US1950406A - Method and apparatus for controlling electrical waves - Google Patents
Method and apparatus for controlling electrical waves Download PDFInfo
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- US1950406A US1950406A US361030A US36103029A US1950406A US 1950406 A US1950406 A US 1950406A US 361030 A US361030 A US 361030A US 36103029 A US36103029 A US 36103029A US 1950406 A US1950406 A US 1950406A
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03C—MODULATION
- H03C3/00—Angle modulation
- H03C3/02—Details
- H03C3/04—Means in or combined with modulating stage for reducing amplitude modulation
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- This invention relates to a method and apparatus for controlling electrical waves or currents of one range of frequency in accordance with waves or currents of another and lower range of frequency, and more particularly to the application of such control to the transmission and reception of signals by radio, carrier current and the like.
- the high frequency currents or waves in accordance with the signals to be transmitted, such as voice currents or the like, thereby producing changes of amplitude or frequency, or both, in the high frequency or carrier wave.
- modulation produces new waves or currents, commonly called side bands, having a frequency range extending above and below the carrier frequency by an amount equal to the highest modulating or signal frequency.
- the side bands may include all frequencies lying within the limit of jrifa, where fr is the carrier frequency and fa the highest modulating or signal frequency.
- phase shift introduced in the carrier wave shall not in any event exceed 180", and which may be held within limits as small as may be desired, as for example or degrees.
- Figure 1 shows diagrammatically a simple form of radio transmitter according to my invention.
- FIG. 2 shows a somewhat different form of transmitting apparatus according to my invention.
- FIG. 3 shows still another form of transmitter according to my invention.
- Figure 4 is a vector diagram illustrating the operation of my invention.
- FIGS 5, 6 and 7V show diagrammatically-variousforms of receivers according to my invention.
- My invention in its fundamental aspect, contemplates modifying the phase of the high frequency carrier wave in such a manner that the phase displacement from normal is at any instant dependent on the amplitude of the current representing the signals to be transmitted, herein termed signal currents.
- signal currents This is achieved by combining a wave, the phase and amplitude of which is constant, with another of the samexfre quency, the phase and amplitude of whichis varied uncle: the control of the signals in such manher as to produce a resultant of constant amplitude but of varying phase which may be transmitted.
- Reception may be obtained from the transmitted wave by a reversal of the process, that is, by combining with the received wave another wave of the same frequency and of constant amplitude and phase, the resultant of which may be detected and will yield currents corresponding to the original signal currents to be transmitted.
- 0 designates diagrammatically an oscillator capable of delivering high frequency oscillations of constant amplitude and frequency to the input points A and B of the four-element network Z1, Z2, Z3 and Z4. It will be noted that these four elements are connected in series with each other in a closed loop.
- the input point A is taken intermedlate impedances Z1 and Z3, and input point B intermediate impedances Z2 and Z4.
- the output circuit is connected across points D and E, point D being located between impedances Z1 and Z2, and point E being located between Z3 and Z4.
- the network as seen from the input or output terminals may therefore be regarded as being made up of two branches in parallel with each other, each branch being in turn made up of two elements in series.
- Impedances Z1 and Z2 may be resistances, inductances, capacities, or combinations thereof, but both should be identical in magnitude and character so that the voltage drops through each due to a voltage impressed between points B and A, and are equal and in phase, whereby they may be represented by vectors Em: and EDA in Fig. 4, Ego and Em. represening the impedance drop in Z2 and Z1, respectively, due to the current flowing in Z2 and Z1, as a result of the impressed voltage.
- Impedances Z3 and Z4 may be any suitable impedances having phase angles d ffering by 90.
- Z3 may be a reactance, such as a condenser or inductance, the resistance being kept as low as possible, and Z4 being a resistance, the reactance of which is kept as low as possible.
- Either of the impedances Z3 and Z4 is arranged to vary in magnitude under the control of the signal currents of low frequency.
- Fig. 1 I have shown Z3 as a condenser and Z4 as a simple form of carbon transmitter, the resistance of wh ch varies in accordance with sound waves impinging thereon, but other arrangements may be used, as will hereafter be more particularly explained.
- locus of point B is on the circumference of a semi-circle drawn about point D with a radius equal to DA, and that regardless of the location of point E r'n the locus, the fundamental requirements are satisfied.
- the vector DA of Fig. 4 represents the potential difference of constant amplitude and phase, referred to in the method claims. Although represented as a stationary vector to represent magnitude and relative phase; this is a rotating vector, in the sense that it generates by with uniform angular velocity, the peripheral "end of which traces the semicircle BEA of Fig. 4.
- Vector AE represents the potential difference Lam, and is the vector referred to in the method claims, as the vector drawn from the peripheral end of vector DA, to a point on the circumference of the circle traced by vector DA'in its rotation.
- Vector DE is the sum of the above mentioned vectors DA and AE and necessarily remains constant in magnitude but varies in phase, as the magnitude of AE changes, and its quadrature relationship to EB is maintained.
