RU62313U1 - OCTA FILTER - Google Patents

Abstract

The utility model relates to the field of electronics and can be used in ship radio transmitters of high power. The technical result achieved by the utility model is to increase the reliability of the octave filters by increasing the frequency tuning resource of high-power broadband radio transmitters. To this end, magnetization windings of octave filter inductor coils and, connected to these windings, a direct current generator are additionally introduced into the known device. 1 ill.

Description

The utility model relates to radio electronics, namely to broadband power amplifiers, and can be used in ship's radio transmitters.

Broadband power amplifiers, as a rule, have overlap coefficients in the range significantly greater than an octave, i.e. more than 2. For example, a power amplifier in the range of 1.5-30.0 MHz has an overlap factor of 20 and includes 5 octaves (1.5-3.0 MHz, 3.0-6.0 MHz, 6.0-12 , 0 MHz, 12.0-24.0 MHz, 24.0-30.0 MHz).

High-power broadband amplifiers currently use mechanical switching switches to switch octave filters. With the active introduction in recent years of communication channels with frequency adaptation, mechanical switches no longer satisfy the requirements for the resource of their switching. There are no solid-state switching elements that satisfy the requirements for switching high-frequency RF energy without distorting the RF signal and introducing noise.

Various devices are known comprising tunable filters. So, for example, an automatically tunable filter is known, US Patent No. 371569, H 03 H 7/10, which contains an electromechanical drive.

Known low-pass filter with adjustable passband A.S. USSR No. 425311, N 03 N 7/10, which contains a heat-sensitive bridge with a heating resistor.

Known filter with switchable bandwidth EP No. 0099040, N 03 N 7/01.

In the circuit of this filter, diodes are included to the end terminal of the inductance and to the outlet from the middle part of the inductance, which open or close with a high or low voltage supplied to them, thereby changing the inductance value and, as a consequence, the filter boundary frequency.

The disadvantage of analogues and prototype is that they have either mechanical switching elements with a limited switching resource, or solid-state switching elements that do not meet the requirements for the output elements of high-power radio transmitters in terms of limiting values of voltage currents and operating range.

The purpose of the utility model is to increase the reliability of octave filters by increasing the switching resource of octave filters of powerful broadband radio transmitters.

This goal is achieved by the fact that in an octave filter containing a filter for attenuation of harmonics of the carrier frequency, additionally magnetizing windings are placed on the cores of the filter inductors, while the DC generator is turned on, and the magnetizing windings are connected

with the outputs of the DC generator to which the control circuit is connected.

The block diagram of the device is shown in FIG. In accordance with it, the device consists of the following functional units:

1 - octave filter; 2 - DC generator.

The operation of the circuit is as follows. Information V.Ch. the signal at the carrier frequency from the broadband power amplifier is fed to the input of an octave filter, which is transparent to the carrier frequency and opaque to harmonics, because Harmonic frequencies exceed the cutoff frequency of the octave filter. When switching to another operating frequency, the nominal value of which lies in the adjacent octave, a signal is sent to the DC generator via the control circuit to change the magnitude of the bias current. As a result of a change in the magnetization current, the values of the inductances in the octave filter change by 4 times, which will lead to a change in the cutoff frequency of the octave filter by 2 times in accordance with the analytical expression for the cutoff frequency.

As a result, the transparency band of the octave filter will correspond to the octave adjacent to the previous band, and will be transparent to the newly set operating frequency and opaque to its harmonics.

Such stringent requirements as the octave filter switch are not imposed on the switch mode of operation of the DC generator, since it is not affected by V.Ch. signal of high power, so it can be performed on solid-state elements and controlled, for example, by changing the locking voltage of the diodes or transistors.

The continued use of mechanical switches for switching octave filters in high-power radio transmitters hinders the implementation of promising communication channels with frequency adaptation. The proposed switching scheme of these filters will solve this problem and make wider use of promising forms of communication that require frequent tuning of the operating frequency.

Claims (1)

An octave filter containing a carrier frequency harmonic attenuation filter, characterized in that in addition to the cores of the filter inductance coils there are magnetizing windings and a DC generator is turned on, and the magnetizing windings are connected to the outputs of the DC generator to which the control circuit is connected.