US2247203A - Amplifier circuit - Google Patents

Amplifier circuit Download PDF

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US2247203A
US2247203A US249752A US24975239A US2247203A US 2247203 A US2247203 A US 2247203A US 249752 A US249752 A US 249752A US 24975239 A US24975239 A US 24975239A US 2247203 A US2247203 A US 2247203A
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plate
grid
circuit
bias
resistor
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US249752A
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Walter Van B Roberts
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03FAMPLIFIERS
    • H03F1/00Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
    • H03F1/52Circuit arrangements for protecting such amplifiers
    • H03F1/54Circuit arrangements for protecting such amplifiers with tubes only
    • H03F1/548Protection of anode or grid circuit against overload

Definitions

  • This invention relates to electron discharge device amplifier circuits, and more particularly to a method of and means for biasing power amplifiers, whereby the bias varies as a function of several operating conditions.
  • amplifier stages as heretofore employed are often overloaded due to such factors as grid excitation failure, improper tuning of the plate tank circuit, and excessive loading.
  • a primary object of the present invention is to provide a biasing arrangement for an amplifier which will insure adequate bias voltage to safeguard the amplifier tube, in case any of the following conditions occur: (1) Grid excitation failure, (2) improper plate circuit tuning, or (3) excessive plate circuit loading, while at the same time supplying only sufiicient bias for eificient operation in the presence of proper excitation and plate circuit tuning and loading.
  • a particular object of the invention is to provide a bias voltage for the amplifier tube, which voltage varies as a function of amplifier output even though the plate current and excitation remain unchanged.
  • T is an amplifier vacuum tube having a cathode C, a grid G and a plate A.
  • Tube T receives grid excitation from alternating current source e and delivers power to a load represented by R1 connected across the tuned plate tank circuit L, C.
  • R1 connected across the tuned plate tank circuit L, C.
  • R3 is connected in the cathode circuit and shunted by radio frequency by-pass condenser K.
  • a resistance R whose value is sufliciently large to safeguard the tube in case the plate tank circuit L, C is detuned or greatly overloaded. While the biasing elements so far described are sufficient to safeguard the tube against any contingencies that might arise, the resulting bias in the case of proper adjustment of the amplifier stage would be too great to permit proper operation. Therefore, in accordance with the present invention, there is provided a circuit arrangement for reducing the total bias on the grid to a suitable value in the presence of proper grid excitation and plate circuit adjustment. In the illustrated form of the invention, a positive bias component is introduced whose magnitude increases with increasing load voltage.
  • the circuit arrangement for achieving this result comprises a rectifier D which is inductively coupled by way of coil L to the plate tank circuit coil L.
  • a load resistance R4 together with radio frequency by-pass condenser K is included in the circuit of rectifier D with the result that a positive voltage is developed across R4 proportional to the alternating voltage across the load R1 and hence is a function of the power output of the stage.
  • the negative end of resistor R4 is grounded and the grid circuit return is connected by way of contact P to an adjustable point on B4. The total grid bias is thus reduced to a suitable operating value only in the presence of proper circuit adjustment.
  • the amount of reduction in the grid bias in the presence of normal power output from the amplifier tube may be controlled by adjusting the coupling between coils L and L1 as well as by adjustment of contact P, the coupling adjustment being slightly preferable because the resistance in the grid circuit is not affected thereby.
  • other means for couplin the plate tank circuit to the detector D may be employed, such as a capacitive connection.
  • the operation of the invention may be clarified by a description of the initial adjustment of the amplifier circuit. Without grid excitation, resistance R3 is reduced to the lowest value which still limits the plate dissipation to the allowable amount. Then, with the load circuit R1 short circuited and full grid excitation applied, R2 is reduced to the lowest value which will limit the plate dissipation to the allowable amount. Finally, with normal loading and proper plate circuit tuning, the setting of slider P, or preferably the coupling between L and L, is adjusted to reduce the total bias on the grid to the point where normal operation ofv the amplifier is obtained. These adjustments are preferably made initially with reduced plate voltage, after which the plate voltage is gradually increased as the adjustments are repeated until full plate voltage is applied.
