DE19715005C1 - Oscillator circuit for GHz range - Google Patents

Abstract

The oscillator circuit has a pair of tuned amplifiers (1,2) coupled in a ring via resonance filters (5,12) and coupled together via a resonance capacitor network (18). The centre frequency of the oscillator circuit is determined via the voltages coupled to its input voltage terminals (9,21). The tuned amplifiers may be coupled to respective output amplifiers (22,23), which are coupled together via an output capacitance network (32). The outputs (35,36,37,38) of the output amplifiers provide partial signals with a phase offset of 180 degrees. Each tuned filter includes a passive resonant circuit with a capacitance.

Description

The invention relates to a resonant circuit with two together coupled resonance amplifiers, where at the inputs of the Reso power amplifier inductors are connected.

Such a resonant circuit is known from DE 43 31 499 A1. The generic resonant circuit has two resonances amplifier, at their inputs to a supply voltage connected inductors are switched. That work effectively de Capacity of the resonance amplifier is above tuning voltages adjustable so that the center frequency of the resonant circuit diff is profitably controllable. The amplifier stages are via a con capacitive and via a neutral compensation network coupled with each other. Every resonance amplifier delivers one a partial signal that can be picked up by a load resistor. Through both side connection of the inductors to the resonance amplifier is a symmetrical, low-scatter structure of the genus Achieved appropriate resonant circuit, so that vibration frequencies in the range of several 10 gigahertz with fully balanced Partial signals can be generated.

However, the generic resonant circuit proves to be despite a non-balanced resonant circuit high quality vibration signal high frequency the load resistances as disadvantageous, as this differs from the load resistors generated white noise directly to the expediently partial signals to be amplified and the resistances the capacities connected to them form a low pass, so that the resulting vibration signal at high frequencies only slightly or not at all intensified at the exits of the Resonance amplifier is present. Furthermore, the efficiency of the generic resonant circuit due to the load resistances relatively low.  

EP 0 420 974 B1 is a tunable resonance ver stronger with a non-regenerative, negative for DC feedback loop with regulated reinforcement means for a regulated loop gain is known. The loop points first and second first order low-pass RC filters. Farther is a signal switched from an input to an output stretch and one switched from the exit to the entrance Feedback path provided. Either the signal points stretch one of the two low-pass RC filters and the feedback stretch the other low-pass RC filter along with the rules reinforcement means on or the regulated reinforcement medium have two regulated amplifiers, the signal stretch the two low-pass RC filters together with one of the called amplifier and the feedback path the other Amplifier of the amplifier mentioned contains. This resonance ver a relatively frequency-independent Ver strengthening characteristic and its frequency is above that adjustable gain adjustable.

The invention has for its object a resonant circuit to create the kind mentioned above, which is characterized by an intoxication poor, narrow-band vibration signal relatively high Amplitude even at very high vibration frequencies draws.

This task is called at the beginning of a resonant circuit ten kind solved in that each resonance amplifier is an active part and has a resonance filter having an inductance and that an output of each resonance amplifier to the input of the other resonance amplifier is connected so that the Resonance filters for the resonance amplifiers each one of their negative input resistance driven resonant circuit and form a load circuit.

The fact that the inductors have resonance filters from the resonance amplifiers each as that of their negative  Input resistance driven resonance circuit and as a load circuit can be used in the ring-like connection the resonance amplifier formed oscillator circuit only resonance signals are amplified, their phases after one pass equal to 2 n π with n = 0, 1, 2. . . are. Since everyone in the pass band of the oscillator circuit running signals in one pass dangerously delayed, but only by a resonance filter are influenced and therefore the maximum phase shift is only ± π / 4, there is only one in the pass band Correct phase signal. This causes the oscillator circuit to swing in only one vibration mode, the resulting vibration Due to the addition to itself, signal has a high ampli tude, and the spectral line of the vibration signal is relative moderately narrow, as the ones deviating from the center frequency Components at least once more through a resonance filter be suppressed.