- Em is represented by a vector of constant length having a phase relation which may be displaced by an angle 0, which cannot exceed 90 in either direction of shift, and hence the total shift in phase cannot exceed 180".
- R represents the impedance of the element Z4 which is variable
- X the impedance of the element Z3 which is fixed
- R is made equal to X when no sounds are falling upon the microphone
- impedances Z1 and Z2 as inductances
- Z3 as a condenser
- Z4 as a variable resistance transmitter
- I have shown a modified arrangement in which impedances Z1 and Z: are shown as condensers C1 and C2, while Z3 is shown as a fixed resistance R3, and Z4 is a condenser transmitter C4.
- the principle of operation is the same as already described.
- Z1, Z2 and Z: are all condensers, while Z4 is the plate-filament resistance of a suitable vacuum tube amplifier.
- Z1 is a transmitter of any suitable type, the output of which is supplied to the vacuum tube amplifier 17 by means of transformer or other coupling means 16.
- Amplifier 17 comprises an anode 18 a cathode l9 and a control electrode 20, and as these devices are well known in the art and form per se no part of this invention, they are not described in detail.
- a circuit consisting of inductance 25 and capacity 26,-tuned to the high frequency, may be connected in shunt with the input circuit.
- the output circuit may comprise a tuned circuit 24, consisting of inductance 22 and capacity 23, tuned to the high frequency, and a suitable source of plate current 28.
- Circuit 24 offers infinite impedance to the high frequency current, but substantially zero impedance to currents of lower frequencies, so that no audio frequency voltage can be built up between anode 18 and cathode 19 of tube 1'7, the plate circuit of which therefore operates as a variable resistance, varying in accordance with sounds picked up by microphone 15.
- the potential of source 28 should be so large that the anode 18 is always positive with respect to cathode 19.
- a suitable source of power 21 is shown for heating cathode 19, and it may be desirable also to employ some form of stabilization to prevent oscillation of amplifier 17 when the input and output circuits are tuned to the same frequency.
- This may be in the form of a resistance connected in the grid circuit, or may be some form of tube capacity neutralization, all of which are well known. It may be found in certain cases that one or both of the tuned circuits may be omitted without introducing undesirable effects.
- 30 represents the input coil, which may be for example connected in an an-. tenna not shown.
- Coil 30 is coupled to a second coil 31 connected to the control electrode 38 of vacuum tube 35 and connected also through coil 32 and resistance 33 to the cathode 37 of amplifier 35. lfdesired, a tuning condenser 34 may be connected between the cathode37 and control electrode 38.
- the anode 36 is connected to coil 39 to the source of plate supply 49.
- Coil 32 is coupled to'a second coil 40, and resistance 33 and coils 40 and 41 are connected in the input circuit of a second vacuum tube 43, the input circuit of which may be tuned by means of condenser 42 connected between the control electrode 46 and cathode 45.
- Anode 44 is connected to coil 47 for the purpose of permitting the vacuum tube 43 to generate oscillations, as is well known in the art.
- the output circuit of tube 43 is completed through coil 48 and the source of plate supply 49.
- Coils 39 and 48 are coupled to coils 51 and 50, respectively, connected in the input circuit of vacuum tube detector 55, having an anode 56, cathode 57 and control electrode 58.
- Coils 50 and 51 may be tuned by tuning condenser 52.
- Resistance 53, shunting condenser 54 may be provided for causing the tube to operate as a detector.
- a suitable transformer 59 may be provided in the output circuit of tube 55 for supplying the output thereof to any suitable device such, for example, as an amplifier or translating device.
- tube 35 operates as an amplifier
- tube 43 operates as an oscillator, both being tuned to the frequency of the incoming signal.
- the oscillations generated by tube 43 will be of the same frequency as the incoming oscillations impressed on tube 35, that is to say, the oscillator will fall in step with the received signal.
- this coupling, controlled by coils 32 and 40 and resistance 33, should not be made so tight that the phase of the oscillatory currents generated by tube 43 follows the phase of the incoming signals, since tube 43 supplies the oscillations of constant frequency and unvarying phase.
- oscillations are supplied to the input of detector 55 by means of coils 48 and 50, while the amplified signal input is similarly supplied to the input of tube 55 by means of coils 39 and 51.
- the amplitude of oscillator 43 should be so adjusted that the generated oscillations are of substantially the same order of strength as the currents with which they are to be combined. But in any event, the coupling between coils 48 and 50, and 39 and 51, may be adjusted until best results are obtained.
- the detected currents supplied by tube 55 will then correspond to the currents delivered by the microphone or other device in Fig. l, and may be amplified to the extent desired for the particular purpose in view.
- FIG. 6 I have shown a slightly modified arrangement in which the incoming signals are first amplified and in which tube 35 operates as a detector.
