US2404712A - Gain control circuit for radiotelegraph - Google Patents
Gain control circuit for radiotelegraph Download PDFInfo
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- US2404712A US2404712A US516148A US51614843A US2404712A US 2404712 A US2404712 A US 2404712A US 516148 A US516148 A US 516148A US 51614843 A US51614843 A US 51614843A US 2404712 A US2404712 A US 2404712A
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- 230000003068 static effect Effects 0.000 description 9
- 230000004044 response Effects 0.000 description 4
- 239000003990 capacitor Substances 0.000 description 2
- 230000008859 change Effects 0.000 description 2
- 230000008878 coupling Effects 0.000 description 2
- 238000010168 coupling process Methods 0.000 description 2
- 238000005859 coupling reaction Methods 0.000 description 2
- 230000000694 effects Effects 0.000 description 2
- 230000002452 interceptive effect Effects 0.000 description 2
- 230000010355 oscillation Effects 0.000 description 2
- 238000004804 winding Methods 0.000 description 2
- 230000009471 action Effects 0.000 description 1
- 238000005513 bias potential Methods 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 230000000670 limiting effect Effects 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000002829 reductive effect Effects 0.000 description 1
- 230000000717 retained effect Effects 0.000 description 1
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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
Definitions
- This invention relates to automatic gain control systems and is particularly adapted for use with a radio receiver which is intended to receive interrupted carrier wave telegraph signals.
- I show an antenna l for collecting electromagnetic wave energy.
- This antenna is connected through coupling coil 2 and thence to ground.
- Electromagnetic wave energy flowing through coupling coil 2 induces signal currents in the tuned circuit comprising the transformer secondary 3 and the adjustable capacitor 4 in shunt therewith.
- Applied to the suppressor grid g3 of converter tube 5 is the energy from a local oscillator 25.
- the local oscillations beat with the incoming signal to produce an intermediate frequency of a desired value.
- This intermediate frequency energy is transferred to the control grid of an amplifying tube 8 by way of an intermediate frequency transformer which is included in tuned circuits 5 and I.
- the intermediate frequency energy being amplified by amplifier tube 8 is coupled by tuned transformer windings 9 and Ill to a diode rectifier tube ll.
- Parts 12 and I3 represent a bias resistance and a radio frequency bypass condenser respectively, as do parts l4 and I5.
- a triode tube 16 is connected in series with the output of a rectifier tube II and a resistor IT.
- the output terminating resistance of rectifier tube ll includes the transformer secondary winding III, the space path through triode tube l6 and resistance [1.
- a bias battery furnishes a potential gradient in a potentiometer 26, and adjustable taps 20 and 2
- the tap 2i. biases the grid in tube 22 more. negatively than the bias which is applied to the grid of tube I 6 through tap 20.
- Resistor 23 and capacitor 24 constitute the time constant device for this AVC system.
- Output potentials derived from the rectifier tube 1 I may be taken either from the cathode of tube l6 or from a suitable point on the potentiometer I! in the anode circuit of tube [6.
- the polarity ofthe output potential depends, upon the setting of a double pole switch I8.
- any desired translating device such as a keyer tube, a balanced modulator, or a recorder.
- the signal wave energy is amplified by vacuum tube 5 and heterodyned with the local oscillations to produce an intermedate frequency, which is further amplified by intermediate frequency amplifier tube 8, output from which is rectified by the rectifier tube H;
- triode tube l6 has applied thereto a low bias potential sufficient to render this tube non-conductive to very. low strength signals and, tube noise currents.
- signal energy passes through tube l6 and resistance. I l the full -voltage across tube 16 and resistance I] is applied to the AVG circuit.
- the application of this AVC voltage reduces the gain of the receiver during a single impulse and the gain remains at that particular gain value since the control grids of vacuum tubes 5 and 8 are isolated until rectifier tube [6 is again conductive.
- next succeeding signal impulse be stronger than the preceding impulse
- the gain of the receiver will be lowered still further
- the gain of the receiver will be increased and will retain this gain value as heretofore mentioned until another impulse causes tube IE to again be conductive to reset the gain level of the receiver at a new level depending upon the strength of the incoming signal.
