DE1232207B - Circuit arrangement for amplifying two stereophonic electrical signals - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN WWW PATENT OFFICE

EDITORIAL

Int. CL:

H03f

German KL: 21 a2- 18/01

Number:
File number:
Registration date:
Display day:

R 33339 VIII a / 21 a2
August 16, 1962
January 12, 1967

The invention relates to a circuit arrangement for amplifying two stereophonic electrical ones Signals with a single electron tube that has two anodes, one cathode and two between contains control electrodes arranged in the cathode and the anodes, and with a two-channel output circuit, via which the collector anodes are connected to an operating voltage source with a relation to the cathode has positive voltage. The term »anode« is intended here in the broader sense to mean an electron xo mean receiving electrode, so that ζ. Β. with the appropriate circuit also the screen grid of a Pentode falls under this term.

A circuit arrangement for the independent amplification of two currents is already known which contains a double triode with a common, directly heated cathode. The grids of the tube will do that one signal in push-pull and the other in common mode and fed to the anodes is an output circuit connected, which allows a separate pickup of the amplified push-pull and common-mode signal. In principle, it is a circuit arrangement with a double tube, since it is in the double triode Despite the common cathode, two separate electron streams are generated that are independent are controllable from one another by separate control electrodes (German patent 315 627).

Double tubes are also often used in modern stereo amplifiers. There are z. B. Circuits known, in which a tension grid double pentode with a common cathode for amplification two stereophonic signals is used (IRE Transactions on Audio, July / August 1959, p. 105, Fig. 9).

The invention is based on the object of a circuit arrangement for amplifying two to indicate stereophonic electrical signals with a single electron tube, which is characterized by special Simplicity distinguishes itself and is therefore very cheap.

A circuit arrangement for amplifying two stereophonic electrical signals with one single electron tube, the two anodes, one cathode and two between the cathode and the Contains control electrodes arranged anodes, and with a two-channel output circuit via which the anodes to an operating voltage source with a voltage that is positive with respect to the cathode are, is characterized according to the invention in that one of the two stereophonic Signals from a control electrode for controlling the entire flow circuit arrangement from the cathode to the anode for amplifying two stereophonic electrical signals

Applicant:

Radio Corporation of America,

New York, N.Y. (V. St. A.)

Representative:

Dr.-Ing. E. Sommerfeld, patent attorney,
Munich 23, Dunantstr. 6th

Named as inventor:
Henry Michael Bach jun.,
Princeton, NJ (V. St. A.)

Claimed priority:

V. St. v. America August 25, 1961 (133 918)

the current is supplied, whereby in the one, responsive to common mode control of the anode currents Channel of the output circuit that amplifies one stereo signal and the other of the two stereophonic signals is fed to the other control electrode and practically only the Controls the distribution of the current flowing from the cathode to the anodes to the two anodes, such that in the other channel of the output circuit which responds to push-pull control of the collector currents the other stereo signal is amplified.

Circuit arrangements according to the invention are excellent for both small and cheap Stereo radio receivers as well as cheap two-channel amplifiers for stereophonic turntables and Phono devices. The invention can also be used to amplify sum and difference signals as they are transmitted in certain stereo broadcast systems.

According to a development of the invention is between the two-channel output circuit and the Anode of the electron tube is connected to an amplifier tube, the control grid of which is connected to the associated one Collector electrode is coupled, and the anodes are each connected via a working impedance the operating voltage source is connected. Preferential

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3 4

the working impedances are to represent the monophonic sound source, at the input position of the amplitude ratio of the two terminals 7, 8 of the two channels are supplied, stereophonic signals via a changeable The input terminals 7, 8 are via coupling resistor with the operating voltage source, capacitors 13, 14 with input resistors 11, bound. 5 12 connected, which are connected to ground 15 on one side.

According to a further development of the invention, in the example shown, the input

tion, the only electron tube is a pentode, input resistors 11, 12 as volume controls for the

their screen grids as second anodes and their associated signal channels, they are provided with

first and third grid provided as control electrodes switchable pick-up contacts 16, 17 which

are tet. io by a mechanical connection 18 at the same time

A circuit arrangement according to the invention can be adjusted. The input signals of the two channels for formed from two stereophonic signals are fed to a single electron discharge device sum and difference signals (A + B) and (A-B) device or tube 20 with a number of grids shown example of a pentode, which is characterized in that the two-channel output 15 is a cathode 21, an anode 22 and three intermediate output circuit for the one signal additively with these electrodes located in such a way grid, namely one of the anode is coupled that at one From the first control grid 23, a screen grid 24 and an output that produces a stereo signal (A) and that the second control grid 25 contains.
Two-channel output circuit for the other signal. The two control grids 25, 23 are connected to the slide subtracts in such a way with the other anode 20 fen 16 and 17, respectively, of the volume control. The fact is that at the other output the other stereo input circuit of the channels is created by an intermediate signal (B) . the cathode 21 and ground 15 connected cathode

