DE2143049A1 - Method and device for monochromatic recording - Google Patents

Description

Method and device for monochromatic recording The invention relates to a method and a device for monochromatic recording. The invention also relates to a recording medium.

The monochromatic recording of image signals, in particular of Color image signals on a recording medium, e.g. B. on a photographic film, the opposite of radiation energy, z. B. sensitive to electrons or light rays is, is known. Here, color image information is converted into a brightness signal and two types of color signals, e.g. B. divided into the un the Q signal (NTSC system). The health signal is recorded as it is while the two Types of color signals I and Q indicate the amplitude and / or phase (frequency) of a Modulate the carrier wave, which changes a sinusoidal curve accordingly, so that the modulated carrier wave is recorded. There can also be two types of carrier waves to be used.

However, if done in this way, accurate reproduction original image information cannot be guaranteed with certainty, since the modulated carrier wave cannot be reproduced with an exact frequency, if not the recorded lines and lines when reproducing the color signals be tracked exactly.

To avoid this disadvantage, a reference carrier shaft is put together recorded with the aforementioned modulated carrier wave superimposed, where the frequencies of the reference carrier wave and the modulated carrier wave in relation are integral multiples of each other. Furthermore, the phase of each carrier wave becomes perpendicular to the horizontal scanning direction of the electron beam for recording aligned on a recording medium, with the frequency of each carrier wave an integral multiple of the horizontal scanning frequency of the electron beam to record is.

In such a procedure, the size of the reproducing device increased because circuits and circuits are required from that in a detector extract a reference carrier wave from the reproduced signal and the multiply (or step down) the reference carrier wave in frequency 6 Another disadvantage of such a procedure is that a exact reproduction of the original image information cannot be guaranteed with certainty because it is very difficult to refer to the reference carrier wave to multiply or down-transform the frequency exactly. The frequency the reference carrier wave changes irregularly in the playback signal because the scanning speed of the reproducing beam changes, so that color errors appear. If the frequency of the carrier wave changes during recording, the phase of the carrier wave may not be perpendicular be aligned for horizontal scanning in the direction of the recording beam. The result is that during playback the recorded lines and lines must be followed exactly in their lane.

Based on the aforementioned prior art, there is therefore the The invention is based on the object of remedying the aforementioned disadvantages and an improved one To bring a method and an improved device for recording on proposal, whereby the most accurate reproduction possible should be guaranteed. Furthermore should a recording medium with a plurality of recorded signals is proposed are brought, which should enable the most accurate reproduction possible.

According to the invention, the signals to be recorded after a Difference in signal intensity generated is queried in turn and scanned. This is a random polling and sampling, which is called "sampling" in English usage. This expression is also used variously below. The intensity of periodically sampled Rays, like electron beams, are scanned and scanned with the help of Modulated signals.

Several picture-like frames are arranged on the recording medium, wherein a plurality of signals recorded in sequence are arranged and although in rows of transverse lines. The picture-like frames are in the longitudinal direction of the Recording medium arranged at a distance from each other.

The original signals are reproduced due to the differences the intensity of the signals of the recording medium.

Further details are more preferred from the description below Embodiments and can be seen from the accompanying drawing.

