JP2010068401A - Input circuit of television tuner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To optimize a DC voltage/current applied to a switching element provided to an input stage of one antenna input circuit in accordance with a field strength, and to prevent the generation of distortion in the switching element when an intense electric field is input. <P>SOLUTION: In the input circuit of a television tuner, a VHF antenna input circuit 60 and a UHF antenna input circuit 30 are connected in parallel to an input terminal T1, and an AGC circuit 40 constituted of an AGC amplifier is connected to an output stage of the VHF antenna input circuit 60 and a UHF antenna input circuit 90. A diode D1 is connected between the input terminal T1 and the UHF antenna circuit 90. A switching element is DC-connected between an input end of the AGC amplifier 41 and an input end of the AGC amplifier 42. A bias voltage is applied to the diode D1 from an input end of the AGC amplifier in a side selected as a receiving band. An input end of the AGC amplifier at a side which is not selected as a receiving band is DC-grounded. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an input circuit of a television tuner for selectively receiving a television signal having a plurality of bands such as a VHF band / UHF band.

  2. Description of the Related Art Conventionally, there is an input circuit of a television tuner that receives a VHF band / UHF band of a television signal by distributing it to separate high-frequency circuits (see, for example, Patent Document 1).

  FIG. 5 is a configuration diagram of an input circuit of a television tuner that distributes the VHF band / UHF band to separate high-frequency circuits and receives them. A VHF antenna input circuit 20 and a UHF antenna input circuit 30 are connected in parallel to the input end connected to the antenna filter 10, and output stages of the VHF antenna input circuit 20 and the UHF antenna input circuit 30. In addition, an AGC circuit 40 composed of an AGC amplifier is connected, a VHF RF double-tuned circuit 51 and a mixer 52 are connected to the VHF antenna input circuit 20 side, and a UHF RF is connected to the UHF antenna input circuit 30 side. A double tuning circuit 53 and a mixer 54 are connected.

  A diode D1 is connected between the input end of the input circuit of the television tuner and the UHF antenna input circuit 30. A DC voltage (+ B) is applied to the anode of the diode D1, and the VHF antenna input circuit 20 and the UHF antenna are applied to the cathode of the diode D1 from the changeover switch 11 via the resistor R2. The input circuit 30 is switched. If the UHF side terminal 11a is selected, the cathode of the diode D1 is grounded, so that the diode D1 is turned ON and the UHF antenna input circuit 30 is selected, and if the VHF side terminal 11b is selected, a direct current is applied to the cathode of the diode D1. Since a reverse bias voltage larger than the voltage (+ B) is applied, the diode D1 is turned OFF and the VHF antenna input circuit 20 is selected.

  The VHF antenna input circuit 20 is configured to be switched between a VHF low band and a VHF high band by a changeover switch circuit 21. In the changeover switch circuit 21, when the terminal 21a on the VHF high band side is selected, the cathode of the diode D2 is grounded, so that it is grounded via the parallel circuit of the inductors 22 and 24 and VHF is tuned to the VHF high band. The inductance value of the antenna input circuit 20 is adjusted. On the other hand, when the terminal 21b on the VHF low band side is selected, a reverse bias voltage larger than the DC voltage (+ B) is applied to the cathode of the diode D2, so that the diode D2 is turned OFF and the series circuit of the inductors 22 and 33 is connected. The inductance value of the VHF antenna input circuit 20 is adjusted so as to be tuned to the VHF low band.