In the case of stereophonic FM multiplex broadcasting resistor 29 closed. The cathode resistance

The FM detector can receive and multiplex is for audio frequencies through a capacitor 30

Detector output circuits, for example, the demodul 25 bridged. The cathode resistance generates on

lated (/ 4 + ß) FM signal component and the demo- this way automatically biases the

Dulated (A- S) signal component of the negative pressure two grids 23, 25. If the grids are different

th subcarrier to the single-tube amplifier, if you need bias voltages, one thing can be

and the matrix processing of the A and grids in a known manner to a tap of the

B signals can be connected in the usual way or through the 30 cathode resistor,

The above-mentioned matrix output circuits are effected in the present circuit arrangement

the. In a stereophonic AM receiver, the anode 22 and the screen grid 24 with respect to the

the single-tube amplifier can be used as a matrix detector cathode with a positive DC voltage.

for the stereophonically modulated carrier spans, so that from the cathode to these electrodes

serve without an additional matrix 35 an electron current flows. The total flow of

arrangement is required, this represents a further cathode is supplied by the signal voltage on the first

Advantage of the signal transmission arrangement is controlled according to the control grid 23, and the distribution of the

Invention. Cathode current to the anode 22 and the screen

The invention will now be based on the drawings grid 24 is counteracted by the signal voltage

are explained in more detail. It shows 40 controlled on the second control grid 25 without

Fig. 1 is a circuit diagram of a single-tube two-channel through which the total current of the cathode is influenced.

Audio frequency amplifier according to the invention, the anode 22 and the screen grid 24 are with

2 is a circuit diagram of a single-tube, two-channel end terminal 32 or 33 of a primary winding 34

Amplifier stage similar to FIG. 1, but one of an output coupling transformer 35 for the

additional internal two-channel amplification and Korn- 45 / i-channel coupled. The primary winding 34 sets

compensation allows output coupling impedance between the element

F i g. 3 is a circuit diagram of a single-tube, two-channel anode and screen grid and is associated with a

Amplifier stage similar to that in FIG. 1 provided tap 36, which in the present case

Sehaltungsanordmmg, which can, however, be a beam deflection game a center tap. The tap 36 is

tube contains, 5 ° via a primary winding 39 of a second output

F i g. 4 is a circuit diagram of a single-tube two-channel transformer 40 for the IJ channel with the positive one

Amplifier stage similar to that in FIG. 1 connected pole + B of an operating voltage source.

Circuit arrangement, which, however, is the negative pole of this operating voltage source

is changing is that they are going to be used in bulk.

FM multiplex stereo receivers are suitable, 55 The output winding 45 of the transformer 35

F i g. 5 is a circuit diagram of a modified part and the output winding 46 of the transformer 40

the in F i g. 4 amplifier stage, are connected to the inputs of low-frequency line

F i g. 6 a circuit diagram of a complete AM-FM power amplifier 47 or 47 'connected, which feed sound amplitude modulation - angle modulation - stereo speakers or other playback devices 48, receivers with a single-tube two-channel amplifier 60 49 of the respective channels,
ker arrangement, which according to the invention as a stereo The in F i g. The amplifier shown in FIG. 1 works in such a way as a detector and matrix arrangement: One of the two signals, namely the receiver, can be used. the B signal is transmitted from the source 10 via the input

In the drawings, similar parts carry the first control grid 23 and the gear circle

same reference numerals. 65 cathode 21 and causes a de-

Fig. 1 shows an amplifier circuit for two speaking changes in the cathode current. Of the

stereophonic signaled, B, which can be made by two micro-circuits through the primary winding 39 and

Phonen 9, 10, any suitable stereo the two-part primary winding 34 to the anode 22 and

to the screen grid 24 are followed. The B signal is supplied to the source, for example a stereo sound is produced that is to say on the primary winding 39 of the collector.