The drawing shows: FIG. 1 a block diagram of a device for the monochromatic recording of color television signals on an opposed to radiant energy sensitive medium; Fig. 2 is a diagrammatic representation of the shape and shape of a actually recorded signal, being two types of color signals to be recorded I and Q are converted into signals which are recorded by the arrangement according to FIG will; 3a diagram representations of the phase relationship of the sampling and 3b pulse for the alternating sampling of the two types of color signals; 4 shows an embodiment of a sampling pulse generator (for controlling the color switch), which is used in the arrangement according to FIG. 1; Fig. 5 a schematic representation of part of a medium on which signals are transmitted by means of the Arrangement according to Figure 1 are recorded; Figure 6 is a block diagram of a preferred one Embodiment of a device for reproducing the color television signals that are on are recorded in the recording medium of Fig. 5; Fig. 7 shows a preferred one Embodiment of an Ixector used in the arrangement according to FIG. 6; Fig. 8 a block diagram of a preferred embodiment of another apparatus for monochromatic recording of color television signals on an opposed to radiant energy sensitive and sensitive recording medium; 9 is a diagram representation the shape and shape of an actually recorded signal, being of two types of color signals I and Q are converted into signals by means of the arrangement are recorded as shown in Fig. 8; Fig. 10a is a schematic representation of a Part of a medium on which signals are recorded by means of the arrangement according to FIG will; Fig. 10b an enlarged section of part A of the Recording medium according to FIG. 10a; Figure 11 is a block diagram of a preferred one Embodiment of a device for reproducing Fartternsehsignen that on are recorded on the recording medium of Fig. 10a.

As can be seen from Fig. 1, an electron beam recorder is provided, from which air is sucked out with the aid of vacuum pumps, not shown, so that a certain reduced pressure is set. Inside a recording chamber 2 of the recorder 1, a supply reel 3a and a take-up reel 3b are arranged, which are connected to each other by a recording medium 4. This recording medium is sensitive to an electron beam and can e.g. B. from a photographic Film exist. A motor-driven mechanism 5 is also arranged in the chamber 2, which drives and transports the recording medium 4 continuously or intermittently. For the sake of authenticity, continuous transport is assumed below, where z. B. a role can be used.

Within two arrangements 6a and 6b are for generating electron beams Arranged electron guns 7a and 7b and condenser lenses 9a and 9b and 10a and lOb for collecting electron beams 8a and 8b emitted by the electron guns 7a and 7b go out and impinge on the recording medium 4. There are also deflectors lla and lib are provided, which are used for image decomposition and for scanning the electron beams 8a and 8b are used periodically and transversely to the direction of travel of the recording medium 4th

An energy source la for the electron guns not only provides the electrical heating current for the cathodes of the two electron guns 7a and 7b, but is also exposed to a negative high voltage and a constant bias voltage so that when supplying image information signals to a control electrode in each of the two electron guns electron beams 8a and 8b are generated which correspond to the intensity of the signals.

Each of the assemblies 6a and 6b is shown as if the electron beams 8a and 8b would irradiate locations that are longitudinally on the recording medium 4 are arranged at a distance from each other. In reality, however, the arrangement is chosen such that the electron beams emanating from the two arrangements 6a and 6b Irradiate locations of the recording medium 4 that are spaced apart from one another in the transverse direction are arranged. It can thus be a picture information signal on different transverse Positions of the recording medium 4 are recorded by means of the electron beams 8a and 8b will.

A synchronization signal generator 22 generates horizontal synchronization signals, vertical synchronization signals and blanking signals with a frequency of, for example 15.75 kHz and 60 Hz. Of these signals, the horizontal synchronization signals a generator 23 for horizontal scanning signals and a phase-locked pulse generator 24 supplied. The generator 23 generates horizontal scanning signals with a constant Frequency of 15.75 kHz for scanning the electron beams 8a and 8b across the Recording medium 4 based on the input signals. The horizontal Scanning signals are fed to the deflection means via lines 13, 14 and 15. the vertical scanning signals are used in a pulse generator to be described in more detail below 25 supplied. The blanking signals are supplied to adders 27a and 27b.

A color image information signal generator 20 consisting of, for example, a TV camera can consist, works on the basis of the signals of the aforementioned Generator 22 and generates signals in red, blue and green according to the colors of an original image. The respective signals are converted into a brightness signal (hereinafter abbreviated as Y signal) and in two types of color and saturation signals (chroma signals) I and Q or R-Y and B-Y converted by a color encoder 21. The Y signal is supplied to the adder 27a via an amplifier 26. After It is added to the blanking signals by the electron gun 7a of the arrangement 6a supplied via a line 16.

