RU2396701C2 - Variable lc-band-pass filter - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: variable LC-band pass filter consists of n cascaded L-shaped half sections of high-pass filters, each having capacitors in a series circuit. The first lead of the capacitor is the first input of the half section and the second lead is the output which is connected to an inductor coil whose second output is connected to another capacitor. The input of the first half section is connected to the input potential terminal of the filter. The second leads of the capacitors which are connected in parallel circuits of the half sections are connected to a common bus. The output of the last half section is cascaded with m L-shaped half sections of low-pass filters, each consisting of an inductor coil and in a series circuit and a capacitor connected in parallel. The first leads of this inductor coil and the capacitor are the input of the half section and their second leads are the output which is connected to another capacitor. The output of the last half section is connected to the output potential terminal of the filter and the second leads of capacitors in the parallel circuit of the last ℓ half sections low-pass filters are connected to the common bus. k<n and ℓ<m are any integers. The invention is distinguished by that the filter has four groups of switches. The first group consists of n-k switches whose first leads are connected to input leads of half sections of the low-pass filter, starting with the k+1-th to the n-th half section respectively. Second leads of these switches are connected to the output of the high-pass filter. The second group consists of n-k switches whose first leads are connected to second leads of n-k capacitors connected in the parallel circuits of high-pass filters starting with the k+1-th half section to the n-th half section respectively. The second leads of these switches are connected to the common bus. The third group has m-ℓ switches whose first leads are connected to inputs of half sections of low-pass filters starting with the ℓ+1-th to the m-th, respectively. The first leads of these switches are connected to the output of the m-th half section. The fourth group consists of m-ℓ switches whose first leads are connected to second leads of m-ℓ capacitors connected in the parallel circuits of low-pass filters starting with the ℓ+1-th half section to the m-th half section, respectively. The second leads of these switches are connected to the common bus.

EFFECT: simplification.

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Description

The invention relates to radio electronics and can be used as a preselect of a professional radio receiver.

Modern radio receivers use various types of tunable bandpass filters based on LC elements. Most filters can be divided into two groups. The first includes filters made on LC circuits, in which tunable inductances, and more often the so-called discrete capacitors, are used to tune the average frequency of the filter [1].

This type of filter provides fairly high requirements for selectivity, but it is quite complicated to manufacture.

The second group includes filters, also made on LC-elements and representing a set of band-pass filters connected in turn or several pieces with the help of switching devices. In particular, such a filter can be made in the form of a cascade connection of several links of high-pass filters and low-pass filters [2]. At the same time, to implement the necessary bandwidth in a given operating frequency range, appropriate sets of high and low frequency filters are required, from which the desired pair is selected and connected using cascade elements and connected between the input and output of the preselector.

This type of filter is more technologically advanced in production compared to traditional band-pass filters, as a rule, it provides the best transmission coefficient and we have chosen as a prototype.

The disadvantage of this device is that with a large number of tunable discrete bandwidths, it will be quite complicated.

The objective of the invention is to simplify the device.

The problem is solved in that in a device consisting of n cascaded L-shaped half-links of high-pass filters, each of which contains a capacitor in a serial branch, the first output of the capacitor is the input of the half-link, the second is the output to which the inductor is connected, the second output which is connected to another capacitor, while the input of the first half link is connected to the input potential terminal of the filter, and the second conclusions of the capacitors included in the parallel branches of the first k half links, I connect They are connected to a common bus, to the output of the last half-link are cascaded m L-shaped half-links of low-pass filters, each of which contains an inductance coil and a capacitor connected in parallel to it, the first conclusions of this coil and capacitor are the half-link input, and their second conclusions - the output to which another capacitor is connected, while the output of the last half link is connected to the output terminal of the device, and the second conclusions of the capacitors of the parallel branches of the last l half links of the filters are lower frequencies are connected to a common bus, here m, n, l and k are any integers, with k <n and l <m, four additional groups of keys are entered, the first group consists of nl keys, the first conclusions of which are connected to the input conclusions of half-links high-pass filters, starting from k + l-th and up to n-th, respectively, and the second outputs of these keys are connected to the output of the high-pass filter, the second group consisting of nk keys connected by the first conclusions to the second conclusions of nk capacitors included in parallel high pass filter branches starting from k + 1st half link and until the nth, respectively, the second conclusions of these keys are connected to a common bus, the third group contains ml keys, the first conclusions of which are connected to the inputs of the half-links of the low-pass filters from l + 1 to the m-th, respectively, the second conclusions of these keys connected to the output of the mth half link, the fourth group, consisting of ml keys, is connected by the first leads to the second conclusions of ml capacitors included in the parallel branches of low-pass filters starting from l + 1 of the half link and to the mth, respectively, the second conclusions of these keys connected to a common bus .

Comparative analysis shows that the claimed technical solution differs from the prototype in that four groups of keys are additionally introduced into the device, the first group contains nk keys, the first pins of which are connected to the input pins of the HPF half-links starting from k + 1st half-link and up to the nth accordingly, the second terminals of the keys are connected to the output of the HPF, the second group consists of nk keys, which are connected by the first conclusions to the second terminals of nk capacitors included in the parallel branches of the HPF from the k + 1st half link to the nth Of course, the second conclusions of these keys are connected to the common bus, the third group contains ml keys, the first conclusions of which are connected to the inputs of the low-pass filters from the l + 1st half-link to the mth, respectively, the second conclusions of these keys are connected to the output to m- half-link, the fourth group consists of ml keys, the first conclusions of which are connected to the second conclusions of ml capacitors included in the parallel branches of the low-pass filter starting from l + 1st half-link and to the m-th, respectively, the second conclusions of these keys are connected to a common bus.