- A designates an antenna representing the primary or coupling transformer 60, the secondary of which feeds a suitable frequency amplifier 61, the output of which is fed to the input of detector 35 by means of coupling transformer 62.
- grid leak and condenser 64 and 63 are connected in the input circuit of tube 35 in the manner known in the art, to cause the said tube to operate as a detector; also, coils 39, 48, 50 and 51 are dispensed with and a transformer 65 or other suitable coupling device is provided for supplying the detected currents to any suitable amplifier or other translating device.
- the oscillator 43 is preferably enclosed in a suitable shield indicated by the dotted lines as enclosing ,also certain of the elements of the circuit of tube 43 within the shield.
- Fig. 7 I have shown a slightly further modified form of apparatus in which the same tube operates as detector and oscillator.
- the output of radio frequency amplifier 61 is impressed between one pair of opposite points of a balanced Wheatstone bridge made up of coil 70, tuning condenser 71 and series condensers '72 and 73, while the input of tube 77 is taken off condenser '72.
- the anode '78 is connected through coil 76 and the primary of output transformer 82 through the source of plate current 81 to the cathode 79, while the input circuit is connected between control electrode through grid leak '75 to condenser 72, the opposite side of which is connected to cathode '79.
- This arrangement is similar to that described in United States patent to Pressley 1,560,854, dated November 10, 1925, and permits the tube 7'7 to generate oscillations without such oscillations being radiated from the antenna A.
- the locally generated oscillations are combined with the incoming signals in tube 7'7 and its associated circuits, and the resultant is detected by the said tube.
- a method of controlling a high frequency current in accordance with signal currents of lower frequency which comprises deriving a high frequency potential difference of substantially constant amplitude, but shifting phase, by combining a first potential difference of constant amplitude and phase with a second potential difference of varying amplitude and phase, said first potential difference being that which is being represented by a vector of constant length rotating about its point of origin with uniform angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation.
- a method of controlling a. high frequency current in accordance with signal currents of lower frequency which comprises deriving a high frequency potential difference of constant amplitude, but shifting phase, by combining a first potential difference of constant amplitude and phase with a second potential difference of amplitude and phase, which is varied in accordance with said signal currents of lower frequency, said first potential difference being that which is represented by a vector of constant length rotating about its point of origin with uniform'angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation.
- a method of decreasing the frequency channel necessary to transmit signals of lower frequency as variations of higher frequency signalling waves which comprises deriving a high frequency potential difference of constant amplitude, but shifting phase and irrespective of the relative values of the fixed and variable elements, by combining a first potential difference of constant amplitude and phase with a second potential difference of varying amplitude and phase, said first potential difference being that which is represented by a vector of constant length rotating about its point of origin with uniform angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation, and limiting the phase shift of said second potential difference to a predetermined value corresponding to a predetermined width of high frequency signalling wave channel.
- a method of controlling a high frequency current in accordance with signal currents of lower frequency by displacing the phase of said high frequency current while maintaining its amplitude constant, and limiting the phase displacement to a predetermined value which comprises deriving a high frequency potential difference of substantially constant amplitude, but shifting phase and irrespective of the relative values of the fixed and variable elements, by combining a first potential difference of constant amplitude and phase with a second potential difference of varying amplitude and phase and limiting the phase of said second potential difference to a predetermined value corresponding to the predetermined value of phase shift of said high frequency current desired, said first potential difference being that which is represented by a vector of constant length rotating about its point of origin with uniform angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation.
- Apparatus for controlling high frequency currents in accordance with lower frequency signals comprising in combination a network consisting of two branches connected in parallel, each of said branches comprising a pair of impedances connected in series, the impedances in one branch being identical in all respects, and the impedances in the other branch having phase angles differing by a high frequency imput circuit connected across the opposite ends of said network, and a high frequency output circuit connected between points intermediate the impedances in each branch, andmeans for varying the value of one of said impedances in said second branch in accordance with currents of a lower order of frequency.
- Apparatus for producing a high frequency difference of potential, controlled in accordance with signal currents of lower frequency comprising a network consisting of two branches connected in parallel, one of said branches comprising a pair of series connected impedances of equal value, the other branch of said network comprising a pair of series-connected impedances, one of said impedances having substantially zero resistance and the other having substantially zero reactance; a high frequency input circuit connected across the opposite ends of said network; means for impressing high frequency currents of constant frequency and amplitude upon said input circuit; means for varying the value of one of said impedances in said second branch in accordance with currents of a lower order of frequency; and a high frequency output circuit connected at points intermediate the impedances of each branch.
- Apparatus for producing a high frequency difference of potential controlled in accordance with signal currents of lower frequency, and having a phase shift'limited to a predetermined value comprising a network consisting of two branches connected in parallel, one of said branches input circuit; means for varying the impedance value of one of said impedances in said second branch within predetermined limits corresponding to the phase shift permissible in said high frequency currents; and a high frequency output circuit connected at points intermediate the impedances of each branch.
