JP4043214B2 - Television tuner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television tuner, and more particularly to a television tuner having a coupling varactor diode for coupling a double tuning circuit that tunes to a VHF band high band or low band television signal and a frequency conversion mixer. To do.
[0002]
[Prior art]
FIG. 4 shows a circuit diagram of a conventional television tuner. The input tuning circuit 31 to which a VHF band television signal is input is constituted by a single tuning circuit, in which a switching diode 31a and a tuning varactor diode 31b are provided. The switch diode 31a is switched on or off, and the input tuning circuit 31 is switched to tune to the high band or low band of the VHF band. A tuning voltage is applied from the tuning voltage terminal Tu to the tuning varactor diode 31b. The anode of the tuning varactor diode 31b is grounded, and the tuning frequency is changed in any band by changing the tuning voltage applied to the cathode.
[0003]
A high-frequency amplifier 32 is provided at the next stage of the input tuning circuit 31, and an FET (not shown) is used as an amplification element.
[0004]
A double tuning circuit 33 is provided at the next stage of the high frequency amplifier 32. Although the structure of the double tuning circuit 33 is shown in a simplified manner, a high band coil 33a and a low band coil 33b connected in series to each other on the primary side, and a tuning varactor diode 33c connected in parallel to these, A switch diode 33d connected in parallel to the low band coil 33b is provided.
[0005]
Similarly, on the secondary side, a high-band coil 33e and a low-band coil 33f connected in series to each other, a tuning varactor diode 33g connected in parallel thereto, and a switch diode 33h connected in parallel to the low-band coil 3f. And are provided. The anodes of the two tuning varactor diodes 33c and 33g are grounded, and the tuning voltage is applied to the cathode from the tuning voltage terminal Tu. Further, the two switch diodes 33d and 33h are both switched to be turned on or off, and accordingly, the double tuning circuit 33 is switched to be tuned to a high band or a low band. The tuning frequency is changed in any band by changing the tuning voltage applied to the cathodes of the tuning varactor diodes 33c and 33g.
[0006]
A mixer 34 for frequency conversion is provided at the next stage of the double tuning circuit 33. The mixer 34 is coupled to the double tuning circuit 33 via a coupling varactor diode 35. The cathode of the coupling varactor diode 35 is connected to the cathode of the secondary tuning varactor diode 33g, and the anode is connected to the resistor 36. Connected to the ground and connected to the mixer 34 via a DC cut capacitor 37. The mixer 34 is supplied with a local oscillation signal from a local oscillator 38.
[0007]
In the above configuration, the tuning varactor diode 31b in the input tuning circuit 31, the two tuning varactor diodes 33c and 33g in the double tuning circuit 33, and the coupling varactor diode 35 all have the same characteristics. As shown in FIG. 5, the slope of the change in the capacitance value is steep in the range where the tuning voltage is low, whereas the slope of the change in the capacitance value becomes slow at a certain high voltage. .
[0008]
The variable range of the tuning voltage applied to the cathodes of the tuning varactor diodes 31b, 33c and 33g and the coupling varactor diode 35 is determined by the range of the tuning frequency required for the tuning circuits 31 and 33. Is approximately 2.5 to 25 volts, and in the case of a low band, approximately 2.5 to 21 volts. That is, when the tuning voltage is 2.5 volts, the tuning is performed to the lowest frequency of each band. The capacitance values of the tuning varactor diodes 31b, 33c and 33g and the coupling varactor diode 35 at this time are approximately 14.5 pF (picofarad) as shown in FIG.
[0009]
Then, the television signal roughly selected by the input tuning circuit 31 is amplified by the high frequency amplifier 32, and the television signal sharply selected by the double tuning circuit 33 is input to the mixer 34. The mixer 34 mixes with the local oscillation signal and outputs an intermediate frequency signal.
[0010]
[Problems to be solved by the invention]
In general, the gain of a television tuner decreases as the frequency of the receiving channel decreases from the Q of each tuning circuit and the impedance matching state between the stages. For example, in the low band, the tuning voltage is 2.5 as shown in FIG. The lowest channel frequency at which the voltage is volt is about 38 dB , the tuning voltage is about 42 dB when the tuning voltage is 21 volts, and the gain deviation within the same band is as large as 4 dB. As for NF (noise figure), the deterioration on the low frequency side is conspicuous at 6.3 dB for the lowest channel and 4.4 dB when the tuning voltage is 21 volts.
