JP2006197027A - Filter circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive filter circuit which has an excellent characteristic, and fine-adjustment of which is easy, and to provide a filter circuit for common reception employing the same. <P>SOLUTION: In the common reception purpose filter circuit comprising the filter circuit configured to connect a resonance circuit formed on at least an insulation board to a transmission path formed on the insulation board via a capacitive reactance, the capacitive reactance is a jumper wire the one terminal of which is connected to the resonance circuit and the other terminal of which is arranged along the transmission path nearly in the same direction as the arranged direction of the transmission path, and capacitively coupled to the transmission path to form a freely variable very small capacitance. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a filter circuit mainly used in a television joint receiving apparatus, and more particularly to a circuit configuration of the filter circuit.

Conventionally, for example, when designing a trap in the UHF band, a capacitively coupled trap circuit connected to a transmission line via a capacitive reactance is often used for a parallel resonant circuit composed of a coil and a capacitor.
(For example, see Patent Document 1)

JP 2001-136408 A

However, according to the conventional trap circuit, a capacitor is used as the capacitive reactance. Usually, a capacitor having a capacity of 1 pF or less is often used, and the steep characteristics are required as described above. In this case, for example, a minute capacitance of about 0.2 to 0.5 pF is required. In order to realize such a minute capacity, a method of realizing a desired capacity by connecting a plurality of capacitors is adopted. However, it is difficult to obtain a desired capacity by this method.
Therefore, in the present application, it was made to solve such problems,
The purpose is to provide an inexpensive filter circuit with good characteristics.
The purpose is to provide a low cost trap circuit with good characteristics.
Another object is to provide a trap circuit with excellent mounting efficiency.
Another object is to provide a trap circuit coupled with a small capacitance.
Another object is to provide a trap circuit coupled with a variable capacitance that has a simple configuration.
Another object is to provide a method for manufacturing a trap circuit coupled with a variable capacitance that has a simple configuration.
Another object is to provide a band elimination filter having the trap circuit.

In order to solve the above-mentioned problem, the invention of claim 1 is a collective circuit comprising a filter circuit configured to connect at least a resonance circuit formed on an insulating plate to a transmission path formed on the insulating plate through a capacitive reactance. In the filter circuit for reception,
The capacitive reactance is a jumper wire, one of which is connected to the resonance circuit and the other side is arranged so as to be in the same direction as the transmission line. To be capacitively coupled.

According to a second aspect of the present invention, in the first aspect of the invention, an insulating material is provided on a peripheral surface of at least a portion of the jumper wire coupled to the transmission line.

According to a third aspect of the present invention, in the joint reception filter circuit according to the first or second aspect, the filter circuit is a trap circuit having a parallel resonant circuit composed of a capacitor and a coil and the capacitive reactance. Configured.

The invention according to claim 4 is configured such that the joint reception filter circuit is a band elimination filter including at least the trap circuit according to claim 3.

According to a fifth aspect of the present invention, in the joint reception filter circuit according to the first to fourth aspects, the insulating plate is masked at least in the vicinity of the transmission line facing the jumper line. .

The invention according to claim 6 is the filter circuit for joint reception according to any one of claims 1 to 4, wherein the width of the transmission line is substantially equal to or slightly larger than the width of the jumper line. Was formed to have a length capable of obtaining a predetermined capacitance.

According to the invention of claim 1, in the joint reception filter circuit comprising a filter circuit configured to connect at least a resonance circuit formed on the insulating plate to a transmission path formed on the insulating plate through capacitive reactance,
The capacitive reactance is a jumper wire, one of which is connected to the resonance circuit and the other side is arranged so as to be in the same direction as the transmission line. Is configured to be capacitively coupled to
A very small capacitive reactance can be produced at low cost. In addition, due to the bendability, it is possible to provide a filter circuit that can adjust a minute capacitance and has good stability. .

According to the invention of claim 2, in the invention of claim 1, since an insulating material is provided on the peripheral surface of at least a portion of the jumper wire coupled to the transmission line,
For example, even when the transmission line and the jumper line are arranged close to each other, the transmission line and the coupling means are not short-circuited by the insulating material.

