JP2006165738A - Pocket device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the influence of a jamming signal generation source on a receiver, if the jamming signal generation source is provided in the same enclosure of a pocket device. <P>SOLUTION: If an oscillation frequency outputted from a jamming generator 63 is inside or near the band of the oscillation frequencies of a local oscillator or intermediate frequencies outputted from a mixer 56, an oscillation frequency outputted from the local oscillator 57 and the center frequency of a bandpass filter 58 are moved together by a controller 53 to the outside of the oscillation frequency outputted from the jamming generator 63. Consequently, the desired end is attained. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a portable device having a receiving unit provided in the same housing as an interference signal generation source.

  Hereinafter, a conventional portable device will be described. As a conventional portable device, for example, a mobile phone with a television is as follows. That is, as shown in FIG. 9, the transmitting / receiving unit 1 of the mobile phone and the receiving unit 2 of the mobile TV are mounted in the same casing, and each is controlled independently by a separate control unit 3 or 4. .

  The configuration of the receiving unit 2 includes an input terminal 6 connected to the antenna 5, and a mixer 8 in which one input is connected to the input terminal 6 and the output of the local oscillator 7 is connected to the other input. The output of the mixer 8 is connected to the fixed intermediate frequency filter 9 having the bandwidth of the television broadcast wave 21a, and the output terminal 10 is connected to the output of the intermediate frequency filter 9. . In addition, an oscillator 11 is provided in the transmission / reception unit 1 of the mobile phone. Reference numeral 12 denotes a partition plate that separates the transmission / reception unit 1 and the reception unit 2.

  The operation of the portable device configured as described above will be described below. In FIG. 10A, 21 is a television broadcast wave input to the antenna 5, and 22 is an intermediate frequency output from the mixer 8. Reference numeral 23 denotes an oscillation frequency output from the local oscillator 7 for obtaining the intermediate frequency 22 when the television broadcast wave 21 is input.

  First, the output of the local oscillator 7 is set to the oscillation frequency 23a so that the controller 4 can view the desired television broadcast wave 21a. Then, the television broadcast wave 21 a is mixed with the oscillation frequency 23 a by the mixer 8 and converted to the intermediate frequency 22.

  The desired television signal is selected by passing through a fixed intermediate frequency filter 9 having the bandwidth of the television broadcast wave 21a. The selected television signal is output from the output terminal 10. The television signal output from the output terminal 10 is output from the cathode ray tube as a video output via a demodulator, although not shown.

  Thus, in order to receive the desired television broadcast wave 21 a from among the television broadcast waves 21, the oscillation frequency 23 a is set higher (or lower) by the frequency of the desired television broadcast wave 21 a than the intermediate frequency 22. By mixing the oscillation frequency 23a of the local oscillator 7 by the mixer 8, the intermediate frequency 22 is obtained and the channel selection is performed. The horizontal axis 24 is frequency.

  Reference numeral 25 shown in FIG. 10B is an output frequency output from the oscillator 11 of the transmission / reception unit 1 provided in the mobile phone. This output frequency 25 is determined by the local oscillator 7 and the intermediate frequency 22 of the reception unit 2. In some cases, the frequency is included.

As prior art document information related to the invention of this application, for example, Patent Document 1 is known.
JP-A-5-19131

  However, in such a conventional mobile phone, the transmitting / receiving unit 1 of the mobile phone and the receiving unit 2 of the mobile TV are mounted in the same casing, and each frequency is independently controlled by the control unit 3 or 4. Therefore, the following problems occurred.

  That is, when the mobile phone communicates with the base station or receives a mobile phone during reception of the mobile TV, the oscillator 11 provided in the transmission / reception unit 1 operates.

  Then, the output of the oscillator 11 (or the output amplified by the power amplifier) may interfere with the output of the local oscillator 7 and the mixer 8 of the receiving unit 2 provided in the same casing.

  When such interference enters the local oscillator 7, the C / N performance of the local oscillator 7 is deteriorated. Further, if the output signal (intermediate frequency) of the mixer 8 is entered, the S / N performance is degraded. Both of these have the problem of deteriorating the television reception screen.