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Description
Mam-ch 13, 1934. F. W. HOORN L METHOD AND APPARATUS FOR CONTROLLING ELECTRICAL WAVES I Original Filed May 7, 1929 5 Sheets-Sheet l OSCILATOR OSClLLATOR INVENTOR FREDERICK \N. HOORN ATTORNEY arch 13, 1934. HQORN 1,950,406
METHOD AND APPARATUS FOR CONTROLLING ELECTRICAL WAVES Original Filed May 7, 1929 3 Sheets-Sheet 2 AMPLBHER lNVENTOR FREDERlCK W. HOQRN Y a 4 35 (g,- m ATTORNEY F. W. HQORN web 13, 1934.
METHOD AND APPARATUS FOR CONTROLLING ELECTRICAL WAVES Original Filed May '7, 1929 3 Sheets-Sheet 3 mum-2 553 mi INVENTOR FREDERICK w. HOORN ATTORNEY Patented Mar. 934
UNITED STATES mrrnon AND APPARATUS roa conrnomnc ELECTRICAL waves Frederick W. Boom, Washington, D. 0.
Application May "I, 1929, Serial No. 381,030
7 Claims.
(Granted under the act of March 3, 1883, as amended April 30, 1928; 370 0. G. 757) The invention descrlbed'in said application, if patented, may be manufactured and used by or for the Government for governmental purposes, without the payment of any royalty thereon.
This invention relates to a method and apparatus for controlling electrical waves or currents of one range of frequency in accordance with waves or currents of another and lower range of frequency, and more particularly to the application of such control to the transmission and reception of signals by radio, carrier current and the like.
For this purpose it has heretofore been customary to modulate the high frequency currents or waves in accordance with the signals to be transmitted, such as voice currents or the like, thereby producing changes of amplitude or frequency, or both, in the high frequency or carrier wave. As is well understood,such modulation produces new waves or currents, commonly called side bands, having a frequency range extending above and below the carrier frequency by an amount equal to the highest modulating or signal frequency. 'The side bands may include all frequencies lying within the limit of jrifa, where fr is the carrier frequency and fa the highest modulating or signal frequency.
It is also understood that when it is desired to send or receive voice or music signals as modulations of higher frequency waves, a channel or band of frequencies sufl'icient to include the side bands must be available, that is to say, the apparatus used for transmission and reception cannot be so sharply tuned to the carrier frequency as to discriminate against side bands without distorting the signal to a greater or less extent.
Attempts have been made to diminish the width of the frequency channel required, as for example by suppressing one set of side bands, and even one set of side bands and the carrier, but to my knowledge no system has heretofore been devised which does not require the transmission of at least one set of side bands, and in music transmission this requires a band of at least five kilocycles for average good quality. In picture transmission and television the band is usually very much greater.
It is an object of the present invention to provide a method and apparatus for controlling high frequency currents in accordance with currents of lower frequency, which permits the use of a narrower frequency channel for a given signal frequency range than has heretofore been possible.
It is a further object of my invention to provide a methodand apparatus for controlling high frequency currents in accordance with lower frequency signals, by shifting the phase of the high frequency currents under control of the signals while maintaining the amplitude of the carrier current substantially constant.
It is still a further object of my invention to provide a method and apparatus of the class described in which the phase shift introduced in the carrier wave shall not in any event exceed 180", and which may be held within limits as small as may be desired, as for example or degrees.
It is still a further object of my invention to provide a method and apparatus of the class described in which the control of the carrier wave may be achieved without the use of the conventional modulating apparatus, and in which the width of the frequency channel required may be greatly decreased without the necessity for introducing filters, side band suppression circuits or the like.
Still other objects and advantages of my invention will be apparent from the specification.
The features of novelty which I believe to be characteristic of my invention are set forth with particularity in the appended claims. My invention itself, however, both as to its fundamental principles and as to its particular embodiments, will best be understood by reference to the specification and accompanying drawings, in which:
Figure 1 shows diagrammatically a simple form of radio transmitter according to my invention.
Figure 2 shows a somewhat different form of transmitting apparatus according to my invention.
Figure 3 shows still another form of transmitter according to my invention.
Figure 4 is a vector diagram illustrating the operation of my invention.
Figures 5, 6 and 7V show diagrammatically-variousforms of receivers according to my invention.
My invention, in its fundamental aspect, contemplates modifying the phase of the high frequency carrier wave in such a manner that the phase displacement from normal is at any instant dependent on the amplitude of the current representing the signals to be transmitted, herein termed signal currents. This is achieved by combining a wave, the phase and amplitude of which is constant, with another of the samexfre quency, the phase and amplitude of whichis varied uncle: the control of the signals in such manher as to produce a resultant of constant amplitude but of varying phase which may be transmitted.
