JP2008035205A - Television tuner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a television tuner capable of respectively excellently receiving digital television signals and analog broadcast television signals by simple constitution. <P>SOLUTION: The digital television signals and/or the analog broadcast television signals are input to the television tuner. An intermediate frequency tuning circuit 15 respectively separately has a first resonance circuit 15a and a second resonance circuit 15b whose resonance frequency is different from that of the first resonance circuit 15a. The intermediate frequency tuning circuit 15 is constituted of only the first resonance circuit 15a when receiving the digital television signals, and the intermediate frequency tuning circuit 15 is constituted by adding the second resonance circuit 15b to the first resonance circuit 15a when receiving the analog television signals. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a television tuner, and more particularly to a television tuner that can selectively receive a digital television signal and an analog television signal.

  FIG. 15 shows a configuration of an example of a conventional television tuner.

  A digital television signal and an analog television signal are input to the input tuning circuit 101. The digital television signals are arranged in so-called empty channels other than the channels on which conventional analog television signals are arranged. One of the television signals roughly selected by the input tuning circuit 101 is amplified by the high frequency amplifier 102 and then input to the interstage tuning circuit 103. The tuning frequency of the interstage tuning circuit 103 and the tuning frequency of the input tuning circuit 101 are formed so as to be linked. In the interstage tuning circuit 103, the television signal of the adjacent channel is further removed, and the selected television signal is input to the mixer 104. A local oscillation signal is supplied to the mixer 104 from an oscillator (not shown). In the mixer 104, the input television signal is frequency-converted to an intermediate frequency band (41 MHz to 47 MHz in the US specification). Therefore, the converted signal (intermediate frequency signal) includes a digital television signal and an analog television signal. The intermediate frequency signal is input to the intermediate frequency amplifier 106 through the intermediate frequency tuning circuit 105 (see Patent Document 1).

  As shown in FIG. 16, the intermediate frequency tuning circuit 105 includes a parallel tuning circuit including one capacitor 105C and two inductors 105L, and the tuning frequency is higher than the center of the intermediate frequency band, and is almost in the middle of the video. It is in the vicinity of the frequency (45.75 MHz in the US specification). A power supply voltage Vcc is supplied to an intermediate portion between the two inductors 105L, and is grounded via a capacitor 105Ca.

  The output of the intermediate frequency amplifier circuit 106 is output to an analog signal processing unit (not shown) in the subsequent stage through an analog output terminal 107A, and sequentially passes through a saw filter 108 and a digital amplifier circuit 109, and then through two digital output terminals 107D. It is formed so as to be output to a digital signal processing unit (not shown) at the subsequent stage.

  Further, as shown in FIG. 16, due to the modularization of the tuner that receives the digital television signal and the analog television signal, at least the mixer 104 and the intermediate frequency amplifier 106 are built in the IC chip 100. The intermediate frequency tuning circuit 105 is connected to the two output terminals 110 and 111 (MIXout) of the mixer 104 of the IC chip 100.

  In the television tuner formed as described above, the digital television signal input from the interstage tuning circuit 103 to the mixer 104 is subjected to the action of the mixer 104 and the intermediate frequency tuning circuit 105, and the response shown in FIG. Output with characteristics. In FIG. 6, A indicates the output level of Pix, B indicates the output level of chroma, C indicates the output level of audio, and D indicates the output level of adjacent channels.

JP 2004-048121 A

  In the conventional television tuner formed in this way, in order to receive a digital signal, in order to maintain a wide band characteristic as the intermediate frequency tuning circuit 105, the capacitance of the inductor 105L is increased and the capacitance of the capacitor 105C is increased. It is small. For this reason, what can be used as the inductor 105L is not a conventional air core type but a chip type, and naturally the frequency cannot be adjusted. The output of the mixer 104 and the input of the intermediate frequency amplifier circuit 106 are connected to each other in the IC chip 100, and the intermediate frequency is between two output terminals 110 (MIXout) provided in the IC chip 100. The tuning circuit 105 is formed, and the circuit cannot be added on the signal line in the IC chip 100.