  Therefore, the present invention solves such a problem, and an object of the present invention is to provide a portable device that is not affected by an interference signal generation source provided in the same housing.

  In order to achieve this object, the portable device of the present invention is configured such that the oscillation frequency output from the interference generator is within or near the band of the oscillation frequency of the first local oscillator or the intermediate frequency output from the first mixer. In this case, the control unit moves both the oscillation frequency of the first local oscillator and the center frequency of the first intermediate frequency filter so that they are outside the oscillation frequency output from the interference generator.

  Thereby, the intended purpose can be achieved.

  As described above, according to the present invention, in the case where the oscillation frequency output from the interference generator is within or near the band of the oscillation frequency of the first local oscillator or the intermediate frequency output from the first mixer, The control unit moves both the oscillation frequency of the first local oscillator and the center frequency of the first intermediate frequency filter so as to be outside the oscillation frequency output from the interference generator. The intrusion of the oscillation frequency output from the interference generator into the oscillation frequency and the first intermediate frequency can be prevented and the influence can be eliminated.

  Therefore, it is possible to realize a portable device that is not affected by the interference signal generation source provided in the same housing.

  Further, unlike the conventional case, a partition plate that separates the interference generator and the receiving unit at a high frequency is not necessary, and a reduction in size and cost can be realized.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram of a portable device according to Embodiment 1 of the present invention. The portable device in the present embodiment controls a reception unit 51 that receives a high-frequency signal, an interference signal generation unit 52 that becomes an interference signal for the reception unit 51, and controls both the interference signal generation unit 52 and the reception unit 51. The control unit 53 is mounted in the same housing.

  Reference numeral 54 denotes an antenna that receives a high-frequency signal. The antenna 54 is connected to the input terminal 55 of the receiving unit 51. Note that a cable for transmitting a high-frequency signal may be connected to the input terminal 55 instead of the antenna 54.

  The input terminal 55 is connected to one input of the mixer 56, and the output of the PLL-controlled local oscillator 57 is connected to the other input of the mixer 56. A filter or a high-frequency amplifier that allows a high-frequency signal to pass may be connected in series between the input terminal 55 and one input of the mixer 56.

  The output of the mixer 56 is connected to the output terminal 60 via a band pass filter 58 as an intermediate frequency filter that passes the intermediate frequency. The bandwidth of the band pass filter 58 is substantially equal to the bandwidth of the high frequency signal, and the center frequency can be varied via the filter control terminal 61. The variable range of the center frequency can be moved upward and downward by more than one half of the bandwidth. An intermediate frequency amplifier may be inserted between the band pass filter 58 and the output terminal 60.

  Reference numeral 62 denotes a tuning data input terminal. The tuning data input terminal 62 is connected to a PLL circuit (not shown), and the oscillation frequency output from the local oscillator 57 is controlled by this PLL circuit. .

  Reference numeral 63 denotes an interference generator provided in the interference signal generator 52 and is connected to the data terminal 64. Therefore, the frequency of the interference signal output from the interference generator 63 can be controlled by the data supplied to the data terminal 64.

  The data terminal 64, the tuning data input terminal 62, and the filter control terminal 61 are connected to the control unit 53, respectively. Therefore, the desired high frequency signal can be received by controlling the oscillation frequency of the local oscillator 57 (via the PLL circuit) with the control signal output from the control unit 53. Further, the center frequency of the band pass filter 58 can be controlled by a filter control signal supplied to the filter control terminal 61. Furthermore, the oscillation frequency of the interference generator 63 can be controlled.

  As described above, in the portable device in the present embodiment, the control unit 53 controls the oscillation frequency of the interference generator 63 and the oscillation frequency of the local oscillator 57. That is, the control unit 53 is in a position where the oscillation frequency of the interference generator 63 and the oscillation frequency of the local oscillator 57 can be managed so as not to interfere with each other.

  In other words, when the desired high frequency signal input from the antenna 54 is received, the control unit 53 knows the oscillation frequency of the local oscillator 57 and the intermediate frequency output from the mixer 56. The oscillation frequency output from the interference generator 63 is also known.

