JP2007124290A - Dual type digital television tuner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the phenomenon that local oscillation signals leak from one system to the other system and to prevent the decline of a reception performance due to the leakage of the local oscillation signals into the other system, such as the deterioration of phase noise. <P>SOLUTION: When setting the oscillation frequency band of local oscillators 15 and 35 on the band side higher than the frequency band of digital television signals, low-pass filters 20 and 40 for turning the frequency band of the local oscillation signals to a block band are interpolated between lines 23-25 and 43-45 connecting first and second direct conversion circuits 10 and 30 and a distributor 1, and leakage local oscillation signals generated on the line 23 or 43 accompanying the oscillation operation of the local oscillator 15 or 35 of one system are blocked from flowing into the direct conversion circuit 10 or 30 of the other. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a dual-type digital television tuner having two systems.

  2. Description of the Related Art Conventionally, there is a dual type digital television tuner provided with two systems capable of selecting an arbitrary channel (see, for example, Patent Document 1). As shown in FIG. 7, the dual-type digital television tuner described in Patent Document 1 branches a digital television signal frequency-converted by an outdoor down converter by a distributor 201, and the branched digital television signal is The signals are respectively input to the corresponding direct conversion circuits 210 and 230 and converted into baseband signals (I, Q) orthogonal to each other, and then added by the demodulators 222 and 242 to be demodulated.

  In the direct conversion circuit 210, the digital television signal is input to the pair of mixers 213 and 214 via the intermediate frequency amplifier 211 and the variable gain amplifier 212, while the local oscillation signal of the local oscillator 215 is input to the phase shifter 217. To the mixers 213 and 214. At this time, the oscillation frequency of the local oscillator 215 is set so that a local oscillation signal having the same frequency as the frequency of the desired channel is input to the mixers 213 and 214.

The other direct conversion circuit 230 inputs the digital television signal to the pair of mixers 233 and 234 via the intermediate frequency amplifier 231 and the variable gain amplifier 232 in the same manner as described above, and the local oscillation signal of the local oscillator 235 is a phase shifter. It is configured to input to the mixers 233 and 234 via 237.
Japanese Patent Laid-Open No. 2002-300488

  However, when the local oscillator 215 oscillates in one direct conversion circuit 210, the local oscillation signal of the local oscillator 215 may be input to the other direct conversion circuit 230 via the distributor 201. Similarly, when the local oscillator 235 oscillates in the other direct conversion circuit 210, the local oscillation signal of the local oscillator 235 may be input to the one direct conversion circuit 210 via the distributor 201. Therefore, when receiving the same channel, the oscillation frequencies of the local oscillators 215 and 235 are the same, so that there is a problem that phase noise is deteriorated due to interference between local oscillation signals and reception performance is lowered.

  Further, as shown in FIG. 1 of Japanese Patent Application Laid-Open No. 2002-300488, one frequency-divides the local oscillation signal by a frequency divider, and the other frequency-multiplies the local oscillation signal by a frequency multiplier, so that each oscillation frequency is It is possible to solve such a problem. However, in this case, two types of direct conversion integrated circuits having different configurations are required, and there is a problem that the cost is significantly increased.

  The present invention has been made in view of the above point, and can prevent a phenomenon in which a local oscillation signal leaks from one system to the other system. An object of the present invention is to provide a dual-type digital television tuner that can prevent a decrease in reception performance due to leakage without significant cost increase.

  A dual type digital television tuner according to the present invention includes a distributor for branching a received signal and outputting it to a line of one system and a line of the other system, and a first local oscillator connected to the line of the one system A first frequency conversion circuit that converts the frequency of the received signal using a local oscillation signal output from the first oscillation circuit, and a local oscillation signal output from a second local oscillator connected to the line of the other system. A second frequency conversion circuit that converts the frequency of the received signal, and a path from the first frequency conversion circuit to the second frequency conversion circuit via the distributor to limit the passage of the local oscillation signal And a band limiting unit.

  According to this configuration, since the band limiting means for limiting the passage of the local oscillation signal is provided on the path from the first frequency conversion circuit to the second frequency conversion circuit via the distributor, the first frequency conversion The band limiting means can prevent the local oscillation signal leaking from the local oscillator of the circuit to the one line from being mixed into the second frequency conversion circuit, and from the local oscillator of the second frequency conversion circuit to the other frequency converter. The band limiting means can prevent the local oscillation signal leaking from the line from being mixed into the first frequency conversion circuit.

