US1839455A - Signaling - Google Patents

Signaling Download PDF

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US1839455A
US1839455A US1839455DA US1839455A US 1839455 A US1839455 A US 1839455A US 1839455D A US1839455D A US 1839455DA US 1839455 A US1839455 A US 1839455A
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energy
tube
modulated
interrupter
signaling
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N5/00Details of television systems
    • H04N5/38Transmitter circuitry for the transmission of television signals according to analogue transmission standards
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N5/00Details of television systems
    • H04N5/38Transmitter circuitry for the transmission of television signals according to analogue transmission standards
    • H04N5/40Modulation circuits

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  • WhlCll I fulfill by interposing between the picture and the photoelectric means responsive to the light energy therefrom a chopper wheel which interrupts the light energy at a high frequency.
  • the resulting high frequency electrical energy may be amplified through transformer coupled amplification stages, and to again provide a continuous modulated wave the high frequency energy may be rectified in a suitable detector tube.
  • a sensitive mechanical relay may be used to control the output of the transmitter, preferably by changing the bias of one of the transmitter tubes.
  • short waves energy is employed for the signaling carrier it becomes possible to interrupt the transmission at frequencies much higher than 60 cycles, and to so, do is advantageous because it greatly improves the quality of the picture reproduced at the receiving station.
  • frequencies of the order of 1000 or 2000 cycles it is not possible to employ a mechanical relay, and to overcome this difliculty is a further object of my invention, which I accomplish by utilizing an electron emission tube, to the input circuit of which transmission energy is fed, while the superimposed modulated and interrupter energies are applied to the control electrode of the tube to vary its bias.
  • This bias is chosen so to make the tube conductive only when it exceeds a predetermined mean value in amplitude, and while the transmission is interrupted at the frequency of the interrupter current, the duration of the signaling period during each cycle of the interrupter current depends upon the light intensity of the picture at that instant.
  • Figure 2 is a wiring diagram for an em bodiment of my invention in simplest form
  • Figure 3 is a. modification employing a chopper wheel
  • Figure 5 is a graph explanatory of Figure 4.
  • wave 2 is continuous electrical energy modulated in accordance with the light intensity of the portion of a picture being scanned.
  • the wave 4 is alternating energy, which may range in frequency anywhere from twentyfive to several thousand cycles per second.
  • the wave 4 is shown superimposed on the modulated wave 2, and it is obvious, if the superimposed energy s applied to a relay device having a holding or trip potential indicated by the line 6, that the relay will be actuated during periods the lengths of which are dependent upon the value of the modulated energy represented by the wave 2.
  • the interrupter wave is triangular in shape the relation will be exactly linear, but even employing a sinusoidal wave the results are sufii'ciently accurate to produce very excellent pictures.
  • FIG. 2 there is a photoelectric cell 10, which varies the flow of current from a battery 12 through a resistance 14, and so varies the potential across the input circuit of the tube 16.
  • the amplified output energy is proportional to the light intensity, and is coupled to a. suitable relay 18 by means of a coupling resistance 20.
  • Interrupter energy is supplied by the leads 22 through a transformer 24 to the relay circuit.
  • a battery 26 and resistance 28 are employed to properly bias the relay.
  • the relay is made to key the transmitter by loading the bias of a desired one of the amplifier tubes in the transmitter, indicated at 30. As is evident from the diagram, with the relay closed the bias applied is that of the battery 32, while with the relay open the bias is that of the battery 34. A resistance 36 is provided to prevent one battery from short circuiting the other.
  • the bias potential is applied to the control electrode of the tube 30 through a radio frequency choke 38, while the radio frequency may be fed from the preceding stage through a radio frequency condenser 40.
  • Figure 3 which,-generally speaking, is similar to the arrangement shown in Figure 2, but in this case a chopper wheel 42-has been shown in the path of the light ray impinging on the photo electric cell 10. Numerous slots or teeth are cut in this wheel, and when it is rapidly rotated the light energy is interrupted at any desired high frequency, in conuence of which the output of the amplifying tube 16 is high frequency energy, rather than slowly pulsating direct current.
  • the modulated high frequency energy may be readily amplified by transformer coupled electron emission tube stages, such as the stage 44, and converted into pulsating electrical energy by rectification in a suitable detector tube 46.
  • the modulated electrical energy and interrupter energy are superimposed and applied to a properly biased relay 18, which serves to load the bias of an amplifier tube 30 of the transmitter.
  • the bias of the tube 30 is provided from leads 50, across which a potentiometer 52 is connected.
