JP4375099B2 - High frequency signal receiver - Google Patents

Description

  The present invention relates to a high-frequency signal receiving apparatus that simultaneously receives two high-frequency signals.

  FIG. 5 is a block diagram of a conventional high-frequency signal receiver. In FIG. 5, reference numeral 1 denotes an input terminal to which two high frequency signals are input. A distributor 2 is connected to the input terminal 1, and a tuner 3 that receives a frequency of 57 MHz to 861 MHz is connected to one output of the distributor 2. The output of the tuner 3 is connected to the output terminal 5 via the demodulator 4.

  A tuner 6 that receives a frequency of 70 MHz to 130 MHz is connected to the other output of the distributor 2, and the output of the tuner 6 is connected to an output terminal 8 via a demodulator 7. These tuners 3 and 6 are mounted in different cases in order to eliminate mutual influences.

As prior art document information related to the invention of this application, for example, Patent Document 1 is known.
JP-A-6-334543

  However, in such a conventional high-frequency signal receiving apparatus, the tuner 3 and the tuner 6 are mounted in different cases, so that there is a problem that the overall size increases. Therefore, it is conceivable that the two tuners 3 and 6 are simply mounted in one case. However, since these two tuners 3 and 6 are operating at the same time, when these two tuners 3 and 6 are simply mounted in one case, The tuners 3 and 6 are physically close to each other and have a problem in that they interfere with each other.

  For example, if the intermediate frequency of the tuner 6 is 44 MHz, the image frequency is 158 MHz to 218 MHz, and the reception frequency 70 MHz to 130 MHz and the image frequency 158 to 218 MHz of the tuner 6 are the reception frequencies of the tuner 3 ( 57 MHz to 861 MHz) in the first high frequency signal. Therefore, it can be considered that the first high-frequency signal directly interferes with the tuner 6.

  If the intermediate frequency of the tuner 3 is 44 MHz, the oscillation frequency of the local oscillator is 101 MHz to 905 MHz, and the oscillation frequency of the local oscillator of the tuner 3 is also the interference frequency of the tuner 6 as it is. Furthermore, when the frequency of the sum or difference of the integral multiple frequency of the local oscillator of the tuner 6 and the interference frequency becomes equal to the intermediate frequency of the tuner 6, this frequency also becomes the interference frequency.

  Accordingly, an object of the present invention is to provide a high-frequency signal receiving apparatus that does not interfere with each other even if two tuners operating simultaneously are mounted in one case.

In order to achieve this object, the high-frequency signal receiving device of the present invention is inserted into a single rectangular parallelepiped metal case, and the case has a printed circuit board mounted thereon and a metal partition plate. has a forward portion and a rear portion which are separated, on one longitudinal side of the front portion of the casing equipped with the input terminal, said implement at least the high frequency part of the first tuner to the front portion of said casing And at least a second tuner is mounted on the rear portion of the case, a first local oscillator is mounted in the vicinity of the upper lateral surface of the front portion of the case, and the second output from the other output of the distributor. the wiring portion to the input of the tuner is provided on a surface of the front portion of the lower lateral sides and along a near printed board of the case, the ground pattern on the back surface of the printed circuit board opposite to the wiring portion Only, the power terminal provided with the wiring portion enclosing the lower side surface of the front portion of the casing, inserting a filter which passes the data signal to one input of the second mixer.
Thereby, the intended purpose can be achieved.

As described above, the high-frequency signal receiving device of the present invention is inserted into a single rectangular parallelepiped metal case, and the case has a printed board mounted thereon and is separated by a metal partition plate. has parts and rear part, on one longitudinal side of the front portion of the casing equipped with the input terminal, to said front portion of said casing is mounted a high-frequency portion of the at least a first tuner, said case At least a second tuner is mounted on the rear part of the case, a first local oscillator is mounted in the vicinity of the upper lateral surface of the front part of the case, and the second tuner input is input from the other output of the distributor. wiring part to is along a lower lateral side near the front portion of the casing provided on a surface of the printed circuit board, a ground pattern provided on the back surface of the printed circuit board opposite to the wiring portion, of the case The power supply terminal is provided to surround the wire part to the lower side surface of the serial front portion, it inserts a filter that passes the data signal to one input of the second mixer.