  In the dual digital television tuner, the present invention sets the oscillation frequency of the first and second local oscillators to a frequency band higher than the frequency band of the received signal, and the band limiting unit includes the band limiting unit, The oscillation frequency band of the first and second local oscillators is composed of at least one low-pass filter having a stop band.

  With this configuration, the local oscillation signal leaked from the local oscillator of the first frequency conversion circuit to one line and the local oscillation signal leaked from the local oscillator of the second frequency conversion circuit to the other line are provided on the path. Is attenuated by the low-pass filter.

  In the dual digital television tuner, the present invention sets the oscillation frequency of the first and second local oscillators to a frequency band lower than the frequency band of the received signal, and the band limiting unit includes the band limiting unit, The oscillation frequency band of the first and second local oscillators is composed of at least one high-pass filter having a stop band.

  With this configuration, the local oscillation signal leaked from the local oscillator of the first frequency conversion circuit to one line and the local oscillation signal leaked from the local oscillator of the second frequency conversion circuit to the other line are provided on the path. Is attenuated by a high-pass filter.

Further, the present invention provides the dual digital television tuner, wherein the band limiting means comprises at least one variable trap circuit that is controlled so that a trap position is an oscillation frequency of the first or second local oscillator. It is characterized by being.
With this configuration, when receiving the same channel, the local oscillation signal leaked from the local oscillator of the first frequency conversion circuit to one line and the local oscillation signal leaked from the local oscillator of the second frequency conversion circuit to the other line Is removed by a trap circuit provided on the path.

  According to the present invention, it is possible to prevent the local oscillation signal from leaking from one system to the other system, and to prevent the reception performance from being deteriorated due to leakage of the local oscillation signal to other systems, such as deterioration of phase noise. it can.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a configuration diagram of a dual-type digital television tuner according to the present embodiment. In the dual-type digital television tuner according to the present embodiment, for example, a digital television signal frequency-converted by an outdoor down converter is input to the distributor 1. The distributor 1 branches the digital television signal into two and outputs it. The first and second direct conversion circuits 10 and 30 integrated in the output stage of the distributor 1 are provided in parallel. Further, the demodulator is provided at the output stage of the first and second direct conversion circuits 10 and 30. 22 and 42 are provided.

  The first direct conversion circuit 10 amplifies an input digital television signal with an intermediate frequency amplifier 11, and further performs amplitude control with a variable gain amplifier 12 whose gain is controlled by AGC control. Input to mixers 13 and 14. A local oscillation signal having the same frequency as that of the channel to be received is input to the pair of mixers 13 and 14. Therefore, the local oscillator 15 set to an oscillation frequency N times the frequency of the channel to be received, and the channel to be received by dividing the local oscillation signal output from the local oscillator 15 by 1 / N. A frequency divider 16 that outputs a local oscillation signal of the same frequency, and a mixer 13 that generates two local oscillation signals that are 90 ° out of phase by shifting the phase of the local oscillation signal output from the frequency divider 16. 14 and a phase shifter 17 for inputting to 14. The oscillation frequency of the local oscillator 15 is controlled by the PLL circuit 21. The baseband signals (I, Q) output from the mixers 13 and 14 are input to the demodulator 22 via the corresponding baseband amplifiers 18 and 19.

  The second direct conversion circuit 30 has the same circuit configuration as that of the first direct conversion circuit 10. That is, an intermediate frequency amplifier 31 that amplifies an input digital television signal, a variable gain amplifier 32 that is gain-controlled by AGC control, a pair of mixers 33 and 34, and an oscillation frequency that is N times the frequency of the channel to be received A local oscillator 35, a frequency divider 36 that divides the local oscillation signal by 1 / N, a phase shifter 37, baseband amplifiers 38 and 39, and a PLL circuit 41. The PLL circuit 41 determines the oscillation frequency of the local oscillator 35 based on the frequency of the channel to be received by the second direct conversion circuit 30.

  In this embodiment, when the local oscillator 15 of the first direct conversion circuit 10 oscillates, a local oscillation signal leaked on the line 23 flows into the second direct conversion circuit 30 at least on the local oscillator 15. Band limiting means for limiting the oscillation frequency band is provided. In addition, when the local oscillator 35 of the second direct conversion circuit 30 oscillates, at least the oscillation frequency band of the local oscillator 35 on the path through which the local oscillation signal leaked on the line 43 flows into the first direct conversion circuit 10. Band limiting means for limiting the bandwidth is provided.