  The AGC circuit 40 includes a VHF side AGC amplifier 41 connected to the output terminal of the VHF antenna input circuit 20, a UHF side AGC amplifier 42 connected to the output terminal of the UHF antenna input circuit 30, and an AGC amplifier 41. And an AGC amplifier 42 are provided. The AGC amplifiers 41 and 42 are composed of FETs. The transistor Trs1 is turned on / off by the changeover switch 44. The base of the transistor Trs1 is connected to the input terminal (gate 1) of the AGC amplifier 42 on the UHF side, and is connected to the output terminal of the changeover switch 44 through resistors R3 and R4 in series. In the changeover switch 44, when the VHF side terminal 44a is selected, the base of the transistor Trs1 is grounded, the transistor Trs1 is turned OFF, and the input terminal of the UHF side AGC amplifier 42 is grounded. As a result, the output voltage of the AGC amplifier 41 on the VHF side is applied to the input terminal via the resistor 45 and the resistor R1 in series and amplifies. At this time, the resistor R1 uses a large resistance value of about 13 kΩ in order to reliably insulate the transistor Trs1 (UHF side). Further, in the changeover switch 44, when the UHF side terminal 44b is selected, a voltage is applied to the base of the transistor Trs1 and the transistor Trs1 is turned on. Therefore, the input terminal of the VHF side AGC amplifier 41 is between the collector and emitter of the transistor Trs1. Since it is grounded via the pin and becomes zero bias, it does not perform the function of signal amplification.

As described above, the VHF antenna input circuit 20 and the VHF side AGC amplifier 41, the UHF antenna input circuit 30 and the UHF side are formed using the three changeover switches 11, 21, 44, the diode D1, and the transistor Trs1. The AGC amplifier 42 is switched.
JP 2002-300065 A

However, the conventional television tuner input circuit has the following problems.
Since the DC voltage (when VHF is selected) / current (when UHF is selected) applied to the diode D1 is constant regardless of the input electric field strength, there is a possibility that distortion occurs in the diode D1 when a strong electric field is input. It was.

  The present invention has been made in view of the above points, and the DC voltage / current applied to the switching element provided in the input stage of one antenna input circuit can be optimized according to the electric field strength. An object of the present invention is to provide a television tuner input circuit capable of suppressing the occurrence of distortion in the switching element.

  The input circuit of the television tuner of the present invention includes an input terminal to which a television signal is input, a first high-frequency circuit connected to the input terminal and having a first band as a reception band, and the input terminal having the input terminal A second high-frequency circuit connected in parallel with the first high-frequency circuit and having a second band different from the first band as a reception band, and provided between the input terminal and the second high-frequency circuit. A switching element made of a semiconductor that is turned off when the first band is selected and turned on when the second band is selected, and the first high-frequency circuit, and is connected to the AGC voltage in the switching element when receiving the first band. The first AGC circuit that applies a bias voltage that increases or decreases in the reverse direction and the second high-frequency circuit are provided in the second high-frequency circuit, and the bi-directional signal that increases or decreases in the reverse direction in conjunction with the AGC voltage is received in the switching element when receiving the second band. A second AGC circuit for applying a voltage to the switching element, wherein the switching element has a current flowing through the switching element or a voltage applied across the switching element in accordance with the level of the television signal. The signal level varies in the same direction as the change direction of the signal level.

  According to this configuration, the first AGC circuit applies a bias voltage that increases or decreases in the reverse direction in conjunction with the AGC voltage when receiving the first band, and from the second AGC circuit when receiving the second band. A bias voltage that increases or decreases in the reverse direction in conjunction with the AGC voltage is applied to the switching element, and the current flowing through the switching element or the voltage applied across the switching element depends on the level of the television signal. Since the signal level fluctuates in the same direction as the change direction, the DC voltage / current applied to the switching element can be optimized according to the electric field strength, and distortion can be generated in the switching element when a strong electric field is input. Can be suppressed.

  According to the present invention, in the input circuit of the television tuner, the first AGC circuit has a first amplifier circuit whose gain is controlled by an AGC voltage, and the second AGC circuit has a gain by the AGC voltage. A second amplifier circuit to be controlled; and the switching element is connected in a direct current manner between the input terminal of the first amplifier circuit and the input terminal of the second amplifier circuit, and is selected as a reception band. The bias voltage is applied to the switching element from the input terminal of the amplifier circuit of the AGC circuit on the side that has been selected, and the input terminal of the amplifier circuit of the AGC circuit that is not selected as the reception band is grounded in a DC manner. Features.

