RU2333596C2 - Multi-channel filter on surface acoustic waves - Google Patents

Abstract

FIELD: radio technology.

SUBSTANCE: invention pertains to wireless communication and can be used for selecting radio signals in input cascades of radio receiving devices. The multi-channel filter on surface acoustic waves has input and output terminals, input and output commutators, each of which consists of N switches on the number of filter channels, with their control inputs, frequency-selective unit with an amplifier, between the input and output commutators and consisting of N channels, each of which has input and output filters on surface acoustic waves, channel input and output switches with their control inputs, first and second group electric bus lines. The input terminal is connected to the inputs of the switch of the input commutator, and the output terminal is connected to the outputs of the switch of the output commutator. There are N-1 amplifiers in the frequency-selective unit. In each channel of the frequency-selective unit the input of the amplifier is connected to the output of the input filter on surface acoustic waves of the first group electric bus line, and the output of the amplifier is connected to the input of the output filter on surface acoustic waves of the second group electric bus line. The input of the channel input switch is connected to the output of the corresponding switch of the input commutator, and the output of the channel input switch is connected to the input of the output filter on surface acoustic waves. The input of the channel output switch is connected to the output of the output filter on surface acoustic waves, and the channel output switch is connected to the input of the corresponding switch of the output commutator. In that case the length of the first and second group electric bus lines does not increase with increase in the number of channels and the central frequency of the input and output filters on surface acoustic waves.

EFFECT: design of a multi-channel filter on surface acoustic waves, providing for lowering distortions of the amplitude-frequency response.

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Description

The invention relates to techniques for radio communication and can be used for selection of radio signals in the input stages of radio receivers.

Known multichannel filters made on LC circuits and consisting of a comb of switched filters at fixed center frequencies [1]. With known positive effects, these devices have the following disadvantages: insufficient selectivity, large dimensions and weight, low manufacturability and reliability.

The closest set of features to the claimed filter is a multi-channel filter on surface acoustic waves (SAW) [2] (Figure 1), having input 1 and output 2 terminals, input 3 and output 4 switches, each of which consists of N in number channels of the key filter 5 with its control inputs, a frequency-selective block 6 with an amplifier 7, located between the input 3 and output 4 switches and consisting of N channels, each of which contains input 8 and output 9 filters for SAW, channel input 10 and output 11 keys with its control inputs, and the input terminal 1 is connected to the key inputs 5 of the input switch 3, and the output terminal 2 is connected to the outputs of the keys 5 of the output switch 4, the input of the amplifier 7 is connected to the outputs of the channel input keys 10 by electric buses 12 of the first group, and the output of the amplifier 7 is connected to the inputs of the channel output keys 11 by electric buses 13 of the second group, in each channel of the frequency-selective block 6, the input of the channel input key 10 is connected to the output of the input filter 8 to the SAW, the input of which is connected to the output By the corresponding key 5 of the input switch 3, the output of the channel output key 11 is connected to the input of the output filter 9 on the SAW, the output of which is connected to the input of the corresponding key 5 of the output switch 4.

The known device, having good adaptability and reliability, has significant disadvantages. This is a deterioration in the shape of the amplitude-frequency characteristic (AFC) due to spurious reactances that appear as a result of an increase in the length of the electric buses 12, 13 of the first and second groups as the number of filter channels and the center frequencies of the input 8 and output 9 filters on the SAW increase.

The objective of the invention is the creation of a multi-channel filter on a surfactant, providing reduced distortion of the frequency response.

The essence of the invention lies in the fact that in a multichannel filter on a SAW having input and output terminals, input and output switches, each of which consists of N in the number of channels of the key filter with its control inputs, is a frequency-selective block with an amplifier located between the input and output switches and consisting of N channels, each of which contains input and output filters for SAWs, channel input and output keys with their control inputs, electrical buses of the first and second groups, and input the terminal is connected to the inputs of the keys of the input switch, and the output terminal is connected to the outputs of the keys of the output switch, N-1 amplifiers are introduced into the frequency-selective block, and in each channel of the frequency-selective block the input of the amplifier is connected to the output of the input filter on the SAW by the electric bus of the first group and the output of the amplifier is connected to the input of the output filter on the SAW by the electric bus of the second group, the input of the channel input key is connected to the output of the corresponding key of the input switch, and the output of the channel input one key is connected to the input of the input filter to the SAW, the input of the channel output key is connected to the output of the output filter to the SAW, and the output of the channel output key is connected to the input of the corresponding key of the output switch.

Figure 2 shows a multi-channel filter on a surfactant, an example implementation. The multi-channel filter has input 1 and output 2 terminals, input 3 and output 4 switches, each of which consists of N by the number of channels of the key filter 5 with its control inputs, a frequency-selective block 6 located between input 3 and output 4 switches and consisting from N channels, each of which contains input 7 and output 8 filters for SAW, channel input 9 and output 10 keys with their control inputs. The input terminal 1 is connected to the inputs of the keys 5 of the input switch 3, and the output terminal 2 is connected to the outputs of the keys 5 of the output switch 4. Each channel of the frequency-selective filter unit 6 contains an amplifier 11, and the input of the amplifier 11 is connected to the output of the input filter 7 on the SAW electric the bus 12 of the first group, and the output of the amplifier 11 is connected to the input of the output filter 8 on the SAW electric bus 13 of the second group, the input of the channel input key 9 is connected to the output of the corresponding key 5 of the input switch 3, and the output of the channel the input key 9 is connected to the input of the input filter 7 on the SAW, the input of the channel output key 10 is connected to the output of the output 8 filter on the SAW, and the output of the channel output key 10 is connected to the input of the corresponding key 5 of the output switch 4.