- tube 22 in this AVC circuit is as follows: If very strong signal currents, or heavy atmospheric impulses are received, tube 22' becomes conductive since a slightly more negative bias is applied thereto, than is applied to the grid of rectifier tube l6, creating a bypass circuit which prevents the grids of amplifier tubes and 8 from [becoming blocked.
- Another efiect present is that the AVG circuit is momentarily drained of electrons when tube 22 suddenly becomes conductive, causing the gain of the receiver to slightly increaseas a result of a strong static impulse, whereas, in normal AVC practice the gain of the receiver would be greatly reduced and the time constant circuit would'be overloaded with voltagepossibly producing dropouts of one or more subsequent signal impulses.
- the time constant circuit 23, 24 is preferably small in value in order to provide substantially instantaneous gain compensation. This arrangement has proven very practical when receiving telegraph signals under conditions such that the strength of the incoming signals varies over a very wide amplitude range. Since the 'rate of gain compensation canibe extremely fast it natyurally follows that the rectified signal energy available at switch laremains relatively constant though theinput signal may befadingover a very wide range.
- thismethod of auto- .matic gain control may be used in conjunction with adiversity receiving system which is at present in wide usage for short wave, long-distance ,radio telegraph-telephone reception.
- .Furthenthis method of automatic volume lcontrol may be utilized in a conventional all-wave broadcast receiver and will be found particularly useful in establishing a maximum volume at which positive llimiting results, there-by preventing heavy atmospheric noises from exceeding the maximum level of modulated waves as received. This is-accomplishedbyadjusting rectifier tube 22 to be conductiveat approximately 6 to .10 deci- :bels below the maximum modulation level.
- an automatic gain control circuit comprising series resistanceand shunt ca- ;pacityin circuit with rectifying means coupled toaparticular stage of said receiver, said circuit being operative to apply gain control potentials to the input circuits of said stages, a load resistor and electronic switching means in series with said rectifying means whereby said gain control circuit is rendered effective to adjust the gain in said receiver to a desired value in the presence of marking signals and to hold thatgain adjustment during carrier wave interruptions of normal spacing signal duration, an electronic limiter device connected in shunt with said load resistor and switching means, said limiter device being operable in the presence of peak impulses due to static dered relatively insensitive to noise energy of low amplitude and also to static crashes of relatively high amplitude.
- Apparatus for automatically controlling the gain in the amplifier stages of an interrupted carrier wave receiver comprising a gain control ,circuit having time constant elements insnunt with a unilateral impedance of the tri'ode discharge tube type, means including a rectifier for supplying rectified output energy from said, ampliw bomb stages to said gain control circuit, means operative in response to the reception of model"?
- this means comprising an auxiliary discharge tube rendered conductive by said strong interfering potentials, thereby to shunt to ground a portion .of said rectified output energy ,along with a portion of the charge previously, stored in said time constant circuit.
- An automatic gain control circuit for use in a radio telegraph receiver, said circuit having .a rectifier coupled to .a certainstage of the receiver, a load in series with the vrectifier, said load including two discharge tubes which are mutually in parallel, a negative biasing means so connected between the cathode and control grid of each one of said'tubes that one tube [of said gain control circuit andarranged for cooperation with .saidload .to control the gain in .said receiver.
- Apparatus for-automatically controlling the gain in the amplifier stages of an interrupted carrier wave receiver, said apparatus comprising a rectifier circuit coupled to a particular stage of said receiver, said circuit including the space path of an electron discharge tube having a cathode, an anode and a control grid, negative biasing means connected between the cathode and control grid of said tube, means including a time constant circuit in shunt with the space path of said tube, said means havingresistance and capacitance for prolonging the gain control effects through space intervals between the marking signal elements, and means responsive to static impulses and high amplitudesignals which tend to paralyze the receiver for reducing the bias that would otherwise be derived from said negative biasing means, whereby said tube is caused to compensate for excessive gainvcontrol 6.
- said bias reducing means includes a second electron discharge tube the space path of which is in series with a resistor, this tube and resistor being in shunt with the space path of the first said tube and the second tube being operatively biased to supply substantially instantaneous adjustment of the gain control potential to a new level in response to a change in the incoming signal level.