The intensity of the electron beam emanating from the electron gun 7a 8a is controlled by the signals supplied from the adder 27a. On the recording medium 4 therefore become frame-like images 40a, 40b, 40c ....... of the brightness signal generated due to the electron beam 8a, as shown in FIG.

The signal I of the two types of color signals represented by the aforementioned Color encoder 21 is generated, one of the inputs of a sampling circuit 30 supplied via a circuit (level-up circuit) 29 after an amplification by means of of an amplifier 28a has taken place. The other color signal Q becomes the other The input of the sampling circuit 30 is supplied via an amplifier 28b. In the circle 29 becomes a constant signal (above the maximum variation intensity of the respective Color signals) are added to the color signal I to give the color signals 1 and Q as the difference to distinguish the signal intensity.

The circle 30 is a control and query pulse of, for example 1.5 MHz, which has been generated by the generator 31, is supplied.

The supply takes place via a nesting circle (interleaving circuit) 32.

From the circle 30, the two color signals I and Q are sent to the adder 27b supplied, with a switchover due to the control pulse he follows.

The output of the adder 27b becomes the electron gun 7b Via a conductor 17 for generating the electron beam 8b and for controlling the Intensity of the same supplied. From the signal sent from circuit 30 to the adder 27b is fed, a signal, which is composed of the color signals I and Q, there is a difference in signal intensity as shown in FIG is. The aforementioned signal is formed by modulating the upper amplitude a square wave by the color signal I and the lower amplitude by the color signal Q. It is therefore a signal in which the upper envelope has the signal I. and the lower envelope shows the Q signal. On the recording medium 4 are thus frame-like images 41a, 41b, 41c .... of the color signals by means of the electron beam 8b formed in sequence as shown in Fig. 5, within one two types of color signals across the recording medium for each frame-like image are recorded. The recording density on each recording part changes. according to the signal intensity and the type of signal.

With this arrangement, the phase of a generated by the generator 31 becomes Sampling pulse of 1.5 MHz controlled by the phase control pulse generated by the phase-locked pulse generator 24 is generated based on the horizontal Synchronization signal works so that the phases at the beginning of the horizontal Scanning the electron beam for recording 8b are always the same. if thus the frequency of the sampling pulse, namely the switching frequency of the color signals I and Q are not an integral multiple of the horizontal scanning frequency of the electron beams 8a and 8b, the phases are not aligned from scan line to scan line, as shown in Fig. 3a. It follows that the recording parts of the Signal I and signal Q on the recording medium are not from the scanning line are aligned with scanning lines so that the recording line during the reproduction should be followed closely. As can be seen in FIG. 3b, when the Phases the recording parts of the color signals I and Q aligned so that it is not it is necessary to closely follow the recording line during playback (track).

With this arrangement there is consequently a transistor 35 on the side a transistor Trl of an astable multivibrator 34 is provided.

According to FIG. 4, the multivibrator 34 consists of transistors Tr1 and Tr2, resistors R1, R2, R3 and R4, and capacitors C1 and C2. The multivibrator 34 serves as a pulse generator 31. By means of a circuit, the emitters and turn Collectors of the two transistors Tr1 and 35 respectively connected. With this circuit a terminal 36 is connected to a power source B, which is not shown in FIG is, while another terminal 37 is connected to a direct current source, which is also not shown in FIG. When the value of each circuit element is determined, the frequency of the sample or sampling pulse, which is from the terminal 38 is forwarded to the circle 32, can be controlled by the size of the voltage applied to terminal 37 is changed. The phase control pulse that passes through the phase-locked pulse generator 24 based on the horizontal synchronization signals is generated has the same frequency as the horizontal synchronization signal, namely, 15.75 kHz, as shown by the Xeichen Pc in FIG. If this Pulse is passed from terminal 39 to the base of transistor 35 is a "continuity established between the emitter and the collector of the transistor Tr1, so that the level of the output signal of the terminal 38 corresponds to the reference level will be changed. A certain square wave is thus generated at the output 38. The phase of the output signal at output 58 is constantly determined by the phase control pulse, which is applied to the base of the transistor 35, controlled and controlled. the phase of the sampling pulse is therefore roughly the same from scan line to scan line, as shown in Fig. 3b. The recording parts 42a, 42b, 42c ... and 43a, 43b, 43c ... of the color signals I and Q are thus on the recording medium 4 at right angles to the horizontal scanning direction of the electron beam 8b for the Record within the respective frame-like images 41a, 41b, 41c according to FIG Fig. 5 aligned, i.e. in the longitudinal direction of the recording medium 4. In Fig. 5 the recording parts of the signal I are also shown in black while the recorded parts of the signal Q are shown with hatched oblique lines are. In addition, the density of the recording parts of each signal changes according to the density of the signals in practice.

