RU2683625C1 - Short-wave transmitter harmonic filter - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: harmonic filter of the short-wave transmitter contains in its middle part N medium inductor coils, the first and second variable capacitor, N input L-shaped links, containing in the longitudinal arm of the input inductor, N output L-shaped links, containing in the longitudinal arm an output inductor, with each input L-shaped link containing at the output in the transverse arm the first fixed capacitor, and each output L-shaped link contains, at the input in the transverse arm, a second constant capacitor, each middle inductor and its associated inductive coupling input and the output coils of the inductance of the corresponding input and output L-shaped links are made in the form of three cylindrical windings interconnected at a certain distance from each other, interconnected, however, the direction of winding of the middle inductor is opposite to the direction of winding of the input and output inductors of the corresponding input and output L-shaped links.

EFFECT: technical result is to increase the power of the transmitted signal while reducing the overall dimensions.

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Description

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

To transmit high-frequency signals with harmonic components suppressed to the required level in the harmonic filters of short-wave transmitters, low-pass filters (LPFs) are usually used [1]. Based on the requirements for filtering higher harmonics, starting from the second, the filters are designed for a given attenuation value in the delay band. In this case, the overlap coefficient of the sub-bands in frequency is usually chosen within 1.4 ... 1.8, that is, for a short-wave transmitter that covers the frequency range of 1.5 ... 30 MHz, nine to five filters are required, respectively, and the smaller the number of filters, the their structure is more complicated. Sub-band filters are switched, as a rule, by means of relays connected at the input and output of each filter.

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

More rationally, the problem of matching the harmonics filter and reducing its overall dimensions can be solved by taking not tunable low-pass filters as a basis, but tunable bandpass filters, and ensure matching only at the frequency of the transmitted signal. Such a device, presented in [2], is selected as a prototype as the closest in technical essence to the claimed one.

Analysis of the prototype showed that, despite a decrease in the number of frequency subbands to three in the frequency range from 1.5 to 30 MHz, it does not provide a sufficient reduction in overall dimensions, since five inductors are used in each subband. In addition, as shown by calculations, when tuning the harmonic filter to the lower frequency of each frequency subband, the current flowing through the capacitors increases significantly, and therefore through the contacts of the corresponding switches that turn these capacitors on. All of the above means that the prototype has limitations both in terms of the power of the transmitted signal and in terms of overall dimensions when it is increased. In addition, in the case of applying the corresponding increased signal power of vacuum relays and capacitors, the cost of the harmonics filter will also increase significantly.

The objective of the invention is the expansion of the operational capabilities of the harmonic filter in terms of increasing the power of the transmitted signal while reducing overall dimensions and simplifying the device.

This problem is solved by the fact that in the harmonic filter of the short-wave transmitter, containing in its middle part N medium inductors, 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, and a second capacitor of variable capacitance, connected to the second terminal of each middle inductor using one of the N second switches, as well as N input L-shaped links, each of which which contains in the longitudinal arm an input inductor connected to the first terminal of the corresponding middle inductor and connected inductively with it, and N output L-shaped links, each of which contains an output inductor in the longitudinal arm connected to the second terminal of the corresponding middle coil inductance and inductive coupling associated with it, while the input of each input L-shaped link is connected to the input connector of the harmonic filter through the corresponding input switch spruce, and the output of each output L-shaped link is connected to the output connector of the harmonic filter through the corresponding output switch, the first and second capacitors of variable capacitance made in the form of a set of capacitors switched using a control device, each input L-shaped link contains at the output the transverse arm the first capacitor of constant capacity, and each output L-shaped link contains at the input in the transverse arm of the second capacitor of constant capacity, with each middle coil in of inductance and associated inductance of the corresponding inductance coils of the input and output G-shaped links are made in the form of three cylindrical coils coaxially spaced at a certain distance from each other, the winding direction of the middle inductor opposite to the direction of winding the input and output coils output L-shaped links.

