USRE24678E - pinckaers - Google Patents

Description

Aug. 11, 1959 B. H. PINCKAERS TRANSISTOR CONTROL APPARATUS Original Filed Dec. 29, 1954 A. C. SUPPLY INVENTOR B. H. PINCKAERS ATTORNEY Re. 24,678 Re'issued Aug. 11, 1959 United States Patent Ofifice TRANSISTOR CONTROL APPARATUS Balthasar H. Pinckaers, Edina, Minn., assignor to Minneapolis-Honeywell Regulator Company, Minneapolis, Minn., a corporation of Delaware Original No. 2,872,595, dated February 3, 1959, Serial No. 478,469, December 29, 1954. Application for reissue February 4, 1959, Serial No. 791,241 7 12 Claims. (Cl. 307-885) Matter enclosed in heavy brackets appears in the original patent but forms no part of this reissue specification; matter printed in italics indicates the additions made by reissue.

This invention rel-ates to transistor control apparatus and more specifically to a new and improved transistor discriminator circuit. The transistor discriminator circuit which provides an AC. output is so constructed that the input and output transformers previously required in discriminator circuits of this type have been eliminated. The invention describes a transistor control apparatus which supplies AC. power to a load device when the input signal potential is of one phase, proportional to the magnitude of the signal potential, and supplies no power to the load when the signal is of the opposite phase.

An object of the invention is to provide an improved and simplified transistor discriminator circuit which is selectively responsive to an AC. signal potential to produce an AC. output proportional in magnitude to the signal.

Another object of the invention is to provide a transistor discriminator circuit which has no input or output transformer and which provides an AC. output to a load device.

These and other objects of the present invention will be understood upon consideration of the accompanying specification, claims and drawings of which the single figure of the drawing is a schematic diagram of the improved transistor discriminator circuit comprising the invention.

Referring now to the single figure of the drawing there is shown a transformer 10 having a primary winding 11 connected to a suitable source of alternating current and having secondary windings 12, 13 and 14. Secondary winding '12 is connected by conductors 15 and 16 to input terminals 20 and 21 of a resistance bridge circuit 17. The bridge 17 comprises fixed impedance members 22, 23, 24, and a condition responsive impedance member 25, which may be, for example, a temperature responsive element such as a NTC resistor. The bridge has a pair of output terminals 26 and 27, the former being connected to ground 30 by a ground conductor 31. The bridge is connected to control a transistor amplifier stage which comprises a transistor 32, shown for illustrative purposes as a p-n-p transistor. The transistor 32 includes a collector electrode 33, an emitter electrode 34 and a base electrode 35. The emitter electrode 34 is connected to ground by a conductor 36 and conductor 31. Base electrode is connected to output terminal 27 of bridge 17 by a conductor 37. Collector electrode 33 is connected to a terminal of a source of negative potential through a conductor 40, a resistor 41 and a conductor 42. A base bias resistor 29 is connected between junction 28 on conductor 37 and a junction 47 on the conductor 42. The source of negative potential 46 includes secondary winding 13, a diode rectifier 43, and a filter capacitor 44. The positive side of the potential source is connected to ground potential. A pair of output transistors 50 tive.

and 51 are controlled by the output of transistor 32. Transistor 50 has a collector electrode 52, an emitter electrode 53, and a base electrode 54, and transistor 51 has a collector electrode 55, an emitter electrode 56 and a base electrode 57. A pair of diodes 60 and 61, which may be germanium diodes, are connected in series with emitter electrodes 53 and 56 respectively by conductors 62 and 63. Emitter electrode 53 is connected to base electrode 57 through conductor 62, diode 60, a conductor 63,'a junction 64, and a conductor 65, likewise emitter electrode 56 is connected to base electrode 54 through conductor 63, diode 61, a conductor 66, a junction 67 and a conductor 68. Base 54 and emitter 56 are connected to the previous stage transistor collector electrode 33 by a capacitor '70 connected between junction 67 and a junction 38 on conductor 40. Base electrode 57 and emitter electrode 53 are connected to emitter electrode 34 of transistor 32 by a conductor 71 connected between junction 64 and a junction 39 on conductor 36. Secondary winding 14 of the transformer 10 has a terminal 18 connected to the collector electrode 55 of transistor 51 by a conductor 72. A terminal 19 of the winding 14 is connected to the collector electrode 52 of transistor 50 through a conductor 73, a suitable load device 74, and a conductor 75.

