JP3108419U - Double-tuned circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress a disturbing signal by reducing a peak of a parasitic resonance caused by a small capacitance of a switch diode which is turned off during low band tuning.
One end of a first high-band tuning coil and a first low-band tuning coil are connected to one end of a first or second varactor diode, and one end of the other varactor diode is connected in series to one end of the other varactor diode. One end of the tuning coil 16 on the second high band tuning coil 16a side is connected, and the other end of the first low band tuning coil 14 and the other end of the series tuning coil 16 on the second low band coil 16b side are connected to the ground side. The other end of the first high-band tuning coil 13 is connected to the ground side via the first switch diode 18, and the second high-band tuning coil 16a and the second low-band tuning coil 16b are connected. The point was connected to the ground side via the second switch diode 19.
[Selection] Figure 1

Description

  The present invention relates to a double tuning circuit used in a television tuner or the like.

  A conventional double-tuned circuit will be described with reference to FIG. The primary tuning circuit 51 includes a DC blocking capacitor 53 and a varactor diode 54 connected in series, a high band tuning coil 55, a low band tuning coil 56, a resistor 57, a coupling coil 58, which are connected in series in the illustrated order. A DC blocking capacitor 59 is connected in parallel. The varactor diode 54 has an anode grounded and a cathode connected to the DC blocking capacitor 53. The other end of the DC blocking capacitor 59 is also grounded. A connection point between the DC blocking capacitor 53 and the tuning coil 55 is connected to the high-frequency amplifier 60 in the previous stage. A DC blocking capacitor 61, a switch diode 62, and a DC blocking capacitor 63 connected in series are provided between the connection point of the tuning coil 55 and the tuning coil 56 and the ground. The switch diode 62 has an anode connected to the DC blocking capacitor 61 and a cathode connected to the DC blocking capacitor 63.

  A connection point between the DC blocking capacitor 61 and the switch diode 62 is connected to a switching terminal 65 for high band reception through a feeding resistor 64. A connection point between the switch diode 62 and the DC blocking capacitor 63 is connected to a switching terminal 67 for low band reception through a feeding resistor 66. A bias resistor 68 is provided between the connection point between the switch diode 62 and the DC blocking capacitor 63 and the ground. A connection point between the DC blocking capacitor 53 and the varactor diode 54 is connected to the tuning voltage terminal 70 via the feeding resistor 69.

  The secondary tuning circuit 52 includes a varactor diode 71, a high-band tuning coil 72, a low-band tuning coil 73, a resistor 74, a DC blocking capacitor 75, a coupling coil 58, and a DC blocking capacitor 59 connected in series in the illustrated order. Are connected in parallel. The varactor diode 71 has an anode grounded and a cathode connected to the tuning coil 72. A varactor diode 76 and a DC blocking capacitor 77 connected in series are connected to a connection point between the varactor diode 71 and the tuning coil 72. The varactor diode 76 has an anode connected to the DC blocking capacitor 77 and a cathode connected to the tuning coil 72. The other end of the DC blocking capacitor 77 is connected to the mixer 78 at the subsequent stage.

  A DC blocking capacitor 79 and a switch diode 80 connected in series are provided at a connection point between the tuning coil 72 and the tuning coil 73 and a connection point between the switch diode 62 and the DC blocking capacitor 63. The switch diode 80 has an anode connected to the DC blocking capacitor 79 and a cathode connected to the DC blocking capacitor 63. A connection point between the DC blocking capacitor 79 and the switch diode 80 is connected to a switching terminal 65 for high-band reception through a feeding resistor 81. A connection point between the switch diode 80 and the DC blocking capacitor 63 is connected to a switching terminal 67 for low-band reception through a feeding resistor 66. A connection point between the varactor diode 71 and the tuning coil 72 is connected to the tuning voltage terminal 70 via the feeding resistor 82.

  With the above configuration, by applying a voltage to the switching terminal 65 for high-band reception or the switching terminal 67 for low-band reception, both the switch diode 62 and the switch diode 80 are made conductive or non-conductive, This double-tuned circuit is switched to a high-band reception state or a low-band reception state (see, for example, Patent Document 1).

