JPH11220362A - Television tuner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily obtain tracking with a local oscillation frequency by expanding the variation range of tuning frequencies of an antenna tuning circuit and an inter-stage tuning circuit so that tuning to a lower frequency becomes possible. SOLUTION: This tuner is equipped with tuning circuits 1 and 4 which have 1st varactor diodes 1b and 4b and select a receive signal by varying a tuning frequency through the capacity variation of the 1st varactor diodes 1b and 3h4b and a local oscillator 6 which has a 2nd varactor diode 6b and varies in local oscillation frequency through the capacity variation of the 2nd varactor diode 6b, and voltages applied across the 1st varactor diodes 1b and 4b are made smaller than the voltage applied across the 2nd varactor diode 6b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television tuner, and more particularly to a television tuner adapted to match tracking between the oscillation frequency of a local oscillator and the tuning frequency of a tuning circuit.

[0002]

2. Description of the Related Art The structure of a conventional television tuner is shown in FIG. In FIG. 7, among the television signals input to the antenna tuning circuit 52 via the input terminal 51, the television signal of the receiving channel is selected by the antenna tuning circuit 52 and input to the high frequency amplifier 53. Then, after being amplified by the high frequency amplifier 53, the inter-stage tuning circuit 54 gives a sharper selectivity characteristic to the mixer 55.
Is input to The local oscillation signal from the local oscillator 56 is input to the mixer 55, and the television signal of the receiving channel is frequency-converted into an intermediate frequency signal and output to the output terminal 58 via the intermediate frequency tuning circuit 57.

The antenna tuning circuit 52 has a tuning coil 52a, a varactor diode 52b, and the like connected in parallel. The tuning frequency is changed by the tuning voltage applied to the varactor diode 52b, and the receiving channel is changed. A television signal is selected. The interstage tuning circuit 54 is composed of a double tuning circuit having two single tuning circuits having the same configuration, and one of the single tuning circuits has a tuning coil 54a and a varactor diode 54b connected in parallel. I do. The tuning frequency is changed by the tuning voltage applied to the varactor diode 54b. The local oscillator 56 also has a tuning coil 56a and a varactor diode 56b connected in parallel.
The frequency of the local oscillation signal (local oscillation frequency) changes according to the tuning voltage applied to b.

The varactor diode 52b of the antenna tuning circuit 52, the varactor diode 54b of the inter-stage tuning circuit 54, and the varactor diode 56 of the local oscillator 56.
Each of the anodes b is set to a DC ground potential,
A common tuning voltage VT is applied to each cathode. Although not shown, a tuning coil 52a of the antenna tuning circuit 52, a tuning coil 54a of the interstage tuning circuit 54, and a tuning coil 56a of the local oscillator 56
In the case where a television tuner receives a high-band television signal and a case where it receives a low-band television signal, the values of the inductances are switched so as to be different from each other. Switching type.

By the way, recent television tuners are not limited to so-called terrestrial television signals, but also to cable terrestrial television signals.
Bull television (CATV) signals can also be received. In CATV, frequency bands not used in terrestrial television, for example, high band and low band
Frequency bands sandwiched between bands are also used. For this reason, in recent television tuners, the reception frequency range of the high band and the reception frequency range of the low band are:
We try to make it as wide as possible, regardless of the terrestrial band division. For example, CATV in Europe (Germany)
For a compatible television tuner, the reception frequency range of the low band is 45.5 MHz to 149.5 MHz, and the reception frequency range of the high band is 156.5 MHz to 426 MH.
z (center frequency). In recent years, the range of reception frequencies used by one band has been increasingly widened.

[0006]

The local oscillation frequency of the local oscillator 56 is higher than the frequency of the television signal to be received (reception frequency) by the intermediate frequency. German version)
The local oscillation frequency range at low band is 82.15 MH
z to 186.15 MHz, and the range of the local oscillation frequency in the high band is 193.15 MHz to 462.15 M
Hz. Therefore, the change ratio of the local oscillation frequency in the low band is approximately 2.27 (= 186.15 / 82.15).
Whereas the change ratio of the reception frequency is approximately 3.29.
(= 149.5 / 45.5), while the change ratio of the local oscillation frequency in the high band is almost 2.39 (462.
15 / 193.15), the change ratio of the reception frequency is approximately 2.72 (= 426 / 156.5).