  Therefore, when the oscillation frequency output from the interference generator 63 interferes with the oscillation frequency output from the local oscillator 57 or the intermediate frequency output from the mixer 56, the oscillation frequency output from the local oscillator 57 is moved. Thus, the influence of the oscillation frequency output from the interference generator 63 can be eliminated.

  That is, when the oscillation frequency of the disturbance generator 63 is higher (including the case where it is equal) and within the band of the bandpass filter 58 or in the vicinity thereof, the oscillation frequency output from the local oscillator 57 is set to the intermediate frequency. Move one half or more of the bandwidth in the direction of decreasing frequency. Further, the center frequency of the band pass filter 58 is also moved in the direction of decreasing by the same amount.

  Conversely, when the oscillation frequency of the interference generator 63 is lower than the intermediate frequency and within the band of the bandpass filter 58 or in the vicinity thereof, the oscillation frequency output from the local oscillator 57 is increased in the intermediate frequency. Move more than half of the bandwidth. Further, the center frequency of the band pass filter 58 is also moved in the direction of increasing by the same amount.

  By performing such control by the control unit 53, the intermediate frequency after the mixer 56 for the desired high frequency signal can be separated from the frequency of the interference generator 63. That is, the bandpass filter 58 can remove the frequency of the interference generator 63.

  As described above, in the mobile device in the present embodiment, AM receiver, FM radio, TV tuner, mobile phone receiver, transceiver, GPS, etc. can be considered as the receiver 51, and the interference signal generator 52 can be A mobile phone mainly includes a transmitter, a transceiver mainly includes a transmitter, a telemeter, and the like.

  Therefore, such a receiving unit 51 and an interference signal generating unit 52 are effective in a portable device mounted in the same casing.

(Embodiment 2)
FIG. 2 shows various forms of the intermediate frequency filter used in the present invention. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and the description is simplified. The intermediate frequency filter 71 shown in FIG. 2A changes the capacitance value of the varicap diode 72 with the control voltage input from the filter control terminal 61 and continuously varies the center frequency.

  The bandwidth of the intermediate frequency filter 71 is slightly wider than the bandwidth of the high frequency signal. Then, the control voltage input from the filter control terminal 61 can be moved by a half or more of the bandwidth to the higher and lower center frequencies, respectively. 71a is an input terminal of the intermediate frequency filter 71, and 71b is an output terminal. Since the intermediate frequency filter 71 uses the varicap diode 72, the center frequency can be continuously varied.

  The intermediate frequency filter 73 shown in FIG. 2B controls the open / short circuit of the electronic switch 74 with the control voltage input from the filter control terminal 61. That is, a fixed capacitor 73c or a fixed inductor 73d constituting the intermediate frequency filter 73 is connected to the electronic switch 74, and the center frequency band to be passed is switched by opening or shorting the electronic switch 74. .

  Note that the capacitor 73c or the inductor 73d may be formed on the printed board in a pattern, or may be formed by mounting a chip component.

  Alternatively, a low-pass filter or a high-pass filter may be configured using the fixed capacitor 73c or the fixed inductor 73d.

  The bandwidth of the intermediate frequency filter 73 is slightly wider than the bandwidth of the high frequency signal. Then, the control voltage input from the filter control terminal 61 can be shifted by a bandwidth or more to the higher or lower center frequency. 73a is an input terminal of the intermediate frequency filter 73, and 73b is an output terminal. Since the intermediate frequency filter 73 uses a fixed capacitor or a fixed inductor, the intermediate frequency filter 73 having a stable pass band can be obtained.

  The intermediate frequency filter 75 shown in FIG. 2C has two independent intermediate frequency filters 76 and 77 whose center frequencies are different from each other by the bandwidth of the high frequency signal, arranged in parallel, and input from the filter control terminal 61. The electronic switches 78a and 78b are both switched by voltage to select one of the intermediate frequency filters 76 and 77.

  The bandwidth of the intermediate frequency filters 76 and 77 is slightly wider than the bandwidth of the high frequency signal. 75a is an input terminal of the intermediate frequency filter 75, and 75b is an output terminal. Since the intermediate frequency filter 75 uses two independent intermediate frequency filters 76 and 77, the intermediate frequency filter 75 having excellent attenuation characteristics can be realized.