Reception may be obtained from the transmitted wave by a reversal of the process, that is, by combining with the received wave another wave of the same frequency and of constant amplitude and phase, the resultant of which may be detected and will yield currents corresponding to the original signal currents to be transmitted.
Referring now more particularly to Fig. 1: 0 designates diagrammatically an oscillator capable of delivering high frequency oscillations of constant amplitude and frequency to the input points A and B of the four-element network Z1, Z2, Z3 and Z4. It will be noted that these four elements are connected in series with each other in a closed loop. The input point A is taken intermedlate impedances Z1 and Z3, and input point B intermediate impedances Z2 and Z4. The output circuit is connected across points D and E, point D being located between impedances Z1 and Z2, and point E being located between Z3 and Z4.
The network as seen from the input or output terminals may therefore be regarded as being made up of two branches in parallel with each other, each branch being in turn made up of two elements in series.
Impedances Z1 and Z2 may be resistances, inductances, capacities, or combinations thereof, but both should be identical in magnitude and character so that the voltage drops through each due to a voltage impressed between points B and A, and are equal and in phase, whereby they may be represented by vectors Em: and EDA in Fig. 4, Ego and Em. represening the impedance drop in Z2 and Z1, respectively, due to the current flowing in Z2 and Z1, as a result of the impressed voltage.
Impedances Z3 and Z4 may be any suitable impedances having phase angles d ffering by 90.
For example Z3 may be a reactance, such as a condenser or inductance, the resistance being kept as low as possible, and Z4 being a resistance, the reactance of which is kept as low as possible. Either of the impedances Z3 and Z4 is arranged to vary in magnitude under the control of the signal currents of low frequency.
In Fig. 1, I have shown Z3 as a condenser and Z4 as a simple form of carbon transmitter, the resistance of wh ch varies in accordance with sound waves impinging thereon, but other arrangements may be used, as will hereafter be more particularly explained.
Referring now to Fig. 4, since the nature of impedances Z3 and Z4 are so chosen that the voltage drops across them are always in quadrature,
"and since EBDA must always equal Essa in magnitude and phase (Kirchoffs law), the conditions define the locus of two sides of a trangle, the angle between which sides is fixed and the third side of which is fixed.
It will be seen that the locus of point B is on the circumference of a semi-circle drawn about point D with a radius equal to DA, and that regardless of the location of point E r'n the locus, the fundamental requirements are satisfied.
From this diagram we may find the voltage drop Eng which must equal the vector sum of Em; and EBE, which always equals EDA plus EAE vectorially. The vector DA of Fig. 4, represents the potential difference of constant amplitude and phase, referred to in the method claims. Although represented as a stationary vector to represent magnitude and relative phase; this is a rotating vector, in the sense that it generates by with uniform angular velocity, the peripheral "end of which traces the semicircle BEA of Fig. 4.
Vector AE represents the potential difference Lam, and is the vector referred to in the method claims, as the vector drawn from the peripheral end of vector DA, to a point on the circumference of the circle traced by vector DA'in its rotation.
Vector DE is the sum of the above mentioned vectors DA and AE and necessarily remains constant in magnitude but varies in phase, as the magnitude of AE changes, and its quadrature relationship to EB is maintained. In either case, Em: is represented by a vector of constant length having a phase relation which may be displaced by an angle 0, which cannot exceed 90 in either direction of shift, and hence the total shift in phase cannot exceed 180". It will be understood that by controlling the change of impedance Z4, that is, by operating it within certain fixed limits, the phase displacement of Eng may also be kept within corresponding limits, and hence, to obtan any predetermined limit of phase shift of Ema, it is only necessary to operate Z4 in such a way that the greatest possible change of Z4 shall be small as compared with the normal value of Z4.
Now, it can be shown mathematically that the actual frequency transmitted according to my invention may be represented by ft=fr:L-fz, where fr is the basic carrier frequency and f2 is the apparent frequency introduced by a phase 116 displacement 0 introduced in the carrier. If R represents the impedance of the element Z4 which is variable, and X the impedance of the element Z3 which is fixed, and if R is made equal to X when no sounds are falling upon the microphone, 115 then we may write R=r1+r2 sin wat, where wa, represents the audio or other low frequency signal.
When, as already pointed out, T2 is made small, say .10 x R, and 1-1, which represents the normal value of R, is equal to X, it can be shown that 120 under this condition I: =fa
in which 1 60 [Z E a and fa is the signal or audio frequency, and 12 has a maximum value which is a small fraction of fa when cos wat is unity or nearly unity. The equation for transmitted frequency then becomes ft=fr:l; cos coat) fa in which grounded at 10, through coupling coils '7 and 8.
In Fig. 1, I have shown impedances Z1 and Z2 as inductances, Z3 as a condenser and Z4 as a variable resistance transmitter. In Fig. 2, I have shown a modified arrangement in which impedances Z1 and Z: are shown as condensers C1 and C2, while Z3 is shown as a fixed resistance R3, and Z4 is a condenser transmitter C4. The principle of operation is the same as already described.