  In order to obtain a modular television tuner that supports both digital and analog under these conditions, it is necessary to solve the following problems.

  Problem 1: With respect to the response characteristic of the intermediate frequency amplifier circuit 106, when one digital television signal is received, a good response characteristic can be obtained over a wide band, and when the other analog television signal is received. Can obtain good response characteristics in a narrow band range.

  Problem 2: To obtain the following response characteristic of the intermediate frequency amplifier circuit 106 in order to ensure reception performance when receiving an analog television signal.

  1) Attenuate the chroma level and audio level from the time of digital television signal reception to improve audio beat.

  2) To match with an analog saw filter (not shown) and ensure the frequency characteristics of the video signal, the Pix level can be set to the peak value of the response characteristics.

  3) In order to improve the resistance to interference from adjacent channels, the response characteristic in the vicinity of Pix + 1.5 MHz can be attenuated.

  The present invention has been made in view of these points, and an object thereof is to provide a television tuner that can solve the above-described problems with a simple configuration.

  Further, the present invention provides a television tuner capable of selectively receiving a digital television signal and an analog television signal. As a response characteristic of the intermediate frequency amplifier circuit, when receiving one of the digital television signals, a wide band is provided. Another object of the present invention is to provide a television tuner capable of obtaining a good response characteristic over a wide range and obtaining a good response characteristic in a narrow band when receiving the other analog television signal. And

  Further, according to the present invention, when an analog television signal is received, the chroma level and the audio level can be attenuated from the time when the digital television signal is received, and the Pix level is set to be a peak value of the response characteristic. Another object of the present invention is to provide a television tuner that can attenuate the response characteristic in the vicinity of Pix + 1.5 MHz.

  In order to achieve the above object, the television tuner according to the present invention is characterized in that a digital television signal and / or an analog broadcast television signal are input and converted into an intermediate frequency band signal, and a subsequent stage of the mixing circuit. And an intermediate frequency amplifier circuit provided at a subsequent stage of the intermediate frequency tuning circuit, wherein the intermediate frequency tuning circuit includes a first resonance circuit and The second resonance circuit having a different resonance frequency from the first resonance circuit is separately provided, and when the digital television signal is received, the intermediate frequency tuning circuit is provided only by the first resonance circuit. When the analog television signal is received, the intermediate frequency tuning circuit is configured by adding a second resonance circuit to the first resonance circuit. And wherein the door.

  According to the television tuner of the present invention, it is possible to provide a television tuner that can satisfactorily receive a digital television signal and an analog broadcast television signal with a simple configuration.

  Another feature of the television tuner according to the present invention is that the output circuit of the mixing circuit, the input circuit of the intermediate frequency amplifier circuit, and the intermediate frequency tuning circuit are each constituted by a balanced circuit, and the first resonant circuit Is constituted by a parallel resonance circuit of a capacitor and an inductor, the parallel resonance circuit is connected between the balanced output circuits of the mixing circuit, and the resonance frequency of the first resonance circuit is set to the center frequency of the reception channel frequency. The second resonant circuit is connected in series between one output end of the mixing circuit and one input end of the intermediate frequency amplifier circuit, and a switching element is provided in parallel with the second resonant circuit. And the second resonant circuit is constituted by a series connection circuit of a capacitor and an inductor and a parallel connection circuit of a capacitor, and the digital television signal receiving circuit. Sometimes, when the switching element is turned on, and when the analog television signal is received, the switching element is turned off, and the parallel resonant frequency of the second resonance circuit when the switching element is turned off is below the receiving channel. A frequency in the adjacent channel is set, and a series resonance frequency of the first resonance circuit when the switching element is turned off is set to a frequency in the reception channel.

  According to the television tuner of the present invention, when one digital television signal is received as a response characteristic of the intermediate frequency amplifier circuit, a good response characteristic can be obtained over a wide band, and the other analog television is provided. In the case of receiving a signal, good response characteristics can be obtained in a narrow band range. Further, according to the present invention, when an analog television signal is received, the chroma level and the audio level can be attenuated from the time when the digital television signal is received, and the Pix level is set to be a peak value of the response characteristic. It is possible to attenuate the response characteristic when the frequency is in the vicinity of Pix + 1.5 MHz.

