US2087429A - Phase and frequency modulation wave receiving system - Google Patents
Phase and frequency modulation wave receiving system Download PDFInfo
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- US2087429A US2087429A US25231A US2523135A US2087429A US 2087429 A US2087429 A US 2087429A US 25231 A US25231 A US 25231A US 2523135 A US2523135 A US 2523135A US 2087429 A US2087429 A US 2087429A
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03D—DEMODULATION OR TRANSFERENCE OF MODULATION FROM ONE CARRIER TO ANOTHER
- H03D3/00—Demodulation of angle-, frequency- or phase- modulated oscillations
- H03D3/02—Demodulation of angle-, frequency- or phase- modulated oscillations by detecting phase difference between two signals obtained from input signal
- H03D3/22—Demodulation of angle-, frequency- or phase- modulated oscillations by detecting phase difference between two signals obtained from input signal by means of active elements with more than two electrodes to which two signals are applied derived from the signal to be demodulated and having a phase difference related to the frequency deviation, e.g. phase detector
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- This invention relates to a new and improved means for receiving, amplifying and demodulating high frequency waves modulated in phase or in frequency by intelligence to be transmitted.
- phase or frequency modulation receiving systems wherein a multi-grid detector is utilized. ⁇
- a multi-grid detector By feeding the filtered or retarded signal to one grid and the unfiltered signal to another grid,- detection is accomplished by the use of a single detector tube without losing any of the advantages of a differential or dual detector system.
- frequency modulation has been received' by receivers which convert the l5 frequency modulation to amplitude modulation and detect in the normal square-law ⁇ manner.
- receivers which convert the l5 frequency modulation to amplitude modulation and detect in the normal square-law ⁇ manner.
- the multigrid detector takes the place of the differential detectors and does not require two conversion branches to produce amplitude modulations with envelopes 180 degrees out of phase. In this Way design is simplified without losing any of the advantages of the more complicated systems.
- Fig. 1 illustrates the essential elements of a frequency modulated wave receiving, amplifying and demodulating system including a multiple grid tube detector connected'in a novel circuit;
- Figs. 2 and 6 are modifications of the system of Fig. l;
- Figs. 2a and 6a are modifications of portions of the circuits of Figs. 2 and 6, respectively;
- Figs. 3 and 7 are curves illustrating the characteristics of filters in the output of the detectors of Figs. 2, 2a and 6, 6a, respectively; while Figs. 4 and 5 are tube characteristic curves showing the mode of operation of the detector 55 tubes of Figs. 1, 2, 2a, 6 and 6a.
- Fig. 2 shows an adaptation of a retard circuit type of frequency modulation receiver of the type disclosed in my copending U. S. application Ser. No. 618,154, filed June 20, 5 1932.
- the novel demodulation means of the present invention replaces the differential demodulator of said prior application.
- the signal is fed from antenna I to radio frequency amplifier 2, comprising the desired number of 10 thermionic amplifiers.
- the amplified signal is fed from the radio frequency amplifier 2l to a first detector comprising a thermionic tube 3 of the multi-grid electrode type, and a source of high frequency oscillations 4, which produces oscilla- 15 tions to be beat with the signal in 3 to produce an intermediate frequency output which is fed to the intermediate frequency amplifier 5.
- the signals from the amplifier 2 may be fed to either of the grids in 3, while the high frequency oscil- 20 lations from 4 may be fed to the other grid in 3.
- 'I'he intermediate frequency amplifier 5 may also include a bandpass filter.
- the intermediate frequency energy from the output of amplifier and filter 5 is fed to the input end of a retard circuit 25 6, which is terminated at the other end by a variable resistance R.
- the applied intermediate frequency Wave sets up incident and refiected waves in the series inductance of the retard circuit 6.
- the relative phases of the incident and re- 30 flected waves in 6 may be regulated as desired by means of the adjustable resistance R and/or the values of the capacities and inductance in the circuit 6.'
- Intermediate frequency potential Variations are applied from the input end of the 35 retard circuit 6 to one of the grids, say grid GI ofdetector tube 8 by way of a tapped resistance 1.
- Intermediate frequency potentials are also applied from a point on the retard circuit 6 directly to the other grid, say grid G2 of detectoi 40 8.
- the audio output of detector 8 is resistance coupled by a resistance and c-apacity unit I5 to the control grid of an audio frequency amplifier 9 and will appear in the indicator or recording device III.
- the re- 45 sistance coupling I5 between the output of detector 8 and the input of audio frequency amplifier 9 may be replaced by a low pass filter I2as shown in Fig. 2a.
- the filter I2 removes the remaining carrier frequency components from the energy in the output of the detector 8 and from the input of the audio frequency amplifier 9, and also provides a low impedance path for the carrier frequency.
- phase of the output of the retard circuit is directly proportional to the applied frequency.
- a frequency modulated wave given by:
- variable output would be:
- the output of the detector consists of the fundamental frequency Sin pt proportional to a first order Bessel function of 2rDfd, and all the odd harmonics of the modulation frequency.
- the second harmonic which normally is present v in square-law detection, isabsent from the output of this detector.