  • the amplifier tube is safeguarded against nearly any contingency that might arise. For example, if grid excitation fails, the output voltage ceases and hence no positive bias is developed across R4 and the space current through R: develops a bias which limits the plate dissipation as above explained. On the other hand, if excessive loading or a detuning of the output circuit occurs, the output voltage drops and the positive bias is reduced and the tube is safeguarded by the excitation self-bias developed across resistor R2 as well as by the drop across B3.
  • the arrangement of the invention is advantageous for other purposes.
  • the constants of the circuit may be so adjusted as to make the bias of the amplifier stage vary throughout the modulation cycle in a predetermined manner so as to permit a larger carrier output than in the case of fixed'bias operation.
  • condensers K and/ or K will be chosen small enough so that the component bias voltages developed across resistors R3 and/or R4 Vary throughout the modulation cycle.
  • a radio frequency power amplifier tube circuit having grid and plate circuits
  • the method of operation which includes applying a first bias potentialto said grid which is proportional to the grid current and sufiiciently high to protect the tube from overheating in the event of plate circuit misadjustment, applying a second bias potential which is proportional to the space current in said amplifier and sufficiently high to tect the tube in the event of failure of grid excitation, and deriving from the alternating voltage in said plate circuit a third bias potential having a polarity in opposition to said first and second potentials and of such value as to reduce the total bias to a desired operating value in the presence of proper grid excitation and plate circuit adjustment.
  • a radio frequency power amplifier tube circuit having grid and plate circuits
  • the method of operation which includes applying a first bias potential to said grid which is proportional to the grid current, applying a second bias potential which is proportional to the space current in said amplifier, and deriving from the alternating voltage in said plate circuit a third bias potential having a polarity in opposition to said first and second potentials, the relations of said three applied bias potentials being such as to cause the total bias to vary in a predetermined manner throughout a cycle of modulation of the excitation voltage.
  • a radio frequency power amplifier comprising a vacuum tube having a grid, a cathode and a plate, a first resistor connected between said cathode and ground, a source of alternating current energy coupled to said grid and the grounded grounded end of said resistor, a parallel tuned tank circuit coupled between said plate and the positive terminal of a source of direct current potential, a rectifier having a cathode and plate coupled to said tuned circuit, a second resistor connected in the space current path of said rectifier, the negative end of said last resistor being connected to ground, whereby a positive voltage is developed across said second resistor which is proportional to the voltage across said tuned circuit, and a direct current connection from a point intermediate the ends of said last resistor to aid grid, said direct current connection including another resistor in series therewith, said resistor having such values as to permit operation of said power amplifier with full allowable plate excitation.
  • a radio frequency power amplifier comprising a vacuum tube having a grid, a cathode and a plate, a first resistor connected between said cathode and ground, a source of alternating current energy coupled to said grid and the grounded end of said resistor, a parallel tuned tank circuit coupled between said plate and the positive terminal of a source of direct current potential, a rectifier having a cathode and plate inductively coupled to said tuned circuit, a second resistor shunted by a condenser connected in the space current path of said rectifier, the negative end of said last resistor being connected to ground, whereby a positive voltage is developed across said second resistor which is proportional to the voltage across said tuned circuit, and a direct current connection from. a point intermediate the ends of said last resistor to said grid, said direct current connection including another resistor in series therewith, said resistors having such values as to permit operation of said power amplifier with full allowable plate excitation.
  • a radio frequency power amplifier comprising a vacuum tube having a grid, a'cathode and a plate, a first resistor connected between said cathode and ground, a source of alternating current energy coupled to said grid and the grounded end of said resistor, a parallel tuned tank circuit coupled between said plate and the positive terminal of a source of direct current potential, a rectifier having a cathode and plate inductively coupled to said tuned circuit, a second resistor shunted by a condenser connected in the space current path of said rectifier, the negative end of said last resistor being connected to ground, whereby a positive voltage is developed acrcss said second resistor which is proportional to the voltage across said tuned circuit, and a direct current connection from a point intermediate the ends of said last resistor to said grid, said direct current connection being adjustable over said second resistor and including another resistor in series therewith, said resistor having such values as to permit operation of said power amplifier with full allowable plate excitaion.

