JP3038797B2 - Television tuner - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television tuner used for a television receiver, a home VTR, and the like.

2. Description of the Related Art Hereinafter, (prior art 1) will be described with reference to the drawings. 2 (a) to 2 (c) are a circuit diagram of an input circuit unit of a conventional television tuner and an equivalent circuit diagram of a main part thereof.

2 (a), (b) and (c), 1 is an input terminal from an antenna, 2 is a 1F filter, 3, 9, 11, 14, 21 are DC blocking capacitors, and 4 is a low band. Matching coil, 5 is a matching coil for high band, 6, 7, 12, 22,
23 is a bias resistor for a switching diode, 8 is a tuning coil for a low band, 10 is a tuning coil for a high band, 1
3, 24 are switching diodes, 15 is a tuning varicap diode, 16 is a varicap diode bias resistor, 17 is an RF signal amplifier circuit, 18 is a low band receiving voltage applying terminal, 19 is a high band receiving voltage applying terminal, Reference numeral 20 denotes a varicap diode voltage application terminal. The television tuner configured as described above will be described below.

The television signal (hereinafter abbreviated as RF signal) input to the input terminal 1 from the antenna is attenuated in the intermediate frequency band by the 1F filter 2 and input to the high-band matching coil 5 and subsequently to the low-band matching coil 4. Is done. The RF signal output from these is the next stage tuning coil
8 and 10 and input to tuning varicap diode 15,
After selecting the RF signal of the desired channel, the signal is amplified by the RF signal amplifier circuit 17 and transmitted to the next stage. afterwards,
It is converted to an intermediate frequency by mixing with local oscillation, and output from a television tuner.

Next, a method of switching between the low band and the high band will be described.

FIG. 2 (b) is an equivalent circuit of the portion A in FIG. 2 (a) at the time of low band reception, and FIG. 2 (c) is an equivalent circuit of the portion A of FIG. 2 (a) at the time of high band reception. ). In FIG. 2 (b), 7A is the combined resistance of the switching diode bias resistors 6 and 7 in FIG. 2 (a), and in FIG. 2 (c), 10A is the low band tuning coil in FIG. 2 (a). 2A is the combined inductance of the high band tuning coil 10 and 22A is the combined resistance of the switching diode bias resistors 6, 7 and 22 in FIG. In part A of FIG. 2A, a voltage is applied to the low-band reception voltage application terminal 18 during low-band reception, and the high-band voltage application terminal 19 is set to zero potential or open. Then, the switching diode bias resistor 7
, The cathode potential of the switching diode 13 rises and the switching diode 13 is turned off, and the matching coil for low band reception is formed by connecting the low band matching coil 4 and the high band matching coil 5 in series to obtain low band matching. Similarly, when the switching diode 24 is turned off,
The high-band tuning coil 10 is opened, and the low-band tuning coil 8 performs low-band tuning. During high band reception, set the low band reception voltage application terminal 18 to 0.
By applying a voltage to the high band voltage application terminal 19 as a potential or open, a current flows through the switching diode 13 via the switching diode bias resistor 22,
When the switching diode 13 is turned on, the low-band matching coil 4 is short-circuited, and high-band matching is obtained. Similarly switching diode 24
Is turned on, the tuning coil 10 for high band is grounded and connected in parallel with the tuning coil 8 for low band.
High band tuning coil 10 is low band tuning coil 8
The inductance at the time of high band reception is determined by the high band tuning coil 10 substantially.
Thereby, high band reception becomes possible.

(Prior Art 2) A low band matching coil and a high band matching coil (parallel technique 2) will be described with reference to the drawings.

3 (a) to 3 (c) are a circuit diagram and an equivalent circuit diagram of an input circuit section of a conventional television tuner. 3 (a), (b) and (c), 1 is an input terminal from an antenna, 2 is a 1F filter, 3, 9, 11, 14, 21 are DC blocking capacitors, 4 is a low band. Matching coil, 5
Is a high band matching coil, 6, 7, 12, 22, and 23 are switching diode bias resistors, 8 is a low band tuning coil, 10 is a high band tuning coil, 13, 24 are switching diodes, and 15 is a tuning burr. Cap diode, 16 is bias resistor for varicap diode, 17
Is an RF signal amplifier circuit, 18 is a low-band receiving voltage application terminal, 19 is a high-band receiving voltage application terminal, and 20 is a varicap diode voltage application terminal. The television tuner configured as described above will be described below. .

