US2948869A - Reactance networks - Google Patents
Reactance networks Download PDFInfo
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- US2948869A US2948869A US555535A US55553555A US2948869A US 2948869 A US2948869 A US 2948869A US 555535 A US555535 A US 555535A US 55553555 A US55553555 A US 55553555A US 2948869 A US2948869 A US 2948869A
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- voltage
- electrode
- circuit
- reactance
- tuned circuit
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03J—TUNING RESONANT CIRCUITS; SELECTING RESONANT CIRCUITS
- H03J7/00—Automatic frequency control; Automatic scanning over a band of frequencies
- H03J7/02—Automatic frequency control
- H03J7/04—Automatic frequency control where the frequency control is accomplished by varying the electrical characteristics of a non-mechanically adjustable element or where the nature of the frequency controlling element is not significant
- H03J7/042—Automatic frequency control where the frequency control is accomplished by varying the electrical characteristics of a non-mechanically adjustable element or where the nature of the frequency controlling element is not significant with reactance tube
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03G—CONTROL OF AMPLIFICATION
- H03G1/00—Details of arrangements for controlling amplification
- H03G1/0005—Circuits characterised by the type of controlling devices operated by a controlling current or voltage signal
- H03G1/0035—Circuits characterised by the type of controlling devices operated by a controlling current or voltage signal using continuously variable impedance elements
Definitions
- This invention relates generally to variable reactance circuits, and more particularly to such circuits wherein triodes or transistors may be more efliciently embodied.
- a reactance may be simulated by means of'a vacuum tube and associated elements.
- Such a reactance circuit usually requires a tube of the pentode type,"and additional circuit elements, such as, a capacitor andaresistor, are utilized as a phase-splitting network.
- a variable reactance circuit of this type may be used for many purposes, such as, for example, adjusting or varying the resonant frequency of a tuned circuit.
- three electrode electrical elements, for example, triodes have not been adaptable to these purposes because the rather low plate resistance of the triode presents a large realcomponent of impedance along with the imaginary component which results in an unsatisfactory variable loading effect on the tuned circuit.
- the present invention is directed toward an improved reactance network wherein a triode, or other three electrode device, may be embodied as a variable-reactance element. It has been found that this objective may be attained by providing two feedback paths to the element, one of which functions to increase theap parent internal resistance of the element, thus reducing-loading, and the other of which provides a reactive current through the element, thus causing the element to appear as a reactance to the load. This reactiv'e current may then be easily controlled, thereby providing a variable reactance device capable of exercising' control over a load circut.
- Fig. 1 is aschematic diagram of a reactance network in accordance with the invention
- Fig. 2 is' aplot of the plate characteristics of a triode useful in explainingithe operation of the invention
- Fig. 3 is a vector diagram useful in further illustrating the operation of the invention.
- Figs. 4 and S are schematic diagrams of reactance network'sin accordance with the invention wherein a transistor may be embodied as the three-electrode element.
- a reactance network comprising a three-electrode element 10, such as, a triode, for example, having a tuned parallel resonant circuit comprising coil 1 and condenser 2 connected to its plate electrode 3.
- Triode is self-biased in a conventional manner by means of resistor 4 and by-pass condenser 5, connected in circuit with cathode 6, although it should be understood that other biasing methods may be conveniently substituted.
- Grid 7 is connected to a junction point between a condenser 8 and a resistor 9, the other side of condenser 8 being connected to the resonant circuit, while the other end of resistor 9 is connected to a source of DC. control voltage through resistor 11.
- a pick-up coil 12 allows voltage to be fed back degeneratively from coil 1 into the circuit of cathode 6 in order toeifectively change the bias existing at the grid 7.
- triode 10 Since, as shown by the vector diagram of Fig. 3, the change of current in the plate circuit Ai due to e is 180 out of: phase with the change Ai' due to the feedbackwoltage e the amount of net current actually flowing maybe controlled by the value assigned to e due to the cancellation effect caused thereby.
- a second feedback path is provided through condenser 8.
- signal voltage as from an oscillator circuit (not shown)
- a current will flow through condenser 8 and resistance 9, which jcurrent will lead by an angle depending on the value of condenser 8.
- the voltage drop across resistor 9 dueto this-current will be in phase with the current through condenser 8. This voltage drop will tend to appear on grid 7 of the tube, and is represented as e fl in Fig. 3.
- Thevectorial combination of e',, and e fl thus provides thetotal voltage e which is applied to grid 7.