OPERATION In the drawing there is shown a null balance system. A.C. bridge 17 is energized by transformer winding 12. Assuming a condition such that the bridge is balanced there is no signal from output terminals 26 and 27 of the bridge. If conditions change so that condition responsive resistor 25 increases in resistance, an output signal of one phase will result, and if the conditions change in the opposite direction so that resistor 25 decreases, an output signal of the reverse phase will result. The A.C. output signal from the bridge is fed to the input of transistor 32, which is biased class A. The bridge signal is applied across emitter 34 and base 35 and results in an amplified alternating component being impressed on the DC. current flowing in the collector circuit and through resistor 41. The alternating signal is coupled to the discriminator stage through coupling capacitor 70. Transistor stage 32 merely providessignal amplification and may be omitted if desired. The discriminator stage comprising transistors 50 and 51 is arranged to provide a full Wave alternating output to a load directly without the use of input and output transformers.

Let us assume an instantaneous polarity of the source such that terminal 18 of transformer winding 14 is negati ve with respect to terminal 19. Let us also assume the instantaneous signal potential at junction 67 is posi- Current will tend to flow from terminal 19 through load device 74, through the low impedance collector-base junction of transistor 50 in the forward direction, or direction of easy current fiow, through conductors 68 and 66, diode '61 in the forward direction, conductor 63 to the emitter 56 of transistor 51. Since we assumed a signal potential such that base 57 is negative with respect to emitter 56, the transistor is biased to conduct easily cur rent and the load current flows through the transistor and from collector 55 through conductor 72 to terminal 18 of the Winding 14. The diode 60 in the emitter circuit of transistor 50 prevents any current from flowing out of the emitter circuit during the portion of the cycle transistor 50 is acting as a diode from collector 52 to base 54. On the succeeding half cycle terminal 18 becomes instantaneously positive with'respect to terminal 19 of transformer winding 14. Now current tends to flow from terminal 18 through conductor 72 to collector 55 of transistor 51, through the collector-base junction in the forward direction, through conductors 65 and 63, through diode 60 in the forward direction, conductor '62 to emitter 53 of transistor 50. The instantaneous polarity of the signal having also reversed, function 67 is negative with respect to ground so that base 54 is. negative with respect to emitter 53 biasing transistor 50 for easy current flow. The load current flows through the transistor, from col lector '52- through conductor 75 to the load 74, and from the load through conductor 73 to terminal 19 of winding 14. Diode 61 prevents current from flowing out of the emitter circuit 56 during the portion of the cycle transistor 51 is operating as a diode from collector 55 to base 57. Thus it is seen that only one transistor operates as a transister on each half cycle, the other operating as a diode.

The system is. a proportional system so that as. the signal unbalance. from bridge 11 increases, the larger becomes the current permitted to flow through the load 74'. The load device 74' which preferably is a pro-portioning device, may for example, control the condition being sensed by condition responsive resistor 25. As the condition being sensed changes so that the. bridge 17' returns toward balance the signal magnitude decreases reducing the bias to the discriminator stage and the current flowing to the load 74 decreases. At a balanced condition of the bridge, with. no A.C. signal being applied to the discriminator the load. current is substantially' cut oit. A reverse condition from that previously described unbalances the bridge in the opposite direction producing a signal output of the opposite phase. When a signal of the opposite phase is applied to the input of the discriminator stage the transistors remain cut off and. no current flows to the load. Thus with a signal of one phase applied a. full wave A.C. output results and with a signal of the opposite phase the load is not energized.

The transistors have been shown and described as p-n-p type, however, the invention. is not so limited and by proper consideration of energizing polarities and the direction which diodes 60 and 61 are connected with respect to the emitters, any suitable transistor may be used. If the transistors 50 and 51 are n-p-n the diodes 60 and 61 must be connected to conduct in the opposite direction.

In general while. I' have shown a specific embodiment of my invention, it is. to be. understood that this is for the purpose of illustration and that my invention is to be limited solely by the scope; otLthe. appended claims.

