DE652566C - Automatic amplitude control for photographic sound recording - Google Patents

Description

The invention relates to a device for the automatic control of the Amplitudes in the production of sound recordings. The characteristic. sign of the invention is that at Sound currents up to a fixed amplitude for transmission or amplification is constant, but in the case of sound currents of greater amplitude the degree of amplification or transmission decreases. This device for automatic amplitude control can be used both in the normal recording circuit as well as in the so-called noiseless circle.

Amplitude control devices in the recording of sound films are already known. These known amplitude regulating devices work partly automatically, partly they are set by hand. at the subject of the invention is only about automatic control devices. The previously known automatic control devices work so that small amplitudes are amplified more than large amplitudes. In contrast to this, according to the invention, the amplitudes should be up to one certain size can be increased or strengthened by a constant amount, if exceeded but this amount should decrease the reinforcement number. The principle according to the invention is thus different from the known ones Procedure fundamentally different. It offers particular advantages when used in Devices for recording background noise-free sound films. Because if you look for the Zero-line displacement method works, so one must ensure that when enlarging the 'amplitude over a certain value does not exceed the zero line of the record Center line of the recording strip is shifted out, as in this case the distortions get too big. According to the invention, various embodiments of this idea are provided. It is both possible to set up the automatic amplitude control in the control circuit as well to use in the noiseless circle of recording.

The transmission device can expediently consist of an amplifier. That mean negative potential, d. H. the bias of the control electrode of these tubes decreases when the alternating currents corresponding to the sound waves are a predetermined one Exceed amplitude. To achieve this, a high resistance can be used, for example connected in series with a bias voltage source to the control electrodes of the tubes will. The preload is adjusted so that it is greater than that

Peak voltage of the amplitudes normally supplied by the alternating currents. First when the amplitudes to be recorded exceed a certain value they are greater than the negative bias of these tubes and thus generate a grid current, which generates a corresponding voltage drop across the resistor, making the grid more negative by this voltage drop biased so that the reinforcement number of the tubes is reduced. One can on this way achieve that the transmission or amplification up to certain Amplitudes is constant and that the gain then decreases.

As already mentioned, the arrangement according to the invention can be advantageous in terms of recording can be used by sound films with no background noise. In these known facilities the background noise-free sound recording are the sounds to be recorded rectified and the rectified current is used, an aperture or the like. Correspondingly to drive the envelope of the tone curve, so that a record after the covering process or the line displacement process. Even in these arrangements it is very desirable to prevent the middle The value of the rectified currents does not exceed a certain value to be determined in advance, if the recording device, strong notes.

For this reason, according to the invention, the alternating currents are before rectification sent by a transmission device, for example by an amplifier, whose transmission or amplification decreases in the sense described above when the alternating currents have a certain im exceed predetermined amplitude size.

According to another idea of the invention, the alternating currents are not, before the Rectification sent by a transmission device whose gain is decreasing, when the currents exceed a certain amplitude, but the control circuit (Noiseless circuit) contains a bias battery that comes with a rectifier is interconnected in such a way that the voltages caused by rectification of the Counteract preload. 'By means of this arrangement via rectifiers can be prevented that the recording device is subjected to a voltage which is the opposite Has the sign of the preload battery.

If an exposure in accordance with the alternating currents and by means of a is controlled by the mean amplitude of the alternating currents dependent bias, 'the circuit through which the Alternating currents' are supplied, consist of two parts that are electrical around two points are symmetrical, which are equipotential with respect to 'the alternating currents. In one part of this circuit houses the actual recording device, and in the other part of the circuit there is an equivalent balancing agent. One of the envelopes of the Voltage corresponding to alternating sound currents can be supplied through a circuit, which connects the two equipotential points with each other.

Two exemplary embodiments of the invention are shown in the drawing.

In the embodiment shown in Fig. 1 According to the invention, the sounds are converted into electrical currents at the microphone 19 and via the amplifiers 20 and 21 to the transformer primary windings 22 given. The amplifier, which consists of tubes 24 and 25, is connected in push-pull. The grid of the tubes is negatively biased by a battery 27. With this' A resistor 26 is connected to the bias voltage source. In the output circuit of the tubes 24, 25 is the primary winding of the transformer 28. The anode voltage is supplied to the tubes via the impedance 30 from a battery 29.

The negative bias applied by the battery 27 to the tubes' Stejier electrodes 24 and 25 is pressed on, is set in such a way that the operating points of the tubes 24 and 25 come to lie in the middle of the characteristic curve of these tubes. As long as the the voltage impressed on the transformer 22 on the control electrodes is not higher than that Bias, the tubes will work like the well-known push-pull amplifier. As soon however, the control electrodes receive a peak voltage which is the value of the bias voltage exceeds, they'a positive potential is obtained, as a result of which a grid current flows and as a result of which a voltage drop is generated across the resistor 26 which shifts the operating point of the tubes on the characteristic curve. This shift has the effect of increasing the gain of the amplifier decreases. . Since the output circuits of the tubes 24 and 25 are in push-pull circuit with each other are connected, the distortion created by the force limitation is essentially neutralized.

The secondary winding of the transformer becomes a familiar one, made by hand actuated volume control device; e leads, which from the two resistors 31 and 32 consists.

The one consisting of tubes 34 and 35

Amplifier operates in the same way as amplifier 24 and 25 previously described. Due to the limited effect of the amplifier 34, 35, that of the transformer 23 the power supplied to the transformer 36 has a predetermined maximum value not significantly exceed.

The audio currents are fed from the transformer 36 to the recording device 12. A resistor 37 is connected in series with the loop 12 which essentially equal to the impedance of motion of the loop 12, so that about half of the energy supplied by the transformer 36 is used in the movement of the loop 12 will.

