US2303542A - Receiving system - Google Patents

Receiving system Download PDF

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US2303542A
US2303542A US410495A US41049541A US2303542A US 2303542 A US2303542 A US 2303542A US 410495 A US410495 A US 410495A US 41049541 A US41049541 A US 41049541A US 2303542 A US2303542 A US 2303542A
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output
energy
channels
channel
carrier
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US410495A
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Goddard De Witt Rugg
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/10Polarisation diversity; Directional diversity
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B1/00Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
    • H04B1/06Receivers
    • H04B1/16Circuits
    • H04B1/26Circuits for superheterodyne receivers

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  • the present invention relates to a receiving system in which an ordinary amplitude, frequency or phase modulated signal may be made to provide diversity effect.
  • an ordinary amplitude, frequency or phase modulated signal may be made to provide diversity effect.
  • it has beennecessary to use spaced antennas or antennas of diiierent polarizations, directivities, etc., to obtain a ldiversity effect.
  • these systems did not provide any means,V to reduce the distortion due to selective fading.V
  • An object, therefore, ofthe present invention is to provide a diversity effect in a radio receiving system using only a single antenna.
  • ⁇ Another object of the present invention is to reduce the effect of frequency selective fading.
  • Still another object is to provide a receiving system in which it is not necessary to used spaced antennas or antennas of different polarizations or directivities in order to obtain a diversity effect.
  • Still a further objectof the present invention is to provide a radio receiving system which may also be used with spaced antennas or antennas of different polarizations and/or directivities to further increase the diversity effect and to further decrease the effects 0f frequency selective fading.
  • a radio receiver operated from a single antenna and including a single channel high frequency amplifier, a mixer, a multi-channel intermediate frequency amplifier having one channel which is tuned to pass the carrier frequency only, another of which passes the upper side bands of the signal only and the other of which passes the lower side band only r of the signal.
  • the outputs of the two side band channels are separately combined with a portion of the output of the carrier channel and applied to separate rectiiiers.
  • the output of the rectifiers iscombined to provide the audio ⁇ frequency output of the system.
  • the single figure of the drawing shows an antenna feeding a high frequency amplifier I which, in turn, feeds converter 2 where the signal is combined with the output of oscillator 3 to produce an intermediate frequency signal which is applied tothe intermediate frequency channels 4, 5 and 6.
  • 'A portion of the converter output or intermediatefrequency is also applied to a recti- :lier I4 where it is rectied and the resultant direct current used in a conventional manner in radio frequency amplifier I to control the gain thereof.
  • the intermediatefrequency signal output from converter 2 is maintained at a sub- ⁇ stantially constant amplitude in spite of variations in signal input to the antenna.
  • Intermediate frequency channel 4 is tuned to pass only the upper set of side bands accompanying the converted radio frequency signal; channel 6 is tuned to pass only the lower set of side bands while channe1'5 is arranged to pass only the converted carrier frequency.
  • Each of channels 4, 5 and 6 may contain, in addition to the required filter networks for frequency separation, as many stages of amplification as may be deemed necessary.
  • channel 5 carrying the converted carrier only passes through limiter 'I and is applied to coupling units 9 and I Channel 4 which carries the upper side bands has its output connected to av coupling unit 8 and channel 6 has its output -connected to coupling unit Il.
  • the output of coupling units 8 and 9 is combined in rectifier I2 to produce an audio signal representative of the modulations'on the received signal.
  • the output of coupling ⁇ units III and I I is combined in rectifier I3 to likewise produce an audio output. ⁇
  • the audio output from rectiers I2 and I3 is combined to produce a single audio frequency signal. .Y
  • part ofthe output from intermediate frequency channel 4 is fed through transformer I5 and diode rectifier I8 -toresistor 20. Also, part of the output from intermediate frequency channel 6 is fed through transformer I6 and diode rectifier I'I to ⁇ resistor I9. These resistors are connected in series oppositionk and in series with bias battery 23. From the hignpotential side of resistor I9 automatic gaincontrol is obtained for intermediate Lfrequency channel B while automatic gain control for intermediate frequency channel 4 is obtained from the same point by passing through diode 2l and bucking battery 22 which reverses lthe control voltage polarity.
  • the potential across resistor I9 will be greater than the potential across resistor 20 and the resultant bias voltage at the high side of resistor I9 will be less than before, so the bias on'intermediate frequency channel 6 will decrease while the bias on inter ⁇ mediate frequency channel 4 will, due to the interposition of polarity reversing tube 2I and battery 22, increase, resulting in a further increased signal from intermediate frequency channel 6 and a decreased signal from intermediate frequency channel 4.