  With this configuration, it is possible to improve the distortion characteristics of the switching element by applying a bias voltage linked to the AGC voltage to the switching element from the input terminal of the amplification circuit of the AGC circuit on the side selected as the reception band. The input terminal of the amplifier circuit of the AGC circuit on the non-selected side can be grounded in a direct current manner so as not to perform the amplification function.

  According to the present invention, in the input circuit of the television tuner, a capacitor connected between the input terminal to which a television signal is input and a cathode of the switching diode, and a collector are input to the first amplifier circuit. A transistor having a DC connection to the end, a base connected to the input terminal of the second amplifier circuit, and an emitter grounded; an input terminal of the first amplifier circuit; and a collector of the transistor A first resistor having a resistance value that is low impedance with respect to the first band and a cathode of the switching diode and an input terminal of the first amplifier circuit are connected in a direct current manner. And connected to the anode of the switching diode and the base of the transistor in a direct current manner, and the first band is received when receiving the first band. Grounded base of the anode and the transistor of Tsu quenching diode, when the second band receiver is characterized by comprising a selector switch which outputs a DC voltage as a forward bias voltage to the switching diodes.

  With this configuration, when the second band side is selected, the input terminal of the first amplifier circuit is grounded via the first resistor having a low impedance. Generation of distortion by the amplifier circuit can be suppressed.

  In addition, since the switching diode is turned on / off using the DC voltage output of the changeover switch that turns the transistor on / off according to the selection of the reception band, conventionally, it is provided only for turning on / off the switching diode. Therefore, the number of dedicated switches for supplying DC voltage can be reduced on the IC side.

  In the input circuit of the television tuner, the switching element can be formed of a switching diode. Further, a VHF band receiving circuit can be used as the first high frequency circuit, and a UHF band receiving circuit can be used as the second high frequency circuit.

  According to the present invention, the DC voltage / current applied to the switching element provided in the input stage of one antenna input circuit can be optimized according to the electric field strength, and distortion can be generated in the switching element when a strong electric field is input. Can be suppressed.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a configuration diagram of an input circuit of a television tuner according to an embodiment of the present invention.
In the input circuit of the television tuner according to the present embodiment, the VHF antenna input circuit 60 and the UHF antenna input circuit 90 are connected in parallel to the input terminal T1, and the VHF antenna input circuit 60 and the UHF are connected. The AGC circuit 40 composed of an AGC amplifier is connected to the output stage of the antenna input circuit 90, and the VHF RF double-tuned circuit 51 and the mixer 52 are connected to the VHF antenna input circuit 60 side. A UHF RF double tuning circuit 53 and a mixer 54 are connected to the input circuit 90 side.

  Between the input terminal T1 and the ground, a DC blocking capacitor C1, a diode D1 formed of a band switching semiconductor switching element, an inductor L1, and a high frequency grounding capacitor C2 are connected in series. The diode D1 for band switching has a cathode connected to the input terminal T1 side. A connection point between the cathode of the diode D1 and the capacitor C1 is connected to the input terminal of the AGC amplifier 41 on the VHF side via a resistor R2.

  The VHF antenna input circuit 60 includes an antenna tuning circuit 61 that receives a VHF band that is a first band, and a changeover switch 62 that switches between a VHF high band and a VHF low band. In the antenna tuning circuit 61, an inductor 63 is connected in parallel to the input terminal T1, and the inductor 63 is grounded at a high frequency by a capacitor 65 via a diode 64 in the forward direction. A capacitor 66 is connected in parallel to the diode 64, and a connection point between the capacitor 66 and the cathode of the diode 64 is connected to the output terminal of the changeover switch 62 via a resistor 67. A series circuit composed of inductors 68 and 69 is connected in parallel to the input terminal T1. The ground side end of the inductor 69 is grounded at a high frequency by a capacitor 71 and grounded via a resistor 72. The inductor 68 is configured to form a closed circuit together with the inductor 73, the diode D2, and the capacitor 74. The cathode of the diode D2 is connected to the output terminal of the changeover switch 62 via the resistor 75, and the DC voltage (+ B) is applied to the anode of the diode D2 via the resistor 76 and the inductors 69, 68, 73. .