  Further, another high-frequency circuit television tuner according to the present invention is characterized in that the output circuit of the mixing circuit, the input circuit of the intermediate frequency amplifier circuit, and the intermediate frequency tuning circuit are each constituted by a balanced circuit, and the first circuit The resonant circuit is constituted by a parallel resonant circuit of a capacitor and an inductor, the parallel resonant circuit is connected between the balanced output circuits of the mixing circuit, and the resonant frequency of the first resonant circuit is set to the center frequency of the reception channel frequency. Setting, and connecting the second resonance circuit via a switching element between one output end of the mixing circuit and the ground, and connecting the second resonance circuit to a series connection circuit of a capacitor and an inductor and a capacitor And switching the switching element off when receiving the digital television signal, and the analog television The first resonant circuit and the second resonant circuit formed between one output terminal of the mixing circuit and the ground when the switching element is turned on when the switching signal is received. Is set between the output terminal of the mixing circuit and the ground when the switching element is turned on. The parallel resonance frequency of the combined circuit of the first resonance circuit and the second resonance circuit is set to a frequency in the reception channel.

  According to the television tuner of the present invention, when one digital television signal is received as a response characteristic of the intermediate frequency amplifier circuit, a good response characteristic can be obtained over a wide band, and the other analog television is provided. In the case of receiving a signal, good response characteristics can be obtained in a narrow band range. Further, according to the present invention, when an analog television signal is received, the chroma level and the audio level can be attenuated from the time when the digital television signal is received, and the Pix level is set to be a peak value of the response characteristic. It is possible to attenuate the response characteristic when the frequency is in the vicinity of Pix + 1.5 MHz.

  Another feature of the television tuner according to the present invention is that a capacitor is interposed between one output end of the mixing circuit and the hot side of the second resonance circuit and in series with the switching element. It is characterized by that.

  According to the television tuner of the present invention, it is possible to further suppress the signals of the upper adjacent channel portion and the lower adjacent channel portion without lowering the Pix level of the reception channel.

  As described above, according to the television tuner of the present invention, it is possible to obtain a television tuner that can satisfactorily receive a digital television signal and an analog broadcast television signal with a simple configuration.

  Hereinafter, embodiments of a television tuner according to the present invention will be described with reference to the drawings.

[First embodiment]
1 to 3 are circuit diagrams showing a first embodiment of the television tuner of the present invention.

  In the first embodiment, the intermediate frequency tuning circuit 15 is formed in a configuration different from the conventional one, and the other input tuning circuit 11, high frequency amplifier 12, interstage tuning circuit 13, mixer 14 and intermediate frequency amplifier 16 are shown in FIG. It is formed in substantially the same manner as the conventional example shown in FIG.

  Further, the intermediate frequency tuning circuit 15 of the present embodiment includes the first resonance circuit 15a shown in FIG. 2 and the first resonance circuit 15a so that the bandwidth can be switched between the digital television signal reception and the analog television signal reception. The first resonance circuit 15a is formed with a second resonance circuit 15b having a different resonance frequency. The roles of the first and second resonance circuits 15a and 15b are to form the intermediate frequency tuning circuit 15 with only the first resonance circuit 15a when receiving a digital television signal and to perform intermediate frequency tuning when receiving an analog television signal. The circuit 15 is formed by adding the second resonance circuit 15b to the first resonance circuit 15a.

  More specifically, the output circuit of the mixing circuit 14, the input circuit of the intermediate frequency amplifier circuit 16, and the intermediate frequency tuning circuit 15 are each formed by a balanced circuit.