[0011]
To correct such gain deviation and NF deterioration in the same band, the capacitance value at the lowest tuning voltage (2.5 volts) is larger and the ratio to the capacitance value when the tuning voltage is lowered. However, it is only necessary to use a varactor diode having a large size for coupling and to make the double-tuned circuit 33 and the mixer 34 tightly coupled in a low frequency region. However, such a varactor diode is expensive.
[0012]
Therefore, in the present invention, the same band can be obtained by using a varactor diode having the same characteristics as that used in the double-tuned circuit for coupling the double-tuned circuit and the mixer without using an expensive and special varactor diode. The purpose is to level out the gain deviation.
[0013]
[Means for Solving the Problems]
As means for solving the above-described problems, the present invention has a primary and secondary tuning varactor diodes, and a tuning frequency is changed by a tuning voltage applied to the cathodes of both tuning varactor diodes. A tuning circuit; a mixer provided downstream of the double tuning circuit; and a coupling varactor diode for coupling the secondary double tuning circuit to the mixer, the tuning varactor diode and the coupling The cathodes of the varactor diodes were connected to each other, and a bias voltage higher than the anode voltage of the tuning varactor diode and lower than the lowest voltage of the tuning voltage was applied to the anode of the coupling varactor diode.
[0014]
The mixer includes a transistor having a base bias voltage applied to a base, the anode of the tuning varactor diode is grounded, the anode of the coupling varactor diode is directly connected to the base of the transistor, and the anode The bias voltage applied to the base voltage is the same as the base bias voltage .
[0015]
In addition, the double tuning circuit is configured by a band switching type tuning circuit that can be switched to tune to a VHF band high band or low band television signal.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
The present invention will be described below with reference to the drawings. In FIG. 1, an input tuning circuit 1 to which a VHF band television signal is input is constituted by a single tuning circuit, and the input tuning circuit 1 is provided with a switch diode 1a and a varactor diode 1b. The switch diode 1a is switched on or off, and the input tuning circuit 1 is switched to tune to the high band or low band of the VHF band. The anode of the varactor diode 1b is grounded, and a tuning voltage is applied to the cathode from the tuning voltage terminal Tu. Changing the tuning voltage changes the tuning frequency in any band.
[0017]
Then, the television signal selected by the input tuning circuit 1 is input to a high frequency amplifier 2 provided at the next stage and amplified there. An FET (not shown) is used for the amplifying element of the high-frequency amplifier 2.
[0018]
A double tuning circuit 3 is provided at the next stage of the high frequency amplifier 2. On the primary side of the double tuning circuit 3, a high band coil 3a having one end connected to the output end of the high frequency amplifier 2, a low band coil 3b connected in series to the other end of the high band coil 3a, and an anode are grounded. A tuning varactor diode 3c whose cathode is coupled to the output terminal of the high-frequency amplifier 2, a switching diode 3d whose anode is connected to the connection point of the high-band coil 3a and the low-band coil 3b, and whose cathode is grounded in high frequency Is provided.
[0019]
On the secondary side of the double tuning circuit 3, a tuning varactor diode 3e having an anode grounded, a high band coil 3f having one end connected to the cathode, and a low band connected in series to the other end of the high band coil 3f. An anode is connected between the coil 3g, the high band coil 3f, and the low band coil 3g, and a switch diode 3h having a cathode grounded in a high frequency manner is provided.
[0020]
Two low band coils 3b and 3g are connected to each other, one end of a coupling coil 3i for coupling the primary side and the secondary side is connected to the connection point, and the other end is grounded in high frequency. The cathodes of the two tuning varactor diodes 3c and 3e are connected to the tuning voltage terminal Tu. The other end of the coupling coil 3i is connected to the power supply terminal B, and the cathodes of the two switch diodes 3d and 3h are connected to the band switching terminal Sw. A power supply voltage to be supplied to the high-frequency amplifier 2 is applied to the power supply terminal B, and the same voltage as the power supply voltage or 0 volts is applied to the band switching terminal Sw.
