point Γ, the quasi-stable state is initiated. Transistor 31 is blocked and its collector voltage increases. As a result, the base voltage of transistor 30 rises and saturates it. As a result, the voltage at the collector of transistor 30 drops essentially to ground potential. Lir. A corresponding voltage gradient is transmitted through the capacitor 36, so that a negative potential appears at the base of the transistor 31 and blocks it. When transistor 31 is blocked, transistor 48 becomes saturated and the voltage at point D drops essentially to ground potential. The diode 46 possesses sufficient capacity to maintain the effect of the Tnggerimpulses until the described transition of the monovibrator into its quasi-stable state has taken place. When the quasi-stable state has been established, the capacitor 36 is charged via the resistor 53 against the voltage at the point F until the potential at the base of the transistor 31 becomes positive again. At this point the monovibrator returns to its stable state. Transistor 31 is saturated and transistor 30 is blocked. The time it takes for capacitor 36 to charge up to the point where the base of transistor 31 becomes positive depends on the magnitude of the positive voltage against which the capacitor charges. The greater this positive voltage, the shorter the period of time which elapses before the base of the transistor 31 becomes positive, which corresponds to the duration of the quasi-stable state

In Fig. 3 shows the circuit of the control voltage generator 21. It is essential that the voltage that controls the duration of the quasi-unstable state of the monovibrator 10 is generated by charging a regulating capacitor 60 at constant speed during the quasi-stable state of the monovibrator 10 and by discharging the capacitor 60 at a constant speed during the stable state of the monovibrator 10. The voltage across the capacitor 60 is with the curve E in FIG. 4 shown. An essentially

ίο constant charging current is supplied to the capacitor 60 from the collector of the transistor 61. The emitter of the transistor 61 is connected to a positive voltage source 62 via a resistor 63. Resistor 64 is connected between source 62 and the base of transistor 61 and resistor 65 is connected between the base of transistor 61 and ground. The collector of a transistor 66 is also connected to the capacitor 60. Resistor 67 and diode 68 are in series between the emitter of transistor 66 and ground. A resistor 69 is located between the junction of resistor 67 and diode 68 and voltage source 62. Output D of monovibrator 10 is connected to the base of transistor 66 via a diode 70. A fixed resistor 71 and a variable resistor 72 form a voltage divider between the voltage source 62 and ground. The connection point between the resistors 71 and 72 is at the base of the transistor 66. During the quasi-stable state, point D is essentially at ground potential and the transistor 66 is blocked. Therefore, the constant charging current from the collector of transistor 61 causes the voltage across capacitor 60 to rise linearly. When the monovibrator 10 assumes its stable state, the potential at point D rises and the transistor 66 conducts. A path of constant discharge current is then established from the capacitor 60 via the transistor 66 to ground, as a result of which the voltage across the capacitor 60 drops linearly. The size of the constant discharge current depends on the adjustable variable resistor 72.

An output capacitor 73 with a substantially larger capacitance than the capacitor 60 ″ lies between the point F and ground. The capacitor 60 is connected to the capacitor 73 through the npn transistors 74 and 75, so that the voltage across the capacitor 73 exceeds the average voltage represents the capacitor 60. Curve F in Fig. 4 shows the voltage across the capacitor 73. The base of the transistor 74 is directly connected to the capacitor 60, and its collector is connected to the voltage source 62 through a resistor 76 emitter of the transistor 74 and the base of the transistor 75 and between the collector of the transistor 75 and the voltage source 62 is a direct connection in each case. a resistor T) is located between the emitter of transistor 74 and ground. When the voltage across the capacitor 6i increases, a charging current flows through transistors 74 and 75 to capacitor 73, so that the voltage across it follows this rise. Emitter and Basil one The pnp transistors 78 are connected directly to the middle or the base of the transistor 75. De collector of transistor 78 is via a counter-stand 79 to earth. When the voltage across resistor 60 decreases, transistor 78 is rendered conductive so that it provides a discharge path for the condenser

Sator 73 emits to earth. With the arrangement of the transistors 74, 75 and 78 it is achieved that the Voltage across the capacitor 73 increases as well as the decrease in the voltage across the capacitor 60 follows and thus represents their mean value. Monovibrator 10 and voltage regulator 21 work

