US2179966A - Noise suppression circuits - Google Patents
Noise suppression circuits Download PDFInfo
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- US2179966A US2179966A US210419A US21041938A US2179966A US 2179966 A US2179966 A US 2179966A US 210419 A US210419 A US 210419A US 21041938 A US21041938 A US 21041938A US 2179966 A US2179966 A US 2179966A
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03G—CONTROL OF AMPLIFICATION
- H03G3/00—Gain control in amplifiers or frequency changers without distortion of the input signal
- H03G3/20—Automatic control
- H03G3/22—Automatic control in amplifiers having discharge tubes
- H03G3/26—Muting amplifier when no signal is present or when only weak signals are present, or caused by the presence of noise, e.g. squelch systems
Definitions
- This invention relates to radio and like receivers and has for its object to provide improved so-called noise suppression circuits for such receivers.
- the demodulating detector of a radio or similar receiver is normally held inoperative by a biasing voltage drop which is set up across a resistive impedance which is, also, included in a rectifier circuit the anode of which is connected to a point which is normally maintained positive with respect to earth by a voltage drop set up across a second resistive impedance.
- the second resistive impedance is in the cathode-anode circuit of a valve which is normally conductive, but whose bias is controlled by the voltage drop set up across a third resistive impedance in the circuit of a further rectifier to which received signals are applied, the whole arrangement being such that ,when signals of a predetermined strength are received the bias on the said Valve is reduced, the anode current thereof is reduced, the said point becomes less positive with respect to earth, and the voltage drop across the first mentioned resistive impedance is accordingly reduced until, when signals of a strength suitable for reproduction are received, the last mentioned voltage drop is reduced so far that the demodulating detector is rendered operative.
- the demodulating detector and the rectifier whose anode point is connected to the point which is normally positive with respect to earth, form parts of a double diode having a common cathode, and preferably also the valve, the further rectifier and an additional rectifier, from whose circuit automatic volume control potentials are derived, are constituted by parts of a double diode triode.
- valve i in the last carrier stage of the receiver which stage may be a radio frequency stage but will most usually be the last intermediate frequency stage of a superheterodyne receiver, has" in its anode circuit a carrier frequency tuned circuit 2 coupled to a second carrier frequency tuned circuit 3, one end of which is connected to one anode t of a double diode ii and the other end of which is connected through a resistance 6, shunted by a capacity 1, to earth.
- the diode anode 4 constitutes, in conjunction with the common cathode it of the double diode, the demodulating detector of the receiver and the said cathode 8 is connected to earth through a resistance 9 shunted by a capacity H).
- the second anode ii of the double diode is connected to the cathode I2 of a double diode triode t3, the triode portion of which acts as an automatic volume control amplifier.
- the first diode anode i l of the double diode triode i3 is connected to the cathode l2 thereof through a resistance l5, and the second diode anode 16 of the said double diode triode i3 is connected to earth through a resistance it.
- the junction point of resistance H with the anode i6 is the point from which automatic volume control (designated as AVC) potentials are derived for application to the valve, or valves, of the receiver to be controlled, the AVG lead (i8 is an AVC lead) having associated therewith the usual filter resistance and condenser (such as 99, 20) for smoothing the AVG potential.
- AVC automatic volume control
- the control grid ii of the double diode triode I3 is connected to the cathode 52 through a condenser 22, and is also connected to the diode anode it through a resistance 23.
- a coupling condenser 24 is connected between the anode 25 of the valve I and the diode anode i l.
- the anode 26 of the triode section of the double diode triode I3 is connected either (as shown) through an anode resistance 21, or direct to the positive terminal 28, of a source of anode potential, and the cathode l2 of the said double diode triode is connected through a resistance 36 to the negative terminal 29 of the said source.
- the terminal 29 is connected through a choke 38 to earth and to the cathode return lead of the first audio frequency amplifier valve 3
- the grid 32 of the said valve 3i is connected through a coupling condenser 33 to a tapping point 34 (which may be made adjustable for manual control purposes) upon the resistance 6.
- the lead to the tap 3t may include a high frequency filter circuit consisting of a resistance 35 and a condenser 38.
- the elements 22 and 23 are designed to filter out the detected audio components produced across resistance 55 and an additional resistance 3'? is inserted between grid 2i and the junction point of elements 22 and 23.
- the output audio voltage from the double diode triode is then developed across any suitable impedance such as the resistance 2'5 or an audio frequency choke, or a transformer primary, in the anodecathode circuit of the triode section.
