KR830002652B1 - Tuner device - Google Patents

Abstract

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Description

Tuner device

1 is a block diagram showing one embodiment of a prior art TV tuner in which the present invention can be advantageously applied.

2 is a graph showing the relationship between the tuning voltage and the frequency (receiving channel) of a TV system proposed in West Germany to explain the background of the present invention.

3 is a graph showing channel distribution of TV standard broadcasting in Canada.

4 is a graph showing the relationship between tuner voltage and frequency (receive channel) for explaining the principle of the present invention.

5a and 5b are schematic views of a TV tuner adopted as an example of the present invention. FIG. 5a is a UHF portion, and FIG. 5b is a VHF portion.

6 is a schematic view for explaining an embodiment of the present invention.

7, 8 and 9 are schematic views for explaining another embodiment of the present invention using another type of channel selection device, that is, a variable tuner voltage generating means.

10 to 13 are schematic diagrams of principal parts of the foregoing embodiment of the tuner voltage generating circuit.

14 and 15 are schematic diagrams showing examples of impedance means.

FIG. 16 is a graph for explaining the operation of the embodiment shown in FIG. 10 and FIG.

Fig. 17 is a schematic diagram of the main part of the above-described embodiment in the tuner voltage generating circuit.

FIG. 18 is a graph for explaining the embodiment of FIG. 7, wherein the abscissa indicates the rotational speed of the fine tuner knob and the ordinate indicates the tuner voltage.

19 is a block diagram depicting further embodiments of the present invention.

20 is a graph showing the relationship between the tuner frequency (receive channel) and the tuner voltage for explaining the embodiment of FIG. 19. FIG.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tuner device, and more particularly, to a tuner device using a variable reactance element for voltage control such as a variable capacitance diode for voltage control used in a TV receiver, an FM receiver, and the like.

The prior art will be described with reference to the accompanying drawings, in which FIG. 1 is a block diagram showing one example of a tuner device in a TV receiver of a superhero heterodyne system, in which the present invention can be advantageously applied. Such TV tuners are well known to those skilled in the art, but briefly describe only those parts to which the present invention relates.

In the configuration, the tuner 100 includes two input terminals 117 and 119, and the input terminal 117 is configured to receive the received TV signal according to the VHF antenna 1, and the input terminal 119 Is configured to accept a TV signal received by the UHF antenna 2.

The signal received from the input terminal of the VHF antenna is applied to the VHF high frequency amplifier and amplified, and the amplified output is applied to the VHF mixer 105. The tuner 100 also includes a VHF local oscillator 107, and the oscillation output of the VHF local oscillator 107 is applied to the VHF mixer 105, and the VHF mixer 105 is a VHF gold oscillator 107. The VHF TV signal is mixed with the oscillation output from the signal, thereby returning the VHF TV signal as a VHF intermediate frequency signal.

Meanwhile, the received signal applied to the UHF antenna input terminal 119 is applied to the UHF high frequency amplifier 109 and amplified, and the amplified output is applied to the UHF mixer 111.

The tuner 100 also includes a UHF local oscillator 113, which oscillation output is applied to the UHF mixer 111, so that the UHF mixer 111 is UHF with an oscillation output from the UHF local oscillator 113. The TV signal is mixed, thereby converting the UHF TV signal into a UHF intermediate frequency signal. The output of the UHF mixer 111, that is, the UHF intermediate frequency signal, is amplified by the UHF intermediate frequency amplifier 115 and applied to the VHF mixer 105. During the reception of the UHF signal, the VHF high frequency amplifier 103 and the VHF local oscillator 107 do not operate while the VHF mixer 105 continues to operate.

Thus, during UHF signal reception, the VHF mixer 105 acts as a UHF intermediate frequency amplifier to amplify the UHF intermediate frequency signal, while those circuits (109) (111) (113) (115) associated with the UHF signal during VHF signal reception. Does not operate, only the circuits 103, 105 and 107 associated with the VHF signal operate. The UHF intermediate frequency signal or the VHF intermediate frequency signal obtained from the VHF mixer 105 is applied to the next stage intermediate frequency circuit not shown from the output terminal 121.

These circuits 103-115 are embedded in a shield member 101, such as a metal case or frame, to effectively prevent any undesirable radiation from these circuits embedded in the shield member 101 to other radio equipment, These circuits effectively prevent the injection of unwanted or interfering electromagnetic waves from other radio equipment.

The above-described antenna input terminals 117 and 119 and the intermediate frequency output terminal 121 are formed at predetermined positions of the shielding member 101, while these terminals are electrically isolated from the shielding member 101.

The VHF high frequency amplifier 103, the VHF local oscillator 107, the UHF high frequency amplifier 109, and the UHF local oscillator 113 each constitute a tuning circuit, but are not shown, and are tuned for channel selection having a desired reception frequency band. Change frequency

Each of these tuning circuits includes a variable reactance element for voltage control, such as a variable capacitance diode for voltage control.

The tuner 100 embedded in the shielding member 101 also provides a tuning voltage supply terminal 123 electrically isolated from the shielding member 101 to supply the tuning voltage Vt.

The tuning voltage Vt from this terminal 123 is applied to the associated circuits 103, 107, and 109, and the shielding member 113, that is, the tuner 101, is also used to adjust the tuner 100 in addition. And a test point 101 and a terminal 127 electrically isolated from the shielding member 100 to supply the output from the tuner 100 to an unshown adjusting device for adjusting the output waveform.

In general, the VHF band includes a VHF low (L) band (first band) in a relatively low frequency range, and a VHF high (H) band (second band) in a relatively high frequency range.

On the other hand, the UHF band is higher than the VHF high band, and can be considered as the third band of the high frequency range.

The tuner 100 thus comprises terminals (! 29) 131 and 133 which are electrically isolated from the shield member 101 to supply a voltage signal for the selection of these frequency bands.

In particular, the terminal 129 is for supplying a band selection voltage BL for selecting the VHF low band, and the terminal 131 is for supplying a band selection voltage BH for selecting the VHF high band. 133 is for supplying a band selection voltage BU for selecting a UHF band.

The tuner 100 further includes a terminal 125 for supplying an automatic gain adjustment (AGC) voltage obtained from an intermediate frequency circuit (not shown) and a terminal 135 for supplying an automatic unregulation (AFT) voltage. Both terminals are electrically isolated from the shield member 101.