JP 2001-157127 A (FIG. 5)

  When the switch diodes 62 and 80 are turned off and tuned to the low band, these switch diodes have a small capacity, and on the primary side, a resonant circuit is formed by the switch diode 62, the low band tuning coil 56, and the coupling coil 58, and the secondary circuit. On the side, a resonant circuit is formed by the switch diode 82 low-band tuning coil 73 and the coupling coil 58. Since the resonance frequencies of these newly formed resonance circuits are substantially equal, they overlap and appear in the UHF band as resonance characteristics having a large peak value. For this reason, when a frequency in the vicinity is input to the mixer 78, it is mixed with the harmonics of the local oscillation signal and appears as an interference signal in the intermediate frequency band.

  An object of the present invention is to suppress the interference signal by reducing the peak of the parasitic resonance caused by the minute capacitance of the switch diode which is turned off during the low band tuning.

  As a first means for solving the above-mentioned problems, there are a primary tuning circuit and two switching circuits each having an inductor, a varactor diode, and a switch diode, which are switched to be tuned to two bands by turning on / off the switch diode. The primary tuning circuit and the secondary tuning circuit have different resonance frequencies of the resonance circuit composed of the secondary tuning circuit and configured by the off-state capacitance of the switch diode and the inductor.

  As a second means, the primary tuning circuit includes the first varactor diode, the secondary tuning circuit includes the second varactor diode, and the inductor includes the first or second varactor diode. From the first high-band tuning coil and the first low-band tuning coil, one end of which is connected to one end of the varactor diode, and the second high-band tuning coil and the second low-band tuning coil connected in series with each other And a series tuning coil having one end on the second high-band tuning coil side connected to one end of the other varactor diode, and the anodes of the first and second varactor diodes are grounded in a DC manner, and the cathode A tuning voltage is applied to the other end of the first low-band tuning coil and the second low-band coil side of the series tuning coil. The other end of the first high-band tuning coil is connected to the ground side via the first switch diode, and the second high-band tuning coil and the second high-band tuning coil are connected to the ground side. The connection point with the low-band tuning coil was connected to the ground side via the second switch diode.

  As a third means, the other end of the first low band tuning coil and the other end of the series tuning coil on the second low band coil side are grounded via a first coupling coil, and the first And the second switch diode was grounded through the second coupling coil.

  According to the first solution, each of the primary tuning circuit and the secondary tuning circuit includes an inductor, a varactor diode, and a switching diode, which are switched to be tuned to two bands by turning on / off the switching diode. Since the resonance frequency of the resonance circuit constituted by the capacitance and inductor when the switch diode is off is made different between the primary tuning circuit and the secondary tuning circuit, the position of the peak point of each resonance circuit is shifted and its level Becomes lower and the level of the interference signal is lowered.

  According to the second means, the primary tuning circuit has the first varactor diode, the secondary tuning circuit has the second varactor diode, and the inductor is the first or second varactor diode. A first high-band tuning coil and a first low-band tuning coil, each of which is connected to one end, and a second high-band tuning coil and a second low-band tuning coil connected in series with each other. One end of the high-band tuning coil is a series tuning coil connected to one end of the other varactor diode. The anodes of the first and second varactor diodes are grounded in a DC manner and a tuning voltage is applied to the cathode. The other end of the first low band tuning coil and the other end of the series tuning coil on the second low band coil side are connected to the ground side, and the first high band tuning coil is connected to the first high band tuning coil. The other end of the second tuning coil is connected to the ground side via the first switch diode, and the connection point between the second high band tuning coil and the second low band tuning coil is connected to the ground via the second switch diode. Since the parasitic resonance circuit including the two switch diodes in the off state is formed when switched to the low band, the parasitic resonance circuit including the first switch diode is a resonance including the second switch diode. Since the resonance frequency is lower than that of the circuit and the respective resonance frequencies are different, the peak of the resonance characteristics can be suppressed. For this reason, even if the resonance frequency of the second parasitic resonance circuit appears in the UHF band, the peak value of the resonance characteristic is lower than that of the conventional one, and the level of the interference signal is lowered.