- Fig. l shows a sloping lter type l of receiver utilizing the multi-grid detector and also showing the utilization of the principle described in my U. S. application Ser. No. 25,026, led June 5, 1935, wherein frequency multiplication is employed at the receiver.
- the output of the intermediate frequency amplifier 5 is supplied to a frequency multiplier- 26.
- This multiplier may be any type known, such as a4 harmonic generator, a multiplier of the overloaded thermionic tube type, etc.
- the signal modulation carrying ⁇ energy of increased frequency is supplied from 'the output of the frequency multiplier 26 to the input of a second detector 21, which is also coupled to an intermediate frequency oscillator 28. 'I'he frequency multiplier in 26 increases the depth of modulation of the frequency modulated wave.
- Transformer 29 supplies energy to the control grids of tubes 30 and 8
- the plate circuit of coupling tube 30 includes a filter 33, having a sloping characteristic, such as shown inv Fig. 3.
- a filter may take many alternative forms, such as the side of a bandpass filter, band elimination filter, low-pass or high-pass filter, all of which are known in the filter art.
- the main requirement is that the characteristic slope 1inearly from substantially zero output at one side of the wave channel to a maximum at the other side of the wave channel, as shown in Fig. 3.
- the output of filter 33 is connected by the resistance and capacity coupling I3 to one of the grids, say grid GI, of detector tube 8.
- is fed by way of the -coupling impedance 34 and capacity 3G to the other grid, say grid G2, of detectorl tube 8.
- the control grid of the audio frequency amplifier 9 is resistance coupled by way of I5 to the plate electrode of the detector tube 8.
- the resistors and condenser of coupling unit I5 may be replaced by the low-pass filter, as shown in Fig. 2a, for eliminating the carrier wave components and other unwanted frequency, as well as providing a low impedance path for the carrier frequencies.
- the output of amplifier 9 may be supplied to any recording device or indicating device or utilization device I0.
- the filter 33 converts the frequency modulation to amplitude modulation.
- the grids of detector 8 are operating on the linear part of their characteristics, there will be no detection with only the output of the filter fed to the detector grid. Consequently, the unfiltered output must be fed to the other grid via impedance coupling 34 so that the two waves may coact to produce detection. The manner in which the detection takes place is explained in the following:
- the frequency modulated wave is given an envelope [l-i-fd/fc-fo sin pt] which has the same form as the familiar amplitude modulation envelope and whose percentage of modulation is fd/fc-fa Detector 8 of Fig. 1 has applied to one grid,
- Equation (8) the variable output (neglecting direct current Aterms and radio frequency terms removed by detector output filter):
- the circuit of. Fig. 6 makes it possible to balance out the undesired amplitude modulation for the sloping filter type of circuit. .In the retard circuit type of detection, the amplitude modulation is inherently balanced out with the use of any of these receivers.
- a differential detection arrangement as shown in Fig. 6 must be utilized.
- intermediate frequency energy from a superheterodyne receiver is fed to transformer 29 and distributed to coupling tubes 30, 3
- a filter providing a characteristic as shown in Fig. 3.
- a filter providing a characteristic of opposite slope to Fig. 3, such as shown in Fig. '7.
- the outputs of filters 33 and 34 are fed to detector grids GI of detectors 36 and 31.
- the output of coupling tube 32 is fed via aperiodic impedance coupling 35 to the second grids G2 of detectors 36 and 31.
- Filters 38 and 39 remove the carrier energy from the detector output.
- Transformer 40 combines the detector outputs in the push-pull or series connection, depending upon the position of switch S2. The output is made available at jack 4I.
- switch Sz would have the push-pull connection.
- amplitude modulation reception the parallel connection would be used. When frequency modulation is being received, the amplitude modulation would be balanced out and when amplitude modu1a tion is being received, the frequency modulation would be balanced out.
- limiting could be used in conjunction with In the case of the sloping filter type circuit, if limiting were used, the balanced circuits of Fig. 6 and 6a. would not be required since the limiter would remove the'undesired amplitude modulation.
- the limiter could be inserted at the points X in the intermediate frequency leads following the intermediate frequency amplifier of any of the circuits or could be inserted in the radio ⁇ frequency circuits at the points Y, if desired.
- any of these receivers could be used for the reception of phase modulation by the addition of a correction circuit following the output jack.
- This correction circuit would have its output inversely proportional to the modulation frequency as is described in my U. S. appln. Ser. No. 618,154, filed June 20, 1932.
- a wave retarding circuit comprising inductive and capacitive reactances, means for applying frequency modulated waves to be demodulated to said circuit to produce therein wave energy of a phase directly proportional to the frequency modulations on the applied wave, a thermionic tube having a plurality of control electrodes, a circuit connecting one of said control electrodes to a point on said wave retarding circuit to apply produced wave energy to said control electrode, and a circuit coupling the other of said control electrodes to said means to apply original frequency modulated wave en- Y,
- a wave retarding circuit comprising inductive and' parallel capacitive reactances, means for applying frequency modulated waves to be demodulated to said circuit to produce therein wave energy of a phase directly proportional to the frequency modulations on the applied wave, a thermionic tube having an anode, a cathode and a plurality of grid-like electrodes,
- connection between one of said grid-like electrodes and a point on said wave retarding circuit to impress produced energy on said one of said grid-like electrodes a connection between the other of said grid-like electrodes and said means to apply original frequency modulated wave energy to said other electrode, means for applying biasing potentials between said gridlike electrodes and said cathode, and an indicator coupled to the anode of said tube.