When the corresponding reception frequency bands of each of these terminals 119, 131 and 133 are selected, a band selection voltage (BL, BH or BU of + 15V) is supplied. Each tuning circuit included in the tuner 100 is configured to respond to a tuning band selection voltage (BL, BH or BU) to correspond to a circuit constant or circuit connection of the tuning configuration as is well known to those skilled in the art. Change it to suit the frequency band.

As described above, the tuner 100 uses a variable capacitor diode for voltage control as each tuning element of the tuning circuit, and in such a conventional tuner, the tuning voltage Vt supplied to the variable capacitance diode is determined according to a given condition. Lose.

Therefore, the determination of such tuning voltage is described below with reference to an example of a TV tuner in West Germany as shown in FIG.

Referring to FIG. 2, the abscissa indicates the tuning voltage, and the ordinate indicates each channel in the VHF low band, the VHF high band, and the UHF band. For example, in West Germany, VHF low band (first band) is channel E ₂ through E ₄ , VHF high band (second band) is channel E ₅ through H ₁₂ , and UHF band (third band) is channel E ₂₁ through E _69. To cover.

This tuner is designed such that the threshold frequency of the VHF low band is determined, such that the channel E ₂ is received when the tuning voltage Vt is 3V. However, the TV tuner must be able to reliably select channel E ₂ under any and worst case conditions.

In particular, it is designed to receive the channel (E ₂ ) reliably even under such worst case conditions in consideration of frequency drift due to frequency drift and mechanical shock due to power voltage fluctuation, ambient temperature change, time change etc. It must be done.

Therefore, according to the conventional studies, the tuner is designed such that a tuning voltage Vt of 0.2V to 0.3V as an example sufficiently lower than the above-mentioned 3V is supplied from a channel selection device (not shown).

As a result, with such a conventional TV tuner, the frequency range that can be received extends beyond the receivable frequency range required in normal use to the low region indicated by the dotted line in FIG.

For example, the conventional tuner can receive a signal even when the frequency is lower than the frequency of the channel E ₂ by the frequency difference corresponding to approximately one channel in the case of the VHF low band shown by the curve L of FIG. To be adopted.

Furthermore, in the case of the VHF high band shown by the curve H, the conventional tuner can receive a signal even when the frequency is lower than the lower limit channel E ₅ due to the frequency difference of approximately three channels. To be adopted. In addition, the conventional tuner is adopted to receive a signal even when the frequency is lower than the lower limit channel due to the frequency difference corresponding to the channel in the case of the band shown by the curve.

This conventional toner has been adopted so that any desired reception frequency band can be reliably received, taking full account of any conceivable worst case conditions regarding the upper limit of each band.

However, in some countries, for the purpose of effective use of electromagnetic waves and to maintain communication security, for example, TV receivers have tended to suppress the reception of tuners beyond the new frequency range.

In particular, in some countries, as shown in FIG. 2, TV receivers have an allowable frequency corresponding to one channel in the upper and lower limits of each reception frequency band, and a tendency to restrict the receptionable frequency by the tuner by law. appear.

For example, in West Germany, the Fermenlde Technisches Zentralamt (FTZ) made the following proposal in January 1979.

Especially in West Germany, the frequency range of TV broadcasting covers 47MHz ~ 68MHz for band I, 174 ~ 230MHz for band III, and 470MHz ~ 790MHz for band IV, V.

In the upper and lower limits of each band and frequency range, deviation allowance has been determined as 300 KHz in principle.

As an exception, deviation allowances outside the frequency range for the reception frequency of 47 MHz to 870 MHz have been determined to be 7 MHz at the lower end of the frequency range and 8 MHz at the upper end of the frequency range.

As another example, similar restrictions have been applied to the Canadian TV standard broadcast shown in FIG.

According to the Canadian TV standard, the VHF low band includes channel numbers 2 through 6, and the VHF high band includes channel numbers 7 through 13 and the UHF band includes channel numbers 14 through 84.

In October 1978, by the Canadian DOC, the following restrictions were planned:

In addition, according to the Canadian TV standard, the channel for CATV is active in the area under the channel number 7 and the area over the channel number 13. Therefore, this restriction has been designed for Canadian television receivers to never receive anything other than CATV channels assigned in the area below channel number 7 and above channel number 13.

In particular, it is possible to reliably receive TV signals of channel numbers 2 to 6, 7 to 13, and 14 to 83 on TV receivers not designed to receive such CATV broadcasts. Therefore, such a receiver has a limited plan to not receive the signal of I in channel A of CATV channel in the area under channel number 7 and the signal of W in CATV channel A in the area of channel number 13 and above.

However, in making such a restriction, channel J and channel J in one area, that is, the area close to channel number 7 or less, channel J and channel J in the area close to channel number 13 or more, and channel J, in the area close to channel number 13 or more, are different from each other. It has been considered to allow for range.

As mentioned above, in some countries, there is a tendency to strictly limit the up and down deviation from the original frequency band for the purpose of communication security monitoring and efficient use of electromagnetic waves.

In order to cope with such a strict frequency limit in such a situation, people would have considered the upper and lower limits of the tuning voltage described above. In general, however, in the tuner apparatus, the reception frequency characteristic tuning voltage varies depending on each set.

Referring to FIG. 2, such variability is shown as the range specified by A to F connecting the lower end points a to f of each receive band U (H) (L).

As an example, when the top of the UHF band and the VHF high band are related, the tuning voltage of the high channel of the UHF band for a given tuner is lower than the tuning voltage of the high channel of the VHF high band.

The same applies to the relationship between the tuning voltage of the low channel of the VHF high band and the tuning voltage of the channel of the VHF low band.

Thus, in the case where there is a change in the high and low relationship between the high-channel tuning voltage and the low-channel tuning voltage between each band, the above-mentioned tuning voltage limitation is such that such tuning voltage limiting means is not applied to each receiving band. Had to be provided.

As an example, in limiting the upper limit of the receivable frequency of the UHF band to conform to the FTZ standard, assuming the relationship shown in FIG. 2, the upper limit of the tuning voltage from the tuning voltage generating means (not shown) is the change range (E). The minimum value of can be set constant to 20V.

This is evidenced by the assumption that when a high channel in the VHF highband is able to receive a so-called 22 V tuning voltage, then that high channel will be capable of receiving beyond that setting.