For this reason, for example, in the low band, the change ratio of the tuning capacitance in the local oscillator 56 is 5.
15 (= 2.27 × 2.27), the change ratio of the tuning capacitance in the antenna tuning circuit 52 and the interstage tuning circuit 54 needs to be 10.8 (= 3.29 × 3.29). And Similarly, in the high band, the change ratio of the tuning capacitance in the local oscillator 56 is 5.71 (= 2.3).
9 × 2.39), whereas the antenna tuning circuit 5
The change ratio of the tuning capacitance in the second and interstage tuning circuit 54 requires 7.40 (= 2.72 × 2.72). The change ratio of the tuning capacitance in each of the antenna tuning circuit 52, the interstage tuning circuit 54, and the local oscillator 56 depends on the capacitance change of the varactor diodes 52b, 54b, 56b. Moreover, these varactor diodes 52b,
54b and 56b have the same capacitance characteristics.

Therefore, particularly in the low band, the tuning frequency of the antenna tuning circuit 52 and the tuning frequency of the interstage tuning circuit 54 are made to match the reception frequency of the highest channel (for example, 149.5 MHz) by the tuning voltage VT. For example, the tuning characteristics of the inter-stage tuning circuit 54 are set as shown in FIG. 8, and the circuit constants are set so that the local oscillation frequency matches the corresponding frequency (186.15 MHz). Even if the tuning voltage is changed so that the local oscillation frequency becomes a frequency (for example, 82.15 MHz) corresponding to the lowest channel, the tuning frequency of the antenna tuning circuit 52 and the tuning frequency of the interstage tuning circuit become the lowest channel. Reception frequency (45.5 MH
z), the tracking with the so-called local oscillation frequency could not be obtained. As a result, the tuning characteristics of the lowest channel are as shown in FIG. 9, and there is a problem that the level of the video carrier P is lowered by shifting the tuning frequency to a higher one. Therefore, the television tuner of the present invention expands the change range of the tuning frequency in the antenna tuning circuit and the interstage tuning circuit so that it can be tuned to a lower frequency, and can easily track the local oscillation frequency. To be obtained.

[0009]

In order to solve the above-mentioned problems, a television tuner according to the present invention has a first varactor diode, and tunes by changing the capacitance of the first varactor diode. A tuning circuit for selecting a received signal by changing a frequency; and a local oscillator having a second varactor diode, wherein a local oscillation frequency changes according to a change in capacitance of the second varactor diode. The voltage applied to both ends of the first varactor diode and the voltage applied to both ends of the second varactor diode are respectively changed to change the capacitance of the first varactor diode and the second varactor diode. The voltage applied to both ends of the first varactor diode was made smaller than the voltage applied to both ends of the second varactor diode by changing the capacitance of the diode.

Further, the television tuner of the present invention comprises:
A common tuning voltage is applied to one end of the first varactor diode and one end of the second varactor diode, and a DC bias voltage is applied to the other end of the first varactor diode. The other end of the second varactor diode was set to the ground potential.

Further, the television tuner of the present invention comprises:
A capacitor for frequency correction was connected in series with the first varactor diode.

Further, the television tuner of the present invention comprises:
A high-frequency amplifier or mixer connected downstream of the tuning circuit; a third varactor diode connecting the tuning circuit and the high-frequency amplifier or mixer;
The DC bias voltage was applied to the anode of the third varactor diode, and the tuning voltage was applied to the cathode of the third varactor diode.

[0013]

FIG. 1 shows a circuit configuration of a television tuner according to the present invention. In FIG. 1, an antenna tuning circuit 1 is a tuning circuit for selecting a television signal of a channel to be received from a television signal input to an input terminal 2, and a television signal selected by the antenna tuning circuit 1. Is amplified by the high-frequency amplifier 3 and then input to the interstage tuning circuit 4. The inter-stage tuning circuit 4 is a tuning circuit for selecting the television signal amplified by the high-frequency amplifier 3 with a steeper selectivity characteristic, and is usually constituted by a double tuning circuit. Then, the television signal passed through the interstage tuning circuit 4 is input to the mixer 5.
A local oscillation signal is input from a local oscillator 6 to the mixer 5, and the received television signal is frequency-converted into an intermediate frequency signal here and output to an output terminal 8 via an intermediate frequency tuning circuit 7.