- Tube 10 will thus function as a capacitive reactance in parallel with the tuned circuit, the value of the reactance being controllable, as by a DC. control voltage applied to grid 7, to change the effective reactance of the tuned circuit, and hence the resonant frequency thereof.
- Such a device may include a semiconducting body and at least three electrodes called the base, emitter and collector electrodes which are in contact with the body.
- the semiconducting body may, for example, consist of a crystal of silicon or germanium while the emitter and collector electrodes may be fine pointed wires in rectifying smallarea contact with the body.
- Transistor 15 has an emitter electrode 16, a collector electrode 17, and a base Patented Aug. 9, 1960 electrode 18 in contact with semiconducting body 19.
- Base electrode 18 may be grounded as shown.
- a variable voltage in the forward direction is impressed between emitter 16, and base 18, while a bias voltage in the reverse direction is applied to collector 17 from a suitable source such as a battery 20.
- the variable voltage applied to emitter 16 may also be provided by a suitable battery 21, across which a resistor 22 is connected.
- a tap 23 on resistor 22 may be grounded as shown, while a variable tap 24 is connected to emitter 16 through emitter resistor 25.
- Included in the circuit is a parallel resonant circuit comprising a condenser 26 and an inductor 2.7, one end of each of which is connected together. The other end of condenser 26 is connected to emitter 1 6, while the other end of inductor 27 is grounded thereby being effectively connected to base electrode .18.
- a pick-up coil 28 is provided to feed a portion of the voltage developed across inductor 27 back to emitter 16. Since the collector characteristics of a point contact transistor are very similar to the characteristics of a triode as shown in -Fig. 3, the feedback arrangement serves to increase the internal resistance of the transistor in the manner previously described, thus reducing the objectionable loading effect on the resonant circuit. The magnitude of the reactance thereby placed in circuit with the resonant circuit is easily controlled 'by variation of emitter bias by means of tap 24.
- an arrangement such as shown in Fig. 5, may be utilized which is identical to that in Fig. 4 except that pick-up coil 28 feeds into the base 18 rather than emitter .16.
- a variable reactance circuit comprising an electrical translation device having at least an input electrode, an output electrode, and an electrode common to the circuits of said input and output electrodes, an output load in circuit with said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said load for applying a feedback voltage from said output load to said common electrode which is 180 out of phase with and responsive to changes in a first voltage existing across said load whereby the current flowing through said load remains substantially constant with changes in said first voltage, and means interconnected between said load and said input electrode for simultaneously applying a second voltage substantially out of phase with said feedback voltage to said input electrode whereby current flowing through said device is out of phase with the voltage across said device.
- a variable reactance circuit comprising an electrical translation device having at least an input electrode, an output electrode, and an electrode common to the circuits of said input and output electrodes, a tuned circuit connected to said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said tuned circuit for applying a feedback voltage from said tuned circuit to said common electrode which is 180 out of 6 phase with and responsive to changes in a first voltage 4 existing across said tuned circuit whereby the current flowing through said tuned circuit remains substantially constant with changes in said first voltage, and means interconnected between said tuned circuit and said input electrode for applying a second voltage to said input electrode which is substantially out of phase with said feedback voltage whereby current flowing through said device is out of phase with a voltage across said device.
- a variable reactance circuit comprising an electron tube having at least an input electrode, an output electrode, and an electrode common to the circuits of said input and output electrodes, an output load in circuit with said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said load for applying a feedback voltage from said output load to said common electrode which is out of phase with and responsive to changes in a first voltage existing across said load whereby the current flowing through said load remains substantially constant withchanges in said first voltage, and means interconnected between said load and said input electrode for simultaneously applying a second voltage substantially out of phase with said feedback voltage to said input electrode whereby current flowing through said tube is out of phase with the voltage across said tube.
- a variable reactance circuit comprising an electrical translation device having at least an input electrode, an output electrode, an electrode common to the circuits of said input and output electrodes, said device further having a family of characteristics such that an increase in voltage applied to one of said electrodes will cause'an increase in the current drawn by said electrode, a tuned circuit connected to said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said tuned circuit for applying a feedback voltage from said tuned circuit to said common electrode which is 180 out of phase with and responsive to changes in a first voltage existing across said tuned circuit whereby the current flowing through said tuned circuit remains substantially constant with changes in said first voltage, and means interconnected between said tuned circuit and said input electrode for applying a second voltage to said input electrode substantially out of phase with said feedback voltage whereby current flowing through said device is made to be out of phase with the voltage across said device.