Therefore, it is essential to limit both upper and lower limits of the tuning voltage for each of the reception bands.

However, the provision of such tuning voltage limiting means in each of the reception bands complicates the structure of the tuner device and makes the tuner device expensive. In view of the above, in accordance with the present invention, the tuner device of the present invention is provided in common to a plurality of receive bands and includes a variable reactance element for voltage control for supplying a tuning voltage from a single tuning voltage generating means.

And a means for limiting the upper and lower limits of the applied tuner voltage, wherein the tuner device of the present invention has a tuning voltage for tuning to the highest receivable frequency of one reception band between a plurality of reception bands. Tuning voltage to be equal to or higher than the tuning voltage for tuning to the tuning frequency for tuning to the lowest reception frequency of one of the other reception bands among the plurality of reception bands. Set to establish a relationship equal to or lower than the voltage. Therefore, according to the present invention, it is not necessary to provide the tuning voltage limiting means for each of the reception bands in order to limit the variation range of the tuning frequency. Therefore, the tuning range of the tuner device of the present invention has a frequency range that is limited to a single circuit configuration.

In a detailed embodiment of the present invention, the tuner voltage generating means may be voltage synchronous.

Such voltage-synchronized tuning voltage generating means includes switching means which are conducted in response to a pulse signal and a smoothing circuit for smoothing the output of the switching means.

In this embodiment, the impedance means is inserted into the current path of the switching device, allowing a predetermined residual voltage to be supplied to the smoothing circuit until the switching means becomes conductive.

According to the above-described implementation, the lower limit of the tuning voltage can be limited to a very simple structure.

In another embodiment of the present invention, the tuning voltage generating means constitutes a potentiometer provided for each channel, so that the supply voltage is fed by each potentiometer to provide a tuning voltage corresponding to each channel, and the diodes are each slid to the potentiometer. Each diamond is commonly connected to the input electrode of the main transistor.

The second electrode of the transistor is connected to the supply voltage source, and the third electrode of the transistor is connected to the tuning voltage removing terminal.

The predetermined output resistance is connected between the tuning voltage removing terminal and the ground potential, and the power supply voltage is stabilized by the constant voltage diode, thereby limiting the upper limit of the tuning voltage obtained from the tuning voltage removing terminal.

In addition, since a predetermined resistance is connected between the voltage source and the output resistance so that a constant current flows through the output resistance, the lower limit of the output voltage (tuning voltage) obtained from the tuning voltage removing terminal or the voltage applied to the output resistance is limited to a predetermined value.

In the above-described embodiment, the lower limit of the tuning voltage can be limited to only one resistor added to the tuning voltage generating means in the future, while the upper limit of the tuning voltage can also be limited since only the constant voltage diode is used, so that The tuner device employing the restriction can be a very simple structure.

Therefore, the main object of the present invention is to provide a tuner device which can ensure the limitation of the change range of the tuning frequency as a simple structure. Another object of the present invention is to provide a tuner device that can be surely applied to the limitation of the tuning frequency at a low price.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following description the invention has been described by way of some examples, in which the invention is embodied in a TV tuner, but the invention can be adapted not only to a TV tuner but also to an FM receiver.

Briefly, the tuner device is used to establish a reception frequency characteristic between the tuning voltages of the tuning frequencies of a plurality of reception bands, so that the tuning voltage for tuning to the highest receivable frequency of one reception band is the remaining reception band. Is equal to or greater than the tuning voltage for tuning to the highest receivable frequency, and the tuning voltage for tuning to the lowest reception frequency in the remaining reception bands among the plurality of reception bands is tuned to the lowest reception frequency in the remaining reception band. Is equal to or higher than the tuning voltage. 4 is a graph showing an example of such a reception frequency characteristic, where the abscissa indicates the tuning voltage, and the ordinate indicates the tuning frequency (receive channel) for each reception band of the VHF low band VHF high band UHF band. do.

In this illustrated embodiment, the tuning voltage for tuning to the upper limit frequency (highest receivable frequency) of the UHF band is V ₆ , the VHF high band upper limit frequency tuning voltage V ₅ , and the tuning voltage for the upper limit frequency of the VHF low band is V _4. Assume In addition, it is assumed that the tuning voltage for tuning to the lower limit frequency (lowest reception frequency) in the VHF low band is V ₁ , and in the case of the high band, V ₂ is the VHF band.

The relationship of these voltages (V ₁ to V ₆ ) is chosen such that V ₆ > V ₅ , V ₆ > V ₄ , V ₁ <V ₂ , V ₁ <V ₃ .

Especially when the tuning voltage V ₆ is applied in the UHF band, the high channel E ₆₉ is reliably received, but the channel E ₆₉ +8 MHz is adjusted so that it cannot exceed the upper limit.

On the other hand, in the case of the tuning voltage V ₁ , the low channel E ₂ is reliably received in the VHF low band, but the channel E ₂ -7 MHz is exceeded.

The upper and lower limit frequencies of the VHF high band are limited by the tuning voltage (V ₅ ) (V ₂ ), and the upper limit frequency of the VHF low band is limited by the lower limit frequency or tuning voltage (V ₅ ) of the UHF band. It is limited by the tuning voltage V ₄ .

In other words, the tuning voltages V ₁ to V ₆ are set in a relationship of V ₆ = V ₅ = V ₄ and V ₁ = V ₂ = V ₃ .

The tuning voltage generating means, one example described later, is configured to generate the tuning voltage common to each of the reception bands according to the last mentioned relationship. 5a and 5b are schematic views of an example of a TV tuner according to the present invention, and FIG. 5a shows a UHF related part, and FIG. 5b shows a VHF related part.

These UHF and VHF portions are housed in a single shielding member 101 and housed in a single tuner, but these portions are shown as being contained within the shielding member 101 partitioned in FIGS. 5A and 5B for simplicity. . Referring to FIG. 5A, the UHF portion will first be described.

The shielding member 101 is divided into appropriate descriptions by a suitable shielding plate. The UHF high frequency amplifier 109 including the input tuning circuit is in the first chamber, and the interstage tuning circuit 110 is in the next chamber, and is disposed between the UHF high frequency amplifier 109 and the mixer 111.

The mixer diode Dm constituting the UHF mixer 111 is disposed in the same chamber as the inter-stage tuning circuit 110.