The control grids 25, 23 are in this example output winding 46 to the input of the amplifier 47 directly with the associated resistors 11, 12 and the loudspeaker 49. The ß-signal generates 5 bound. The volume control takes place in this, however, no current change in the secondary winding circuit arrangement elsewhere, and the development 45, since the current flow in the two parts of the control grids are the full input voltage primary winding 34 oppositely equal voltages from the input terminals 7, 8 supplied, gene induced in the secondary winding 45, so that the input circuits and the amplifier tube 20 do not work, no output signal can reach the loudspeaker 48 otherwise in the same way as in FIG. An additional amplification of the signals supplied by the signal source 9 to the input terminal 20 in FIG. 1 takes place there by the men 7 supplied A signal is via the input circuit connected to the output windings 45, 46 between the second control grid 25 and the amplifiers 47, 47 '. In the case of the cathode 21 shown in FIG other part of the primary formers 35, 40. The output transformers 35, winding 34 is accompanied, while the cathode 40 are the same as in the one in FIG. 1 as a whole practically does not change. This circuit arrangement, which is connected to the amplifier clock effect, has a corresponding yi output tube 20 coupled via an amplifier stage, which results in a signal at the primary winding 34, which then has two differentially and additionally connected via the secondary winding 45 to the input of the circuit. Amplifier tubes 56, 57 contains. These tubes are supplied to the amplifier 47, which feeds the loudspeaker 48. The A signal does not occur at the output winding 46 via a suitable combination of cathodes 59, 60, since there is no current change in this winding which produces a bias voltage which is connected to ground 15. It is assumed here that the tube The control grid 61, 62 of the amplifier tubes 56, geometry is such that the anode 57 are connected to the anode 22 and the screen grid 24, the current is equal to the screen grid current when tube 20 is over Suitable coupling capacitors are connected to the tap 36 of the primary winding 34 in the middle 30 63, 64. The anode 22 and the screen are located, grid 24 via resistors 65 and 66, respectively. A single multi-grid tube can thus be connected to a line 68 which forms an adjustable and short-circuited serial transmission system for a two-channel signal fer 70 through a slime-single amplifier stage contains a separate excess resistor 69 and causes the signals from the two channels to be transmitted to the positive pole. 35 anode voltage source leads. The grids 61, 62 are. This can be called a matrixless circuit, via bleeder resistors 71 and 72, respectively, to ground 15 in which the A and B signals or the left and right are connected.

Signal to the two input grids 25, 23 in the same way. The anodes 75, 76 of the amplifier tubes 56, 57 are fed and the transconductance are connected to the terminals 32 and 33 of the primary winding between first the first beam grid 23 and the 40 34 of the output transformer. As with screen grid 24, secondly between the first controller in FIG. 1 is the grid 23 and the anode 22 and third between the tap 36 of the primary winding via the primary the second control grid 25 and the anode equal to the winding 39 of the output transformer 40 and the circuit impedances R ₁ , R _sg and R _{k are} also the second Channel with the positive pole + B of the seizure are the same. In this example the anode 45 or voltage source is connected,
impedance R ₁ , through the primary winding 34, the secondary winding 45 of the output transformer screen grid impedance R _sg through the primary winding mators 35 is directly connected to the speaker 48 of the 34 of the transformer and the cathode impedance R _k channel A , and the secondary winding 46 through the impedance the primary winding 39 is formed. of the output transformer 40 of the channel B It can also be assumed that the 50 is also directly on the loudspeaker 49, since in the transconductance of the tube 20 between the control amplifier arrangement in front of the output transformer grid 25 and the screen grid 24, conversely, equals 35, 40 there is already sufficient gain erder that between the control grid 25 and that follows.

Anode 22 is. Under these conditions, the results shown in FIG. 2 shown circuit arrangement

two-channel, stereophonic input signals, the 55 works practically in the same way as the switching

are fed to the control grids 25, 23, output direction of FIG. 1, with the exception that the amplification

signals at the output winding 45 for the ^ 4-Kanal kung of the supplied signals in the two channels

and in the same way amplified output signals to between the amplifier tube 20 and the output

of winding 46 for the B-channel. With other word transformers 35, 40 takes place. It can be seen that

t is said with the one shown in FIG. 1 shown circuit 60 the anode 22 and the screen grid 24 via the

processing arrangement an effective stereo signal amplifier stage with the tubes 56, 57 effectively with the

kung for two channels with a single Signalver- terminals 32, 33 is coupled. The control grid

Strengthening device 20 possible. 25 supplied signals of channel A change the

In the case of the in FIG. 2 shown modified current distribution between these electrodes and

