RU199123U1 - The device for adding the powers of two generators of electrical oscillations - Google Patents

Abstract

The utility model relates to radio engineering and can be used in radio communication, in particular, in high-power broadband transistor HF radio transmitters. The device for adding the powers of two generators of electrical oscillations, contains two pieces of the same length of coaxial cable, located on separate ferrite cores, two ballast resistors. In this case, the second terminal of the first ballast resistor is connected to the common conductor, the second terminal of the second ballast resistor is connected to the output of the device, in addition, the end of the inner conductor of the second piece of coaxial cable is connected to the second generator input of the adder. The technical result is to simplify the device and improve the manufacturability of its manufacture. 4 ill.

Description

The proposed device relates to radio engineering and can be used in radio communication, in particular, in high-power broadband transistor radio transmitters in the HF range.

In modern high-power radio transmitters, the method of adding the power of individual transistor generators using bridge devices is widely used.

Known two-input bridge devices, which are used both independently and as part of more complex adders, made, for example, according to the binary principle [Combining units for a 1 kW wideband HF amplifier. Application Note AN98032. Philips Semiconductors. 1998 Mar 23.]. Various versions of such devices are obtained by converting the classical Winston bridge based on the principle of reciprocity, using additional transformers and phase-compensating lines, combining points that have the same potential, combining pairs of resistances of opposite arms into one using matched lines, as well as other methods [Addition and distribution devices power of high-frequency oscillations / V.V. Zaentsev, V.M. Katushkina, S.E. London, Z.I. Model; Ed. Z.I. Model. - M .: Sov. radio, 1980., London S.E., Tomashevich S.V. Handbook of high-frequency transformer devices. - M .: Radio and communication, 1984.].

Structurally, the adders are made of sections of transmission lines, which can be, for example, sections of a two-wire line, strip or coaxial cable, wound on ferrite cores.

For example, the adder bridge circuits made on one section of the transmission line are very simple [Grebennikov_2011, Shahgildyan_2003, AN749, Alekseev_1978].

In this case, bridge devices with a minimum number of transmission line segments, for example, adders with the addition of currents or voltages in the load, are not broadband enough, since their operating frequency band is limited from above by the phase incursion in the transmission lines, which should not exceed 7 ° [Design of radio transmitting devices: Textbook ... manual for universities / V.V. Shahgildyan, V. A. Vlasov, V.B. Kozyrev and others; Ed. V.V. Shahgildyan. - 3rd ed., Rev. and add. M .: Radio and communication, 1993 - 512 p.].

At the same time, among bridge devices, there are circuits for adding the powers of two generators, in which the phase incursion in the transmission lines is not a factor limiting the upper operating frequency.

Such a property is possessed by circuits that are circuits of a non-minimum-phase type, a feature of which is the presence of two or more signal paths. One of these channels contains the payload, the other contains the ballast resistor. In this case, the inputs of the adder are mutually decoupled [Generators of high and ultrahigh frequencies: Textbook. allowance / O.V. Alekseev., A.A. Golovkov, A.V. Mitrofanov and others - M .; Higher. shk., 2003. - 326 p.].

The electrical decoupling property means that, subject to the conditions of the balance of the bridge circuit, the currents of one of the generators flowing through the load and decoupling circuits must be mutually compensated at the terminals of the other generator, thereby not creating a voltage at these terminals, as a result of which the generators operate independently of each other. ...

In the event that all sections of transmission lines have the same length and are matched (loaded on resistances equal to the wave), then regardless of their length, the generators will be matched and decoupled from each other, and the lower operating frequency of the adder will be determined by the value of the longitudinal inductance of the line segments transmission, placed on ferrite cores, and the upper operating frequency will be infinitely high [S.E. London. A device for adding the powers of generators of electrical oscillations, and.with. USSR No. 543144, Devices for adding and distributing the power of high-frequency oscillations / V.V. Zaentsev, V.M. Katushkina, S.E. London, Z.I. Model; Ed. Z.I. Model. - M .: Sov. radio, 1980., patent US 4774481, A. V. Grebennikov, V. V. Nikiforov, A. B. Ryzhikov. Powerful transistor amplifier modules for VHF FM and TV broadcasting // Electrosvyaz. –1996. - No. 3. - S. 28–31., Andrei Grebennikov. Power Combiners, Impedance Transformers and Directional Couplers. High Frequency Electronics. December 2007.].

The closest analogue in technical essence to the proposed one is a bridge power combiner for two generators, presented in US patent 4774481, taken as a prototype.