- a system as recited in claim 2 in which a low pass filter is interposed between said indicator and the anode of said tube.
- a thermionic tube having a cathode and a plurality of grid-like electrodes
- a tuned reactance acting as a filter having a sloping characteristic connecting one of said grid-like electrodes to said wave receiving means and an impedance acting as a filter having a characteristic which is uniform over the frequency range of the received wave 4coupling a second grid-like electrode in said tube to said wave receiving means.
- wave receiving means a'plurality of thermionic tubes each having a plurality of grid-like electrodes, a cathode and an anode
- separate circuits each including a filter having sloping characteristics which slope in opposite sense coupling like gridlike electrodes in said tubes to said wave receiving means to excite the said like grid-like electrodes differentially in accordance with. the amplitude variations superimposed on said moduulated waves passed by said filters, and a second circuit including a filter having a flat topped characteristic coupling like grid-like electrodes in each of said tubes in phase to said wave receiving means.
- each of said separate circuits includes a coupling tube.
- wave receivingv means wave amplifying means coupled to said receiving means, frequency multiplying means coupled to said amplifying means, a pair of electron discharge tubes each having a control grid and an anode, a circuit connecting the control grids of both of said tubes to the output of said frequency multiplier, a filter circuit having a sloping characteristic coupled to the anode of one of said tubes, a circuit having a fiat topped characteristic coupled to the anode of the other of said tubes, a detector tube having an anode, a cathode and a plurality of grid-like electrodes, a connection between one of the gridlike electrodes of said detector tube and the filter circuit ofsloping characteristics connected with the anode of one of said irst named tubes, and a circuit connectinganother grid-like electrode of said detector tube to said circuit having a at topped characteristic connected with the anode of the other of said ilrst named tubes.
- a phase or frequency modulated wave demodulating means signal receiving l and amplifying means, a frequency multiplier lconnected to said amplifying means, said frequency multiplier having an output, two thermionic coupling tubes each having a control grid a cathode and ananode, a circuit coupling the control grid and cathode of each of said coupling tubes in ⁇ phase to the output of said frequency multiplier, a filter circuit having a sloping characteristic coupled to the anode of one of.
- a separate filter circuit having a flat topped characteristic coupled to the anode of the second of said coupling tubes, a thermionic detector having a cathode, and a plurality of grid-like electrodes, and circuits connecting said filter circuits to different grid-like electrodes in said detector tube.
- a frequency or phase modulated wave demodulating means -wave receiving means, a frequency multiplier connected to said wave receivlng means, three thermionic coupling tubes each having a control grid a cathode and an.
- a circuit including a filter whose attenuation varies substantially linearly with the frequency of the received frequency modulated wave connecting one of said control electrodes to said Wave receiving means, an additional circuit including a filter whose attenuation is substantially uniform for all frequencies of the received frequency modulated Wave coupling a second control electrode in said tube to said wave receiving means, and an output circuit connected with the output electrode of said tube.
- an additional circuit including an impedance coupling a second grid-like electrode in said tube to said wave receiving means to impress additional wave energy on said second grid-like electrode from said wave receiving means, said circuits'having outputs which vary in different respects relative to the variations in phase or frequency of the received wave energy, biasing means connected between the cathode of said tube and each grid-like electrode', and a utilization circuit coupled to said anode and cathode.
- the method of demodulating phase or frequency modulated Wave energy by means of an electron discharge device having a plurality of control electrodes, a cathode, and an anode which consists in producing wave energy the phase of which is varied asa function of the phase or frequency modulations of the said phase or frequency modulated Wave energy, applying said produced Wave'energy between the cathode and one of said control electrodes, applying phase or frequency modulated Wave energy whose phase has not been so altered between the other of said control electrodes and the cathode, andA biasing both of said control electrodes relative to the cathode by potentials such that said tube operates on the vlinear portion of the control electrode potential plate current characteristic curves, and utilizing the resultant energy from the anode and cathode of said tube.