- the whole arrangement is such that normally the voltage drop developed across the resistance 38 by the anode current of the triode section of the double diode triode is greater than the voltage drop across the choke to so that the cathode of the double diode triode is positive with respect to earth, and the second diode 8l I of the double diode passes current and the voltage drop across the resistance 9 is sufficient to bias the demodulating diode back so that it is inoperative to demodulate incoming signals.
- the si nal strength applied to the diode i -EQ of the double diode triode increases sufficiently, the voltage drop across the resistance l5 drives the grid PE!
- the time constant provided by the resistance 9 and shunt condenser II! should be approximately equal to that provided by the resistance 6 and shunt condenser E, and the value of the said resistance 9 should be about one-tenth, or less, of the value of the said resistance 6.
- Change of position of the point of suppression may be achieved by changing the cathode bias of one or more of the gain controlled carrier frequency valves of the receiver, and/or by deriving the voltage on the anode of the triode section of the double diode triode either from an adjustable tappin on a potentiometer resistance connected between the positive terminal of the source of anode potential and earth, or from an adjustable series resistance between the anode of the said triode section and the said positive terminal.
- the demodulating detector is biased only for noise suppression, and. all bias is quickly removed as soon as the suppression point is passed allowing normal and, therefore, substantially distorticnless operation of the detector thereafter.
- One end of the audio frequency output resistance (the resistance 6 in Figs. 1. and 2) is earthed thus avoiding liability of hum pickup from the source of negative voltage for producing the AVG voltage. In mains-driven sets this source is often the field coil of a moving coil loudspeaker. This earthing of the audio frequency output resistance at one end also assists in preventing audio frequency break through when the normal volume control (the tapping 3 1 on the resistance 6) is set to zero.
- the double diode triode is not employed as an audio frequency amplifier, and, therefore, liability to instability and distortion due to varying bias on the grid of the triode section of the double diode triode is avoided altogether.
- a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator inefiective to produce demodulation voltage, and connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current fiow through the impedance decreasing below a predetermined value.
- a demodulator coupled to said network and including a demodulation voltage output circuit
- a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, means for producing a gain control potential for said network, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said econd rectifier to said demodulator so as to cause said second direct voltage to render the demodulator ineifective to produce demodulation volta e, and connections between said second rectifier and said impedance for rendering said second rectifier inefiective upon the current flow through the impedance decreasing below a predetermined value.
- a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator ineffective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current flow through the impedance decreasing below a predetermined value, and means, responsive to said decreased current flow through said impedance, for producing a gain control voltage for the network.
- a demodulator coupled to said network and including a demodulation voltage output circuit
- a control circuit for the receiver comprising a signal rectifier coupled to said nework and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current fiow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator inefiective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current flow through the impedance decreasing below a predetermined value
- said network including a pair of cascaded resonant circuits tuned to a desired carrier frequency, said demodulator being coupled to the second resonant circuit, and said two
- a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator inefiective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current flow through the impedance decreasing below a predetermined value, and means for connecting said demodulation voltage output circuit to said electron discharge device whereby the latter amplifies said demodulation voltage.
- demodulator coupled to said network and including a demodulation voltage output circuit
- a control circuit for the receiver comprising a signal rectifier coupled to said nework and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator ineffective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current fiow through the impedance decreasing below a predetermined value, the electrodes of said demodulator and second rectifier being provided by a tube having a common cathode and two anodes, and the electrodes of the first rectifier being housed within the envelope of said discharge device.
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Description
K. R. STURLEY NOISE SUPPRESSION CIRCUITS Nov. 14, 1939. I
Filed May 2'7, 193s INVENTOYR KENNETH R. .STURLE Y BY 7Kgwv AZFIZORNEY Patented Nov. 14, 1939 UNITED STATES Z,ll9,966
rarest series NOISE SUPPRESSION CIRCUITS Application May 2'7, 1938, Serial No. 210,419 In Great Britain July 15, 1937 6 Claims.
This invention relates to radio and like receivers and has for its object to provide improved so-called noise suppression circuits for such receivers.
For the sake of convenience of terminology the Word normally will be employed in the description which follows to indicate that state of affairs which exists in the absence of incoming signals. According to this invention the demodulating detector of a radio or similar receiver is normally held inoperative by a biasing voltage drop which is set up across a resistive impedance which is, also, included in a rectifier circuit the anode of which is connected to a point which is normally maintained positive with respect to earth by a voltage drop set up across a second resistive impedance. The second resistive impedance is in the cathode-anode circuit of a valve which is normally conductive, but whose bias is controlled by the voltage drop set up across a third resistive impedance in the circuit of a further rectifier to which received signals are applied, the whole arrangement being such that ,when signals of a predetermined strength are received the bias on the said Valve is reduced, the anode current thereof is reduced, the said point becomes less positive with respect to earth, and the voltage drop across the first mentioned resistive impedance is accordingly reduced until, when signals of a strength suitable for reproduction are received, the last mentioned voltage drop is reduced so far that the demodulating detector is rendered operative. Preferably the demodulating detector and the rectifier, whose anode point is connected to the point which is normally positive with respect to earth, form parts of a double diode having a common cathode, and preferably also the valve, the further rectifier and an additional rectifier, from whose circuit automatic volume control potentials are derived, are constituted by parts of a double diode triode.