  • the audio signal output is then largely from rectifier I3.
  • a limiter 1 following the carrier intermediate frequency channel 5. This may not, in all cases, be essential as the rectifier I4 and its associated gain control circuit tends to hold the signal constant, but a limiter in this position tends to further maintain the amplitude of the carrier channel constant.
  • the separation of the received signal into separate channels and the re-combination into two channels each capable of supplying an audio frequency signal allows several things to be accomplished. First, it provides two signals neither of which is seriously bothered by a second harmonic distortion should the carrier fade to a value such that the modulation thereon is greater than that corresponding to 100% modulation. This is not true of a diode signal derived from the carrier and both upper and lower side bands combined. Second, it removes audio distortion due to some of the upper and lower side bands becoming out of phase with each other and neutralizing each other since the relative phase relationships of the side bands disappear after rectification.
  • the resultant audio signal might consist of a composite of 20% of the modulation band .from the lower set of side bands and 80% from the upper set of side bands. Further, the 20% from the lower set of side bands might be divided up unevenly throughout the band as, for instance, from the components nearest the carrier and from the central portion of the side band envelope.
  • a radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels passing one group of the side band frequencies, means for separately combining the energy in each of said side. band channels with a portion of the energy in said carrier channel, means for separately rectifying each of said combined energies and means for combining the output from each of said rectifying means, means for separately rectifying a portion of the energy in each of said side band channels, means for comparingA said last mentioned rectified energies and means responsive to said comparison for discriminating against the energy in one of said channels.
  • a radio receiver including means for receiving modulated high frequency energy, selective means for separating said-energy into a plurality of separate bands, separate ampliers for each of said bands, one of said amplifiers for the carrier frequency and each of the other amplifiers for one group of the side band frequencies, means for separately combining the output of the amplifiers for each of said side band frequencies with a portion of the output of said carrier amplifier, means for separately rectifying each of said combined outputs and means for combining the output from each of said rectifying means, means for separately rectifying a portion of the energy in each of said side band amplifiers, means for comparing said last mentioned rectified energies and means responsive to said comparison for decreasing the gain in one of said side band amplifiers and increasing the gain in the other of said amplifiers.
  • a radio receiver including means for receiving modulated high frequency energy, selectIve means for separating said energy into a plurality ofseparate bands, separate amplifiers for each of said bands, one of said amplifiers for the carrier frequency and each of the other amplifiers for one group of the side band frequencies, means for separately combining the output of the ampliers for each of said side band frequencies with a portion of the output of said carrier ampliiier, means for separately rectifying each of said combined outputs and means for combining the output from each of said rectifying means,
  • a radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels passing one group of the side band frequencies, means for separately combining the energy in each of said side band channels with a portion of the energy in said carrier channel, means for separately rectifying each of said combined energies and means for combining the output from each of said rectifying means, means for comparing the energies in each of said side band channels and means responsive to said comparison for decreasing the output of one of said side band channels which carries the lesser enelgy.
  • a radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels containing one group of the side band frequencies, means for separately combining the energy in each of said side band channels With a portion of the energy in said carrier channel, means for separately rectifying each of said combinecl energies and means for combining the output from each of said rectifying means, means for comparing the energies in each of said side band channels and means responsive to said comparison for discriminating against the energy in the one of said channels which has the lesser energy therein, limiting means in said carrier channels for preventing the energy in said channel from exceeding a predetermined maximum.
  • a radio receiver including means for receiving modulated high frequency energy, means for amplifying said energy, means for converting said energy to an intermediate frequency, means responsive to the amplitude of said converted energy for controlling the gain of said high frequency amplifier, selective means for separating said converted energy into a plurality of separate channels, one of said channels passing the converted carrier frequency and each of the other channels passing one group of converted side band frequencies, amplifier means in each of said channels, means for separately rectifying a portion of the energy in the output of each of said amplifiers, means for comparing said rectied energies and means responsive to said comparison for decreasing the gain in the one of said amplifiers which passes the lesser energy and means for increasing the gain of the amplifier passing the greater energy, means for combining the output of each of said side band amplifiers with a portion of the output of said carrier amplier, means for separately rectifying-each of said separate combined outputs and means for combining the output from each of said rectifying means.
