DE1039575B - Method for the distortion and equalization of signal alternating currents for the purpose of secrecy during transmission - Google Patents

Description

Method for distortion and equalization of signal alternating currents for Purposes of secrecy during transmission It is known for the purpose of Confidentiality during the transmission of an alternating signal current an alternating interference current of similar frequency and waveform and with such an amplitude that the Signal alternating current goes down in the interference level. On the receiving end, the incoming Frequency mixture corresponding to the interfering alternating current in frequency, curve shape and amplitude, but superimposed in phase opposition to this standing compensation alternating current, which compensates for the interference frequency current so that the signal change - #: trom is undistorted can be listened to or written.

From the inventor's own preliminary work, cf. B. the German patent specification 688247 and the USA patent specification 2 083 653, it is known to generate the interference or compensation alternating currents by synchronous, photoelectric scanning of phonograms; In particular, the photoelectric scanning of synchronously driven rotating pieces of glass is used with the optical sound recording of an interference frequency spectrum. These panes of glass are driven by synchronous motors and contain an interference frequency curve that recurs with each revolution. B. for voice encryption covers about a frequency band from 200 to 3000 Hz.

There are several disadvantages associated with this method. In the z. B. off Speech and interference frequencies existing. via the transmission system, e.g. Legs Line or-a high-frequency connection, transmitted frequency composite are, since it is a simple superposition of both, the aperiodic curves of the language and the periodically recurring curve of the interfering alternating current unchanged contain. To equalize the speech it was therefore possible to use the frequency mixture to be recorded continuously with the help of a magnetic tape and by double scanning of the recorded frequency mix and by the arrangement of the two scanning systems in such a way that their distance from each other or their relative position to the recorded Frequency mixture a single or multiple length of the recurring interference frequency curve is to get them synchronously twice. By superimposing the two interfering frequency mixtures sampled in this way succeed in eliminating the periodically recurring Eliminate interference frequency curve while the aperiodic and asynchronous speech frequencies remain uncompensated. The unskilled person who uses this method listens then the language is double, but completely understandable.

It is also known not to generate interference frequency phonograms to use of interfering alternating currents, which are superimposed on the signal currents, but with them directly or via electrical switching elements the signals or the signal currents to modulate and only these modulated signals via the transmission system, z. B. a telephone line or any other transmission system, your To be transmitted to the recipient. This alternating signal current encoded by the modulation is indicated on the receiver by a corresponding to the interfering phonogram, but in phase opposition for this working phonogram deinodulated on the receiving station and on this '\ Ant suppressed again. In this process, the character goes from the original Transmission frequency (signal and interference frequency) on the transmission system to a large extent lost, but it is difficult to avoid that the interference modulation curve is determined on the transmission path by unauthorized persons.

Therefore, technical means are provided according to the invention, which prevent the curve of the noise frequency phonogram in practical operation without the presence of the signal frequency to be modulated on the transmission system, z. B. the line arrives. This is achieved according to the invention in that the Signal alternating currents at the transmission location divided into their positive and negative half-waves both of which are modulated by at least one interference frequency phonogram, and that the half-waves modulated in this way on separate transmission paths or reassembled and fed to the receiving location on a common transmission path be, where positive and negative half-waves for themselves by at least one Kompensationsstö rfrequency phonogram demodulated and the thus etitzerrteti signal frequency half-waves assembled your signal receiver. In this "" way, the interfering phonograms become only then on the line, d. 1i. the electrical transmission system, given when at least one half-wave of the signal to the system causing the interference modulation acts.

In the following description of the inventive method for distortion and equalization of signal currents for the purpose of secrecy the technical terms used should have the following meanings: 1. Signal alternating currents are such alternating currents that the carrier somehow type of message. This includes both telephony and telegraphy or video telegraphy and television.

2. Interfering frequencies. All of them are of some kind under interference frequencies Understood vibrations which are suitable for a signal or a signal alternating current disturb.

3. T'nter compensation frequencies are understood to mean all vibrations, which are suitable that are superimposed on a signal or a signal alternating current or to compensate for modulated interference frequencies.

4. Overlay. Overlaying is understood in the context of the invention, to mix in any vibrations other vibrations in such a way that the resulting Vibration mixture does not contain a significant proportion of frequencies that are in the Input vibrations were not included.

