DE1108278B - Parametric amplifier arrangement - Google Patents

Description

Parametric amplifier arrangement The parametric amplifiers work on the principle of a variable reactance, which is connected as a coupling element between two resonant circuits that are tuned to different frequencies (f1 f,), whereby the variable reactance is controlled with the so-called pump frequency fp. All of these arrangements are by their nature mixer amplifiers in which energy is taken from the pump frequency source by mixing the frequencies f 1, f, and fP and supplied to both frequency f and frequency f2. In particular, the frequencies are chosen so that fP = f, -f-fa, because then a negative resistance occurs both at frequency f and at frequency f2, which produces the amplifying effect. With the same circuit it is possible to achieve either a gain at the same frequency f or f2 (straight amplifier) or between f and f2 (mixer amplifier). The variable reactance can be a capacitance or an inductance. At high frequencies, the capacitance is realized by suitable semiconductors in the restricted area, while the variable inductance is produced by suitable ferrites.

In building such a regenerative amplifier, there is an essential one Difficulty in realizing the three circles for the frequencies f ,, f2 and fp so that they can be tuned and adjusted independently of each other. This requirement is more fundamental in the negative resistance amplifier (regenerative amplifier) This is important because the individual circles are perfectly balanced for stability of the amplifier is necessary.

In parametric amplifier arrangements, it is already known to have a of the three characteristic frequencies by low-pass and high-pass devices of to separate the two remaining frequencies. Furthermore, in such amplifier arrangements known, one of the three frequencies mentioned with bandpass devices from the rest Separate frequencies while these remaining frequencies using bridge circuits are decoupled from each other.

The aim of the present invention is, inter alia, to show a particularly advantageous embodiment of the adjustment possibilities of such an amplifier, the pump oscillator being connected to the amplifier arrangement with the aid of a specially designed bridge circuit. In connection with the low-pass and high-pass devices, this enables the three characteristic frequencies to be adjusted separately. In a parametric amplifier arrangement in which one of the three characteristic frequencies f 1, f2 or fp is separated from the two remaining frequencies by low-pass or high-pass devices, it is therefore proposed according to the invention that the remaining frequencies are decoupled from one another with the aid of bridge circuits that the pump frequency fr is fed into the amplifier arrangement through such a bridge circuit. This bridge circuit consists of two high-frequency bridges with interposed filters, which are designed as bandpass filters for the pump frequency fp or as bandstop filters for the other frequency, f2. When using magic T as high-frequency bridges, these filters are offset from one another by A / 4 with regard to their mutual position between these bridges.

In the further description of the invention it is assumed that f, the lowest, f2 the middle frequency. The frequency fp must always be the highest Frequency so that negative resistances at the other two frequencies and so that a gain is achieved.