In the sense of the present invention is under resonance input or resonance output the input respectively To understand the output of a resonance amplifier that with the Output or input of the other resonance ver is more strongly coupled. The output becomes the distant signal output understood a resonance amplifier on which a verver strengthening signal. Accordingly, under distant signal understood the input of an amplifier that is connected to a Distortion signal output of a resonance amplifier is connected. On The signal outputs of these amplifiers are the amplified ones Distant signals on.  

It is appropriate that each resonance filter as a passive Resonance circuit with a capacitance, especially as one Parallel resonance circuit with at least one inductor and at least one capacitance placed in parallel. For differential tuning of the resonant circuit by one Center frequency, it is advantageous that each resonance filter with a reference voltage and each active part with one vote voltage, for example to control an effective one Capacity of the resonance amplifier in question can be controlled.

In preferred embodiments, an input stage and an output stage having resonance amplifiers with one another assigned resonant part inputs and resonant part outputs constructed symmetrically with respect to a center line to balanced Partial signals at two sub-signal partial outputs of each resonance to achieve amplifier. In one variant, resonance parts are off gears of a resonance amplifier with the same directional resonance part inputs of the other resonance amplifier connected. In a another variant are resonance part inputs of a resonance ver stronger with opposing resonance part inputs of the other Resonance amplifier connected. At the four distant signals In the first variant, partial outputs are partial signals with a Phase shift of 180 degrees and in the second variant Partial signals with a phase shift of 90 degrees each available.

Furthermore, it is expedient that the resonant circuit at least has two output amplifiers, each output amplifier at distant signal outputs of each resonance amplifier applied partial signals can be fed. To improve the Quality of the output amplifier signal at the useful part signal outputs applied useful part signals, it is appropriate to use this To couple output capacity network with each other.  

For balanced useful part signals, it is also advantageous Output amplifier symmetrical with respect to a center line to build.

In a resonant circuit with two resonance amplifiers and two Output amplifiers it is for particularly well balanced Useful part signals very useful, the resonance amplifier with the Resonance filters, the output amplifiers as well as optional seen capacitance networks for coupling the resonance amplifier or the output amplifier with respect two axes that are perpendicular to each other as far as possible symmetrical to build a double balanced To achieve structure.

Further expedient configurations and advantages of the invention are the subject of the subclaims to the following Be Description of exemplary embodiments with reference to the figures the drawing. Show it:

Fig. 1 is a block diagram of an embodiment of a resonant circuit, each with two respectively-coupled capacitor networks Resonanzverstär core and output amplifiers,

Fig. 2 is a block diagram of another Ausführungsbei of a resonant circuit according to the invention with two playing at their resonant inputs each connected to a parallel resonant circuit affected resonance amplifiers, wherein resonance inputs and resonance outputs of the resonance amplifier are equal intimately bonded mitein other,

Fig. 3 is a block diagram in a section a further embodiment of an oscillator circuit according to the invention with two according to the embodiment of FIG. 2 with parallel resonant circuits amplifiers affected Resonanzver, wherein resonance inputs and resonance outputs of the resonance amplifiers are oppositely connected with each other,

Fig. 4 in an electric circuit diagram of a Resonanzver more according to Fig. 2,

Fig. 5 in an electric circuit diagram of a main action stronger in accordance with Fig. 2,

Fig. 6 shows an embodiment of a switchable between Resonanzver stronger or output amplifier capaci titätsnetzwerkes and

Fig. 7 shows another embodiment of a capacitance network that can be switched more strongly between the resonance amplifier or the output amplifier.

Fig. 1 shows a block diagram of an embodiment of a resonant circuit according to the invention. The resonant circuit shown in FIG. 1 has a first active unit 1 and a second active unit 2, which are identical in structure respectively. A first resonance filter 5 , whose phase output 6 is connected to a resonance input 7 of the second active unit 2 , is connected to a resonance output 3 of the first active unit 1 with its phase input 4 . Furthermore, the first resonance filter 5 is connected to a reference voltage terminal 9 with a tuning input 8 . The reference voltage terminal 9 can be acted upon with a reference voltage having an adjustable DC voltage component.