- Apparatus for automatically controlling the gain in the amplifier stages of an interrupted carrier wave receiver comprising a gain control circuit having time constant elements in shunt with a unilateral impedance of the triode dis- 16 charge tube type, said circuit being operative to reduce the gain in said amplifier stages in response to the reception of moderate strength static crashes and other interference waves of moderate amplitude, means occasionally operative to increase the gain in said amplifier stages, this means comprising an electron discharge device the space path of which is connected in shunt with said time constant elements, and means operative upon reception of strong static or other noise energy for reducing the impedance of said space path, thereby to effect said gain increase.
Description
R. L. HOLLINGSWORTH I 'GAIN CONTROL CIRCUIT FOR RADIO TELEGRAPH Filed Dec. 30, 1943 Oar/ 07 INVENTOR BY M ZMW ATTORN E3 Patented July 23,1946
GAIN CONTROL CIRCUIT FOR RADIOTELEGRAPH R. Lee Hollingsworth, Riverhead, N. Y., assignor to Radio Corporation of America, a corporation of Delaware Application December 30, 1943, Serial No. 516,148
7 Claims.
This invention relates to automatic gain control systems and is particularly adapted for use with a radio receiver which is intended to receive interrupted carrier wave telegraph signals.
It is an object of my invention to provide an automatic gain control system whereby the gain 'of the receiver is adjusted to an optimum value during each signal impulse, that gain value being retained during a space interval until the next succeeding impulse.
It is another object of my invention to provide an automatic gain control system which produces almost instantaneous adjustment of the gain to a new level in response to a change in the incoming signal level.
It is another object of my invention to control the gain in an interrupted carrier wave receiver in such a manner that the tube noise currents in the receiving circuitswill be substantially eliminated.
It is another object of my invention to provide a system comprising a plurality of discharge tubes operative to so influence an automatic gain control circuit that incoming static impulses are prevented from paralyzing the receiver circuit.
The invention will now be fully described, reference being made to the accompanying drawing, the sole figure of which shows a circuit diagram of a preferred embodiment.
Referring to the drawing, I show an antenna l for collecting electromagnetic wave energy. This antenna is connected through coupling coil 2 and thence to ground. Electromagnetic wave energy flowing through coupling coil 2 induces signal currents in the tuned circuit comprising the transformer secondary 3 and the adjustable capacitor 4 in shunt therewith. Applied to the suppressor grid g3 of converter tube 5 is the energy from a local oscillator 25. The local oscillations beat with the incoming signal to produce an intermediate frequency of a desired value. This intermediate frequency energy is transferred to the control grid of an amplifying tube 8 by way of an intermediate frequency transformer which is included in tuned circuits 5 and I. The intermediate frequency energy being amplified by amplifier tube 8 is coupled by tuned transformer windings 9 and Ill to a diode rectifier tube ll. Parts 12 and I3 represent a bias resistance and a radio frequency bypass condenser respectively, as do parts l4 and I5.
A triode tube 16 is connected in series with the output of a rectifier tube II and a resistor IT. The output terminating resistance of rectifier tube ll includes the transformer secondary winding III, the space path through triode tube l6 and resistance [1. A bias battery furnishes a potential gradient in a potentiometer 26, and adjustable taps 20 and 2| on this potentiometer may be set to maintain suitable threshold biases on the grids of tubes l6 and 22 respectively. The tap 2i. biases the grid in tube 22 more. negatively than the bias which is applied to the grid of tube I 6 through tap 20. Resistor 23 and capacitor 24 constitute the time constant device for this AVC system.
