JP4330902B2 - Communication terminal - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a portable terminal such as a cellular phone, PHS, and PDA, and more specifically, a portable device that reduces the amount of absorption of radio waves radiated from a portable terminal into a human body, in particular, the amount of absorption into a user's head. It relates to the terminal.
[0002]
[Prior art]
When a strong radio wave hits the human body, that part absorbs the radio wave energy and the temperature rises. The biological action caused by this temperature rise is called thermal action. As a limitation to this, guidelines (guidelines) that set standards for the whole body average and the specific absorption rate (SAR) of local radio waves are shown by public institutions in Japan and overseas.
[0003]
Here, the SAR is the amount of energy absorbed per unit time by the tissue of a unit mass when the living body is exposed to an electromagnetic field, and the local SAR is averaged over an arbitrary tissue 10 g of the local body in 6 minutes. It is a thing. Based on the radio wave protection guideline, the local SAR tolerance (2 W / kg) based on the radio wave protection guideline must be met for mobile phone terminals used near the human head in accordance with the Ordinance of the Ministry of Internal Affairs and Communications (Radio Equipment Regulations) Is required. This tolerance is consistent with the private sector standards of the Radio Industries Association and international guidelines established by the International Commission on Non-Ionizing Radiation Protection (ICNIRP).
[0004]
In addition, many electronic devices have electronic circuits built therein, which may be affected by relatively weak radio waves. Measures have been taken for the electronic device itself, but the opportunity to come close to the electronic device is increasing due to the spread of mobile phones. In particular, medical electronic devices and cardiac pacemakers in hospitals may malfunction due to reception of radio waves from a mobile phone.
[0005]
As described above, in recent years, with the spread of mobile terminals, the amount (SAR) of radio waves radiated from the terminals is absorbed by the human head. For example, a technique related to a portable terminal having an antenna system capable of improving SAR and ensuring good communication characteristics has been proposed (see, for example, Patent Document 1). In this technique, two dipole antennas are provided on a printed circuit board (PCB) of a mobile phone body. The signal power transmitted from the transmission / reception circuit unit is distributed by the power distributor / combiner, the transmission mode is unbalanced-balanced by the balun via the phase shifter, and supplied to the two dipole antennas via the feed terminals. . By appropriately adjusting the phase of each antenna current between 0 to 180 degrees by the phase shifter, SAR can be reduced by canceling and reducing the electromagnetic fields near the human head. Further, by adjusting the power distribution ratio by the power distributor / combiner and the phase of the phase shifter, the radiation pattern and the SAR can be optimized to improve the communication performance.
[0006]
[Patent Document 1]
JP 2002-152115 A (first page)
[0007]
[Problems to be solved by the invention]
By the way, in wireless communication, a transmission path may become a multiple transmission path (multipath) due to reflected waves from various obstacles. In addition, frequency selective fading may occur due to the difference in the propagation delays, which distorts the frequency characteristics in the transmission band. This results in intersymbol interference in which adjacent signals (symbols) interfere with each other on the time axis, resulting in deterioration of communication quality. As a countermeasure against such frequency-selective fading, a multicarrier transmission method has attracted attention.
[0008]
The multi-carrier transmission method transmits information by dividing it into a plurality of low-rate carriers (subcarriers). In particular, the one selected so that the carriers are orthogonal to each other is called an orthogonal multicarrier modulation scheme, and there is orthogonal frequency division multiplexing (OFDM). This multicarrier transmission system has the following advantages.
[0009]
First, when the multicarrier transmission method is used, since the transmission is divided into a large number of carriers, the bandwidth per wave is narrow, and the influence of multipath can be handled relatively easily.
[0010]
In addition, since the signal is transmitted by being divided into a large number of digital modulation waves, the symbol period can be made longer than that in the case of transmitting with a single carrier wave. Therefore, even if multipath is added, deterioration of transmission characteristics due to intersymbol interference can be suppressed. In particular, increasing the number of carriers is more effective because the symbol period per carrier becomes longer and the bandwidth becomes narrower. However, even in such a multicarrier transmission having many advantages, there is a possibility that a problem due to the influence of electromagnetic field concentration occurs.
[0011]
An object of the present invention is to provide a communication terminal that supports multi-carrier transmission and can suppress electric field concentration.