A diagram of the prototype device is shown in Fig. 1, where it is indicated:

1, 2, 3, 4 - the first, second, third and fourth pieces of coaxial cable, located on separate ferrite cores;

1.1, 1.2 - inner conductor and braid of the first piece of coaxial cable;

2.1, 2.2 - inner conductor and braid of the second piece of coaxial cable;

3.1, 3.2 - inner conductor and braid of the third piece of coaxial cable;

4.1, 4.2 - inner conductor and braid of the fourth piece of coaxial cable;

n, k - the beginning and end of the inner conductor and braid of each piece of coaxial cable;

R1, R2 - ballast resistors.

The prototype device contains four pieces of coaxial cable 1-4 of the same length, which are located on separate ferrite cores, and two ballast resistors R1 and R2. In this case, the inner conductors of the coaxial cable segments 1 - 4 are designated 1.1, 2.1, 3.1 and 4.1, and the braids of the indicated coaxial cable segments are 1.2, 2.2, 3.2 and 4.2, respectively. The beginnings and ends of the inner conductors and braids of the coaxial cable segments 1 - 4 are designated by the letters "n" and "k", and the beginning of the inner conductor 1.1 of the coaxial cable segment 1 is connected to the first generator input of the adder Bx. 1, the end of the inner conductor 1.1 of the first piece of coaxial cable 1 is connected to the end of the inner conductor 4.1 of the fourth piece of coaxial cable 4 and one terminal of the ballast resistor R2, the other terminal of which is connected to the ends of the inner conductors 2.1 and 3.1 of the second 2 and third 3 pieces of coaxial cable. The beginning of the braid 3.1 of the third piece of coaxial cable 3 is connected to the second generator input of the adder Bx. 2, and the beginning of the inner conductor 2.1 of the second piece of coaxial cable 2 is connected to the output of the adder Out. and with the beginning of the inner conductor 4.1 of the fourth piece of coaxial cable 4.

In addition, one terminal of the ballast resistor R1 is connected to the end of the braid 3.2 of the third piece of coaxial cable 3, connected to the end of the braid 4.2 of the fourth piece of coaxial cable 4, and the beginning of the braid 3.2 of the third piece of coaxial cable 3 and the beginning of the braid 4.2 of the fourth piece of coaxial cable 4 are connected to common ("earth") conductor. The other terminal of the ballast resistor R1 is connected to the end of the braid 1.2 of the first piece of coaxial cable 1, connected to the end of the braid 2.2 of the second piece of coaxial cable 2, and the beginning of the braid 1.2 of the first piece of coaxial cable 1 and the beginning of the braid 2.2 of the second piece of coaxial cable 2 are connected to a common (" earthen ") conductor.

The prototype device works as follows.

In the matched mode, the equal-amplitude and common-mode signals of the generators are fed to the first and second generator inputs of the adder Bx. 1 and Bx. 2 and propagate, respectively, along four sections of coaxial cable 1 - 4 to the output of the adder, and are summed up in the load of the adder without reflections if the load resistance of the adder is equal to the characteristic impedance of each of the sections of coaxial cables 1 - 4, while the potentials at the terminals of the ballast resistors R1 and R2 are the same, and power is not transferred to ballast resistors R1 and R2.

Changing the amplitudes and phases of signals arriving at the generator inputs of the Bx adder. 1 and Bx. 2, leads to redistribution of signals between the load of the adder connected to its output. and ballast resistors R1 and R2. In the worst case, for example, when one of the generators is turned off, half of the power of the second operating generator is transferred to the adder load, and the other half of this power is transferred to ballast resistors R1 and R2 and dissipated in them.

The disadvantage of the prototype device is a large number of winding units made of pieces of coaxial cable located on separate ferrite cores.

The objective of the proposed technical solution is to reduce the number of winding units in the device, made of coaxial cable sections located on separate ferrite cores, which simplifies the device and increases its manufacturability.

To solve the problem in the device for adding the powers of two generators of electrical oscillations, containing two pieces of coaxial cable of the same length, located on separate ferrite cores, and two ballast resistors, while the beginning of the inner conductor of the first piece of coaxial cable is connected to the first generator input of the adder, the end the inner conductor of the first length of coaxial cable is connected to the second terminal of the second resistor, the first terminal of which is connected to the end of the inner conductor of the second length of coaxial cable, the beginning of which is connected to the output of the adder; the first terminal of the first ballast resistor is connected to the end of the braid of the first piece of coaxial cable and to the end of the braid of the second piece of coaxial cable, and the beginning of the braid of the first piece of coaxial cable and the beginning of the braid of the second piece of coaxial cable are connected to a common conductor, according to the utility model, the second terminal of the first ballast resistor is connected to a common conductor, the second terminal of the second ballast resistor is connected to the output of the device, in addition, the end of the inner conductor of the second piece of coaxial cable is connected to the second generator input of the adder.