  Here, the relationship between the frequency band of the digital television signal and the oscillation frequency band of the local oscillators 15 and 35 will be described. In the present embodiment, the local oscillators 15 and 35 are oscillated in a frequency band higher than the frequency band of the digital television signal. As shown in FIG. 2, for example, when receiving a digital television signal in a frequency band from 950 MHz to 2150 MHz, the oscillation frequency of the local oscillators 15 and 35 is 2500 MHz to 4500 MHz, which is a frequency band higher than 950 MHz to 2150 MHz. Set. A local oscillation signal oscillated at an oscillation frequency N times the frequency of the digital television signal to be received is frequency-divided by 1 / N by the frequency dividers 16 and 36 and the same frequency as the frequency of the digital television signal. Has been converted.

  As described above, when the local oscillators 15 and 35 are oscillated in a frequency band higher than the frequency band of the digital television signal, the local oscillation signal leaked on the lines 23 and 43 is higher than the frequency band of the digital television signal. High frequency. Therefore, in order to cut the leak local oscillation signal, band limiting means having a stop band in a frequency band higher than the frequency band of the digital television signal is used.

  In the present embodiment, a low-pass filter 20 as a band limiting unit is inserted on a line 23 for introducing a digital television signal distributed by the distributor 1 to the first direct conversion circuit 10. A low pass filter 40 serving as a band limiting unit is inserted on a line 43 for introducing the digital television signal to the second direct conversion circuit 30.

Next, the operation of the dual type digital television tuner configured as described above will be described.
In the first direct conversion circuit 10, the PLL circuit 21 controls the oscillation frequency of the local oscillator 15 to be an oscillation frequency N times the channel frequency to be received. The local oscillation signal generated by the local oscillator 15 is frequency-divided to 1 / N by the frequency divider 16 and supplied to the mixers 13 and 14 with the phase shifter 17 being 90 ° out of phase. The digital television signal output from the distributor 1 is attenuated by the low-pass filter 20 on the higher band side than the frequency band of 950 MHz to 2150 MHz, and then input to the mixers 13 and 14. The mixers 13 and 14 extract digital television signals of channels to be received. The digital television signal of the channel to be received extracted in this way is amplified by the baseband amplifiers 18 and 19 and then input to the demodulator 22 as a baseband signal (I, Q).

  Here, by causing the local oscillator 15 to oscillate, a leak local oscillation signal having the oscillation frequency appears on the line 23. In the present embodiment, as shown in FIG. 3, the leak local oscillation signal generated by the oscillation operation of the local oscillator 15 is attenuated by the low-pass filter 20 having the oscillation frequency band of the local oscillators 15 and 35 as the stop band. A leak local oscillation signal that could not be attenuated by the low-pass filter 20 flows into the line 45 on the second direct conversion circuit 30 side via the distributor 1. It is attenuated again by the low-pass filter 40 having the oscillation frequency band as a stop band. As a result, the leak local oscillation signal that appears on the line 23 by the oscillation operation of the local oscillator 15 of the first direct conversion circuit 10 is blocked by the low-pass filters 20 and 40, and therefore flows into the second direct conversion circuit 30. Can be suppressed.

  In the second direct conversion circuit 30, the PLL circuit 41 controls the oscillation frequency of the local oscillator 35 to be an oscillation frequency N times the channel frequency to be received. When the same channel is received simultaneously by two systems, the same oscillation frequency as that of the first direct conversion circuit 10 is set. When a different channel is received, an oscillation frequency different from that of the first direct conversion circuit 10 is set. . The digital television signal output from the distributor 1 is attenuated on the high-band side from the frequency band of 950 MHz to 2150 MHz in the low-pass filter 40, and then the mixers 33 and 34 via the intermediate frequency amplifier 31 and the variable gain amplifier 32. To enter. Digital television signals of channels to be received by the mixers 33 and 34 are extracted, amplified by the baseband amplifiers 38 and 39, and then input to the demodulator 42 as baseband signals (I, Q).