- variable reactance circuit according to claim 1 wherein said electrical device is a transistor.
Description
1950 JL F. BIGELOW 2,948,869
REACTANCE NETWORKS Filed Dec. 27, 1955 CONTROL JOHN F. BIGELOW G r ORA/EV United States PatentO REACTAN CE NETWORKS John F. Bigelow, Philadelphia, Pa., assignor to Raytheon Company, a corporation of Delaware Filed Dec. 27, 1955, Ser. No. 555,535
Claims. (Cl. 333-80) This invention relates generally to variable reactance circuits, and more particularly to such circuits wherein triodes or transistors may be more efliciently embodied.
it is well known that a reactance may be simulated by means of'a vacuum tube and associated elements. Such a reactance circuit usually requires a tube of the pentode type,"and additional circuit elements, such as, a capacitor andaresistor, are utilized as a phase-splitting network. A variable reactance circuit of this type may be used for many purposes, such as, for example, adjusting or varying the resonant frequency of a tuned circuit. In the past, three electrode electrical elements, for example, triodes, have not been adaptable to these purposes because the rather low plate resistance of the triode presents a large realcomponent of impedance along with the imaginary component which results in an unsatisfactory variable loading effect on the tuned circuit.
Accordingly, the present invention is directed toward an improved reactance network wherein a triode, or other three electrode device, may be embodied as a variable-reactance element. It has been found that this objective may be attained by providing two feedback paths to the element, one of which functions to increase theap parent internal resistance of the element, thus reducing-loading, and the other of which provides a reactive current through the element, thus causing the element to appear as a reactance to the load. This reactiv'e current may then be easily controlled, thereby providing a variable reactance device capable of exercising' control over a load circut.
The invention will be better understood as the following description proceeds, taken in conjunction with the accompanying drawingwherein:
Fig. 1 is aschematic diagram of a reactance network in accordance with the invention;
Fig. 2 is' aplot of the plate characteristics of a triode useful in explainingithe operation of the invention;
Fig. 3 is a vector diagram useful in further illustrating the operation of the invention; and
Figs. 4 and S are schematic diagrams of reactance network'sin accordance with the invention wherein a transistor may be embodied as the three-electrode element.
Referring now to the drawing, and more particularly toJFig. 1 thereof, there is shown a reactance network comprising a three-electrode element 10, such as, a triode, for example, having a tuned parallel resonant circuit comprising coil 1 and condenser 2 connected to its plate electrode 3. Triode is self-biased in a conventional manner by means of resistor 4 and by-pass condenser 5, connected in circuit with cathode 6, although it should be understood that other biasing methods may be conveniently substituted. Grid 7 is connected to a junction point between a condenser 8 and a resistor 9, the other side of condenser 8 being connected to the resonant circuit, while the other end of resistor 9 is connected to a source of DC. control voltage through resistor 11. A pick-up coil 12, allows voltage to be fed back degeneratively from coil 1 into the circuit of cathode 6 in order toeifectively change the bias existing at the grid 7.
As shown by the curves of Fig. 2, an increase in the value of voltage, e existing at the plate of a triode, will ordinarily result in an increase in the plate current i if the value of grid voltage e is maintained constant. This change of plate voltage and corresponding change of. plate current may be =usedto represent the internal A.C. refsistance of the tube, r which may be further represented as This. resistance, r may thus be considered as being shunted across the tuned circuit of Fig. l, and since its value varies withchange of plate current or voltage,
it gives rise to an undesirable variable loading effect on the'tunedcircuit. In accordance with the present invention,lthis difliculty is overcome by feeding a portion of the voltage developed across the tuned circuit, back to the cathode circuit through pickup coil 12. Since this voltage is 180 out of phase with the voltage across the tuned circuit, the effect will be to move the operating point from A to B 'as shown in Fig. 2, thus holding the change in plate current to any desired value. The ratio may thus be controlled to impart a higher value to r thanheretofore possible, thereby considerably reducing the loading on the tuned circuit.