Description

e 1941- W. VAN B. ROBERTS 0 AMPLIFIER CIRCUIT Filed Jan. 7, 1939 INVENTOR. WALTER VAN B. ROBERTS A TTORNEY.
Patented June 24, 1941 M L I C RC I Walter van B. Roberts, Princeton, N. .L, assignor to Radio Corporation of America, a corporation of Delaware Application January 7, 1939, Serial No. 249,752
6 Claims.
This invention relates to electron discharge device amplifier circuits, and more particularly to a method of and means for biasing power amplifiers, whereby the bias varies as a function of several operating conditions.
It is known that amplifier stages as heretofore employed are often overloaded due to such factors as grid excitation failure, improper tuning of the plate tank circuit, and excessive loading.
To avoid excessive plate dissipation upon failure of grid excitation, it has been suggested to utilize a cathode bias resistor with the idea that excessive plate current is prevented by the resulting increasing bias. However, a sufiiciently large bias resistor to accomplish this result will usually produce too much bias under normal operating conditions because a much larger plate current is permissible in the presence of a large power output than in the absence of excitation or output. It has therefore been further proposed to utilize for a cathode bias resistor a material having a resistance which decreases rapidly with increasing current density so as to maintain a bias voltage sulliciently independent of plate current for many practical purposes. However, there still remains the possibility of excessive heating in case the plate tank circuit is improperly tuned or overloaded in the presence of excitation.
A primary object of the present invention is to provide a biasing arrangement for an amplifier which will insure suficient bias voltage to safeguard the amplifier tube, in case any of the following conditions occur: (1) Grid excitation failure, (2) improper plate circuit tuning, or (3) excessive plate circuit loading, while at the same time supplying only sufiicient bias for eificient operation in the presence of proper excitation and plate circuit tuning and loading.
A particular object of the invention is to provide a bias voltage for the amplifier tube, which voltage varies as a function of amplifier output even though the plate current and excitation remain unchanged.
The invention may be best described by reference to the accompanying drawing which represents one form of the invention. In the drawing, T is an amplifier vacuum tube having a cathode C, a grid G and a plate A. Tube T receives grid excitation from alternating current source e and delivers power to a load represented by R1 connected across the tuned plate tank circuit L, C. To prevent excessive dissipation in the absence of grid excitation, a sufliciently large resistance R3 is connected in the cathode circuit and shunted by radio frequency by-pass condenser K. To provide a grid bias which increases with increasing grid excitation, there is provided in the grid circuit a resistance R: whose value is sufliciently large to safeguard the tube in case the plate tank circuit L, C is detuned or greatly overloaded. While the biasing elements so far described are sufficient to safeguard the tube against any contingencies that might arise, the resulting bias in the case of proper adjustment of the amplifier stage would be too great to permit proper operation. Therefore, in accordance with the present invention, there is provided a circuit arrangement for reducing the total bias on the grid to a suitable value in the presence of proper grid excitation and plate circuit adjustment. In the illustrated form of the invention, a positive bias component is introduced whose magnitude increases with increasing load voltage. The circuit arrangement for achieving this result comprises a rectifier D which is inductively coupled by way of coil L to the plate tank circuit coil L. A load resistance R4, together with radio frequency by-pass condenser K is included in the circuit of rectifier D with the result that a positive voltage is developed across R4 proportional to the alternating voltage across the load R1 and hence is a function of the power output of the stage. The negative end of resistor R4 is grounded and the grid circuit return is connected by way of contact P to an adjustable point on B4. The total grid bias is thus reduced to a suitable operating value only in the presence of proper circuit adjustment. The amount of reduction in the grid bias in the presence of normal power output from the amplifier tube may be controlled by adjusting the coupling between coils L and L1 as well as by adjustment of contact P, the coupling adjustment being slightly preferable because the resistance in the grid circuit is not affected thereby. It will, of course, be obvious that instead of the inductive, coupling between coils L and L, other means for couplin the plate tank circuit to the detector D may be employed, such as a capacitive connection.
The operation of the invention may be clarified by a description of the initial adjustment of the amplifier circuit. Without grid excitation, resistance R3 is reduced to the lowest value which still limits the plate dissipation to the allowable amount. Then, with the load circuit R1 short circuited and full grid excitation applied, R2 is reduced to the lowest value which will limit the plate dissipation to the allowable amount. Finally, with normal loading and proper plate circuit tuning, the setting of slider P, or preferably the coupling between L and L, is adjusted to reduce the total bias on the grid to the point where normal operation ofv the amplifier is obtained. These adjustments are preferably made initially with reduced plate voltage, after which the plate voltage is gradually increased as the adjustments are repeated until full plate voltage is applied. When the adjustments have been carried out as above indicated, the amplifier tube is safeguarded against nearly any contingency that might arise. For example, if grid excitation fails, the output voltage ceases and hence no positive bias is developed across R4 and the space current through R: develops a bias which limits the plate dissipation as above explained. On the other hand, if excessive loading or a detuning of the output circuit occurs, the output voltage drops and the positive bias is reduced and the tube is safeguarded by the excitation self-bias developed across resistor R2 as well as by the drop across B3.