Circuitry, the A and B signal 65 will produce a push-pull signal to the control grids 61,

the input terminals 7, 8 through input circuits 51, 62 of the tubes 56, 57 and thus to the anode circuits

left and right channels, respectively, of any one of the terminals 32, 33 of the primary winding 34.

suitable two-channel, stereophonic sound through the coupling with the secondary winding 45

So if an amplified signal arrives for the left, this tube contains between the cathode channel A to the loudspeaker 48. and the anode electrodes a first control or

All of the cathode current is passed through the first input grid 86, a screen grid 87, and two output grids 23 of the amplifier tube 20 corresponding to the steering electrodes 88, 89, the from the cathode 28 Controls B signals of the right channel and changes 5 outgoing electron beam under control of the anode and screen grid current practically in signal voltages between the anode electrodes in the same way and in the same sense, so that 82, 83 distract each other.

also the signal voltages at the grids 61, 62 in the In this example, input 8 is the A channel

same sense change. This results in a with the control grid 86 and the input of the practically in-phase change in anode currents, io B-channel connected to deflection electrode 88; the and the total anode current in deflection electrode 89 thus controlled is grounded. The screen grid The positive pole of the primary winding 39 of the output transformer 40 87 is connected to the voltage source generates the B signal for loudspeaker 49. Da connected.

the anode current in the primary winding 34 is compensated in the scarf containing the beam deflection tube, If there is no circuit arrangement on the secondary winding 45, the control grid 86 controls the B signal output on. Cathode current as a whole, without a deflection of the

The resistor 69 in the common lead to effect cathode current between the anode electrodes 82, for the screen grid and the anode of the amplifier 83. The fluctuations of the cathode tube 20 represents an impedance element for the B-signal current as a whole therefore appears at the output currents, but not for the A -signal.
Adjustment of the resistor 69 can control the amplitude The deflection electrodes 88, 89 under

The B-signal fed to the amplifier tubes 56, 57 and the loudness of the B-signals fed to the terminals 7, speaker 49 of the B-channel, can be adjusted to deflect the output from the cathode, so it serves as a stereo or channel signal. Electron beam, ie a distribution of the cathobalance regulator with respect to the A signal. The signal 25 denstromes between the anode electrodes 82, 83, amplitude in the B-channel can be adjusted by this simple so that the currents in the primary winding 34 of the circuit arrangement of the amplitude of the ^ [- signal output transformer 35 change in push-pull, while at the same time a from and generate a signal in the secondary winding 45, sufficient amplification is ensured by which the terminals 43 can be removed. The control sound transducer of the channels, such as the loudspeakers 48, 30 grid 86 and the deflection electrodes 88, 89 act 49, feed directly through the output transformers of the so in the same way as the control grid 23 or system, without that as in the in Fig. 1 25 of the circuit arrangement shown in Fig. 1, the circuit arrangement shown additional connections. 3, however, the signal inputs of the A- and more must be interposed. B signal with regard to the transmission channels of the

The single-tube two-channel amplifier shown in FIG. 3 interchanged to show that the two The amplifier circuit is similar to the circuit of the signals in any way interchangeable by the F i g. 1, a signal transmission channel runs from which channels are transmittable.

Input terminals 7 to output terminals 43 As in the previous embodiments

and a second signal transmission channel between the invention, the cathode current is a function of the input terminals 8 and the output terminals 40 of the between the control grid 86 and the cathode 28 44. As with the circuit shown in Fig. 2 signal voltage and is independent of the arrangement, there are no volume controls , and the input signal voltage between the deflection electrode 88 signals are from the terminals 7, 8 directly to the and cathode or ground. The division of the Katho input resistors 11, 12 is placed. With this two current on the anode electrodes 82, 83, on the other hand, the B signal is fed to the terminals 7 45, on the other hand, a function of the signal voltage is picked up between and at the gills 43, while that of the deflection electrode 88 and the cathode and becomes the A signal Terminals 8 is supplied and to which cannot be removed by the signal voltage between the control terminals 44. electrode 86 and the cathode affected.

