DE2414315C3 - Vinyl record recording arrangement - Google Patents

Description

The invention relates to a phonograph record recording arrangement with a cutting and recording device, the cutting head of which when recording of signals on a rotating record from the outer edge of the record towards the inner edge of the record running.

At a constant record speed, the relative linear speed changes between one spinning record and one scanning the recorded signals from the record Pickup, if the pickup is playing from the outer edge of the record towards the inner edge of the record or the center of the plate runs. This is due to the changing radius between the center of the record and the cartridge due to playback. The relationships are such that the tracking conditions of the pickup with respect to the record from the outer edge towards the inner edge.

This is especially true if the recorded signals are a piece of music, that ends with a rich sound at high volume, for example a symphony whose finale is fortissimo ends. In these noisy places, the groove distortion increases as the groove radius decreases on. This severely adversely affects the reproduction quality.

If it was a question of a multi-channel record with several separate or discrete sound channels it is common to use an angle-modulated signal in the multiplexed state together with a direct one Record the signal on the record. With such an arrangement the distortion increases also when the cartridge approaches the inner part of the record. In addition, there is here the risk that higher harmonics of the direct signal get into the angle-modulated signal band and there is cross-modulation or over-modulation. This creates abnormal noises.

In order to overcome these difficulties, attempts have been made to determine the entire level of the recording signal reduce or use limiting amplifiers, which carry out an automatic gain control with respect to the recording signal. In

In this context, the amplifier has been set in such a way that the gain control in one exercised to a high degree.

However, these usual measures are all disadvantageous, because they lead to a loss of sonority in the entire program sequence and already during the The dynamic range of the recording is limited because it is independent of the Grooves adius reduce the level of the recording signal and, under certain circumstances, the maximum level below press a relatively low-lying special level.

In order to overcome this problem, according to the invention, the level of the signal to be recorded increasingly limited when the cutting head moves from the outer edge of the plate in the direction of the signal recording runs onto the inner edge of the plate.

The sound recorder recording arrangement described at the beginning is characterized according to the invention that a device during the time in which the cutting head runs from the outer edge of the record towards the inner edge of the record. Signals generated, which indicate the respective position of the cutting head on the record that a device this Receives position signals and generates a control voltage in accordance with the position signals has successively changing voltage values that a limiter device limits the amplitude of the signals supplied to it to be recorded on the record that a control device acting on the limiting amplifier device for limiting the amplitude of the signals to be recorded, the gain of the limiting amplifier means in accordance controls with the control voltage, the voltage values of which are such that the degree of amplitude limitation of the signals to be recorded increases successively when the cutting head on the record from The outer edge of the plate runs in the direction of the inner edge of the plate, and that a device receives the output signals of the Limitation amplifier device supplies the cutting head.

According to the invention, use is thus made of a limiting amplifier which is an automatic Carries out gain control in such a way that the maximum level of the Signals progressively decreases as the cutting head moves away from the disk's outer edge towards the The middle of the plate runs.

The input level at which the amplitude limitation of the input signal begins is preferably kept constant. Depending on the movement of the cutting head from the outer edge of the plate in Reduction of the maximum level of the signals to be recorded towards the center of the disk can be done continuously or in stages.

Preferred exemplary embodiments of the invention are described with reference to drawings. It shows

Fig. 1 is a block diagram of a first embodiment a phonograph record recording assembly,

Fig; 2 (A) to 2 (M) time courses of signals different points of the shown in FIG Embodiment,

F i g. 3 shows an input level-output level characteristic curve of a device in the exemplary embodiment according to FIG. 1 used limiting amplifier,

4 shows a block diagram of a second exemplary embodiment a phonograph recorder

F i g. 5 shows an input-level offset line one in the embodiment according to the Γ i g. 4 used limiting amplifiers,

Fig.6 shows a special circuit for one in the Embodiments according to FIGS. 1 and 4 usable staircase curve generator,

FIGS. 7 (A) and 7 (B) show the timing of signals at various points in the FIG. 6 shown Circuit and

8 shows a special circuit of a further embodiment of a staircase curve generator.

1, 2 and 3 is a first embodiment a Schail disk recording assembly is shown.

A cutting device 10 receives via input connections 11 a recording signal which has been subjected to special signal processing, including an amplitude limitation to be described below, and records this signal on a record 12 by cutting. While the cutting head of the cutting device 10 runs from the outside to the inside when cutting the record 12, a detector 13 determines the position of the cutting head successively at special line intervals in the period of time during which the cutting head moves from the outer edge / around the inner edge of the record. Er2 on the basis of this finding; EUGT a circuit 14 sequentially pulse voltages a to e, the g in the F i. 2 (A) through 2 (E) are shown. The dash-dotted lines P and Q represent the entry point and the exit point.