  The intermediate frequency filter 75 shown in FIG. 2C has two independent intermediate frequency filters 76 and 77 whose center frequencies are different from each other by the bandwidth of the high frequency signal, arranged in parallel, and input from the filter control terminal 61. The electronic switches 78a and 78b are both switched by voltage to select one of the intermediate frequency filters 76 and 77.

  The bandwidth of the intermediate frequency filters 76 and 77 is slightly wider than the bandwidth of the high frequency signal. 75a is an input terminal of the intermediate frequency filter 75, and 75b is an output terminal. Since the intermediate frequency filter 75 uses two independent intermediate frequency filters 76 and 77, the intermediate frequency filter 75 having excellent attenuation characteristics can be realized.

  The intermediate frequency filter 79 shown in FIG. 2D includes a parallel circuit in which a high-pass filter 79a having a cutoff frequency higher than the center frequency and a low-pass filter 79b having a cutoff frequency lower than the center frequency are arranged in parallel. An intermediate frequency filter 79c having a bandwidth more than twice the bandwidth of the high-frequency signal connected in series with the circuit is arranged, and the electronic switches 80a and 80b are switched by the control voltage input from the filter control terminal 61. One of the high-pass filter 79a and the low-pass filter 79b is selected.

  Thereby, the intermediate frequency filters 79 having different center frequencies can be realized. The bandwidth of the intermediate frequency filter 79 is slightly wider than the bandwidth of the high frequency signal. In addition, 80c is an input terminal of the intermediate frequency filter 79, and 80d is an output terminal. As the intermediate frequency filter 79, for example, a SAW filter can be used as the intermediate frequency filter 79c, and the high-pass filter 79a and the low-pass filter 79b can have a circuit configuration with few circuit elements. In this way, since it can be realized with a single SAW filter and a simple circuit configuration, it is small and suitable for low cost.

  The intermediate frequency filters 73, 75, and 79 are switched only when there is an interference signal.

(Embodiment 3)
FIG. 3 is a block diagram of the portable device in the third embodiment. In the third embodiment, a tuner 51b of a television receiver is used as an example of the receiving unit 51 of the first embodiment, and a transmission / reception unit 52b of a mobile phone is used as an example of the interference signal generating unit 52. Explains. Further, the third embodiment is different from the first embodiment in that the second mixer and the second filter are connected to the output of the bandpass filter (intermediate frequency filter) 58.

  Because of this difference, the second filter can further suppress the interference signal, and the frequency output from the output terminal 60 can always be constant. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and the description is simplified.

  As shown in FIG. 3, the portable device shown in Embodiment 3 includes a television receiver unit, a cellular phone unit, and a control unit 53b that controls both the cellular phone unit and the television receiver unit.

  The television receiver unit includes a tuner 51b connected to the antenna 54, a demodulation circuit unit 81 connected to the output terminal 60 of the tuner 51b, a signal processing unit 82 connected to the output of the demodulation circuit unit 81, The video display unit 83 and the audio output unit 84 are connected to the output of the signal processing unit 82.

  The mobile phone unit includes an antenna 85, a transmission / reception unit 52b connected to the antenna 85, a signal processing unit 82 connected to the transmission / reception unit 52b, and a video display unit 83 connected to the signal processing unit 82. And an audio output unit 84 and an audio / data input unit 86. The signal processing unit 82, the video display unit 83, and the audio output unit 84 are shared with the television receiver unit.

  The tuner 51b has a configuration in which an antenna 54 is connected to an input terminal 55, a high-frequency filter 87 connected to the input terminal 55, a high-frequency amplifier 88 connected to the output of the high-frequency filter 87, and the high-frequency amplifier 88. A mixer 56 having an output connected to one input and an output of the local oscillator 57 connected to the other input, and a band-pass filter as a first intermediate frequency filter connected to the output of the mixer 56 58 (variable around a center frequency of 1200 MHz, the bandwidth is 6 MHz), and a mixer in which the output of the bandpass filter 58 is connected to one input and the output of the local oscillator 89 is connected to the other input 90 and a bandpass filter 91 (center frequency) as a second intermediate frequency filter connected to the output of the mixer 90 56.5 MHz, the bandwidth is 6 MHz), an output terminal 60 to which the output of the band pass filter 91 is connected, a PLL circuit 92 which is connected to the local oscillators 57 and 89 and performs PLL control, and the PLL circuit A tuning data input terminal 62 that supplies tuning data to 92 and a filter control terminal 61 that is connected to the band pass filter 58 and controls the center frequency thereof.