Referring now to Fig. 3, I have shown a still further modification in which Z1, Z2 and Z: are all condensers, while Z4 is the plate-filament resistance of a suitable vacuum tube amplifier. In this case 15 is a transmitter of any suitable type, the output of which is supplied to the vacuum tube amplifier 17 by means of transformer or other coupling means 16.
In order to prevent the building up of any high frequency voltage on the input circuit of tube 1'7, a circuit consisting of inductance 25 and capacity 26,-tuned to the high frequency, may be connected in shunt with the input circuit.
The output circuit may comprise a tuned circuit 24, consisting of inductance 22 and capacity 23, tuned to the high frequency, and a suitable source of plate current 28. Circuit 24 offers infinite impedance to the high frequency current, but substantially zero impedance to currents of lower frequencies, so that no audio frequency voltage can be built up between anode 18 and cathode 19 of tube 1'7, the plate circuit of which therefore operates as a variable resistance, varying in accordance with sounds picked up by microphone 15. To prevent the tube acting as a rectifier of the high frequency current, the potential of source 28 should be so large that the anode 18 is always positive with respect to cathode 19.
A suitable source of power 21 is shown for heating cathode 19, and it may be desirable also to employ some form of stabilization to prevent oscillation of amplifier 17 when the input and output circuits are tuned to the same frequency. This may be in the form of a resistance connected in the grid circuit, or may be some form of tube capacity neutralization, all of which are well known. It may be found in certain cases that one or both of the tuned circuits may be omitted without introducing undesirable effects.
For the purpose of deriving signal currents from the received carrier or radio frequency wave on which the signals have been impressed, as already described, it is necessary to combine with the received wave a second wave of the same prequency as the constant frequency used for transmission, which second wave has a constant amplitude and phase relation. This process is the reverse of the process described for transmission and is also represented by the vector diagram of Fig. 4, wherein, for example Ema represents the received high frequency wave and E131) the local wave of constant frequency amplitude and unvarying phase, which is combined, thereby producing voltage EBE of varying amplitude.
Referring now more particularly to Fig. 5, I
: have shown one arrangement suitable for the purpose, in which 30 represents the input coil, which may be for example connected in an an-. tenna not shown. Coil 30 is coupled to a second coil 31 connected to the control electrode 38 of vacuum tube 35 and connected also through coil 32 and resistance 33 to the cathode 37 of amplifier 35. lfdesired, a tuning condenser 34 may be connected between the cathode37 and control electrode 38. The anode 36 is connected to coil 39 to the source of plate supply 49. Coil 32 is coupled to'a second coil 40, and resistance 33 and coils 40 and 41 are connected in the input circuit of a second vacuum tube 43, the input circuit of which may be tuned by means of condenser 42 connected between the control electrode 46 and cathode 45. Anode 44 is connected to coil 47 for the purpose of permitting the vacuum tube 43 to generate oscillations, as is well known in the art. The output circuit of tube 43 is completed through coil 48 and the source of plate supply 49. Coils 39 and 48 are coupled to coils 51 and 50, respectively, connected in the input circuit of vacuum tube detector 55, having an anode 56, cathode 57 and control electrode 58. Coils 50 and 51 may be tuned by tuning condenser 52. Resistance 53, shunting condenser 54, may be provided for causing the tube to operate as a detector. A suitable transformer 59 may be provided in the output circuit of tube 55 for supplying the output thereof to any suitable device such, for example, as an amplifier or translating device. In the operation of this arrangement tube 35 operates as an amplifier, whereas tube 43 operates as an oscillator, both being tuned to the frequency of the incoming signal. By adjustment of condenser 42, the oscillations generated by tube 43 will be of the same frequency as the incoming oscillations impressed on tube 35, that is to say, the oscillator will fall in step with the received signal. However, this coupling, controlled by coils 32 and 40 and resistance 33, should not be made so tight that the phase of the oscillatory currents generated by tube 43 follows the phase of the incoming signals, since tube 43 supplies the oscillations of constant frequency and unvarying phase. These oscillations are supplied to the input of detector 55 by means of coils 48 and 50, while the amplified signal input is similarly supplied to the input of tube 55 by means of coils 39 and 51. The amplitude of oscillator 43 should be so adjusted that the generated oscillations are of substantially the same order of strength as the currents with which they are to be combined. But in any event, the coupling between coils 48 and 50, and 39 and 51, may be adjusted until best results are obtained. The detected currents supplied by tube 55 will then correspond to the currents delivered by the microphone or other device in Fig. l, and may be amplified to the extent desired for the particular purpose in view.