The 1.5 MHz sampling pulse generated in this way is fed to circuit 32.

This circle converts the phase of the aforementioned sampling pulse from field to field and forwards it to circle 30. The control signal from 60 Hz, which is generated by the pulse generator 25 on the basis of the vertical synchronization signal of 60 Hz, which in turn was generated by the synchronization signal generator 22 has been generated, is thus fed to the circuit 32. When the phase of the sampling pulse is converted from field to field in a television signal, the sampling order of the two types of color signals in circle 30 are reversed from field to field.

The result is that the two types of color signals are recorded that the recording parts of each signal are recorded so that the recording parts of each signal go from frame-like picture to frame-like Image can be reversed as shown in FIG. The recording parts of the signal I in the frame-like image 41b thus come to positions representing the recording parts of Signal Q in the frame-like image 41a correspond while the recording parts of the signal Q in the frame-like image 41b come to positions which are the recording parts of the signal I in the frame-like image 41a. Although actually an impairment due to the missing parts in signals 1 and Q in the reproduced Picture, this is not the case in practice because of the aftereffect of an image in the human eye in the continuous display of a series of pictures. Since the circuit 32 convert the phase by 180 ° at a frequency of 60 Hz can ¢ synchronization of the sampling pulse with the vertical synchronization signal), For example, a phase converter using a delay circuit can be used.

A medium on which a record can be made with such an arrangement is recorded is with picture-like frames 40a, 40b, 40c of the brightness signal of the electron beam 8a and with picture-like frames 41a, 41b, 41c .... of the color signals of the recording electron beam 8b in the longitudinal direction, as shown in Fig. 5 is shown. Since two kinds of color signals 1 and Q drive the electron beam 8b for recording during a horizontal scanning period within the picture-like Modulate frames 41a, 41b, 41c .... of the color signals, the two types of Color signals I and Q recorded across the recording medium 4 in sequence. The recording location 42a, 42b, 42c .... and 43a, 43b, 43c .... of the color signals are controlled so that the phases of the sampling pulse at the beginning of the horizontal Scanning of the electron beam 8b are always the same, with approximately one alignment takes place along the recording medium. As the phases of the sampling pulse from field are reversed to field, the recording parts of the respective color signals recorded in reverse from picture-like frame to picture-like frame. The drawing density the color sighale in each frame not only changes accordingly of each signal density, but very strongly according to the type of signal, since a direct current component is added to the color signal 1.

In Fig. 5 are also vertical synchronization indices 44a, 44b, 44c and sound traces 45a and 45b are shown.

