RU2685978C1 - Radio transmitter adjustable harmonic filter - Google Patents

Abstract

FIELD: radio equipment.SUBSTANCE: invention relates to the field of radio equipment, and can be used in the wide-band radio transmitters power amplifiers harmonic filters. In its middle part the radio transmitter harmonics adjustable filter contains N middle inductance coils, where N is the number of frequency subranges, the first adjustable capacitor, connected to the each middle inductance coil first output by means of one of the N first switches, the second adjustable capacitor connected to the each middle inductance coil second output by one of the N second switches, N input L-shaped links, each of which consists of two inductance coils, which connection point is connected to the corresponding middle inductance coil first output, and N output L-shaped links, each of which consists of two inductance coils, which connection point is connected to the corresponding inductance middle coil second output, at that, each of the input L-shaped link input is connected to the harmonic filter input connector through the corresponding input switch, and each of the output L-shaped link output is connected to the harmonic filter output connector through the corresponding output switch, at that, the N first additional capacitors are additionally introduced, each of which is connected between the corresponding middle inductance coil first output and common bus, and N second additional capacitors, each of which is connected between the corresponding middle inductance coil second output and the common bus, at that, in parallel to each of the first and second additional capacitors one of 2N additional switches is connected.EFFECT: technical result consists in expansion of the radio transmitter adjustable harmonics filter operational capabilities with simultaneous reduction in the transmitted signal harmonic components level.1 cl, 1 dwg

Description

The invention relates to the field of radio and can be used in the harmonic filters of power amplifiers of wide-band radio transmitters.

For the transmission of high-frequency signals with harmonic components suppressed to the required level in the harmonic filters of short-wave transmitters, low-pass filters (LPF) are usually used [1]. Based on the requirements for filtering higher harmonics, starting from the second, the filters are projected to the specified attenuation value in the delay band. In this case, the frequency overlap ratio of the subbands is usually chosen in the range 1.4 ... 1.8, that is, for a shortwave transmitter that covers the frequency range 1.5 ... 30 MHz, you need nine to five filters, respectively, and the smaller the number of filters, the their structure is more complicated. Sub-band filters are switched, as a rule, with the help of relays connected to the input and output of each filter.

The main disadvantages of harmonic filters based on switchable low-pass filters are the difficulty in setting up, as well as the need for high precision manufacturing of inductors and the use of capacitors with small deviations of capacitance from nominal values, that is, more expensive. Otherwise, it is not possible to provide the necessary level of harmonic filter matching, since the traveling-wave coefficient (KBV) at the input of the harmonic filter is most sensitive to the accuracy of its adjustment. In addition, harmonic filters based on switchable low-pass filters have, as a rule, large overall dimensions and mass. This problem is exacerbated with an increase in the power of the transmitted signal, since the dimensions of the inductors increase in proportion to the increase in the current passing through them.

A more rational problem of harmonizing the harmonic filter and reducing its overall dimensions and mass can be solved by using not tunable low-pass filters, but band-tunable filters that provide matching not in the entire wide passband of the low-pass filter, but only at the frequency of the transmitted signal and at nearby frequencies. Such a device, presented in [2], was chosen as a prototype as the closest in technical essence to the claimed one.

Analysis of the prototype showed that it has limitations on the power of the transmitted signal in those cases when it is required to ensure the signal power at the transmitter output equal to 20 kW and more. These limitations arise primarily due to an excessively large amount of current flowing through the contacts of the switches, and above all those used in variable capacitors. In addition, vacuum relays used for switching subbands, designed for such power, do not have a third contact, which closes the input and output of the filter in each non-operating subband to the common bus, which leads to an increase in the level of the harmonic components of the transmitted signal due to their passage to the filter output harmonics through the capacitance of the open contacts of the relay non-working subranges.

The objective of the invention is the expansion of the operational capabilities of the tunable filter of the harmonics of the radio transmitter while reducing the level of the harmonic components of the transmitted signal.

