JP5093988B2 - transceiver - Google Patents

Description

  The present invention relates to a radio, and more particularly to a radio that receives, for example, frequency signals of a plurality of different bands from each other by a plurality of antennas.

An example of a conventional wireless device of this type is disclosed in Patent Document 1. According to this conventional technology, the antenna for receiving GPS information is provided at a position as far as possible from the antenna for calling. As a result, deterioration of the reception characteristics of the antenna is suppressed.
JP 2002-314313 A [H01Q1 / 24, 21/28, H04M1 / 02, 1/21, H04Q7 / 32]

    However, there is a limit to the distance that can be secured between the antennas due to the portability of the radio, and deterioration of the reception characteristics of the antenna cannot be sufficiently suppressed.

    Therefore, a main object of the present invention is to provide a portable radio device capable of improving at least one reception characteristic of a plurality of antennas.

The radio according to the invention of claim 1 is a first antenna (38) for receiving a first frequency signal transmitted using the first frequency band, and a second frequency signal transmitted using the second frequency band. A second antenna (12s) for receiving the first content, first output means (42) for outputting the first content based on the first frequency signal received by the first antenna, and a third antenna (12m) for receiving the second frequency signal , Second output means (34) for outputting the second content based on the second frequency signal received by the second antenna and the third antenna, a stop condition that the first output means is in the stop state, and the second content Discriminating means (S7, S11) for discriminating whether or not at least one of the requirement conditions that the acquisition request is in the issuing state is satisfied, and the length of the first antenna is set to the first when the discrimination result of the discriminating means is affirmative 2 frequency bands There is provided characteristic changing means (S9, S13) for changing the wavelength to 1/4 of the wavelength of the specific frequency to which it belongs and connecting one end of the first antenna to the reference potential plane.

  The first frequency signal and the second frequency signal are transmitted using the first frequency band and the second frequency band, respectively. The first frequency signal is received by the first antenna and the second frequency signal is received by the second antenna.

  The first output means outputs the first content based on the first frequency signal received by the first antenna, and the second output means outputs the second content based on the second frequency signal received by the second antenna. To do.

The determination means determines whether at least one of a predetermined condition, that is, a stop condition that the first output means is in a stop state and a request condition that the second content acquisition request is in an issue state is satisfied. When the determination result is affirmative, the characteristic changing means sets the length of the first antenna to a specific length at which interference occurs between the first antenna and the second antenna, that is, a wavelength of a specific frequency belonging to the second frequency band. And one end of the first antenna is connected to the reference potential plane.

If the first output means is stopped, it is not necessary to receive the first frequency signal by the first antenna. Further, when the second content acquisition request is issued while the first output means is in the activated state, the first output means is forcibly stopped. Accordingly, at this time, the characteristics of the first antenna may be changed.
By changing the length of the first antenna to ¼ of the wavelength of the specific frequency belonging to the second frequency band and connecting one end of the first antenna to the reference potential plane, the first antenna becomes the parasitic antenna. Cooperate with 2 antennas. As a result, the reception characteristics of the second antenna are improved.
By preparing the third antenna, the second content can be acquired satisfactorily.

The wireless device according to the invention of claim 2 is dependent on claim 1 , and the first content is a broadcast program.

  According to the present invention, the first antenna cooperates with the second antenna as a parasitic antenna by changing the length of the first antenna to a specific length and connecting one end of the first antenna to the reference potential plane. To do. As a result, the reception characteristics of the second antenna are improved.

  The above object, other objects, features and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.

  Referring to FIG. 1, the mobile communication system of this embodiment includes a plurality of BSs (Base Stations) 100, 100,... That perform radio communication with mobile communication terminal 200. The mobile communication base station 100 is connected to an MLS (Mobile Local Switch) 400, and the MLS 400 is connected to another MLS 400 via an MGS (Mobile Gateway Switch) 300. Telephone exchanges between the mobile communication terminals 200, that is, voice data communication is performed via the BS 100, the MLS 400, and the MGS 300.