The RF signal input to input terminal 1 from the antenna is 1F
The intermediate frequency band is attenuated by the filter 2 and input to the low-band matching coil 4 and the high-band coil 5. The RF signals output from these are input to the tuning coils 8 and 10 and the tuning varicap diode 15 in the next stage, and after selecting the RF signal of the desired channel, the signal is amplified by the RF signal amplifier circuit 17 and the next stage. Is transmitted. Thereafter, the signal is converted into an intermediate frequency by mixing with the local transmission, and output from the television tuner.

Next, a method of switching between the low band and the high band will be described.

FIG. 3 (b) is an equivalent circuit at the time of low-band reception of the portion A in FIG. 3 (a), and FIG. 3 (c) is an equivalent circuit at the time of high-band reception of the portion A in FIG. 3 (a). ). In FIG. 3 (b), 7A is the combined resistance of the switching diode bias resistors 6, 7 and 22 in FIG. 3 (a), and in FIG. 3 (c), 5A is for the low band in FIG. 3 (a). There is a combined inductance of the matching coil 4 and the high-band matching coil 5, 10A is a combined inductance of the low-band tuning coil 8 and the high-band tuning coil 10 in FIG. 3 (a), and 22A is FIG. 2) is the combined resistance of the switching diode bias resistors 6, 7 and 22.

In part A of FIG. 3 (a), when a low-band reception is performed, a voltage is applied to the low-band reception voltage application terminal 18 and the high-band voltage application terminal 19 is set to zero potential or opened. The cathode potential of 13 becomes high, and the switching diode 13 is turned off. For this reason, the matching coil for low band reception is the matching coil for low band 4.
And a low band match is obtained.
Similarly, when the switching diode 24 is turned off, the tuning coil 10 for high band is opened, and tuning for low band is performed by the tuning coil 8 for low band.
At the time of high band reception, the low band reception voltage application terminal 18 is set to 0 potential or open, and a voltage is applied to the high band voltage application terminal 19. Then, a current flows through the switching diode 13 via the switching diode bias resistor 22, and the switching diode 13 is turned on. When the high band is received, the matching coil 4 for the low band and the matching coil 5 for the high band are connected in parallel. And get high band matching. Similarly, when the switching diode 24 is turned on, the high band tuning coil 10 is grounded, and the low band tuning coil 8 is turned on.
Are connected in parallel. Since the high-band tuning coil 10 is sufficiently smaller than the low-band tuning coil 8, the inductance at the time of high-band reception is substantially determined by the high-band tuning coil 10. This enables high band reception.

However, in a configuration such as (Prior Art 1), as is apparent from the equivalent circuit of FIG. 2C at the time of high-band reception, the bias resistors for switching diodes 6, 7, and
22 is connected in parallel to the tuning coil 10 for high band. The switching diode bias resistors 6, 7, 22
The combined resistance 22A is 400Ω when the power supply voltage is 5V and the diode current is 2mA, and it is 400Ω. There is a problem that it acts as a stray capacitance and deteriorates NF, selectivity, and broadband reception of the circuit.

In order to solve this problem, there is a method of connecting the switching diode bias resistors 6, 7, 22 to a point having a low impedance (conventional technology 2). However, there is the following problem.

Usually, the matching coil requires about 550 nH for low band reception and about 250 nH for high band reception. Therefore, in (conventional technology 1), the low band matching coil 4 is about 330 nH, and the high band matching coil 5 is 250 nH. On the other hand, in the circuit configuration of FIG. 3A (prior art 2), the low-band matching coil 4 is 580n because the configuration is a parallel connection.
About H, the matching coil 5 for the high band needs about 500 nH, and the air core coil generally used has a very large shape, which has a problem that it greatly hinders the miniaturization of the television tuner. Was. Therefore, the present invention is to prevent the deterioration of the NF, selectivity and wideband reception of the circuit as in (Prior Art 1), and to prevent the circuit from becoming larger as in (Prior Art 2). It is the purpose.