According to a third aspect of the present invention, in the joint reception filter circuit according to the first or second aspect, the filter circuit is a trap circuit having a parallel resonant circuit composed of a capacitor and a coil and the capacitive reactance. Because it was configured as
A trap circuit with high production efficiency and low cost can be provided.

According to the invention of claim 4, since the filter circuit for joint reception is configured to be a band elimination filter including at least the trap circuit according to claim 3, a band with high production efficiency and low cost. Elimination filter can be provided.

According to the invention of claim 5, in the joint reception filter circuit according to claims 1 to 4, since the insulating plate is masked at least in the vicinity of the transmission line facing the jumper line,
Since the transmission line and the jumper line are insulated, there is no short circuit.

(6) The width of the line is a filter circuit for joint reception according to any one of (1) to (5), and is formed to be substantially equal to or slightly larger than the width of the jumper line. Because it was formed to a length
With a very small capacitance formed by jumper wires, a filter circuit with good production efficiency and low cost can be created. In addition, the bendability of the jumper wire makes it possible to easily adjust the minute capacitance, and to provide a filter circuit with good characteristics and easy adjustment.

Hereinafter, an example of an embodiment embodying the present invention will be described in detail with reference to the drawings.
FIG. 1 shows an embodiment of a filter circuit for joint reception provided with a filter circuit according to the present application. FIG. 2 shows an example of frequency characteristics of the joint reception filter circuit shown in FIG. 1, and FIG. 3 is a front view showing an example of mounting the joint reception filter circuit on a printed board. 4 is a cross-sectional view taken along line AA in FIG.

FIG. 1 is an example of a joint reception filter circuit including a filter circuit according to the present application. In this embodiment, a mixing circuit that mixes radio waves in the UHF band is shown, and radio waves from local broadcasting stations and satellite stations are distant from each other. The satellite station is a mixer for receiving and mixing radio waves having different directions of arrival with different antennas.
The channel of terrestrial digital broadcasting using the UHF band started in recent years is assigned to the low frequency side of the UHF band, and will be a simulcast with the terrestrial analog broadcast of the UHF band until 2011. For this reason, some conventional UHF band terrestrial analog broadcast waves have the channel unchanged, and measures have been taken to change the channel so as not to affect digital broadcasting. However, from the viewpoint of the user viewing the television, the conventional analog terrestrial broadcast must be able to be viewed without being affected by the terrestrial digital broadcast, and in addition, the terrestrial digital broadcast can be viewed. A receiving system is desired. However, there is a level difference between terrestrial analog broadcasting and terrestrial digital broadcasting, and even between terrestrial analog broadcasting radio waves, there is a difference between terrestrial analog broadcasting with strong radio waves from local broadcasting stations and terrestrial analog broadcasting with weak radio waves far away. As described above, the levels are different, the frequencies are close, and the terrestrial digital broadcasting includes wide-area broadcasting and prefectural broadcasting, and the receiving system needs to cope with a combination of optimum filters in each area.

In the filter circuit shown in the embodiment of the present application, INPUT1 is an input terminal for inputting radio waves from a prefectural broadcast received by a UHF antenna or a local satellite station. The digital terrestrial broadcast wave and analog terrestrial broadcast wave signals in the frequency band are input.
INPUT2 is an input terminal for inputting the terrestrial digital broadcast wave of ch13 to ch25 and the terrestrial analog broadcast wave of ch35 which is a specific signal, which are radio waves from a remote transmission tower.

First, the flow of signals input from INPUT1 will be described. The signals of local channels 27 to 44 input from INPUT1 are input to the changeover switch SW1 via the capacitor C1. This change-over switch SW1 is used for selectively switching between allowing an input signal to pass or passing through an attenuator circuit composed of resistors R1, R2, and R3.
Next, the signals of channels 27 to 44 that have passed through SW1 are input to a band-emitting filter BEF (hereinafter referred to as BEF). This BEF is composed of capacitors C2 to C9 and coils L1 to L5, and the parallel resonance circuit of the capacitor C9 and coil L5 and the capacitor C8 constitute a trap circuit as an embodiment of the filter circuit described in the claim hole. ing. In the embodiment of the present application, this BEF uses at least the specific signal ch35 as a stop band, and prevents the specific signal ch35 from being input from OUTPUT1.
The signals of ch 27 to 44 excluding ch 35 that is at least a specific signal that has passed through the BEF are input to a high-pass filter HPF (hereinafter referred to as HPF). This HPF is composed of capacitors C10 to C13 and coils L6 to L8, and is configured to have ch13 to ch25 as a stop band and ch27 to 44 as a pass band. A signal passing through this HPF is passed through a capacitor C17. Output from OUTPUT.