- a source of phase or frequencyor amplitude modulated wave energy three electron discharge devices each having a control grid, a cathode and an anode, a circuit coupling the control gridsand cathodes of all of said tubes in parallel to said source of modulated wave energy, a lter circuit having a sloping characteristic connected at its input to the anode and cathode of one of said tubes, said lter circuit having an output, a second filter circuit having a sloping characteristic connected at its input to the anode and cathode of a second one of said tubes, a pair of electron discharge detector tubes each having a plurality of control electrodes, a cathode and an anode, circuits cony necting the outputs of said filter circuits in pushf pull relation to like control electrodes in said detector tubes, a circuit having a flat topped characteristic connected at its input to the anode of the third of said first named three tubes, said last named circuit having an output,
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Description
July 20, 1937. M. G. CROSBY 2,087,429
PHASE AND FREQUENCY MODULATION WAVE RECEIVING SYSTEM Filed June 6, 1955 2 Sheets-Sheet l %\5 E: SN
July 20, 1937. M. G. CROSBY 2,087,429
PHASE AND FREQUENCY MODULATION WAVE RECEIVING SYSTEM Filed June 6, 1955 2 Sheets-Sheet 2 fp fp 2 l:52 0 9/ f -k 1 52 fg, --15 592 5k g1 =z/:
OUTPUT INVENTOR MURRAY 6. CROSBY ATTORNEY Patented July 20, 1937 PATENT OFFICE PHASE AND FREQUENCY MODULATION WAVE RECEIVING SYSTEM Murray G. Crosby, Riverhead, N. Y., assignor to Radio Corporation of America, a. corporation of Delaware Application June 6, 1935, Serial No. 25,231
16 claims. (c1. 25o-2o) This invention relates to a new and improved means for receiving, amplifying and demodulating high frequency waves modulated in phase or in frequency by intelligence to be transmitted.
More in detail this disclosure describes phase or frequency modulation receiving systems wherein a multi-grid detector is utilized.` By feeding the filtered or retarded signal to one grid and the unfiltered signal to another grid,- detection is accomplished by the use of a single detector tube without losing any of the advantages of a differential or dual detector system.
In the prior art, frequency modulation has been received' by receivers which convert the l5 frequency modulation to amplitude modulation and detect in the normal square-law `manner. By utilizing two converting systems which produced amplitude modulated waves with their envelopes 180 degrees out of phase, together with bined differentially, unwanted amplitude modulation could be balanced out together with the second-harmonic square-law detector distortion.
In the receivers of this disclosure, the multigrid detector takes the place of the differential detectors and does not require two conversion branches to produce amplitude modulations with envelopes 180 degrees out of phase. In this Way design is simplified without losing any of the advantages of the more complicated systems. The novel features of my invention have been pointed out with particularity in the claims appended to the end of this specification as required by law. The nature of my invention and the manner of operation thereof will be understood from the following detailed description of several specific embodiments of my novel receiving means and therefrom when read in connection with the attachedl drawings, throughout which like reference characters indicate like parts insofar as possible, and in which:
Fig. 1 illustrates the essential elements of a frequency modulated wave receiving, amplifying and demodulating system including a multiple grid tube detector connected'in a novel circuit;
Figs. 2 and 6 are modifications of the system of Fig. l;
Figs. 2a and 6a are modifications of portions of the circuits of Figs. 2 and 6, respectively;
5o Figs. 3 and 7 are curves illustrating the characteristics of filters in the output of the detectors of Figs. 2, 2a and 6, 6a, respectively; while Figs. 4 and 5 are tube characteristic curves showing the mode of operation of the detector 55 tubes of Figs. 1, 2, 2a, 6 and 6a.
two detectors whose detected outputs were com- In describing my invention, reference will first be made to Fig. 2. Fig. 2 shows an adaptation of a retard circuit type of frequency modulation receiver of the type disclosed in my copending U. S. application Ser. No. 618,154, filed June 20, 5 1932. In Fig. 2, the novel demodulation means of the present invention replaces the differential demodulator of said prior application. Here, the signal is fed from antenna I to radio frequency amplifier 2, comprising the desired number of 10 thermionic amplifiers. The amplified signal is fed from the radio frequency amplifier 2l to a first detector comprising a thermionic tube 3 of the multi-grid electrode type, and a source of high frequency oscillations 4, which produces oscilla- 15 tions to be beat with the signal in 3 to produce an intermediate frequency output which is fed to the intermediate frequency amplifier 5. The signals from the amplifier 2 may be fed to either of the grids in 3, while the high frequency oscil- 20 lations from 4 may be fed to the other grid in 3. 'I'he intermediate frequency amplifier 5 may also include a bandpass filter. The intermediate frequency energy from the output of amplifier and filter 5 is fed to the input end of a retard circuit 25 6, which is terminated at the other end by a variable resistance R. The applied intermediate frequency Wave sets up incident and refiected waves in the series inductance of the retard circuit 6. The relative phases of the incident and re- 30 flected waves in 6 may be regulated as desired by means of the adjustable resistance R and/or the values of the capacities and inductance in the circuit 6.' Intermediate frequency potential Variations are applied from the input end of the 35 retard circuit 6 to one of the grids, say grid GI ofdetector tube 8 by way of a tapped resistance 1. Intermediate frequency potentials are also applied from a point on the retard circuit 6 directly to the other grid, say grid G2 of detectoi 40 8. The audio output of detector 8 is resistance coupled by a resistance and c-apacity unit I5 to the control grid of an audio frequency amplifier 9 and will appear in the indicator or recording device III.' In a more specific application, the re- 45 sistance coupling I5 between the output of detector 8 and the input of audio frequency amplifier 9 may be replaced by a low pass filter I2as shown in Fig. 2a. The filter I2 removes the remaining carrier frequency components from the energy in the output of the detector 8 and from the input of the audio frequency amplifier 9, and also provides a low impedance path for the carrier frequency.