This problem is solved by the fact that the tunable filter of the harmonics of the radio transmitter, containing in its middle part N average coils, where N is the number of frequency subranges, the first variable capacitor connected to the first output of each middle inductor using one of the N first switches, the second variable capacitor connected to the second output of each middle inductor using one of the N second switches, N input L-shaped links, each of which consists of two inductors, the connection point of which is connected to the first output of the corresponding average inductor, and N output L-shaped links, each of which consists of two inductors, the connection point of which is connected to the second output of the corresponding average inductance, and the input each input L-shaped link is connected to the input connector of the harmonic filter through the corresponding input switch, and the output of each output L-shaped link is connected to the output connector he harmonic filter through the corresponding output switch, with the first and second variable capacitors each made in the form of a set of capacitors, switched using the control device, introduced N first additional capacitors, each of which is connected between the first output of the corresponding average inductor and common bus, and N second additional capacitors, each of which is connected between the second output of the corresponding average inductance coil and the common bus, while parallel flax each of the first and second additional capacitor connected to one of 2N additional switches.

The figure shows the scheme of the claimed device in the initial state. Tunable harmonic filter of a radio transmitter, which contains in its middle part N medium inductors 1, where N is the number of frequency subranges, the first variable capacitor 2 connected to the first output of each middle inductor by one of the N first switches 3, the second capacitor 4 variable capacitance connected to the second output of each middle inductor using one of the N second switches 5, N input L-shaped links 6, each of which consists of two inductor coils the connection point of which is connected to the first output of the corresponding average inductance coil, and N output L-shaped links 7, each of which consists of two inductors, the connection point of which is connected to the second output of the corresponding average inductance, and the input of each input G -shaped link 6 is connected to the input connector 8 of the harmonic filter through the corresponding input switch 9, and the output of each output L-shaped link 7 is connected to the output connector 10 of the harmonic filter the corresponding output switch 11 is cut, while the first 2 and second 4 variable capacitors are each made as a set of capacitors switched by the control unit 12. N first additional capacitors 13 are inserted into the harmonic filter, each of which is connected between the first output of the corresponding middle coil inductance and common bus, and N second additional capacitors 14, each of which is connected between the second output of the corresponding average inductance coil and common bus, with a pair Allelicly to each of the first and second additional capacitors is connected one of the 2N additional switches 15 with the contacts closed in the initial state.

Tunable harmonic filter of the radio transmitter works as follows.

The output signal of the transmitter power amplifier together with the harmonic components of the signal is fed to the input 8 of the harmonic filter, previously switched on and tuned to the signal frequency. The frequency of the main signal is in the frequency band of one of the subbands, therefore, using the control device 12, the input 9 and output 11 switches corresponding to the included subband are turned on, as well as the corresponding additional switches 15, whose normally closed contacts open in this case. In this case, the first 2 and second 4 capacitors of variable capacitance are connected to the corresponding middle inductor 1 through the corresponding first 3 and second 5 switches. Capacitors 2 and 4 of variable capacitance using the control device 12 pre-set the values of the capacitances, which ensure the adjustment of the harmonic filter at a given frequency. As a result, the signal passes to the output 10 of the harmonic filter through the corresponding input L-shaped link 6, the middle inductance 1 and the output L-shaped link 7 with minimal losses and maximum KBV at the tuning frequency. In this case, thanks to additional switches 15, closing the first and second pins of the middle inductor in each disconnected sub-band, the harmonic filter provides increased attenuation at the harmonic frequencies of the transmitted signal.