Means for Solving the Problems And to achieve this object, the present invention provides an input terminal to which a television signal is input, a low-band matching coil in which a signal input to the input terminal is supplied to one end, A high-band matching coil, one end of which is connected to the other end of the low-band matching coil; a first switching diode connected in parallel with the low-band matching coil; A tuning coil for high band having one end connected thereto, a tuning coil for low band connected between the other end of the tuning coil for high band and the ground, and a second coil connected in parallel with the tuning coil for low band. Switching diode, the first switching diode, and the second switching diode. A high-band reception voltage application terminal for turning both the first and second switching diodes off, and a high-band reception voltage application terminal for turning off both the first switching diode and the second switching diode. A first series-connected body formed by connecting a coil and the low-band tuning coil in series, a tuning varicap diode connected in parallel with the first series connected body, and a tuning voltage applied to the varicap diode. A voltage application terminal for applying a varicap diode to be supplied, an RF signal amplifying circuit connected to the other end of the high-band matching coil, and an output of the RF signal amplifying circuit is mixed with local oscillation and converted to an intermediate frequency. A high-band receiving voltage application terminal, comprising: a circuit; and an output terminal to which an output of the circuit for converting to the intermediate frequency is connected. A short circuit is applied to the low band matching coil and the low band tuning coil by applying a voltage, impedance matching is performed by the high band matching coil, and a high band is formed by the high band tuning coil and the varicap diode. A variable tuning circuit is formed, and both ends of the low-band matching coil and the low-band tuning coil are opened by applying a voltage to the low-band receiving voltage application terminal, and the high-band matching coil and the low-band matching coil are opened. The impedance is matched by a second series connection formed by series connection of the above, and a low-band variable tuning circuit is formed by the parallel connection of the first series connection and the varicap diode.

Operation With this configuration, the first switching diode having a low impedance is connected at least via the high-band matching coil at the preceding stage of the variable tuning circuit having the high impedance, so that the loss is reduced.
NF is improved.

In addition, by imprinting the voltage on the high-band reception voltage application terminal and the low-band reception voltage application terminal respectively, the reception band can be switched between the low band and the high band, so that wideband reception is possible.

Further, the tuning circuit becomes a variable tuning circuit by applying a tuning voltage to a voltage application terminal for applying a varicap diode, so that selectivity is improved.

Furthermore, the tuning coil is formed of a series connection of a high-band tuning coil and a low-band tuning coil, and the matching coil is formed of a series connection of a high-band matching coil and a low-band matching coil. Therefore, the size can be reduced as compared with the case where the coils for the high band and the coils for the low band are independently formed.

Example Hereinafter, an example of the present invention will be described.

1 (a) to 1 (c) are a circuit diagram and an equivalent circuit diagram according to one embodiment of the present invention.

1 (a), 1 (b) and 1 (c), 1 is an input terminal from an antenna, 2 is a 1F filter, 3, 9, 11, 14, 21 are capacitors for blocking DC, and 4 is matching for low band. Coil, 5 is matching coil for high band, 6, 7, 12, 22, 23
Is the bias resistor for the switching diode, 8 is the tuning coil for the low band, 10 is the tuning coil for the high band, and 13,2
4 is a switching diode, 15 is a tuning varicap diode, 16 is a varicap diode bias resistor, 17 is an RF signal amplifier circuit, 18 is a low-band reception voltage application terminal, 19 is a high-band reception voltage application terminal, and 20 is This is a voltage application terminal for a varicap diode.

The television tuner configured as described above will be described below.

The RF signal input to input terminal 1 from the antenna is 1F
The intermediate frequency band is attenuated by the filter 2 and input to the low-band matching coil 4 and subsequently to the high-band matching coil 5. The RF signals output from these are input to the tuning coils 8 and 10 and the tuning varicap diode 15 in the next stage, and after selecting the RF signal of the desired channel, the signal is amplified by the RF signal amplifier circuit 17 and the next stage. Is transmitted. Thereafter, the signal is converted into an intermediate frequency by mixing with local oscillation, and output from a television tuner.

Next, a method of switching between the low band and the high band will be described.

FIG. 1 (b) is an equivalent circuit at the time of low-band reception of the portion A in FIG. 1 (a), and FIG. 1 (c) is an equivalent circuit at the time of high-band reception of the portion A in FIG. 1 (a). ). In FIG. 1B, 7A is a combined resistance of the switching diode bias resistors 6 and 7 in FIG.
Is the combined inductance of the low-band tuning coil 8 and the high-band tuning coil 10 in FIG.
In FIG. 1 (c), 22A is a combined resistance of the switching diode bias resistors 6, 7 and 22 in FIG. 1 (a).