1 claim asmy invention:

1. Transistor discriminator. apparatus comprising: first. and second transistors, said first transistor having a first base, collector, and emitter, said second transistor having a second base, collector, and emitter; first and second asymmetrical conducting devices each having an input and an output terminal, said output terminals of said first and second asymmertical conducting devices being directly connected respectively to said first and second emitters; a source of alternating potential means including load means connecting opposite terminals of said potential source intermediate said first and second c01- lectors so that said transistors are energized out of. phase; means directly connecting said first base to said second input terminal and directly connecting said second base to said first input terminal so that current flowing; from said first base flows to said second emitter through said second asymmetrical conducting. device; a source of alternating signal current of variable magnitude and reversible phase, said signal current source being connected to said first and second transistors in. phase opposition, so that with a signal of one phase both transistors will conduct current on alternate half cycles of said potential source. respectively, while. a signal of the. reverse phase prevents conduction of both transistors.

2 Transistor control apparatus comprising: first and: second transistors, each oi. said transistors. havingv a plurality of electrodes including a collector, an emitter, and.

a base electrode, two of said electrodes oi each transis tor comprising input terminals; direct current conductive means directly connecting said first transistor base electrode exclusively to said second transistor emitter electrode and directly connecting said second transistor base electrode exclusively to said first transistor emitter electrode; a source of alternating potential; load means; circuit means including said load means connecting the collectors of said transistors to opposite. terminals of saidalternating potential; source so that said transistors. are energized in phase opposition; a first current path through said transistors, said path being between emitter and collector; a second current path through said transistors, said path being between collector and base, so. that during one half cycle current flows through the first current path of said first. transistor and the second current path of said second transistor and on the succeeding half cycle current flows through said second current path of said first transistor and through said first current path of, said second transistor; and a source of signal current connected to said input terminals to control the magnitude of current fiow through said transistors.

3. Transistor control? apparatus: comprising: first and second transistors, each of said transistors having a plurality of electrodes including a collector, an emitter and.

a baseelectrode, two of said electrodes comprising the. input terminals; first and second asymmetrical conducting means, conductive. means directly connecting the base. of said first transistor to the emitter of said second. transistor through. said second asymmetrical conducting means; conductive means directly connecting said. base of said second transistor to the emitter of said first tran sistor through said; first. asymmertical conducting. means;

a source of alternating current potential; load means;

circuit means including said load means connecting the."

collectors of said transistors to opposite terminals of said potential: source; and means connecting a source of alternating signal potential to the input terminals of said transistors to control the conduction of said transistors in response to said signal.

4. Control apparatus comprising: a pair of transistors, each of said transistors including a collector electrode, an emitter electrode and a control electrode; means including nonlinear impedance means directly connecting the emitter electrode of a first of said transistors to the control electrode of the second of said transistors, and directly connecting the emitter electrode of said second transistor to the control electrode of said first transistor; a source of alternating current potential; load means; circuit means including said load means directly connecting the collector electrodes of said first and second transistors respectively to opposite terminals of said source; and a source of alternating current signal potential connected to control the current flow through said transistors.

5. Control apparatus comprising: first and second. transistors, each of said transistors having a collector electrode, a base electrode and an emitter electrode, two of said electrodes comprising input terminals; conductive coupling means directly connecting together the first transistor emitter electrode to the second transistor base electrode and also directly connecting together the second transistor emitter electrode to the first transistor base elecrode; a source of alternating potential; means 6. Transistor control apparatus comprising: a. signal.

current source of variable magnitude and reversible phase;

a pair of transistors each having. a plurality of electrodes. including a collector, an: emitter, and a base; conductive.

means directly connecting the base electrode of the first of said transistors to. the: emitter electrode of. the second. of said transistors; and also directly connecting the. base electrode of said second transistor to the emitter electrode of said first transistor; output means; a source of alternating potential; means including said output means connecting said collectors to opposite terminals, respectively, of said source of alternating potential; circuit means connecting said signal current source to the emitter and base electrodes of said transistors, said signal being applied in opposite sense to each of said pair of transistors in such manner that a signal current of one phase controls conduction of said transistors so that a substantially continuous current flows through said transistors to said output means, while a signal current of the opposite phase substantially cuts off current flow to said output means.