[0012]
[Means for Solving the Problems]
In order to solve the above problem, the invention according to claim 1 is a communication terminal that transmits an input signal by multicarrier transmission, and the communication terminal supports the input signal to an adjacent subcarrier. Conversion means that divides the signal into a plurality of signal groups, a transmission means that performs modulation independently for each signal group generated by the conversion means, and an antenna that is independently connected for each transmission means Is the gist.
[0013]
According to a second aspect of the present invention, in the communication terminal according to the first aspect, the conversion means performs serial-parallel conversion to convert a serial string signal into a parallel string signal, and divides the parallel string signal, The gist is to generate a plurality of signal groups.
[0014]
The gist of a third aspect of the present invention is the communication terminal according to the first or second aspect, wherein the subcarrier frequencies are orthogonal to each other.
The gist of a fourth aspect of the present invention is the communication terminal according to any one of the first to third aspects, wherein the transmission means performs an inverse Fourier transform for each signal group.
[0015]
A fifth aspect of the present invention is the communication terminal according to any one of the first to fourth aspects, wherein the transmitting means performs frequency conversion using a different intermediate frequency for each signal group. To do.
[0016]
The invention according to claim 6 is the communication terminal according to any one of claims 1 to 5, wherein the transmission means includes amplification means independent for each signal group corresponding to a subcarrier. This is the gist.
[0017]
A seventh aspect of the present invention is the communication terminal according to any one of the first to sixth aspects, wherein a signal group to be input from the conversion unit to the transmission unit is determined based on an arrangement for each antenna. The gist is that the signal group corresponds to the number of subcarriers.
(Function)
According to the first aspect of the present invention, the communication terminal has the converting means for dividing the input signal into a plurality of signal groups corresponding to adjacent subcarriers. Furthermore, it has the transmission means which modulates independently for every signal group produced | generated by the said conversion means, and the antenna connected independently for every said transmission means. For this reason, radio waves are emitted from a plurality of antennas corresponding to the subcarriers. Therefore, the electromagnetic field level near the antenna can be reduced, and the amount of absorption due to electromagnetic field concentration can be suppressed.
[0018]
According to a second aspect of the present invention, the conversion means performs serial / parallel conversion for converting a serial string signal into a parallel string signal, and divides the parallel string signal to generate a plurality of signal groups. For this reason, an input signal can be divided | segmented using a serial-parallel conversion.
[0019]
According to a third aspect of the present invention, the subcarrier frequencies are orthogonal to each other. For this reason, multicarrier transmission (OFDM transmission) by orthogonal frequency division multiplexing can be realized. Accordingly, it is possible to perform communication resistant to fading by making use of the characteristics of OFDM transmission.
[0020]
According to a fourth aspect of the present invention, the transmission unit performs an inverse Fourier transform for each signal group. For this reason, it is possible to perform inverse Fourier transform for each transmission means to convert information on the frequency axis into information on the time axis.
[0021]
According to a fifth aspect of the present invention, the transmission means performs frequency conversion using an intermediate frequency that is different for each signal group. For this reason, since a frequency differs for every antenna, disorder of an antenna pattern can be suppressed.
[0022]
According to a sixth aspect of the present invention, the transmitting means has an amplifying means for each signal group corresponding to a subcarrier. For this reason, the band which amplifies becomes narrow and it can amplify efficiently. That is, communication can be performed using a small output amplification means.
[0023]
According to the seventh aspect of the present invention, the signal group input from the conversion unit to the transmission unit is a signal group corresponding to the number of subcarriers determined based on the arrangement for each antenna. For this reason, transmission output can be changed according to a human body, an environment, etc.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of multicarrier transmission embodying the present invention will be described below with reference to FIGS. In the present embodiment, description will be made using OFDM transmission as multicarrier transmission. A mobile phone 10 as a communication terminal is used for OFDM transmission. In the present embodiment, 1 GHz is used as the carrier frequency (f0), and 100 MHz OFDM transmission is assumed as the frequency band.
[0025]
A schematic configuration of the entire block of the cellular phone 10 is shown in FIG. The mobile phone 10 includes an input circuit 11 that converts sound into a signal via a microphone or the like. Furthermore, the cellular phone 10 includes a serial / parallel converter 12 as a conversion unit, a first transmission block 20a as a transmission unit, and a second transmission block 20b. A first antenna 50a and a second antenna 50b as antennas are connected to the first transmission block 20a and the second transmission block 20b, respectively.