  The first resonance circuit 15a is formed by a parallel resonance circuit of a capacitor 15aC and an inductor 15aL as in the conventional example, and a power supply voltage Vcc is supplied to an intermediate portion between the two inductors 15aL. It is grounded via a capacitor 15Ca. Further, due to the modularization of the tuner that receives digital television signals and analog television signals, at least the mixer 14 and the intermediate frequency amplifier 16 are built in the IC chip 10 as shown in FIG. The first resonance circuit 15 a of the intermediate frequency tuning circuit 15 is connected to the two balanced output terminals 20 and 21 (MIXout) of the mixer 14 of the IC chip 10. The resonance frequency of the first resonance circuit 15a is set to the center frequency of the reception channel frequency.

  The second resonance circuit 15b is connected in series between one output terminal 21 of the mixing circuit 14 and one input terminal 22 of the intermediate frequency amplifier circuit 16, and a series connection circuit of a capacitor 15bC and an inductor 15bL. And a capacitor 15bCa in parallel connection circuit. A switching element composed of a diode 15D for turning on and off the second resonance circuit 15b is connected in parallel to the second resonance circuit 15b. The switching element 15D is turned on when a digital television signal is received, and is turned off when an analog television signal is received. Then, the parallel resonance frequency of the second resonance circuit 15b when the switching element 15D is turned off is set to the frequency in the channel adjacent to the lower side of the reception channel, and the first when the switching element 15D is turned off. The resonance frequency of the resonance circuit 15a is set to the frequency in the reception channel.

  A switching transistor Sw for turning on / off the switching element 15D is provided in the IC chip 10. The collector of the switching transistor Sw is connected to the input terminal 22 via a resistor R1 which is a conducting element, and is connected to the supply terminal 23 of the power supply voltage Vcc via a resistor R2 which is a conducting element. The emitter of the switching transistor Sw is grounded.

  Further, the output of the intermediate frequency amplifier circuit 16 is output to an analog signal processing unit (not shown) at the subsequent stage through the analog output terminal 17A as in the prior art, and passes through the saw filter 18 and the digital amplifier circuit 19 in order. It is configured to be output to a subsequent digital signal processing section (not shown) through the digital output terminal 17D.

  Next, the operation of the first embodiment will be described.

  A digital television signal and an analog television signal are input to the input tuning circuit 11.

  In order to receive a digital television signal in this state, a command to turn on the switching transistor Sw is given to the gate of the transistor Sw from a control unit (not shown) provided in the IC chip 10. Turn on.

  Thereby, the switching element 15D is turned on, and a current flows from the power supply voltage Vcc in the order of the inductor 15aL, the switching element 15D, the resistor R1, the switching transistor Sw, and the ground. As a result, the second resonance circuit 15b is disabled, and only the first resonance circuit 15a operates as the intermediate frequency tuning circuit 15. Since the resonance frequency of the first resonance circuit 15a is set to the center frequency of the reception channel frequency, the response characteristic over a wide band is improved, and it is suitable for receiving a digital television signal like the a line in FIG. Characteristics are output. In FIG. 3A, Aa indicates the output level of Pix, Ba indicates the output level of chroma, Ca indicates the output level of audio, and Da indicates the output level of the adjacent channel.

  Next, when receiving an analog television signal, a control unit (not shown) provided in the IC chip 10 gives a command to turn off the switching transistor Sw to the gate of the transistor Sw. Turn off.

  As a result, since the power supply voltage Vcc is connected to both the anode and the cathode of the diode forming the switching element 15D, the switching element 15D is turned off, and the second resonance circuit 15b is activated. As a result, as the intermediate frequency tuning circuit 15, the first resonance circuit 15a and the second resonance circuit 15b provided between the first resonance circuit 15a and the intermediate frequency amplifier 16 operate together. When both the resonance circuits 15a and 15b operate, the resonance frequency of the first resonance circuit 15a is set to the center frequency of the reception channel frequency, and the parallel resonance frequency of the second resonance circuit 15b is adjacent to the lower side of the reception channel. Since the frequency within the channel is set, response characteristics as shown by line b in FIG. 3 can be obtained. The characteristics can be narrowed, the Pix level Ab can be set to the peak value of the response characteristics, and matching with an analog saw filter (not shown) can be achieved. Further, the chroma level Bb and the audio level Cb can be attenuated from when the digital television signal is received, and the audio Beat can be improved. Furthermore, the response characteristic when the frequency is in the vicinity of Pix + 1.5 MHz can be attenuated, and the output level Db of the adjacent channel can be attenuated to improve the interference resistance from the adjacent channel. Moreover, since the peak point of the response characteristic can be adjusted by finely adjusting the value of the inductor 15bL of the second resonance circuit 15b, the Pix level Ab can be easily set to the peak point.