The UHF high frequency amplifier 109 constitutes an input tuning circuit, which constitutes a resonant circuit including the first voltage control variable capacitance diode D ₁ and the first resonant conductor L ₁ .

This resonant circuit is set to select a desired one of the broadcast signals in the UHF band supplied from the UHF antenna input terminal 119.

The amplifying transistor T ₁ amplifies the selected UHF VT signal, and the amplified TV signal is applied to the braking circuit of the inter-stage tuning circuit 110.

This braking circuit consists of a variable capacitance diode D ₂ for controlling the second voltage and a providing conductor L ₂ .

This braking circuit is electronically coupled to the second tuning circuit, which is composed of a third voltage control variable capacitance diode D ₃ and a third resonant conductor L ₃ .

Therefore, the TV signal amplified by the transistor T ₁ is supplied to the anode of the mixer diode Dm through the coupling between the first resonant circuit and the second resonant circuit.

On the other hand, the UHF pole oscillator 113 includes an oscillation transistor (T ₂ ), the fourth voltage control variable capacitance diode (D ₄ ), the fourth resonant conductor (L ₄ ), and the oscillation output from the UHF pole oscillator (113) Is applied to the cathode of the diode Dm.

The mixer diode Dm thus mixes the two supplied frequency signals to provide a UHF intermediate frequency signal, which is applied to the UHF intermediate frequency amplifier 115.

This UHF intermediate frequency amplifier 115 includes an amplifying transistor T ₃ , and this output is applied to the VHF mixer 105 shown in FIG. 5B.

The tuning voltages Vt obtained from the tuning voltage terminals 123 of the tuner 100 are variable capacitance diodes D ₁ and D ₂ for controlling the first second third fourth voltage constituting the public vibration circuit, respectively. ₃ ) (D ₄ ) is commonly applied. This tuning voltage Vt is also applied to the VHF portion shown in FIG. 5B. UHF band selection jeonchung (BU) obtained from the terminal 133 is a transistor (T ₁₎ (T ₂₎ is applied to the (T _3), so these transistors _{(T 1) (T 2)} (T 3) to the terminals (133 Is applied as the application of the voltage BU.

The frequency adjustment of the two UHF parts is performed by the following method.

In order to adjust the tuning frequency of the UHF portion, the first voltage BU is applied to the terminal 133.

As the tuning voltage Vt humanized to the terminal 123, the tuning voltage V6 shown in FIG. 4 is determined, for example.

At that time, the pole oscillation frequency of the UHF pole oscillator 113 is adjusted.

This frequency adjustment consists of a tree loop TL ₄ coupled to a fourth resonant conductor L ₄ .

At the same time, the extreme oscillation frequency is adjusted to be the frequency corresponding to the highest one channel, which is several MHz lower than the normal oscillation frequency of the high channel of the UHF band.

Then the tuning voltage (Vt) derived from terminal 123 is applied as the voltage (V _3).

The trimmer capacitor TC ₄ included in the UHF pole oscillator 113 is simultaneously adjusted so that the stationary pole oscillation frequency of the low channel of the UHF band is obtained as the voltage V ₃ , whereby the frequency of the UHF pole oscillator 113 is increased. After the adjustment, the input tuning circuit and the short tuning circuit 110 of the UHF high frequency amplifier 109 are adjusted so that the output of the UHF mixer 111 becomes a normal intermediate frequency signal. In particular, if the tuning voltage Vt is the upper limit voltage limited by the Zener diode ZD or the upper limit voltage, the trimmer capacitor TC ₅ (TC ₆ ) (TC ₇ ) and the corresponding trimmer loop (TL ₁ ) (TL ₂ ) (TL ₃ ) is adjusted so that the normal intermediate frequency reaches the highest reception frequency of the UHF band.

At that time, trimmer capacitors TC ₁ (TC ₂ ) and TC ₃ adjust so that the normal intermediate frequency reaches the lowest reception frequency of the UHF band when the tuning voltage Vt becomes the lower limit.

In general, the adjustment of the difference between the input tuning and the step tuning frequency wave that is the normal intermediate frequency and the polar oscillation frequency is made by tracking adjustment. Such tracking adjustments are made in both these areas as well as in the UHF high and UHF low bands.

Tracking in such intermediate region is carried out by trimmer loops TC ₁ (TC ₂ ) (TC ₃ ), whereby the characteristics of the reception frequency with respect to the tuning voltage Vt are shown, for example, by curve U in FIG. As determined. At that time, the reception frequency characteristic of the UHF band with respect to the tuning voltage Vt is determined by adjusting the UHF part.

The VHF portion of the next tuner 100 is shown in FIG. 5B.

This VHF portion includes a VHF high frequency amplifier 103, which includes an input tuning circuit, which receives a VHF TV signal from the VHF antenna input terminal 117.

The input tuning circuit includes an inductor L ₅ (L ₆ ) and a variable capacitance diode D ₅ for voltage control acting with these inductors for setting the tuning frequency of the resonant circuit.

Furthermore, the VHF high frequency amplifier 103 includes an amplifying transistor T ₄ , and this output is applied to the braking circuit that constitutes the inter-stage interrogation 104. The braking circuit includes an inductor L ₇ (L ₈ ) coupled to the second tuning circuit and a variable capacitance diode D ₆ for voltage control.

The second tuning circuit includes an inductor L ₄ (D ₁₀ ) and a voltage controlled variable capacitance diode D ₇ .

Therefore, the VHF TV signal selected by the input tuning circuit of the VHF high frequency amplifier 103 is applied to the transistor T ₅ constituting the VHF mixer 105 through the inter-step tuning circuit 104 and the second tuning circuit.

Meanwhile, the VHF pole oscillator 107 includes an oscillation transistor T ₆ , a full-voltage control variable capacitance diode D ₈ , and an inductor L ₁₁ and L ₁₂ .

The switching diodes SD ₁₁ , SD ₁₂ , SD ₁₃ , and SD ₁₄ are an input tuning circuit formed of a VHF high-frequency amplifier 103, a braking tuning circuit of the inter-stage tuning circuit 104, and a VHF pole oscillator 107. Is coupled to.

The VHF band select voltage suppressor BL is applied from the terminal 129 to the cathode of the switching diodes SD ₁₁ to SD ₁₄ , and the VHF hibernation select voltage BH is applied from the terminal 131 to the switching diode SD ₁₁ . Is applied to the enwood of SD ₁₄ ).