  A connection point between the anode of the diode D2 and one end of the inductor 73 is connected to one end of the inductor 78 through a DC cut capacitor 77. The other end of the inductor 78 is connected to the cathodes of varactor diodes 79 and 81. The cathode of one varactor diode 79 is grounded, the anode of the other varactor diode 81 is grounded via a resistor 82, and the input terminal (gate) of the AGC amplifier 41 on the VHF side via a capacitor 83 for direct current cut. 1). A tuning voltage Tu can be applied to the cathodes of the varactor diodes 79 and 81. A capacitor 84 is connected in parallel between the input terminal T1 and the input terminal of the AHF amplifier 41 on the VHF side.

  In the selector switch 62, when the terminal 62a on the VHF high band side is selected, the diodes D2 and 64 are turned on and the cathode is grounded. When the terminal 62b on the VHF low band side is selected, the diodes D2 and 64 are in the OFF state. It becomes. Thus, by switching ON / OFF of the diodes D2 and 64, it is possible to switch the inductors 63, 68, and 69 supplied between the ground and the VHF high band / VHF low band. Further, by controlling the tuning voltage Tu applied to the varactor diodes 79 and 81, the tuning frequency in the VHF high band or the VHF low band can be varied.

  The UHF antenna input circuit 90 includes an antenna tuning circuit 91 that tunes to the UHF band. The antenna tuning circuit 91 is connected to the anode of the diode D1 through a DC cut capacitor 92. One end of the inductor 93 is connected to one end of the capacitor 92, and the inductor 94 is connected between the other end of the inductor 93 and the ground. The anode of the varactor diode 95 is connected to the other end of the inductor 93, and the cathode of the varactor diode 96 is connected to the cathode of the varactor diode 95. The anode of the varactor diode 96 is grounded at a high frequency by a capacitor 97 and is grounded at a direct current by a resistor 98. A tuning voltage Tu is applied to the cathodes of the varactor diodes 95 and 96 via a resistor 99. The output terminal of the antenna tuning circuit 91 is connected to the input terminal (gate 1) of the AGC amplifier 42 on the UHF side via a DC cut capacitor 101. A capacitor 102 is connected in parallel between the input and output terminals of the UHF antenna input circuit 90.

  An output terminal of the changeover switch 44 for switching between the UHF band and the VHF band is connected to an intermediate connection point between the inductor L1 and the capacitor C2 via a bias resistor R3. Further, it is connected to the input terminal (gate 1) of the AGC amplifier 42 on the UHF side via the resistor R4.

  The AGC circuit 40 includes a VHF-side AGC amplifier 41, a UHF-side AGC amplifier 42, and a transistor Trs1 that switches an AGC amplifier that performs an amplification operation. Here, the AGC circuit 40 is configured in the same manner as the AGC circuit 40 shown in FIG. 5, but a resistor R0 serving as a first resistor for grounding the input terminal (gate 1) of the AGC amplifier 41 via the transistor Trs1 is provided. The difference is that it is formed of a resistor having a small resistance value (for example, several tens of ohms to several hundreds of ohms). In the AGC amplifiers 41 and 42, an AGC voltage whose voltage is controlled to be inversely proportional to the input electric field strength is applied to the gate 2. That is, the AGC voltage is interlocked so that it decreases as the input electric field strength increases, and conversely increases as the input electric field strength decreases. The AGC amplifiers 41 and 42 are controlled so that the output signal level becomes constant with respect to fluctuations in the input electric field intensity by gain control according to the AGC voltage applied to the gate 2. That is, when the input electric field strength is increased, the input voltage of the input terminal (gate 1) of the AGC amplifier is also increased, so that the AGC voltage is decreased and the output signal level is lowered. Conversely, when the input electric field strength is weakened, the input voltage at the input terminal (gate 1) of the AGC amplifier is also reduced, so that the AGC voltage is increased and the output signal level is increased.