Output potentials derived from the rectifier tube 1 I may be taken either from the cathode of tube l6 or from a suitable point on the potentiometer I! in the anode circuit of tube [6. The polarity ofthe output potential depends, upon the setting of a double pole switch I8. By means of the circuit arrangement shown and described it is, therefore, possible to control any desired translating device such as a keyer tube, a balanced modulator, or a recorder. In operation the signal wave energy is amplified by vacuum tube 5 and heterodyned with the local oscillations to produce an intermedate frequency, which is further amplified by intermediate frequency amplifier tube 8, output from which is rectified by the rectifier tube H; The
triode tube l6 has applied thereto a low bias potential sufficient to render this tube non-conductive to very. low strength signals and, tube noise currents. When signal energy passes through tube l6 and resistance. I l the full -voltage across tube 16 and resistance I] is applied to the AVG circuit. The application of this AVC voltage reduces the gain of the receiver during a single impulse and the gain remains at that particular gain value since the control grids of vacuum tubes 5 and 8 are isolated until rectifier tube [6 is again conductive. If the next succeeding signal impulse be stronger than the preceding impulse, the gain of the receiver will be lowered still further, whereasfif the following signal impulse be less in value than the preceding impulse, the gain of the receiver will be increased and will retain this gain value as heretofore mentioned until another impulse causes tube IE to again be conductive to reset the gain level of the receiver at a new level depending upon the strength of the incoming signal.
The action of the tube 22 in this AVC circuit is as follows: If very strong signal currents, or heavy atmospheric impulses are received, tube 22' becomes conductive since a slightly more negative bias is applied thereto, than is applied to the grid of rectifier tube l6, creating a bypass circuit which prevents the grids of amplifier tubes and 8 from [becoming blocked. Another efiect present is that the AVG circuit is momentarily drained of electrons when tube 22 suddenly becomes conductive, causing the gain of the receiver to slightly increaseas a result of a strong static impulse, whereas, in normal AVC practice the gain of the receiver would be greatly reduced and the time constant circuit would'be overloaded with voltagepossibly producing dropouts of one or more subsequent signal impulses.
The time constant circuit 23, 24 is preferably small in value in order to provide substantially instantaneous gain compensation. This arrangement has proven very practical when receiving telegraph signals under conditions such that the strength of the incoming signals varies over a very wide amplitude range. Since the 'rate of gain compensation canibe extremely fast it natyurally follows that the rectified signal energy available at switch laremains relatively constant though theinput signal may befadingover a very wide range.
,It will be appreciated that thismethod of auto- .matic gain control may be used in conjunction with adiversity receiving system which is at present in wide usage for short wave, long-distance ,radio telegraph-telephone reception.
.Furthenthis method of automatic volume lcontrol may be utilized in a conventional all-wave broadcast receiver and will be found particularly useful in establishing a maximum volume at which positive llimiting results, there-by preventing heavy atmospheric noises from exceeding the maximum level of modulated waves as received. This is-accomplishedbyadjusting rectifier tube 22 to be conductiveat approximately 6 to .10 deci- :bels below the maximum modulation level.
Various modifications and applications will be suggested by this disclosure .to those skilled in the art. The scope oftheinventio-n is to be understood, therefore, as comprehending embodiments other than that which is herein iliustratively shownand described.
-1. In an interrupted .carrier wave receiver ,an automatic gain control-circuit comprising means for rectifying the output from said receiver, .a first electron discharge tube the space path of which is inseries withlsaid rectifying means, said tube having a cathode, an anode .and a control grid,=a load resistor connected between said anode and ground, a-second electron discharge tube the .space path-oi? which is connected in shunt between the cathode of .the first .said tube and ground, 'saidsecond tubelhaving a cathode, an anode and a control grid, means for maintaining different threshold biases on the grids of said tubes whereby the firstsaid tube is rendered non- :conductive in the presence of signal and noise energy belowa predetermined level, and .the second tubeis :held non-conductive in the presence of rectified.signalenergywithin a normal volume range, and-a time constantcircuit comprisingseries resistance and shunt capacity so connected as tosupplygain control potentials to the amplifier stages .of said receiver, said potentials being subject to the :limiting action of said discharge tubes.
' 2. .In.an interrupted carrier wave receiver having amplifier stages, an automatic gain control circuit comprising series resistanceand shunt ca- ;pacityin circuit with rectifying means coupled toaparticular stage of said receiver, said circuit being operative to apply gain control potentials to the input circuits of said stages, a load resistor and electronic switching means in series with said rectifying means whereby said gain control circuit is rendered effective to adjust the gain in said receiver to a desired value in the presence of marking signals and to hold thatgain adjustment during carrier wave interruptions of normal spacing signal duration, an electronic limiter device connected in shunt with said load resistor and switching means, said limiter device being operable in the presence of peak impulses due to static dered relatively insensitive to noise energy of low amplitude and also to static crashes of relatively high amplitude.