Since, as shown by the vector diagram of Fig. 3, the change of current in the plate circuit Ai due to e is 180 out of: phase with the change Ai' due to the feedbackwoltage e the amount of net current actually flowing maybe controlled by the value assigned to e due to the cancellation effect caused thereby. In order to make triode 10 appear as a reactance to the tuned circuit, a second feedback path is provided through condenser 8. When signal voltage, as from an oscillator circuit (not shown), is applied across the tuned circuit, a current will flow through condenser 8 and resistance 9, which jcurrent will lead by an angle depending on the value of condenser 8. The voltage drop across resistor 9 dueto this-current will be in phase with the current through condenser 8. This voltage drop will tend to appear on grid 7 of the tube, and is represented as e fl in Fig. 3. Thevectorial combination of e',, and e fl thus provides thetotal voltage e which is applied to grid 7.
This voltage e will then be amplified, and cause a final plate current i to flow which current may be made to lead the voltage'across the tuned circuit by by proper choice of the size of condenser 8. Tube 10 will thus function as a capacitive reactance in parallel with the tuned circuit, the value of the reactance being controllable, as by a DC. control voltage applied to grid 7, to change the effective reactance of the tuned circuit, and hence the resonant frequency thereof.
As a further feature of the present invention, it has been found that the foregoing principles are equally applicablewhen a transistor is embodied in the circuit as the. three electrode electrical element. Such a device may include a semiconducting body and at least three electrodes called the base, emitter and collector electrodes which are in contact with the body. The semiconducting body may, for example, consist of a crystal of silicon or germanium while the emitter and collector electrodes may be fine pointed wires in rectifying smallarea contact with the body. Such a device is shown embodied in the circuit of Fig. 4. Transistor 15 has an emitter electrode 16, a collector electrode 17, and a base Patented Aug. 9, 1960 electrode 18 in contact with semiconducting body 19. Base electrode 18 may be grounded as shown. A variable voltage in the forward direction is impressed between emitter 16, and base 18, while a bias voltage in the reverse direction is applied to collector 17 from a suitable source such as a battery 20. The variable voltage applied to emitter 16 may also be provided by a suitable battery 21, across which a resistor 22 is connected. A tap 23 on resistor 22 may be grounded as shown, while a variable tap 24 is connected to emitter 16 through emitter resistor 25. Included in the circuit is a parallel resonant circuit comprising a condenser 26 and an inductor 2.7, one end of each of which is connected together. The other end of condenser 26 is connected to emitter 1 6, while the other end of inductor 27 is grounded thereby being effectively connected to base electrode .18. A pick-up coil 28 is provided to feed a portion of the voltage developed across inductor 27 back to emitter 16. Since the collector characteristics of a point contact transistor are very similar to the caracteristics of a triode as shown in -Fig. 3, the feedback arrangement serves to increase the internal resistance of the transistor in the manner previously described, thus reducing the objectionable loading effect on the resonant circuit. The magnitude of the reactance thereby placed in circuit with the resonant circuit is easily controlled 'by variation of emitter bias by means of tap 24.
If desired, an arrangement, such as shown in Fig. 5, may be utilized which is identical to that in Fig. 4 except that pick-up coil 28 feeds into the base 18 rather than emitter .16.
Although there have been described what are considered to .be preferred embodiments of the present invention, various adaptations and modifications thereof may be made without departing from the spirit and scope of the invention as defined in the appended claims.
What is claimed is:
l. A variable reactance circuit comprising an electrical translation device having at least an input electrode, an output electrode, and an electrode common to the circuits of said input and output electrodes, an output load in circuit with said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said load for applying a feedback voltage from said output load to said common electrode which is 180 out of phase with and responsive to changes in a first voltage existing across said load whereby the current flowing through said load remains substantially constant with changes in said first voltage, and means interconnected between said load and said input electrode for simultaneously applying a second voltage substantially out of phase with said feedback voltage to said input electrode whereby current flowing through said device is out of phase with the voltage across said device.
2. A variable reactance circuit comprising an electrical translation device having at least an input electrode, an output electrode, and an electrode common to the circuits of said input and output electrodes, a tuned circuit connected to said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said tuned circuit for applying a feedback voltage from said tuned circuit to said common electrode which is 180 out of 6 phase with and responsive to changes in a first voltage 4 existing across said tuned circuit whereby the current flowing through said tuned circuit remains substantially constant with changes in said first voltage, and means interconnected between said tuned circuit and said input electrode for applying a second voltage to said input electrode which is substantially out of phase with said feedback voltage whereby current flowing through said device is out of phase with a voltage across said device.