  • a potentiometer 52 When the relay is open the potential of the line 50 is applied to the control electrode of the tube 30, while when the relay is closed the potential at the point 54 is applied thereto.
  • a resistance 56 is provided to prevent the relay from short circuiting the potentiometer.
  • the connections to the potentiometer 52 may be suitably interchanged.
  • FIG. 4 The first part of this arrangement is quite similar to that shown in Figure 3, there being a chopper wheel 42 for interrupting the light energy from a picture mounted on a drum 48, the applied and reflected light energies being suitably focused and concentrated by appropriate lenses.
  • the high frequency modulated electrical energy is amplified in one or more amplifier stages 44, and rectified in a detector tube 46.
  • a source of interrupter energy 62 is superimposed on the output of the detector tube 46, and the superimposed wave may be amplified, if desired, in an amplifying tube 64.
  • the keying relay is indicated at 66, and to its in ut circuit a source of low powered radio requency energy 68 is coupled, through a transformer 70 and a radio frequency condenser 72.
  • the steady bias of the tube 66 is provided by means of a bias battery 74, which serves to overcome the anode potential of the tube 64, as well as to establish the normal bias of the tube 66.
  • This bias is varied in accordance with the output of the tube 64, that is, in aconly becomes conductive with the aid of the superlmposed wave, and therefore passes'radio frequency energy from the oscillator 68 only during the peaks of the interrupter wave, and for a duration of time dependent upon the magnitude of the modulated energy in the output of the detector tube 46, as was I already explained in connection with Figure 1.
  • Figure 5 is a graph of the characteristic of the tube 66, showing the plate current plotted as a function of the grid potential. It will be seen that at the point 100, where the characteristic curve 102 and the axis of grid potential 104 cross, is a point above which the tube is conductive, and below which it is not. The tube is operated around the point 100 as a mean potential, and it thereby keys the transmission energy from the oscillator 68.
  • the interrupted radio frequency output of the tube 66 may be amplified in a tube 80, which preferably is operated as a limiting device, in order that its output may be an interrupter radio frequency of constant amplitude.
  • the energy is thereafter amplified in a power amplifier 82, and radiated from a suitable antenna circuit 84.
  • the power amplifier ,82 may be operated with limiting characteristics, so as to aid the action of the tube 80, or even dispense therewith.
  • the picture may be printed by known means of either the inking, pyro recording, photographic, or other suitable type.
  • the method of transmitting pictures which includes modulating electrical energy in accordance with the light intensity of the picture, superimposing alternating interrupter energy of constant frequency and amplitude on the modulated energy, and radiating signaling energy only when the superimposed wave exceeds a predetermined mean value in amplitude.
  • the method of transmitting pictures which includes chopping the light energy at high frequency, modulating electrical energy in accordance with the chopped light intensity, amplifying the resulting high frequency electrical energy, rectifying it, superimposing thereon alternating interrupter energy of constant frequency and amplitude, and radiating signaling energy only when the superimposed wave exceeds a predetermined value in amplitude.
  • the method of transmitting pictures which includes chopping the light at high frequency, modulating electrical energy in accordance with the chopped light intensity," amplifying the resulting high frequency electrical energy, rectifying it, superimposing thereon alternating interrupter energy of constant frequency and amplitude, applying a radio frequenc signaling wave to the control electrode 0 an electron emission tube, so biasing the control electrode of the tube in response to the superimposed wave that the tube is conductive only when the superimposed wave exceeds a predetermined mean value in amplitude, and amplifying and radiating the tube output.
  • An arrangement for picture transmission comprising photo-electric means for modulatin electrical energy in accordance with the light intensity of the transmitted picture, a source of alternating interrupter energy of consant frequency and amplitude, means to superimpose the modulated and in terrupter energies, a source of signaling energy, and means for causing the signaling energy to flow only When the superimposed wave exceeds a predetermined mean value in amplitude.
  • An arrangement for picture transmission comprisingv a chopper wheel for the transmitted light, photoelectric means for modulating electrical energy in accordance with the chopped light intensity, means to amplify the modulated energy, means to rectify the amplified current, a source of alternating interrupter energy of constant frequency and amplitude, means to superimpose the rectified and interrupter energies, a source of signaling energy, and means for radiating the signaling energy only when the superimposed wave exceeds a predetermined mean value in amplitude.