The pulse voltages a to e generated in this way by the circuit 14 are supplied to a gate circuit 15 which, based on the supplied pulse voltages, emits successive pulse voltages g with a pulse width Ti , as shown in FIG. 2 (G). These pulse voltages g are fed to a monostable multivibrator 16 in which they are converted into pulse voltages h with a pulse width T2 which is slightly wider than the pulse width T1. The pulse voltages h are shown in Fig. 2 (H). The pulse voltages h then pass to a differentiating circuit 17 which uses them to produce differentiated pulses /, as shown in FIG. 2 (1) is shown. The differentiated pulses / are fed to a stepped curve generator 18. Before the run-in time Per, the circuit 14 generates a reset pulse f, shown in FIG. 2 (F), which reaches a monostable multivibrator 19. The reset pulse is wave-shaped therein and fed to a circuit 20. The output signal of the circuit 20 is also fed to the aforementioned staircase generator 18 and there causes the discharge of a staircase voltage that was built up during the previous period. In this way, the staircase waveform generator 18 is reset prior to the start of the application of the differentiated pulses /.

The stepped curve generator 18 reset in this way stores the successively supplied differentiated pulses / and therefore emits a stepped curve oscillation j , the voltage value of which increases step by step, as shown in FIG. 2 (J) is shown. The step curve oscillation j is fed to an integration circuit 21, in which it is converted into an integrated oscillation Ar or /, the crotch edge being given a smooth curve, as shown in FIG. 2 (K) or 2 (L). In Fig. 2 (K)

and 2 (L) the vibrations k and / are identical. The only difference between these figures is that, in the case of Fig. 2 (L), a charging voltage is present before the reset by the reset pulse f. The voltage of the oscillation k or / is fed as a control voltage to a direct current amplifier and control circuit 22, which is located in the feedback branch of a limiting amplifier.

A sound signal originating from a microphone or a tape recorder is amplified by an amplifier and supplied to an input terminal 23. This signal m occurring at the input terminal 23 is shown in FIG. 2 (M). In this illustration the audio signal is only shown in an idealized manner for only one period, although this signal is continuous and has variously varying amplitudes. The audio signal is supplied by a resistor and a field effect transistor

25 voltage-divided, the field effect transistor 25 operating as a variable resistance element. The voltage-divided signal then reaches a main amplifier 26, in which it is amplified.

The amplified output signal from the main amplifier

26 passes through a control signal amplifier 28 and after it is rectified by a rectifier 29 has been converted by an integration circuit 30 into a control voltage. The one at the exit of the Integration circuit 30 occurring control voltage is the aforementioned DC amplifier and Control circuit 22 supplied.

On the basis of this control voltage, the DC amplifier and control circuit 22 controls the Control voltage of the integration circuit 21. The control voltage occurring at the output of the circuit 22 is pressed on the gate of the field effect transistor 25 and changes the internal resistance of the Field effect transistor between the sink and the source. The gain of the amplifier becomes thus controlled by changes in the resistance of the field effect transistor 25.

Thus, when the writing head of the cutter 10 continues to cut from the outer edge to the inner edge of the record 12, the limiting level of a limiting amplifier, which contains the amplifier 26 and the associated feedback branch, is successively reduced in an order n, o, p,. .. see as it is shown in the input level-output level characteristic curve shown in FIG. The consequence of this is that the limiting amplifier performs an amplitude limiting by successively deepening (ie increasing) the degree of amplitude limiting, as is the case at points n, o, p. ... s is shown in FIG. 2 (M) in relation to an input signal shown at the point m. Since in the FIG. 2 (L) shown initial period / 'no control voltage is present but only a constant fixed bias voltage is fed to the gate of the field effect transistor 25, the gain of the limiting amplifier has a maximum value in this period /' so that an output signal π is obtained on the basis of the input signal m as shown in FIG. 2 (M) is shown the period during which the signal s occurs is fixed in practice so that it occurs slightly prior to discharge time Q

The output signal of the amplifier 26, limited in amplitude in the manner described above, is fed to an output terminal 27 ) and a sum and difference signal for two channels are formed from them. The sum signal is fed to a special equalization circuit, while the difference signal is angle-modulated after passing through a special equalization circuit. The resulting direct sum signal and the angle-modulated difference signal are multiplexed, amplified, to the input terminal 11 of the cutting head; of the cutting device 10 and recorded on the record 12 by cutting.