5. Modulation. Modulation is to be understood as meaning that any Vibrations are so influenced by other vibrations that the amplitudes of one or the other vibration can be changed and thereby in the vibrational genius new frequencies occur in the individual oscillations before the modulation were not present.

6. Transmission system. A transmission system should be understood to mean technical means for transmitting a message from one location to any other, in particular electrical transmission means of any type, such as lines, carrier frequency systems, etc.

7. Phonogram. A phonogram should be understood to mean every recording of oscillations or oscillation processes outside the audible frequency range or their graphic representations as longitudinal or transverse waves a material carrier.

In Fig. 1, 1 represents a pane of glass, which the Trä-I; he for the Forms disturbance phonogram. The Störphonogramm, which z. B. a frequency spectrum from 300 to 3000 Hz is on this disk as a circular photographic Intensity recording arranged, e.g. B. by appropriate exposure and development a photographic layer on the plate (see 2 in Figs 5).

This phonogram carrier 1 is driven by a synchronous motor 3 with a number of revolutions of z. B. 25 per second in constant rotation. An arrangement consisting of a cathode ray oscilloscope 4, in which the cathode ray 5 is dimensioned by electron-optical means so that it images a rectangular light spot 7 on the fluorescent screen 6, as also shown in FIG. 2 in is shown again on an enlarged scale. An optical diaphragm 8 is arranged behind the phonogram carrier 1 in such a way that it blocks the light passing through from the light spot of the oscilloscope in the rest position of the cathode ray. This rest position is shown in FIGS. A microphone circuit 9, consisting of the microphone, a supply battery and a transformer, is connected to the deflection plates of the oscilloscope 4 via a universal switch 10. When alternating speech voltages strike the deflection plates, the cathode beam 5 is deflected upwards or downwards from its rest position, and the deflection upwards corresponds to the positive half-wave of the alternating current. the distraction down the negative. Each deflection of the cathode ray in one direction or the other allows an amount of light corresponding to its amplitude to fall through the interference frequency phonogram via the deflecting mirror 11 either onto the photocell 12 or 13. This deflection of the light spot out of the area of the covering diaphragm is shown in FIGS. The lines labeled zero above the phonograms in FIGS. 3 and 5 serve to represent the respective cathode ray deflection and the currents in the photocells 12 and 13 corresponding to them.

In Fig. 2 the light spot is behind the aperture. This location he takes. when no alternating speech current affects the cathode ray. In this At the moment there is no light falling on either of the two photocells and the phonogram consequently does not produce any modulation and no alternating current is passed through the push-pull transformer 14 and the changeover switch 15 are sent to the line. When discussing des .Mikrophone is positive in the event that the top plate of the oscilloscope is charged, the light spot is deflected upwards. The light falls through the interfering phonogram on the photocell 12 and sends an amplified positive half-wave via the tube 16 to the line (see illustration of the half-waves in Fig. 4). When the voltage is reversed on the plates of the oscilloscope light falls on the photocell 13 and sends over the tube 17 has an amplified negative half-wave for conduction, as illustrated in FIG. The half-waves shown in Fig. 4 and 5 correspond to the undistorted alternating speech current, d. that is, it is assumed that the phonogram carrier is stationary and not rotating. With a rotating phonogram, the half-waves are depending on the course of the permeability same, that is, according to the curve of the interference frequency that the phonogram in the form of intensity fluctuations contains, modulated, d. i.e., the signal currents are distorted beyond recognition. At the receiving location, the equalization is used for equalization Arrangement used as shown in Fig. 1, with the difference that the Changeover switch 10 the capacitor plates of the oscilloscope 4 to the one with the long-distance line connected transformer 18 and the switch 15 instead of the long-distance line a telephone receiver 19 to the output transformer 14 of the push-pull amplifier switches. This switch position is indicated by the dashed lines at 10 and 15 shown. Fig. 1 then corresponds to the receiving arrangement for the modulated, i.e. H. distorted signal alternating current. The incoming modulated alternating current is again through the oscilloscope and the photocells into its two modulated half-waves disassembled and accessed via the Push-pull amplifier as a composite Vibration on the phone 19.