Therefore, when the VHF high band is selected, the corresponding switch diodes SD ₁₁ (SD ₁₂ ) (SD ₁₃ ) (SD ₁₄ ) are conducted by the band select voltage BH, so that the inductor L ₆ (L ₈ ) ( L ₁₀ ) L ₁₂ is removed from each resonant circuit. On the other hand, the transistor T ₅ of the VHF mixer 105 is applied not only with VHF reception but also with UHF reception, and thus the transistor T ₅ acts as an intermediate frequency amplifier of UHF when receiving UHF. . The output of the VHF mix 105, which is an intermediate frequency signal of, is applied to the terminal 121. On the other hand, the terminal 127 serving as a test point is connected to the output header of the second tuning circuit of the inter-step tuning circuit 104.

And although the terminal 135 for automatic micro defibrillation is not shown, it is associated with the VHF pole oscillator 107 and the UHF pole oscillator 113.

A terminal 125 for the automatic gain adjustment voltage is also used to supply the automatic gain adjustment voltage to the transistor T ₁ shown in FIG. 5A and the transistor T ₄ shown in FIG. 5B.

Main water adjustment of the VHF portion is performed after the above-described frequency adjustment of the UHF portion is made.

In the frequency adjustment of the VHF portion, first, the VHF high band is adjusted. This is followed by adjustment of the VHF low band.

This is followed by adjustment of the VHF low band.

However, the continuous tuning sequence of the VHc highbend and VHF lowband can be reversed.

First, the voltage BH is applied to the terminal 131, thereby placing the VHF portion in the VHF high band mode.

At this time, as the tuning voltage Vt, for example, the voltage V5 shown in FIG. ₄ is applied.

The inductor L ₁₁ included in the VHF pole oscillator 107 is adjusted so that the adjustment is performed to be synchronized with the solid neil E ₁₂ of the VHF high band. The voltage V ₃ of FIG. 4 is then applied to the tuning voltage Vt and the inductor L ₁ is adjusted so that the frequency is tuned to the low channel of the VHF high band. The inductor L ₅ , L ₇ and L ₉ are then adjusted by making tracking adjustments. At that time, in order to adjust the VHF low band, a voltage BL is applied to the terminal 129, and at this time, the voltage ₁ V (V ₄ ) shown in FIG. 4 is applied as the tuning voltage _t V. As the inductor L ₁₂ adjusts, the frequency will be tuned to the high and low channel of the VHF low band.

At that time, the lower limit of the pole oscillation frequency is adjusted to be lower than the stationary pole oscillation frequency of the low channel E ₂ and by MHz, i.

Tracking adjustment is performed by adjusting inductors L ₆ (L ₈ ) and L ₁₀ . After the above-described adjustments are made in each frequency band, the adjustment of the VHF high band is again performed to fix the effect caused by the adjustment of the VHF low band.

The above-described frequency adjustment as a real system problem is determined by the temperature variable of the extreme oscillation frequency of the UHF pole oscillator 113 and the VHF pole oscillator 107, the duration range of the time variable automatic frequency tuning operation, and the pull-in frequency. In performing the frequency adjustment, the points to be considered are given as time variables and temperature variables of the pull-in frequency of the automatic fine tuning operation and the polar oscillation frequency of the UHF polar oscillator 113.

In particular, the temperature variable of the polar oscillation frequency of the UHF polar oscillator 113 is within ± 1.5MHz in the temperature change range -10 ℃ ~ +60 ℃, the time variable of the local oscillation frequency of the UHF polar oscillator is within ± 2MHz, automatic The pull-in range of the fine tuning operation is ± 1.5MHz.

Therefore, the highest receivable frequency in the UHF band is determined to be 2 MHz higher than the highest channel E ₆₉ .

By selecting the highest frequency by the above-mentioned method, the temperature variable (+1.5 MHz) + time variable (+2 MHz) + pull-in range of automatic fine operation (+1.5 MHz) and the sum of the aforementioned 2 MHz (+7 MHz) It will be a frequency range that contains the possibility of leaving at a higher frequency above the highest receiving channel.

In the West, the frequency range that allows the upper limit of the UHF channel is 8 MHz, so this remains 1 MHz even in the worst case, considering the various variables and pull-in ranges mentioned above, so the tuner thus installed will meet the FTZ standard requirements.

Even when these temperature and time variables affect low frequencies, those changes will be -1.5 MHz and -2 MHz, respectively.

In the above-mentioned adjustment, the frequency is adjusted to be 2 MHz higher than the normal frequency of the uppermost channel, so that no problem occurs in the reception of the uppermost channel.

The lowest receivable frequency of the VHF low band is determined to be 1.5 MHz lower than the lowest channel (E ₂ ).

For example, the temperature variable of the oscillation frequency of the VHF local oscillator-107-is within ± 0.4 MHz and the time variable is within ± 1.0 MHz in the temperature range of -10 ° C to + 60 ° C.

Pull-in range of automatic frequency tuning is ± 1.5MHz.

Therefore, taking into account the lowest reception frequency mentioned above, the sum of the temperature variable (-0.4 MHz) + time variable (-1 MHz) + automatic fine tuning pull-in range (-1.5 MHz) + -1.5 MHz (4.4 MHz) is the lowest reception. It can change in a lower direction that is lower than the channel.

Since the lower limit frequency range of the VHF low band in West Germany is 7 MHz, a margin of 2.6 MHz remains even in the above-described variables and pull-in ranges and in the worst case.

Therefore, the tuner of the present invention can fully satisfy the FTZ standard requirements. Although this frequency varies higher by temperature and time variables, such a variable is +0.4 MHz + 1.5 MHz, and this frequency is adjusted to be 1.5 MHz lower than the normal frequency of the lowest channel, so that the lowest channel There is no effect on reception of (low channel).

FIG. 6 is a schematic diagram of one embodiment of the present invention. Referring to FIG. 6, the tuning voltage generation circuit 200 is connected to provide the tuning voltage Vt to the tuner 100 described in FIG. Zener diode ZD and terminal 137 shown in dashed lines are applied to the eighth embodiment described below.

Some of the above-described embodiments of the tuning voltage generating circuit 200 shown in FIG. 6 will be described with reference to FIGS.

7 is a schematic diagram of the main part of the above-described embodiment of the tuning voltage generating circuit. Here, the zener diode ZD is used to limit the upper limit of the tuning voltage Vt.