According to the third means, the other end of the first low-band tuning coil and the other end of the series tuning coil on the second low-band coil side are grounded via the first coupling coil, and the first and second Since the two switch diodes are grounded via the second coupling coil, the primary and secondary tuning circuits can be coupled by the dedicated coupling coils in both the high band and the low band. Become.

  The double-tuned circuit of the present invention will be described with reference to FIGS. In FIG. 1, the double-tuned circuit 1 of the present invention is interposed between a high-frequency amplifier 2 and a mixer 3. One end (cathode) of the first varactor diode 12 constituting the primary tuning circuit is connected to the input end 1a coupled to the high-frequency amplifier 2 via the DC cut capacitor 11, and the other end (anode) is grounded. . One end of the first high band tuning coil 13 and one end of the first low band tuning coil 14 are connected to one end of the first varactor diode 12.

  One end (cathode) of the second varactor diode 15 constituting the secondary tuning circuit is connected to the output terminal 1b coupled to the mixer 3, and the anode is grounded. One end of the second varactor diode 15 has one end on the second high band tuning coil 16a side in the series tuning coil 16 including the second high band tuning coil 16a and the second low band tuning coil 16b connected in series. Is connected. The first high band tuning coil 13 and the second high band tuning coil 16a have substantially the same inductance value. The inductance value of the first low band tuning coil 14 is substantially equal to the sum of the inductance value of the second high band tuning coil 16a and the inductance value of the second low band tuning coil 16b.

  The other end of the first low band tuning coil 14 and the other end of the series tuning coil 16 on the second low band tuning coil 16 b side are grounded via the first coupling coil 17 in a high frequency manner. The other end of the first high band tuning coil 13 is connected to the anode of the first switch diode 18. The anode of the second switch diode 19 is connected to the middle point of the series tuning coil 16, that is, the high-frequency connection point between the second high-band tuning coil 16a and the second low-band tuning coil 16b. The cathode of the first switch diode 18 and the cathode of the second switch diode 19 are connected to each other, and this connection point is grounded via the second coupling coil 20.

  The cathode of the first varactor diode 15 is connected to the cathode of the second varactor diode 15 by being connected to the second high-band tuning coil 16 a by the resistor 21. Then, the tuning voltage Vt is applied to the cathode of the second varactor diode 15. The power supply voltage Vb is applied to the first coupling coil 17. By applying the power supply voltage, the power supply voltage is supplied to the high-frequency amplifier 2, and the power supply voltage is also supplied to the anodes of the first and second switch diodes 18 and 19. Further, a high or low band switching voltage Vs is applied to the cathodes of the first and second switch diodes 18 and 19.

  The output terminal 1 b of the double-tuned circuit 1 is coupled to the mixer 3 via a third varactor diode 22. A tuning voltage is also applied to the cathode of the third varactor diode 21, and the anode is grounded in a DC manner.

  In the above configuration, when tuning to the high band, the band switching voltage is set low and the first and second switch diodes 18 and 19 are turned on. Then, the double-tuned circuit 1 becomes a circuit shown in FIG. 2, and the first high-band tuning coil 13 and the second coupling coil 20 together with the first varactor diode 12 constitute a primary-side tuning circuit. The high band tuning coil 16a and the second coupling coil 20 together with the second varactor diode 15 constitute a secondary side tuning circuit. The tuning frequency is high band. The first high-band tuning coil 13 is connected to the first low-band tuning coil 14, the first coupling coil 17 connected thereto, the second low-band tuning coil 16b, and the like. Since the inductance value is larger than that of the first high-band tuning coil 13, it can be ignored.

  When tuning to the low band, the band switching voltage is set high to turn off the first and second switch diodes 18 and 19. Then, the double-tuned circuit 1 becomes a circuit shown in FIG. 3, and the first low-band tuning coil 14 and the first coupling coil 17 together with the first varactor diode 12 constitute a primary-side tuning circuit, and the series tuning coil 16 (The series connection of the second high-band tuning coil 16 a and the second low-band coil 16) and the first coupling coil 17 together with the second varactor diode 15 constitute a secondary side tuning circuit. The tuning frequency is low band.