Referring now more particularly to Fig. 6, I have shown a slightly modified arrangement in which the incoming signals are first amplified and in which tube 35 operates as a detector. In this arrangement A designates an antenna representing the primary or coupling transformer 60, the secondary of which feeds a suitable frequency amplifier 61, the output of which is fed to the input of detector 35 by means of coupling transformer 62. In this arrangement it will be noted that grid leak and condenser 64 and 63 are connected in the input circuit of tube 35 in the manner known in the art, to cause the said tube to operate as a detector; also, coils 39, 48, 50 and 51 are dispensed with and a transformer 65 or other suitable coupling device is provided for supplying the detected currents to any suitable amplifier or other translating device. In this instance the oscillator 43 is preferably enclosed in a suitable shield indicated by the dotted lines as enclosing ,also certain of the elements of the circuit of tube 43 within the shield.
Referring now more particularly to Fig. 7, I have shown a slightly further modified form of apparatus in which the same tube operates as detector and oscillator. In this instance the output of radio frequency amplifier 61 is impressed between one pair of opposite points of a balanced Wheatstone bridge made up of coil 70, tuning condenser 71 and series condensers '72 and 73, while the input of tube 77 is taken off condenser '72. The anode '78 is connected through coil 76 and the primary of output transformer 82 through the source of plate current 81 to the cathode 79, while the input circuit is connected between control electrode through grid leak '75 to condenser 72, the opposite side of which is connected to cathode '79. This arrangement is similar to that described in United States patent to Pressley 1,560,854, dated November 10, 1925, and permits the tube 7'7 to generate oscillations without such oscillations being radiated from the antenna A. In this case the locally generated oscillations are combined with the incoming signals in tube 7'7 and its associated circuits, and the resultant is detected by the said tube.
I claim:
1. A method of controlling a high frequency current in accordance with signal currents of lower frequency, which comprises deriving a high frequency potential difference of substantially constant amplitude, but shifting phase, by combining a first potential difference of constant amplitude and phase with a second potential difference of varying amplitude and phase, said first potential difference being that which is being represented by a vector of constant length rotating about its point of origin with uniform angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation.
2. A method of controlling a. high frequency current in accordance with signal currents of lower frequency, which comprises deriving a high frequency potential difference of constant amplitude, but shifting phase, by combining a first potential difference of constant amplitude and phase with a second potential difference of amplitude and phase, which is varied in accordance with said signal currents of lower frequency, said first potential difference being that which is represented by a vector of constant length rotating about its point of origin with uniform'angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation.
3. A method of decreasing the frequency channel necessary to transmit signals of lower frequency as variations of higher frequency signalling waves, which comprises deriving a high frequency potential difference of constant amplitude, but shifting phase and irrespective of the relative values of the fixed and variable elements, by combining a first potential difference of constant amplitude and phase with a second potential difference of varying amplitude and phase, said first potential difference being that which is represented by a vector of constant length rotating about its point of origin with uniform angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation, and limiting the phase shift of said second potential difference to a predetermined value corresponding to a predetermined width of high frequency signalling wave channel.
4. A method of controlling a high frequency current in accordance with signal currents of lower frequency by displacing the phase of said high frequency current while maintaining its amplitude constant, and limiting the phase displacement to a predetermined value, which comprises deriving a high frequency potential difference of substantially constant amplitude, but shifting phase and irrespective of the relative values of the fixed and variable elements, by combining a first potential difference of constant amplitude and phase with a second potential difference of varying amplitude and phase and limiting the phase of said second potential difference to a predetermined value corresponding to the predetermined value of phase shift of said high frequency current desired, said first potential difference being that which is represented by a vector of constant length rotating about its point of origin with uniform angular velocity, and said second potential difference being that which is represented by a second vector drawn from the peripheral end of said first vector to a point on the circumference of the circle traced by the outer end of said first vector in its rotation.
5. Apparatus for controlling high frequency currents in accordance with lower frequency signals, comprising in combination a network consisting of two branches connected in parallel, each of said branches comprising a pair of impedances connected in series, the impedances in one branch being identical in all respects, and the impedances in the other branch having phase angles differing by a high frequency imput circuit connected across the opposite ends of said network, and a high frequency output circuit connected between points intermediate the impedances in each branch, andmeans for varying the value of one of said impedances in said second branch in accordance with currents of a lower order of frequency.
6. Apparatus for producing a high frequency difference of potential, controlled in accordance with signal currents of lower frequency, comprising a network consisting of two branches connected in parallel, one of said branches comprising a pair of series connected impedances of equal value, the other branch of said network comprising a pair of series-connected impedances, one of said impedances having substantially zero resistance and the other having substantially zero reactance; a high frequency input circuit connected across the opposite ends of said network; means for impressing high frequency currents of constant frequency and amplitude upon said input circuit; means for varying the value of one of said impedances in said second branch in accordance with currents of a lower order of frequency; and a high frequency output circuit connected at points intermediate the impedances of each branch.