The second active unit 2 is closed with a resonance output 10 at a phase input 11 of a second resonance filter 12 . A phase output 13 of the second resonance filter 12 is connected to a resonance input 14 of the first active unit 1 . Furthermore, the second resonance filter 12 is connected to the reference voltage terminal 9 by a reference input 15 .

The first active unit 1 and the first resonance filter 5 form a first resonance amplifier, and the second active unit 2 and the second resonance filter 12 form a second resonance amplifier. The resonance amplifiers coupled to one another via their resonance inputs and resonance outputs in turn form a ring oscillator. Furthermore, the first active unit 1 and the second resonance filter 12 and the second active unit 2 and the first resonance filter 5 each form an oscillator with a negative input impedance, these oscillators also being composed.

Between a coupling terminal 16 of the first active unit 1 and a coupling terminal 17 of the second active unit 2, a resonance capacitor network 18 is connected, the units of the active 1, 2 capacitively coupled to each other.

Furthermore, the first active unit 1 with a tuning input 19 and the second active unit 2 with a tuning input 20 are connected to a tuning voltage connection 21 , which has an adjustable DC voltage component with a tuning voltage for setting the oscillation frequency around a center frequency and the phase of the resonant circuit according to FIG. 1 one is feedable. The reference voltage that can be fed into the reference voltage connection 9 and the tuning voltage that can be fed into the tuning voltage connection 21 are in phase opposition, the tuning voltage having a higher DC voltage level than the reference voltage.

Furthermore, the resonant circuit has as shown in FIG. 1 via a first output current amplifier unit 22 and a second output-current amplification unit 23 as an output amplifier, which are constructed identically. The first output current amplifier unit 22 is connected via a first distant signal input 24 to a first distant signal output 25 of the first active unit 1 and via a second distant signal input 26 to a first distant signal output 27 of the second active unit 2 . The second output current amplifier unit 23 is correspondingly connected via a second pre-signal input 28 to a second distant signal output 29 of the first active unit 1 and via a second distant signal input 30 to a second distant signal output 31 of the second active unit 2 . The output current amplifier units 22 , 23 also serve as output stages for realizing a negative resistance in order to reduce the influence of the load circuits on the active units 1 , 2 .

Furthermore, an output capacitance network 32 is provided which is connected both to a coupling connection 33 of the first output current amplifier unit 22 and to a coupling connection 34 of the second output current amplifier unit 23 and capacitively couples the output current amplifier units 22 , 23 to one another.

The first output current amplifier unit 22 has a first useful signal output 35 and a second useful signal output 36 , at which two useful part signals can be tapped with a phase ratio predetermined by the connection of the active units 1 , 2 . Correspondingly, the second output current amplifier unit 23 has a first useful signal output 37 and a second useful signal output 38 , from which two further useful partial signals can be tapped, which can be tapped by one another and in relation to the useful part signals tapped at the useful signal outputs 35 , 36 of the first output current amplifier unit 22 Connection of the active units 1 , 2 have predetermined phase relationships.

Conveniently, the circuit 1 is shown in FIG. As shown in the block diagram of largely symmetrical construction, so that the entire resonant circuit has a double balanced structure. Vibration signals of high quality can thereby be generated.

The resonance filters 5 , 12 are expediently designed as inductive and capacitive passive resonance circuits, the resonance filters 5 , 12 having a double function. On the one hand, each of the active units 1 , 2 uses a resonance filter 5 , 12 designed as a passive resonance circuit as the resonance circuit driven by its negative input resistance, on the other hand the other resonance filter 5 , 12 designed as a passive resonance circuit as its load circuit.