In addition to its action in safeguarding against tube damage, the arrangement of the invention is advantageous for other purposes. For example, in the case of an amplifier for modulated radio frequency voltage, the constants of the circuit may be so adjusted as to make the bias of the amplifier stage vary throughout the modulation cycle in a predetermined manner so as to permit a larger carrier output than in the case of fixed'bias operation. It will be understood that when modulated signals are to be amplified, condensers K and/ or K will be chosen small enough so that the component bias voltages developed across resistors R3 and/or R4 Vary throughout the modulation cycle.
While I have described one form of the invention, it will be apparent to those skilled in the art that many modifications thereof may be em.- ployed within the scope of the following claims.
It should be understood that the ground connection shown in the drawing and mentioned in the claims is deemed to include any point of zero radio frequency potential.
What is claimed is:
1. In a radio frequency power amplifier tube circuit having grid and plate circuits, the method of operation which includes applying a first bias potentialto said grid which is proportional to the grid current and sufiiciently high to protect the tube from overheating in the event of plate circuit misadjustment, applying a second bias potential which is proportional to the space current in said amplifier and sufficiently high to tect the tube in the event of failure of grid excitation, and deriving from the alternating voltage in said plate circuit a third bias potential having a polarity in opposition to said first and second potentials and of such value as to reduce the total bias to a desired operating value in the presence of proper grid excitation and plate circuit adjustment.
2. In a radio frequency power amplifier tube circuit having grid and plate circuits, the method of operation which includes applying a first bias potential to said grid which is proportional to the grid current, applying a second bias potential which is proportional to the space current in said amplifier, and deriving from the alternating voltage in said plate circuit a third bias potential having a polarity in opposition to said first and second potentials, the relations of said three applied bias potentials being such as to cause the total bias to vary in a predetermined manner throughout a cycle of modulation of the excitation voltage.
3. A radio frequency power amplifier comprising a vacuum tube having a grid, a cathode and a plate, a first resistor connected between said cathode and ground, a source of alternating current energy coupled to said grid and the grounded grounded end of said resistor, a parallel tuned tank circuit coupled between said plate and the positive terminal of a source of direct current potential, a rectifier having a cathode and plate coupled to said tuned circuit, a second resistor connected in the space current path of said rectifier, the negative end of said last resistor being connected to ground, whereby a positive voltage is developed across said second resistor which is proportional to the voltage across said tuned circuit, and a direct current connection from a point intermediate the ends of said last resistor to aid grid, said direct current connection including another resistor in series therewith, said resistor having such values as to permit operation of said power amplifier with full allowable plate excitation.
4. A radio frequency power amplifier comprising a vacuum tube having a grid, a cathode and a plate, a first resistor connected between said cathode and ground, a source of alternating current energy coupled to said grid and the grounded end of said resistor, a parallel tuned tank circuit coupled between said plate and the positive terminal of a source of direct current potential, a rectifier having a cathode and plate inductively coupled to said tuned circuit, a second resistor shunted by a condenser connected in the space current path of said rectifier, the negative end of said last resistor being connected to ground, whereby a positive voltage is developed across said second resistor which is proportional to the voltage across said tuned circuit, and a direct current connection from. a point intermediate the ends of said last resistor to said grid, said direct current connection including another resistor in series therewith, said resistors having such values as to permit operation of said power amplifier with full allowable plate excitation.
5. A radio frequency power amplifier comprising a vacuum tube having a grid, a'cathode and a plate, a first resistor connected between said cathode and ground, a source of alternating current energy coupled to said grid and the grounded end of said resistor, a parallel tuned tank circuit coupled between said plate and the positive terminal of a source of direct current potential, a rectifier having a cathode and plate inductively coupled to said tuned circuit, a second resistor shunted by a condenser connected in the space current path of said rectifier, the negative end of said last resistor being connected to ground, whereby a positive voltage is developed acrcss said second resistor which is proportional to the voltage across said tuned circuit, and a direct current connection from a point intermediate the ends of said last resistor to said grid, said direct current connection being adjustable over said second resistor and including another resistor in series therewith, said resistor having such values as to permit operation of said power amplifier with full allowable plate excitaion.
6-.'A radio frequency power amplifier in accordance with claim 3, characterized in this that the degree-of coupling between said rectifier and said tuned circuit is adjustable.
WALTER VAN B. ROBERTS.
US249752A 1939-01-07 1939-01-07 Amplifier circuit Expired - Lifetime US2247203A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2589299A (en) * 1950-05-23 1952-03-18 Barton T Sctchell Safety control circuit for electronic amplifiers
DE966205C (en) * 1944-07-22 1957-07-25 Siemens Ag Device for regulating high-frequency generators
US2918629A (en) * 1957-12-03 1959-12-22 Avco Mfg Corp Automatic overload protection system

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE966205C (en) * 1944-07-22 1957-07-25 Siemens Ag Device for regulating high-frequency generators
US2589299A (en) * 1950-05-23 1952-03-18 Barton T Sctchell Safety control circuit for electronic amplifiers
US2918629A (en) * 1957-12-03 1959-12-22 Avco Mfg Corp Automatic overload protection system

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