[0026]
First, a signal input via the input circuit 11 is converted from a serial string signal to a parallel string signal by a serial / parallel converter 12. It should be noted that error conversion and interleaving processing for randomizing the signal may be performed when the serial string signal is converted into the parallel string signal. Specifically, in order to prevent data loss, a data stream including an error correction function is distributed so that the error correction function works effectively at the time of decoding on the receiving side even if there is a burst error. In this case, a deinterleaving process is performed on the receiving side in order to restore the interleaved signal.
[0027]
Since the signal output from the serial / parallel converter 12 is divided into a plurality of bands and transmitted, the signal is input to a transmission block corresponding to each band. That is, it is divided into a plurality of signal groups corresponding to subcarriers. In this embodiment, it is divided into two bands. For this reason, the divided signals are input to the first transmission block 20a and the second transmission block 20b, respectively. For example, when the parallel string output from the serial / parallel converter 12 is 700 channels, a signal group of 350 channels is equally input to each transmission block (20a, 20b).
[0028]
The input signal is subjected to modulation processing described later in each transmission block (20a, 20b). The output from the first transmission block 20a is transmitted as an RF signal from the first antenna 50a, and the output from the second transmission block 20b is transmitted as an RF signal from the second antenna 50b.
[0029]
In the present embodiment, the first antenna 50a is a transmission / reception shared antenna, and the second antenna 50b is used as a transmission-dedicated antenna. For this reason, the RF signal received by the first antenna 50a is demodulated by the receiving block 100 described later. Then, it is converted into sound by an output circuit 15 having a speaker or the like and output.
[0030]
Hereinafter, processing in a transmission block (FIG. 2) used when transmitting an RF signal to the outside and a reception block (FIG. 3) used when receiving an RF signal from the outside will be described separately.
[0031]
(Send block)
First, the processing of each transmission block (20a, 20b) will be described with reference to FIG. Since the processing in the first transmission block 20a and the processing in the second transmission block 20b are basically the same, here, the processing in the first transmission block 20a will be mainly described.
[0032]
First, the signal output from the serial / parallel converter 12 is modulated by the modulator 21a of the first transmission block 20a. Here, BPSK (Binary Phase Shift Keying), QPSK (Quadrature Phase Shift Keying), QAM (Quadrature Amplitude Modulation), or the like is used as a digital modulation method. In this embodiment, multi-value quadrature amplitude modulation (256QAM) capable of transmitting 6-bit (256 values) information with one symbol is used. This multilevel quadrature amplitude modulation has a larger amount of information that can be transmitted per symbol than other digital modulation schemes, and can realize high-speed digital communication in a narrow band.
[0033]
The output of each modulator 21a is input to the IFFT circuit 23a. The IFFT circuit 23a synthesizes the signals of the respective channels arranged on the frequency axis by inverse fast Fourier transform, and converts them into a time waveform having an effective symbol length. Further, a guard interval for reducing the influence of multipath interference distortion is added, and an I component (Inphase component) and a Q component (Quadrature component) are output. In the present embodiment, a redundant time for the intersymbol interference region can be provided by adding a guard interval.
[0034]
The I component output from the IFFT circuit 23a is input to the D / A converter 25a, and the Q component is input to the D / A converter 26a to be converted into an analog signal.
Next, quadrature modulation is performed on each component. In the first transmission block 20a, modulation is performed using the first intermediate frequency (f1). In the present embodiment, 975 MHz is used as the first intermediate frequency (f1). In the frequency mixer 33a, it is mixed with the sine wave from the oscillator 30a having the first intermediate frequency (f1). On the other hand, the Q component is mixed with the cosine wave generated by the π / 2 phase shifter 31a with respect to the sine wave from the oscillator 30a having the first intermediate frequency (f1) in the frequency mixer 34a.
[0035]
Next, the output of the frequency mixer (33a, 34a) converted to the intermediate frequency is synthesized by the synthesizer 35a. The output of the synthesizer 35a is amplified by an amplifier 36a as an amplifying unit, converted into a carrier frequency by a synthesizer 37a, and output as an RF signal.