The main difference between these in the two-channel amplifiers of FIGS

Circuit arrangement and the in F i g. 50 and 3 shown in FIG. 1, the stereophonic signals consist in that an electron tube 80 operating with beam deflection is supplied to the transmission channels and the electron tube 80 is used. This removed again without a matrix-like tube containing a cathode 81, which is connected to earth via a cathode processing or another transformation earth combination 29, 30, and follows. When composite signals are supplied, a split anode with two anode electrodes 82, 55 den, such as stereophonic (A + B) - and (A - B) -83, connected to terminals 32 and 33 of the primary winding signals, respectively, can be applied to the push-pull and Single ended circuits 34 of the output transformer 35 connected to the transmission stage of the invention are a common one. The center tap 36 is connected via the primary winding matrix circuit, for example a circuit 39 of the output transformer 40 of the other system with two transformers whose channel with the positive pole + B of the anode chip 60 secondary connections form a suitable matrix, voltage source. The secondary winding 46, as it is shown, for example, in the transformer 40 shown in FIG. 4, is shown with the output terminals circuit arrangement that is otherwise in the 44 of the A channel and the secondary winding 45 of the essential FIG. 1 corresponds. Alternatively, the coupling transformer 35 can also be connected to the output terminal impedances in the anode cathome 43 for the B signal. 65 den and screen grid cathode circuits used

As a beam deflection tube 80, the one in the ver, as FIG. 5 shows, since the one between the anode united states of america under the designation and cathode flowing current of the sum and the 7360 commercially available tube type uses current flowing between the screen grid and cathode

corresponds to the difference between the signals applied to the two control grids. The formation of the sum and difference from the sum and the difference of the two signals results in the two original signals, yes: (A + B) + (A - B) = 2 A and (A + B) - (A - B ) = 2B. This will be discussed in more detail below.

For the time being, go back to FIG. 4 should be referenced. In an FM multiplex high-frequency receiver for stereo purposes, output circuits 95, 96 of an FM demodulator and multiplex detector are connected to the input terminals 7 and 8 of the illustrated single-tube two-channel amplifier, so that the (A + β) modulation component of the FM signal to the control grid 25 and the (A - B) modulation component of the subcarrier signal to the control grid 23 of the single-tube amplifier. The output signals of the FM demodulator and the multiplex detector are both in the audio frequency range, pilot oscillation and subcarrier sidebands are outside the audio frequency range. As shown in this example, the intensifier tube may include a fourth grid 97 between the first control grid 23 and the screen grid 24. The grid 97 is connected to the positive pole of a voltage source via a line 42 and has the effect of reducing the crosstalk between the two channels, since the cathode current becomes more independent of the instantaneous values of the potential at the screen grid 24.

In this circuit arrangement, the anode 22 and the screen grid 24 are as in FIG. 1 connected in push-pull to the symmetrical primary winding 34 of the output transformer 35, and they are connected in parallel to the primary winding 39 of the output transformer 40, which in turn is connected by a feed line 42 to the anode voltage source. Up to this point, this circuit arrangement works in the same way as the circuit arrangement in FIG. 1. Since the supplied signals are composite (A + B) - and (AB) - signals, signals of this form are transmitted via the transformers 35, 40 and arrive at modified secondary windings 98, 99 which are connected directly to sound reproduction devices 48, 49 can and form a matrix circle. The modified secondary windings take the place of windings 45, 46 in FIG. 1. The secondary winding 98 has two end terminals 100, 101 and a tap 102 located in the middle here. The secondary winding 99 has two terminals 103, 104 and should have approximately the same impedance as one half of the winding 98. The loudspeakers 48, 49 are connected in series between the terminals 100,101 of the secondary winding 98. The secondary winding 99 lies between the terminal 102 and a connection point 108 of the loudspeakers 48, 49 connected in series.

The (A +2?) ~ Signal transmitted through the single-tube two-channel amplifier appears between terminals 100, 102 of secondary winding 98 and the - (/ if-2?) Signal between terminals 101, 102 of secondary winding 98. These signals are combined with the (A- S) signal in the matrix, which lies between the terminals 103, 104 of the secondary winding 99, which is connected between the two loudspeakers 48, 49 and the tap 102 of the secondary winding 98. This matrix circuit of the secondary windings therefore supplies the ./! signal to the loudspeaker 48 and the 5 signal to the loudspeaker 49. Otherwise, the one in FIG. 4 as well as the circuit arrangement of FIG. 1.

The two-channel single stage amplifier of the present invention can be configured to perform both transmission and matrix combination of composite stereophonic signals such as the (A + B) and (A- ß) signals similar to the one shown in FIG. 4 are supplied to the circuit arrangement shown. This feature of the invention is intended with reference to FIG. 5 are described, which is a modification of the output circuit of FIG. 4 represents.