Compared with the prototype, the declared harmonic filter with the same power of the transmitted signal provides less current flowing through the contacts of switches used in variable capacitors, as well as reducing the current flowing through the contacts of switches 3 and 5. This result is due to the presence of constantly connected first 13 and second 14 additional capacitors, diverting a certain part of the current flowing through these contacts and through switchable capacitors, to themselves. The capacitors 13 and 14, together with the initial capacitances of the capacitors 2 and 3 of variable capacitance, respectively, in their initial state, provide the initial setting of the sub-band filter to the maximum frequency of the included sub-band. In this case, the contacts of the switches 3 and 5, corresponding to this sub-range, are closed, and the contacts of the switches in the capacitors 2 and 4 of variable capacitance are open. It can be noted that the placement of additional capacitors 13 and 14 directly in the subband filter plays a positive role in shaping the characteristics of the harmonic filter at the upper frequencies of each subband, which reduces the influence of parasitic design factors on the harmonic filter parameters at these frequencies. When reconstructing the harmonic filter within the included frequency subband, the total capacitance of each variable capacitor is determined by the following expression:

,

,

where F _B is the maximum frequency of the included frequency subband;

F ₀ is the frequency of harmonic filter settings;

С ₀ - the minimum total capacity of the constantly switched on additional capacitor and the corresponding variable capacitor, in which at F ₀ = F _B all capacitors are disconnected.

The declared tunable filter of the radio transmitter harmonics is a set of N band-tunable filters (PPF) with an asymmetric amplitude-frequency characteristic (AFC) approaching the shape of the frequency response of the low-pass filter, that is, the attenuation in the delay band to the right of the tuning frequency is much greater (tens of dB) attenuation in the delay band to the left of the tuning frequency. Each FPS is rebuilt in the corresponding frequency range. The claimed harmonic filter provides matching across the entire operating frequency range at any of the tuning frequencies and, as a result, reducing the attenuation of the signal. At the same time, the harmonic filter provides increased selectivity, and due to the asymmetric frequency response of the switched on PPF, approaching the shape of the frequency response of the low-pass filter, the level of the harmonic components of the signal at the output of the harmonic filter is quite low. At the same time, the amplitude of the third harmonic of the signal at the AFP frequency response is approximately 20 dB less than the amplitude of the second harmonic, which compensates for the inverse ratio of the levels of these harmonics at the output of the power amplifier (PA) and when the harmonic filter is connected to the PA, the levels of the second and third harmonic components of the output signal filter harmonics become approximately equal. In addition, the claimed harmonic filter, compared to conventional harmonic filters based on switchable low-pass filters, provides an exception to the time-consuming tuning of the harmonic filter during its manufacture. Tuning is carried out programmatically in automatic mode until the maximum KBV value is obtained at each tuning frequency specified with a certain step. The tuning results are stored in the control device and used during operation of the harmonic filter in the transmitter.

Information sources:

1. Radio transmitting devices: Textbook for universities / V.V. Shahgildyan, V.B. Kozyrev, A.A. Lyakhovkin and others; Ed. V.V. Shahgildyan. - 3rd ed., Pererab. and add. - M: Radio and communications, 2003. - p.205 ... 208.

2. Patent RU 2538299, IPC H03H 9/00. Harmonic filter shortwave transmitter / A.G. Zinoviev, A.V. Bogdanov. - Declared 04/01/2013; published 01/10/2015, Bull. №1.

Claims (1)

Tunable radio harmonic filter containing in its middle part N medium coils, where N is the number of frequency subbands, the first variable capacitor connected to the first output of each middle inductor using one of the N first switches, the second variable capacitor connected to the second output of each middle inductor using one of the N second switches, N input L-shaped links, each of which consists of two coils inductively ti, the connection point of which is connected to the first output of the corresponding average inductance coil, and N output L-shaped links, each of which consists of two inductors, the connection point of which is connected to the second output of the corresponding average inductance coil, the figurative link is connected to the input connector of the harmonic filter through the corresponding input switch, and the output of each output L-shaped link is connected to the output connector of the harmonic filter through the corresponding The first output switch, each of the first and second variable capacitors, is made as a set of capacitors switched by a control device, characterized in that there are N first additional capacitors, each connected between the first output of the corresponding average inductance and the common bus, and N second additional capacitors, each of which is connected between the second output of the corresponding average inductor and the common busbar, with each parallel and One of the 2N additional switches is connected to the first and second additional capacitors.

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