Due to the ring-like connection of the active units 1 , 2 under the influence of the resonance filters 5 , 12 , which are designed in particular as resonance circuits, only the oscillation signals receive their maximum amplitude, the phases of which after a pass are equal to 2 n π with n = 0, 1, 2,. . . are. Since all the signals in the pass band of the resonant circuit are delayed approximately uniformly in one pass by the two active units 1 , 2 , but are only influenced by a resonance filter 5 , 12 and therefore the maximum phase shift is only ± π / 4, which is Passband only one useful signal can be coupled out with one phase. As a result, the resonant circuit has only a single oscillation mode and, at the relevant oscillation frequency, the useful signal has a particularly high amplitude, since the resonance signal excited by the negative resistance is added back to itself after amplification. Furthermore, the spectral line of the vibration signal is very narrow, since the resonance signal components deviating from the center frequency are suppressed at least once more by a resonance filter 5 , 12 .

Fig. 2 shows a block diagram of a further exemplary embodiment of a resonant circuit according to the invention which, except for the absence of the resonant capacitance network 18 and the output capacitance network 32, is basically constructed like the resonant circuit according to FIG. 1. In this case, corresponding construction 2 are parts of the resonant circuits shown in FIG. 1 and FIG. Provided with the same reference numerals and are not explained in more detail below, wherein surfaces in Fig. 2 with single and double coated Bezugszei labeled components subcomponents in Fig. 1 with unprimed reference numerals provided components are.

In the embodiment according to FIG. 2, the resonance filter 5, 12 is designed as a passive parallel resonant circuits, wherein the first resonance filter 5 via a first resonance inductor 39 as an inductor and connected in parallel with first resonant capacitor 40 as an additional capacity, and the second resonant filter 12 accordingly via have a first resonance inductance 41 as an inductor and a parallel resonance capacitance 42 connected as an additional capacitance. The reference voltage which can be fed in at the reference voltage connection 9 can be fed to the first resonance filter 5 via a center tap of the first resonance inductance 39 forming the reference input 8 and the second resonance filter 12 via a center tap of the second resonance inductance 41 forming the reference input 15 , the reference voltage being the reference inputs 8 , 15 Resonance filter 5 , 12 can be fed via a reference voltage conductor loop 43 which symmetrically surrounds the active units 1 , 2 .

A first resonance part output 3 'of the first active unit 1 is connected via a first phase part input 4 ' of the resonance filter 5 , to which connections of the first resonance inductor 39 and the first resonance capacitance 40 are also connected, to a resonance part input 7 'of the second active unit 2 with the same meaning. Correspondingly, a second resonance part input 3 ″ of the first active unit 1 is connected via a second phase part input 4 ″ of the first resonance filter 5 , to which the other connections of the first resonance inductance 39 and the first resonance capacitance 40 are connected, to a second resonance part input 7 in the same direction '' connected to the second active unit 2 .

Correspondingly, a first resonance part output 10 'and a second resonance part output 10 ''of the second active unit 2 are each via a first phase part input 11 ' and a second phase part input 11 '' of the second resonance filter 12 , to which connections of the second resonance inductance 41 and the second are also connected Resonance capacitance 42 are connected, connected in the same direction to a first resonance part input 14 'and a second resonance part input 14 ''of the first active unit 1 .

The first active unit 1 is connected via a first tuning part input 19 'and a second tuning part input 19 ''and the second active unit 2 is connected via a first tuning part input 20 ' and a tuning part input 20 '' to a tuning voltage conductor loop 44 which closes the active units 1 , 2 is connected to the tuning voltage terminal 21 .

In the exemplary embodiment according to FIG. 2, the useful signal outputs 35 , 36 , 37 , 38 of the output current amplifier units 22 , 23 are connected via load resistors 45 for tapping the useful part signals to switching ground.