Next, the flow of signals input from INPUT2 will be described. The signals of ch 13 to 25 and the signal of ch 35 which is a specific signal input from INPUT 2 are input to the changeover switch SW 2 via the capacitor C 21. The change-over switch SW2 is used to selectively switch whether an input signal is allowed to pass or whether an attenuator circuit including resistors R21, R22, and R23 is allowed to pass.
Next, the signals of ch 13 to 25 and the specific signal ch 35 that have passed through SW 2 are input to a trap circuit TRF (hereinafter referred to as TRF). This TRF is composed of a capacitor C22, a coil L9 parallel resonance circuit, and a capacitor C22. The TRF blocks the terrestrial analog broadcast ch33 signal, which is a radio wave from a local broadcast station, and receives the ch35, which is a radio wave from a distant broadcast station. This is to prevent the influence from being affected. This TRF is the trap circuit described in the claims.

The signals of ch 13 to 25 and a specific signal ch 35 that have passed through the TRF are transmitted to an interconnection point between a band-pass filter BPF (hereinafter referred to as BPF) and a low-pass filter LPF (hereinafter referred to as LPF). Is done.
The BPF is composed of capacitors C24 to C33 and coils L10 to L14, and allows at least a specific signal ch35 out of the signals input from the INPUT to pass through the channel lower than ch33 and the channel higher than ch44 as a stop band. It is configured to receive a ch35 signal, which is a radio wave from a distant broadcasting station, without being affected by a signal (for example, ch33) transmitted from a local broadcasting station.

The LPF is composed of capacitors C38 to C40 and coils L15 to L21. The LPF is configured so that channels 13 to 25 of the signal input from the INPUT 2 are used as a pass band and a channel higher than ch 27 is used as a stop band. This is for passing the signals of channels 13 to 25 that are radio waves from the station.

The output of the BPF is connected to an interconnection point between the BEF and the HPF, and a specific signal of at least ch 35 that has passed through the BPF is at least ch 35 to which ch 35 that has passed through the BEF is divided by BEF. 44 is input to the HPF and output from OUTPUT.
The output of the LPF is connected to the output of the HPF, and the signals of the channels 13 to 25 that have passed through the LPF are output from OUTPUT.
FIG. 2 shows an example of frequency characteristics in OUTPUT.

Thus, as in the embodiment of the present application, a specific signal from a distant broadcasting station is received while receiving a signal within the range of ch27 to 44 transmitted from a local broadcasting station (for example, ch33) or a satellite station. (For example, ch35) and a signal within the range of ch13 to 25 transmitted from a radio tower, it is necessary to mix without interfering with adjacent signals. The BEF efficiently blocks the specific signal ch35 from being received by the antenna for receiving the local radio wave, and the specific signal ch35 is not affected by the local radio wave. In order to receive, it is necessary to form the BPF in a narrow band. By the way, in order to form the BEF or BPF with good characteristics, the circuit becomes complicated and a space is required, which in turn increases the cost of the product. Therefore, the BEF cannot easily and stably block a specific signal, and the BPF has a TRF for the ch33 that affects the specific signal before this, so that the lower side of the BPF passband ch35 Then, a method of improving the blocking amount for ch33 by sharply cutting the frequency characteristic on the upper side of ch33, which is the blocking band, may be simple.