7. Apparatus for producing a high frequency difference of potential controlled in accordance with signal currents of lower frequency, and having a phase shift'limited to a predetermined value, comprising a network consisting of two branches connected in parallel, one of said branches input circuit; means for varying the impedance value of one of said impedances in said second branch within predetermined limits corresponding to the phase shift permissible in said high frequency currents; and a high frequency output circuit connected at points intermediate the impedances of each branch.
FREDERICK W. HOORN.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US361030A US1950406A (en) | 1929-05-07 | 1929-05-07 | Method and apparatus for controlling electrical waves |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US361030A US1950406A (en) | 1929-05-07 | 1929-05-07 | Method and apparatus for controlling electrical waves |
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US1950406A true US1950406A (en) | 1934-03-13 |
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US361030A Expired - Lifetime US1950406A (en) | 1929-05-07 | 1929-05-07 | Method and apparatus for controlling electrical waves |
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Cited By (15)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2524845A (en) * | 1944-08-22 | 1950-10-10 | William L Smith | Radio phase modulator |
US2551802A (en) * | 1948-01-05 | 1951-05-08 | Rca Corp | Phase modulator |
US2561455A (en) * | 1947-03-10 | 1951-07-24 | Autophon Ag | Device for phase modulation |
US2563964A (en) * | 1949-05-21 | 1951-08-14 | Schlang Arthur | Phase modulator |
US2577297A (en) * | 1944-01-22 | 1951-12-04 | Antranikian Haig | Signaling system |
US2668282A (en) * | 1948-09-20 | 1954-02-02 | Phillips Petroleum Co | Transmitter for radio seismic systems |
DE907313C (en) * | 1949-07-28 | 1954-03-22 | Rolf Merten Dr Ing | Two-pole circuit with a complex resistor that can be varied in phase |
US2673238A (en) * | 1950-05-20 | 1954-03-23 | Zenith Radio Corp | Timing system for subscription type television receivers |
US2841785A (en) * | 1946-05-08 | 1958-07-01 | Jr Frederic Cunningham | Target simulating signal generator |
US2887662A (en) * | 1956-07-20 | 1959-05-19 | Mauduech Robert Rene | Phase shifting and modulating device |
US2973482A (en) * | 1949-01-07 | 1961-02-28 | Rex E Lovejoy | Synchronized oscillator for fm limiter and discriminator |
US2977569A (en) * | 1951-04-04 | 1961-03-28 | Harris Transducer Corp | Detector with modulation by magnetostrictive-core acoustic transducer |
US3028757A (en) * | 1948-03-03 | 1962-04-10 | Benjamin L Snavely | Electrical bridge measuring apparatus |
US3146292A (en) * | 1954-03-08 | 1964-08-25 | Don L Bonham | Electrical vibrato and tremolo devices |
US3214710A (en) * | 1962-08-28 | 1965-10-26 | Ibm | Phase and frequency modulator circuits |
-
1929
- 1929-05-07 US US361030A patent/US1950406A/en not_active Expired - Lifetime
Cited By (15)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2577297A (en) * | 1944-01-22 | 1951-12-04 | Antranikian Haig | Signaling system |
US2524845A (en) * | 1944-08-22 | 1950-10-10 | William L Smith | Radio phase modulator |
US2841785A (en) * | 1946-05-08 | 1958-07-01 | Jr Frederic Cunningham | Target simulating signal generator |
US2561455A (en) * | 1947-03-10 | 1951-07-24 | Autophon Ag | Device for phase modulation |
US2551802A (en) * | 1948-01-05 | 1951-05-08 | Rca Corp | Phase modulator |
US3028757A (en) * | 1948-03-03 | 1962-04-10 | Benjamin L Snavely | Electrical bridge measuring apparatus |
US2668282A (en) * | 1948-09-20 | 1954-02-02 | Phillips Petroleum Co | Transmitter for radio seismic systems |
US2973482A (en) * | 1949-01-07 | 1961-02-28 | Rex E Lovejoy | Synchronized oscillator for fm limiter and discriminator |
US2563964A (en) * | 1949-05-21 | 1951-08-14 | Schlang Arthur | Phase modulator |
DE907313C (en) * | 1949-07-28 | 1954-03-22 | Rolf Merten Dr Ing | Two-pole circuit with a complex resistor that can be varied in phase |
US2673238A (en) * | 1950-05-20 | 1954-03-23 | Zenith Radio Corp | Timing system for subscription type television receivers |
US2977569A (en) * | 1951-04-04 | 1961-03-28 | Harris Transducer Corp | Detector with modulation by magnetostrictive-core acoustic transducer |
US3146292A (en) * | 1954-03-08 | 1964-08-25 | Don L Bonham | Electrical vibrato and tremolo devices |
US2887662A (en) * | 1956-07-20 | 1959-05-19 | Mauduech Robert Rene | Phase shifting and modulating device |
US3214710A (en) * | 1962-08-28 | 1965-10-26 | Ibm | Phase and frequency modulator circuits |
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