[Second Embodiment]
4 to 9 are circuit diagrams showing the intermediate frequency tuning circuit portion of the second embodiment of the television tuner of the present invention.

  In the second embodiment, the intermediate frequency tuning circuit 35 is different from the first resonance circuit 35a having the same configuration as the first resonance circuit 15a in the first embodiment, and the second resonance circuit 15b in the first embodiment. The second resonance circuit 35b is configured.

  Further, the intermediate frequency tuning circuit 35 of the present embodiment includes the first resonance circuit 35a shown in FIG. 4 and the first resonance circuit 35a so that the bandwidth can be switched between the digital television signal reception and the analog television signal reception. The first resonance circuit 35a is formed with a second resonance circuit 35b having a different resonance frequency. The roles of the first and second resonance circuits 35a and 35b are to form the intermediate frequency tuning circuit 35 with only the first resonance circuit 35a when receiving a digital television signal, and to perform the intermediate frequency tuning when receiving an analog television signal. The circuit 35 is formed by adding a second resonance circuit 35b to the first resonance circuit 35a.

  The first resonance circuit 35a is formed by a parallel resonance circuit of a capacitor 35aC and an inductor 35aL as in the conventional example, and a power supply voltage Vcc is supplied to an intermediate portion between the two inductors 35aL. It is grounded via a capacitor 35Ca. The first resonance circuit 35 a is connected to the two balanced output terminals 20 and 21 (MIXout) of the mixer 14 of the IC chip 10. The resonance frequency of the first resonance circuit 35a is set to the center frequency of the reception channel frequency.

  The second resonance circuit 15b is connected between one output terminal 21 of the mixing circuit 14 and the ground via a switching element including a resistor R3 and a diode 35D, which are conductive elements, and includes a capacitor 35bC and an inductor 35bL. It is formed by a parallel connection circuit of a series connection circuit and a capacitor 15bCa. The switching element 35D for turning on / off the second resonance circuit 35b is turned off when the digital television signal is received, and turned on when the analog television signal is received. When the switching element 35D is turned on, the series resonance frequency of the combined circuit of the first resonance circuit 35a and the second resonance circuit 35b formed between the one output terminal 21 of the mixing circuit 14 and the ground is set. The first resonance circuit 35a formed between one output terminal 21 of the mixing circuit 14 and the ground when the frequency in the channel adjacent to the lower side of the reception channel is set and the switching element 35D is turned on. The parallel resonance frequency of the synthesis circuit with the second resonance circuit 35b is set to the frequency in the reception channel.

  A switching transistor Sw1 for turning on / off the switching element 35D is provided in the IC chip 10. The collector of the switching transistor Sw1 is connected to the supply terminal 23 of the power supply voltage Vcc through the resistor R4, which is a conductive element, and is also connected to the output terminal 24. The output terminal 24 is connected to a connection point between the capacitor 35bC of the second resonance circuit 35b and the inductor 35bL via a resistor R5 which is a conductive element. The emitter of the switching transistor Sw is grounded.

  Next, the operation of the second embodiment will be described.

  A digital television signal and an analog television signal are input to the input tuning circuit 11.

  When a digital television signal is received in this state, as shown in FIG. 5, a command for turning off the switching transistor Sw1 is given to the gate of the transistor Sw1 by a control unit (not shown) provided in the IC chip 10. The transistor Sw1 is turned off. As a result, the power supply voltage Vcc is connected to both the anode and the cathode of the diode forming the switching element 35D, so that the switching element 35D is turned off and the second resonance circuit 35b is disabled.