In the same sense interconnection of the passages through the Resonanzteilaus 3 ', 3' ', 10', 10 '' formed resonance outputs 3, 10 of each active unit 1, 2 forming the resonance inputs 7, 14 resonating part inputs 7 ', 7' ', 14' , 14 '' of the other active unit 1 , 2 via the phase part inputs 4 ', 4 '', 11 ', 11 '' as phase inputs 4 , 11 of the resonance filter 5 , 12 are on the pair of useful signal outputs 35 , 36 of the first output current amplifier unit 22 and on the pair of useful signal outputs 37 , 38 of the second output current amplifier unit 23 generated by 180 degrees antiphase useful part signals, since each active unit 1 , 2 generates a phase rotation of 180 degrees and at the vibration frequency, the entire phase change after a revolution 0 degrees or 360 degrees must be in order to achieve a reinforcement. This type of connection is particularly useful when differential vibration signals at the opposite useful signal outputs 35 , 36 , 37 , 38 of the resonant circuit are required, as is customary in a phase-locked loop.

Fig. 3 shows a detail of a block diagram of a resonant circuit according to FIG. 2 with an opposite connection device of the resonance part outputs 10 ', 10 ''of the second active unit 2 with the resonance part inputs 14 ', 14 '' of the first active unit 1 . The first resonance part output 10 'of the second active unit 2 is connected to the second phase part input 11 ''of the second resonance filter 12 .

Of course, alternatively, the first resonance part output 3 'of the first active unit 1 in opposite directions with the second resonance part input 7 ''of the second active unit 2 and the second phase part input 4 ''of the resonance filter 5 and the second resonance part input 3 ''of the first active unit 1 in the opposite direction first resonance part input 7 'of the second active unit 2 and the first phase part input 4 ' of the resonance filter 5 .

In this opposing interconnection of the resonance outputs 3, 10 forming the resonance part outputs 3 ', 3' ', 10', 10 '' of an activated unit 1, 2 forming the resonance inputs 7, 14 resonating part inputs 7 ', 7' ', 14', 14 '' The other resonance amplifier unit 1 , 2 under the action of the resonance filter 5 , 12 are generated at the useful signal outputs 35 , 36 , 37 , 38 of the output current amplifier units 22 , 23 four useful signals, each with a relative phase angle of 90 degrees. This type of connection is useful when useful part signals with a phase spacing of 90 degrees are used, for example in a 4: 1 multiplexer or a 1: 4 demultiplexer.

The following is in connection with transistors in the Use of field effect transistors under input the so-called called "gate" and under exit the so-called "source" to understand the so - called "drain", while at the use of bipolar transistors under input the base and the output or the collector or emitter are understand. The contacting of the outputs results for the specialist taking into account the doping of the tran sistors and the potential relationships.

The circuits are preferred with field effect transistors for the Application in the high frequency range with a few 10 GHz executed, the circuit preferably integrated up is building. In other areas of application, especially in lower frequencies, the circuits are also in bipolar technology feasible.

FIG. 4 shows an electrical circuit diagram of an exemplary embodiment of the first active unit 1 according to FIG. 2 or FIG. 3, the second active unit 2 being constructed accordingly. The first active unit 1 is constructed from an input stage 46 and an output stage 47 . The input stage 46 has a first resonance input transistor 48 , the input of which is connected to the first resonance input 14 'of the resonance input 14 , and a first tuning transistor 49 , the input of which is connected to the first tuning input 19 ' of the voice input 19 . An output of the first resonance input transistor 48 is connected to the switching ground via a first input current source 50 . An output of the first tuning transistor 49 is connected directly to the switching ground, while the other outputs of the resonance input transistor 48 and the first tuning transistor 49 are in contact with one another.

Correspondingly, the input of a second resonance input transistor 51 is connected to the second resonance part input 14 ″ of the resonance input 14 and the input of a second tuning transistor 52 of the input stage 46 is connected to the second tuning part input 19 ″ of the tuning input 19 , one of the outputs of the second resonance input transistor 51 are connected directly to the switching ground via a second input current source 53 and an output of the second tuning transistor 52 . The respective other outputs of the resonance input transistor 51 and the second tuning transistor 52 are connected to one another.

Furthermore, the merged output connections of the first resonance input transistor 48 and the first tuning transistor 49 are connected via a connecting line 54 to the merged output connections of the second resonance input transistor 51 and the second tuning transistor 52 .