'I'he novel part of the invention of Fig. 2 and 2a 55 lay D,`the phase of the output of such a circuit would be:
where T is the period of the wave applied and a is in radians. 'I'his may be rewritten:
a=21rDf (2) where'f is the frequency of the applied wave, l is `the electrical length of the retard, circuit and V='3108 meters per second.
Thus, the phase of the output of the retard circuit is directly proportional to the applied frequency. In the case of a frequency modulated wave given by:
e=E eos (wt-fd/fm) cospt) (a) 'Where w=21r carrier frequency, fd=`frequency deviation with modulation and p=21rfm where fm=the modulating frequency, the instantaneous frequency is given by f: (fe-i-fd sin pt) (5) Substituting (5) in (2) gives:
a=2fD(fc+fd sin pt) (6) Hence, the wave passed through the retardation circuit has the phase given by (6) added to it or The grids of the detector 8 are adjusted according to the characteristics of Figs. 4 and 5. Both grids are adjusted to point "a which is the linear portion of the characteristic. Thus, in accordance withv the general description of this detector given in my U.` S. application Ser. No. 716,469, filed March 20, `1934, Patent No. 2,063,- 588, December 8, 1936, the variable current in the output of the detector would be substantially given by:
where ai and az are constants of the tube and e1 and e2 are the two grid voltages. Applying the .unretarded voltageof Equation (3) t one grid,
say GI, and the retarded voltage of (7) to the other grid, say G2, gives as the variable output:
simplifying and eliminating radio frequency terms which would be eliminated by the low pass filter in the detector output, the variable output would be: l
In practice ZrDfc is adjusted to equal 1r/2, 31/2, 51r/2, etc.,--so that 1:8182'25152 .in by applyingv the Bessel ll'unc'tion"Expansion:'y
zrDtd sin pt (11) diagElEg Thus, the output of the detector consists of the fundamental frequency Sin pt proportional to a first order Bessel function of 2rDfd, and all the odd harmonics of the modulation frequency.
The second harmonic, which normally is present v in square-law detection, isabsent from the output of this detector.
The circuit of Fig. l shows a sloping lter type l of receiver utilizing the multi-grid detector and also showing the utilization of the principle described in my U. S. application Ser. No. 25,026, led June 5, 1935, wherein frequency multiplication is employed at the receiver. The output of the intermediate frequency amplifier 5 is supplied to a frequency multiplier- 26. This multiplier may be any type known, such as a4 harmonic generator, a multiplier of the overloaded thermionic tube type, etc. The signal modulation carrying `energy of increased frequency is supplied from 'the output of the frequency multiplier 26 to the input of a second detector 21, which is also coupled to an intermediate frequency oscillator 28. 'I'he frequency multiplier in 26 increases the depth of modulation of the frequency modulated wave. or depth of modulation of the phase modulated wave, where phase modulation is to be received and the final detector is to be followed by a correction circuit, the output of which is inversely proportional to the modulation frequency. The manner in Awhich the modulation depth is increased by multiplying the frequency of the wave is set forth in my U..S. application Ser. No. 704,257, filed Dec. 28, 1933 and also my U. S. application Ser. No. 25,026, filed June 5, 1935. An audible frequency correction circuit having the characteristics described above to be inserted in the circuit after the final detector has been described in my U. S. appln. Ser. No. 618,154, filed June 20, 1932. Heterodyning the frequency multiplied wave to a different frequency in 21 does not affect the depth of modulation of the frequency or phase modulated wave. The theory of this operation has been disclosed in detail in my U. S. appln. Ser. No. 704,257, filed Dec. 28, 1933. If frequency multiplication at the receiver is not desired, the output of the y intermediate frequency amplifier 5 may be fed directly to the primary of transformer 29, thereby eliminating units 28, 21 and 28.
In the type'of receiver of Fig. 1, the filter 33 converts the frequency modulation to amplitude modulation. However, since the grids of detector 8 are operating on the linear part of their characteristics, there will be no detection with only the output of the filter fed to the detector grid. Consequently, the unfiltered output must be fed to the other grid via impedance coupling 34 so that the two waves may coact to produce detection. The manner in which the detection takes place is explained in the following:
When an alternating voltage is passed through a filter having a characteristic as shown in Fig. 3, the output will be given by:
where f is the frequency of the input voltage. (14) may also be written:
Applying the frequency modulated wave of Equation (3) which has a frequency given by Equation (5) to the input of this filter gives the following output voltage:
cos (wt-fd/fm cos pt) (16) Simplifying:
Thus, the frequency modulated wave is given an envelope [l-i-fd/fc-fo sin pt] which has the same form as the familiar amplitude modulation envelope and whose percentage of modulation is fd/fc-fa Detector 8 of Fig. 1 has applied to one grid,
say, grid GI the voltage given by Equation (17) and to the other grid, say grid G2, the voltage given by Equation (3). Substituting these in Equation (8) gives as the variable output (neglecting direct current Aterms and radio frequency terms removed by detector output filter):
J=22 fdcm sin pf (18) From (18) it can be seen that the fundamental of the modulation is received free from harmonics and linearly dependent upon the depth of modulation.