  By causing the local oscillator 35 to oscillate, a leak local oscillation signal having the oscillation frequency appears on the line 43. In the present embodiment, as shown in FIG. 3, the leak local oscillation signal generated by the oscillation operation of the local oscillator 35 is attenuated by the low-pass filter 40 having the oscillation frequency band of the local oscillators 15 and 35 as the stop band. A leak local oscillation signal that could not be attenuated by the low-pass filter 40 flows into the line 25 on the first direct conversion circuit 10 side via the distributor 1, but the oscillation frequencies of the local oscillators 15 and 35 are the same as those of the low-pass filter 40. It is attenuated again by the low-pass filter 20 whose band is the stop band. As a result, the leak local oscillation signal that appears on the line 43 due to the oscillation operation of the local oscillator 35 of the second direct conversion circuit 30 is blocked by the low-pass filters 40 and 20, and therefore flows into the first direct conversion circuit 10. Can be suppressed.

  As described above, according to the present embodiment, when the oscillation frequency band of the local oscillators 15 and 35 is set higher than the frequency band of the digital television signal, the frequency band of the local oscillation signal is set as the stop band. Since the low-pass filters 20 and 40 are inserted in the lines 23-25 and 43-45 connecting the first and second direct conversion circuits 10 and 30 and the distributor 1, the local oscillator 15 or 35 of one system is used. It is possible to prevent the leak local oscillation signal generated on the line 23 or 43 due to the oscillation operation from interfering with the local oscillation signal oscillated by the local oscillator 35 or 15 of the other system. Deterioration can be prevented. In addition, the low-pass filters 20 and 40 provided as the band limiting means between the lines 23-25 and 43-45 of the two systems have an attenuation effect on the leak local oscillation signals from both systems. Thus, the attenuation effect can be obtained, and the number of elements of the filter circuit for obtaining the same attenuation can be halved.

  In the above description, the oscillation frequencies of the local oscillators 15 and 35 are set to a frequency band higher than the frequency band (for example, 950 MHz to 2150 MHz) of the digital television signal, but the present invention is a frequency band of the digital television signal. The present invention is also applicable when the frequency band is set lower than (for example, 950 MHz to 2150 MHz).

  When the local oscillators 15 and 35 oscillate in a frequency band lower than the frequency band of the digital television signal, the leaked local oscillation signal leaked on the lines 23 and 43 has a frequency lower than the frequency band of the digital television signal. Become. Therefore, in order to cut the leak local oscillation signal, band limiting means having a stop band on the lower frequency side than the frequency band of the digital television signal is used.

  FIG. 4 is a circuit configuration diagram in the case where the oscillation frequency of the local oscillators 15 and 35 is set to a frequency band lower than the frequency band (for example, 950 MHz to 2150 MHz) of the digital television signal. As shown in the figure, multipliers 24 and 44 are provided in place of the frequency dividers 16 and 36, and are lower than the frequency band of the digital television signal on the lines 23-25 and 43-45 where the leak local oscillation signal appears. High pass filters 51 and 52 having a stop band on the frequency side are provided.

The operation of the dual type digital television tuner configured as described above will be described.
In the first direct conversion circuit 10, the PLL circuit 21 controls the oscillation frequency of the local oscillator 15 to be an oscillation frequency that is 1 / N times the channel frequency to be received. The local oscillation signal generated by the local oscillator 15 is multiplied by N by the multiplier 24 and supplied to the mixers 13 and 14 with the phase shifter 17 being 90 ° out of phase. The digital television signal output from the distributor 1 is attenuated by the high-pass filter 51 on the lower frequency band side than the frequency band of 950 MHz to 2150 MHz, and then input to the mixers 13 and 14. The mixers 13 and 14 extract digital television signals of channels to be received.

  By causing the local oscillator 15 to oscillate, a leaked local oscillation signal having the oscillation frequency appears on the line 23. The generated leak local oscillation signal is attenuated. Further, the leak local oscillation signal that could not be attenuated by the high pass filter 51 flows into the line 45 on the second direct conversion circuit 30 side via the distributor 1, but as with the high pass filter 51, It is attenuated again by the high-pass filter 52 having the oscillation frequency band as a stop band. As a result, the leak local oscillation signal that appears on the line 23 due to the oscillation operation of the local oscillator 15 of the first direct conversion circuit 10 is blocked by the high-pass filters 51 and 52.