A constant current flows from the battery 38 through the wire 39 to the tap the secondary winding of the transformer 36. From this tap point, the partial currents branch off, one of which through the Loop 12, the other flows through resistor 37. By means of the resistor 40 is the current from the battery 38 adjusted so that the bands 12 tight next to each other when no tones are being recorded. This constant current is supposed to hereinafter referred to as the static preload.

The currents coming from the transformer 33 are passed through the full wave rectifier 41 rectified. Tests have shown that the highest efficiency of Recording device is achieved when the rectifier has an impedance about the same size as the impedance of the light valve. There is now a light valve normally If the impedance has a fairly low impedance, the impedance of the rectifier may as well not to be chosen large; for this reason it is proposed as a rectifier 41 to use a copper oxide rectifier. The output current of the Rectifier 41 is made up of an adjustable resistor 42 and a choke coil

43 is fed to the connection point between the resistor 37 and the loop 12. From this point a partial current flows through the ribbons 12 and part of the secondary winding of the transformer 36, while the other partial current the resistor 37 and the corresponding other part of the secondary winding 36 flows through. Over the line

44 the current is then fed back to the secondary winding of the transformer 33.

In the loop 12, the current originating from the rectifier 41 flows in the opposite direction to that originating from the battery 38. The output current of the rectifier 41 changes with the modulated waves impressed on the transformer 33 and shall now be called the dynamic bias voltage. The dynamic pre-tensioning counteracts the static pre-tensioning. By appropriate choice of coil 43 and capacitors 45 and 46, the time constant of the system can be set correctly. By adjusting the resistor 42 it can be achieved that the bands 12 adjust themselves just so far from one another that their distance is equal to twice the value of the oscillation amplitude of the modulated tones. A weak current also flows from the battery 38 via the rectifier 41 and via the resistors 42, 40 and the impedance 43 back to the battery. This current produces such a change in the operation of the rectifier 41 that the working impedance thereof falls below the normal value and the impedance of the loop 12 comes closer. According to FIG. 2, the sound waves are fed from the microphone 47 via amplifiers 48, 49 and primary windings of the transformers 50, 51. The currents drawn from the secondary windings of the transformers are amplified by similar amplifiers. Each amplifier contains a potentiometer, which consists of two controllable resistors 52, 53 connected in series. The resistor 53 is bridged by a second potentiometer 54, which regulates the modulated voltage that is fed to the control electrode of the amplifier tube 55. By means of the contact arm 60 of the potentiometer 54, the voltage can be changed from zero to the maximum voltage prevailing between the ends of the resistor 53. If the switch 56 is opened and the switching arm 57 is swiveled over from contact 58 ^{1 (} > ⁰ to contact 59, the voltage supplied can assume the same value as the maximum voltage developed by the secondary winding of transformer 50; it is thus by means of the two ¹⁰ S potentiometer possible to regulate the voltage applied to the control electrode of the tube is pressed 55 within wide limits. the output terminals of the tube 55 can be connected to a further ^no \ '~ erstärkerstufe via the transformer 61, for example, two in push-pull circuit arranged tubes 62 and 63 may exist.

From the transformer 64 the "5 loop 12 of the light valve is the alternating voltage fed. The light valve is in series with a resistor 37 and, if desired, connected in series with another resistor 65. Those from the transformer 66 Output power is fed to the control circuit (noiseless circuit), namely

with the interposition of a full-wave rectifier 41. Those parts of the circuits, which have the same functions in Fig. 1 and 2 are numbered with the same reference numerals.

Another rectifier 6y is connected in series with the battery. This rectifier can also be a copper oxide rectifier. The static bias current flows from the battery 38 through the line 68 to the secondary winding of the transformer 64. Part of the current flows through one section of the secondary winding, the resistor 65 and the loop 12, while the other part of the current flows through the second section of the secondary winding and the resistor 37 flows through. All of the static bias current then flows back through rectifier 67 and resistor 40 to battery 38.

The dynamic bias current flows from the secondary winding of transformer 66, through rectifier 41, via resistor 40 and battery 38, back to the secondary winding of transformer 66. The rectifier 67 prevents the dynamic bias current generated by the rectifier 41 from flowing through the loop] 2. However, this dynamic bias current creates a voltage drop across resistor 40 which counteracts the static bias current. The dynamic voltage current can cause the static bias current flowing through loop 12 to be reduced to zero. A current reversal of the current flowing through the loop 12 can not occur because of the rectifier 6y if the energy supplied by the transformer 66 exceeds a previously determined value.

Claims (5)

Patent claims: 1. Device for automatic regulation of the amplitudes to be recorded Production of optical sound recordings, characterized in that in the case of sound currents the transmission or amplification up to a fixed amplitude is constant, but the degree of amplification or transmission decreases with sound currents of greater amplitude. 2. Device according to claim 1, characterized by the application in Noiseless circle with clear audio recording. 3. Amplifier with variable negative bias on the grid of an amplifier tube in a device according to claim 1 or 2, characterized in that that the negative bias is only increased when the amplitude of the sound currents is predetermined Value exceeds. 4. Device according to claim 2, characterized in that a rectifier (6y) is connected in series with a bias voltage (38) which counteracts the noiseless current, so that the current cannot change its direction when the noiseless current is a certain one Value exceeds. 5. Device according to claim 2 or 4, characterized in that the sound circuit consists of parts electrically symmetrical about two points, in one part a light control device (12), in the other part an equivalent Equalizing impedance (37) is arranged, and that the noiseless current obtained from the rectifier (41) between 8ü the two symmetrical points. 1 sheet of drawings