Fig. 6 shows an embodiment of a device for reproduction image information from the recording medium as shown in FIG Supply reel 50a and one. Take-up reel 50b is provided for the recording medium 4, which by a drive mechanism 51 z. B. continuously by a role is transported. A cathode ray tube 52 is powered by a power source 53 controlled. The scanning electron beam in this cathode ray tube has a constant one Intensity and is sampled in one direction at the same frequency as the Electron beams 8a and 8b in the arrangement according to FIG. 1. The frequency is thus 15.75 kHz. The generated on the fluorescent screen of the cathode ray tube 52 Rays are generated with the help of condenser lenses 54a and 54b, of which lens 54b is not shown, focused on the recording medium 4. Feel the rays the recording medium 4 in the transverse direction. This scan accompanies the scan of the scanning electron beams in the cathode ray tube 52. Those through the lens 54a passing rays thus feel the inside of the picture-like frame (see Fig. 5) of the brightness signal, while those passing through the lens 54b Rays scan the inside of the picture-like frame of the color signals. Since the respective rays pass through the recording medium, their intensity depends (Amount of light) depends on the recording density on a transmission part. That through light passing through the recording medium is thus made via appropriate light guide means 55a and 55b on photo multipliers 56a and 56b irradiated and converted into an electrical signal that corresponds to the intensity of the light. The conversion takes place by means of the photo multipliers. The output signal of the Photo multiplier 56a corresponds to the luminance signal in the case of recording and this signal is fed to a mixer 58 via an amplifier 57. on the other hand The output of the photomultiplier 56b is similar to that shown in FIG Signal. However, there is some deviation and variation, and more or less according to the size of the spot of the electron beam 8b (see Fig. 1) and / or the beam for playback. If the size of the spot or point of the E lektronenstrahles 8b or the beam for reproduction is enlarged, changes the playback signal changes according to a sine wave. This playback signal is passed through an amplifier 59 and then to envelope detectors or rectifiers 60a and 60b consisting of diodes 70a and 70b, resistors 71a and 71b and capacitors 72a and 7ab exist. As can be seen in FIGS. 7a and 7b, here the diodes connected in reverse. The detector 60a is here the upper envelope curve of the playback signal, while the detector 60b of the lower envelope assigned. The upper envelope of the playback signal is a color signal I, while the lower envelope is a Q color signal.

The color signals I and Q produced in this way become correction circles, respectively 61a and 61b supplied. The correction circuit 61a is a part of the color signal Q des Detector 60b fed through a polarity converter 62b to detect the component of the reject other color signal Q, which is due to the reproduced color signal I the transverse polarization is mixed. On the other hand, the correction circle 61b will Color signal I via a polarity converter or polarity reverser 62a for the same reason fed. The polarity converters 62a and 62b do not only convert the amplitudes of the respective color signals I ume certain amplitude, but lead them to the correction circles 61a and 61b after conversion the polarity continues.

The output signals of the correction circuits 61a and 61b are fed to a mixer 58 supplied. For a display of the vertical synchronization indices 44a, 44b, 44c .... on the recording medium 4 shown in Fig. 5, a lamp 63 outgoing continuous light beam 64 approximately on the middle part of the Recording medium 4 directed. The transmitted light becomes after transformation into electrical signals by means of a photomultiplier 65 to a synchronization signal generator 66 supplied. The signal applied to the sync signal generator 66 has a frequency of BO Hz. The sync signal generator 66 generates a vertical Synchronization signal and a horizontal synchronization signal on the basis of the aforementioned signal of 60 Hz and forwards the respective signals to the mixer 58 next.

In the mixer 58 are to be forwarded to a television picture receiver Television signals generated on the basis of all input signals and sent to the output 67 given.

The vertical sync signal and / or the horizontal sync signal ignal (generated by sync signal generator 66) controls the sampling frequency of the scanning electron beam in the cathode ray tube 52, with a supply to the energy source 53 and the energy source 68 of the drive mechanism 51 takes place. In addition, the signal or signals are used to control the transport speed of the recording medium 4 or the energy source 68 is used.