The antenna tuning circuit 1 has a tuning coil 1a connected in parallel and a varactor diode 1b as a first varactor diode.
The tuning voltage VT is applied to the cathode (one end) of the device. Voltage dividing resistors 9 and 10 are connected to the anode (the other end) of the varactor diode 1b.
, A bias voltage obtained by dividing the DC voltage from the resistors by the voltage dividing resistors 9 and 10 is applied. Then, when the tuning voltage VT applied to the cathode of the varactor diode 1b changes, the capacitance of the varactor diode 1b changes and the tuning frequency changes, thereby selecting the television signal of the receiving channel. .

The interstage tuning circuit 4 has two single tuning circuits having the same configuration to form a double tuning circuit.
Only one of the single tuning circuits is shown. The interstage tuning circuit 4 has a tuning coil 4a connected in parallel and a varactor diode 4b as a first varactor diode, and is connected to a cathode (one end) of the varactor diode 4b. Is applied with a tuning voltage VT. The voltage dividing resistors 12 and 1 are connected to the other end of the anode of the varactor diode 4b.
3 is connected, and a bias voltage obtained by dividing a DC voltage from a voltage terminal 11 by voltage dividing resistors 12 and 13 is applied. Then, when the common tuning voltage VT applied to the cathode of the varactor diode 4b changes, the capacitance of the varactor diode 4b changes and the tuning frequency changes, thereby selecting the television signal of the receiving channel. Is done. The local oscillator 6 also has a tuning coil 6a connected in parallel and a varactor diode 6b as a second varactor diode.
The tuning voltage VT is applied to the cathode (one end) of b.
The anode (the other end) of the varactor diode 6b has the same potential as the ground in DC. The frequency of the local oscillation signal (local oscillation frequency) changes according to the common tuning voltage VT applied to the cathode of the varactor diode 6b.

Although not shown, the tuning coil 1a of the antenna tuning circuit 1 and the tuning coil 4 of the interstage tuning circuit 4 are not shown.
a, the tuning coil 6a of the local oscillator 6 has different inductance values when the television tuner receives a high-band television signal and when it receives a low-band television signal. , And each tuning circuit is of a so-called band switching type.

As a result, a tuning voltage VT common to the respective cathodes of the varactor diode 1b of the antenna tuning circuit 1, the varactor diode 4b of the interstage tuning circuit 4, and the varactor diode 6b of the local oscillator 6. Is applied, the voltage applied between the cathode and the anode of the varactor diode 1b of the antenna tuning circuit 1 and the varactor diode 4b of the interstage tuning circuit 4 is changed by the varactor of the local oscillator 6. The voltage is lower than the voltage applied between the cathode and the anode of the diode 6b. FIG. 2 shows this situation. First, curve A is a varactor diode 1b,
The relationship between the voltage applied between the cathode and the anode of 4b and 6b and the capacitance at that time is shown. As is apparent from the curve A, the capacity increases rapidly as the voltage decreases.
Then, the tuning voltage VT is set in the range of VT1 to VT2 (V
T1> VT2), the VT is connected between the cathode and the anode of the varactor diode 6a of the local oscillator 6.
The tuning voltage of 1 to VT2 is applied as it is, and the capacitance at that time changes to CT1 to CT2, and the change range is CT. On the other hand, the varactor diode 1b of the antenna tuning circuit 1 and the varactor diode 4b of the interstage tuning circuit 4 have a cathode and a varactor diode 6b of the local oscillator 6, respectively, between the anodes. Vt1 to vt2, which is lower than the voltage applied between the gate and the anode by the bias voltage applied to each cathode. Then, the capacitance is c corresponding to the voltages vt1 to vt2.
It becomes t1 to ct2, and the change range ct becomes larger than CT.