  The MLS 400 is also connected to a backbone network 600 via a PPM (Packet Processing Module) 500, and a server 700 is connected to the backbone network 600. Server 700 is also connected to the Internet 800.

  When packet data is transmitted from the mobile communication terminal 200, the packet data is given to the server 700 via the BS 100, the MLS 400, the PPM 500, and the backbone network 600.

  If the transferred packet data is a mail addressed to another mobile communication terminal 200, the server 700 continues to manage this mail until a mail acquisition request is issued from the destination mobile communication terminal 200.

  If the transferred packet data is a mail acquisition request, the server 700 identifies a mail addressed to the request source from among a plurality of mails being managed, and identifies the identified mail as the backbone network 600, PPM 500, MLS 400, The data is transmitted to the requesting mobile communication terminal 200 via the BS 100.

  If the transferred packet data is a file acquisition request directed to the WEB site 900, the server 700 accesses the WEB site 900 via the Internet 800 and requests a file (for example, a movie file) acquired from the access destination. Is returned to the portable communication terminal 200. The acquired file is transferred to the requesting mobile communication terminal 200 via the backbone network 600, the PPM 500, the MLS 400, and the BS 100 as described above.

  The data communication as described above is performed using a frequency band of 832 MHz to 870 MHz.

  The mobile communication terminal 200 of this embodiment has a radio reception function for receiving FM radio broadcasts. FM radio signals broadcast by FM radio stations 1000, 1000... Using a band of 76 MHz to 108 MHz are received using this radio reception function.

  The mobile communication terminal 200 is specifically configured as shown in FIG. When a call operation for a call is performed by the key input device 30, the CPU 28 controls the signal processing circuit 16 and the radio circuit 14 to output a call signal. The call signal is transmitted to the mobile communication terminal 200 of the other party using the main antenna 12m and the sub antenna 12m. On the other hand, when the other party performs an incoming call operation, a call can be made.

  When voice is input to the microphone 26 after the call is ready, the voice is converted into an audio signal which is an analog signal by the microphone 26. The converted audio signal is amplified by the amplifier 24 and converted into audio data which is a digital signal by the AD / DA conversion circuit 18. The converted audio data is subjected to coding processing by the signal processing circuit 16 and further subjected to modulation processing by the radio circuit 14. The modulated audio data generated by the radio circuit 14 is transmitted to the other party using the main antenna 12m and the sub antenna 12s as described above.

  On the other hand, the modulated audio data sent from the other party is received by the main antenna 12m and the sub antenna 12s. The received modulated audio data is demodulated by the radio circuit 14 and decoded by the signal processing 16. The audio data decoded by the signal processing circuit 16 is converted into an audio signal which is an analog signal by the AD / DA conversion circuit 18, and the converted audio signal is output from the speaker 22 via the amplifier 20.

  When a call end operation is performed by the key input device 30 while a call is being made with the other party in this way, the CPU 28 controls the signal processing circuit 16 and the radio circuit 14 to call the other party. Send a call end signal. After transmitting the call end signal, the CPU 28 ends the call process. Also when the call end signal is received from the other party first, the CPU 28 ends the call process.

  When a mail acquisition operation or a file acquisition operation is performed by the key input device 30, the CPU 28 controls the signal processing circuit 16 and the wireless circuit 14 to issue a mail acquisition request or a file acquisition request. As a result, a mail or file is downloaded from the server 700 shown in FIG.

  The downloaded mail or file is input to the CPU 28 via the antenna 12, the radio circuit 14, and the signal processing circuit 16. The CPU 28 stores the received mail or file in the flash memory 32. The stored mail or file is output from the LCD monitor 34 in response to a mail display operation or file reproduction operation by the key input device 30.

  Note that when a mail is created and a transmission operation is performed by the operator, the mail is transmitted to the server 700 through the signal processing circuit 16, the radio circuit 14, and the antenna 12.