[0021]
In the double tuning circuit 3, the switch diodes 3d and 3h are turned on when 0 V is applied to the band switching terminal Sw and tuned to the high band, and when the same voltage as the power supply voltage is applied, the switch diodes 3d and 3h are turned on. Turns off and tunes to the low band. The tuning frequency changes in any band by changing the tuning voltage. The television signal selected by the double tuning circuit 3 is input to a frequency conversion mixer 4 provided at the next stage.
[0022]
The double tuning circuit 3 and the mixer 4 are coupled by a coupling varactor diode 5. At this time, the mixer 4 is constituted by a well-known double balanced mixer (double balance mixer) using a transistor, and the base of one of the two transistors 4a and 4b on the constant current source side in the mixer 4 is the base. The anode of the coupling varactor diode 5 is connected to the cathode, and the cathode is connected to the cathode of the tuning varactor diode 3e on the secondary side. The base of the other transistor 4b is grounded in high frequency. The emitters of the two transistors 4a and 4b are connected to the constant current sources 4c and 4d, respectively, and the bases are connected to the power supply terminal B via the resistors 4e and 4f. As a result, a bias voltage of approximately 2 volts is supplied to each base.
[0023]
Although not shown, two transistors are connected to the collectors of the two transistors 4a and 4b, respectively, and a local oscillation signal is balancedly input between their bases. The mixer 4 outputs an intermediate frequency signal.
[0024]
In the above configuration, the tuning varactor diode 1b in the input tuning circuit 1, the two tuning varactor diodes 3c and 3e in the double tuning circuit 3, and the coupling varactor diode 5 all have the same characteristics. As shown in Fig. 2, when the tuning voltage applied to the cathode is low in the range where the anode is used as a reference, the slope of the change in the capacitance value is steep while the slope of the change in the capacitance value is somewhat high. Has a slow voltage / capacitance characteristic.
[0025]
The variable range of the tuning voltage applied to the cathodes of the tuning varactor diodes 1b, 3c and 3e and the coupling varactor diode 5 is determined by the range of the tuning frequency required for the tuning circuits 1 and 3. It is approximately 2.5 to 25 volts, and in the case of a low band, approximately 2.5 to 21 volts. When the tuning voltage is 2.5 volts, the capacitance values of the tuning varactor diode 1b in the input tuning circuit 1 and the tuning varactor diodes 3c and 3e in the double tuning circuit 3 are 14.5 pF (pico Farad) and tune to the lowest frequency of each band.
[0026]
However, since the coupling varactor diode 5 has the base bias voltage (approximately 2 volts) of the transistor 4a of the mixer 4 applied to its anode, the voltage between the anode and the cathode becomes 0.5 volts. As shown in FIG. 2, the capacitance value is about 31.5 pF, which is twice as large. As a result, in the region where the tuning voltage is close to 2.5 volts, the double tuning circuit 3 and the mixer 4 are tightly coupled, and the level of the television signal input to the mixer 4 increases. On the other hand, when the tuning voltage is increased, the capacitance value of the coupling varactor diode 5 becomes almost the same as that of the conventional one, so that the coupling amount does not change.
[0027]
Therefore, the gain increases at the lower tuning voltage, and there is almost no gain change at the higher tuning voltage. For example, the overall gain in the low band is the lowest at which the tuning voltage is 2.5 volts as shown in FIG. The frequency channel is 40 dB, and when the tuning voltage is 21 volts, it is 42 dB as in the conventional case. Therefore, the gain deviation in the low band is 2 dB, which can be improved by 2 dB as compared with the prior art. Also, NF is 5.8 dB for the lowest channel, and 4.4 dB for a tuning voltage of 21, which can be improved on the low frequency side.
Such an effect can be obtained in the high band as well.