The input signal applied to the input terminal 23 may be an audio signal which is the entire Frequency band covered. In this case, you only need to provide an arrangement as Block diagram in FIG. 1 is shown. In one arrangement, the multiple systems, for example three systems as shown in FIG. 1, for a single recording arrangement are provided, and the recording signal into a low band signal, a medium band signal and a high band signal is divided with the aid of a low-pass filter, a band-pass filter, and a high-pass filter the split signals are fed to correspondingly assigned limiting amplifiers in the three systems. In this case, depending on the program source of the signal to be recorded, the Arbitrarily choose the degree of amplitude limitation for each of the bands. For example, you can use the Make the magnitude of the amplitude limitation larger for the low-band signal than for the other band signals. Although in the described embodiment, the staircase curve generator 18 due to the Pulse voltages a to e of the circuit 14 and, in connection with the detector 13, a step-wave voltage which has five stages, the number of stages is not limited to five, but can be arbitrary. In addition, the voltage increase can also be carried out continuously or steadily.

In Figures 4 and 5 is a second embodiment a phonograph record recording arrangement. In FIG. 4 are parts that are matched with parts according to the F i g. 1 are identical or similar are provided with the same reference numerals. For a detailed description these parts are omitted.

As can be seen from Figure 3, change in the first embodiment when changing the

Limiting level in the order n, op ... s the

critical points at which the limitation starts,

d. H. the input level points that are used when displaying

according to FIG. 3 correspond to the bend points of the curve,

in terms of input level from a large to

a small value, according to the

Change the clipping level from a large one

to a small value In the embodiment according to the F i g. 4 and 5 remain these critical points regarding the input level despite changing

Output level or limiting level constant

The signal component of the output signal of the main amplifier 26, the control signal amplifier 28. the Rectifier 29 and the integration circuit 30 is passed by a DC amplifier 40 amplified and then fed to the gate of the field effect transistor 25, with the effect that thereby the The gain of the main amplifier 26 is controlled

will. The output signal of the amplifier 26 occurs the output terminal 27 after it has been determined according to the resistance value of a resistor 41 and the resistance of a field effect transistor 42 has been voltage divided.

The staircase-shaped control voltage k from the integration circuit 21 is applied to the gate of the field effect transistor 42 and changes its internal resistance in a corresponding manner. The drain and the source of the field effect transistor 42 are connected between the output terminal 27 and ground (earth).

Since in this Ausl'ührungsbeispiel the field effect transistor 42 is provided on the output side of the amplifier 26 and the internal resistance of this field effect transistor is controlled by the control voltage k , you get a characteristic between the input signal level at the input terminal 23 and the output signal level at the output terminal 27 as shown in FIG F i g. 5. This shows that the critical limit points, ie the input level points corresponding to the break points, remain constant regardless of the limit level. This is due to the fact that, in accordance with the control voltage A-, all input level-output level characteristic curves change according to the level limitation in the order n, op .

In the following, particular embodiments of the stair curve caerator 18 are described, which is shown in FIG the explained exemplary embodiments is used.

In the case of one shown in FIG. 3, a pulse voltage and that of the pulse voltage / according to FIG. 2 (1), with a period T3 and a pulse width Γ4 as shown in FIG. The DC voltage component is removed from this pulse voltage υ with the aid of a coupling capacitor 51 and a capacitor 53 is then charged via a silicon diode 52. The charging takes place momentarily at this time, since the time constant, which results from the forward resistance of the diode 52 and the capacitance of the capacitor 53, has a suitably small value.

At a time when the pulse voltage is absent. the charge of the capacitor 53 is discharged through a resistor 54 to charge a capacitor 55. The time constant caused by the capacitor 55 and the resistor 54 is on the order of ten times greater than the time constant caused by the forward resistance of the diode 52 and the capacitor 53. The capacitors 53 and 55 together with the resistor 54 form a CR-jr integration circuit.

The capacitors 53 and 55 continue to be charged and discharged in the manner described until the charging voltages become equal. This equilibrium state with the same tensions is maintained. This voltage is impressed on the gate of a field effect transistor 56, at the drain of which a positive DC voltage and at the source of which a negative DC voltage is applied via a resistor 57. A voltage occurring at the source follower resistor 57 of the field effect transistor 56 is impressed on the base of an NPN transistor 58, the collector of which is connected to a positive DC supply voltage and the emitter of which is connected via a resistor 59 to a negative DC supply voltage. The direct voltage occurring at the emitter of transistor 58 is fed back to the anode of diode 52 via a resistor 60. The consequence of this is that the voltage at the anode of the diode 52 assumes a bootstrap voltage curve ν, which is shown in FIG. 7 (B).

As a result, the pulse voltage u a 'is successively supplied to the input terminal 50 with a period Γ3, whereupon a pulse current conducted through the diode 52 is charged into the capacitor 53, and

ίο / was in such a way that this current is superimposed on the potential on the anode side of the diode 52. A charging voltage w therefore occurs across the capacitor 53. which has the curve shown in Fig. 7 (C). In the case of a charging voltage w across the capacitor 53, the charging voltage across the capacitor 55 assumes a curve a, which is shown in FIG. 7 (D) is shown. In a corresponding manner, a step-shaped voltage y occurs at an output terminal 63, at which all step potentials are equal and which is shown in FIG. 7 (E)

The circuit is reset as follows; By closing one of the circuit 20 after F i g. 1 corresponding switch 62, the charge of the capacitor 55 is discharged via a resistor 61.