  When the radio reception function is turned on by the key input device 30, the CPU 28 connects the switch SW1 to the terminal T2, supplies power to the FM tuner 36, and tunes a desired channel and outputs a stereo audio signal. Command FM tuner 36. The FM radio signal received by the FM antenna 38 is input to the FM tuner 36 via the switch SW1, and subjected to signal processing such as tuning and stereo sound conversion. As a result, an audio signal of the FM radio program broadcast on the desired channel is generated. The generated program audio signal is output from the speaker 42 via the amplifier 40.

  When the radio reception function is turned off by the key input device 30, the CPU 28 connects the switch SW1 to the terminal T1 and stops supplying power to the FM tuner 36. As a result, the output of the FM radio program is stopped.

  When the above-described mail acquisition operation or file acquisition operation is performed, the switch SW1 is connected to the terminal T1 even if the radio reception function is on. The connection of the switch SW1 is returned to the terminal T2 after the mail or file download is completed. Therefore, when downloading a mail or file, the output of FM radio broadcasting is temporarily interrupted.

  3A and 3B, the LCD monitor 34 is disposed slightly above the front of the cabinet C1, and a part of the operation key group 30a forming the key input device 30 is the same as that of the cabinet C1. It is arranged slightly in front. Another part of the operation key group 30b forming the key input device 30 is arranged in front of the cabinet C2. The main antenna 12m is embedded in the vicinity of the upper surface of the cabinet C2, and the sub antenna 12s and the FM antenna 38 are embedded in proximity to the lower surface of the cabinet C2. The cabinets C1 and C2 are fitted to each other, and the operation key group 30b is exposed by sliding the cabinet C2 downward.

  Returning to FIG. 2, when the switch SW1 is connected to the terminal T2, the length of the FM antenna 38 is λ / 4 of 100 MHz. That is, the antenna length is ¼ of the wavelength of the specific frequency belonging to the frequency band of FM radio broadcasting. As a result, FM radio broadcasting can be received satisfactorily.

  On the other hand, when the switch SW1 is connected to the terminal T1, one end of the FM antenna 38 is connected to the ground, and the length of the FM antenna 38 is λ / 4 of 800 MHz. That is, one end of the FM antenna 38 is connected to the reference potential plane, and the antenna length is ¼ of the wavelength of the specific frequency belonging to the frequency band for data communication.

  As shown in FIGS. 3A and 3B, the FM antenna 38 is close to the sub antenna 12s. For this reason, when the switch SW1 is connected to the terminal T1, mutual interference occurs between the FM antenna 38 and the sub-antenna 12s, and the FM antenna 38 cooperates with the sub-antenna 12s as a parasitic antenna. Thereby, the gain of the sub-antenna 12s is improved.

  The impedance characteristics of the sub-antenna 12s draw a waveform shown in FIG. 5A when the cabinet C2 is in a non-sliding state, and draw a waveform shown in FIG. 5B when the cabinet C2 is in a sliding state. 5A and 5B, VSWR (Voltage Standing Wave Ratio) belongs to the range of “2” to “4” in the frequency band of 832 MHz to 870 MHz. From this, it can be seen that the sub-antenna 12s resonates in this frequency band.

  The impedance characteristic of the FM antenna 38 when the switch SW1 is connected to the terminal T1 draws the waveform shown in FIG. 6A when the cabinet C2 is in a non-sliding state, and FIG. 6 (when the cabinet C2 is in a sliding state). Draw the waveform shown in B). In both FIG. 6A and FIG. 6B, VSWR (Voltage Standing Wave Ratio) is distributed around “3” in the frequency band of 832 MHz to 870 MHz. From this, it can be seen that the FM antenna 38 cooperates with the sub antenna 12s as a parasitic antenna.

  The CPU 28 implements the above-described operation by executing a plurality of tasks including the SW control task shown in FIG. 4 in parallel. Note that control programs corresponding to these tasks are stored in the flash memory 32.