  As a result, only the first resonance circuit 35a operates as the intermediate frequency tuning circuit 35. The relationship of the impedance between the L property and the C property of the first resonance circuit 35a is as shown in FIG. Since the resonance frequency of the first resonance circuit 35a is set to the center frequency of the reception channel frequency, the response characteristic over a wide band is improved, and it is suitable for receiving a digital television signal like the a line in FIG. Characteristics are output. In line a of FIG. 7, Aa indicates the output level of Pix, Ba indicates the output level of chroma, Ca indicates the output level of audio, and Da indicates the output level of the adjacent channel.

  Next, when an analog television signal is received, as shown in FIG. 8, a command to turn on the switching transistor Sw1 is given to the gate of the transistor Sw1 by a control unit (not shown) provided in the IC chip 10. The transistor Sw1 is turned on. As a result, current flows from the power supply voltage Vcc in the order of the inductor 35aL, the resistor R3, the switching element 55D, the inductor 36bL, the resistor R5, the switching transistor Sw1, and the ground, thereby enabling the second resonance circuit 35b.

  As a result, the intermediate frequency tuning circuit 35 is connected between the first resonance circuit 35a and the one output terminal 21 of the mixing circuit 14 and the ground via a switching element composed of a resistor R3 and a diode 35D. The second resonance circuit 15b is operated together. When both the resonance circuits 35a and 35b are operated, as shown in FIG. 6B, the relationship between the impedance of the first resonance circuit 35a and the L property is the same as that when the digital television signal shown in FIG. Moving to a higher frequency, the impedance relationship between the L property and the C property of the second resonance circuit 35b is lower than that of the first resonance circuit 35a. A position is obtained between the two. When the switching element 35D is turned on, the series resonance frequency of the combined circuit of the first resonance circuit 35a and the second resonance circuit 35b formed between the one output terminal 21 of the mixing circuit 14 and the ground is The first resonance formed between the one output terminal 21 of the mixing circuit 14 and the ground when the switching element 35D is turned on, and is set to the frequency in the channel adjacent to the lower side of the reception channel. Since the parallel resonance frequency of the combined circuit of the circuit 35a and the second resonance circuit 35b is set to the frequency in the reception channel, response characteristics as shown by the b line in FIG. 7 are obtained. The characteristics can be narrowed, the Pix level Ab can be set to the peak value of the response characteristics, and matching with an analog saw filter (not shown) can be achieved. Further, the chroma level Bb and the audio level Cb can be attenuated from when the digital television signal is received, and the audio Beat can be improved. Furthermore, the response characteristic when the frequency is in the vicinity of Pix + 1.5 MHz can be attenuated, and the output level Db of the adjacent channel can be attenuated to improve the interference resistance from the adjacent channel. Further, as shown in FIG. 9, it can be seen that the transmission characteristic a when receiving a digital television signal is a wide band, and the transmission characteristic b when receiving an analog television signal is a narrow band. Moreover, since the peak point of the response characteristic can be adjusted by finely adjusting the value of the inductor 35bL of the second resonance circuit 35b, the Pix level Ab can be easily set to the peak point.

[Third embodiment]
10 to 14 are circuit diagrams showing an intermediate frequency tuning circuit portion of the third embodiment of the television tuner of the present invention.

  In the third embodiment, in order to connect the second resonance circuit 35b of the intermediate frequency tuning circuit 35 and one output terminal 21 of the mixing circuit 14 in the second embodiment, a resistor R3 and a diode that are conductive elements are connected. What is connected via a switching element made of 35D is connected using a capacitor 35C as a capacitive element instead of the resistor R3 which is a conducting element. Further, in order to enable energization to the switching element 35D, the connection point between the inductor 35aL and the capacitor 35Ca and the connection point between the switching element 35D and the capacitive element 35C are connected by R6 which is a conduction element. . Others are formed similarly to the second embodiment.

  Next, the operation of the third embodiment will be described.

  A digital television signal and an analog television signal are input to the input tuning circuit 11.