  The configuration of the transmission / reception unit 52b includes an input / output terminal 93 connected to the antenna 85, an antenna switch 94 having a common terminal connected to the input / output terminal 93, and a receiver connected to one terminal of the antenna switch 94. 95, a telephone output terminal 96 connected to the output of the receiver 95 and connected to the signal processing unit 82, a telephone input terminal 97 connected to the output of the signal processing unit 82, and the telephone input A transmitter 98 connected between the terminal 97 and the other terminal of the antenna switch 94; a data terminal 64 to which the output of the control unit 53b is connected; a PLL circuit 99 connected to the data terminal 64; A PLL circuit 99 performs PLL control, and a transmitter 98 and a local oscillator 100 connected to a receiver 95 are included. Here, in this embodiment, local oscillator 100 corresponds to disturbance generator 63 in the first embodiment.

  The operation of the mobile device configured as described above will be described below. The television broadcast wave 21 is input to the antenna 54. As this television broadcast wave 21, 90 MHz to 108 MHz in the VHFL band, 170 MHz to 222 MHz in the VHFH band, and 470 MHz to 770 MHz in the UHF band are input.

  These television broadcast waves 21 are mixed with the output of the local oscillator 57 by a mixer 56 through a high frequency filter 87 and a high frequency amplifier 88. At this time, the local oscillator 57 outputs an intermediate frequency higher than the desired reception frequency.

  That is, the first intermediate frequency in the present embodiment is set to 1200 MHz. This is a preferable setting value in terms of less interference with other radio waves and miniaturization (the miniaturization of the bandpass filter 58).

  When the first intermediate frequency is 1200 MHz, the lowest oscillation frequency of the local oscillator 57 is at 90 MHz in the VHFL band, and its value is 1290 MHz. The highest frequency is at 770 MHz in the UHF band, and the value is 1970 MHz.

  The desired frequency (channel selection frequency) converted to the intermediate frequency 1200 MHz passes through the band pass filter 58. This desired frequency is mixed with the output of the local oscillator 89 by the mixer 90 to become a second intermediate frequency of 56.5 MHz, for example. Then, it passes through the band pass filter 91. That is, all the selected frequencies are output at 56.5 MHz, and the interference wave is further suppressed by the band pass filter 91.

  In the transmitting / receiving unit 52b of the mobile phone unit, the PDC 800 uses a frequency of 940 MHz to 958 MHz, and the PDC 1500 uses a frequency of 1429 MHz to 1453 MHz. In WCDMA, a frequency of 1710 MHz to 2100 MHz is used. Furthermore, these other frequencies are also being used in the future.

  The local oscillator 100 is the center of the frequency generation source of these mobile phone units. The local oscillator 100 is mounted in the same housing as the television receiver. Therefore, it can be considered that the tuner 51b is also disturbed. When the signal of the local oscillator 100 enters the first intermediate frequency of the tuner 51b, the S / N deteriorates. Further, when entering the local oscillator 57, C / N deteriorates. In any case, the TV image screen will be deteriorated.

  The control unit 53b manages the frequency of the local oscillator 100 that becomes an interference signal in this way. The control unit 53b also manages the frequency of the local oscillator 57 (the same is true because the intermediate frequency is also determined by the local oscillator 57). That is, in the control unit 53b, when a desired frequency to be selected is selected, the frequency and the intermediate frequency of the local oscillator 57 for realizing the desired frequency and the local oscillator 100 serving as an interference signal are under the same management.

  Therefore, by comparing the frequencies close to these frequencies with the frequencies output from the local oscillator 100 of the transmission / reception unit 52b, when the difference is within a predetermined range, the intermediate frequency of the tuner 51b or The oscillation frequency of the local oscillator 57 is moved. As a result, the frequency output from the local oscillator 100 provided in the transmission / reception unit 52b is not an interference signal.

