US2159453A - Dual action volume control - Google Patents
Dual action volume control Download PDFInfo
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- US2159453A US2159453A US370545A US37054529A US2159453A US 2159453 A US2159453 A US 2159453A US 370545 A US370545 A US 370545A US 37054529 A US37054529 A US 37054529A US 2159453 A US2159453 A US 2159453A
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- 230000009977 dual effect Effects 0.000 title description 3
- 238000005513 bias potential Methods 0.000 description 11
- 230000003321 amplification Effects 0.000 description 8
- 238000003199 nucleic acid amplification method Methods 0.000 description 8
- 238000000034 method Methods 0.000 description 5
- 230000003247 decreasing effect Effects 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 230000000694 effects Effects 0.000 description 2
- 230000009467 reduction Effects 0.000 description 2
- 230000008859 change Effects 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 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
- H03G3/02—Manually-operated control
- H03G3/14—Manually-operated control in frequency-selective amplifiers
- H03G3/16—Manually-operated control in frequency-selective amplifiers having discharge tubes
Definitions
- My invention relates to amplifier systems utilizing thermionic vacuum tubes in which the amplification may be controlled by altering the bias potential applied to the control member or grid.
- One purpose of my invention is to provide means for simultaneously controlling the amount of the amplification and the amount of energy supplied to the input of the amplifier.
- a further purpose is to provide a method of controlling the output energy of a radio receiving set from maximum to zero in such a way as to make the change in output volume approximately linear when a uniform volume control resistance is employed.
- An additional purpose is to accomplish complete control of volume without increasing the negative bias on the amplifier grids to a point 35 where troublesome distortion occurs.
- Figure 1 is a circuit diagram of a preferred form of my invention applied to a single stage amplifier using the heater type of three element vacuum tube, and
- Figure 2 is a circuit diagram showing how my 50 invention may be applied to a multi-stage amplifier such as is commonly used in radio receiving" sets.
- reference character 2 indicates a coil which re- 55 ceives energy from the antenna l and which is coupled to coil 3.
- Coil 3 and condenser 4 form a resonant circuit, grounded at 5, and connected at its upper end to the grid 6 of a control electrode or vacuum tube VT whose cathode l is heated by current from a source not shown and 5 passing through heater 8.
- the plate or anode 9 is connected to the positive terminal of the source of B potential l4 through the coil l0.
- Coil II is inductively coupled to coil l0, and the output of the amplifier is delivered between the terminals 10 I2 and I3.
- the source of B potential M has its positive terminal connected to anode 9 and its negative to ground 5 and is shunted by the by-pass condenser l5.
- a second by-pass condenser l6 connects the cathode l with ground 5.
- and resistance l9 are connected in! series between the antenna I and the cathode I.
- the movable contact 20, associated with resistance I9, is connected to ground 5.
- the electron 20 stream which flows from cathode l to anode 9 when the amplifier is in operation causes a current to flow through resistance 2
- the effect of this current is to cause the cathode 'l to assume a plus potential with respect to the ground 5.
- the grid 6 being at ground potential, so far as direct current is concerned, will therefore be held at a potential negative with respect to the cathode I:
- the preferred form of my invention combines with it the shunting effect of a resistance around the antenna coil 2. It will be noted that I connect the end ll of the resistance l9 to the high potential end of the antenna coil 2. When the movable contact 2! is at the end IS, the antenna coil 2 will be shunted by the total resistance of 19, which is made high in comparison with the effective impedance of coil 2, whereby substantially all the antenna current flows through coil 2.
- resonant circuits comprising coil 3 and condenser 4, coil 3' and condenser l and coil 3" and condenser 4" are provided in the 'input of each tube according to common practice, and are each grounded. It will be understood that additional or fewer stages maybe utilized if desired and that one or more .of the tuning circuits may be omitted if desired.
- the heaters of the various tubes are shown as energized in parallel for purposes of simplicity, but other arrangements may be used if desired.
- the operation is the same as in the case of the single stage amplifier, except that in this case the common bias potential on grids 6, 6' and 6" is controlled by the position of movable contact 28, so that as this contact is moved the input signal strength, as well as the amplification in each stage, is varied.
- a vacuum tube amplifier in combination, a vacuum tube amplifier, an input circuit associated therewith, a variable resistance in shunt therewith, a second variable resistance traversed by the space current of said tube, means for applying the voltage drop developed therein as a bias potential to the grid of said tube and a single means for varying both said resistances simultaneously and in an opposite sense.