  That is, by configuring in this way, the first tuner and the second tuner are mounted in one case, so that downsizing can be realized. Even if two tuners are operated simultaneously, the first local oscillator constituting the first tuner is mounted in the vicinity of the upper surface of the front part of the case, and from the other output of the distributor constituting the second tuner. The wiring to the second mixer is along the vicinity of the lower surface of the front portion of the case. Therefore, the physical distance becomes large and does not disturb each other.

  Further, since the first tuner is mounted on the front portion of the case and the second tuner is mounted on the rear portion, the case has a horizontally long shape, and the height dimension can be reduced.

(Embodiment 1)
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of the high-frequency signal receiving apparatus according to the first embodiment. In FIG. 1, reference numeral 10 denotes an input terminal. A first high frequency signal of 57 MHz to 861 MHz and a second high frequency signal of 70 MHz to 130 MHz are input to the input terminal 10.

  Reference numeral 11 denotes a distributor connected to the input terminal 10, and one output of the distributor 11 is connected to an AGC (automatic gain control) circuit 12. The output of the AGC circuit 12 is connected to one input of the mixer 14 via the amplifier 13. The output of the local oscillator 15 is connected to the other input of the mixer 14, and a PLL circuit 16 is connected to the local oscillator 15 in a loop.

  The output of the mixer 14 is connected to a SAW (surface acoustic wave) filter 17 having an intermediate frequency of 44 MHz. The output of the SAW filter 17 is connected to an output terminal 52 via an IF (intermediate frequency) AGC amplifier 18. It is connected. The output terminal 52 is connected to the demodulator 19. The output of the demodulator 19 is connected to the demodulator output terminal 20.

  The other output of the distributor 11 is connected to an amplifier 22 via a BPF (band pass filter) 21 having a pass band of 70 MHz to 130 MHz. The output of the amplifier 22 is connected to one input of the mixer 24 via a BPF 23 having a pass band of 70 MHz to 130 MHz. The other input of the mixer 24 is connected to the output of a local oscillator 25 (not shown) built in the demodulator 19.

  The output of the mixer 24 is connected to the output terminal 54 via the SAW filter 26 having an intermediate frequency of 44 MHz. The output terminal 54 is connected to the demodulator 19. Reference numeral 27 denotes a control signal input terminal to which a control signal for controlling the demodulator 19 is input. Reference numeral 28 denotes a data clock terminal from which a clock signal and a data signal are output. The demodulator 19 sends channel selection data to the PLL circuit 16.

  Here, the first tuner 51 includes the AGC circuit 12 to the IFAGC amplifier 18. The IFAGC amplifier 18 and the demodulator 19 are connected via the output terminal 52 of the first tuner 51 within the same substrate. Further, the AGC circuit 12 to the mixer 14 of the first tuner 51 are used as a high frequency unit.

  Similarly, the amplifier 22 to the SAW filter 26 are used as the second tuner 53. The SAW filter 26 and the demodulator 19 are connected to each other on the same substrate via the output terminal 54 of the second tuner 53.

  The operation of the high-frequency signal receiving apparatus configured as described above will be described below. A digital TV (television) signal of 57 MHz to 861 MHz is input to the input terminal. This signal is input to the first tuner 51. That is, it is amplified to an appropriate level via the AGC circuit 12 and the amplifier 13. This signal is mixed with the output of the local oscillator 15 by the mixer 14 and selected. The output of the mixer 14 is passed through the SAW filter 17 by 44 MHz to an intermediate frequency of 44 MHz. The intermediate frequency is amplified by the IFAGC amplifier 18 and then input to the demodulator 19. The digital TV signal input to the demodulator 19 is output to the demodulator output terminal 20.

  On the other hand, the data signal of 70 MHz to 130 MHz input to the input terminal 10 is input to the second tuner 53 via the BPF 21. That is, it is input to one input of the mixer 24 via the amplifier 22 and the BPF 23. In the mixer 24, the signal is mixed with the signal of the local oscillator 25 mounted in the demodulator 19, and is selected from the output terminal of the mixer 24. This output signal passes through the 44 MHz SAW filter 26 and is then input to the demodulator 19. The demodulator 19 demodulates the data signal. Then, the data is output from the data clock terminal 28. Here, the first tuner 51 and the second tuner 53 in the present embodiment are operating simultaneously.