In this modified circuit arrangement there is an A channel output transformer 35 a with a primary winding 34 a and a secondary winding

45 a in the circuit containing the anode 22 and the cathode 21, so that the current flowing from the cathode to the anode also runs through the primary winding 34 α. In the same way, there is an output transformer 40 a for channel B in the circuit containing the screen grid-cathode path, so that the screen grid current flows through the primary winding 39 α. It has already been mentioned that the anode current is a function of the sum of the signal voltages applied to the control grids 23, 25, ie (A-B) + (A + B) -2A, and that the screen grid current is a function of the difference between the grids 23, 25 lying signal voltages, thus: (A-B) - (A + B) -2B. Accordingly, the A stereo signal arises on the secondary winding 45 a and on the secondary winding

46 a the .B stereo signal. Incidentally, the in Fig. 5 shown circuit arrangement like the circuit arrangement of FIG. 4th

F i g. Figure 6 shows a complete stereo broadcast receiver with a stereo embdulator and decoder circuit. The receiving part can be designed in any way, in the example shown it contains a mixer 115 connected to an antenna 116, which can be used in the usual manner IF amplifier 117 follows. The output circuit of the IF amplifier contains one through a capacitor 120 matched winding 118 of an IF coupling transformer 119.

The IF coupling transformer is provided with two matched channel output circuits 121, 122 for the two stereophonically linked modulation components of the received carrier wave; in the example shown, the circuit 121 is for an angle-modulated (A- ß) signal component and the circuit 122 for an amplitude-modulated (A + 5) signal component is determined. It can therefore be a radio receiver for the AM radio frequency band, the carrier oscillation being amplitude-modulated by the (/ 4 + Z?) Signal component so that it can be received with conventional monaural receivers; at the same time, the frequency of the carrier wave is modulated by the (A- B) stereo signal component. The demodulated signals are combined in a matrix-like manner in an output circuit network 125 and pass from this to channel output terminals 126, 127 for the A or B signal.

609 757/271

The remainder of the receiver's two-channel transmission arrangement may be power amplifiers 128, 129 for the separate channels, connected to the speakers 130, 131 for the two channels are. The amplifier 128 is between ground 132 and a wiper 133 of a volume control 134 connected, which is between the output terminals 126 of the ^ 4 channel of the demodulator circuit. In appropriate Way, the amplifier 129 is between ground and a wiper 136 of a volume control potentiometer 137 connected, which is connected to the output terminals 137 of the .B channel of the detector circuit is. The two sliders 133, 136 can be mechanically coupled, as indicated by the dashed line Line 139 is indicated so that the amplification of the two channels in the usual way at the same time can be adjusted.

The tuned circuit 122 of the transformer 119 includes a secondary winding 150 which is a tuning capacitor 151 is connected in parallel. The circle 122 lies between a first control grid 142 and a terminal 152, which is connected to a cathode 140 via a resistor 153. Of the Resistor 153 is from terminal 152 to ground for high frequency through a capacitor 155 bridged.

Matched circuit 121 of transformer 119 includes a second matched secondary winding 156, to which a tuning capacitor 157 is connected in parallel and which is between a second control grid 144 and ground 132 and connected through the cathode capacitor 148 to the cathode is. The secondary windings 156, 150 are as shown inductive with one another and the primary winding 118 coupled.

During operation of the decoder shown, the IF signal induced in the secondary winding 150 is coupled between the grid 142 and (via the bypass capacitors 155, 148) the cathode 140. The amplitude of this signal is a function of (A + B) and the phase angle is a function of (A-B). The amplitude fluctuations according to {A - \ - B) control the cathode current of the tube 124. The angular changes of the signal do not affect the cathode current. Since the circuit 121 is tuned to the center frequency of the IF oscillation, ie the frequency of the signal in the absence of (A- ! ^ - modulation, the IF signal between the grid 144 and the cathode 140 is between the grid with respect to the IF signal 142 and cathode 140 are 90 degrees out of phase when the frequency of the IF signal is equal to the center frequency, and when the IF signal is angle modulated, ie, (A-B) f0, a phase shift occurs between the grids 144 and the potential supplied to the grid 142, the magnitude of which is determined by the magnitude and the sign of which is determined by the direction of the instantaneous deviation of the IF oscillation from the resonance frequency of the tuned circuit 121. The instantaneous anode current of the tube 124 thus changes in direction and magnitude as Function of the direction and size of the instantaneous frequency deviation of the oscillation developed at the parallel resonance circuit 121 from the resonance frequency of the parallel resonance circuit 122 the current between the cathode and screen grid 143 starts in the opposite sense as the anode current. The anode and screen grid currents change in phase depending on the (^ 4 + jB) modulation and out of phase depending on the (A - 5) modulation.