Next, the operation of the present embodiment configured as described above will be described.
The operation when receiving the UHF band will be described. In the changeover switch 44, the terminal 44b on the UHF side is selected. When receiving in the UHF band, the DC voltage (positive side) applied to the terminal 44b on the UHF side is applied to the base of the transistor Trs1 via the resistors R3 and R4. As a result, the collector-emitter of the transistor Trs1 becomes conductive, and the input terminal (gate 1) of the AGC amplifier 41 on the VHF side is grounded via the resistor R0 having a low impedance. Since the AGC amplifier 41 becomes zero bias in terms of DC bias, the signal amplifying function is not fulfilled.

  On the other hand, the DC voltage (positive side) applied to the terminal 44b on the UHF side is applied to the anode of the diode D1 via the resistor R3 and the inductor L1. Since the diode D1 conducts with the DC voltage applied from the changeover switch 44, the high-frequency signal propagated to the input terminal T1 is introduced into the antenna tuning circuit 90 on the UHF side. At this time, the tuning voltage Tu is used to control the capacitance of the varactor diodes 95 and 96 to tune to a desired frequency to extract the received frequency, and the AGC amplifier 42 amplifies and outputs the received frequency to the UHF side.

  FIG. 2 is an equivalent circuit diagram when receiving the UHF band. As shown in the figure, the input terminal (gate 1) of the AHF amplifier 41 on the VHF side that does not perform the amplification function during reception in the UHF band is grounded via the resistor R0 and the transistor Trs1. The resistor R0 uses a small resistance of several tens of ohms to several hundreds of ohms, so that the input terminal (gate 1) of the AGC amplifier 41 is grounded with a small resistance. Accordingly, since the input terminal (gate 1) of the AGC amplifier 41 has an extremely low impedance, even if a signal of a strong electric field is input to the antenna end, the AGC amplifier 41 is very likely to be distorted. There is an advantage of lowering.

  Further, as shown in FIG. 2, a forward bias current indicated by a dotted line flows from the changeover switch 44 toward the emitter ground of the transistor Trs1. That is, the forward bias current flows from the changeover switch 44 to the ground via the resistors R3, L1, the diode D1, the resistor R2, the resistor R0, and the collector-emitter of the transistor Trs1. At this time, the forward bias voltage of the diode D1 of the UHF side AGC amplifier 42 changes in conjunction with the magnitude of the AGC signal. When the input electric field strength is strong, the AGC voltage of the AGC signal is small, and when the electric field strength is low, the AGC voltage of the AGC signal is large. Therefore, when the AGC voltage changes from high to low, the forward bias voltage is Change from low to high. That is, the forward bias voltage increases as the input electric field strength increases, and the forward bias current flowing through the diode D1 increases. Therefore, when the input electric field strength is strong, the forward bias current flowing through the diode D1 becomes large, so that the possibility of distortion of the diode D1 can be reduced.

  Note that an LC series resonance circuit of an inductor L1 and a capacitor C2 is formed between the input terminal of the UHF antenna input circuit 90 and the ground. By setting the resonance frequency of the LC series resonance circuit to the VHF reception band, the signal in the VHF reception band flows to the ground, so that the signal in the VHF reception band is prevented from being mixed into the antenna tuning circuit 91 in the UHF band. Therefore, a positive effect can be brought about on the attenuation characteristic of the antenna tuning circuit 91.

  Next, the operation when receiving the VHF band will be described. In the changeover switch 44, the terminal 44a on the VHF side is selected. When receiving in the VHF band, the input terminal of the UHF side AGC amplifier 42 is grounded via the VHF side terminal 44b, so that the UHF side AGC amplifier 42 becomes zero bias in terms of DC bias and performs the signal amplification function. Disappear. Further, since the base of the transistor Trs1 is grounded via the resistors R5, R4, R3 and the contact 44a, the collector-emitter of the transistor Trs1 becomes non-conductive. As a result, the input terminal of the AGC amplifier 41 on the VHF side is not grounded, so that the signal amplification function is achieved.

  The anode of the diode D1 is grounded via the inductor L1, the resistor R3, and the contact 44a. As a result, the diode D1 becomes non-conductive and becomes high impedance, so that the high frequency signal applied to the input terminal T1 is introduced into the antenna tuning circuit 61 on the VHF side. The high frequency signal extracted by the antenna tuning circuit 61 is amplified by the AGC amplifier 41 on the VHF side and then sent to the double tuning circuit 51 in the subsequent stage.