  As shown in FIG. 2, the high-frequency signal receiving device is mounted on a metal case 31 having a length of 40 mm, a width of 85 mm, and a width of 12 mm. The input terminal 10 is mounted on one vertical side surface 32 of the case 31, and the local oscillator 15 is disposed near the upper horizontal side surface of the case 31.

  Reference numeral 33 denotes a metal partition plate that separates the case 31 into a front part 34 and a rear part 35. The front part 34 is mainly mixed from the AGC circuit 12 that forms the high-frequency part of the first tuner 51. The device 14 and the local oscillator 15 are mounted. Further, the demodulator 19 and the amplifier 22 to the SAW filter 26 that mainly form the second tuner are mounted on the rear portion 35.

  Further, a power supply terminal 36 of 5V, 30V, etc. is provided on the lower lateral surface of the front portion 34 of the case 31, and the demodulator output terminal 20, the data clock terminal are disposed on the lower lateral surface of the rear portion 35. Terminals 37 such as 28 are provided.

  A distributor 11 is disposed in the front portion 34 in the vicinity of the input terminal 10, and a BPF 21 is disposed in the vicinity of the distributor 11. Then, from the output of the BPF 21, the wiring 39 formed in a pattern is wired along the lower lateral surface and led to the rear portion 35. Then, it is guided to the rear portion 35 and input to the amplifier 22, and the output of the amplifier 22 is input to the BPF 23.

  As described above, in the present embodiment, since the first tuner 51 and the second tuner 53 are mounted in one case 31, compared to the conventional case using two cases. Downsizing.

  In addition, although the first tuner 51 and the second tuner 53 are operating at the same time, the high-frequency signal receiving apparatus according to the present embodiment has the above-described configuration, so that mutual interference is extremely high. It is running low. That is, since the local oscillator 15 and the wiring 39 are physically separated from each other, the output of the local oscillator 15 has little influence on the wiring 39 that is the input of the second tuner 53. Further, since the local oscillator 15 is separated from the power supply terminal 36, the oscillation frequency output from the local oscillator 15 is less likely to leak from the power supply terminal 36. In other words, it is possible to prevent noise that interferes with other devices from being supplied via the power supply terminal 36.

  An input signal to the second tuner 53 passes through the front part 34 and is transmitted to the rear part 35 via the wiring 39. The second and third terminals 53 are respectively connected to the entrance and exit of the wiring 39. BPFs 21 and 23 through which only high-frequency signals (70 MHz to 130 MHz) pass are inserted.

  Therefore, the signal of the local oscillator 15 and the like generated in the front portion 34 is not emitted from the input terminal 10 through the wiring 39 and does not disturb other devices. Further, an interference signal such as the local oscillator 15 generated in the front portion 34 is not input to the second tuner 53. That is, the intrusion of frequencies other than the frequency band (70 MHz to 130 MHz) of the second high frequency signal is prevented.

  Furthermore, since at least the high frequency part of the first tuner 51 and the second tuner 53 are separated in high frequency by the partition plate 33, the second tuner 53 does not interfere with the first tuner 51. . Conversely, the first tuner 51 does not interfere with the second tuner 53. In this way, mutual interference is reduced by the effect of the partition plate 33.

  As shown in FIG. 3, the wiring 39 is provided on the surface of the printed circuit board 40 mounted in the case 31, and a ground 41 is provided on the back surface of the printed circuit board 40 facing the wiring 39. Yes. A low impedance power supply terminal 36 is provided so as to surround the wiring 39. Accordingly, the wiring 39 is surrounded by a low impedance, and an interference signal in the front portion 34 is prevented from entering the wiring 39.

  The power supply terminal 36 is a power supply of 5V, 30V, etc., and its impedance is low. Further, a certain distance is required between the mounting portion 36a of the power supply terminal 36 to the printed board 40 and the end 40a of the printed board 40, and this distance is usually a dead space. However, in the present embodiment, since the wiring 39 is provided by utilizing the space that becomes the dead space, the mounting density can be increased as a result, which contributes to downsizing.

  Further, the output of the first tuner 51 and the output of the second tuner 53 are connected to the demodulator 19 via output terminals 52 and 54, respectively, and this demodulator 19 is also mounted in the same case 31. Therefore, the overall size of the high-frequency signal receiving device can be reduced.

