RU184445U1 - Broadband device of addition of power of HF generators of electric oscillations - Google Patents

Abstract

The utility model relates to radio engineering and can be used in radio communications, in particular, in powerful broadband transistor radio transmitting devices. The technical result is an extension of the operating range of the adder to the upper frequencies. To do this, in the broadband device for adding power to RF oscillators of electrical oscillations, the beginning of the braid (1.2) of the first The length of the coaxial cable is connected to the end of the braid (2.2) of the second segment of the coaxial cable, the beginning of which is connected to the end of the braid (1.2) of the first segment of the coaxial cable. xial cable, while the ballast resistor (3) is connected between the connecting points of the beginning and end of the braids of the first (1.2) and second (2.2) lengths of coaxial cable, respectively, in addition, the ends of the inner conductors of the first (1.1) and second (2.1) lengths of coaxial cable combined and are the output of the device. 3 il.

Description

The utility model relates to radio engineering and can be used in radio communications, in particular in high-power broadband transistor radio transmitting devices.

In modern radio transmission devices of high power, the method of adding power to individual transistor generators using bridge devices has become widespread. If the conditions of the balance of the bridge circuit are observed, the currents of one of the generators are mutually compensated at the terminals of the other generator, without thereby creating a voltage on these terminals, with the result that the generators operate independently of each other.

The most important characteristics of bridge adders are the CWS of the σ inputs and the degree of their decoupling ξ. For practical use, it is considered sufficient to provide in the operating frequency range σ ≤ 1.2 and ξ ≥ 20 dB [Design and technical operation of radio transmitting devices / M.A. Sivers, G.A. Zeytlenok, Yu.B. Nesvizhsky et al .: 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, Solov'ev AA; Ed. O.A. Alekseeva. - M .: Communication, 1978.]

Structurally, the adders are made of segments of transmission lines, which can be, for example, segments of a two-wire line, a strip or coaxial cable, wound, if necessary, on ferrite cores, i.e. Transmission lines are used in the form of long line transformers.

Known device addition of two RF generators, made using two transformers of the type of long line, based on segments of coaxial cable [Broadband radio transmitting devices (RF paths on semiconductor devices) Alekseev OV, Golovkov AA, Polevoy VV, Solovyov A.A .; Ed. O.A. Alekseeva. - M .: Communication, 1978., Andrei Grebennikov, "RF AND MICROWAVE TRANSMITTER DESIGN". A JOHN WILEY and SONS. 2011 .; Devices of addition and distribution of high-frequency oscillation powers V.V. Zaentsev, V.M. Katushkina, S.E. London, Z.I. Model; Ed. Z.I. Model - M .: Owls. radio, 1980., Designing radio transmitters: Proc. manual for universities / V.V. Shahgildyan, V.A. Vlasov, V.B. Kozyrev and others; Ed. V.V. Shahgildyan. - 3rd ed., Pererab. and add. M .: Radio and communications, 1993 - 512 p., H. Granberg. BROADBAND TRANSFORMERS AND POWER COMBINING TECHNIQUES FOR RF. APPLICATION NOTE AN749, Motorola. 1993].

The closest analogue to the technical nature of the proposed is a bridge adder power of two generators, presented in [Degtyar GA Transformers in matching circuits and the addition of the power of radio frequency generators: Proc. allowance. - Novosibirsk: NSTU Publishing House, 2003. - 504 p. - (Series “NSTU Textbooks”), Fig.P.5.8.], Adopted for the prototype.

The layout of the prototype device is shown in FIG. 1, where indicated:

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

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

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

3 - ballast resistor;

n, k - the beginning and the ends of the inner conductors and braids of segments of coaxial cable.

The prototype device (adder) contains two coaxial cables 1 and 2 of the same length, which are located on separate ferrite cores, and a ballast resistor 3 (Fig. 1). Moreover, the beginning of the inner conductor 1.1 of the length of the coaxial cable 1 is connected to the first generator input of the adder, the end of the inner conductor 1.1 of the length of the coaxial cable 1 is connected to the end of the inner conductor 2.1 of the length of the coaxial cable 2 and the second output of the ballast resistor 3 is connected to the end of the braid 1.2 length of coaxial cable 1 and the end of the inner conductor 2.1 length of coaxial cable 2.

The beginning of the inner conductor 2.1 of the length of the coaxial cable 2 is connected to the second generator input, and the beginning of the braid 1.2 of the length of the coaxial cable 1 is connected to the output of the adder and the beginning of the braid 2.2 of the length of the coaxial cable 2.

The prototype device works as follows.