The circuit of. Fig. 6 makes it possible to balance out the undesired amplitude modulation for the sloping filter type of circuit. .In the retard circuit type of detection, the amplitude modulation is inherently balanced out with the use of any of these receivers.
one detector only. In order to balance out the amplitude modulation when sloping lters as in Fig. l are used, a differential detection arrangement as shown in Fig. 6 must be utilized.
Referring to Fig. 6, intermediate frequency energy from a superheterodyne receiver is fed to transformer 29 and distributed to coupling tubes 30, 3| and 32. In the plate of coupling tube 30 is a filter providing a characteristic as shown in Fig. 3. In the plate of coupling tube3| is a filter providing a characteristic of opposite slope to Fig. 3, such as shown in Fig. '7. The outputs of filters 33 and 34 are fed to detector grids GI of detectors 36 and 31. The output of coupling tube 32 is fed via aperiodic impedance coupling 35 to the second grids G2 of detectors 36 and 31. Filters 38 and 39 remove the carrier energy from the detector output. Transformer 40 combines the detector outputs in the push-pull or series connection, depending upon the position of switch S2. The output is made available at jack 4I. For frequency modulation reception, switch Sz would have the push-pull connection. For amplitude modulation reception, the parallel connection would be used. When frequency modulation is being received, the amplitude modulation would be balanced out and when amplitude modu1a tion is being received, the frequency modulation would be balanced out. y
From the preceding mathematics, it is fairly easy to understand the balancing action of the circuit of Fig. 6. Since the two filters have opposite slopes, the amplitude modulation envelopesv fed to the two detectors will be degrees out of phase and their detected outputs will combine inphase with the push-pull connection of transformer 4U. The undesired amplitude modulation will be unaffected by the filters and Will produce detector outputs in-phase; consequently, the push-pull connection will cancel or balance out the undesired amplitude modulation.
In the circuit of Fig. 6 it would be possible to substitute an aperiodic coupling, such as 'an impedance or resistance coupling, as shown in Fig. 6a, in place of one of the filters 33 or 34. This would make one of the detectors receive the frequency modulation plus the undesired amplitude modulation and the other detector, only th; undesired amplitude modulation. Consequently, the push-pull connection of transformer 40 would balance out the undesired amplitude modulation and leave the frequency modulation.
As is well known in the art of frequency modulation, limiting could be used in conjunction with In the case of the sloping filter type circuit, if limiting were used, the balanced circuits of Fig. 6 and 6a. would not be required since the limiter would remove the'undesired amplitude modulation. The limiter could be inserted at the points X in the intermediate frequency leads following the intermediate frequency amplifier of any of the circuits or could be inserted in the radio `frequency circuits at the points Y, if desired.
Any of these receivers could be used for the reception of phase modulation by the addition of a correction circuit following the output jack. This correction circuit would have its output inversely proportional to the modulation frequency as is described in my U. S. appln. Ser. No. 618,154, filed June 20, 1932.
The principle described in my U. S. appln. Ser. No. 25,026, filed June 5, 1935, wherein frequency multiplication is employed at the receiver to increase the depth of modulation, could be applied to the receiver of Figs. 2 and 2a as well as the one of Fig. 1. 'I'his would probably be most convenientlyaccomplished by tuning oscillaterV 4 to approximately twice the signal frequency and operating the grids of detector 3 at points "b of their characteristics.
What is claimed is:
1. In a system for demodulating a -frequency modulated wave, a wave retarding circuit comprising inductive and capacitive reactances, means for applying frequency modulated waves to be demodulated to said circuit to produce therein wave energy of a phase directly proportional to the frequency modulations on the applied wave, a thermionic tube having a plurality of control electrodes, a circuit connecting one of said control electrodes to a point on said wave retarding circuit to apply produced wave energy to said control electrode, and a circuit coupling the other of said control electrodes to said means to apply original frequency modulated wave en- Y,
ergy to said other electrode.
2. In a system for demodulating a frequency modulated wave, a wave retarding circuit comprising inductive and' parallel capacitive reactances, means for applying frequency modulated waves to be demodulated to said circuit to produce therein wave energy of a phase directly proportional to the frequency modulations on the applied wave, a thermionic tube having an anode, a cathode and a plurality of grid-like electrodes,
a connection between one of said grid-like electrodes and a point on said wave retarding circuit to impress produced energy on said one of said grid-like electrodes, a connection between the other of said grid-like electrodes and said means to apply original frequency modulated wave energy to said other electrode, means for applying biasing potentials between said gridlike electrodes and said cathode, and an indicator coupled to the anode of said tube.
3. A system as recited in claim 2 in which a low pass filter is interposed between said indicator and the anode of said tube.
4. In a system for demodulating a frequency modulated wave, wave receiving means, a thermionic tube having a cathode and a plurality of grid-like electrodes, a tuned reactance acting as a filter having a sloping characteristic connecting one of said grid-like electrodes to said wave receiving means, and an impedance acting as a filter having a characteristic which is uniform over the frequency range of the received wave 4coupling a second grid-like electrode in said tube to said wave receiving means.