Between frequency components of the anode and screen grid currents are diverted by capacitors 176, 177 and the capacitor 148 to the cathode, so that no significant IF voltage occurs at external resistors 168, 169, 170 and 147 has a low impedance compared to resistor 147. The modulation components of the anode current flow through resistors 168, 170 and capacitor 148 to the cathode, and the modulation components in the screen grid current flow through resistors 169, 170 and capacitor 148 to the cathode. The (A- 5) component does not appear across resistor 170. The voltage component (A + B) occurring at resistor 170 is added to the components falling at resistors 168, 169. With a suitable choice of the ohmic values of the resistors 168, 169, 170, the ^ signal is produced at the output terminals 126 and the 5 signal is produced at the output terminals 127.

A voltage for automatic gain control (AVR) can be taken from the demodulator circuit and fed to the mixer and the intermediate frequency amplifiers to adjust the gain to regulate depending on the mean value of the received carrier wave. For this is in the present example, the terminal 152 with the control loops of the IF amplifier 117 through a AVR line 160 and a filter arrangement with a series resistor 161 and a bypass capacitor 162 connected. The AGC voltage is also fed to the mixer 115 via a line 163 and fed to a filter arrangement comprising a series resistor 164 and a bypass capacitor 165 contains.

The anode 141 of the tube 124 is connected via a coupling capacitor 143 to the terminal of the output terminals 126 of the A channel carrying signal voltages. The other of the output terminals 126 is connected to ground 132.

The screen grid 143 is connected to the signal voltages via a coupling capacitor 146 Terminal of output terminals 127 of the S channel connected. The other terminal of pair 127 depends on mass.

With this advantageous and simple output circuit, the y4 signals are taken directly from the anode connection and the S signals directly from the screen grid connection in full matrix form in the output circuit processed from the modulated IF signals received, which are fed to the stage from the input circuits 122 and 121, respectively. This output circuit includes a first impedance arrangement connected between the anode and the screen grid, and two series-connected resistors 168, 169, and a second impedance arrangement having a resistor 170, which is between the connection point of resistors 168, 169 and (via the bypass capacitor 148, 172) cathode is connected. The connection point of the resistor 170 with the bypass capacitor 172 is with a positive voltage source connected. The current from this voltage source flows through the resistor 170 and then through resistors 168, 169

to the anode 141 or to the screen grid 143. The capacitors 145, 146 prevent the DC current to the output terminals. The audio frequency bypass capacitors 172, 148 cause that the end of the resistor 170 connected to the capacitor 172 for the transmitted Signals in terms of alternating voltage is practically at cathode potential. The capacity values of the HF discharge capacitors 176, 177 between anode 141 or screen grid 143 and ground can thus be ίο be measured that there is a desired disaccentuation.

The demodulator and decoder circuit of the receiver shown generates stereophonic output signals for the left and right channels A and B from a received RF signal that is simultaneously modulated by two stereophonically linked items of information and is suitable for all radio receivers of this type. In the present example, a single multigrid tube 124 is connected to provide an anti-phase demodulated (A -2?) Output for angle modulation or frequency or phase modulation and a single-phase demodulated output (A + B) which are in the same output circuit 125 can easily be combined so that the desired audio signals for the two different channels result. It is easy to see that this circuit arrangement is simple, provides high output levels, and can easily be trimmed during manufacture.

The circuit 122 can be tuned to an intermediate frequency of 450 kHz, and the i? C grating coupling circuit 153, 155, at which the amplitude-modulated (<4 + .B) signal drops, has for modulation frequencies a short time constant. The (/ i + ß) signal is thus between the first control grid 142 and the cathode effective, and its DC component occurs in the AGC circuit 160, which is known to have a correspondingly longer time constant. The resistor 161 can do this has a value of 1 MOhm and the capacitor 162 has a capacitance of 10nF. The condenser 155 can have a capacitance of 1 nF and the resistor 153 a value of 0.25 MOhm, Of course, none of these values are to be interpreted as restrictive.

The demodulation signal (A + B) at the grid 142 controls the cathode current as a whole and appears at the common output resistor 170. It is thereby effectively fed to the common connection point of the resistors 168, 169.