As a result, the tuning frequencies of the antenna tuning circuit 1 and the inter-stage tuning circuit 4 can be shifted to lower ones, and even if the reception frequency ranges of the high band and the low band are widened, the local oscillation Tracking with frequency can be obtained. The varactor diode 1b of the antenna tuning circuit 1 and the varactor diode of the interstage tuning circuit 4, which are the first varactor diodes.
Since a bias voltage is applied to each of the anodes of the varactor diodes 4b and 4b, a tuning voltage VT common to the respective cathodes of the first varactor diodes 1b and 4b and the second varactor diode 6b is applied. The capacitance of the first varactor diodes 1b and 4b can be easily increased simply by applying the voltage.

As a result, for example, CA in Europe (Germany)
Like a TV tuner compatible with TV, the reception frequency range of the low band is 45.5 MHz to 149.5 MHz.
z, the reception frequency range of the high band is 156.5 MHz ~
In the case of setting as wide as 426 MHz (all center frequencies), for example, the tuning frequency of the interstage tuning circuit 4 at the reception frequency (center frequency 149.5 MHz) of the low-band highest channel is set as shown in FIG. Even when the center frequency (149.5 MHz) is set, as shown in FIG. 4, the center frequency (45.5 M
Hz) can be obtained. The same applies to the antenna tuning circuit 1.

FIG. 5 is a detailed circuit diagram of the antenna tuning circuit 1 in the television tuner of the present invention. FIG.
, The input terminal 11 is connected to an antenna or the like (not shown), and the output terminal 12 is connected to the high-frequency amplifier 3. Tuning coils 13, 14, and 15 connected in series are connected in parallel to a varactor diode 1b, which is a first varactor diode. A tuning coil 18 is connected to the tuning coil 15 via two switch diodes 16 and 17 connected to both ends thereof. The switch diode 16 is provided so as to be connected to both ends of the tuning coil 14. The anodes of these switch diodes 16 and 17 are high band switching voltage terminals H.
B and the cathode is connected to a low-band switching voltage terminal LB. A tuning voltage VT is applied to a cathode (one end) of the varactor diode 1b. A connection point between the anode (the other end) of the varactor diode 1b and the tuning coil 13 is connected to the output terminal 12 via a varactor diode 19, which is a third varactor diode for coupling. Have been. Further, the cathode of the varactor diode 1b is grounded via a capacitor 20 for frequency correction. As a result, the varactor diode 1b and the capacitor 20 for frequency correction are connected in series. The tuning voltage VT is also applied to the cathode (one end) of the varactor diode 19. Further, two voltage dividing resistors 21 and 22 are connected to one end of the tuning coil 14, one end of the voltage dividing resistor 21 is grounded, and the other end of the voltage dividing resistor 22 is connected to the cathode of the switch diode 16. Have been.

In the above configuration, when a low-band television signal is received, a switching voltage is applied to the low-band switching voltage terminal LB to make the switch diodes 16 and 17 non-conductive and to change the varactor diode. A tuning circuit is constituted by the capacitor 1b, the frequency correcting capacitor 20 and the tuning coils 13, 14, 15; when a high-band television signal is received, a switching voltage is applied to the high-band switching terminal HB. The switch diodes 16 and 17 are turned on to short-circuit both ends of the tuning coil 14, and the tuning coil 15 and the tuning coil 18 are connected in parallel to form the varactor diode 1.
b and capacitor 20 for frequency correction and tuning coil 1
A tuning circuit is constituted by 3, 15, and 18. As a result, the switching voltage is divided by the voltage dividing resistors 21 and 22 in both the low band and the high band, and the divided voltage (bias voltage) is passed through the tuning coils 13 and 14 to the varactor diode. Are applied to the anodes (the other ends) of the nodes 1b and 19, respectively. As a result, the voltage between the cathode and the anode of the varactor diode 1b decreases, and the capacitance value increases. Here, the tuning capacitance of the entire tuning circuit is corrected by the capacitor 20 for frequency correction. In addition, since a bias voltage is also applied to the coupling varactor diode 19, the coupling capacitance increases, whereby the coupling with the high-frequency amplifier 3, which is a circuit connected at the subsequent stage, can be made dense, and the gain can be increased. And NF are improved.