The invention is illustrated in the accompanying drawing which shows diagrammatically two embodiments of the invention in Figs. 1 and 2.
Referring to Fig. 1 the valve i in the last carrier stage of the receiver, which stage may be a radio frequency stage but will most usually be the last intermediate frequency stage of a superheterodyne receiver, has" in its anode circuit a carrier frequency tuned circuit 2 coupled to a second carrier frequency tuned circuit 3, one end of which is connected to one anode t of a double diode ii and the other end of which is connected through a resistance 6, shunted by a capacity 1, to earth. The diode anode 4 constitutes, in conjunction with the common cathode it of the double diode, the demodulating detector of the receiver and the said cathode 8 is connected to earth through a resistance 9 shunted by a capacity H). The second anode ii of the double diode is connected to the cathode I2 of a double diode triode t3, the triode portion of which acts as an automatic volume control amplifier. The first diode anode i l of the double diode triode i3 is connected to the cathode l2 thereof through a resistance l5, and the second diode anode 16 of the said double diode triode i3 is connected to earth through a resistance it. The junction point of resistance H with the anode i6 is the point from which automatic volume control (designated as AVC) potentials are derived for application to the valve, or valves, of the receiver to be controlled, the AVG lead (i8 is an AVC lead) having associated therewith the usual filter resistance and condenser (such as 99, 20) for smoothing the AVG potential.
The control grid ii of the double diode triode I3 is connected to the cathode 52 through a condenser 22, and is also connected to the diode anode it through a resistance 23. A coupling condenser 24 is connected between the anode 25 of the valve I and the diode anode i l. The anode 26 of the triode section of the double diode triode I3 is connected either (as shown) through an anode resistance 21, or direct to the positive terminal 28, of a source of anode potential, and the cathode l2 of the said double diode triode is connected through a resistance 36 to the negative terminal 29 of the said source. The terminal 29 is connected through a choke 38 to earth and to the cathode return lead of the first audio frequency amplifier valve 3| of the receiver. The grid 32 of the said valve 3i is connected through a coupling condenser 33 to a tapping point 34 (which may be made adjustable for manual control purposes) upon the resistance 6. The lead to the tap 3t may include a high frequency filter circuit consisting of a resistance 35 and a condenser 38.
Although from the point of View of stability and freedom from distortion, it is preferred not to employ the triode section of the double diode In this case the elements 22 and 23 are designed to filter out the detected audio components produced across resistance 55 and an additional resistance 3'? is inserted between grid 2i and the junction point of elements 22 and 23. The output audio voltage from the double diode triode is then developed across any suitable impedance such as the resistance 2'5 or an audio frequency choke, or a transformer primary, in the anodecathode circuit of the triode section.
In either case the whole arrangement is such that normally the voltage drop developed across the resistance 38 by the anode current of the triode section of the double diode triode is greater than the voltage drop across the choke to so that the cathode of the double diode triode is positive with respect to earth, and the second diode 8l I of the double diode passes current and the voltage drop across the resistance 9 is sufficient to bias the demodulating diode back so that it is inoperative to demodulate incoming signals. When, however, the si nal strength applied to the diode i -EQ of the double diode triode increases sufficiently, the voltage drop across the resistance l5 drives the grid PE! negative thus reducing the current fiow through the resistance 36, and, also the positive potential with respect to earth at the cathode of the double diode triode. Accordingly, the current through the diode 8! l of the double diode is reduced and the bias on the demodulating detector is reduced until, when the signal is strong enough, the demodulating diode operates correctly, the current through the diode 3-H then being zero. In this way the suppression bias on the demodulating diode is removed as soon as automatic volume control commences, that is to say, as soon as the incoming signal is strong enough for proper reproduction.
The time constant provided by the resistance 9 and shunt condenser II! should be approximately equal to that provided by the resistance 6 and shunt condenser E, and the value of the said resistance 9 should be about one-tenth, or less, of the value of the said resistance 6. Change of position of the point of suppression may be achieved by changing the cathode bias of one or more of the gain controlled carrier frequency valves of the receiver, and/or by deriving the voltage on the anode of the triode section of the double diode triode either from an adjustable tappin on a potentiometer resistance connected between the positive terminal of the source of anode potential and earth, or from an adjustable series resistance between the anode of the said triode section and the said positive terminal.