The angle or frequency modulation component (AB) arises as a result of the phase difference between the signals at the two control grids 142, 144 as a result of the inductive coupling of the secondary windings 150, 156 and the tuning of these circuits to the same frequency of 455 kHz. Because of this phase difference, the control grid 144 modulates the distribution of the cathode current to the anode 141 and the screen grid 143 and thus the distribution of the currents flowing through the resistors 168, 169 without the total current flowing through the resistor being significantly changed. The demodulated (A- 5) signal component therefore appears on the impedance element as indicated, and the demodulated - (A -B) component appears on resistor 169. It can be seen that the A and B signals are due to the connections of the output terminals between the screen grid 143 and anode 141 and ground are formed by combination and appear at terminals 126 and 127, respectively. To adjust the matrix, the resistor 170 can be changed by means of an adjustable short-circuit contact 180. In this way, the (/ 1 + B) signal component can be precisely matched to the (AB) and - (^ 4-ß) signal components.

The demodulated amplitude modulation signal (A + B) therefore appears as a fluctuation in the total cathode current flowing through the impedance element 170 and is adjusted to a value which, in a matrix-like combination with the (AB) - and - (A- 5) signal components desired, separate A and .B signals at the output terminals 126, 127 and finally at the sound reproduction devices 130 and 131, respectively.

It has been mentioned that the (^ + ^ component appears across resistor 170; however, some of the whole (^ 4 + 5) component also drops across resistor 168 and another part drops across resistor 169. For example, if the anode current and screen grid current changes for the (A + B) component are equal and the (A- 5) component is 0, the cathode current consisting of the sum of the anode and screen grid current flows through resistor 170, while through resistor 168 and the Resistor 169 each half of the cathode current flows.

In this or other circuit arrangements according to the invention which automatically process composite signals in a matrix-like manner, the three impedance elements 168, 169, 170, which can be referred to as R _t , R _sg and R _k , respectively, preferably have the same values, so that in the case of a pentode 124 with the same transconductance G _m from the first grid 142 to the screen grid 143 and anode 141 and opposite equal transconductance from the third grid to the screen grid 143 and the anode 141, the transconductance from the third grid 144 to the anode 141 approximately three times the transconductance from the first grid 142 to Anode should be 141. Then, when the sum (A + B) of the left and right signals is fed to one and the difference (A-B) is fed to the other of control grids 142, 144, separate left and right signals A and B, respectively, arise between the cathode (or ground ) and the anode and between the cathode (or ground) and the screen grid as described above.

Claims (5)

Patent claims: 1. Circuit arrangement for amplifying two stereophonic electrical signals with a single electron tube, the two anodes, one cathode and two between the cathode and contains control electrodes arranged at the anodes, and with a two-channel output circuit, via which the anodes are connected to an operating voltage source with one with respect to the cathode positive voltage lie, characterized in that one of the two stereophonic signals of a control electrode to control the total current flowing from the cathode to the anodes becomes, whereby in the one, on equal clock control of the anode currents responsive channel of the output circuit the one stereo signal amplified occurs, and that the other of the two stereophonic signals of the other Control electrode is fed and practically only the distribution of the from the cathode to the anodes current flowing to the two anodes controls, so that in the other, on push-pull control the channel of the output circuit that responds to the anode currents, the other stereo signal occurs more often. 2. Circuit arrangement according to claim 1, characterized in that between the two-channel output circuit (35, 40) and the anodes (22 and 24) of the electron tube (20) each have an amplifier tube (56 and 57) connected, whose control grid (61 or 62) is each coupled to the associated anode, and that the Anodes (22, 24) each via a working impedance (65 or 66) to the operating voltage source are connected (Fig. 2). 3. Circuit arrangement according to claim 2, characterized in that the working impedances (65, 66) to adjust the mutual amplitude ratio of the two stereophonic Signals via a changeable stand (69) are connected to the operating voltage source (FIG. 2). 4. Circuit arrangement according to claim 1, characterized in that the single electron tube (20) is a pentode, the screen grid (24) of which is the second anode and the first and the third grid are connected as control electrodes (23 or 25) (FIGS. 1 and 2). 5. Circuit arrangement according to claim 1 for sum and difference signals formed from two stereophonic signals (A + B) and (A-B), characterized in that the two-channel output circuit (35 a, 40 a) for one of the signals additively in such a way is coupled to one anode (22) so that one stereo signal (A) is produced at one output and that the two-channel output circuit for the other signal is subtractively coupled to the other anode (24) in such a way that the other stereo signal at the other output (B) arises (Fig. 5). Considered publications:
German Patent No. 315,627;
"IRE Transactions on Audio", July / August 1959, pp. 101 to 106. 1 sheet of drawings 609 757/271 1.67 © Bundesdruckerei Berlin