  In step S1 shown in FIG. 4, the switch SW1 is connected to the terminal T1. The FM antenna 38 functions as a parasitic antenna that cooperates with the sub-antenna 12s. In step S3, it is determined whether or not the radio reception function is turned on. If YES, the switch SW1 is connected to the terminal T2 in step S5. As a result, the FM radio signal is received, and the sound of the desired FM broadcast program is output from the speaker 42.

  In step S7, it is determined whether or not an operation for turning off the radio reception function has been performed. In step S11, it is determined whether or not a mail acquisition operation or a file acquisition operation has been performed. If “YES” in the step S7, the switch SW1 is connected to the terminal T1 in a step S9, and then the process returns to the step S3.

  On the other hand, if “YES” in the step S11, the switch SW1 is connected to the terminal T1 in a step S13. In step S15, it is determined whether or not downloading of the mail or file is completed. If YES, the switch SW1 is connected to the terminal T2 in step S17, and the process returns to step S7.

  As can be seen from the above description, packet data is transmitted using a frequency band of 832 MHz to 870 MHz, and FM radio broadcast is transmitted using a frequency band of 76 MHz to 108 MHz. The packet data is received by the main antenna 12m and the sub antenna 12s, and the FM radio broadcast is received by the FM antenna 38.

  The LCD 34 outputs content (mail or file) based on the packet data, and the speaker 42 outputs FM radio broadcast program audio.

  The CPU 28 determines whether or not the FM reception function is turned on (S7), and further determines whether or not a mail acquisition operation or a file acquisition operation is performed (S11). If either one of the determination results is affirmative, the CPU 28 changes the length of the FM antenna 38 to a specific length at which interference occurs between the sub antenna 12s and the FM antenna 38, and one of the FM antennas 38. Connect the end to the reference potential plane. The FM antenna 38 cooperates with the sub antenna 12s as a parasitic antenna. As a result, the reception characteristics of the sub antenna 12s are improved.

  In this embodiment, the sub antenna is arranged in the vicinity of the FM antenna, but the main antenna may be arranged in the vicinity of the FM antenna. In this case, it is necessary to control the connection of the main antenna.

It is an illustration figure which shows the structure of one Example of this invention. It is a block diagram which shows an example of a structure of the communication terminal applied to the FIG. 1 Example. (A) is a front view which shows the external appearance of FIG. 2 Example in a sliding state, (B) is a rear view which shows the external appearance of FIG. 2 Example in a sliding state. It is a flowchart which shows a part of operation | movement of CPU applied to the FIG. 2 Example. (A) is a graph which shows the impedance characteristic of the subantenna in a non-sliding state, (B) is a graph which shows the impedance characteristic of the subantenna in a sliding state. (A) is a graph which shows the impedance characteristic of the FM antenna in a non-sliding state, (B) is a graph which shows the receiving characteristic of the FM antenna in a sliding state.

Explanation of symbols

12 m ... main antenna 12 s ... sub antenna 14 ... radio circuit 16 ... signal processing circuit 28 ... CPU
32 ... Flash memory 30 ... Key input device 34 ... LCD
38 ... FM antenna 200 ... Mobile communication terminal

Claims (2)

A first antenna (38) for receiving a first frequency signal transmitted using the first frequency band;
A second antenna (12s) for receiving a second frequency signal transmitted using the second frequency band;
A third antenna (12m) for receiving the second frequency signal;
First output means (42) for outputting first content based on a first frequency signal received by the first antenna;
Second output means (34) for outputting second content based on a second frequency signal received by the second antenna and the third antenna ;
Determination means (S7, S11) for determining whether or not at least one of a stop condition that the first output means is in a stop state and a request condition that the acquisition request for the second content is in an issue state is satisfied; and When the discrimination result of the discrimination means is affirmative, the length of the first antenna is changed to ¼ of the wavelength of the specific frequency belonging to the second frequency band, and one end of the first antenna is changed to a reference potential plane. A wireless device comprising characteristic changing means (S9, S13) connected to the.   The wireless device according to claim 1, wherein the first content is a broadcast program.

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