  • An arrangement for picture transmission comprising a chopper wheel for the transmitted light, photoelectric means for modulating electrical energy in accordance with the chopped light intensity, means to amplify the modulated energy, means to rectify the amplified energy, a source of alternating interrupter energy of constant frequency and amplitude, means to superimpose the rectified and interrupter energies, a source of radio frequency signaling energy, an electron emission tube, means to supply the signaling energy to the tube, means for biasing the control electrode of the tube in response to the superimposed wave to make the tube conductive only when the superimposed wave exceeds a predetermined mean value in amplitude, and means to amplify and radiate the resulting interrupted tube output.
  • An arrangement for picture transmission comprising means for modulating electrical energy in accordance with the light intensity of the picture to be transmitted, means for amplifying said modulated fre-. quency, means for converting said modulated frequency into impulses of constant duration and varying amplitude, a source of alternating interrupter enregy of constant frequency and amplitude, means to superimpose the modulated energy and interrupted energy, a source of signaling energy, and means for causing the signaling energy to flow only when the superimposed wave exceeds a predetermined mean value in amplitude.
  • the method of transmitting pictures which includes the step of producing light rays, the intensity of which is characteristic of the picture to be transmitted, interrupting said rays at a constant frequency, producing energy pulses characteristic of said rays, pro

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  • Multimedia (AREA)
  • Signal Processing (AREA)
  • Image-Pickup Tubes, Image-Amplification Tubes, And Storage Tubes (AREA)

Description

1932- E F. w. ALEXANDERSON 1,339,455
SIGNALING Original Filed June 16, 1928 2 Sheets-Sheet 1 /4 F Mnn/mnA \l \I" lNVENTOR 5T F- ALEXANDERSON fi m flda o TTORNEY Jan. 5, 1932. EIF. w. ALEXANDERSON 1,339,455
SIGNALING Original Filed June 16, 1928 2 Sheets-Sheet 2 NVENTOR ERNST F.W. ALEXANDERSD f/ fi a A TORNEY Patented Jan. 5, 1932 I UNITED STATES PATENT OFFICE ERNST F.. W. ALEXANDERSON, F SCHENECTADY, NEW YORK, ASSIGNOR TO RADIO COB- PORATION OF AMERICA, A CORPORATION OF DELAWARE SIGN ALING Application filed .Tune 16, 1928, Serial No. 285,927. Renewed August 23, 1929.
' quality. It is sometimes desirable, however,
to transmit signaling energy of constant intensity, but so interrupted into marking and spacing periods that the reproduced picture, while not continuously shaded, will, nevertheless, present to the eye apparent shading similar to that which would be produced by modulated signaling. The advantage of on and ofl' signaling is that of simplification of apparatus, and more especially the fact that regular code transmission apparatus may be employed for picture work.
From what has so far been said it is obvious that there is needed a method of changing continuous electrical energy of modulated intensity into interrupted signallng energy of constant intensity such that the duration of the signaling periods is substantially proportional to the intensity of the modulated energy, and to provide such a method, and means for its practice, is a primary object of my invention. For this purpose I superimpose alternating energy of constant frequency and amplitude, which may be termed interrupter energy, on the modulated energy, and by means of a sensitive mechanical relay, or a properly ad usted electron relay, cause the signaling energy to flow only when the superimposed wave exceeds a predetermined mean value in ampli tude.
For the purpose of modulating electrical energy in accordance with the light intensity of the picture and of thereafter ampl1fymg the modulated energy it is sometlmes advantageous to have the electrical energy in the form of high frequency alternating energy, rather than continuous current, and to provide such hight frequency modulated energy is a further object of my inventlon, WhlCll I fulfill by interposing between the picture and the photoelectric means responsive to the light energy therefrom a chopper wheel which interrupts the light energy at a high frequency. The resulting high frequency electrical energy may be amplified through transformer coupled amplification stages, and to again provide a continuous modulated wave the high frequency energy may be rectified in a suitable detector tube.
If the frequency of the superimposed interrupter energy does not exceed a frequency of cycles per second a sensitive mechanical relay may be used to control the output of the transmitter, preferably by changing the bias of one of the transmitter tubes. When short waves energy is employed for the signaling carrier it becomes possible to interrupt the transmission at frequencies much higher than 60 cycles, and to so, do is advantageous because it greatly improves the quality of the picture reproduced at the receiving station. However, with frequencies of the order of 1000 or 2000 cycles it is not possible to employ a mechanical relay, and to overcome this difliculty is a further object of my invention, which I accomplish by utilizing an electron emission tube, to the input circuit of which transmission energy is fed, while the superimposed modulated and interrupter energies are applied to the control electrode of the tube to vary its bias. This bias is chosen so to make the tube conductive only when it exceeds a predetermined mean value in amplitude, and while the transmission is interrupted at the frequency of the interrupter current, the duration of the signaling period during each cycle of the interrupter current depends upon the light intensity of the picture at that instant.