The switch 62 is controlled by the output signal of the monostable multivibrator 19.

If, in the embodiment described, the pulse width of the pulse voltage u is sufficiently large. It is also possible to differentiate the input pulse voltage u beforehand by means of the capacitor 51 and the resistor 60, and to supply the resulting pulse voltage to the anode of the diode 52.

By changing the values of capacitor 53, resistor 54 and capacitor 55 and through Change of the pulse width and pulse height of the pulse voltage and with that of the diode 52 pushed on Pulse voltage is changed, it is still possible to change the step potential of the staircase curve oscillation.

If a diode with an extremely small reverse current is selected for the silicon diode 52, a metal oxide semiconductor field effect transistor is used as the field effect transistor 56 and large constants are selected for the capacitors 53 and 55 as well as for the resistor 54, it is always possible to have an excellently graduated one at the output terminal 63 Obtain output signal even if the input pulse voltage has a long period, for example with a pulse voltage ο with a period Γ3 of 1800 s.

Another embodiment of a special circuit for the staircase curve generator is shown in FIG . 8 shown. This includes parts that are associated with parts of the circuit according to FIG. 6 are identical or similar are provided with the same reference numerals. A detailed one

Description of these parts can be omitted.

A PNP transistor 70 is used for temperature compensation of the circuit. The emitter of this transistor 70 is connected to the resistor 60 and connected via a resistor 71 to a positive DC voltage . The collector of transistor 70 is connected to a negative DC supply voltage. Resistors 72, 73, 75 and 77 and NPN transistors 74 and 76 form a constant current circuit and ensure a level shift of the output current. This embodiment offers the advantage that it can be operated with greater stability than the first-described embodiment of the stepped curve generator.

For this 5 Rlalt Zcichnunecn

609 643/285

Claims (6)

Claims: 24 315 1. A record recording arrangement with a cutting and recording device whose Cutting head when recording signals on a rotating record from the outer edge of the record running in the direction of the inner edge of the plate, characterized in that a device (13, 14) during the time in which the cutting head (10) moves from the outer edge of the record into Direction running towards the inner edge of the record, generates signals that indicate the respective position of the Cutter head on the record that a device (15 to 18,21) these position signals receives and generates a tax voltage, which in Has successively changing voltage values in accordance with the position signals, that a limiting amplifier device (26) the amplitude of the fed to it, on the Signals to be recorded on the record limit that one acting on the limiting amplifier device Control device (22, 25; 42) for limiting the amplitude of the signals to be recorded Amplification of the limiting amplifier means in accordance with the control voltage controls whose voltage values are such that the degree of amplitude limitation of the Signals successively increases when the cutting head on the record from the outer edge of the record runs in the direction of the inner edge of the plate, and that a device (27,11) the Ausgingssigna-Ie the limiting amplifier device supplies the cutting head. 2. Recording arrangement according to claim 1, characterized in that the device for Generate the position signals during these signals successively at specific time intervals the period of time in which the cutting head moves from the outer edge to the inner edge of the record. 3. Recording arrangement according to claim 1, characterized in that the device for Generating the control voltage generates a voltage with a step-shaped curve, the Voltage levels successively increase in accordance with the position signals. 4. Recording arrangement according to claim 1, characterized in that the limiting amplifier means a main amplifier (26), a negative feedback branch 28 to 30) to the negative Feedback of part of the output signal of the main amplifier to its input side and a on the input side of the main amplifier switched into the negative feedback branch Contains resistance device (25), the change in resistance thereof caused by the negative feedback voltage controls the gain of the main amplifier, and that the control device in the has means (22) connected to the negative feedback branch of the limiting amplifier device, which is under the influence of the tax franchise of the control voltage generating device the negative Control feedback voltage. 5. Recording arrangement according to claim 1, characterized in that the control device a variable one provided on the output side of the limiting amplifier device Resistance device (42) and that the resistance of the variable resistance device device can be controlled by the control voltage of the control voltage generating device. 6. Recording arrangement according to claim 1, characterized in that the control voltage generating device has a π-integration circuit constructed from capacitors (53, 55) and a resistor (54), to which the position signals are fed in succession via a diode (52), the capacitors being charged that a field effect transistor (56) is connected with its gate to the jr integration circuit and has a source follower output element (57,63) at which an output voltage occurs, and that means (58, 60,70) are provided which this output voltage for Return the anode to the side of the diode (52), with a step-shaped voltage occurring at the output element of the field effect transistor, the voltage values of which gradually increase in succession. take