The voltage applied from the voltage source Vcc through the resistor R becomes a constant voltage by the zener diode ZD.

Thus, the constant voltage obtained by the zener diode is adjusted by the semi-fixed resistor VR ₁ to reach the tuning voltage V ₆ for tuning the high channel E ₆₉ of the UHF band.

On the other hand, the tuning voltage V ₁ , which can be tuned to the low channel E ₂ of the VHF low band, is applied to the variable resistor VR ₂ from the terminal 129 of the VHF low band setting voltage BL of the tuner 100. Is applied through.

In addition, the potential difference or the variable resistors P ₁ to Pn are provided in series between the outputs of the tuning voltage supply terminal 123 and the semi-fixed resistor VR ₁ to provide a predetermined tuning voltage associated with each channel.

Then, by closing one of the switches SW ₁ to (SW _n ) connected to each sliding contact of the potentiometer, the voltage of the potentiometer corresponding to the closed switch is transferred from the terminal 123 to the tuner 100 through the diode D ₁₀ . Is approved.

Even if any one of the potentiometers is adjusted to provide a voltage lower than the lower limit of the tuning voltage V ₁ , the diode D ₁₀ is reverse biased and turned off because the voltage adjusted by the variable resistor VR ₂ is higher than that voltage. Thus, a voltage lower than the voltage Vt is left to be supplied to the tuner 100.

According to the FIG. 7 embodiment, the upper limit of the tuning voltage Vt is limited to the voltage V ₆ , and the lower limit of the tuning voltage Vt is limited to the voltage V ₁ .

Therefore, as shown in FIG. 4, the highest receivable frequency of the UHF band and the lowest receivable frequency of the VHF low band are limited.

On the other hand, the tuning voltage generating circuit 200 acts to provide the tuner 100 with a voltage of V ₆ = V ₅ = V ₄ and V ₁ = V ₂ = V ₃ and various embodiments described later as in FIG. The same applies to the example.

In doing so, there is an advantage that the limiting means of the tuning voltage acts to determine only the upper and lower limits.

Therefore, it is not necessary to determine the upper and lower limits of the tuning voltage Vt for each of the reception bands individually.

Furthermore, the embodiment of FIG. 7 uses the voltage BL for setting the VHF low band to obtain the voltage V ₁ .

Therefore, the circuit configuration is greatly simplified.

The use of voltage BL simplifies the structure since it is sufficient to determine at least the lowest receivable frequency of the VHF low band with this voltage V ₁ .

Therefore, this band setting voltage BL does not need to be used to obtain the voltage V ₁ as in the seventh embodiment, and this voltage can be removed from any other part.

Therefore, the tuner can be configured such that the voltage V ₁ is always obtained in any receive band.

On the other hand, semi-fixed resistance VR _{1 is} provided for fine tuning and is not essential.

8 is a modification of the FIG. 7 embodiment.

Section 8 of the embodiment sets the upper limit voltage (V ₆₎ of the sixth degrees to dotted line using the pathway shown, the tuning voltage (Vt).

The variable resistor VR ₂ for setting the lower limit voltage V ₁ is provided inside the tuner 100.

9 is a schematic view of essential parts of the above-described embodiment of the tuning voltage generating circuit.

9 is the simplest example.

In particular, the illustrated embodiment used a jumper wire 201.

In this embodiment, the jumper wire 201 is first removed, and a voltage of +30 volts is applied to the contact 204 as an example from a negative voltage source (not shown). This is determined by adjusting the variable semi-fixed resistor VR ₃ connected between each stage of the potentiometers P ₁ to P _n of this tuning voltage Vt and the ground potential.

At that time, the jumper wire 201 is swallowed between the terminals 202 and 203, and a voltmeter (not shown) is connected to the contact 204.

While observing the voltmeter, the semi-fixed resistor VR ₁ is adjusted so that the voltmeter becomes + 30V, thereby determining the highest voltage V ₆ of the tuning voltage Vt.

The jumper wire 201 is connected between the terminals 202 and 203 until the tuner is installed in the TV receiver.

10 to 13 show further embodiments of the tuning voltage generating circuit, and FIGS. 14 to 15 show examples of impedance means for using the above-described embodiment.

The embodiment shown in Figs. 10 to 13 is a so-called voltage synthesizer type tuning voltage generating circuit.

A voltage synthesizer type channel selector is disclosed, for example, in US Pat. No. 3,968,440, issued to George John Ehni, dated 7.6.1976.

Referring to the embodiment of Fig. 10, the pulse signal terminal 207 as shown in Fig. 16A is applied.

The pulse width of such a pulse signal is controlled by a control circuit, not shown, to be the same as that associated with the designated channel.

The conduction period of the switching transistor Tr included in the switching circuit 205 is controlled as the action of the pulse signal applied from the terminal 207, and during the conduction period of the transistor Tr, through the resistor R ₃ from the voltage source. Current flows through the transistor Tr.

Therefore, the voltage magnitude coinciding with the conduction period of the transistor Tr, i.e., the pulse width of the pulse signal applied in this way, appears at the input of the smoothing circuit 206 or at the defect.

The voltage appearing at the contact 208 is smoothed by the smoothing circuit 206 and is applied to the terminal of the tuner 100 as the tuning voltage Vt. In the illustrated embodiment, the impedance Z is inserted into the current path of the switching circuit 205, that is, the emitter circuit of the transistor Tr.

Zener diode ZD is also coupled between contact 208 and ground. This zener diode ZD is used to limit the input voltage of the smoothing circuit 206 and thus to the constant voltage V6 of the tuning voltage Vt.

On the other hand, the impedance Z is used to limit the lower limit V ₁ of the tuning voltage Vt.

가 되고, 여기에서 전압(V_CE)은 트랜지스터(Tr)의 전도의 경우 콜렉터와 에미터 전간의 포화전압이 된다.In particular, in the case of conduction of the transistor Tr at the contact 208, the voltage V is V = (120-V _CE ) × by the impedance Z.

Here, the voltage V _CE becomes the saturation voltage between the collector and the emitter in the case of conduction of the transistor Tr.

만큼 더 높다.On the other hand, when there is no impedance (Z), the voltage (V) is equal to the voltage (V _CE ), so the voltage (V) in the presence of the impedance (Z) is (120-V _CE ) × than without the impedance (Z) ×.

As high as.