My invention is described more in detail in the following specification, which is accompanied by drawings in which Figure 1 is a drawing explanatory of my invention;
Figure 2 is a wiring diagram for an em bodiment of my invention in simplest form;
Figure 3 is a. modification employing a chopper wheel,
Figure 5 is a graph explanatory of Figure 4.
Referring to Figure 1 the value of superimposed modulated and interrupter energies is shown plotted as a function of time. The
wave 2 is continuous electrical energy modulated in accordance with the light intensity of the portion of a picture being scanned. The wave 4 is alternating energy, which may range in frequency anywhere from twentyfive to several thousand cycles per second. In the drawings the wave 4 is shown superimposed on the modulated wave 2, and it is obvious, if the superimposed energy s applied to a relay device having a holding or trip potential indicated by the line 6, that the relay will be actuated during periods the lengths of which are dependent upon the value of the modulated energy represented by the wave 2. If'the interrupter wave is triangular in shape the relation will be exactly linear, but even employing a sinusoidal wave the results are sufii'ciently accurate to produce very excellent pictures.
Referring to Figure 2 there is a photoelectric cell 10, which varies the flow of current from a battery 12 through a resistance 14, and so varies the potential across the input circuit of the tube 16. The amplified output energy is proportional to the light intensity, and is coupled to a. suitable relay 18 by means of a coupling resistance 20. Interrupter energy is supplied by the leads 22 through a transformer 24 to the relay circuit. A battery 26 and resistance 28 are employed to properly bias the relay.
The relay is made to key the transmitter by loading the bias of a desired one of the amplifier tubes in the transmitter, indicated at 30. As is evident from the diagram, with the relay closed the bias applied is that of the battery 32, while with the relay open the bias is that of the battery 34. A resistance 36 is provided to prevent one battery from short circuiting the other. The bias potential is applied to the control electrode of the tube 30 through a radio frequency choke 38, while the radio frequency may be fed from the preceding stage through a radio frequency condenser 40.
Attention is now directed to Figure 3, which,-generally speaking, is similar to the arrangement shown in Figure 2, but in this case a chopper wheel 42-has been shown in the path of the light ray impinging on the photo electric cell 10. Numerous slots or teeth are cut in this wheel, and when it is rapidly rotated the light energy is interrupted at any desired high frequency, in conuence of which the output of the amplifying tube 16 is high frequency energy, rather than slowly pulsating direct current.
' The modulated high frequency energy may be readily amplified by transformer coupled electron emission tube stages, such as the stage 44, and converted into pulsating electrical energy by rectification in a suitable detector tube 46. As in Figure 2, the modulated electrical energy and interrupter energy are superimposed and applied to a properly biased relay 18, which serves to load the bias of an amplifier tube 30 of the transmitter.
In this case the bias of the tube 30 is provided from leads 50, across which a potentiometer 52 is connected. When the relay is open the potential of the line 50 is applied to the control electrode of the tube 30, while when the relay is closed the potential at the point 54 is applied thereto. A resistance 56 is provided to prevent the relay from short circuiting the potentiometer. Of course, if it is desired to invert the marking and spacing periods the connections to the potentiometer 52 may be suitably interchanged.
It has already been mentioned that if the interruptions in transmission are to take place at higher frequencies than, say 60 cycles per second, it is preferable to employ an electron relay, rather than a mechanical relay, and such an arrangement is indicated in Figure 4. The first part of this arrangement is quite similar to that shown in Figure 3, there being a chopper wheel 42 for interrupting the light energy from a picture mounted on a drum 48, the applied and reflected light energies being suitably focused and concentrated by appropriate lenses. The high frequency modulated electrical energy is amplified in one or more amplifier stages 44, and rectified in a detector tube 46. A source of interrupter energy 62 is superimposed on the output of the detector tube 46, and the superimposed wave may be amplified, if desired, in an amplifying tube 64. The keying relay is indicated at 66, and to its in ut circuit a source of low powered radio requency energy 68 is coupled, through a transformer 70 and a radio frequency condenser 72. The steady bias of the tube 66 is provided by means of a bias battery 74, which serves to overcome the anode potential of the tube 64, as well as to establish the normal bias of the tube 66. This bias is varied in accordance with the output of the tube 64, that is, in aconly becomes conductive with the aid of the superlmposed wave, and therefore passes'radio frequency energy from the oscillator 68 only during the peaks of the interrupter wave, and for a duration of time dependent upon the magnitude of the modulated energy in the output of the detector tube 46, as was I already explained in connection with Figure 1.