  The movement of the intermediate frequency is realized by moving the frequency output from the local oscillator 57. Further, the frequency output from the local oscillator 89 is simultaneously moved by the same amount, so that the frequency output from the output terminal 60 is always constant.

  Hereinafter, this point will be described with reference to FIGS. In FIG. 4A, 101 is the bandwidth (6 MHz) of the bandpass filter 58, and 102 is its center frequency. This is also the first intermediate frequency.

  Reference numeral 103 denotes a selected desired signal, and reference numeral 104 denotes an interference signal output from the local oscillator 100. As described above, if the disturbing signal 104 is within the bandwidth 101 (in particular, the desired signal 103) of the bandpass filter 58, the desired signal 103 is disturbed. That is, the S / N performance is degraded.

  Therefore, the control unit 53b moves the center frequency 102 of the bandpass filter 58 in the direction of the arrow 105, and also moves the desired signal 103 by the same frequency in the direction of the arrow 105. That is, the oscillation frequency of the local oscillator 57 of the tuner 51b is moved.

  Then, as shown in FIG. 4B, the desired signal 103 is separated from the jamming signal 104 and is out of the bandwidth 101 of the bandpass filter 58, and the level of the jamming signal 104 is suppressed by the bandpass filter 58. Is done.

  In this case, as shown in FIG. 4A, when the frequency of the disturbing signal 104 is higher than the center frequency 102 (including the case where it is equal), both the center frequency 102 and the desired signal 103 are banded in the direction of lower frequency. Move one half or more of width 101.

  Conversely, when the frequency of the disturbing signal 104 is lower than the center frequency 102, both the center frequency 102 and the desired signal 103 are moved in the direction of higher frequency by more than half of the bandwidth 101.

  As a result, the interference signal 104 can be separated from the desired signal 103 and suppressed. 4A, the difference frequency 106 between the interference signal 104 and the center frequency 102 of the bandpass filter 58 can be increased in FIG. 4B. The horizontal axis 108 is the frequency.

  FIG. 5 shows the relationship between the interference signal 104 and the desired signal 103 at the output of the bandpass filter 91. That is, in this case, since the oscillation frequency of the local oscillator 57 is moved and the first intermediate frequency is moved, the oscillation frequency of the local oscillator 89 is also moved by the same amount, and the second intermediate frequency is changed to the original frequency. It has returned to. Therefore, the output frequency of the tuner 51b does not change and becomes 56.5 MHz.

  Further, the band pass filter 91 as the second intermediate frequency filter may be a fixed filter. Reference numeral 109 denotes a bandwidth (6 MHz) of the bandpass filter 91. The jamming signal 104 is shown to be suppressed away from the center frequency 102 of the bandpass filter 91 by a difference 111 from the center frequency.

  If a trap filter is inserted in the vicinity of both ends of the bandwidth 109 of the bandpass filter 91, the interference signal 104 can be further suppressed.

(Embodiment 4)
FIG. 6 is a block diagram of a portable device in the fourth embodiment. The fourth embodiment is different from the fourth embodiment in that a fixed bandpass filter 115 is used in the tuner 51c in this embodiment instead of the variable bandpass filter 58 used in the third embodiment. That is, if this band pass filter 115 is used, it is not necessary to control by the control part 53c.

  Therefore, the interference signal 104 is not suppressed by the band pass filter 115. Therefore, the interference signal 104 is suppressed by the band pass filter 91 next. Further, as in the third embodiment, the frequency output from the output terminal 60 is characterized by being always constant. Note that the same components as those in the third embodiment are denoted by the same reference numerals, and the description is simplified.

  As shown in FIG. 6, the portable device according to the fourth embodiment includes a television receiver unit, a mobile phone unit, and a control unit 53c that controls both the mobile phone unit and the television receiver unit.

  In FIG. 6, a bandpass filter 115 as a first intermediate frequency filter is provided between the output of the mixer 56 and one input of the mixer 90. The band pass filter 115 is a fixed filter, and the controller 53c does not need to control the center frequency of the band pass filter 115. Since the center frequency is not controlled, the bandwidth is assumed to be the bandwidth of the desired signal plus at least twice the moving width of the local oscillator 57 instead.