[0028]
Although the anode of the coupling varactor diode 5 is directly connected to the base of the transistor 4a in the mixer 4 to give a bias voltage of 2 volts to the anode, the bias voltage is not limited to this and is applied by a resistance voltage dividing circuit or the like. Of course, you may give it. In any case, the bias voltage applied to the anode of the coupling varactor diode must be higher than the anode voltage of the tuning varactor diode and lower than the minimum value of the tuning voltage. However, by connecting the anode of the coupling varactor diode 5 directly to the base of the transistor 4a in the mixer 4, a resistor (resistor 36 in FIG. 4) for fixing the anode to a DC reference potential point, and the mixer 4 Since the direct-current cut capacitor (the direct-current cut capacitor 37 in FIG. 4) for coupling with can be omitted, there is an effect such as reduction of parts cost.
[0029]
【The invention's effect】
As described above, the television tuner of the present invention has primary and secondary tuning varactor diodes, and the tuning frequency varies depending on the tuning voltage applied to the cathodes of both tuning varactor diodes. A double-tuned circuit; a mixer provided at a subsequent stage of the double-tuned circuit; and a coupling varactor diode that couples the secondary-side double-tuned circuit to the mixer; and the tuning varactor diode and the coupling The cathodes of the varactor diodes are connected to each other, and a bias voltage higher than the anode voltage of the tuning varactor diode and lower than the lowest voltage of the tuning voltage is applied to the anode of the coupling varactor diode. Therefore, in the region where the tuning voltage is low, the double tuning circuit and the mixer are tightly coupled, and in the region where the tuning voltage is high, the coupling amount Thus, the gain deviation in the region where the tuning voltage is low can be increased to level the gain deviation in the same band.
[0030]
The mixer includes a transistor having a base bias voltage applied to a base, the anode of the tuning varactor diode is grounded, the anode of the coupling varactor diode is directly connected to the base of the transistor, and the anode is connected to the anode. Since the applied bias voltage is the same voltage as the base bias voltage, a resistor for fixing the anode of the coupling varactor diode to a DC reference potential point, and a direct current for coupling with the mixer Since cut capacitors can be omitted, parts costs can be reduced.
[0031]
In addition, since the double tuning circuit is composed of a band switching type tuning circuit that can be switched to tune to a VHF band high band or low band television signal, a gain deviation can be achieved in either the high band or the low band. Leveling can be done.
[Brief description of the drawings]
[1] a television tuner of the present voltage / capacitance characteristic diagram of the varactor diodes used in the television tuner circuit diagram invention; FIG showing an example of an embodiment of a television tuner of the invention the present invention; FIG FIG . 4 is a circuit diagram showing an example of an embodiment of a conventional television tuner . FIG . 5 is a voltage / capacitance characteristic diagram of a varactor diode used in a conventional television tuner. FIG. 6 is a characteristic diagram showing the relationship between tuning voltage and gain of a conventional television tuner.
DESCRIPTION OF SYMBOLS 1 Input tuning circuit 1a Switch diode 1b Tuning varactor diode 2 High frequency amplifier 3 Double tuning circuit 3a, 3f High band coil 3b, 3g Low band coil 3c, 3e Tuning varactor diode 3d, 3h Switch diode 3i Coupling coil 4 Mixer 4a, 4b Transistor 4c, 4d Constant current source 4e, 4f Resistor 5 Coupling varactor diode B Power supply terminal Sw Band switching terminal Tu Tuning voltage terminal

Claims (3)

A double tuning circuit having primary and secondary tuning varactor diodes, the tuning frequency of which varies according to the tuning voltage applied to the cathodes of the two tuning varactor diodes; And a coupling varactor diode for coupling the secondary double-tuned circuit to the mixer, the cathodes of the tuning varactor diode and the coupling varactor diode are connected to each other, and A television tuner characterized in that a bias voltage higher than the voltage of the anode of the tuning varactor diode and lower than the lowest voltage of the tuning voltage is applied to the anode of the coupling varactor diode. The mixer includes a transistor having a base bias voltage applied to a base, the anode of the tuning varactor diode is grounded, and the anode of the coupling varactor diode is directly connected to the base of the transistor and applied to the anode. The television tuner according to claim 1, wherein the bias voltage to be applied is the same voltage as the base bias voltage .   3. The television tuner according to claim 1, wherein the double tuning circuit is configured by a band switching type tuning circuit that is switched so as to be tuned to a VHF band high band or low band television signal.

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