  FIG. 3 is an equivalent circuit diagram at the time of VHF band reception. As shown in the figure, the output terminal of the AGC amplifier 41 on the VHF side is connected to the input terminal (gate 1) via a resistor 45 and a resistor R0. The input terminal (gate 1) of the AGC amplifier 41 on the VHF side is connected to the cathode of the diode D1 via a resistor R2. Therefore, as indicated by a dotted line in FIG. 3, an off-bias voltage is applied to the diode D1 during reception in the VHF band. The off-bias voltage changes in conjunction with the input electric field strength. The off-bias voltage increases as the input electric field strength increases, and the off-bias voltage decreases as the input electric field strength decreases. Therefore, when the input electric field strength is strong, the off-bias voltage applied to the diode D1 increases, so that the possibility that the diode D1 is distorted can be reduced.

  Further, according to the present embodiment, the cathode of the diode D1 is grounded at the time of receiving the UHF band, and the diode at the time of receiving the VHF band without providing the selector switch 11 for turning the diode D1 ON / OFF in synchronization with the band selection. Since the off bias voltage can be applied to the cathode of D1, there is an advantage that it is not necessary to provide a dedicated port in the IC to which the DC voltage is supplied.

  FIG. 4A shows a simulation result of the antenna selection characteristic of the antenna input circuit according to the present embodiment. The UHF reception band is set to 369 MHz. When the UHF reception band is 369 MHz, a position separated by 72.3 MHz is the image frequency. As shown in the figure, a good antenna selection characteristic in which the image frequency is greatly attenuated is realized.

  FIG. 4B shows a simulation result of the attenuation characteristic at the input terminal of the AGC amplifier 41 on the VHF side. In this example, the resistor R0 connected to the input terminal (gate 1) of the AGC amplifier 41 is set to a large resistance of 13 kΩ. As shown in the figure, a peak is established at 119 MHz, which is the tuning frequency of the antenna tuning circuit 61 on the VHF side. When the input electric field strength is strong, the AGC amplifier 41 may be distorted by the 119 MHz peak signal.

  FIG. 4C shows a simulation result of the attenuation characteristic at the input terminal of the AGC amplifier 41 on the VHF side, in which the resistor R0 is set to a small resistance of 50Ω. As shown in the figure, the peak is at 114 MHz, but the attenuation characteristic is improved as compared with the case of the large resistance shown in FIG.

  FIG. 4D shows a simulation result of the attenuation characteristic at the input terminal of the AGC amplifier 41 on the VHF side, in which the resistor R0 is set to a small resistance of 10Ω. As shown in the figure, the peak is at 112 MHz, but the attenuation characteristic is greatly improved as compared with the case of the large resistance shown in FIG.

  When the same simulation was performed for the UHF intermediate band (603 MHz) and the UHF high band (861 MHz), the same tendency as described above could be confirmed.

  As described above, according to the present embodiment, the resistance R0 connected to the input terminal of the AHF amplifier 41 on the VHF side and grounded at the time of receiving the UHF band is made small, so that the attenuation characteristic at the time of receiving the UHF band is improved. be able to.

  The cathode of the diode D1 provided at the input stage of the antenna input circuit 90 on the UHF side is forward-biased when receiving the UHF band, while being grounded when receiving the VHF band, and the anode of the diode D1 is connected to the VHF side in a DC manner. Since it is connected to the input terminal of the AGC amplifier 41, the changeover switch 44 for controlling the transistor Trs1 can also be used as a changeover switch for turning on / off the diode D1, and the dedicated port provided in the IC to which the DC voltage is supplied can be reduced.

  In addition, since the bias voltage (at VHF) / current (at UHF) of the diode D1 changes in a direction in which distortion is reduced in conjunction with the input electric field strength, the occurrence of distortion in the diode D1 can also be suppressed. .

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, the present invention is not limited to switching between the VHF band and the UHF band, and can be applied to other bands.