Two kinds of signals to be recorded are recorded after enveloping the carrier wave at a higher frequency than that of the sampling frequency of the electron beam 8b has been modulated in accordance with a signal intensity and after the other wrapping accordingly the other signal intensity has been modulated. The respective signals are thus sequentially recorded on the recording medium recorded, the density of the recording parts of the respective signals increasing changes according to the type of signal and the signal intensity. It follows from this that the respective signals can be distinguished by the difference of the Reproduction signal intensities at the time of reproduction is made usable so that there is no risk of erroneous signal reproduction, as the respective Signals simply by finding and sensing the reproduced signal by means of simple detector circuit can be reproduced, in particular by Finding and feeling the wrappings on both sides. With the help of the envelope curve detectors the playback device according to the invention is much simpler than the conventional ones Devices that require a synchronization detector circuit.

Because the phases of the sampling pulse at the beginning of the horizontal scanning of the electron beam 8b are forcibly aligned, are the recording parts of the respective signals on the recording medium approximately in the longitudinal direction thereof aligned. It follows that it is not necessary to use the recording line to follow closely during playback (track). The recorded signals can precisely tracked, even if the point and spot size of the Playback beam changes on the recording medium.

Referring to Figure 8, another preferred embodiment is one in accordance with the invention Device for the monochromatic recording of color television signals on a A medium sensitive to radiation energy is shown in the case of an FM modulator 80 is arranged between the circle 30 and the adder 27b. The modulator 80 generates a carrier wave with a frequency corresponding to the intensity of the Signals according to FIG. 2, which is supplied by the circuit 30. Step into this carrier wave the I signal part and the Q signal part in sequence (see FIG. 9), since the signal I and the signal Q are fed from circuit 30 to FM modulator 80 in turn will. Since the frequency of the I signal part is the signal component added by the circle 29 contains, the result is a frequency which is higher than the frequency of the Q signal part. With this arrangement, therefore, the frequency of the I signal part changes within a range from 5.5 to 6.5 MHz corresponding to the intensity of signal I, while the frequency of the Q signal part is within a range of 4.4 to 5.4 MHz according to the intensity of the signal Q changes. The difference of approx. 1 MHz between the frequency of the I signal part and the frequency of the Q signal part is based on the signal component which is added to the signal I by the circle 29 is.

Since the FM modulator 80 is used in this embodiment, this generates a carrier wave whose phases are at the beginning of the horizontal scanning of the electron beam 8b are always the same, so that it is not necessary to follow the recording line during playback. A circle can be used as a modulator 4, which serves as generator 31, can be used. The signals of the circle 30 are thus fed to the terminal 37 of the circuit according to Fiig.4, during the Terminal 39 of the phase-locked pulse Pc is supplied, which has a frequency of 15.75 kHz and is generated by the pulse generator 24. It is thus on the one with the Terminal 38 connected to adder 27b generates a pulse which has a frequency which corresponds to the signal intensity at connection 37.

This pulse is phase locked by the applied to terminal 39 Pulse controlled so that the phases at the beginning of the horizontal scanning of the electron beam 8b are always the same.

The medium on which information is recorded with such an arrangement is shown in Fig. 10a and Fig. 10b. This recording medium 4 is provided with picture-like frames 40a, 40b, 40c of the brightness signal (due to the Electron beam 8a) and with picture-like frames 41a, 41b, 41c .... of the two Kinds of color signals I and Q are provided in the same way as the medium according to FIG FIG. 5, on which the recordings are made with the arrangement according to FIG. 1.

In the picture-like frames 41a, 41b, 41c .... of the two types of Color signals 1 and Q are carrier waves as a multitude of light and shadow spots recorded transversely to the recording medium 4 according to FIG. 10b. In Fig. 10b is the Half frequency of the carrier wave shown in white, while the other half frequency shown in black. Since the two types of color signals I and Q of the series after modulating the electron beam 8b, they occur one after the other across the Recording medium on and there the phases of the test and switching pulse constantly are controlled, the recording parts of the respective signals are along the Aligned recording medium. Intervals between light and shadow of the carrier wave in the respective recording parts not only differ greatly between the I signal part and the Q signal part, but also according to the respective Signal intensity. The light and shadow areas of the carrier wave are roughly longitudinal aligned with the recording medium 4, since the phases of the carrier wave at the beginning of the horizontal scanning of the electron beam Bb are constantly controlled in such a way that that they are the same.