FIG. 6 is a detailed circuit diagram of the interstage tuning circuit 4 in the television tuner of the present invention. 6, the inter-stage tuning circuit 4 has a primary tuning circuit 31 and a secondary tuning circuit 32. An input terminal 33 is connected to the high-frequency amplifier 3 and an output terminal 34 is connected to the mixer 5. The primary tuning circuit 31 and the secondary tuning circuit 32 are respectively varactor diodes 4b1 and 4b1 which are first varactor diodes.
and the cathode (one end) of the varactor diode 4b1 and the cathode (one end) of the varactor diode 4b2 are grounded via frequency-correcting capacitors 35 and 36 connected in series, respectively. Have been. The tuning coils 37 and 38 and the coupling coil 3 connected in series
9 is connected in parallel with the varactor diode 4b1 and the capacitor 35 for frequency correction. The tuning coils 40 and 41 and the coupling coil 39 connected in series are connected in parallel to the varactor diode 4b2 and the correction capacitor 36. One end of the coupling coil 39 is grounded via a voltage dividing resistor 42, and connected to a low band switching voltage terminal LB via a voltage dividing resistor 43.

The connection point between the tuning coils 37 and 38 is connected via a DC blocking capacitor 44 to a switch diode.
An anode of a switch diode 47 is connected to a connection point between the tuning coils 40 and 41 via a DC blocking capacitor 46. The respective cathodes of the switch diodes 45 and 47
Is connected to the low band switching voltage terminal LB. Further, the anodes of the switch diodes 45 and 47 are connected to the high band switching voltage terminal HB.
Anode of varactor diode 4b2 of secondary tuning circuit 32
The varactor diode is connected to the output terminal 34 via a varactor diode 48 which is a third varactor diode for coupling.
The tuning voltage VT is applied to the cathode of the varactor diode 4b1 and the cathode of the varactor diode 4b2 of the secondary tuning circuit 32.

When a low-band television signal is received, a switching voltage is applied to a low-band switching voltage terminal LB to make the switch diodes 45 and 47 non-conductive so that the tuning coils 37 and 38 are turned off. The coupling coil 39, the varactor diode 4b1, and the capacitor 35 for frequency correction constitute a low-band primary tuning circuit. Similarly, the tuning coils 40 and 41, the coupling coil 39, the varactor diode 4b2, and the frequency correction And a low-band secondary tuning circuit. Also,
When a high-band television signal is received, a switching voltage is applied to a high-band switching voltage terminal HB to make the switch diodes 45 and 47 conductive so that a connection point between the tuning coils 37 and 38 and a tuning coil 40 are provided. The connection point of the tunable coil 41, the varactor diode 4b1, the correction capacitor 3
5 constitutes a high-band primary tuning circuit. Similarly, the tuning coil 40, the varactor diode 4b2, and the correction capacitor 36 constitute a high-band secondary tuning circuit.

In both the low band and the high band, the band switching voltage is applied to the voltage dividing resistors 42 and 43, so that the divided voltage generated in the voltage dividing resistors is coupled to the coupling coil 39 and the tuning. The voltage is applied to the anode (the other end) of the varactor diode 4b1 via the coils 37 and 38, and is applied to the anode (the other end) of the varactor diode 4b2 via the coupling coil 39 and the tuning coils 40 and 41. ) To bias each anode. As a result, the voltage between the cathode and the anode of the varactor diode 4b1 and the anode of the varactor diode 4b2,
The voltage between the cathodes decreases and the capacitance value increases. Here, the entire tuning capacitance of each of the primary tuning circuit 31 and the secondary tuning circuit 32 is corrected by the capacitors 35 and 36 for frequency correction.

Further, since a bias voltage is also applied to the varactor diode 48 for coupling, the coupling capacity increases, whereby the coupling with the mixer 5, which is a subsequent circuit, can be made dense, and the gain can be increased. And NF are improved.

[0027]

As described above, the television tuner of the present invention has the first varactor diode, and changes the tuning frequency by changing the capacitance of the first varactor diode to thereby receive the signal. And a local oscillator having a second varactor diode and having a local oscillation frequency that varies with a change in the capacitance of the second varactor diode. To change the capacitance of the first varactor diode and the capacitance of the second varactor diode by changing the voltage applied to the first varactor diode and the voltage applied to both ends of the second varactor diode, respectively. Since the voltage applied to both ends of the varactor diode is smaller than the voltage applied to both ends of the second varactor diode, the tuning frequency of the tuning circuit can be shifted to a lower one. It can be obtained tracking with oscillation frequency.