  Hereinafter, this state will be described with reference to FIGS. In FIG. 7A, 116 is the bandwidth of the bandpass filter 115, and 117 is its center frequency. Reference numeral 103 denotes a selected desired signal. Usually, the center frequency 117 of the bandpass filter 115 exists at the center of the desired signal 103. Here, 104 is an interference signal output from the local oscillator 100.

  Thus, when the interference signal 104 is close to the desired signal 103, the desired signal 103 is moved in the direction of the arrow 118. That is, the oscillation frequency of the local oscillator 57 of the tuner 51c is moved. Then, as shown in FIG. 7B, the desired signal 103 is separated from the interference signal 104. Thus, by moving the oscillation frequency of the local oscillator 57, the interference signal 104 is out of the band of the desired signal 103.

  In this case, as shown in FIG. 7A, when the interference signal 104 is higher in frequency than the center frequency 117 of the bandpass filter 91 (including the case where they are equal), the desired signal 103 is desired in the direction of lower frequency. Move one half or more of the bandwidth of the signal 103. Conversely, when the interference signal 104 has a frequency lower than the center frequency 117, the desired signal 103 is moved in the direction of higher frequency by more than half of the bandwidth of the desired signal 103.

  As a result, the desired signal 103 can be separated from the interference signal 104. In FIG. 7A, the difference frequency 119 between the interference signal 104 and the center frequency 117 is the difference frequency 120 in FIG. The horizontal axis 121 is the frequency.

  FIG. 8 shows the relationship between the interference signal 104 and the desired signal 103 at the output of the bandpass filter 91. That is, when there is an interference signal 104, the oscillation frequency of the local oscillator 57 is moved and the first intermediate frequency is moved. Therefore, the oscillation frequency of the local oscillator 89 is also moved by the same amount, and the second intermediate frequency is moved. The frequency is returned to the original frequency.

  Therefore, the output frequency output from the output terminal 60 of the tuner 51c does not change at 56.5 MHz. Further, the band pass filter 91 as the second intermediate frequency filter may be a fixed filter. Reference numeral 109 denotes the bandwidth of the bandpass filter 91. The jamming signal 104 is separated from the center frequency 117 of the bandpass filter 91 by a frequency 123 that is the difference from the jamming signal 104, and is outside the bandwidth 109 of the bandpass filter 91. Therefore, the interference signal 104 is suppressed by the band pass filter 91.

  Further, if a trap filter is inserted in the vicinity of both ends of the bandwidth 109 of the bandpass filter 91, the interference signal 104 can be further suppressed.

  In the third and fourth embodiments, it has been described that 56.5 MHz is output from the mixer 90, but the center frequency may be 4 MHz. In this case, since the input frequency to the A / D converter as the subsequent stage is lowered, the current consumption of the A / D converter can be reduced.

  Further, in the third and fourth embodiments, the mixer 90 may use a direct conversion mixer. In this case, the oscillation frequency of the other local oscillator 89 input to the mixer 90 is set to be substantially the same as the desired frequency supplied to one input of the mixer 90. As a result, a low-frequency demodulated signal is output from the mixer 90, and a low-pass filter is used as the band-pass filter 91.

  In the first and third embodiments, for example, the same applies to a broadcast signal using a digital system and broadcast using a part of the frequency band. For example, in Japan, there are digital audio broadcasts using 1 seg or 3 seg among digital systems using 13 seg. In this case, the bandwidth of the bandpass filter 58 may be a value that allows 0.429 MHz and 1.287 MHz, which are the bandwidths of the received signals of 1seg and 3seg, respectively.

  As described above in the first to fourth embodiments, even if the interference signal 104 exists in the vicinity of the oscillation frequency of the local oscillator 57, or the interference signal exists in the vicinity of the first intermediate frequency that is the output of the mixer 56. Even if 104 exists, the interference signal 104 can be suppressed. Therefore, S / N and C / N can be improved.