3. Apparatus for automatically controlling the gain in the amplifier stages of an interrupted carrier wave receiver comprising a gain control ,circuit having time constant elements insnunt with a unilateral impedance of the tri'ode discharge tube type, means including a rectifier for supplying rectified output energy from said, ampliw fier stages to said gain control circuit, means operative in response to the reception of model"? ate strength static crashes and other interference waves of moderate amplitude for causing said rectified output energy to automatically control the gain of the receiver, and means operative to increase the gain of the receiver when receiving strong static'or other interfering potentials, this means comprising an auxiliary discharge tube rendered conductive by said strong interfering potentials, thereby to shunt to ground a portion .of said rectified output energy ,along with a portion of the charge previously, stored in said time constant circuit.
4. An automatic gain control circuit for use in a radio telegraph receiver, said circuit having .a rectifier coupled to .a certainstage of the receiver, a load in series with the vrectifier, said load including two discharge tubes which are mutually in parallel, a negative biasing means so connected between the cathode and control grid of each one of said'tubes that one tube [of said gain control circuit andarranged for cooperation with .saidload .to control the gain in .said receiver.
5. Apparatus for-automatically controlling the gain .in the amplifier stages of an interrupted carrier wave receiver, said apparatus comprising a rectifier circuit coupled to a particular stage of said receiver, said circuit including the space path of an electron discharge tube having a cathode, an anode and a control grid, negative biasing means connected between the cathode and control grid of said tube, means including a time constant circuit in shunt with the space path of said tube, said means havingresistance and capacitance for prolonging the gain control effects through space intervals between the marking signal elements, and means responsive to static impulses and high amplitudesignals which tend to paralyze the receiver for reducing the bias that would otherwise be derived from said negative biasing means, whereby said tube is caused to compensate for excessive gainvcontrol 6. Apparatus in accordance with claim 5 wherein said bias reducing means includes a second electron discharge tube the space path of which is in series with a resistor, this tube and resistor being in shunt with the space path of the first said tube and the second tube being operatively biased to supply substantially instantaneous adjustment of the gain control potential to a new level in response to a change in the incoming signal level.-
7. Apparatus for automatically controlling the gain in the amplifier stages of an interrupted carrier wave receiver, comprising a gain control circuit having time constant elements in shunt with a unilateral impedance of the triode dis- 16 charge tube type, said circuit being operative to reduce the gain in said amplifier stages in response to the reception of moderate strength static crashes and other interference waves of moderate amplitude, means occasionally operative to increase the gain in said amplifier stages, this means comprising an electron discharge device the space path of which is connected in shunt with said time constant elements, and means operative upon reception of strong static or other noise energy for reducing the impedance of said space path, thereby to effect said gain increase.
R. LEE HOLLINGSWORTH.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US516148A US2404712A (en) | 1943-12-30 | 1943-12-30 | Gain control circuit for radiotelegraph |
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US516148A US2404712A (en) | 1943-12-30 | 1943-12-30 | Gain control circuit for radiotelegraph |
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US2404712A true US2404712A (en) | 1946-07-23 |
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US516148A Expired - Lifetime US2404712A (en) | 1943-12-30 | 1943-12-30 | Gain control circuit for radiotelegraph |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2556070A (en) * | 1943-06-01 | 1951-06-05 | Hartford Nat Bank & Trust Co | Control circuit arrangement |
US2572235A (en) * | 1948-03-30 | 1951-10-23 | Bell Telephone Labor Inc | Multichannel intermodulation interference reduction radio communication system |
US2615158A (en) * | 1943-05-01 | 1952-10-21 | Edwin K Stodola | Radio object locating system |
-
1943
- 1943-12-30 US US516148A patent/US2404712A/en not_active Expired - Lifetime
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2615158A (en) * | 1943-05-01 | 1952-10-21 | Edwin K Stodola | Radio object locating system |
US2556070A (en) * | 1943-06-01 | 1951-06-05 | Hartford Nat Bank & Trust Co | Control circuit arrangement |
US2572235A (en) * | 1948-03-30 | 1951-10-23 | Bell Telephone Labor Inc | Multichannel intermodulation interference reduction radio communication system |
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