A special property of the reactance amplifier is the very low noise, and you will therefore choose the pump frequency as high as possible, since the noise factor is then particularly small. A typical example for the frequency selection is: f, = 1000 MHz, f2 = 9000 MHz and fP = 10 000 MHz. 1 shows the basic circuit diagram of the invention, it being assumed here, as in all other examples, that the variable reactance is a capacitance and is formed by a semiconductor diode D with a negative bias voltage. In particular, a mixer amplifier is shown in FIG. 1, the frequency f1 being fed to the line L, and the amplified and offset frequency f2 = fp- f1 being taken from the line L2. The connecting lines between the individual switching elements represent special line elements in coaxial or hollow tube design. The diode D is connected to the line L via the low-pass filter TP and the complex transformer T. The low-pass filter only lets the frequency f 1 through and blocks the other two frequencies f2 and fp. With the transformer T, the complex conductance of the diode (negative conductance and susceptibility) for the frequency f, is suitably adapted to L, so that a real negative conductance of a suitable size occurs there. Furthermore, the diode is connected to the line L2 P via the high-pass filter HP and the complex transformer T21. The high-pass filter lets the frequencies f2 and fp through and blocks the frequency f1. The complex transformer generates a suitable pre-transformation of the complex diode conductance and is so broadband that it also transmits the two frequencies f2 and fp. In FIG. 1, the elements T1, TP, D, HP and T2 are combined to form the unit P. A bridge arrangement, which consists of the two high-frequency bridges B1, B2 and the filters F, is connected to the further end of the line L2p. These two filters are offset from one another by A, 2/4 in the course of the lines L2 and L22. The two bridges can be constructed in any way, e.g. B. in the form of a magic T. If you use 3-db directional couplers with hollow tubes, the 2/4 offset of the filters is omitted. The two filters F are identical to one another and can either be bandpass filters for frequency fp or bandstop filters for frequency f2. The pump frequency fp is fed from the pump source P via the complex transformer Tp and the line LP to the bridge B2. There she is z. B. in two in-phase partial waves in the lines L2, and L22 via the filter F, to bridge B. Here the partial waves are reassembled and fed to the diode D via the line L2 P. Line L2 is decoupled from the pump energy. Residual reflections at the filters at the frequency fp are absorbed on the line LZ by the terminating resistor Z, which is equal to the characteristic impedance. If the filters are perfectly dimensioned, Z and thus LZ can be omitted, ie B2 becomes a simple line branch. The line L2 only carries the frequency f2, the complex transformer T22 is used for suitable tuning and adaptation of the line circuit for the frequency f2. The resonant circuit consists of the diode, the transformer T2 ,, the line L2 p, the bridge lines L2 ,, L22 and the line L2 with the transformer T22.

If one assumes that L, energy of the frequency f, is fed into, the frequency f2 at the diode arises due to the mixing effect of the reactance diode. The corresponding wave runs through the transformer T2 ,, the line L2 p in the bridge B ,, is there z. B. split in phase onto the two lines L2 and L22 and totally reflected at the filters F. Due to the a2 / 4 offset of these filters, the waves in the bridge, rotated 180 'relative to one another, are combined and finally fed to line L2. The line circuits for the frequencies f2 and fp are decoupled by the bridge arrangement and can be tuned independently of one another with the help of the transformers T22 and Tp. In the case of mixed amplification from f to f2, the line output 2 is expediently closed off by a ferrite insulator J without reflection. The amplified frequency fz passes through this ferrite insulator and the connected band filter F2 and then arrives at the terminating and consumer resistor Z. The band filter F2 is used to select, in particular, against energy residues at frequencies f and fp.

The same arrangement can also be used as a straight line amplifier for the frequency f1 can be used. Then between the transformer T, and the low-pass filter TP over a second transformer T, 'another line L,' connected to which the amplified frequency f, can be taken off. The connection 2 for the frequency f2 is then terminated with a resistor Z. It should be noted here that a such a resistance with the temperature To = 300 ° K is noisy. In this case it remains the frequency f2 necessary to generate the negative resistance at frequency f, in the system. Then this frequency is also called auxiliary frequencyfu = f2, and the resonant circuit this is called the auxiliary circle.