In part A of FIG. 1A, at the time of low band reception, a voltage is applied to the low band reception voltage application terminal 18 and the high band voltage application terminal 19 is set to zero potential or open. Then, the cathode potential of the switching diode 13 rises via the switching diode bias resistor 7, and the switching diode 13 is turned off. The matching coil for low band reception is a series connection of the matching coil 4 for low band and the matching coil 5 for high band. To obtain a low band match. Similarly, the switching diode 24 is turned off and the tuning coil for high band is used.
The low band is tuned by the inductance formed by the series connection of the low band tuning coil 8 and 10. Low band reception voltage application pin when receiving high band
18 is set to 0 potential or open, and high band voltage application terminal 19
Voltage. Then, a current flows through the switching diode 13 via the switching diode bias resistor 22, and when the switching diode 13 is turned on, the low-band matching coil 4 is short-circuited and high-band matching is obtained. Similarly, when the switching diode 24 is turned on, the tuning coil 8 for the low band is short-circuited, and tuning of the high band is performed by the inductance of the tuning coil 10 for the high band.

As described above, according to the present embodiment, one end of the low-band matching coil 4 is electrically connected to the input terminal 1 of the tuner to which the television signal is input. One end of the high band matching coil 5 is electrically connected, and a switching diode is connected in parallel with the low band matching coil 4.
13 is made electrical.

Therefore, at the time of high-band reception, as is clear from the equivalent circuit at the time of high-band reception, FIG. 1 (c), the combined resistance 22 of the switching diode bias resistors 6, 7 and 22 is used.
A is 400Ω when the power supply voltage is 5V and the diode current is 2mA. However, since it is connected to the antenna input section having a low impedance of 75Ω, there is almost no influence of stray capacitance due to damping and component mounting in a circuit. Therefore, it is possible to design a circuit that prevents deterioration of NF, selectivity, and broadband reception. In addition, since the matching coil is formed by connecting the low-band matching coil 4 and the high-band matching coil 5 in series, in the (prior art 2), the low-band matching coil 4 is about 580 nH, and the high-band matching coil 5 is 500 nH. While it is composed of degrees,
According to this embodiment, the matching coil 4 for low band is 33
0nH and the high band matching coil 5 can be configured with about 250n. The inductance of the low band matching coil 4 and the high band matching coil 5 can be reduced, and the tuner of the tuner can be reduced by using a smaller air core coil. Downsizing is also possible at the same time.

As described above, the present invention provides an input terminal to which a television signal is input, a low-band matching coil to which a signal input to the input terminal is supplied to one end, and the other end of the low-band matching coil. , A first switching diode connected in parallel with the low-band matching coil, and a high-band one end connected to the other end of the high-band matching coil. A tuning coil for low band connected between the other end of the tuning coil for high band and the ground; a second switching diode connected in parallel with the tuning coil for low band; Hibernating both the switching diode and the second switching diode in the on state And a series connection of a low-band reception voltage application terminal for turning off both the first switching diode and the second switching diode, and a tuning coil for the high band and a tuning coil for the low band. , A tuning varicap diode connected in parallel with the first series connection, and a varicap diode application voltage application terminal for supplying a tuning voltage to the varicap diode. An RF signal amplifying circuit connected to the other end of the high-band matching coil; a circuit for mixing the output of the RF signal amplifying circuit with local oscillation to convert the output to an intermediate frequency; and a circuit for converting the output to the intermediate frequency. And an output terminal to which the output of the low band is connected. Short-circuiting the band matching coil and the low band tuning coil, taking impedance matching with the high band matching coil and forming a high band variable tuning circuit with the high band tuning coil and the varicap diode, Both ends of the low-band matching coil and the low-band tuning coil are opened by applying a voltage to the low-band receiving voltage application terminal, and the low-band matching coil and the low-band matching coil are formed in series. The impedance is matched by the second series connection body, and the first
Form a low-band tunable circuit with a series-connected body of the varicap diode and a parallel-connected body of the varicap diode. Since one switching diode is connected, loss is reduced and NF is improved.

Further, by applying a voltage to each of the high-band reception voltage application terminal and the low-band reception voltage application terminal, the reception band can be switched between the low band and the high band, so that wideband reception is possible.

Further, the tuning circuit becomes a variable tuning circuit by applying a tuning voltage to a voltage application terminal for applying a varicap diode, so that selectivity is improved.