1 is a configuration diagram of an input circuit of a television tuner according to an embodiment of the present invention. Equivalent circuit diagram at the time of UHF band reception of the input circuit of the television tuner of one embodiment Equivalent circuit diagram at the time of VHF band reception of the input circuit of the television tuner of one embodiment (A) The figure which shows the simulation result of the antenna selection characteristic of the antenna input circuit of one Embodiment, (b) It is the attenuation characteristic in the input terminal of the AGC amplifier by the side of VHF, and shows the simulation result at the time of using 13 kohm. (C) Attenuation characteristics at the input terminal of the AGC amplifier on the VHF side and showing simulation results when 50Ω is used. (D) Attenuation characteristics at the input terminal of the AGC amplifier on the VHF side. The figure which shows the simulation result when 10Ω is used Configuration diagram of an input circuit of a television tuner that distributes the VHF band / UHF band to separate high-frequency circuits and receives them

Explanation of symbols

T1 input terminal D1 diode Trs1 transistor R0 resistor 10 antenna filter 40 amplifier circuit 41, 42 AGC amplifier 44 selector switch (VHF / UHF)
60 Antenna input circuit for VHF 61 Antenna tuning circuit (VHF)
62 selector switch (VHF low band / VHF high band)
90 UHF antenna input circuit 91 Antenna tuning circuit (UHF)

Claims (5)

An input terminal to which a television signal is input;
A first high-frequency circuit connected to the input end and having a first band as a reception band;
A second high-frequency circuit connected to the input end in parallel with the first high-frequency circuit and having a second band different from the first band as a reception band;
A switching element that is provided between the input terminal and the second high-frequency circuit, and is made of a semiconductor that is turned off when the first band is selected and turned on when the second band is selected;
A first AGC circuit that is provided in the first high-frequency circuit and applies a bias voltage that increases or decreases in the reverse direction in conjunction with the AGC voltage to the switching element during reception of the first band;
A second AGC circuit that is provided in the second high-frequency circuit and applies a bias voltage that increases or decreases in a reverse direction in conjunction with the AGC voltage to the switching element when receiving a second band;
Comprising
The switching element is characterized in that a current flowing through the switching element or a voltage applied between both ends of the switching element varies in the same direction as the change level of the signal level according to the level of the level of the television signal. TV tuner input circuit. The first AGC circuit has a first amplifier circuit whose gain is controlled by an AGC voltage,
The second AGC circuit has a second amplifier circuit whose gain is controlled by an AGC voltage,
The switching element is connected in a direct current manner between the input terminal of the first amplifier circuit and the input terminal of the second amplifier circuit,
The bias voltage is applied to the switching element from the input terminal of the amplification circuit of the AGC circuit on the side selected as the reception band, and the input terminal of the amplification circuit of the AGC circuit on the side not selected as the reception band is DC grounded 2. The television tuner input circuit according to claim 1, wherein:   3. The television tuner input circuit according to claim 1, wherein the switching element is a switching diode. A capacitor connected between the input terminal to which a television signal is input and the cathode of the switching diode;
A transistor having a collector connected to the input terminal of the first amplifier circuit in a direct current, a base connected to the input terminal of the second amplifier circuit in a direct current, and an emitter grounded;
A first resistor connected between an input terminal of the first amplifier circuit and a collector of the transistor, and having a resistance value with a low impedance with respect to the first band;
A second resistor for DC connection between the cathode of the switching diode and the input terminal of the first amplifier circuit;
The switching diode is connected to the anode of the switching diode and the base of the transistor in a direct current manner. When receiving the first band, the anode of the switching diode and the base of the transistor are grounded, and when receiving the second band, the switching diode is connected to the switching diode. A changeover switch that outputs a DC voltage that is a forward bias voltage,
The input circuit of the television tuner according to any one of claims 1 to 3, further comprising: The first high-frequency circuit is a VHF band receiving circuit;
The second high-frequency circuit is a UHF band receiving circuit.
5. An input circuit for a television tuner according to claim 1, wherein the input circuit is a television tuner.

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