In FIG. 2, a practical embodiment of the invention is shown, which is constructed according to FIG. The line circuit for the frequency f1 is realized with coaxial line elements. The line L, 2 matched with the short-circuit slide S, is the basic element of the resonant circuit for f1; together with the coupling capacitance Clc in the input line L, it represents the complex transformer T. The low-pass filter TP consists of two ring-shaped capacitances and an intermediate line. It is also tuned into the resonant circuit for the frequency f1. The line L2 p is a hollow pipeline with the narrow side b and the broad side a, which is closed at one end with the short-circuit slide valve S2. The reactance diode D has one terminal connected to the wall of L, p and the other terminal to the low-pass filter TP. The transformer T2, consisting in the present example of the hollow pipe section, the short-circuit slide valve S2 and the unavoidable feed line inductances, is used for the corresponding transformation and adaptation. If necessary, other tuning elements, such as hollow tube diaphragms or coaxial tuning lines, can be inserted between the diode and the hollow tube. The bridge arrangement is made up of hollow tubes, and the two bridges are possible designs in the manner of a magic T. The line L2 for the frequency f is attached to the side and has the longitudinal axis perpendicular to the plane of the drawing. According to the drawing, this line is folded into the plane of the drawing in its further course. The stub lines L2 and L22 with the corresponding short-circuit sliders S2 and S22 are also a possible embodiment of the complex transformer T22. The filters F, in the hollow tubes L2 and L, ″ consist of the diaphragms B and the tuning stamps A and, in the exemplary embodiment, are bandpass filters which are tuned to the frequency fp and which totally reflect the frequency f. The line LP contains the complex transformer Tp in the form of the two lines LP, and LP, with the associated tuning slides Sp, and Spe.

The arrangement according to FIG. 1 or 2 can be operated as a straight amplifier or as a mixer amplifier and has the property that no adaptation to the internal resistance occurring there is possible at terminals 1 and 2. This internal resistance can in particular be a negative resistance.

A further embodiment of the present invention achieves by using two identical reactance diodes in a suitable bridge circuit that the internal resistances of the circuit at terminals 1 and 2 are positive real resistances equal to the characteristic impedance of the lines concerned, so that adjustments can be made at both terminals. The basic circuit diagram of such a circuit is shown in FIG. For the sake of simplicity, the elements T,., TP, D, HP and T21 are combined to form the switching element P, with two identical elements P and P "being used. These elements are connected to the lines L" and L "for the frequency f1. connected to bridge B11, the two lines being A, / 4 different lengths. Two line terminals 1 and 1 'are available for the frequency f1, whereby when a line, for example L,' with its characteristic impedance Z, is terminated, the input impedance at terminal 1 is also equal to the characteristic impedance Z, regardless of frequency (Z = const. ). The elements P 'and P ", on the other hand, are connected for the frequencies f2 and fp via the lines L" p' and L2 p "to the identical bridge arrangements I and II according to FIG. 1. The connecting lines L2 and L,", " which only forward the frequency f2 are continued in the partial lines L '.,. = and L.) = of a further bridge B22, whereby L' .- and are different in length by. In this way, two connections 2 and 2 'are available for frequency f2, which have the same matching properties (Z = const.) As terminals 1 and 1' . Finally, the two lines LP 'and LP "are combined in the bridge BP to form the common feed line LP, so that when the pump generator P is connected, in-phase feed is achieved.

With this arrangement, straight-ahead amplification or mixed amplification with frequencies f1 and f2 is also possible. If the frequency f 1 is to be amplified, the output 1 'is terminated with the characteristic impedance Z as a consumer and the power to be amplified is fed to terminal 1. The frequency f2 arises here only at connection 2, which is terminated with Z. The connection 2 'is decoupled from the frequency f2 and can therefore be terminated as desired. In particular, it is advantageous to terminate the connection 2 'with a reactance (line section with short-circuit slide). The connecting line L ″ can also be omitted, ie the bridge B22 thus becomes a simple junction, for example with in-phase distribution of the power.

This is for the noise factor of the amplifier for the following reason significant: the output noise of the amplifier at connection 1 'and thus the noise factor is essentially due to the noisy terminating resistance at the noise temperature To = 300 ° K Z determined at the connection for the frequency f2. Because the reactance diode except for inevitable Loss in the resistance of the diode leads to pure reactive power, is its contribution to noise very low compared to the mentioned contribution of the terminating resistor. In the circuit According to Fig. 1, the noise power of the f2 terminating resistor becomes a certain one Part transmitted to the amplifier output 1 'and forms the main part of the inherent noise of the amplifier. In the present case (FIG. 3), after omitting the line L2 ', arrives the noise power of the terminating resistor at terminal 2 when converted into the frequency position f, not to the output line L, 'of the f, amplifier, but only to line L, and thus to the f, generator, d. i.e., the noise factor of the amplifier will be much better.