  When a digital television signal is received in this state, as shown in FIG. 11, a command to turn off the switching transistor Sw1 is given to the gate of the transistor Sw1 by a control unit (not shown) provided in the IC chip 10. The transistor Sw1 is turned off. As a result, since the power supply voltage Vcc is connected to both the anode and the cathode of the diode forming the switching element 35D, the switching element 35D is turned off, and the second resonance circuit 35b is disabled, as in the second embodiment. In addition, only the first resonance circuit 35a acts to output response characteristics suitable for receiving a digital television signal such as the a line in FIG.

  Next, when receiving an analog television signal, as shown in FIG. 12, a command to turn on the switching transistor Sw1 is given to the gate of the transistor Sw1 by a control unit (not shown) provided in the IC chip 10. The transistor Sw1 is turned on. As a result, the current flows from the power supply voltage Vcc in the order of the resistor R6, the switching element 35D, the inductor 36bL, the resistor R5, the switching transistor Sw1, and the ground, thereby enabling the second resonance circuit 35b.

  As a result, the intermediate frequency tuning circuit 35 is connected to the first resonance circuit 35a and the first output terminal 21 of the mixing circuit 14 and the ground through the switching element including the capacitive element 35C and the diode 35D. The two resonance circuits 15b operate together. When both the resonance circuits 35a and 35b are operated, and when the switching element 35D is turned on, the first resonance circuit 35a and the second resonance circuit formed between the one output terminal 21 of the mixing circuit 14 and the ground. The series resonance frequency of the synthesis circuit with 35b is set to the frequency in the channel adjacent to the lower side of the reception channel, and one output terminal 21 of the mixing circuit 14 and the ground when the switching element 35D is turned on. The parallel resonance frequency of the combined circuit of the first resonance circuit 35a and the second resonance circuit 35b formed between the two is set to the frequency in the reception channel, and is further connected with the capacitive element 35C. As a result, response characteristics as indicated by line b in FIG. 13 are obtained. As in the second embodiment, the characteristics can be narrowed, the Pix level Ab can be set to the peak value of the response characteristics, and matching with an analog saw filter (not shown) can be achieved. . Further, the chroma level Bb and the audio level Cb can be attenuated from when the digital television signal is received, and the audio Beat can be improved. Furthermore, the response characteristic when the frequency is in the vicinity of Pix + 1.5 MHz can be attenuated, and the output level Db of the adjacent channel can be attenuated to improve the interference resistance from the adjacent channel. Further, since the capacitive element 35C is used, the signals of the upper adjacent channel part (c part in FIG. 13) and the lower adjacent channel part (d part in FIG. 13) are transmitted without reducing the Pix level of the receiving channel. It can be further suppressed. As shown in FIG. 14, the transmission characteristic b when the capacitive element 35C is used is higher than the transmission characteristic a when the conductive element R3 is used. It can be seen from the fact that it is further reduced in the lower adjacent channel portion (d portion in FIG. 14). Moreover, since the peak point of the response characteristic can be adjusted by finely adjusting the value of the inductor 35bL of the second resonance circuit 35b, the Pix level Ab can be easily set to the peak point.

  In addition, this invention is not limited to the said embodiment, A various change is possible as needed.

The circuit diagram which shows 1st embodiment of the television tuner of this invention The circuit diagram which shows the intermediate frequency tuning circuit of 1st embodiment of this invention The diagram which shows the response characteristic of the intermediate frequency tuning circuit part of 1st embodiment of this invention The circuit diagram which shows 2nd embodiment of the intermediate frequency tuning circuit of this invention Circuit diagram of intermediate frequency tuning circuit shown in FIG. 4 when receiving digital television signal FIG. 5 is a characteristic diagram showing impedance characteristics of the intermediate frequency tuning circuit of FIG. 4, wherein (a) shows a time when a digital television signal is received, and (a) shows a time when an analog television signal is received. The diagram which shows the response characteristic of the intermediate frequency tuning circuit part of 2nd Embodiment Circuit diagram of the intermediate frequency tuning circuit shown in FIG. 4 when receiving an analog television signal The diagram which shows the transmission characteristic of the intermediate frequency tuning circuit part of 2nd Embodiment The circuit diagram which shows 3rd embodiment of the intermediate frequency tuning circuit of this invention Circuit diagram of intermediate frequency tuning circuit shown in FIG. 10 when receiving digital television signal Circuit diagram of intermediate frequency tuning circuit shown in FIG. 10 when receiving analog television signal The diagram which shows the response characteristic of the intermediate frequency tuning circuit part shown in FIG. Diagram showing transmission characteristics of intermediate frequency tuning circuit shown in FIGS. 11 and 12 Circuit diagram showing a conventional television tuner Circuit diagram showing a conventional intermediate frequency tuning circuit Diagram showing response characteristics of conventional intermediate frequency tuning circuit