By the way, a capacitively coupled trap circuit that is connected to a transmission line via a capacitor C8 that is a capacitive reactance is suitable for a trap circuit that constitutes such a BEF.
A capacitor is used as the capacitive reactance used in such a trap circuit. Usually, a capacitor having a capacity of 1 pF or less is often used, and when the steep characteristics are required as described above. For example, a minute capacity of about 0.2 to 0.5 pF is required. In order to realize such a small capacity, a method of realizing a desired capacity by connecting a plurality of capacitors is adopted. However, this method is difficult to obtain a desired capacity or has a large variation. Further, since the reduction of “Q” occurs, it is difficult to realize. The same applies to a trap circuit including a capacitor C22 and a parallel resonance circuit of the capacitor C23 and the coil L9 constituting the TRF.

Therefore, in the present application, as shown in FIGS. 3 and 4, the BEF includes a signal line P formed on the printed circuit board PK, and a parallel resonant circuit including a capacitor C9 and a coil L5 provided in the vicinity of the signal line P. The jumper wire C8 is connected to the parallel resonant circuit by soldering or the like and the other end is a free end, and the jumper wire C8 is provided in a direction substantially the same as the direction of the transmission line P. Are arranged so as to be along each other and capacitively coupled, and used as a capacitor having a predetermined minute capacity by varying the degree of coupling between the signal line P and the jumper line 22 Thus, “Q” is high with a simple configuration, fine adjustment is easy, and the configuration can be made inexpensively. Similarly, it is needless to say that a very small capacitance can be configured with the same configuration in C22 of TRF in FIG.
In addition, if the wire material provided with the insulator like the polyurethane wire which coat | covered polyurethane on the copper wire as the jumper wire 22 is provided with an insulator between the copper foil which is the constituent material of the signal wire P, and the wire material. Therefore, there is no risk of short-circuiting each other. Further, the signal line P may be covered with a resist. The jumper wire has a width substantially equal to or slightly smaller than that of the transmission line P, and is configured to form a predetermined capacity.

The present invention is not limited to the above-described embodiment. For example, as a means for forming a capacitor as a capacitive reactance, a metal material may be press-molded instead of a jumper wire. It is also possible to implement by appropriately changing the configuration of each part without departing from the above. Moreover, it goes without saying that the frequency arrangement shown in the embodiment is a general example and is not limited to this embodiment.

It is an Example of the filter circuit for joint reception provided with the filter circuit which concerns on this application. The frequency characteristic example of the filter circuit for joint reception shown in FIG. 1 is shown. It is a front view which shows the example which mounted the filter circuit for joint reception on the printed circuit board. It is the sectional view on the AA line in FIG.

Explanation of symbols

C1-17 ... capacitor, C21-33 ... capacitor, C38-40 ... capacitor, L1-L18 ... coil, R1-3 ... resistor, R21-23 ... resistor, SW1, SW2 ... changeover switch, INPUT1, INPUT2 ... input terminal, OUTPUT ... Output terminal, BEF ... Band light filter, BPF ... Band pass filter, HPF ... High pass filter, LPF ... Low pass filter, TRF ... Trap circuit, PK ... Printed circuit board, P ... Signal line

Claims (6)

In a joint reception filter circuit comprising a filter circuit configured to connect at least a resonance circuit formed on an insulating plate to a transmission path formed on the insulating plate through a capacitive reactance,
The capacitive reactance is a jumper wire, one of which is connected to the resonance circuit and the other side is arranged so as to be in the same direction as the transmission line. A filter circuit for joint reception characterized by being configured to be capacitively coupled to the receiver.
2. The filter circuit for joint reception according to claim 1, wherein an insulating material is provided on a peripheral surface of at least a portion of the jumper wire coupled to the transmission line.
The filter circuit for joint reception according to claim 1 or 2, wherein the filter circuit is configured to be a trap circuit with a parallel resonance circuit including a capacitor and a coil and the capacitive reactance.
4. The joint reception filter circuit according to claim 3, wherein the joint reception filter circuit is a band elimination filter including at least the trap circuit according to claim 3.
5. The joint reception filter circuit according to claim 1, wherein the insulating plate is masked at least in the vicinity of the transmission line facing the jumper line.
6. The transmission line according to claim 1, wherein a width of the transmission line is substantially equal to or slightly larger than a width of the jumper line, and a dimension of the jumper line is formed so as to obtain a predetermined capacitance. The filter circuit for joint reception described in 1.

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