Therefore, the lower limit of the tuning voltage Vt is limited to the constant voltage V ₁ (so-called 1.25V).

Thus, according to the tenth embodiment, when the impedance Z is inserted and the switching element is conducted, a predetermined residual voltage appears at the output point 208, and the lower limit of the tuning voltage Vt is greater than the voltage V ₁ . Undesirably lowers.

FIG. 11 illustrates an example in which the impedance Z is connected between the collector electrode of the switching transistor Tr and the contact 208 instead of being connected between the emitter electrode ground of the switching transistor Tr.

In this case, the residual impedance is present in the electric current path of the switching transistor Tr, so that a given residual voltage is generated at the contact 208. Therefore, the tuning voltage Vt is limited so as not to be lower than the constant voltage V ₁ .

In FIG. 12 and FIG. 13, the deployment effect transistor is used as the switching transistor Tr, while the remainder is the same as the embodiment shown in FIG. 10 and FIG.

14 illustrates one embodiment of impedance Z.

Example 14 used a resistor as impedance Z.

Figure 15 shows another embodiment of impedance Z.

FIG. 15 was used as series Z of a plurality of diodes D ₁₁ to D _1n as impedance Z. FIG.

On the other hand, the series connection of the diode is selected such that the current flow direction in the current path of the switching element 205 becomes the forward direction of the series connection.

When using a series connection of diodes D ₁₁ to D _1n as impedance (Z), the voltage (V ') of contact 208 is V' = V _CE + _n V _a K, where V _a K is diode D _1. Is the forward drop voltage for each of D _n . Therefore, when the impedance Z is terminated by the series connection of the diodes, the voltage V is increased by the total sum of the diode's falling voltages _n V _a K, and thus the tuning voltage Vt is the constant voltage V ₁ . Limited to. Operation of the tenth embodiment in combination with the fourteenth embodiment will now be described in detail with reference to FIG.

A pulse signal (Fig. 16A) having a pulse width corresponding to the designated channel is applied to the terminal 207 from a pulse signal circuit not shown.

At this time, the transistor Tr is conducted as a function of the pulse width of the pulse signal, and at this time, the voltage at the contact point 208 does not become O (V _CE ), but the impedance Z, that is, the transistor Tr due to the resistance. Is maintained at the above-mentioned voltage V ₁ while conducting.

Thus, as shown in FIG. 16B, the voltage appearing at the contact 208 is smoothed by a smoothing circuit with direct current that does not include a ripple element as shown in FIGS. 16C and 16D.

At this time, the pulse width of the pulse signal is maximized and the lower limit is limited by the resistance connected to the emitter electrode of the transistor Tr even if the transistor Tr is conducted during a substantial portion of this period. The tuning voltage Vt will not be lower than the constant voltage V ₁ (so-called 1.25V).

FIG. 17 is a schematic diagram of a main part of still another embodiment of the tuning voltage generating circuit, and FIG. 18 is a graph for explaining its operation.

A feature of the illustrated embodiment is that a resistor R ₉ is connected between the collector of the transistor Tr ₁ and the emitter electrode.

In operation, the channel selection signal is applied to one of the input terminals a ₁ to a _n of the channel setting portion 209 made by the integrated circuit, for example. At that time, one of the transistors Q ₁ to Q _n corresponding to the channel selection signal is turned on, and the current is supplied from one of the variable resistors VR ₁₁ to VR 1 _n corresponding to the transistor that is now conducting from the voltage source Vcc. Flow. Therefore, one of the diodes D ₂₁ to D _2n connected to the sliding contact of the variable resistor corresponding to the transistor in the conducting state is conducted, and the voltage set by the corresponding variable resistor is applied to the base electrode of the transistor Tr ₁ . This transistor Tr ₁ is commonly connected to the anode of D _2n in each diode D ₂₁ as described above, and is also connected to the voltage source Vcc via a resistor R ₈ (R ₁₀ ) and emitter The electrode is connected to the output resistor R ₇ and the ripple cancellation capacitor C ₄ .

The diode D ₄₁ is connected in parallel in the reverse direction between the base of the transistor Tr ₁ and the emitter electrode.

This diode D ₄₁ is conducted when the tuning voltage Vt from the output terminal 210 changes from a high value to a low value, thereby helping to discharge the capacitor C ₄ .

Transistor Tr ₁ acts to compensate for the change in tuning voltage (Vt) due to the change in voltage drop by diode D ₂₁ to V _2n with temperature, and this compensation is reversed for these diodes D ₂₁ to D _2n . By means of an inserted PN junction.

Zenidaio Wood (ZD) is used to limit the upper limit of the limiting tuning voltage (Vt) to the set value (V ₆ ).

The input terminals 211, 212 and 213 are input terminals to the band setting voltage BL (BH) and BU, respectively, and are terminals of the channel setting portion 209 by the selection switches S ₁ to S _n . is optionally linked to (b ₁ to b _n ).

On the other hand, D _3n at diode D ₃₁ is connected to terminals 211 to 213 and terminals b ₁ to b _n only for the selection channel, and not to other channels.

In the illustrated embodiment, resistor R _{9 is} connected between voltage source line 214 and output resistor R ₇ .

Thus, the constant current flows mainly through the resistor R ₉ to the output resistor R ₇ regardless of the conduction and non-conductivity of the transistor TR ₁ .

Therefore, the constant voltage drop is obtained due to such a constant current at both ends of the output resistor R ₇ , that is, at the output terminal 210.

Accordingly, the lower limit of the tuning voltage Vt may be limited to the constant voltage V ₁ by properly selecting the ratio of the resistors R ₉ and R ₇ .

For example, when the voltage of the voltage source line 214 is 32V, the output resistance R ₇ is selected to 100 KΩ, and the resistor R ₉ is selected to approximately 2.2 MΩ.

The lower limit of the tuning voltage Vt is limited to the constant voltage V ₁ (so-called 1.25V). In particular, referring to FIG. 17, the voltage obtained from any one of the variable resistors VR ₁₁ to VR _1n serving as a function of the selection signal is applied to the base electrode of the transistor Tr ₁ , and the magnitude of the voltage and the transistor at that time. The conductivity of Tr ₁ is determined, and thus the capacitor C ₄ is charged, so that the voltage at the output terminal 210, that is, the tuning voltage Vt, is increased to become the voltage value of the channel associated with the channel selection signal.