  Further, unlike the prior art, the partition plate 12 that separates the interference generator 63 and the receiving unit 51 in high frequency is not necessary, and a reduction in size and price can be realized.

  Since the portable device of the present invention can suppress the interference signal even if the interference signal directly enters the local oscillator or the intermediate frequency of the receiving unit, the interference signal generation source is provided in the same housing. It can be applied to portable devices.

Block diagram of portable device in Embodiment 1 of the present invention (A) is the block diagram by the 1st example of the filter used for the portable apparatus in Embodiment 2, (b) is the block diagram by the 2nd example, and (c) is by the 3rd example. Block diagram, (d) is a block diagram according to the fourth example. Block diagram of portable device in Embodiment 3 (A) is the first state diagram of the first intermediate frequency and the interference signal, and (b) is the second state diagram of the same. Same as above, second intermediate frequency and interference signal state diagram Block diagram of portable device according to Embodiment 4 (A) is the first state diagram of the first intermediate frequency and the interference signal, and (b) is the second state diagram of the same. Same as above, second intermediate frequency and interference signal state diagram Block diagram of a conventional portable device (A) is the frequency relationship diagram of the receiver, and (b) is the frequency relationship diagram of the interference signal.

Explanation of symbols

51 Reception Unit 52 Interference Signal Generation Unit 53 Control Unit 55 Input Terminal 56 Mixer 57 Local Oscillator 58 Bandpass Filter 60 Output Terminal 63 Interference Generator

Claims (8)

A receiving unit that receives a high-frequency signal, an interference signal generating unit that includes an interference generator that interferes with the receiving unit, and a control unit that controls both the interference signal generating unit and the receiving unit are included in the same housing. In the mounted portable device, the receiving unit receives an input terminal to which a high-frequency signal is input, and the high-frequency signal input to the input terminal is supplied to one input, and the other input has a first input A first mixer to which the output of one local oscillator is connected, a first intermediate frequency filter to which the output of the first mixer is connected, and an output of the first intermediate frequency filter are supplied. And when the oscillation frequency output from the interference generator is within or near the oscillation frequency of the first local oscillator or the intermediate frequency output from the first mixer. Is the system It said first local oscillator portable device to the outside oscillation frequency output from the disturbance generator together by moving the center frequency of the the oscillation frequency first intermediate frequency filter in parts. When the oscillation frequency of the disturbance generator is higher than the center frequency of the first intermediate frequency filter, the first intermediate frequency is moved in a direction that is lower than half the bandwidth of the high-frequency signal, 2. The portable device according to claim 1, wherein when the oscillation frequency is lower than the center frequency of the first intermediate frequency filter, the first intermediate frequency is moved in a direction higher than one half of the bandwidth of the high-frequency signal. The portable device according to claim 1, wherein the center frequency of the first intermediate frequency filter is moved by using the capacitance change of the varicap diode. The portable device according to claim 1, wherein the center frequency of the first intermediate frequency filter is moved by short-circuiting or opening a fixed inductor or a fixed capacitor with an electronic switch. In parallel with the first intermediate frequency filter, a second intermediate frequency filter having a center frequency at a position where the center frequency is one half or more of the bandwidth of the high frequency signal compared to the center frequency of the first intermediate frequency filter The portable device according to claim 1, wherein the first intermediate frequency filter and the second intermediate frequency filter are switched. A high-pass filter having a first intermediate frequency filter whose bandwidth is at least twice that of a high-frequency signal and having a cutoff frequency higher than the center frequency between the first intermediate frequency filter and the output terminal The portable device according to claim 1, wherein a parallel circuit in which a low-pass filter having a cutoff frequency at a frequency lower than the center frequency is connected in parallel is connected, and the high-pass filter and the low-pass filter are switched. A second mixer in which an output of the first intermediate frequency filter is connected to one input between an output of the first intermediate frequency filter and an output terminal, and the other input of the second mixer 2. The portable device according to claim 1, further comprising a second local oscillator connected to the first local oscillator, wherein the second oscillation frequency is also moved by an amount corresponding to the movement of the oscillation frequency of the first local oscillator. The portable device according to claim 7, wherein a filter is inserted between the output of the second mixer and the output terminal.

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