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Input tuning circuit 12 High frequency amplifier 13 Interstage tuning circuit 14 Mixing circuit 15, 35 Intermediate frequency tuning circuit 15a, 35a First resonance circuit 15b, 35b Second resonance circuit 16 Intermediate frequency amplification circuit

Claims (4)

A digital television signal and / or an analog broadcast television signal are inputted and converted to an intermediate frequency band signal, an intermediate frequency tuning circuit provided at a subsequent stage of the mixing circuit, and an intermediate stage of the intermediate frequency tuning circuit A television tuner comprising an intermediate frequency amplifier circuit provided,
The intermediate frequency tuning circuit has a first resonance circuit and a second resonance circuit different in resonance frequency from the first resonance circuit, respectively.
At the time of receiving the digital television signal, the intermediate frequency tuning circuit is constituted only by the first resonance circuit,
A television tuner characterized in that, when receiving the analog television signal, the intermediate frequency tuning circuit is configured by adding a second resonance circuit to the first resonance circuit. The output circuit of the mixing circuit, the input circuit of the intermediate frequency amplifier circuit, and the intermediate frequency tuning circuit are each constituted by a balanced circuit,
The first resonance circuit is constituted by a parallel resonance circuit of a capacitor and an inductor,
Connecting the parallel resonant circuit between the balanced output circuits of the mixing circuit;
Set the resonance frequency of the first resonance circuit to the center frequency of the reception channel frequency,
The second resonance circuit is connected in series between one output end of the mixing circuit and one input end of the intermediate frequency amplifier circuit,
Connecting a switching element in parallel with the second resonant circuit;
The second resonant circuit is composed of a capacitor and inductor series connection circuit and a capacitor parallel connection circuit,
When the digital television signal is received, the switching element is turned on, and when the analog television signal is received, the switching element is turned off,
The parallel resonance frequency of the second resonance circuit when the switching element is turned off is set to a frequency in a channel adjacent to the lower side of the reception channel, and the first resonance when the switching element is turned off The television tuner according to claim 1, wherein the series resonance frequency of the circuit is set to a frequency in the reception channel. The output circuit of the mixing circuit, the input circuit of the intermediate frequency amplifier circuit, and the intermediate frequency tuning circuit are each constituted by a balanced circuit,
The first resonance circuit is constituted by a parallel resonance circuit of a capacitor and an inductor,
Connecting the parallel resonant circuit between the balanced output circuits of the mixing circuit;
Set the resonance frequency of the first resonance circuit to the center frequency of the reception channel frequency,
The second resonance circuit is connected via a switching element between one output end of the mixing circuit and the ground,
The second resonant circuit is composed of a capacitor and inductor series connection circuit and a capacitor parallel connection circuit,
When the digital television signal is received, the switching element is turned off, and when the analog television signal is received, the switching element is turned on,
When the switching element is turned on, the series resonance frequency of the combined circuit of the first resonance circuit and the second resonance circuit formed between one output terminal of the mixing circuit and the ground is set to the reception channel. The first resonance circuit and the second resonance circuit formed between one output end of the mixing circuit and the ground when the frequency in the channel adjacent to the lower side is set and the switching element is turned on The television tuner according to claim 1, wherein the parallel resonance frequency of the synthesis circuit is set to a frequency in the reception channel. 4. The television tuner according to claim 3, wherein a capacitor is interposed between one output end of the mixing circuit and a hot side of the second resonance circuit and in series with the switching element. .

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