From the circuit diagram of FIG. 4 it is seen that the Reso nanzeingangstransistoren 48, 51 and their associated input transistors 50, 53 with the use of field effect transistors each have a source follower, and each of which forms an emitter follower with the use of bipolar transistors.

When using field effect transistors, the resonance input transistors 48 , 51 are normally-off and the tuning transistors 49 , 52 are made normally-on. The self-tuning transistors 49 , 52 are used to draw the direct currents flowing through the drain outputs of the resonance input transistors 48 , 51 through the drain-source channels of the tuning transistors 49 , 52 from ground.

At the ground-side output of the first resonance input transistor 48 , the input of a first resonance output transistor 55 and the input of a first neutralization transistor 56 of the output stage 47 is connected . At the connection between this ground-side output of the first resonance input transistor 48 and the input of the first resonance output transistor 55 , the first distant signal output 25 is connected.

Correspondingly, the input of a second resonance output transistor 57 and the input of a second neutralization transistor 58 of the output stage 47 are connected to the ground-side output of the second resonance input transistor 51 . The second distant signal output 29 is contacted between this ground-side output of the second resonance input transistor 51 and the input of the second resonance output transistor 57 .

An output of the first resonance output transistor 55 is connected to the first resonance output 3 'of the resonance output 3 , while an output of the second resonance output transistor 57 is connected to the second resonance output 3 ''of the resonance output 3 . The outputs of the first neutralization transistor 56 are short-circuited and connected to the second resonant part output 3 ″. The outputs of the second neutralization transistor 58 are also short-circuited and contacted with the first resonant part output 3 '. The neutralization transistors 56 , 58 form in this connection a neutralization network 59 in order to couple parasitic capacitances against phase, to increase the maximum resonance frequency and to reduce feedback of a load connected to the resonance output 3 .

The other output of the first resonance output transistor 55 is connected on the one hand to the switching ground via a first output current source 60 . The other output of the second resonance output transistor 57 is correspondingly connected to switching ground via a second output current source 61 . Furthermore, the switching ground-side output connections of the resonance output transistors 55 , 57 are capacitively coupled to one another via an output capacitance unit 62 , which in the exemplary embodiment shown in FIG. 4 comprises a first output capacitance 63 connected to the first resonance output transistor 55 and a series-connected output capacitance thereto, and also with the second resonance output transistor 57 contacted second output capacitance 64 is formed.

The outputs of the resonance output transistors 55 , 57 connected to the output capacitance unit 62 are provided as first and second coupling partial connections 16 ′, 16 ″ of the coupling connection 16 .

The output stage 57 is used on the one hand to generate the negative resistance on the input side of the resonance output transistors 55 , 57 and to convert the voltage signal at the distant signal outputs 25 , 29 into a differential current signal at the resonance partial outputs 3 ', 3 ''with current amplification.

The active units 1 , 2 are expediently constructed symmetrically with respect to a central axis, as shown in the electrical circuit diagram according to FIG. 4, in order to obtain outputs 3 ′, 3 ″ and resonance part inputs 14 ′, 14 ″ from balanced partial signals at the resonance part.

FIG. 5 shows an electrical circuit diagram of a preferably integrated embodiment of the first output current amplifier unit 22 according to FIG. 1 or FIG. 2, the second output current amplifier unit 23 being constructed identically. The input of a first amplifier input transistor 65 is connected to the first distant signal input 24 , in which one output is connected directly to switching ground and the other output is connected to switching ground via a first amplifier input current source 66 . Correspondingly, the input of a second amplifier input transistor 67 is connected to the second distant signal input 26 , in which one output is connected directly to switching ground and the other output is connected to switching ground via a second amplifier input current source 68 . The amplifier input transistors 65 , 67 form an amplifier input stage 69 of the first output current amplifier unit 22 .