  In the second direct conversion circuit 30, the PLL circuit 41 controls the oscillation frequency of the local oscillator 35 so that the oscillation frequency is 1 / N times the channel frequency to be received. When the same channel is received simultaneously by two systems, the same oscillation frequency as that of the first direct conversion circuit 10 is set. When a different channel is received, an oscillation frequency different from that of the first direct conversion circuit 10 is set. . The digital television signal output from the distributor 1 is attenuated in the high-pass filter 52 on the lower frequency band side than the frequency band of 950 MHz to 2150 MHz, and then the mixer 33 via the intermediate frequency amplifier 31 and the variable gain amplifier 32. 34. The mixers 33 and 34 extract digital television signals of channels to be received.

  By causing the local oscillator 35 to oscillate, a leaked local oscillation signal of the oscillation frequency appears on the line 43 and is generated by the oscillation operation of the local oscillator 35 by the high pass filter 52 having the oscillation frequency band of the local oscillators 15 and 35 as a stop band. The leaked local oscillation signal is attenuated. A leak local oscillation signal that could not be attenuated by the high-pass filter 52 flows into the line 25 on the first direct conversion circuit 10 side via the distributor 1, but the oscillation frequencies of the local oscillators 15 and 35 are the same as the high-pass filter 52. It is attenuated again by the high-pass filter 51 whose band is the stop band. As a result, the leak local oscillation signal that appears on the line 43 by the oscillation operation of the local oscillator 35 of the second direct conversion circuit 30 is blocked by the high-pass filters 52 and 51, and therefore flows into the first direct conversion circuit 10. Can be suppressed.

  Incidentally, in the dual type digital television tuner shown in FIGS. 1 and 4, the low-pass filters 20 and 40 or the high-pass filters 51 and 52 are used as band limiting means, but these filters can be replaced with a variable trap circuit.

  FIG. 5 is a configuration diagram in which the low-pass filters 20 and 40 are replaced with variable trap circuits 61 and 62 in the dual-type digital television tuner shown in FIG. The variable trap circuit 61 of the first direct conversion circuit 10 is set so that a predetermined band including the oscillation frequency of the local oscillator 15 becomes the trap position. Specifically, since the oscillation frequency of the local oscillator 15 is controlled by the PLL circuit 21 according to the change of the channel to be received, the trap position is changed following the oscillation frequency based on the control signal from the PLL circuit 21. Let Similarly, the variable trap circuit 62 of the second direct conversion circuit 30 is set so that a predetermined band including the oscillation frequency of the local oscillator 35 becomes the trap position. The trap position is changed following the oscillation frequency of the local oscillator 15 that changes in response to a change in the channel to be received by a control signal from a set side (not shown) equipped with a dual type digital television tuner.

  The operation of the dual type digital television tuner configured as described above will be described. In the first direct conversion circuit 10, it is assumed that the local oscillator 15 oscillates at an oscillation frequency that matches the Mth channel to be received. By such an oscillation operation, a leak local oscillation signal appears on the line 23 close to the local oscillator 15. As shown in FIG. 6, the trap position of the variable trap circuit 61 is controlled so that the oscillation frequency of the local oscillator 15 becomes the trap position P1 (frequency characteristics indicated by a solid line in FIG. 6). Therefore, the leak local oscillation signal generated with the oscillation operation of the local oscillator 15 is cut by the variable trap circuit 61, and the flow into the second direct conversion circuit 30 is suppressed. When the second direct conversion circuit 30 also receives the Mth channel, the trap position of the variable trap circuit 62 is also controlled to the trap position P1 shown in FIG. For this reason, a part of the leak local oscillation signal that could not be removed by the variable trap circuit 61 of the line 23 flows into the line 45 via the distributor 1, but is removed again by the variable trap circuit 62, so that the second direct The flow into the conversion circuit 30 is suppressed to a level that can be substantially ignored.

  On the other hand, it is assumed that the second direct conversion circuit 30 oscillates at an oscillation frequency that matches the Mth channel to be received by the local oscillator 35. By such an oscillation operation, a leak local oscillation signal appears on the line 43 close to the local oscillator 35. As shown in FIG. 6, the trap position of the variable trap circuit 62 is controlled so that the oscillation frequency of the local oscillator 35 becomes the trap position P1 (frequency characteristic indicated by a solid line in FIG. 6). Therefore, the leak local oscillation signal generated with the oscillation operation of the local oscillator 35 is cut by the variable trap circuit 62, and the flow into the first direct conversion circuit 10 is suppressed. When the first direct conversion circuit 10 also receives the M-th channel, the trap position of the variable trap circuit 61 is also controlled to the trap position P1, so that the variable trap circuit 62 of the line 43-45 is used. A part of the leaked local oscillation signal that could not be removed flows into the line 25 via the distributor 1, but since it is removed again by the variable trap circuit 61, the flow into the first direct conversion circuit 10 is substantially ignored. Suppressed to the extent possible.