When comparing the proposed solution not only with the prototype, but also with other well-known solutions in science and technology, no solutions are found that have similar characteristics.

The drawing shows an electrical diagram of the proposed device. The device contains n L-shaped half-links of the HPF 1, each of which contains a capacitor in the longitudinal branch 2, an inductor 3 is connected to the output of each half-link, capacitors 4 are connected to the second terminals of the latter, the second terminals of the first k capacitors 4 are connected directly to the common bus. The output of the HPF 1 is connected to m half-links of the low-pass filter 5, each of the L-shaped low-pass filters consists of a parallel circuit in the longitudinal branch 6 and capacitors in the transverse branches 7, the first l capacitors are connected directly to the common bus. The device also contains a first group of keys 8, which provides the connection of the inputs of the HPF half-links from k + l to the n-th to the output of the HPF, a second group of keys 9, which provides the connection of capacitors 4 to the common bus, and a third group of keys 10, which provides the connection of the inputs of the low-pass filters starting from l + 1st through mth to the output of the low-pass filter, the fourth group of keys is 11, which provides the connection of capacitors 7 of the half-links of the low-pass filter starting from l + 1st through mth to the common bus in the required time sequence.

The device operates as follows.

The high-pass filter 1 consists of n half links, with the first k half links having a cutoff frequency f _n1 , the next half link (or several half links) have a cutoff frequency f _n2 > f _n1 , the next half link k + 2 has a cutoff frequency f _n3 > f ₂ , etc., therefore, when the first key of group 8 is closed and the keys of group 9 are open, the high-pass filter has a cutoff frequency f _n1 , when the second key of group 8 is closed and the first key of group 9 is closed, the high-pass filter has a cutoff frequency f _n2 , because . the first k half-links are connected to the k + 1st HPF link with a cutoff frequency f _n2 , with open keys of group 8 and closed keys of group 9, the HPF has the highest cutoff frequency f _hn .

The low-pass filter 5 consists of m half links, with the first l half links having a cutoff frequency f _in1 , the next l + 1st half link has a cutoff frequency f _B2 <f _B1 , the next l + 2nd half link has a cutting frequency f _B3 <f _B2 , etc., therefore, the connection to the first l half-links of the low-pass filter of each subsequent half-link accordingly reduces the cutoff frequency of this low-pass filter.

Connection of the required number of subsequent half links is ensured by the appropriate choice of the position of the keys of group 10 and 11. So, for example, with the second key of the group 10 closed, the first key closed and the remaining keys of the group 11 open, the cut-off frequency of the low-pass filter will be equal to f _in2 . With these group 10 public keys and group 11 private keys, the low-pass filter has the lowest cut-off frequency equal to the cut-off frequency of its last half-link.

Thus, choosing the desired position key groups 8-11 can be set as desired _Bi-f HPF cutoff frequency and the cutoff frequency of LPF-f _Bi and receive bandpass filter with a passband _Bi f -f _HI in a predetermined frequency range from f to f _{n c} .

Information sources

1. Znamensky A.E., Popov E.S. Tunable electric filters. M., "Communication", 1979, pp. 46-59.

2. Barefoot N.D. Electric filters. Kiev, Gostekhizdat of the Ukrainian SSR, 1957, p. 123, 144.

Claims (1)

Tunable band-pass LC filter, consisting of n cascaded L-shaped half links of high-pass filters, each of which contains a capacitor in a serial branch, the first output of the capacitor is the input of the half-link, and the second is the output to which the inductor is connected, the second output of which is connected with another capacitor, while the input of the first half link is connected to the input potential terminal of the filter, and the second conclusions of the capacitors included in the parallel branches of the first k half links are connected to the common not, the output of the last half link is connected in cascade of m L-shaped half links of low-pass filters, each of which contains an inductance coil and a capacitor connected in parallel to it, the first conclusions of this coil and capacitor are the half-link input, and their second conclusions are the output, to which another capacitor is connected, while the output of the last half link is connected to the output potential terminal of the filter, and the second conclusions of the capacitors of the parallel branches of the last l half links of the lower filters These are connected to a common bus, where k <n and l <m are any integers, characterized in that the filter contains four groups of keys, the first group contains nk keys, the first pins of which are connected to the input pins of the high-pass filter half-links, starting from k + 1-st and up to the n-th, respectively, and the second terminals of these keys are connected to the output of the high-pass filter, the second group consisting of nk keys connected by the first conclusions to the second conclusions of nk capacitors in parallel branches of the high-pass filters, starting with k + 1st half link and until the nth, respectively, the second conclusions of these keys are connected to a common bus, the third group contains ml keys, the first conclusions of which are connected to the inputs of the half-links of the low-pass filters starting from l + 1 to the m-th, respectively, the second conclusions of these keys connected to the output of the m-th half link, the fourth group consisting of ml keys, the first conclusions of which are connected to the second conclusions of ml capacitors included in the parallel branches of low-pass filters, starting from l + 1-st half-link and to the m-th, respectively, the second conclusions of these keys are connected to her bus.