SU1085001A1 - Multichannel filter - Google Patents

Description

The invention relates to radiotechnology and can be used both to solve the problem of dividing a broadband channel into several narrowband channels and to solve an inverse problem in meter and decimeter wavelengths, for example, when constructing adders to work together on one antenna without mutual influence on each other several VHF FM transmitters having different carrier frequencies.

A multichannel filter is known, consisting of five band-pass filters connected in parallel to a common transmission path, each of which is formed by two coaxial resonators interconnected by a length of transmission lines, a quarter wavelength at the frequency of the corresponding transmission channel 11.

The known filter has a simple construction scheme, however, the reactive nature of the input impedance and its inconsistency in the frequency band of the transmission channels does not allow the use of filters constructed according to this scheme without increasing the number of resonant elements in each of the channels in conditions where it is necessary to ensure high inputs and high matching from each of them in the frequency band and each transmission channel with a small relative separation between the carrier frequencies.

The increase in the number of resonant elements leads to the complexity of the design of channel filters and reduce their efficiency.

The closest to the technical essence of the present invention is a multi-filter filter containing H channels, where 3, 4 ..., each of which consists of a three-junction bridge, the first and second outputs of which are connected to the first and second band-pass filters, to the third output - ballast load 2,

A disadvantage of the known multi-channel filter is that its construction scheme is rather complicated, as a result of which the construction is rather cumbersome: the total number of bridges is equal to twice the number of channels to be divided.

The aim of the invention is to simplify the design of the filter.

The goal is achieved by the fact that in a multi-channel filter containing N channels, where, 3,4 ..., each of which consists of a three-digit bridge, the first and second outputs of which are connected to the first and second band-pass filters, and to the third output - the ballast load, the outputs of the first band-pass filters of all channels and the outputs of the second band pass filters of all channels are connected respectively to the first and second inputs of the input three-dowel bridge via line segments and equal length for each channel.

The drawing shows the scheme of the multichannel filter.

The multichannel filter consists of N channels containing three-digit bridges 1–4, and output three-digit axle 5, band-pass filters 6–9, n types of junctions 10 and 11, and ballast loads 12.

The device works as follows.

The transmitter signal of frequency f, connected to the first input of the three-bridge bridge 1, is divided by the latter between the outputs of bridge 1 into equal parts. In this case, the phase of the voltage of the signal at the first output of bridge 1 lags behind the phase of the voltage of the signal at the second output of. Filters 6, which are tuned to the passage of the frequency signal {, ensure that each of its parts can unimpededly pass to the type of joints 10 and 11 without disturbing the phase difference of the voltages created by bridge 1. Filters 7-9, being tuned, to pass through signals of frequencies f / --- / 4, respectively, for a signal of frequency i - represent a significant reactance. Therefore, the signal of frequency f, having almost completely reflected from the indicated resonant elements, propagates back to the n-type joints 10 and 11. Reflected from the filters 7-9, the signal of the frequency f., From the n-type joints 10 and 11, propagates in the direction of the output Bridge 5, and in the direction of the outputs of the bridge 1.

The undesirable reflection of the energy of the frequency signal towards bridge 1, which leads to a decrease in efficiency when the signal passes through this frequency due to its absorption by the ballast load 12 of bridge 1, can be completely eliminated if the lengths of the transmission lines between each of the n articular junctions 10 and 11 and the filters 7–9 select ta1 “, so that at frequency C., the sum of the reactivities reduced to the articulation points of the transmission lines would be zero.

When this condition is fulfilled, the type pole joint is matched from the side of the input signal of frequency f. Output bridge 5 provides the addition of both parts of the signal power of frequency i, post3 1085001

who drank at his entrances. Those minor devices provide the sleepy portions of the signal power with the local operation per antenna of a number f, which penetrate the filter transmitters having different carriers 7–9, are absorbed by the ballast loading Frequencies.

us 12 input bridges 2-4. Similarly, in comparison with the well-known preferred image, the signal of each of the frequencies of the 5th device is designed structurally prf2 4 brought to the input of my device and allows you to increase the transition

Commodities 2–4, respectively, the relaxation between the separated canapole load, (antenna) is highlighted. Prepositions

Claims (1)

MULTI-CHANNEL FILTER containing H channels, where N = 2,3,4 ..., each of which consists of a three-decibel bridge, the first and second outputs of which are connected to the first and second band-pass filters, and to the third output - ballast load, characterized in that, in order to simplify the design of the filter, the outputs of the first bandpass filter of all channels and the outputs of the second bandpass filter of all channels are connected respectively to the first and second inputs of the input