For demodulation, i. H. to compensate for the distortion of the half waves, but instead of the interfering phonogram used for sending, the Negative of this phonogram used, namely synchronously and with the same phase position of rotation. At the time where z. B. at the transmitter a positive half-wave Light spot of the oscilloscope 4 on a point of low light transmission of the Phonogram controls, the correspondingly distorted half-wave now brings the light spot to a point on the phonogram with high permeability, and the distortion becomes compensated. The same applies to every half-wave at every point in time.

With this type of half-wave division and the modulation of a transversal vibrating light triangle through a longitudinal vibration recording is simultaneously achieves that the amplitude of the distortion is always proportional to the amplitude of the Half wave is. As a result, this method has the advantage that the distortion and the corresponding equalization of the amplitude of the signal alternating currents what is independent of the principle of the known superimposition of interfering alternating currents is by no means the case. This has a particularly beneficial effect on transmission systems with non-linear frequency response of the transmission factor.

It goes without saying that within the scope of the invention instead of this with the help of oscillographs and photocells working system other processes for modulating an alternating signal current with the aid of interference frequency phonograms can kick. So show z. B. Figs. 6 and 7 show another embodiment of a Arrangement for carrying out the method according to the invention, in which the modulation and demodulation of the alternating signal current, which is also divided into half-waves an interfering alternating current generated by means of phonograms takes place. The one from the microphone 20 coming alternating speech currents are via the transformer 21 in the push-pull circuit working tubes 22 and 23 supplied. The grid voltage battery 24 is so high a negative voltage is applied to the grids of the two tubes that they work as a so-called B amplifier, d. i.e., there is only one over each tube Half-wave of the voice alternating current coming from the transformer 21 is amplified. In the The anode circuit of the tubes 22 and 23 is for the purpose of modulation by the interfering alternating currents, respectively one: \ Iodulationsröhre 25 and 26 placed, whose grid voltage with the help of the Batteries 27 and 28 is set so that they are in the even part of the grid voltage-anode current characteristic is working. About the push-pull transformer 29 are the grids of these two control tubes the AC voltages of the interference frequency generator 30 supplied, with the help of which the half-waves transmitted by the tubes 22 and 23 by changing the internal resistance the modulation tubes 25 and 26 are modulated, d. H. distorted and over the push-pull transformer 31 the transmission system, e.g. B. the pipeline, are supplied. The one in Fig. 6 Interference frequency generator 30, which is only shown schematically, is shown separately in FIG. 7. It also consists of a synchronous motor 32 with an on-axis motor circular translucent phonogram carrier 33, which in the exemplary embodiment a transverse optical sound record 34 carries an interference frequency curve. These Optical sound recording is made by one of the incandescent arm 35 via a lens system 36 and a diaphragm 37 generated light beam with a rectangular cross section 38 is scanned and the fluctuations in light from the photocell caused by the movement of the phonogram 39 via a simple straight amplifier 40 of the primary winding of the transformer 29 in the arrangement shown in FIG. Also with this switching arrangement according to FIG the negative of the interfering phonogram can be used for decoding. Since the However, modulation is purely electrical, can also be a positive interference or Modulation phonogram corresponding positive demodulation phonogram is used will. In this case, the phase opposition between the phonograms becomes easy achieved by reversing the polarity of the outputs of the photocell amplifier at the receiver. Of course, instead of the modulation shown in the exemplary embodiment any modulation method can be used by means of anode voltage control. On the other hand, it is important that a half-wave division takes place or by others The means achieved is that the modulation frequency is never in its original Form gets into the transmission channel and that the phonograms in some way modulate the signal oscillations or the alternating currents generated by them.

The inventive method for distortion and equalization can analogously also find application when the signals are not through direct electrical or other remote transmission means to be forwarded to the receiver. So you can z. B. the signal modulated with the interference frequency to any recording medium, z. B. a record or a magnetic tape record and dem through the post Forward recipient. In this case it is advisable to use an auxiliary frequency with which the synchronous scanning of the interfering phonogram at the transmitting station takes place, with on to register the same carrier and to synchronize this auxiliary frequency to use the equalization phonograms at the recipient.

The invention is of course not moved to the application Phonograms as shown in the exemplary embodiments are limited. Fixed phonograms can also be used. B. in the case of photographic phonograms scanned by a synchronously moving light beam will. A light beam rotating around a center point can have a rectangular Bundle cross-section can be used when the scanning is circular Phonogramme acts while a beam of light swinging back and forth rides a rectangular shape Cross-section for scanning linear phonograms comes into question. The Light bundles are generated by deflected cathode rays. But it can also oscillating mirrors or other optical systems for scanning the phonograms be used by means of light.