If you want this possibility of particularly low-noise amplification, for example at the frequency f, do not use, so you can leave the bridge B22 white and the Terminate lines L2 'and L, "separately with a resistor Z. The corresponding applies to the amplification of the frequency f2 for connections 2 and 2 '.

In FIG. 3 a, a circuit is shown which is derived from FIG. 3 emerges through certain simplifications. The bridges BP, B2 'and B2 "are here replaced by simple line branches. The two transformers T ._>. = and T. = (Fig. 3) are omitted, and the bridge B22 is also through a branching line replaced. The output arm L2, this branch has a transformer T22, which is common to both branches. Terminal 2 is terminated with a terminating resistor Z provided. The circuit described is suitable for straight-ahead amplification of Terminal 1 to 1 '.

In contrast to the circuit shown in FIG Circuit of Fig. 3a, the A, / 4 detour loop in line L2 replaced by one Ap / 4 loop in the pumping circuit. Of course, this is always possible.

In the case of mixed amplification from f to f2 with the arrangement according to FIG. B. at terminal 1, the frequency f, is fed in, terminal 1 'is terminated with a resistor Z and at terminal 2, the amplified and converted frequency is removed. Here, the terminal 2 'is terminated with the characteristic impedance Z of the line L = ", and the consumer resistance at the terminal 2 at the end of the line L2 is selected to be equal to Z. Furthermore, the frequency f, can be fed into the terminal 2 and the amplified Frequency f, can be taken from terminal 1.

The circuit of FIG. 3 has the further advantage that it can be used to build a cascade amplifier in which two such arrangements are connected in series at terminals 1, 1 ' and / or 2, 2' of the sub-amplifiers. This is shown in FIG. 4. The line branch from 1 a via 1 ä, 1 b to 1 b 'has the characteristic impedance Z throughout and on it there is a two-fold multiplicative amplification of the frequency f i. The same applies to the line run from 2a via 2a ', 2b to 2b', on which the frequency f i is amplified twice. In order to set the correct phase relationship between the two partial amplifiers, the length of the connecting line between 2a and 2b must match the length of the connecting line between la 'and 1b.

Another embodiment consists in omitting the connecting line between 2a and 2b and terminating 2a ' or 2b individually with terminating resistors Z. Then there is no cascade gain at frequency f2, but the gain at frequency f remains. Furthermore, the circuit can be modified so that the connection of terminals 1ä and 1b is omitted and only terminal 2ä is connected to 2b . Then the arrangement between the connections 1 a and 1 b 'represents a straight amplifier for the frequency F1, which consists of the cascade connection of two mixing amplifiers. In the first stage the frequency f1 is converted into the frequency f2, and in the second stage f2 is mixed back to f1. The straight ahead gain is equal to the product of the two mixed gains. In this case, however, the terminating resistors Z at terminals 2a and 2b 'can contribute to the amplifier's inherent noise. Since the terminal 2a is decoupled from the frequency f , in the terminal 2a and does not receive any signal power, the terminal 2a can also be terminated with a reactance which does not generate any noise power, so that the noise factor of the amplifier arrangement can also be improved with this.

The cascade circuit described can also be used on more than two sub-amplifiers be expanded. It is for both straight reinforcement and mixed reinforcement suitable.

In the case of the cascade connection shown in FIG. 4, for the sake of clarity the individual bridges B11, B22 and BP are only shown schematically. The bridge arrangements I and II of FIG. 3, each consisting of two bridges and two filters offset by 2/4 exist are also only indicated schematically in FIG. B. by the Box la and IIa. The same applies to the switching elements P. The rest of the designation the individual parts correspond to the previous figures.