  • a radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels passing one group of side band frequencies, amplifier means in each of said channels, means for separately rectifying a portion of the energy in the output of leach of said ampliers, means for comparing said rectified energies and means responsive to said comparison for decreasing the gain in the one of said ampliers f which passes the weaker energy and means for increasing the gain of the amplifier passing the stronger of said frequencies, means for combining the output of each of said side band amplifiers with a portion of the output of said carrier amplifier, means for separately rectifying each of said separate combined outputs and means for combining the output from each of said rectifying means.

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Radio Transmission System (AREA)

Description

Dec. l, 1942. DE wlTT R. GODDARD 13ECEIVING SYSTEM Filed sept. 12, 1941 Patented Dec. 1, 1942 RECEIVING SYSTEM De Witt Rugg Goddard, Riverhead, N. Y., assignor to Radio Corporation of America, a corporation of Delaware Application September 12, 1941, Serial No. 410,495
7 Claims.
The present invention relates to a receiving system in which an ordinary amplitude, frequency or phase modulated signal may be made to provide diversity effect. In the past, as far as I am aware, it has beennecessary to use spaced antennas or antennas of diiierent polarizations, directivities, etc., to obtain a ldiversity effect. Furthermore, these systems did not provide any means,V to reduce the distortion due to selective fading.V
An object, therefore, ofthe present invention is to provide a diversity effect in a radio receiving system using only a single antenna.
`Another object of the present invention is to reduce the effect of frequency selective fading.
1 Still another object is to provide a receiving system in which it is not necessary to used spaced antennas or antennas of different polarizations or directivities in order to obtain a diversity effect.
Still a further objectof the present invention is to provide a radio receiving system which may also be used with spaced antennas or antennas of different polarizations and/or directivities to further increase the diversity effect and to further decrease the effects 0f frequency selective fading.
The foregoing objects and others, which may appear from the following detailed des-cription, are obtained by utilizing a radio receiver operated from a single antenna and including a single channel high frequency amplifier, a mixer, a multi-channel intermediate frequency amplifier having one channel which is tuned to pass the carrier frequency only, another of which passes the upper side bands of the signal only and the other of which passes the lower side band only r of the signal. The outputs of the two side band channels are separately combined with a portion of the output of the carrier channel and applied to separate rectiiiers. The output of the rectifiers iscombined to provide the audio `frequency output of the system.
The present invention will be more fully understood by reference to the followingdetailed description which is accompanied by a drawing in which the figure illustrates in block diagram form an embodiment of the present invention.
The single figure of the drawing shows an antenna feeding a high frequency amplifier I which, in turn, feeds converter 2 where the signal is combined with the output of oscillator 3 to produce an intermediate frequency signal which is applied tothe intermediate frequency channels 4, 5 and 6. 'A portion of the converter output or intermediatefrequency is also applied to a recti- :lier I4 where it is rectied and the resultant direct current used in a conventional manner in radio frequency amplifier I to control the gain thereof. As a result, the intermediatefrequency signal output from converter 2 is maintained at a sub-` stantially constant amplitude in spite of variations in signal input to the antenna.
Intermediate frequency channel 4 is tuned to pass only the upper set of side bands accompanying the converted radio frequency signal; channel 6 is tuned to pass only the lower set of side bands while channe1'5 is arranged to pass only the converted carrier frequency. Each of channels 4, 5 and 6 may contain, in addition to the required filter networks for frequency separation, as many stages of amplification as may be deemed necessary.
The output of channel 5 carrying the converted carrier only passes through limiter 'I and is applied to coupling units 9 and I Channel 4 which carries the upper side bands has its output connected to av coupling unit 8 and channel 6 has its output -connected to coupling unit Il. The output of coupling units 8 and 9 is combined in rectifier I2 to produce an audio signal representative of the modulations'on the received signal. The output of coupling `units III and I I is combined in rectifier I3 to likewise produce an audio output.` The audio output from rectiers I2 and I3 is combined to produce a single audio frequency signal. .Y
Now, in order to obtain a diversity effect, part ofthe output from intermediate frequency channel 4 is fed through transformer I5 and diode rectifier I8 -toresistor 20. Also, part of the output from intermediate frequency channel 6 is fed through transformer I6 and diode rectifier I'I to `resistor I9. These resistors are connected in series oppositionk and in series with bias battery 23. From the hignpotential side of resistor I9 automatic gaincontrol is obtained for intermediate Lfrequency channel B while automatic gain control for intermediate frequency channel 4 is obtained from the same point by passing through diode 2l and bucking battery 22 which reverses lthe control voltage polarity.