The figure shows a diagram of the claimed device in its original state. The harmonic filter of the short-wave transmitter contains in its middle part N middle coils 1, where N is the number of frequency subbands, a first capacitor 2 of variable capacitance connected to the first output of each middle coil 1 using one of the N first switches 3, and a second capacitor 4 variable capacitance, connected to the second terminal of each middle inductor 1 using one of the N second switches 5, as well as N input L-shaped links 6, each of which contains in a longitudinal plane another input inductor 7 connected to the first output of the corresponding middle inductor 1 and connected inductively with the mutual inductance M _i [3], where i = 1, 2, 3, ... N is the serial number of the frequency sub-range, and N output Г -shaped links 8, each of which contains in its longitudinal arm an output inductor 9 connected to the second terminal of the corresponding middle inductor 1 and connected with it by an inductive coupling with mutual inductance also equal to M _i . The input of each input L-shaped link 6 is connected to the input connector 10 of the harmonics filter through the corresponding input switch 11, and the output of each output L-shaped link 8 is connected to the output connector 12 of the harmonics filter through the corresponding output switch 13. The first 2 and second 4 variable capacitors the capacitance is made in the form of a set of capacitors switched using the control device 14. Each input L-shaped link 6 contains at the output in the transverse arm the first capacitor 15 of constant capacitance yhodnoe T-shaped element 8 comprises at the entrance to the transverse arm of the second capacitor 16 constant capacity. Each middle inductor 1 and associated inductive coupling input 7 and output 9 inductors of the corresponding input 6 and output 8 L-shaped links are made in the form of three cylindrical windings coaxially spaced at a certain distance from each other, while the direction winding the middle inductor 1 is opposite to the winding direction of the input 7 and output 9 coils of inductance of the corresponding input 6 of the output 8 of the L-shaped links. With a symmetric filter circuit, the harmonics of the inductance of the inductors 7 and 9 are equal to each other and equal to L _i , and the inductance of the corresponding average inductor 1 is 2L _i , while both mutual inductances are equal to each other and equal to M _i , where i = 1, 2, 3, ... N - serial number of the frequency sub-band.

The harmonic filter is a set of N tunable low-pass filters. Each filter is tuned in the corresponding i-th frequency sub-band using the first 2 and second 4 variable capacitors, with the capacity of each of which the capacitance of the corresponding first 15 and second 16 constant capacitors is added. As a result, each such total capacitance is equal to C. The harmonic filter tuning frequency is determined by the following expression:

the frequency of the attenuation pole is

The ratio of the attenuation pole frequency (2) to the harmonic filter tuning frequency (1) is

moreover, the value of K _p during adjustment does not change.

The harmonics filter of the short-wave transmitter operates as follows.

The output signal of the transmitter power amplifier, containing the harmonic components of the signal, is fed to the input 10 of a harmonic filter, previously turned on and tuned to the frequency of the signal. The frequency of the main signal is in the frequency band of one of the subranges, therefore, using the control device 14, the input 11 and output 13 switches corresponding to the included subband are turned on, and the first 2 and second 4 variable capacitors are connected to the corresponding middle inductor 1 through the corresponding first 3 and second 5 switches. On capacitors 2 and 4 of variable capacitance, using the control device 14, the capacitance values are pre-set, which ensure the harmonics filter is tuned to a given frequency. In this case, the capacitance values of the capacitors 15 and 16 of constant capacitance connected in parallel to the capacitors 2 and 4, respectively, are taken into account. As a result, the signal passes to the output 12 of the harmonic filter through the corresponding input L-shaped link 6, the middle inductor 1 and the output L-shaped link 8 with minimal losses and maximum KBB at the tuning frequency. And due to the presence of inductive coupling between the input inductor 7 of the input L-shaped link 6 and the middle inductor 1, and also due to the presence of inductive coupling between the output inductor 9 of the output L-shaped link 8 and the middle inductor 1, in the delay band of the included filter there is a pole attenuation with a given frequency, for example, equal to or close to the frequency of the third harmonic of the transmitted signal. The attenuation pole arises due to the fact that the inductively coupled inductors have a mutually opposite direction of winding, which ensures the opposite direction of their magnetic fluxes with the proposed mutual arrangement of the inductors. In this case, the inductors 7 and 9 are located relative to the corresponding average inductor 1 at a certain distance from it, which determines the magnitude of the inductive coupling between the inductors, on which the attenuation pole frequency and the level of suppression of harmonic components of the transmitted signal depend.