  In this high-frequency signal receiving apparatus, the case 31 in FIG. 2 is formed of a metal frame that opens at the front and the rear, and a lid that is mounted so as to close the opening of the frame. That is, the vertical and horizontal directions forming the frame are all covered with metal. The opening of the front portion 34 of the frame is covered with a metal lid on both the front side and the rear side. However, the rear part 35 of the frame is open and is not covered with a lid. Therefore, in the rear part 35, since there is no cover, the heat dissipation performance is improved. In addition, since there is no lid, it is possible to achieve light weight, small size, and low price.

  FIG. 4 is a diagram showing the frequency relationship between the first tuner 51 and the second tuner 53. In FIG. 4, 45 is a 1st high frequency signal, The frequency band is 57 MHz-861 MHz. If the intermediate frequency of the first tuner 51 is 44 MHz, the oscillation frequency 46 of the local oscillator 15 is 101 MHz to 905 MHz.

  On the other hand, the second high frequency signal 47 input to the second tuner 53 is 70 MHz to 130 MHz. If the intermediate frequency of the second tuner 53 is 44 MHz, the image frequency 48 is 158 MHz to 218 MHz. Therefore, if there is another signal during this period (second high frequency signal 47 and image frequency 48), it becomes an interference signal for the second tuner 53. In the present embodiment, both the first high frequency signal 45 input to the first tuner 51 and the oscillation frequency 46 of the local oscillator 15 are interference signals for the second tuner 53.

  The oscillation frequency of the local oscillator 25 of the second tuner 53 is 114 MHz to 174 MHz. When the local oscillator 25 outputs a harmonic, the harmonic frequency and the input frequency are If the sum or difference of the signals is 44 MHz, they all become interference signals 49 for the second tuner 53. As this interference signal 49, a signal of 184 MHz or more may become an interference signal. Note that the horizontal axis 44 represents frequency and is logarithmic.

  Thus, since the two tuners 51 and 53 operate simultaneously, mutual interference can be considered. However, with the above-described configuration, these interferences can be minimized. In particular, BPF 21 and 23 work effectively with respect to these interference frequencies.

  The high-frequency signal receiving apparatus according to the present invention is useful as a high-frequency signal receiving apparatus that receives a digital TV signal and a data signal at the same time because it hardly receives an interference signal even when two tuners operate simultaneously.

The block diagram of the high frequency signal receiver in one embodiment of the present invention Same as above, top view Same as above, sectional view Same frequency diagram Block diagram of a conventional high-frequency signal receiver

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Input terminal 11 Divider 14 Mixer 15 Local oscillator 20 Demodulator output terminal 24 Mixer 31 Case 32 One vertical side 34 Front part 35 Rear part 39 Wiring 51 1st tuner 52 Output terminal 53 2nd tuner 54 Output Terminal

Claims (1)

A distributor to which a television signal and a data signal are input via an input terminal, a first tuner to which one output of the distributor is connected, and a second to be connected to the other output of the distributor A high-frequency signal receiving apparatus equipped with a tuner, wherein the first tuner is configured such that the television signal is supplied to one input, and the output of the first local oscillator is connected to the other input. And a first output terminal to which the output of the first mixer is supplied. The second tuner is supplied with the data signal at one input and at the other input. Comprises a second mixer to which the output of the second local oscillator is connected, and a second output terminal to which the output of the second mixer is supplied, and the high-frequency signal receiving device has one rectangular parallelepiped is inserted shape in a metal case in which the said cable Has a front portion and a rear portion separated by a metal partitioning plate which has a printed circuit board mounted, the input terminals mounted on one longitudinal side of the front portion of the case, said case on the front section mounting at least a high frequency portion of said first tuner, to the rear portion of the case mounting at least the second tuner, the upper lateral side near the front portion of the case The first local oscillator is mounted, and the wiring portion from the other output of the distributor to the input of the second tuner is on the surface of the printed circuit board along the vicinity of the lower lateral surface of the front portion of the case. A ground pattern is provided on the back surface of the printed circuit board facing the wiring portion, a power supply terminal is provided on the lower side surface of the front portion of the case so as to surround the wiring portion, and one of the second mixers is provided. of Insert the filter which passes data signals to the force, the television signal and the first high-frequency signal receiving apparatus for suppressing interference in the second tuner by the harmonic signal of the first oscillation signal of the tuner.

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