Each channel of the frequency-selective block 6 with its input 7 and output 8 filters for SAW, channel input 9 and output 10 keys, amplifier 11 can be made in a separate case in the form of a miniature module with minimal connecting conductors.

Multichannel filter works as follows.

In the initial state, the keys 5 of the input 3 and output 4 of the switches, channel input 9 and output 10 keys are in the open state. When a control signal is applied to the corresponding control inputs of keys 5 of input 3 and output 4 switches, channel input 9 and output 10 keys of the i-th channel, keys 5 of input 3 and output 4 switches, channel input 9 and output 10 keys of the i-channel closed state.

The input signal from the input terminal 1 through the corresponding corresponding key 5 of the input switch 3, the closed channel input key 9 is fed to the input 7 filter on the SAW with a central frequency f _i , where it passes the frequency selection and then through the electric bus 12 of the first group, amplifier 11, bus bar 13 of the second group, the output of the SAW filter 8 with a central frequency f _i, where he goes further frequency selection, closed channel output key 10, corresponding to a closed switch 5 the output switch 4 is supplied on the output terminal 2.

In the proposed multichannel SAW filter, in comparison with the known devices, N-1 amplifiers 11 are introduced into the frequency-selective block 6, and in each channel of the frequency-selective block 6, the input of the amplifier 11 is connected to the output of the input filter 7 on the SAW by the electric bus 12 of the first group, and the output of the amplifier 11 is connected to the input of the output filter 8 on the SAW electric bus 13 of the second group, the input of the channel input key 9 is connected to the output of the corresponding key 5 of the input switch 3, and the output of the channel input key 5 is connected to the input filter 7 to the SAW, the input of the channel output key 10 is connected to the output of the output filter 8 to the SAW, and the output of the channel output key 10 is connected to the input of the corresponding key 5 of the output switch 4. In this case, the length of the electric buses 12, 13 of the first and the second group as the number of channels and center frequencies of the input 7 and output 8 filters on the SAW increases. As a result, parasitic reactivity in the structure is reduced, which leads to a decrease in the frequency response distortion of a multichannel SAW filter.

The proposed technical solution was tested experimentally. The multi-channel filter covered the frequency range 186-216 MHz and contained 16 channels with SAW filters with a relative bandwidth level of 2 dB of about 1.5%. Surfactant filters are made on a YX / 128 ° LiNbO ₃ slice.

Unpacked p-i-n diodes 2A536-A5, 2A543-A5 were used as keys of the input and output switches, channel input and output keys. For the amplifier, miniature low-noise SiGe transistors SGA 8343 were used. Each channel of the frequency-selective block with its input and output filters on the SAW, channel input and output keys and amplifier was made in a separate 16 × 7 DLCC 10 / 10-1 surface-mounted housing , 3 × 2.6 mm in the form of a miniature module with minimal connecting conductors, in particular, with minimal lengths of busbars of the first and second groups. The overall dimensions of the multi-channel filter were 100 × 60 × 9 mm.

The known prototype device had dimensions of 250 × 180 × 17 mm. (A double-sided printed circuit board with 8 channels on each side was used.) Figure 3 shows the normalized frequency response of a known device when all 16 channels are turned on in order. The range of overlapping frequencies is 186-216 MHz. Figure 4 presents the measured normalized frequency response of the proposed multi-channel filter when you turn on in order all 16 channels. As can be seen from the graphs, the proposed filter has a suppression of about 90 dB for all channels. The known device has the best attenuation of about 80 dB for the first channel. As the number of channels and the central frequencies of the filters increases, the selectivity deteriorates (rise in frequency response) to 70 dB in the center of the overlapping range. Thus, the proposed filter has reduced distortion of the frequency response due to the reduction of parasitic reactivity in the design.

The use of such a multi-channel filter on a SAW for the input circuits of radio receivers will improve the sensitivity and selectivity of the receiving path, as well as its overall dimensions.

Currently, for this technical solution there are laboratory samples and design documentation. Tests are conducted, upon completion of which the proposed technical solution will be used in the newly developed communications equipment.

Information sources

1. V.N. Golubev, "Effective selectivity of radio receivers." M .: Communication, 1978, p.27.

2. Shitang He, Honglang Li, Shunzhou Li, Shu Xie, "Low Loss and High Stopband Rejection Switchable SAW Filter Bank", Proc. of 2002 IEEE Ultrasonics Symposium, pp. 184-187.

Claims (1)

A multi-channel SAW filter with input and output terminals, input and output switches, each of which consists of N by the number of channels of the key filter with its control inputs, a frequency-selective block with an amplifier located between the input and output switches and consisting of N channels each of which contains input and output filters for SAWs, channel input and output keys with their own control inputs, electric buses of the first and second groups, the input terminal being connected to the inputs of the input keys mmutator, and the output terminal is connected to the key outputs of the output switch, while the control inputs of all the keys are interconnected, characterized in that N-1 amplifiers are introduced into the frequency-selective block, and in each channel of the frequency-selective block, the amplifier input is connected to the output the input filter on the SAW electric bus of the first group, and the output of the amplifier is connected to the input of the output filter on the SAW electric bus of the second group, the input of the channel input key is connected to the output of the corresponding key of the input about the switch, and the output of the channel input key is connected to the input of the input filter to the SAW, the input of the channel output key is connected to the output of the output filter to the SAW, and the output of the channel output key is connected to the input of the corresponding key of the output switch.

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