[0036]
On the other hand, the remaining signal output from the serial / parallel converter 12 and subjected to band division is also modulated by the modulator 21b of the second transmission block 20b. Then, the output of each modulator 21b is input to the IFFT circuit 23b. This IFFT circuit 23b also converts it into a time waveform having an effective symbol length by inverse fast Fourier transform. Then, the IFFT circuit 23b outputs an I component and a Q component. The I component is input to the D / A converter 25b, and the Q component is input to the D / A converter 26b to be converted into an analog signal.
[0037]
Next, quadrature modulation is performed on each component. In the second transmission block 20b, modulation is performed using the second intermediate frequency (f2). In the present embodiment, 1025 MHz is used as the second intermediate frequency (f2). In the frequency mixer 33b, the second intermediate frequency (f2) is mixed with the sine wave from the oscillator 30b. On the other hand, the Q component is mixed with the cosine wave generated by the π / 2 phase shifter 31b with respect to the sine wave from the oscillator 30b having the second intermediate frequency (f2) in the frequency mixer 34b.
[0038]
The output of the frequency mixer (33b, 34b) converted to the intermediate frequency is synthesized by the synthesizer 35b to generate a baseband signal. The output of the synthesizer 35b is amplified by an amplifier 36b as an amplifying unit, converted into a carrier frequency by a synthesizer 37b, and output as an RF signal.
[0039]
In this case, FIG. 4 shows the frequency spectrum of the OFDM signal output from each antenna (50a, 50b). This frequency spectrum is composed of a plurality of subcarriers 500. In the present embodiment, a total of 700 subcarriers 500 are configured. This OFDM signal is composed of a first subcarrier group 501 and a second subcarrier group 502. In the present embodiment, the first subcarrier group 501 and the second subcarrier group 502 are each composed of 350 subcarriers 500. The first subcarrier group 501 is modulated by the first intermediate frequency (f1) and then output from the first antenna 50a. On the other hand, the second subcarrier group 502 is modulated by the second intermediate frequency (f2) and then output from the second antenna 50b. By performing a series of signal processing as described above, a transmission frame composed of an OFDM signal, which is an object of the present invention, can be configured.
[0040]
(Reception block)
Next, processing of the reception block 100 will be described with reference to FIG. The RF signal received by the first antenna 50 a is first band-limited by the BPF 101, amplified, and then converted to an intermediate frequency by the synthesizer 102 and the frequency mixer 103. The received signal converted to the intermediate frequency is input to the BPF 104 for image removal.
[0041]
The band-limited signal is quadrature demodulated. Specifically, the signal from the BPF 104 is converted into a baseband signal by the output from the oscillator 110, the output from the π / 2 phase shifter 111, and the frequency mixer (112, 113).
[0042]
The output of the frequency mixer (112, 113) is band-limited by the LPF and converted into a discrete sequence by the A / D converter (115, 116).
Further, the FFT circuit 117 performs fast Fourier transform. Thereby, it converts into a frequency subcarrier. The output of the FFT circuit 117 is deinterleaved as necessary and demodulated by the demodulator 119.
[0043]
Further, a serial string signal is reproduced from the output of the demodulator 119 by the parallel-serial converter 120. The serial string signal is converted into an audio signal or the like via the output circuit 15. By performing a series of signal processing as described above, transmission composed of OFDM signals, which is an object of the present invention, can be realized.
[0044]
According to the multicarrier transmission of the above embodiment, the following effects can be obtained.
-In the said embodiment, it has a some transmission block like the 1st transmission block 20a and the 2nd transmission block 20b. The parallel string signal converted from the serial string signal is divided and input to each transmission block (20a, 20b). And RF signal is produced | generated by each transmission block (20a, 20b), and is output by the 1st antenna 50a and the 2nd antenna 50b. For this reason, the RF signal is spatially dispersed and emitted from the mobile phone 10. Therefore, it is possible to reduce the electromagnetic field level near the antenna, suppress the influence of the electromagnetic field concentration (hot spot) at the end, and reduce the amount of electromagnetic energy absorbed by the human body. In particular, the SAR can be improved in the mobile phone 10 that is normally used in close contact with the head.
[0045]
-In the said embodiment, it has several transmission blocks like the 1st transmission block 20a and the 2nd transmission block 20b, and frequency conversion is performed in each block. For this reason, since the band for performing signal processing is divided and narrowed, the operating frequency of each block can be lowered.