In the coordinated mode, the amplitude and in-phase signals of the generators are fed to the first and second generator inputs of the adder and are distributed respectively along the segments of coaxial cable 1 and 2 to the output of the adder, where they are summed up in the load of the adder without reflections if its resistance is equal to the characteristic impedance of each of the segments of the coaxial cable 1 and 2, while the potentials at the outputs of the ballast resistor 3 are the same, and the power is not transferred to the ballast resistor.

A change in the amplitudes and phases of the signals arriving at the generator inputs of the adder leads to a redistribution of signals between the load of the adder connected to its output and the ballast resistor 3. In the worst case, for example, when one of the generators is disconnected, half of the power of the second operating generator is transferred to the load of the adder and the other half of this power is transmitted to the ballast resistor 3 and dissipated in it.

The disadvantage of the device prototype is a low upper operating frequency, determined by the allowable value of the junction between the inputs of the adder ξ ≥ 20 dB

The objective of the proposed technical solution is the expansion of the working range of the adder in the upper frequencies.

To solve this problem in a broadband device for adding power to high-frequency electric oscillator, containing two coaxial cables of the same length, located on separate ferrite cores, as well as a ballast resistor, with the beginning of the inner conductors of the first and second segments of the coaxial cable connected to the first and second inputs accordingly, according to the utility model, the beginning of the braid of the first segment of the coaxial cable is connected to the end of the braid of the second segment of the coaxial about the cable, the beginning of which is connected to the end of the braid of the first segment of the coaxial cable, while the ballast resistor is connected between the junction points of the beginning and the end of the braids of the first and second segments of the coaxial cable, respectively, in addition, the ends of the inner conductors of the first and second segments of the coaxial cable are combined and are output devices.

The scheme of the proposed device is shown in FIG. 2, where indicated:

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

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

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

3 - ballast resistor;

n, k - the beginning and the ends of the inner conductors and braids of segments of coaxial cable.

The proposed device (adder) contains two identical along the length of the coaxial cable 1 and 2, which are located on separate ferrite cores, and a ballast resistor 3, with the beginning of the inner conductor 1.1 of the first segment of the coaxial cable 1 connected to the first generator input of the adder, the beginning of the inner conductor 2.1 The second segment of coaxial cable 2 is connected to the second generator input, the beginning of the braid 1.2 of the first segment of coaxial cable 1 is connected to the end of the braid 2.2 of the second segment coaxial th cable 2, the beginning of which is connected to the end of the first section 1.2 braid of the coaxial cable. In addition, the ballast resistor 3 is connected between the beginning of the braids of the first 1.2 and second 2.2 lengths of coaxial cables 1 and 2. The ends of the inner conductors of the first 1.1 and second 2.1 lengths of the coaxial cable 1 and 2 are connected to the output of the device.

The proposed device works as follows.

In the coordinated mode, the amplitude and in-phase signals of the generators are fed to the first and second generator inputs of the adder and are distributed respectively along the lengths of coaxial cable 1 and 2 to the output of the adder, where they are summed up in the load of the adder without reflections if its resistance is equal to the characteristic impedance of each of the transmission line segments 1 and 2, while the potentials at the outputs of the ballast resistor 3 are the same, and the power is not transferred to the ballast resistor.

A change in the amplitudes and phases of the signals arriving at both generator inputs of the adder leads to a redistribution of signals between the load of the adder connected to its output and the ballast resistor 3. In the worst case, for example, when one of the generators is disconnected, half of the power of the second operating generator is transferred to the load of the adder and the other half of this power is transmitted to the ballast resistor 3 and dissipated in it. In this case, the presence of a ballast resistor provides electrical isolation of the inputs of the adder.

FIG. 3. shows the dependence of the junction ξ between the inputs of the adder on the frequency (device-prototype - curve 1, the proposed device - curve 2).

As can be seen from FIG. 3 data in the proposed device, the frequency at which the isolation between the inputs of the adder ξ ≥ 20 dB is much higher than in the device-prototype.

Claims (1)

A broadband device for adding power of high-frequency oscillators of electric oscillations, containing two coaxial cables of equal length, located on separate ferrite cores, as well as a ballast resistor, with the beginning of the inner conductors of the first and second coaxial cable segments connected to the first and second inputs, respectively, differing in that the beginning of the braid of the first segment of the coaxial cable is connected to the end of the braid of the second segment of the coaxial cable, the beginning of which is connected to The braid of the first segment of the coaxial cable, the ballast resistor is connected between the connecting points of the beginning and end of the braids of the first and second coaxial cable, respectively, in addition, the ends of the inner conductors of the first and second coaxial cable are combined and output the device.