FIG. 2 shows a diagram of the proposed device, where it is indicated:

1, 2 - the first and second pieces of coaxial cable;

1.1, 1.2 - inner conductor and braid of the first piece of coaxial cable;

2.1, 2.2 - inner conductor and braid of the second piece of coaxial cable;

R1, R2 - the first and second ballast resistors;

n, k - the beginning and end of the inner conductor and braid of a piece of coaxial cable.

The proposed device (adder) contains two equal lengths of coaxial cable 1 and 2, located on separate ferrite cores, and two ballast resistors R1 and R2. The beginning of the inner conductor 1.1 of the first piece of coaxial cable 1 is connected to the first generator input of the Bx adder. 1, the end of the inner conductor 1.1 of the first piece of coaxial cable 1 is connected to the output of the adder V, the beginning of the inner conductor 2.1 of the second piece of coaxial cable 2 and the second terminal of the second ballast resistor R2, the first terminal of which is connected to the second generator input of the adder Bx. 2 and with the end of the inner conductor 2.1 of the second piece of coaxial cable 2. The first terminal of the first ballast resistor R1 is connected to the end of the braid 1.2 of the first piece of coaxial cable 1 and to the end of the braid 2.2 of the second piece of coaxial cable 2, and the beginning of the braid 1.2 of the first piece of coaxial cable 1 and the beginning of the braid 2.1 of the second piece of coaxial cable 2 is connected to a common ("ground") conductor. The second terminal of the first ballast resistor R1 is connected to a common ("ground") conductor,

The proposed device works as follows.

In the matched mode, the equal amplitude and common-mode signals of the generators are fed to the first In. 1 and second In. 2 generator inputs of the adder and propagate respectively along the first 1 and second 2 sections of coaxial cables and to the output of the adder, are summed in the adder load without reflections if the adder load resistance is equal to the characteristic impedance of each of the coaxial cable sections 1 and 2, while the potentials at the ballast terminals resistors R1 and R2 are the same, and power is not transferred to ballast resistors R1 and R2.

Changing the amplitudes and phases of signals arriving at the generator inputs of the Bx adder. 1 and Bx. 2, leads to redistribution of signals between the load of the adder connected to its output. and ballast resistors R1 and R2. In the worst case, for example, when one of the generators is turned off, half of the power of the second operating generator is transferred to the adder load, and the other half of this power is transferred to ballast resistors R1 and R2 and dissipated in them.

The VSWR of the inputs of the adder σ and the degree of their isolation ξ are the most important characteristics of the bridge device. For practical use, it is considered sufficient to provide in the operating frequency range of σ ≤ 1.2 and ξ ≥ 20 dB [Design and technical operation of radio transmitting devices / M.A. Sievers, G.A. Zeytlenok, Yu.B. Nesvizhsky and others: Textbook. manual for universities. - M .: Radio and communication, 1989. Broadband radio transmitting devices (Radio frequency paths on semiconductor devices) / Alekseev OV, Golovkov AA, Polevoy VV, Soloviev AA; Ed. O. A. Alekseeva. - M .: Communication, 1978.]. These values, which determine the range properties in the proposed device, depend on the magnitude of the phase incursion in the sections of the coaxial cable. So, for example, with the length of these segments in the proposed device 680 mm, the decoupling value ξ is 21 dB (Fig. 3), and the VSWR of the adder inputs σ does not exceed 1.2 (Fig. 4), which makes it possible to recommend the use of such a device in transistor power amplifiers HF radio transmitting devices.

Thus, by eliminating two transformers and changing the circuit for switching on ballast resistors, the number of winding units is reduced, which leads to a simplification of the device and an increase in the manufacturability of its manufacture.

Claims (1)

A device for adding the powers of two generators of electrical oscillations, containing two pieces of coaxial cable of the same length located on separate ferrite cores, and two ballast resistors, while the beginning of the inner conductor of the first piece of coaxial cable is connected to the first generator input of the adder, the end of the inner conductor of the first piece of coaxial the cable is connected to the second terminal of the second resistor, the first terminal of which is connected to the end of the inner conductor of the second length of the coaxial cable, the beginning of which is connected to the output of the adder; the first terminal of the first ballast resistor is connected to the end of the braid of the first piece of coaxial cable and to the end of the braid of the second piece of coaxial cable, and the beginning of the braid of the first piece of coaxial cable and the beginning of the braid of the second piece of coaxial cable are connected to a common conductor, characterized in that the second terminal of the first ballast resistor is connected to a common conductor, the second terminal of the second ballast resistor is connected to the output of the device, in addition, the end of the inner conductor of the second piece of coaxial cable is connected to the second generator input of the adder.

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