When this tuning voltage Vt is changed from a high channel to a low channel, the charge accumulated in the capacitor C ₄ discharges through the diode D ₁₄ , and thus the voltage of the output terminal 210 decreases as described above. do.

However, in this case, even if a voltage lower than the set voltage V ₁ (so-called 1.25 V) is applied to the base electrode of the transistor Tr ₁ from any of the variable resistors VR ₁ to VR _n , the transistor Tr ₁ Since no forward bias is applied between the base and the emitter electrode, the transistor Tr ₁ is not conductive, and a tuning voltage Vt lower than the voltage Vt (so-called 1.25V) does not appear at the output terminal 210.

The upper limit V ₆ of the tuning voltage Vt is limited to a value lower than the voltage of the voltage source line 204 due to the voltage drop between the collector of the transistor Tr ₁ and the emitter electrode.

FIG. 18 shows the relationship of the tuning voltage to the rotational speed of the fine tuning knob (not shown). In this case, the sliding contact of the variable resistor VR ₁ to VR _1n is the fine tuning knob in the FIG. 17 embodiment. Is moved.

As shown in FIG. 18, the number of rotations of the fine tuning knob (not shown) is small, that is, the voltage obtained by the variable resistor is small, so that the minimum value of the tuning voltage Vt is lower than the voltage V ₁ (so-called 1.25V). It doesn't work.

When there is no resistance R ₉ , when the rotation angle of the fine tuning knob is small as shown by the dotted line in FIG. 18, the tuning voltage Vt becomes approximately OV, resulting in the lowest reception frequency of the VHF low band. Is, for example, beyond the limits of the FTZ standard.

In this situation, the embodiment shown in FIGS. 7 to 18 is adopted so that the lower limit of the tuning voltage Vt is limited to the constant voltage V ₁ .

On the other hand, since the conventional tuner cannot put such a limit on the lower limit of the tuning voltage Vt, this voltage is lower than 0.3V.

Therefore, it was necessary to design a tuner such that the lowest channel (E ₂ ) can be received with a tuning voltage of approximately 0.5V in order to limit the lowest receivable frequency in the VHF low band to meet the requirements of the FTZ standard. However, the reception performance of channel E ₂ is degraded with respect to the reception performance of other channels.

The reason is that the lower the applied tuning voltage is, the worse the characteristics of the variable capacitance diode for voltage control are.

In comparison, the channel E ₂ is designed to tune the tuner to obtain a relatively high tuning voltage by limiting the lower limit of the tuning voltage Vt as implemented in the present invention to the constant voltage V ₁ (so-called 1.25V). This is enough and the tuner's performance is improved.

It goes without saying that the embodiments shown in Figures 7-18 apply not only to the FTZ standard, but also to other standards such as the DOC standard.

19 shows an example of conversion of a double conversion TV tuner.

Tuners of such dual conversion TVs are disclosed, for example, in US Pat. No. 3,639,840, issued to Jacob Shelcel et al. Dated 1972.2.1. In such dual conversion TV tuners, a single variable local oscillator needs to convert a wide range of tuning frequencies from the VHF low band to the UHF band opening.

However, varying the tuner frequency extensively using only a single voltage controlled variable local oscillator introduces difficulties in the local oscillator 504 and two voltage controlled local oscillators 504V and 504U are used in the FIG. 19 embodiment. come.

In particular, the variable pole oscillator 504V is used in the VHF band and is adapted to be variable over a frequency range of 2000 to 2,350 MHz. On the other hand, the variable local oscillator 504U for voltage control is provided in the UHF band and is adopted to be variable over the frequency range of 2500 to 2900 MHz, for example.

The oscillating outputs of these two variable local oscillators 504V and 504U are applied to the contacts 511V and 511V of the band selector switch 511, and the switch 511 is a band selector voltage terminal provided in the tuner 500. It is switched by the band selection voltage (BV) BU applied to the 431 and 533.

In particular, when a VHF band selection voltage BV for selecting the VHF band is applied to the terminal 531 from a channel selector (not shown), this switch 511 is switched to the contact 511V.

On the other hand, when the UHF band selection voltage BU is applied from the terminal 533, the switch 511 is switched to the contact 511U.

Thus, the oscillation output from the variable local oscillator 504V is applied to the first mixer 503 when VHF is selected.

On the contrary, when the UHF band is selected, the oscillation output from the variable local oscillator 504U is applied to the first mixer.

FIG. 20 is a graph showing the relationship between the broadcast channel (frequency) and the tuning voltage, which is a graph of the FIG. 10 implementation using the TV tuner against the West German standard.

From the case of such a parallel implementation of the double conversion type, it is sufficient to supply a tuning voltage Vt having a limited upper and lower limit as shown in Figs.

Therefore, the highest receivable frequency in the UHF band is limited to a constant tuning voltage (V ₆ ) (V ₁ ), respectively.

While the invention has been shown and described in detail as described above, it will be apparent that the invention is not to be accorded the limitation, the scope of the invention, which is equated with the illustrative embodiments and is limited only by the terms of the appended claims.

Claims (1)

The tuners 100 and 500 include voltage controlled variable capacitance diodes D ₁ to D ₄ , wherein the tuner has a plurality of reception bands and a tuning voltage generating circuit for generating a tuning voltage Vt. 200 is connected to the tuners 100 and 500, and the tuning voltage Vt is applied to the voltage controlled variable capacitance diodes D ₁ to D ₄ , and the voltage controlled variable capacitance diode D is used. ₁ ) to limiting means ZD (VR ₁ ) (VR ₂ and D ₉ ) (VR ₃ ) (R ₇ and R ₉ ) (for limiting the limit of the tuning voltage Vt applied to (D ₄ ) ( Z) is connected to the tuning voltage generating circuit 200 and is connected between the plurality of receiving bands L, H, and U in relation to the tuning voltage V ₁ and V ₆ limited by the limiting means. Receivable frequency determining means (TL ₁ ) to (TL ₄ ), (TC ₁ ) to (TC ₇ ), and (L ₅ ) to (L ₁₂ ) for determining the maximum receivable frequency of a reception band. End of residual receiving band inserted into (100) (500) A tuner device, characterized in that the tuning voltage (V ₂ ) (V ₃ ) (V ₄ ) (V ₅ ) is within the value of said limited tuning voltage (V ₁ ) (V ₆ ).

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