If you do without the possibility of mixing amplification and want to go along with it the arrangement only at the frequency f, achieve straight-ahead gain, so can convert the general circuit of Fig. 3 to the simpler circuit, such as it is shown in FIG. The circuit for frequency f1 is the same, however, the arrangement has been simplified for the frequencies f2 and fp. The Elements P 'and P "are connected to the bridge B22, whose line connection L2p to the common Bridge arrangement I / II for the frequencies f2 and fp leads. The bridge arrangement 1 / 1I consists of the two bridges B, 'and B2 with the two filters in between F, which are again offset from one another by? 2/4. The two between the bridge Bll and the elements P 'and P "existing lines L1' and L," are different in length by? 1/4. In this way one gains for the frequency f2 two connections 2 and 2 ', in each of which half of those in P' and P "are generated Energy of frequency f2 is performed. To form the appropriate impedance for this Frequency lines L2 and L2 'must be terminated. In particular is it possible e.g. B. complete the line Lz with a short circuit slide so that a pure reactance for tuning the resulting circuit for the frequency f2 arises. The line L2 then has a real resistance Z completed, the one for setting the desired active component in the f2 circle with the complex transformer T22 is transformed while the reactive component with the transformer T =. is set.

A further simplification is shown in FIG. 6, in which a filter F without the bridge arrangement 1 / 1I is used. Instead of the adjustable line length of L2 in FIG. 5, the line L, p between the bridge B22 and the filter F with a length of 12 p must be selected appropriately. With this arrangement, the frequency f1 is fed back into terminal 1. The output terminal 1 'for the amplified frequency f1 is terminated with a resistor Z. The line length of the two lines between the bridge B1 and the two elements P 'and P "differs by 2.1 / 4. The two elements P' and P" are connected to the bridge B22. The frequency fp comes from the pump generator P via the transformer Tp and the line LP to the said filter F. The line L2 of the bridge B22 leads via the transformer T22 to terminal 2, which is terminated with the resistor Z for the frequency f2.

FIG. 7 shows a further modification of the circuit according to FIG. 5, which is used for amplification at the frequency f2 between the connections 2 and 2 '. The two elements P 'and P "are again arranged between two bridges B1 and B2. One line is here by A.2 / 4 .. ip / 4 longer, with the assumption that the frequencies f and fp are adjacent Both terminals 1 and 1 ' are terminated with resistors Z. Bridge B2 is connected to bridge B1' via line L, p . This bridge leads via two filters F offset by R2 / 4 to another bridge B2 , into which the Pump frequency fp is fed in via the transformer Tp and the line LP. The fourth bridge arm from the bridge Bz can be omitted here, so that a simple line branch is created, as shown in FIG.

In all the examples described, the bridges are designed in the manner of a "magic T", in which in certain cases 2/4 detour lines are inserted into the bridge lines. It should also be pointed out that bridges like the 3-dB directional coupler can also be used under certain circumstances, in which case the n / 4 detour lines can be omitted because a phase difference of 90 ° is generated in the directional coupler itself. This is e.g. B. in the arrangement according to FIG. 7 advantageous if the two frequencies f2 and fp are not closely adjacent. If the bridge design is carried out with the help of a magic T , the a / 4 difference between P "and B2 can only be adhered to exactly for one of the two frequencies f2 or fp, while with the 3-db directional coupler the analog 90 'difference is much broader in phase, ie more independent of the frequency.