  As shown in FIG. 6, when the channel to be received in the first direct conversion circuit 10 is changed to the (M + 1) th channel, the PLL circuit 21 controls the local oscillator 21 to set the frequency of the (M + 1) th channel to N. Set to double the oscillation frequency. In accordance with this, the trap position of the variable trap circuit 61 is moved from P1 to P2 shown in FIG. That is, the trap position is controlled so that the local oscillation frequency set in the local oscillator 15 at the time of receiving the (M + 1) -th channel becomes the trap position P2 (frequency characteristics indicated by a dotted line in FIG. 6). In the second direct conversion circuit 30 as well, when the channel to be received changes, the trap position of the variable trap circuit 62 is controlled as in the first direct conversion circuit 10.

  In this way, the leak local oscillation signal is removed by controlling the trap positions of the variable trap circuits 61 and 62 so that the local oscillation frequency becomes the trap position following the oscillation frequency of the local oscillators 15 and 35. be able to.

  In the above description, the oscillation frequency band of the local oscillators 15 and 35 is defined as the stop band for both the line 23 for introducing the digital television signal into one system and the line 43 for introducing the digital television signal into the other system. Although band limiting means (low-pass filter, high-pass filter, trap) is provided, the band limiting means may be provided only on one of the lines. Even if the band limiting means is provided only on one line, the effect of blocking the leak local oscillation signal can be expected.

  The present invention can also be applied to a dual tuner other than a digital BS tuner, and can also be applied to a frequency conversion circuit other than a direct conversion receiver system.

  The present invention is applicable to a dual-type digital television tuner having two systems.

1 is a circuit configuration diagram of a dual-type digital television tuner according to an embodiment of the present invention. Explanatory diagram showing the relationship between the frequency band of a digital television signal and the oscillation frequency band of a local oscillator The conceptual diagram which shows the flow of the leak local oscillation signal in the said embodiment Circuit diagram of a dual-type digital television tuner using a high-pass filter as band limiting means Circuit diagram of a dual-type digital television tuner using a variable trap circuit as a band limiting means Explanatory diagram showing the relationship between the trap position of the variable trap circuit and the local oscillation frequency Circuit diagram of a conventional dual-type digital television tuner

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Divider 10 1st direct conversion circuit 11, 31 Intermediate frequency amplifier 12, 32 Variable gain amplifier 13, 14, 33, 34 Mixer 15, 35 Local oscillator 16, 36 Divider 17, 37 Phase shifter 18, 19, 38, 39 Burst band amplifier 20, 40 Low pass filter 21, 41 PLL circuit 22, 42 Demodulator 23, 25, 43, 45 Line 24, 44 Multiplier 51, 52 High pass filter 61, 62 Variable trap circuit

Claims (4)

  A distributor for branching a received signal and outputting it to a line of one system and a line of the other system, and a local oscillation signal output from a first local oscillator connected to the line of one system A first frequency conversion circuit that converts the frequency of the received signal, and a second frequency converter that converts the frequency of the received signal using a local oscillation signal that is connected to the other line and output from a second local oscillator. A dual digital television comprising: a circuit; and band limiting means for limiting the local oscillation signal provided on a path from the first frequency conversion circuit to the second frequency conversion circuit via the distributor. John Tuner. Setting the oscillation frequency of the first and second local oscillators to a frequency band higher than the frequency band of the received signal;
2. The dual type digital television tuner according to claim 1, wherein the band limiting means is composed of at least one low pass filter whose oscillation frequency band of the first and second local oscillators is a stop band. Setting the oscillation frequency of the first and second local oscillators to a frequency band lower than the frequency band of the received signal;
2. The dual-type digital television tuner according to claim 1, wherein the band limiting means comprises at least one high-pass filter whose oscillation frequency band of the first and second local oscillators is a stop band. 2. The dual type according to claim 1, wherein the band limiting means comprises at least one variable trap circuit controlled so that a trap position becomes an oscillation frequency of the first or second local oscillator. Digital television tuner.

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