At the output of the first amplifier input transistor 65 connected to switching ground via the first amplifier input current source 66 , the input of a first amplifier output transistor 70 is connected , in which one output is connected directly to the first useful signal output 35 and the other output is connected to switching ground via a first amplifier output current source 71 . Accordingly, in the set of switching mass via the second amplifier input current source 68 output of the second amplifier input transistor 67 contacts 36 of the one input of a second amplifier output transistor 72 to be closed, in which an output of the second useful signal output and the other output connected to circuit ground through a second amplifier output current source 73 is.

Furthermore, an amplifier output capacitance unit 74 is connected between the switching ground-side outputs of the amplifier output transistors 70 , 72 , which in the exemplary embodiment shown in FIG. 5 is represented by a first amplifier output capacitance 75, which is contacted with the first amplifier output transistor 70 , and a series capacitance 75 connected to the latter and with the latter second amplifier output transistor 72 connected second amplifier output capacitance 76 is formed. The capacitively coupled amplifier output transistors 70 , 72 form an amplifier output stage 77 .

The outputs of the amplifier output transistors 70 , 72 connected to the switching ground and connected to the amplifier output capacitance 74 each form a first coupling part connection 33 ′ and a second coupling part connection 33 ″ of the first output current amplifier unit 22 .

In order to obtain balanced partial signals at the distant signal inputs 24 , 26 , 28 , 30 and at the useful signal outputs 35 , 36 , 37 , 38 of the output current amplifying units 22 , 23 , it is appropriate, according to the circuit diagram shown in FIG. 5, with respect to a center line watch symmetrical structure.

Fig. 6 shows in an electrical diagram an exemplary embodiment of the output capacitance network 32 according to FIG. 1, which is connected between the coupling connections 33 , 34 of the output current amplifying units 22 , 23 . The output capacitance network 32 is in the shown in Fig. 6 execution example of the amplifier output capacity units 74 of the first output current amplifier unit 22 and the second off-current amplifier unit 23 according to Fig. 5 constructed via a between the amplifier output capacitances 75, 76 of each amplifier output capacitance unit 74 specified coupling line 78 with each other are coupled. This configuration of the output capacitance network 32 leads to a doubling of the current of the useful part signals present at the useful signal outputs 35 , 36 , 37 , 38 .

Fig. 7 shows an example of an electrical circuit diagram of the implementation of the resonance capacitance network 18 in the exemplary embodiment of the resonant circuit according to FIG. 1, the connections to first coupling part connections 16 ', 17 ' and to second coupling part connections 16 '', 17 '' of the coupling connections 16 , 17 of the active units 1 , 2 is connected. The resonance capacity network 18 shown in FIG. 7 has two individual output capacitances 79 , each forming an output capacitance unit 62 , each between the coupling part connections 16 ', 16 ''of the coupling connection 16 or the coupling part connections 17 ', 17 '' of the coupling connection 17 of the active units 1 , 2 are switched.

Furthermore, the resonance capacitance network 18 comprises two coupling capacitances 80 , each of which is connected between the first coupling partial connections 16 ', 17 ' and the second coupling partial connections 16 '', 17 '' of the coupling connections 16 , 17 of the active units 1 , 2 , so that the individual output capacitances 79 and coupling capacitances 80 form a capacitive ring circuit. By providing the resonance capacitance network 18 between the active units 1 , 2 , the resonance part signals at the resonance part inputs 7 ′, 7 ″, 14 ′, 14 ″ and at the resonance part outputs 3 ′, 3 ′, 10 ′, 10 ″ are stabilizing with one another correlated.

Claims (15)