5. In a system for demodulating amplitude or phase or frequency modulated waves, wave receiving means, a'plurality of thermionic tubes each having a plurality of grid-like electrodes, a cathode and an anode, separate circuits each including a filter having sloping characteristics which slope in opposite sense coupling like gridlike electrodes in said tubes to said wave receiving means to excite the said like grid-like electrodes differentially in accordance with. the amplitude variations superimposed on said moduulated waves passed by said filters, and a second circuit including a filter having a flat topped characteristic coupling like grid-like electrodes in each of said tubes in phase to said wave receiving means.
6. A system as recited in claim 5 in which each of said separate circuits includes a coupling tube.
7. In a system for demodulating amplitude or phase or frequencymodulated waves, wave rephase or frequency modulated wave, wave receiving'means, a plurality of electron discharge tubes each having a plurality of grid-like electrodes, a cathode and an anode, two circuits each including a filter having sloping characteristics which slope in opposite sense coupled at their outputs to like grid-like electrodes in said tubes, a third circuit including an impedance coupled at its output to like grid-like electrodes in each of said` tubes, and a separate coupling tube coupling the input of each of said circuits to said wave receiving means.
9. In an amplitude or phase or frequency modulated wave demodulating system, wave receivingv means, wave amplifying means coupled to said receiving means, frequency multiplying means coupled to said amplifying means, a pair of electron discharge tubes each having a control grid and an anode, a circuit connecting the control grids of both of said tubes to the output of said frequency multiplier, a filter circuit having a sloping characteristic coupled to the anode of one of said tubes, a circuit having a fiat topped characteristic coupled to the anode of the other of said tubes, a detector tube having an anode, a cathode and a plurality of grid-like electrodes, a connection between one of the gridlike electrodes of said detector tube and the filter circuit ofsloping characteristics connected with the anode of one of said irst named tubes, and a circuit connectinganother grid-like electrode of said detector tube to said circuit having a at topped characteristic connected with the anode of the other of said ilrst named tubes.
10. In a phase or frequency modulated wave demodulating means, signal receiving l and amplifying means, a frequency multiplier lconnected to said amplifying means, said frequency multiplier having an output, two thermionic coupling tubes each having a control grid a cathode and ananode, a circuit coupling the control grid and cathode of each of said coupling tubes in\ phase to the output of said frequency multiplier, a filter circuit having a sloping characteristic coupled to the anode of one of. said coupling tubes, a separate filter circuit having a flat topped characteristic coupled to the anode of the second of said coupling tubes, a thermionic detector having a cathode, and a plurality of grid-like electrodes, and circuits connecting said filter circuits to different grid-like electrodes in said detector tube..
11. In a frequency or phase modulated wave demodulating means, -wave receiving means, a frequency multiplier connected to said wave receivlng means, three thermionic coupling tubes each having a control grid a cathode and an.
anode, a circuit coupling the control grid and cathode of each of said coupling tubes to said frequency multiplier, a filter circuit having a sloping characteristic coupled to the anode of one of said coupling tubes, a lter circuit having a characteristic which slopes in a different direction with respect to the characteristic of said rst named filter circuit coupled to the anode of the second of said coupling tubes, an impedance coupled to the anode of the third of said coupling tubes, a pair of thermionic detector tubes each having a cathode and a plurality of grid-like electrodes, circuits connecting said filter circuits in push-pull relation to like grid-like electrodes in said pair of detector tubes, and a circuit coupling said impedance in parallel to other like grid-like electrodes in said detector tubes.
12. In a system for demodulating a phase or frequency modulated wave, wave receiving means, an electron discharge tube having an output electrode, a cathode and a plurality of control electrodes, a circuit including a filter whose attenuation varies substantially linearly with the frequency of the received frequency modulated wave connecting one of said control electrodes to said Wave receiving means, an additional circuit including a filter whose attenuation is substantially uniform for all frequencies of the received frequency modulated Wave coupling a second control electrode in said tube to said wave receiving means, and an output circuit connected with the output electrode of said tube.
13. A system as recited in claim 12 in which a low pass iilter is connected in said output circuit.
14. In a system for demodulating a phase or frequency modulated Wave, means for receiving said wave, an electron discharge tube having an anode, a cathode and a plurality of grid-like electrodes, a circuit including a lter connecting one of saidgrid-like electrodes to said Wave receiving means to impress wave energy on said grid-like electrode from said receiving means,
an additional circuit including an impedance coupling a second grid-like electrode in said tube to said wave receiving means to impress additional wave energy on said second grid-like electrode from said wave receiving means, said circuits'having outputs which vary in different respects relative to the variations in phase or frequency of the received wave energy, biasing means connected between the cathode of said tube and each grid-like electrode', and a utilization circuit coupled to said anode and cathode.
15. The method of demodulating phase or frequency modulated Wave energy by means of an electron discharge device having a plurality of control electrodes, a cathode, and an anode, which consists in producing wave energy the phase of which is varied asa function of the phase or frequency modulations of the said phase or frequency modulated Wave energy, applying said produced Wave'energy between the cathode and one of said control electrodes, applying phase or frequency modulated Wave energy whose phase has not been so altered between the other of said control electrodes and the cathode, andA biasing both of said control electrodes relative to the cathode by potentials such that said tube operates on the vlinear portion of the control electrode potential plate current characteristic curves, and utilizing the resultant energy from the anode and cathode of said tube.