The claimed harmonic filter of the short-wave transmitter in comparison with the prototype has enhanced operational capabilities due to the reduction of almost a half times the current passing through the contacts of switches 3 and 5, as well as switches in the composition of capacitors 2 and 4 of variable capacity. In addition, constant capacitors 15 and 16 take on a part of the current load, providing, together with the initial capacitance of capacitors 2 and 4, the harmonic filter to be tuned to the maximum frequency in each frequency subband. As a result, the claimed harmonic filter with the same composition of component parts can be used in a radio transmitter with more than 20% increased output power. The overall dimensions of the claimed device compared to the prototype are reduced not only due to the reduction in the number of inductors by 40%, but also due to a more rational use of volume with the coaxial arrangement of inductively coupled inductors and the absence of shielding partitions. As well as the prototype, the claimed harmonic filter provides coordination in the entire range of operating frequencies at any of the tuning frequencies and, as a result, reduces the attenuation of the transmitted signal. Despite the fact that the basis of the claimed harmonic filter is a 5th order low-pass filter, and not the same order, bandpass filters (PF) as in the prototype, and the claimed device and prototype provide approximately the same level of attenuation of the harmonic components of the transmitted signal during tuning: not less 30 dB for the second harmonic, which is enough, given the level of its suppression in the power amplifier (PA), and more than 56 dB for all subsequent harmonics. In addition, in the claimed harmonic filter, the frequency (2) of the attenuation pole can be set equal to the frequency of the third harmonic of the signal, that is, to exclude the third, most powerful, harmonic from the transmitted signal. But more rational is the value of K _p (3), approximately equal to 3.5, since at the same time a very low level of the third harmonic is maintained, but the fifth and seventh harmonics are further weakened. In this case, the harmonic components of the signal with even serial numbers can be ignored, since they are already sufficiently suppressed in the PA. An additional distinguishing feature of the claimed harmonic filter compared to the prototype is that the value of K _p (3) is constant and does not depend on the frequency of tuning of the harmonic filter, thereby ensuring the identity of the characteristics of the claimed device during tuning. In addition, the claimed harmonic filter, in comparison with conventional harmonic filters based on switchable low-pass filters, eliminates the time-consuming operation of tuning the harmonic filter in its manufacture. The adjustment is carried out in a programmatic way in automatic mode until the maximum value of the KBM is obtained at each tuning frequency set with a certain step. The tuning results are stored in the control device and are used during the operation of the harmonic filter in the transmitter. With this tuning method, the use of capacitors in the harmonic filter with small deviations of the capacitance from the nominal values is not required.

Information sources:

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

2. Patent RU 2546309, IPC Н03Н 7/09. Harmonic filter of a short-wave transmitter / A.G. Zinoviev, A.V. Bogdanov. - Announced on March 25, 2014; published April 10, 2015, Bull. No. 10.

3. Handbook of Radio Engineering: Ed. B.A. Smirenin. - M., L .: Gosenergoizdat, 1950 .-- p. 54, 55.

Claims (7)

1. The harmonic filter of the short-wave transmitter, containing in its middle part N middle inductors, where N is the number of frequency subbands, a first capacitor of variable capacitance connected to the first output of each middle inductor using one of the N first switches, and a second variable capacitor connected to the second terminal of each middle inductor using one of the N second switches, as well as N input L-shaped links, each of which contains in the longitudinal arm an input inductance connected to the first terminal of the corresponding middle inductor and connected inductively to it, and N output L-shaped links, each of which contains in the longitudinal arm an output inductor connected to and connected to the second terminal of the corresponding middle inductance inductive coupling, while the input of each input Г-shaped link is connected to the input connector of the harmonic filter through the corresponding input switch, and the output of each output Г-о a single link is connected to the output connector of the harmonic filter through a corresponding output switch, the first and second capacitors of variable capacitance made in the form of a set of capacitors switched using a control device, characterized in that each input L-shaped link contains a first capacitor at the output in the transverse arm constant capacity, and each output L-shaped link contains at the input in the transverse arm of the second capacitor of constant capacity. 2. The harmonic filter of the short-wave transmitter according to claim 1, characterized in that each middle inductance coil and the input and output inductance coils of the corresponding input and output L-shaped links are made in the form of three coaxially spaced at a certain distance from each other by inductive coupling cylindrical windings interconnected, while the direction of winding the middle inductor is opposite to the direction of winding the input and output inductors of the corresponding inputs bottom and output L-shaped links. 3. The harmonic filter of the shortwave transmitter according to claim 1, characterized in that it is symmetrical, while in each frequency subband the ratio of the frequency of the attenuation pole to the tuning frequency is

where L _i is the inductance of the input and output inductors of the corresponding input and output L-shaped links; M _i - the mutual inductance between the middle inductor and the input and output coils of the inductance of the corresponding input and output L-shaped links; i is the serial number of the frequency subband, and the value of K _p during the harmonics filter tuning does not change.

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