M together as a control circuit, which has the ratio - = -

(Keeps the duration of the quasi-stable state constant for the period of the monovibrator 10. If the tape transport speed changes, the period P of the monovibrator 10 also changes, and the ratio deviates a little from the value determined by the setting of the resistor 72 In this case, the length of time during which capacitor 60 discharges changes, resulting in a change in the mean voltage across capacitor 60. This is reflected by the voltage at point F. In general, the voltage remains at the point F unaffected by pulse accumulations, since these effects are averaged out. The voltage change at point F adjusts the duration M of the quasi-stable state of the monovibrator 10 again in such a way that the deviation from the predetermined ratio is reduced. the period of the monovibrator 10 decreases, so that the capacitor 60 in a shorter time interval during each r period discharges. In this way the mean voltage increases

ίο on the capacitor 60, which is transferred to the voltage at point F. A rise in voltage at point F, however, causes capacitor 36 to discharge more rapidly to the point where transistor 31 becomes conductive. The duration of the quasi-stable state of the monovibrator 10 thus decreases. The sequence shown continues until the predetermined ratio has been set again; then the control circuit is again in equilibrium and the voltage at point F remains constant until the belt

ao transport speed changes again.

1 sheet of drawings

Claims (9)

I 774 claims: 1. Arrangement for the transmission of in one Memory of a data processing system, data signals stored in a phase-coded manner, corresponding to data signals from a reading device which reads the data from the memory and data pulses as well as emits phase pulses between at least some data pulses. to an evaluation device, a control circuit emitting masking pulses that block the transmission of the phase pulses, whose pulse duration is less than the time interval between two successive data pulses is. characterized in that the control circuit is a monostable multivibrator (10), which xon the data pulses is triggered in its quasi-stable state, for the duration of its quasi-stable state the Ausblküui. '. Ipu!'. outputs and H ^ i dem the duration of its ao quasi-stable state depends on the amplitude of a DC voltage control signal given to a control terminal of the multivibrator ^, and that the control circuit also has a control voltage generator (21) connected to the multivibrator output, which has the Same spmmmgs Rcgel ^ gnal with such amplitude cizeugi. that the lateral ratio of the duration dc> quasi-stable state to the penode of the multivibrator determined by the data pulses remains constant. v \,> ie the duration of the quasi-stable state is longer than the time interval between a data pulse and the following phase pulse IM 2. Arrangement according to claim 1, characterized in that that in the control voltage generator a control capacitor (60) during a Mulliv ibrator state via a charging circuit (61) rechargeable and during the other multivibratory state via a discharge switch +0 ment (66..) is discharged and that the amplitude of the DC voltage signal proportional to the mean voltage across the regulating capacitor. -V arrangement according to claim 2, characterized in that that the control condenser of a cons; iMistromquelle (61) charged and over discharging a current path with constant current. 4. Arrangement according to claim 2 or 3 thereby .ce ·· nnmarked. that the size of the charging current euv- ellable im \ Arrangement according to one of Claims 2 to 4, characterized in that the charging process (61...) Constantly, the charging circuit (66.. 1 only during one of the two states of the multivibrator (10) is connected to the regulating capacitor (60). ti. Arrangement according to claim 5, characterized in that da;?, the l-nilddescluiltiing only during the stable state of the multivibrator; 10) t> o is connected to the regulating capacitor! .Wl). 7. Arrangement according to one of claims 2 to t>, characterized in that the regulating capacitor is connected to an output capacitor ("? ■ ') at glosses, the capacitance of which is substantially p ^r öoe; than the fts capacitance of the regulating capacitor ibO) , and that Between control capacitor up. ' Atisgangskondensatorin control element (74 ...) .. ί ^! Ui; v, ν, lchc controls the charging and discharging of the output capacitor according to the voltage on the control capacitor, and that the DC voltage control signal is represented by the voltage on the output capacitor. 8. Arrangement according to claim 7, characterized in that .. indicates that the control element (74 ...) has a first and second transistor (74,75) with the same Polarity in tandem and a third transistor (78) of opposite polarity has, the base of which with the base and the emitter with the emitter of the second transistor (75) is directly connected and its collector is at a low reference potential, so that the Charging of the output capacitor (73) via the first and second transistors (74,75) and its discharge takes place via the third transistor (78). 9. Arrangement according to claims, characterized in that that the first and second transistor (74, 75) of the npn type and the third transistor (78) is of the pnn type.