- a vacuum tube amplifier in combination, a vacuum tube amplifier, an input circuit associated therewith, a variable resistance in shunt therewith, a second variable resistance traversed by the space current of said tube, means for applying the voltage drop developed therein as a bias potential to the grid of said tube, and means for varying both said resistances simultaneously.
- a vacuum tube amplifier in combination, a vacuum tube amplifier, an input circuit associated therewith, a variable resistance in shunt therewith, a second variable resistance traversed by the space current of said tube, means for applying the voltage drop developed therein as a bias potential to the grid of said tube, and means for simultaneously increasing one of said resistances and decreasing the other.
- a vacuum tube amplifier in combination, a vacuum tube amplifier, an input circuit associated therewith, a resistance having one portion thereof traversed by the space current of said tube to provide a bias potential for the grid and having another portion in shunt with said input circuit, and a connection to said resistance shiftable to vary the value of said portions inversely.
- an amplifier system comprising a thermionic vacuum tube, an input circuit, a variable resistance in shunt therewith, a fixed resistance and a variable resistance in series connected in the path of space current of said tube, means for applying the voltage drop through said lastnamed resistances as a bias potential to the grid of said tube, and means for simultaneously varying both said variable resistances.
- a volume control for an amplifier using thermionic tubes having an anode, a cathode and a grounded grid, which grid is coupled to a pickup device, comprising the combination of a resistor connected between the cathode and ground, a resistor connected between the pick-up device and the cathode, and a rider connected to ground and engaging said latter resistor.
- a resistor divided into two 1' parts, one part of said resistor being connected between the aerial connection and the earth connection, and the other part between the cathode element and the grid element, and means comprising a single manually operable device for varying the relative resistance of the two parts of the resistor.
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Description
'May 23, 1939. A, SENAUKE 2,159,453
DUAL ACTION VOLUME CONTROL Filed June 13/1929 INVENTOR ALEXANDER SENAUKE 18 a 2:22; ATTbRNEY Patented May 23, 1939 UNITED STATES PATENT OFFICE DUAL ACTION VOLUME CONTROL Application June 13, 1929, Serial No. 370,545
10 Claims.
My invention relates to amplifier systems utilizing thermionic vacuum tubes in which the amplification may be controlled by altering the bias potential applied to the control member or grid.
. In amplifiers whose tubes have filaments heated with alternating current, it is not in general practicable to control volume by reducing the amount of filament current. Heretofore the method most widely used has been to shunt the.
input circuit with a variable resistance. This method is open to two serious objections. First, the output volume increases very fast when the control resistance is increased slightly from its zero value, making it impracticable to use a uniform wire wound resistance. Secondly, when such method of control is used in connection with a high gain multi-stage amplifier, it is difiicult to cut the output volume down sufiiciently, due to the fact that a strong signal may be picked up on the apparatus and wiring associated with the various stages.
,One purpose of my invention is to provide means for simultaneously controlling the amount of the amplification and the amount of energy supplied to the input of the amplifier.
A further purpose is to provide a method of controlling the output energy of a radio receiving set from maximum to zero in such a way as to make the change in output volume approximately linear when a uniform volume control resistance is employed.
An additional purpose is to accomplish complete control of volume without increasing the negative bias on the amplifier grids to a point 35 where troublesome distortion occurs.
Still other objects and advantages of my invention will be apparent from the specification.
The features of novelty which I believe to be characteristic of my invention are set forth with 4 particularity in the appended claims. My invention itself, however, both as to its fundamental principles and as to its particular embodiments, will best be understood by reference to the specification and accompanying drawing, in which:
45 Figure 1 is a circuit diagram of a preferred form of my invention applied to a single stage amplifier using the heater type of three element vacuum tube, and
Figure 2 is a circuit diagram showing how my 50 invention may be applied to a multi-stage amplifier such as is commonly used in radio receiving" sets.