16. In a signalling system,l a source of phase or frequencyor amplitude modulated wave energy, three electron discharge devices each having a control grid, a cathode and an anode, a circuit coupling the control gridsand cathodes of all of said tubes in parallel to said source of modulated wave energy, a lter circuit having a sloping characteristic connected at its input to the anode and cathode of one of said tubes, said lter circuit having an output, a second filter circuit having a sloping characteristic connected at its input to the anode and cathode of a second one of said tubes, a pair of electron discharge detector tubes each having a plurality of control electrodes, a cathode and an anode, circuits cony necting the outputs of said filter circuits in pushf pull relation to like control electrodes in said detector tubes, a circuit having a flat topped characteristic connected at its input to the anode of the third of said first named three tubes, said last named circuit having an output, means connecting the output of said last named circuit in parallel with other like control electrodes in said pair of detector tubes, and means for connecting the anodes of said detector tubes in push-pull or in parallel.
MURRAY G. CROSBY.
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US25231A US2087429A (en) | 1935-06-06 | 1935-06-06 | Phase and frequency modulation wave receiving system |
DER96495D DE675778C (en) | 1935-06-06 | 1936-06-07 | Device for demodulating frequency or phase modulated vibrations |
GB16035/36A GB470131A (en) | 1935-06-06 | 1936-06-08 | Improvements in modulated carrier wave receivers |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US25231A US2087429A (en) | 1935-06-06 | 1935-06-06 | Phase and frequency modulation wave receiving system |
Publications (1)
Publication Number | Publication Date |
---|---|
US2087429A true US2087429A (en) | 1937-07-20 |
Family
ID=21824806
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US25231A Expired - Lifetime US2087429A (en) | 1935-06-06 | 1935-06-06 | Phase and frequency modulation wave receiving system |
Country Status (3)
Country | Link |
---|---|
US (1) | US2087429A (en) |
DE (1) | DE675778C (en) |
GB (1) | GB470131A (en) |
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2488936A (en) * | 1940-12-12 | 1949-11-22 | Rca Corp | Frequency-modulation recording and reproducing and its combination with a radio receiver |
US2510906A (en) * | 1945-03-24 | 1950-06-06 | Avco Mfg Corp | Frequency modulation receiver |
US2531866A (en) * | 1947-01-14 | 1950-11-28 | Hartford Nat Bank & Trust Co | Mixing detector circuit for detecting frequency-modulated oscillations |
DE874926C (en) * | 1937-10-01 | 1953-04-27 | Hazeltine Corp | Reception method for oscillations of variable frequency |
US2835802A (en) * | 1953-10-12 | 1958-05-20 | James R Day | Linear frequency modulation detector |
US2896162A (en) * | 1953-10-30 | 1959-07-21 | Gen Precision Lab Inc | Heterodyne autocorrelator |
FR2171440A1 (en) * | 1972-02-12 | 1973-09-21 | Ted Bildplatten |
Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
BE469561A (en) * | 1942-05-06 | |||
NL66962C (en) * | 1947-02-20 | 1900-01-01 | ||
DE927577C (en) * | 1950-10-21 | 1955-05-12 | Busch Jaeger Duerener Metall | Connection and junction box recessed in the plaster |
DE980076C (en) * | 1950-10-24 | 1969-03-06 | Fernseh Gmbh | Arrangement for synchronizing deflection devices |
DE969436C (en) * | 1951-04-26 | 1958-06-04 | Lorenz C Ag | Arrangement for demodulating frequency or phase modulated oscillations |
DE872229C (en) * | 1951-05-31 | 1953-04-13 | Siemens Ag | Circuit for converting frequency changes of an oscillation into current or voltage fluctuations that follow these changes |
-
1935
- 1935-06-06 US US25231A patent/US2087429A/en not_active Expired - Lifetime
-
1936
- 1936-06-07 DE DER96495D patent/DE675778C/en not_active Expired
- 1936-06-08 GB GB16035/36A patent/GB470131A/en not_active Expired
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE874926C (en) * | 1937-10-01 | 1953-04-27 | Hazeltine Corp | Reception method for oscillations of variable frequency |
US2488936A (en) * | 1940-12-12 | 1949-11-22 | Rca Corp | Frequency-modulation recording and reproducing and its combination with a radio receiver |
US2510906A (en) * | 1945-03-24 | 1950-06-06 | Avco Mfg Corp | Frequency modulation receiver |
US2531866A (en) * | 1947-01-14 | 1950-11-28 | Hartford Nat Bank & Trust Co | Mixing detector circuit for detecting frequency-modulated oscillations |
US2835802A (en) * | 1953-10-12 | 1958-05-20 | James R Day | Linear frequency modulation detector |
US2896162A (en) * | 1953-10-30 | 1959-07-21 | Gen Precision Lab Inc | Heterodyne autocorrelator |
FR2171440A1 (en) * | 1972-02-12 | 1973-09-21 | Ted Bildplatten |
Also Published As
Publication number | Publication date |
---|---|
GB470131A (en) | 1937-08-10 |
DE675778C (en) | 1939-05-19 |
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