The reproducing apparatus shown in Fig. 11 is used to To reproduce color television signals of the recording medium 4 as shown in FIGS. 10a and 10b. This reproducing apparatus differs from that of FIG. 6 in that a Limiter 81 for converting the playback signal to the photomultiplier 56 into a Constant amplitude signal and a FM demodulator 82 for demodulating the frequency of the output signal of the limiter 81 between the amplifier 59 and the envelope detectors 60a and 60b are arranged.

Because cross-polarization phenomena in the process of reproduction If the FM signals of the recording medium do not occur, the correction circuits can 61a and 61b and the polarity converters 82a and 62b of the arrangement according to FIG. 6 in Failure to come. In the case of the arrangement according to FIG. 11, that shown in FIG. 9 is therefore used Signal passed from limiter 81 to FM demodulator 82. The signal according to FIG. 2, which by demodulating said signal by the FM demodulator 82 is obtained is supplied to the envelope detectors 60a and 60b.

The signals forwarded by the mixer 58 to the output 67 are color television signals transmitted to a television picture receiver or the like therein Type are supplied, as in the device according to FIG. 6.

One of the advantages of recording color television signals under Use of a frequency modulation of a carrier wave consists in that in the Playback signal no noise is mixed in.

Claims (24)

Claims 1. Method of monochromatic recording of a variety of Signals on a recording medium sensitive to radiation energy, characterized in that a) periodically a beam with a certain radiation energy is scanned across on or to the recording medium, b) a plurality of to be recorded Signals are interrogated one after the other by means of a sampling pulse with a frequency and are scanned which is higher than the scanning frequency of the beam, c) and that the intensity of the beam is modulated by the interrogated and sampled signal will 2. The method according to claim 1, characterized in that according to the Variety of signals before or after interrogation and sampling of different levels or step heights can be set and that the intensity of the beam by the with the various levels or step heights provided, interrogated and scanned Signal is modulated. 3. The method according to claim 2, characterized in that the phases of the sampling pulse is aligned from sample to sample. 4. The method according to claim 2, characterized in that the 4 order the sampling of two types of signals from field to field reversed which are two kinds of color signals of a color television signal acts. 5. Method of monochromatic recording of a variety of Signals on a radiant energy sensitive recording medium, thereby characterized in that a) periodically a beam with a certain radiation energy transversely is scanned on or to the recording medium, b) a plurality of to be recorded Signals are interrogated one after the other by means of a sampling pulse with a frequency and scanned which is higher than the scanning frequency of the beam, c) different Level or step heights corresponding to the large number of signals before or after the Interrogation or sampling can be set, d) the interrogated or sampled signal, which has different levels or step heights, converted into a carrier wave whose frequency or phase changes according to the intensity, e) and that the intensity of the beam is modulated by the carrier wave. 6. The method according to claim 5, characterized in that the phases of the sampling pulse can be aligned from sample to sample. 7. The method according to claim 5, characterized in that the phases aligned with the carrier wave at the beginning of each scan. 8. The method according to claim 5, characterized in that it is in the signals to be recorded by two types of color signals of a color television signal acts and that the order of interrogation and scanning of the two types of Signals is reversed from field to field. 9. Device for monochromatic recording of a variety of Signals from a recording medium sensitive to radiant energy, marked a) by means of continuous or intermittent Shifting and transporting the recording medium in the longitudinal direction of the same, b) by means of generating a beam with a certain radiation energy, c) by means for periodically scanning the beam transversely onto or to the recording medium, d) by means by which the plurality of signals to be recorded in the series after being interrogated or scanned at a frequency that is higher than that Scanning frequency of the beam, e) and by means by which the queried or sampled signals are fed to the means for generating the beam. 10. A device for monochromatic recording of a plurality of signals on a recording medium sensitive to radiation energy, characterized a) by means for continuous or intermittent displacement and transporting the recording medium in the longitudinal direction thereof, b) therethrough Means