7. Transistor control apparatus comprising: a signal current source of variable magnitude and reversible phase; a pair of transistors each having a plurality of electrodes including a collector, an emitter, and a base, at least one of said included electrodes of each transistor comprising output terminals; a pair of said included electrodes of each transistor comprising input terminals; conductive means directly connecting the base electrode of the first of said transistors to the emitter electrode of the second of said transistors, and also directly connecting the base electrode of said second transistor to the emitter electrode of said first transistor; output means; a source of alternating potential; means including said output terminals to opposite terminals, respectively, of said source of alternating potential, said potential having a frequency corresponding to the frequency of said signal current source; circuit means connecting said signal current source in phase opposition to said input terminals of each of said transistors in such manner that a signal current of one phase controls conduction of said transistors so that a substantially continuous current flows through said transistors to said output means, while a signal current of the opposite phase substantially cuts off current flow through said transistors to said output means.

8. A circuit arrangement comprising a pair of transistors, each having an emitter electrode, a collector electrode, a base electrode, on emitter-collector path and a collector-base path, means for connecting the emittercollector path of one of said transistors in series with the collector-base path of the other of said transistors, means for connecting the collector-base path of said one transistor in series with the emitter-collector path of said other transistor, means for controlling the electrical admittance of said emitter-collector paths comprising a first electrical signal source connected between the emitter and base electrodes of said transistors, a second electrical source, means for deriving an output signal connected in series circuit arrangement with said second source, and means for coupling said collector electrodes comprising said series circuit arrangement.

9. A circuit arrangement comprising a pair of transistors each having an emitter electrode, a collector electrode, a base electrode, an emitter-collector path and a collector-base path, means for connecting the emitter-collector path of one of said transistors in series with the collector-base path of the other of said transistors including means for connecting the emitter electrode of said one transistor to the base electrode of said other transistor, means for connecting the collector-base path of said one transistor in series with the emitter-collector path of said other transistor including means for connecting the base electrode of said one transistor to the emitter electrode of said other transistor, a first electrical signal source connected between said base electrodes, a second electrical source, means for deriving an output signal connected in series circuit arrangement with said second source, and means for coupling said collector electrodes comprising said series circuit arrangement.

10. A circuit arrangement comprising a first transistor and a second transistor, each having an emitter electrode, a collector electrode and a base electrode, a first junction point, means for connecting the emitter electrode of said first transistor to said first junction point, means for connecting the base electrode of said second transistor to said first junction point, a: second junction point, means for connecting the emitter electrode of said second transistor to said second junction point, means for connecting the base electrode of said first transistor to said second junction point, a first electrical signal source connected between said first and second junction points, a second electrical source, means for deriving an output signal connected in series circuit arrangement with said second source, and means for coupling the collector electrode of said first transistor to the collector electrode of said sec- 0nd transistor comprising said series circuit arrangement.

11. A circuit arrangement comprising a pair of transistors each having an emitter electrode forming an input electrode system with a base electrode, a collector electrode, an emitter-collector path and a collector-base path, means connecting the emitter-collector path of each of said transistors in series with the collector-base path of the other of said transistors, a first electrical signal source connected in the input electrode systems of said transistors, a second electrical source, means for deriving an output signal from said circuit arrangement, and means connecting said first-mentioned means in series circuit arrangement with said second source between the collector electrodes of said transistors.

12. A circuit arrangement comprising a pair of transistors each having emitter, collector and base electrodes, on emitter-collector path, an emitter-base path and a collector-base path, means connecting the emitter-collector path of each of said transistors in series with the collector base path of the other of said transistors, a first electrical signal source, means connecting said first signal source in series with the emitter-base path of each of said transistors, a second electrical source, means for deriving an output signal from said circuit arrangement and means connecting said last-mentioned means in series circuit arrangement with said second source between the collector electrodes of said transistors.

References Cited in the file of this patent UNITED STATES PATENTS 2,622,212 Anderson et al Dec. 16, 1952 2,665,845 Trent Jan. 12, 1954 2,695,381 Darling Nov 23, 1954 2,728,857 Sziklai Dec. 27, 1955 2,778,978 Drew Jan. 22, 1957 2,783,384 Bright et a1 Feb. 26, 1957 OTHER REFERENCES Article, Symmetrical Properties of Transistors and Their Applications, Proceedings of the I.R.E., June 1953, by Sziklai.

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