3. A variable reactance circuit comprising an electron tube having at least an input electrode, an output electrode, and an electrode common to the circuits of said input and output electrodes, an output load in circuit with said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said load for applying a feedback voltage from said output load to said common electrode which is out of phase with and responsive to changes in a first voltage existing across said load whereby the current flowing through said load remains substantially constant withchanges in said first voltage, and means interconnected between said load and said input electrode for simultaneously applying a second voltage substantially out of phase with said feedback voltage to said input electrode whereby current flowing through said tube is out of phase with the voltage across said tube.
4. A variable reactance circuit comprising an electrical translation device having at least an input electrode, an output electrode, an electrode common to the circuits of said input and output electrodes, said device further having a family of characteristics such that an increase in voltage applied to one of said electrodes will cause'an increase in the current drawn by said electrode, a tuned circuit connected to said output electrode and said common electrode, feedback means directly connected to said common electrode and cooperative with said tuned circuit for applying a feedback voltage from said tuned circuit to said common electrode which is 180 out of phase with and responsive to changes in a first voltage existing across said tuned circuit whereby the current flowing through said tuned circuit remains substantially constant with changes in said first voltage, and means interconnected between said tuned circuit and said input electrode for applying a second voltage to said input electrode substantially out of phase with said feedback voltage whereby current flowing through said device is made to be out of phase with the voltage across said device.
5. A variable reactance circuit according to claim 1 wherein said electrical device is a transistor.
References Cited in the file of this patent UNITED STATES PATENTS OTHER REFERENCES Terman: Radio Engineering, third ed., published in 1947 by McGraw-Hill Book Co., Inc., pages 322-326.
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US555535A US2948869A (en) | 1955-12-27 | 1955-12-27 | Reactance networks |
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US555535A US2948869A (en) | 1955-12-27 | 1955-12-27 | Reactance networks |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3152309A (en) * | 1960-08-23 | 1964-10-06 | Philco Corp | Simulated high-q inductor |
US3154750A (en) * | 1961-04-28 | 1964-10-27 | Charles E David | High frequency phase splitter utilizing bifilar windings |
DE1201425B (en) * | 1962-09-06 | 1965-09-23 | Blaupunkt Werke Gmbh | Electrically tunable high frequency amplifier |
US3465254A (en) * | 1965-11-29 | 1969-09-02 | Motorola Inc | Ultrahigh frequency phase shifter |
Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1783557A (en) * | 1925-04-02 | 1930-12-02 | Bethenod Joseph | Compensating system for amplifiers |
US2351934A (en) * | 1944-06-20 | Selectivity apparatus | ||
FR905881A (en) * | 1943-05-03 | 1945-12-17 | Licentia Gmbh | Wideband amplifier feedback coupled through multiple stages |
US2457034A (en) * | 1946-06-21 | 1948-12-21 | Hazeltine Research Inc | Arrangement for simulating a reactive impedance |
US2469194A (en) * | 1942-12-12 | 1949-05-03 | Gen Electric | Reactance tube circuit |
US2870421A (en) * | 1954-05-03 | 1959-01-20 | Rca Corp | Transistor reactance circuit |
-
1955
- 1955-12-27 US US555535A patent/US2948869A/en not_active Expired - Lifetime
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2351934A (en) * | 1944-06-20 | Selectivity apparatus | ||
US1783557A (en) * | 1925-04-02 | 1930-12-02 | Bethenod Joseph | Compensating system for amplifiers |
US2469194A (en) * | 1942-12-12 | 1949-05-03 | Gen Electric | Reactance tube circuit |
FR905881A (en) * | 1943-05-03 | 1945-12-17 | Licentia Gmbh | Wideband amplifier feedback coupled through multiple stages |
US2457034A (en) * | 1946-06-21 | 1948-12-21 | Hazeltine Research Inc | Arrangement for simulating a reactive impedance |
US2870421A (en) * | 1954-05-03 | 1959-01-20 | Rca Corp | Transistor reactance circuit |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3152309A (en) * | 1960-08-23 | 1964-10-06 | Philco Corp | Simulated high-q inductor |
US3154750A (en) * | 1961-04-28 | 1964-10-27 | Charles E David | High frequency phase splitter utilizing bifilar windings |
DE1201425B (en) * | 1962-09-06 | 1965-09-23 | Blaupunkt Werke Gmbh | Electrically tunable high frequency amplifier |
US3465254A (en) * | 1965-11-29 | 1969-09-02 | Motorola Inc | Ultrahigh frequency phase shifter |
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