for generating a beam with a certain radiation energy, c) by Means through which the plurality of signals to be recorded are sequentially with a frequency which is higher than the sampling frequency can be queried or sampled of the beam, d) by means for setting different levels and step heights corresponding to the plurality of signals to be recorded, e) by means, by which the signals of the series having different levels and step heights after being queried or are scanned which is higher than the scanning frequency of the beam, f) and by means by which the interrogated and sampled signals are centered to generate the beam. 11. The device according to claim 10, characterized in that means to generate a sampling pulse with the same phases from sample to sample of the beam are provided. 12. The device according to claim 10, characterized in that means to reverse the order of interrogation and sampling of two types of signals from field to field, with S ch for these signals to be recorded are two types of color signals of a color television signal. 13. Device for monochromatic recording of a plurality of signals on a recording medium sensitive to radiation energy, characterized a) by means for continuous or intermittent displacement and transporting the recording medium in the longitudinal direction of the same, b) by Means for generating a beam with a certain radiant energy, c) by Means through which the plurality of signals to be recorded are sequentially with a frequency that is higher than the scanning frequency of the beam, d) by means for setting different levels and step heights corresponding to the plurality of signals to be recorded, e) by means, by which the signals of the series, which have different levels and step heights after being queried or are scanned which is higher than the scanning frequency of the beam, f) by means for converting the interrogated and sampled signals into carrier waves, whose frequency or phase changes according to the intensity, g) and through Means for supplying the carrier waves to the means for generating the beam. 14. The device according to claim 13, characterized in that means provided that a sampling pulse with the same phases of sampling too Generate a scan of the beam. 15. The device according to claim 13, characterized in that means provided for converting the interrogated and sampled signals into carrier waves are whose frequency or phase changes according to the intensity and that Means are provided through which the phases of the carrier waves at the beginning of a be made equal to each beam scan. 16. The device according to claim 13, characterized in that means to reverse the order of interrogation and sampling of two types of signals from field to field are provided, whereby it is the signals to be recorded are two types of color signals of a color television signal. 17. Recording medium with a variety of monochromatic signals, characterized by a plurality of picture-like frames in which a plurality of signals sequentially recorded across the recording medium, which in Longitudinal direction of the recording medium are approximately aligned. 18. Recording medium with a variety of monochromatic signals, characterized by a plurality of longitudinally aligned image-like images Frame in which a plurality of signals in sequence across the recording medium are recorded with the recording densities of the recording parts correspondingly change the signal type. 19. Recording medium according to claim 18, characterized in that that the recording parts of the plurality of signals approximately in the longitudinal direction in are aligned with the respective picture-like frames, 20. Recording medium according to claim 18, characterized in that the locations of the recording parts the multitude of signals move from frame to frame within the picture-like frame change. 21. Recording medium with a variety of monochromatic signals, characterized in that a plurality of longitudinally arranged picture-like Frame is provided within the transverse direction a plurality of signals is recorded in order that the recording parts of the respective signals consist of a multitude of light and shadow spots in the direction mentioned and that the intervals of the light and shadow spots are in said direction in the respective recording parts according to the type and intensity of the Change signal. 22. Recording medium according to claim 21, characterized in that that the recording parts of the plurality of signals approximately in the longitudinal direction in aligned with the picture-like frame. 23. Recording medium according to claim 21, characterized in that that the light and shading or shadow areas roughly in the longitudinal direction in are aligned with the recording parts. 24. Recording medium according to claim 21, characterized in that that the locations of the recording parts of the plurality of signals in the picture-like Frames change from frame to frame.