To synchronize the drive motors for moving phonograms or moving photoelectric or other scanning means for fixed phonograms alternating currents are used, which are either generated by constant vibration generators, such as tuning forks or electrical oscillation circuits, at the sending and receiving points can be generated independently of one another, or a corresponding one is only generated on the transmission side Generates drive alternating current, which is sent to the receiver on the same transmission medium, to which the message is transmitted is forwarded. It is also according to the invention possible this Alternating current, its frequency for technical reasons will generally be lower than the message frequencies, a higher frequency one To modulate alternating current, to conduct this over the transmission system and the Recover the synchronization frequency by deniodulation at the receiving location.

The method according to the invention can also be modified in such a way that that a light or cathode beam scanning the Störphonogramm at the same time in one perpendicular to its scanning direction controlled by the synchronization frequency Direction is controlled by the signal alternating current, such that signal alternating current and interference modulation or demodulation already converting the light oscillations Photocells are created.

Claims (1)

PATENT CLAIMS: 1. A method for distortion and equalization of alternating signal currents for the purpose of secrecy during transmission, in which the alternating signal currents at the transmission location are modulated by interference frequency phonograms prior to transmission, characterized in that the alternating signal currents at the transmission location are divided into positive and negative half-waves which are both modulated by at least one interference frequency phonogram, and that the half-waves modulated in this way are fed to the receiving location on separate transmission paths or reassembled on a common transmission path, where positive and negative half-waves are demodulated separately by at least one Konipmsationsstörfre <luence phonogram and thus equalized Signal frequency half-waves composite fed to the signal receiver «-ground. 2.) 'experience according to claim 1, characterized in that the alternating signal currents by means of light or cathode rays (5) controlled by them in conjunction with at least two push-pull photocells (12, 13) or other light or cathode rays in electrical currents converting devices are broken down into their positive and negative half-waves and that one or more interference frequency phonograms are placed in the path of the light or cathode rays. which modulate these beams and thus the signal frequencies. 3. The method according to claim 1 and 2, characterized in that interference frequency phonograms are arranged in the path of the light or cathode rays (5) controlled by the signal currents. in deneli the interference frequencies are recorded as differences in the radiation permeability of the phonogram. 4. 'The method according to claim 1 to 3, characterized in that at the sending location as Störphonogramme photographic intensity recordings and at the receiving location either identical records or negative copies of the phonograms present on the transmission side are used. 5. The method according to claim 1, characterized in that the signal alternating currents through electron tubes (22, 23) or by these similarly acting electronic devices, such as. B. transistors, broken down into their positive and negative half-waves in push-pull circuit and modulated with interference frequencies, which in turn are generated by one or more phonograms, and that the compensation at the receiving location by generated by the same means, in phase opposition to the Störf frequencies takes place. 6. The method according to claim 1 to 5, characterized in that the modulated by Störfrequenzphonogramme signal currents on per se known recording media, for. B. records or magnetic tapes, recorded together with a synchronizing frequency securing the synchronous scanning of the phonograms and reproduced on the receiving side using the recorded synchronization frequency and a demodulation phonogram corresponding to the interfering phonogram. 7. The method according to claim 1 to 6, characterized in that instead of moving phonograms, mme and unmoved scanning devices, unmoved phonograms are used, which cause the interference modulation of the signal alternating currents or the compensation of the interference frequencies by moving scanning means. B. The method according to claim 1 to 6, characterized in that circular. photoelectric Störphonogramme are scanned by a rotating cathode ray or its fluorescent light or by a rotating light beam. 9.) "experienced according to claim 1 to 6, characterized in that linear Störphotiogratnine are scanned by synchronized oscillating cathode rays or their fluorescent light or by appropriately controlled light beams. 10. The method according to claim 1 to 9, characterized in that a light scanning the Störphonogramm - or cathode-ray is controlled simultaneously in a direction perpendicular to its controlled by the synchronizing frequency scanning direction by the change of signal current such that signal AC and spurious modulation or demodulation already arise in which the light vibrations converting photocells contemplated publications: German Patent No. 731 394.. .