The invention offers quite important operating advantages among them being:
1. The demodulating detector is biased only for noise suppression, and. all bias is quickly removed as soon as the suppression point is passed allowing normal and, therefore, substantially distorticnless operation of the detector thereafter.
2. One end of the audio frequency output resistance (the resistance 6 in Figs. 1. and 2) is earthed thus avoiding liability of hum pickup from the source of negative voltage for producing the AVG voltage. In mains-driven sets this source is often the field coil of a moving coil loudspeaker. This earthing of the audio frequency output resistance at one end also assists in preventing audio frequency break through when the normal volume control (the tapping 3 1 on the resistance 6) is set to zero.
3. In the preferred embodiment (Fig. 1) the double diode triode is not employed as an audio frequency amplifier, and, therefore, liability to instability and distortion due to varying bias on the grid of the triode section of the double diode triode is avoided altogether.
What is claimed is:
1. In combination in a radio receiver provided with a signal carrier transmission network, a demodulator coupled to said network, and including a demodulation voltage output circuit, a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator inefiective to produce demodulation voltage, and connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current fiow through the impedance decreasing below a predetermined value.
2. In combination in a radio receiver provided with a signal carrier transmission network, a demodulator coupled to said network and including a demodulation voltage output circuit, a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, means for producing a gain control potential for said network, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said econd rectifier to said demodulator so as to cause said second direct voltage to render the demodulator ineifective to produce demodulation volta e, and connections between said second rectifier and said impedance for rendering said second rectifier inefiective upon the current flow through the impedance decreasing below a predetermined value.
3. In combination in a radio receiver provided with a signal carrier transmission network, a demodulator coupled to said network and including a demodulation voltage output circuit, a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator ineffective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current flow through the impedance decreasing below a predetermined value, and means, responsive to said decreased current flow through said impedance, for producing a gain control voltage for the network.
4. In combination in a radio receiver provided with a signal carrier transmission network, a demodulator coupled to said network and including a demodulation voltage output circuit, a control circuit for the receiver comprising a signal rectifier coupled to said nework and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current fiow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator inefiective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current flow through the impedance decreasing below a predetermined value, said network including a pair of cascaded resonant circuits tuned to a desired carrier frequency, said demodulator being coupled to the second resonant circuit, and said two rectifiers being coupled to the first resonant circuit.
5. In combination in a radio receiver provided with a signal carrier transmission network, a demodulator coupled to said network and including a demodulation voltage output circuit, a control circuit for the receiver comprising a signal rectifier coupled to said network and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator inefiective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current flow through the impedance decreasing below a predetermined value, and means for connecting said demodulation voltage output circuit to said electron discharge device whereby the latter amplifies said demodulation voltage.
6. In combination in a radio receiver provided with a signal carrier transmission network, a
demodulator coupled to said network and including a demodulation voltage output circuit, a control circuit for the receiver comprising a signal rectifier coupled to said nework and adapted to derive a direct current voltage from rectified signal current, an electron discharge device including an impedance in the space current path thereof, means for impressing said direct voltage on said device to control the current flow through said impedance, a second signal rectifier coupled to said network and adapted to derive a second direct current voltage from rectified signal current, means connecting said second rectifier to said demodulator so as to cause said second direct voltage to render the demodulator ineffective to produce demodulation voltage, connections between said second rectifier and said impedance for rendering said second rectifier ineffective upon the current fiow through the impedance decreasing below a predetermined value, the electrodes of said demodulator and second rectifier being provided by a tube having a common cathode and two anodes, and the electrodes of the first rectifier being housed within the envelope of said discharge device.
KENNETH REGINALD STURLEY.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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GB2179966X | 1937-07-15 |
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US2179966A true US2179966A (en) | 1939-11-14 |
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US210419A Expired - Lifetime US2179966A (en) | 1937-07-15 | 1938-05-27 | Noise suppression circuits |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2507432A (en) * | 1946-06-11 | 1950-05-09 | Us Sec War | Squelch or muting of amplifiers |
US2621287A (en) * | 1948-03-22 | 1952-12-09 | Donald L Hings | Noise neutralizing pulse detector |
-
1938
- 1938-05-27 US US210419A patent/US2179966A/en not_active Expired - Lifetime
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2507432A (en) * | 1946-06-11 | 1950-05-09 | Us Sec War | Squelch or muting of amplifiers |
US2621287A (en) * | 1948-03-22 | 1952-12-09 | Donald L Hings | Noise neutralizing pulse detector |
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