Referring now more particularly to Fig. 1, reference character 2 indicates a coil which re- 55 ceives energy from the antenna l and which is coupled to coil 3. Coil 3 and condenser 4 form a resonant circuit, grounded at 5, and connected at its upper end to the grid 6 of a control electrode or vacuum tube VT whose cathode l is heated by current from a source not shown and 5 passing through heater 8. The plate or anode 9 is connected to the positive terminal of the source of B potential l4 through the coil l0. Coil II is inductively coupled to coil l0, and the output of the amplifier is delivered between the terminals 10 I2 and I3. The source of B potential M has its positive terminal connected to anode 9 and its negative to ground 5 and is shunted by the by-pass condenser l5. A second by-pass condenser l6 connects the cathode l with ground 5. 15 Resistance 2| and resistance l9 are connected in! series between the antenna I and the cathode I. The movable contact 20, associated with resistance I9, is connected to ground 5.
As will be readily understood, the electron 20 stream which flows from cathode l to anode 9 when the amplifier is in operation causes a current to flow through resistance 2|, and through that portion of the resistance l9, which is between the end l8 and the movable contact 20. The effect of this current is to cause the cathode 'l to assume a plus potential with respect to the ground 5. The grid 6 being at ground potential, so far as direct current is concerned, will therefore be held at a potential negative with respect to the cathode I: When the movable contact 20 is brought over to the end l8 of the resistance l9, resistance 2| alone will be in circuit between the cathode and ground. This is the position for maximum amplification, and the value of resistance 2| is chosen to provide a proper negative bias for the grid 6 under such conditions. As the movable contact 20 is moved towards the end 11, an increasing amount of the resistance I9 will be included in the circuit between cathode and ground, resulting in an increased negative bias on the grid 6, and a consequent decrease in amplifica tion.
While the method just described may in some cases serve as an adequate volume control, the preferred form of my invention combines with it the shunting effect of a resistance around the antenna coil 2. It will be noted that I connect the end ll of the resistance l9 to the high potential end of the antenna coil 2. When the movable contact 2!! is at the end IS, the antenna coil 2 will be shunted by the total resistance of 19, which is made high in comparison with the effective impedance of coil 2, whereby substantially all the antenna current flows through coil 2.
It will be recalled that this is also the position of the movable contact 20 which provides normal operating bias to the grid 6 and affords maximum amplification. If now the contact 2|] is shifted towards I1, the amount of resistance shunting the antenna coil will be decreased, with a. corresponding decrease in the amount of signal which reaches the grid 6 and with a simultaneous increase in bias potential and corresponding reduction in amplification. Should the contact 20 reach the end I 7, the antenna coil will be shorted out of circuit and there will be approximately no current flowing in it to produce a voltage on the grid 6. At the same time, as pointed out above, the bias potential on grid '6 will have been in creased to such an extent as to destroy the amplifying property of the tube.
It will thus be seen that by moving the contact 20 I simultaneously vary the amount of signal reaching the grid 6 and modify the amplifying property of the tube by altering the D. C. bias potential applied to the grid, thereby varying the mutual conductance of the tube.
Referring now to Fig. 2, it will be noted that the application of my invention to a cascade amplifier is accomplished by connecting together the leads from the cathodes l, l and 1" of vacuum tubes VTI, VT2 and VT3 in the first, second and third stages respectively. It will be noted that in this instance resonant circuits comprising coil 3 and condenser 4, coil 3' and condenser l and coil 3" and condenser 4" are provided in the 'input of each tube according to common practice, and are each grounded. It will be understood that additional or fewer stages maybe utilized if desired and that one or more .of the tuning circuits may be omitted if desired.
In this instance the heaters of the various tubes are shown as energized in parallel for purposes of simplicity, but other arrangements may be used if desired. The operation is the same as in the case of the single stage amplifier, except that in this case the common bias potential on grids 6, 6' and 6" is controlled by the position of movable contact 28, so that as this contact is moved the input signal strength, as well as the amplification in each stage, is varied.
I have found that in applying my invention to a radio receiver it is practicable to make resistance it in the form of a uniform wire wound resistance. This I believe to be due to the fact that there is a considerable reduction in amplification due to increased grid bias, which becomes effective while the resistance shunting the antenna coil is still relatively high.
It is not necessary to physically separate the two resistances l9 and 2!, as the same result may be secured by using a single resistance of greater value, provided with a stop so that the contact 28 may not be moved beyond a point which will provide the grids with normal operating bias potential. v
I have found, when my invention is used to control the output of a multi-stage amplifier of the tuned radio frequency type, that the loss in selectivity due to shunting the antenna coil with a low resistance when contact 29 is moved toward end ll tends to be compensated by the decrease in mutual conductance of the tubes, resulting from increased grid bias, which tends to sharpen the tuning of succeeding circuits.