Furthermore, the tuning coil is formed of a series connection of a high-band tuning coil and a low-band tuning coil, and the matching coil is formed of a series connection of a high-band matching coil and a low-band matching coil. Therefore, the size can be reduced as compared with the case where the coils for the high band and the coils for the low band are independently formed.

[Brief description of the drawings]

FIG. 1A is a circuit diagram of an input circuit section of a television tuner according to one embodiment of the present invention, FIG. 1B is an equivalent circuit diagram of section A in FIG. 1A at the time of low band reception, FIG. 1 (c) is an equivalent circuit diagram of section A in FIG. 1 (a) at the time of high band reception, and FIG. 2 (a) is a circuit diagram of an input circuit section of a television tuner according to (prior art 1). FIG. 2 (b) is an equivalent circuit diagram at the time of low band reception of the portion A in FIG. 2 (a),
FIG. 2 (c) is an equivalent circuit diagram of section A in FIG. 2 (a) at the time of high band reception, and FIG. 3 (a) is a circuit diagram of an input circuit section of a television tuner according to (prior art 2). FIG. 3 (b) is an equivalent circuit diagram of section A of FIG. 3 (a) at the time of low band reception, and FIG. 3 (c) is an equivalent circuit of section A of FIG. 3 (a) at the time of high band reception. FIG. 1 ... input terminal from antenna 2 ... 1F filter,
3, 9, 11, 14… DC blocking capacitor, 4… Low band matching coil, 5… High band matching coil, 6, 7, 12… Switching diode bias resistor, 8… Low band tuning Coil, 10… Tuning coil for high band, 13… Switching diode, 15…
... Varicap diode for tuning, 16 ... Bias resistor for varicap diode, 17 ... RF signal amplifier circuit, 18
…… Low-band receiving voltage application terminal, 19 …… High-band reception voltage application terminal, 20 …… Varicap diode voltage application terminal, 7A …… Combined resistance of switching diode bias resistors 6 and 7, 8A …… High Synthetic inductance of tuning coil 10 for band and tuning coil 8 for low band, 5A ... Synthetic inductance of matching coil 4 for low band and matching coil 5 for high band, 22A ...
... A combined resistance of the switching diode bias resistors 6, 7 and 22.

Continued on the front page (72) Inventor Akio Iwase 1006 Kadoma Kadoma, Osaka Prefecture Inside Matsushita Electric Industrial Co., Ltd. 56) References JP-A-3-177107 (JP, A) JP-A-3-190412 (JP, A) JP-A-3-192914 (JP, A) Actually open 1-86336 (JP, U) Actually open 58-152024 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) H03J 3/08 H03J 5/24 H04B 1/18 H04N 5/44

Claims (1)

(57) [Claims] An input terminal for inputting a television signal, a low-band matching coil to which a signal input to the input terminal is supplied to one end, and one end connected to the other end of the low-band matching coil. A high-band matching coil, a first switching diode connected in parallel with the low-band matching coil, a high-band tuning coil having one end connected to the other end of the high-band matching coil, A low-band tuning coil connected between the other end of the high-band tuning coil and ground; a second switching diode connected in parallel with the low-band tuning coil; the first switching diode and the second switching diode; 2 high-band receiving voltage application terminal for turning on both switching diodes A low-band receiving voltage application terminal for turning off both the first switching diode and the second switching diode; and a first connection formed of a series connection of the high-band tuning coil and the low-band tuning coil. A series connected body, a tuning varicap diode connected in parallel with the first series connected body, a varicap diode applying voltage application terminal for supplying a tuning voltage to the varicap diode,
Connected to the other end of the high band matching coil
An RF signal amplifying circuit, a circuit in which an output of the RF signal amplifying circuit is mixed with local oscillation to convert to an intermediate frequency, and an output terminal to which an output of the circuit to convert to the intermediate frequency is connected; The low-band matching coil and the low-band tuning coil are short-circuited by applying a voltage to a receiving voltage application terminal, impedance matching is performed by the high-band matching coil, and the high-band tuning coil and the varicap diode are applied. A high-band variable tuning circuit is formed by applying both ends of the low-band matching coil and the low-band tuning coil by applying a voltage to the low-band receiving voltage application terminal, and the high-band matching coil and The low-band matching coil is formed in series. A television tuner in which impedance is matched by a second series connection and a low-band variable tuning circuit is formed by a parallel connection of the first series connection and the varicap diode.