Claims (7)

PATENT CLAIMS: 1. Parametric amplifier arrangement in which one of the three characteristic frequencies, f1, f2 or fp, is separated from the two remaining frequencies by low-pass or high-pass devices, characterized in that the remaining frequencies are decoupled from one another by means of bridge circuits that the pump frequency fp is fed into the amplifier arrangement through such a bridge circuit and that this bridge circuit consists of two high-frequency bridges with interposed filters which are designed as bandpass filters for the pump frequency fp or as bandstop filters for the other frequency, f2, and when using magic T as high-frequency bridges are offset from one another by A / 4 with regard to their mutual position between these bridges. 2. Arrangement according to claim 1, characterized in that the lower of the two frequencies f1 and f2 is fed to the parametric element (D) via a low-pass device and the higher of these two frequencies via a high-pass device, while the pump frequency fP is fed in via a bridge arrangement that the pump frequency fp and the next lower frequency, f2, are decoupled from one another. 3. Arrangement according to claim 2, characterized in that the bridge arrangement consists of two four-armed There are bridges (B1, B2) with two identical filters (F1) in between, the around., 2/4 are arranged offset from one another (Fig.1). 4. Arrangement according to claim 3, characterized in that the filters (F1) bandpasses for the pump frequency fp or bandstop filters for the next lower frequency, f2. 5. Arrangement according to claim 3, characterized in that the fourth arm (L2) of one bridge (B1) and the fourth arm (LP) of the other bridge (B2) are connected to complex transformers (T22 or TP) (Fig. 1). 6. Arrangement according to one of the preceding Claims, characterized in that two parametric elements (P ', P ") are used being, which has the lowest frequency, f1, over a bridge (B11) and two around 2, l / 4 different lines (Lü, L; i) are supplied, while for the other two Frequencies, f2 and fP, two bridge arrangements (I and II) are provided (Fig. 3). 7. Arrangement according to claim 6, characterized in that for the mean frequency, f2, the fourth arms (L2 and L2 ") of the bridges (BI 'and B1") of the two bridge arrangements (I and II) each via a complex transformer ( T, _, T2 ) lead to another bridge (B22), the connecting lines differing by A, 2/4 (Fig. 3). B. Arrangement according to claim 6, characterized in that the pump frequency fp is supplied via a further bridge or branch (BP) , the arms (LP and LP ") of which are connected to the two bridge arrangements (1 and II) (Fig. 3 9. Arrangement according to claim 6, characterized in that the bridges (B2 ', B2 ", B22 and BP) are replaced by simple line branches, with one instead of the two transformers (T.'2 and T.; 2) only transformer (T22) in the line for the medium frequency (L20) is used (Fig. 3a). 10. Arrangement according to claim 6, characterized in that the two bridge arrangements (I and 1I of Fig. 3) are combined into a single bridge arrangement (I / II) and that the bridges for the middle (B22) and the pump frequency (BP) omitted, the pump frequency fp being fed directly into the single bridge arrangement (I / II) (FIG. 5). 11. The arrangement according to claim 7, characterized in that the fourth arm (L20 or L'0) of the bridge for the medium frequency (B22) is terminated with a pure reactance (Fig. 3). 12. The arrangement according to claim 7, characterized in that the fourth arm (L20 or Lz0) of the bridge for the middle frequency (B22) is omitted, so that a pure line branch is created. 13. Arrangement according to claim 6, 7, 11 or 12, characterized in that two amplifiers are connected in cascade (Fig. 4). 14. Arrangement according to claim 13, characterized in that the terminals (1, 1 ' and 2, 2') for the lowest, f1, and for the middle frequency, f2, of the amplifier are connected in series (Fig. 3). 15. The arrangement according to claim 13, characterized in that only the terminals (1 a 'and 1b) for the lowest frequency, f1, are connected in series, while the terminals (2a' and 2b) for the middle frequency, f2, each are terminated with a terminating resistor (Fig. 4). 16. The arrangement according to claim 13, characterized in that only the terminals (2a and 2b) for the mean frequency, f2, are connected (Fig. 4). 17. Arrangement according to one of the preceding claims, characterized in that the bridges in which the connecting lines have A / 4 detour loops are realized by 3-db directional couplers without A / 4 detour loops. Publications considered: IRE-Trans. ED-6 (1959), 2 (April), pp. 223, 224; Proc. IRE, 47 (1959), 4 (April), p. 583; 46 (1958), 6 (June), p. 1303.