Further, the television tuner of the present invention comprises:
A common tuning voltage is applied to one end of the first varactor diode and one end of the second varactor diode, a DC bias voltage is applied to the other end of the first varactor diode, and the second Since the other end of the varactor diode is set to the ground potential, the capacitance of the first varactor diode can be made larger than that of the second varactor diode simply by applying a common tuning voltage.

Further, the television tuner of the present invention comprises:
Since the capacitor for frequency correction is connected in series with the first varactor diode, the tuning capacitance of the entire tuning circuit due to the increase in the capacitance of the first varactor diode can be corrected.

Further, the television tuner of the present invention comprises:
A high-frequency amplifier or mixer connected downstream of the tuning circuit; a third varactor diode coupling the tuning circuit with the high-frequency amplifier or mixer; and an anode of the third varactor diode And a tuning voltage is applied to the cathode of the third varactor diode, so that the coupling capacity increases,
The coupling between the high-frequency amplifier or the mixer, which is a circuit at the subsequent stage, can be made dense, and the gain and NF can be improved.

[Brief description of the drawings]

FIG. 1 is a circuit configuration diagram of a television tuner of the present invention.

FIG. 2 is an explanatory diagram of operating characteristics of a varactor diode in the television tuner of the present invention.

FIG. 3 is a tuning characteristic diagram of the television tuner of the present invention.

FIG. 4 is a tuning characteristic diagram of the television tuner of the present invention.

FIG. 5 is a detailed circuit diagram of an antenna tuning circuit in the television tuner of the present invention.

FIG. 6 is a detailed circuit diagram of an interstage tuning circuit in the television tuner of the present invention.

FIG. 7 is a circuit configuration diagram of a conventional television tuner.

FIG. 8 is a tuning characteristic diagram of a conventional television tuner.

FIG. 9 is a tuning characteristic diagram of a conventional television tuner.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Antenna tuning circuit 1a Tuning coil 1b First varactor diode 2 Input terminal 3 High frequency amplifier 4 Interstage tuning circuit 4a Tuning coil 4b First varactor diode 5 Mixer 6 Local oscillator 6a Tuning coil 6b Second Varactor diode 7 Intermediate frequency tuning circuit 8 Output terminal 9, 10, 12, 13, 21, 22, 42, 43 Voltage dividing resistor 19, 48 Third varactor diode 20, 35, 36 Capacitor for frequency correction

──────────────────────────────────────────────────続 き Continued on front page (51) Int.Cl. ⁶ Identification code FI H04N 5/44 H04N 5/44 K

Claims (4)

[Claims] 1. A tuning circuit having a first varactor diode, wherein a tuning frequency is changed by changing a capacitance of the first varactor diode to select a reception signal, and a second varactor diode is provided. A local oscillator whose local oscillation frequency changes according to a change in the capacitance of the second varactor diode, and a voltage applied to both ends of the first varactor diode and the second varactor diode. The voltage applied to both ends of the first varactor diode is changed by respectively changing the voltage applied to both ends of the first varactor diode, and the capacity of the second varactor diode is changed. A television tuner characterized in that the applied voltage is lower than the voltage applied to both ends of said second varactor diode. 2. A common tuning voltage is applied to one end of the first varactor diode and one end of the second varactor diode, and a direct current bias is applied to the other end of the first varactor diode. 2. The television tuner according to claim 1, wherein a voltage is applied and the other end of said second varactor diode is set to a ground potential. 3. The television tuner according to claim 2, wherein a capacitor for frequency correction is connected in series with said first varactor diode. 4. A high-frequency amplifier or mixer connected to a stage subsequent to the tuning circuit, a third varactor diode connecting the tuning circuit and the high-frequency amplifier or mixer is provided, and a third varactor diode is provided. Varactor diode anode
4. The television tuner according to claim 1, wherein said DC bias voltage is applied to a cathode of said third varactor diode and said tuning voltage is applied to a cathode of said third varactor diode.