'Ihe diversity action of the present invention is obtained in the following manner. Part of the signal from channel 4 produces in `resistor I9- a direct current potential of one polarity, as indi--v cated, while part of the output from intermediate frequency channel 6 produces in resistor 20 a D. C. potential. of opposing polarity, also as indicated.
Now, if the lower-and upper sets of side bands are of equal. strength these potentials-will be equal and opposite and, therefore, buck out leaving a biasing potential for the amplifiers in channels 4 and 6 equal to that with battery 23 alone. If, however, the upper set of side bands is stronger than the lower set, then the potential across resistor 20 will be greater than the potential across resistor I9 and the resultant biasing Voltage in the high side of the resistor -I9 will be greater than before. This increase in bias reduces the gain of the amplifiers incorporated in intermediate frequency channel 6 and, due to the polarity reversing tube 2l, causes a decrease in bias on the amplifiers incorporated in intermediate frequency channel 4 resulting in a strong signal to coupling unit 8 and a weak signal to coupling unit II. The diode output from the system under these conditions is then largely from rectifier I2. If the lower set of the side bands is stronger than the upper set then the potential across resistor I9 will be greater than the potential across resistor 20 and the resultant bias voltage at the high side of resistor I9 will be less than before, so the bias on'intermediate frequency channel 6 will decrease while the bias on inter\ mediate frequency channel 4 will, due to the interposition of polarity reversing tube 2I and battery 22, increase, resulting in a further increased signal from intermediate frequency channel 6 and a decreased signal from intermediate frequency channel 4. The audio signal output is then largely from rectifier I3.
In the embodiment of the invention shown there is incorporated a limiter 1 following the carrier intermediate frequency channel 5. This may not, in all cases, be essential as the rectifier I4 and its associated gain control circuit tends to hold the signal constant, but a limiter in this position tends to further maintain the amplitude of the carrier channel constant.
The separation of the received signal into separate channels and the re-combination into two channels each capable of supplying an audio frequency signal allows several things to be accomplished. First, it provides two signals neither of which is seriously bothered by a second harmonic distortion should the carrier fade to a value such that the modulation thereon is greater than that corresponding to 100% modulation. This is not true of a diode signal derived from the carrier and both upper and lower side bands combined. Second, it removes audio distortion due to some of the upper and lower side bands becoming out of phase with each other and neutralizing each other since the relative phase relationships of the side bands disappear after rectification. Third, from the output of a single receiver it provides two channels that when demodulated and applied to a single audio frecuency output selects only the stronger audio components from the upper and lower side bands. Thus, the resultant audio signal might consist of a composite of 20% of the modulation band .from the lower set of side bands and 80% from the upper set of side bands. Further, the 20% from the lower set of side bands might be divided up unevenly throughout the band as, for instance, from the components nearest the carrier and from the central portion of the side band envelope.
While I have particularly shown and described several embodiments of my invention, it is to be clearly understood that my invention is not Alimited thereto but that modifications may be :made within the scope ofthe invention.
I claim:
1. A radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels passing one group of the side band frequencies, means for separately combining the energy in each of said side. band channels with a portion of the energy in said carrier channel, means for separately rectifying each of said combined energies and means for combining the output from each of said rectifying means, means for separately rectifying a portion of the energy in each of said side band channels, means for comparingA said last mentioned rectified energies and means responsive to said comparison for discriminating against the energy in one of said channels.
2.A radio receiver including means for receiving modulated high frequency energy, selective means for separating said-energy into a plurality of separate bands, separate ampliers for each of said bands, one of said amplifiers for the carrier frequency and each of the other amplifiers for one group of the side band frequencies, means for separately combining the output of the amplifiers for each of said side band frequencies with a portion of the output of said carrier amplifier, means for separately rectifying each of said combined outputs and means for combining the output from each of said rectifying means, means for separately rectifying a portion of the energy in each of said side band amplifiers, means for comparing said last mentioned rectified energies and means responsive to said comparison for decreasing the gain in one of said side band amplifiers and increasing the gain in the other of said amplifiers.
3. A radio receiver including means for receiving modulated high frequency energy, selectIve means for separating said energy into a plurality ofseparate bands, separate amplifiers for each of said bands, one of said amplifiers for the carrier frequency and each of the other amplifiers for one group of the side band frequencies, means for separately combining the output of the ampliers for each of said side band frequencies with a portion of the output of said carrier ampliiier, means for separately rectifying each of said combined outputs and means for combining the output from each of said rectifying means,
means for separately rectifying a portion of the energy in each of said side band ampliers, means for comparing said last-mentioned rectified energies and means responsive to said comparison for decreasing the gain in the one of said side band amplifiers which supplies the smaller of said compared rectified energies.