This may be further explained by refer ring to Figure 5, which is a graph of the characteristic of the tube 66, showing the plate current plotted as a function of the grid potential. It will be seen that at the point 100, where the characteristic curve 102 and the axis of grid potential 104 cross, is a point above which the tube is conductive, and below which it is not. The tube is operated around the point 100 as a mean potential, and it thereby keys the transmission energy from the oscillator 68.
Again adverting to Figure 4 it will be seen that the interrupted radio frequency output of the tube 66 may be amplified in a tube 80, which preferably is operated as a limiting device, in order that its output may be an interrupter radio frequency of constant amplitude. The energy is thereafter amplified in a power amplifier 82, and radiated from a suitable antenna circuit 84. If desired, the power amplifier ,82 may be operated with limiting characteristics, so as to aid the action of the tube 80, or even dispense therewith.
It will be understood, of course, that at the receiver the picture may be printed by known means of either the inking, pyro recording, photographic, or other suitable type.
I claim: 7
1. The method of transmitting pictures which includes modulating electrical energy in accordance with the light intensity of the picture, superimposing alternating interrupter energy of constant frequency and amplitude on the modulated energy, and radiating signaling energy only when the superimposed wave exceeds a predetermined mean value in amplitude.
2. The method of transmitting pictures which includes chopping the light energy at high frequency, modulating electrical energy in accordance with the chopped light intensity, amplifying the resulting high frequency electrical energy, rectifying it, superimposing thereon alternating interrupter energy of constant frequency and amplitude, and radiating signaling energy only when the superimposed wave exceeds a predetermined value in amplitude.
3. The method of transmitting pictures which includes chopping the light at high frequency, modulating electrical energy in accordance with the chopped light intensity," amplifying the resulting high frequency electrical energy, rectifying it, superimposing thereon alternating interrupter energy of constant frequency and amplitude, applying a radio frequenc signaling wave to the control electrode 0 an electron emission tube, so biasing the control electrode of the tube in response to the superimposed wave that the tube is conductive only when the superimposed wave exceeds a predetermined mean value in amplitude, and amplifying and radiating the tube output.
4. An arrangement for picture transmission comprising photo-electric means for modulatin electrical energy in accordance with the light intensity of the transmitted picture, a source of alternating interrupter energy of consant frequency and amplitude, means to superimpose the modulated and in terrupter energies, a source of signaling energy, and means for causing the signaling energy to flow only When the superimposed wave exceeds a predetermined mean value in amplitude.
5. An arrangement for picture transmission comprisingv a chopper wheel for the transmitted light, photoelectric means for modulating electrical energy in accordance with the chopped light intensity, means to amplify the modulated energy, means to rectify the amplified current, a source of alternating interrupter energy of constant frequency and amplitude, means to superimpose the rectified and interrupter energies, a source of signaling energy, and means for radiating the signaling energy only when the superimposed wave exceeds a predetermined mean value in amplitude.
6. An arrangement for picture transmission comprising a chopper wheel for the transmitted light, photoelectric means for modulating electrical energy in accordance with the chopped light intensity, means to amplify the modulated energy, means to rectify the amplified energy, a source of alternating interrupter energy of constant frequency and amplitude, means to superimpose the rectified and interrupter energies, a source of radio frequency signaling energy, an electron emission tube, means to supply the signaling energy to the tube, means for biasing the control electrode of the tube in response to the superimposed wave to make the tube conductive only when the superimposed wave exceeds a predetermined mean value in amplitude, and means to amplify and radiate the resulting interrupted tube output.
7. An arrangement for picture transmission comprising means for modulating electrical energy in accordance with the light intensity of the picture to be transmitted, means for amplifying said modulated fre-. quency, means for converting said modulated frequency into impulses of constant duration and varying amplitude, a source of alternating interrupter enregy of constant frequency and amplitude, means to superimpose the modulated energy and interrupted energy, a source of signaling energy, and means for causing the signaling energy to flow only when the superimposed wave exceeds a predetermined mean value in amplitude.
8. The method of transmitting pictures which includes the step of producing light rays, the intensity of which is characteristic of the picture to be transmitted, interrupting said rays at a constant frequency, producing energy pulses characteristic of said rays, pro
ducing an interrupter wave, superimposing said pulses and said wave, and utilizing said superimposed energy to produce con-v stant amplitude high frequency oscillations,
the duration of which are a function of the amplitude of the signal modulated energy.
ERNST F. W. ALEXANDERSON.
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