  When the first and second switch diodes 18 and 19 are turned off, the first and second switch diodes 18 and 19 have a very small capacity. Therefore, a circuit including the very small capacity is expressed as shown in FIG. According to the circuit of FIG. 3, on the primary side, the first coupling coil 17, the first low-band tuning coil 14, the first high-band tuning coil 13, the first switch diode 18, and the second A first parasitic resonance circuit L1 is formed by a closed loop including the coupling coil 20, and on the secondary side, a first coupling coil 17, a second low-band tuning coil 16b, a second switch diode 19, and It can be seen that the second parasitic resonance circuit L2 is formed by a closed loop including the second coupling coil 20. However, comparing the two parasitic resonance circuits L1 and L2, it is clear that the resonance frequency of the first parasitic resonance circuit L1 is lower than that of the second parasitic resonance circuit L2, and the resonance frequencies do not match.

  For this reason, even if the resonance frequency of the second parasitic resonance circuit L2 appears in the UHF band, the peak value of the resonance characteristics becomes lower than the conventional value, and the level of the interference signal decreases.

  1, the series tuning coil 16 is connected to the second varactor diode 15 of the secondary side tuning circuit, and the first high-band tuning coil 13 and the first varactor diode 12 of the primary side tuning circuit are connected. Although the first low band tuning coil 14 is connected, the first high band tuning coil 13 and the first low band tuning coil 14 are connected to the second varactor diode 15 of the secondary side tuning circuit, and the primary side tuning circuit It goes without saying that the series tuning coil 16 may be connected to the first varactor diode 12.

It is a circuit diagram which shows the structure of the double tuning circuit of this invention. It is an equivalent circuit diagram at the time of high band tuning of the double tuning circuit of the present invention. It is an equivalent circuit diagram at the time of low band tuning of the double tuning circuit of the present invention. It is an equivalent circuit diagram at the time of low band tuning of the double tuning circuit of the present invention. It is a circuit diagram which shows the structure of the conventional double tuning circuit.

Explanation of symbols

1: Double tuning circuit 1a: Input terminal 1b: Output terminal 2: High frequency amplifier 3: Mixer 11: DC cut capacitor 12: First varactor diode 13: First high band tuning coil 14: First low band tuning coil 15: second varactor diode 16: series tuning coil 16a: second high band tuning coil 16b: second low band tuning coil 17: first coupling coil 18: first switch diode 19: second switch Diode 20: Second coupling coil 21: Resistance 22: Third varactor diode

Claims (3)

Each includes an inductor, a varactor diode, and a switch diode, and includes a primary tuning circuit and a secondary tuning circuit that are switched to be tuned to two bands by turning on / off the switch diode, and when the switch diode is off A double-tuned circuit characterized in that the resonant frequency of a resonant circuit constituted by the capacitor and the inductor is different between the primary tuning circuit and the secondary tuning circuit. The primary tuning circuit has the first varactor diode, the secondary tuning circuit has the second varactor diode, and the inductor is at one end of the first or second varactor diode, respectively. The first high-band tuning coil and the first low-band tuning coil connected to one end of the second high-band tuning coil and the second high-band tuning coil and the second low-band tuning coil connected in series with each other. One end of the coil side is composed of a series tuning coil connected to one end of the other varactor diode, the anodes of the first and second varactor diodes are grounded in a DC manner, and a tuning voltage is applied to the cathode, The other end of the first low band tuning coil and the other end of the series tuning coil on the second low band coil side are connected to the ground side. The other end of the first high-band tuning coil is connected to the ground side via the first switch diode, and the connection point between the second high-band tuning coil and the second low-band tuning coil is 2. The double-tuned circuit according to claim 1, wherein the double-tuned circuit is connected to the ground side via the second switch diode. The other end of the first low-band tuning coil and the other end of the series tuning coil on the second low-band coil side are grounded via a first coupling coil, and the first and second switch diodes are The double-tuned circuit according to claim 2, wherein the double-tuned circuit is grounded via two coupling coils.

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