4. A radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels passing one group of the side band frequencies, means for separately combining the energy in each of said side band channels with a portion of the energy in said carrier channel, means for separately rectifying each of said combined energies and means for combining the output from each of said rectifying means, means for comparing the energies in each of said side band channels and means responsive to said comparison for decreasing the output of one of said side band channels which carries the lesser enelgy.
5. A radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels containing one group of the side band frequencies, means for separately combining the energy in each of said side band channels With a portion of the energy in said carrier channel, means for separately rectifying each of said combinecl energies and means for combining the output from each of said rectifying means, means for comparing the energies in each of said side band channels and means responsive to said comparison for discriminating against the energy in the one of said channels which has the lesser energy therein, limiting means in said carrier channels for preventing the energy in said channel from exceeding a predetermined maximum.
6. A radio receiver including means for receiving modulated high frequency energy, means for amplifying said energy, means for converting said energy to an intermediate frequency, means responsive to the amplitude of said converted energy for controlling the gain of said high frequency amplifier, selective means for separating said converted energy into a plurality of separate channels, one of said channels passing the converted carrier frequency and each of the other channels passing one group of converted side band frequencies, amplifier means in each of said channels, means for separately rectifying a portion of the energy in the output of each of said amplifiers, means for comparing said rectied energies and means responsive to said comparison for decreasing the gain in the one of said amplifiers which passes the lesser energy and means for increasing the gain of the amplifier passing the greater energy, means for combining the output of each of said side band amplifiers with a portion of the output of said carrier amplier, means for separately rectifying-each of said separate combined outputs and means for combining the output from each of said rectifying means.
7. A radio receiver including means for receiving modulated high frequency energy, selective means for separating said energy into a plurality of separate channels, one of said channels passing the carrier frequency and each of the other channels passing one group of side band frequencies, amplifier means in each of said channels, means for separately rectifying a portion of the energy in the output of leach of said ampliers, means for comparing said rectified energies and means responsive to said comparison for decreasing the gain in the one of said ampliers f which passes the weaker energy and means for increasing the gain of the amplifier passing the stronger of said frequencies, means for combining the output of each of said side band amplifiers with a portion of the output of said carrier amplifier, means for separately rectifying each of said separate combined outputs and means for combining the output from each of said rectifying means.
DE WITT RUGG GODDARD.
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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2529667A (en) * 1947-01-04 1950-11-14 Radio Electr Soc Fr Radio-electric transmitting system
US2858422A (en) * 1953-04-17 1958-10-28 Gen Dynamics Corp Frequency responsive system having two slope-tuned amplifiers with differential control of gain
US3002088A (en) * 1960-02-15 1961-09-26 Bertram A Trevor Agc for single sideband reception
US3005094A (en) * 1958-09-30 1961-10-17 Rca Corp Automatic gain control circuit
US3009114A (en) * 1957-02-13 1961-11-14 Loren P Meissner Frequency domain switch
US3060380A (en) * 1958-02-03 1962-10-23 Gen Electric Sideband detector circuit
US3120642A (en) * 1961-09-25 1964-02-04 Leonard R Kahn Automatic gain control in independent sideband type transmission systems and the like
US3195049A (en) * 1960-05-04 1965-07-13 Itt Radio diversity receiving system with automatic phase control

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2529667A (en) * 1947-01-04 1950-11-14 Radio Electr Soc Fr Radio-electric transmitting system
US2858422A (en) * 1953-04-17 1958-10-28 Gen Dynamics Corp Frequency responsive system having two slope-tuned amplifiers with differential control of gain
US3009114A (en) * 1957-02-13 1961-11-14 Loren P Meissner Frequency domain switch
US3060380A (en) * 1958-02-03 1962-10-23 Gen Electric Sideband detector circuit
US3005094A (en) * 1958-09-30 1961-10-17 Rca Corp Automatic gain control circuit
US3002088A (en) * 1960-02-15 1961-09-26 Bertram A Trevor Agc for single sideband reception
US3195049A (en) * 1960-05-04 1965-07-13 Itt Radio diversity receiving system with automatic phase control
US3120642A (en) * 1961-09-25 1964-02-04 Leonard R Kahn Automatic gain control in independent sideband type transmission systems and the like

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