1. Amplify resonant circuit with two mutually coupled resonance, inductors being connected to inputs of the resonance amplifier, characterized in that each resonance amplifier has an active part ( 1 , 2 ) and an inductance ( 39 , 41 ) having resonance filter ( 5 , 12 ) and that an output ( 3 , 3 ', 3 '', 10 , 10 ', 10 '') of each resonance amplifier to the input ( 7 , 7 ', 7 '', 14 , 14 ', 14 '') of the other resonance amplifier is connected, so that the resonance filter ( 5 , 12 ) for the resonance amplifier each form a resonance circuit driven by their negative input resistance and a load circuit. 2. resonant circuit according to claim 1, characterized in that each resonance filter ( 5 , 12 ) is a passive resonance circuit with a capacitance ( 40 , 42 ). 3. Oscillating circuit according to claim 2, characterized in that the resonance circuit is a parallel resonance circuit with an inductance ( 39 , 41 ) connected in parallel with a capacitor ( 40 , 42 ). 4. Oscillating circuit according to one of claims 1 to 3, characterized in that each inductor ( 39 , 41 ) has a tap ( 8 , 15 ) to which a reference voltage can be applied. 5. resonant circuit according to claim 4, characterized in that each resonance amplifier ( 1 , 2 ) via at least one tuning input ( 19 , 19 ', 19 '', 20 , 20 ', 20 '') with a tuning voltage for adjusting the center frequency of the resonant circuit is acted upon. 6. resonant circuit according to one of claims 1 to 5, characterized in that each resonance amplifier ( 1 , 2 ) has an input stage ( 46 ) with two respective one part input ( 14 ', 14 '') assigned, directly coupled input transistors ( 48 , 49 , 51 , 52 ) and an output stage ( 47 ) with two each having a pair of input transistors ( 48 , 49 ; 51 , 52 ) associated, via an output capacitance unit ( 62 ) coupled to each other output transistors ( 55 , 57 ). 7. resonant circuit according to claim 6, characterized in that the input stage ( 46 ) and the output stage ( 47 ) of each resonance amplifier ( 1 , 2 ) are constructed symmetrically to a center line. 8. resonant circuit according to claim 6 or claim 7, characterized in that partial outputs ( 3 ', 3 ''; 10 ', 10 '') of each resonance amplifier ( 1 , 2 ) with the same directional part inputs ( 7 ', 7 ''; 14 ' , 14 '') of the other resonance amplifier ( 1 , 2 ) are connected. 9. resonant circuit according to claim 6 or claim 7, characterized in that partial outputs ( 3 ', 3 ''; 10 ', 10 ''). the resonance amplifier ( 1 , 2 ) is connected to opposing partial inputs ( 7 ', 7 ''; 14 ', 14 '') of the other resonance amplifier ( 1 , 2 ). 10. resonant circuit according to one of claims 1 to 9, characterized in that the resonance amplifier ( 1 , 2 ) via a capacitance network ( 18 ) forming capacitors ( 79 , 80 ) are coupled together. 11. resonant circuit according to one of claims 1 to 10, characterized in that two output amplifiers ( 22 , 23 ) each having two signal inputs ( 24 , 26 ; 28 , 30 ) and two signal outputs ( 35 , 36 ; 37 , 38 ) are provided, wherein each signal output ( 25 , 29 ; 27 , 31 ) of a resonance amplifier ( 1 , 2 ) is connected to a signal input ( 24 , 26 ; 28 , 30 ) of each output amplifier ( 22 , 23 ). 12. Oscillating circuit according to claim 11, characterized in that each output amplifier ( 22 , 23 ) has an input stage ( 69 ) with two respective input transistors ( 65 , 67 ) and a signal input ( 24 , 26 ; 28 , 30 ) and an output stage ( 77 ) with two each having an input transistor ( 65 , 67 ) and a signal output ( 35 , 36 ; 37 , 38 ) assigned, via a capacitance unit ( 74 ) coupled to each other th amplifier output transistors ( 70 , 72 ). 13. resonant circuit according to claim 12, characterized in that the input stage ( 69 ) and the output stage ( 77 ) of each output amplifier ( 22 , 23 ) are constructed symmetrically to a center line. 14. resonant circuit according to one of claims 11 to 13, characterized in that the output amplifiers ( 22 , 23 ) via a capacitance network ( 32 ) forming amplifier output capacitances ( 75 , 76 ) are coupled together. 15. resonant circuit according to one of claims 1 to 14, characterized characterized that he was two at right angles to each other standing axes essentially symmetrical and has a double balanced structure.