While I have shown and described certain preferred embodiments of my invention, it will be understood that modifications and changes may be made without departing from the spirit and scope of my invention, as will be understood by those skilled in the art.
I claim:
1. In an amplifier system, in combination, a vacuum tube amplifier, an input circuit associated therewith, a variable resistance in shunt therewith, a second variable resistance traversed by the space current of said tube, means for applying the voltage drop developed therein as a bias potential to the grid of said tube and a single means for varying both said resistances simultaneously and in an opposite sense.
2. In an amplifier system, in combination, a vacuum tube amplifier, an input circuit associated therewith, a variable resistance in shunt therewith, a second variable resistance traversed by the space current of said tube, means for applying the voltage drop developed therein as a bias potential to the grid of said tube, and means for varying both said resistances simultaneously.
3. In an amplifier system, in combination, a vacuum tube amplifier, an input circuit associated therewith, a variable resistance in shunt therewith, a second variable resistance traversed by the space current of said tube, means for applying the voltage drop developed therein as a bias potential to the grid of said tube, and means for simultaneously increasing one of said resistances and decreasing the other.
4. In an amplifier system, in combination, a vacuum tube amplifier, an input circuit associated therewith, a resistance having one portion thereof traversed by the space current of said tube to provide a bias potential for the grid and having another portion in shunt with said input circuit, and a connection to said resistance shiftable to vary the value of said portions inversely.
5. In an amplifier system, comprising a thermionic vacuum tube, an input circuit, a variable resistance in shunt therewith, a fixed resistance and a variable resistance in series connected in the path of space current of said tube, means for applying the voltage drop through said lastnamed resistances as a bias potential to the grid of said tube, and means for simultaneously varying both said variable resistances.
6. A volume control for an amplifier using thermionic tubes having an anode, a cathode and a grounded grid, which grid is coupled to a pickup device, comprising the combination of a resistor connected between the cathode and ground, a resistor connected between the pick-up device and the cathode, and a rider connected to ground and engaging said latter resistor.
'7. The combination with a radio set having an antenna coupled to the grid of a thermionic tube which has a cathode, of a volume control comprising a shunt resistance connected between said antenna and said cathode, a resistor connecting said cathode to ground, and means for varying the effective value of said shunt resistance.
8. The combination in radio receiving apparatus of a thermionic tube having a cathode element and a grid element, an aerial connection, an
earth connection, a resistor divided into two 1' parts, one part of said resistor being connected between the aerial connection and the earth connection, and the other part between the cathode element and the grid element, and means comprising a single manually operable device for varying the relative resistance of the two parts of the resistor.
9. The combination in radio receiving apparatus of a thermionic tube, a cathode and a grid located in said tube, a resistor, a connection between said resistor unit and the said grid, a connection between the resistor and said cathode, an aerial connection, a connection between the aerial connection and the resistor, an earth connection and an adjustable connection between said earth connection and the resistor, said adjustable connection being adapted to vary the resistance in the connections between the aerial antenna coil connected between an antenna and ground, a grid coil connected between the grid of a tube and ground and iductively coupled to said antenna coil, and a cathode in said tube, of a resistor connecting said cathode to ground, a resistor connecting said antenna to said resistor, and a rider connected to ground and engaging said second resistor and movable thereover to regulate the voltage induced in said grid coil and the potential of said grid with respect to said 10
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US370545A US2159453A (en) | 1929-06-13 | 1929-06-13 | Dual action volume control |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US370545A US2159453A (en) | 1929-06-13 | 1929-06-13 | Dual action volume control |
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US2159453A true US2159453A (en) | 1939-05-23 |
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US370545A Expired - Lifetime US2159453A (en) | 1929-06-13 | 1929-06-13 | Dual action volume control |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2503787A (en) * | 1943-03-05 | 1950-04-11 | Hartford Nat Bank & Trust Co | Radio receiver gain control |
-
1929
- 1929-06-13 US US370545A patent/US2159453A/en not_active Expired - Lifetime
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2503787A (en) * | 1943-03-05 | 1950-04-11 | Hartford Nat Bank & Trust Co | Radio receiver gain control |
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