[0046]
In the above embodiment, an amplifier (36a, 36b) is provided for each transmission block (20a, 20b). For this reason, the frequency band which the amplifier of each transmission block takes can be narrowed, and each amplifier can be made small. Therefore, since the peak ratio is reduced, the cost of the amplifier can be reduced.
[0047]
In the above embodiment, each transmission block includes an IFFT circuit (23a, 23b). For this reason, the inverse fast Fourier transform can be separately performed on the divided parallel string signals. Therefore, it is possible to perform transmission resistant to fading by making use of the characteristics of OFDM transmission.
[0048]
In the above embodiment, the IFFT circuit 23a adds a guard interval. For this reason, similarly to normal OFDM transmission, even if a signal (ghost) having a time shift at the reception point due to irregular reflection or the like arrives, the influence (frequency selective fading) can be reduced.
[0049]
-In the said embodiment, since a frequency differs for every antenna (50a, 50b), disorder of an antenna pattern can be suppressed. That is, it is possible to prevent directivity disturbance due to the influence of the radiation pattern by a plurality of antennas.
[0050]
In addition, you may change the said embodiment as follows.
In the above embodiment, the mobile phone 10 has two transmission blocks, the first transmission block 20a and the second transmission block 20b. Then, the subcarrier group is divided into two to generate an RF signal. Alternatively, more transmission blocks may be provided, and the subcarrier group may be divided accordingly. Then, an RF signal is transmitted using more antennas. Thereby, dispersion | distribution of electromagnetic field intensity | strength can be aimed at and SAR can be improved.
[0051]
In the above embodiment, the parallel strings output by the serial / parallel converter 12 are each divided into equal numbers (here, 350 channels) and input to the transmission blocks (20a, 20b). Alternatively, it may be divided unevenly. In this case, for example, the number of channels is changed depending on the antenna arrangement. Specifically, for an antenna at a position where electromagnetic field concentration is likely to occur, the number of channels is reduced and the strength of the RF signal is reduced. Thereby, the electromagnetic field intensity can be dispersed and the SAR can be further improved.
[0052]
In the above embodiment, OFDM transmission is used as a multicarrier transmission scheme for digital modulation. The multicarrier transmission method is not limited to this, and other multicarrier transmission methods may be used. For example, the “MC-CDMA (Multi-Carrier CDMA)” method or the “Multi-carrier DS-CDMA” method may be used. Here, the “MC-CDMA (Multi-Carrier CDMA)” method is a method of modulating different subcarriers in each chip after spreading an information data sequence with a given spreading code. Also, in the “Multi-Carrier DS-CDMA” method, an information data sequence is assigned to each carrier by a serial-parallel converter, and after directly spreading with a spreading code given in each carrier, a different subcarrier is assigned to each data sequence. Modulation method.
[0053]
In the above-described embodiment, the mobile phone 10 is assumed as the communication terminal of the multicarrier transmission method. However, the present invention is not limited to this and may be a communication terminal that emits radio waves. For example, it may be a mobile computer terminal having a communication function, a PDA, or the like.
[0054]
【The invention's effect】
According to the present invention, it is possible to reduce the SAR by reducing the electromagnetic field in the vicinity of the user by providing a plurality of antennas and using them for transmitting divided subcarriers. Further, the amplifier can be made smaller by dividing the band.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of the overall configuration of an embodiment of the present invention.
FIG. 2 is an explanatory diagram of a transmission block.
FIG. 3 is an explanatory diagram of a reception block.
FIG. 4 is an explanatory diagram of an OFDM spectrum.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Mobile phone as communication terminal, 20a ... First transmission block as transmission means, 20b ... Second transmission block as transmission means, 36a ... Amplifier as amplification means, 36b ... Amplifier as amplification means, 50a ... As antenna First antenna, 50b, second antenna as an antenna, 500, subcarrier.

Claims (6)

A communication terminal for transmitting an input signal by multicarrier transmission,
The communication terminal is
Converting means for dividing the input signal into a plurality of signal groups corresponding to adjacent subcarriers;
A plurality of transmission means for performing modulation independently for each signal group generated by the conversion means;
Have a plurality of antennas connected independently for each of the plurality of transmitting means, the number of subcarriers, each of which transmits a plurality of antennas, characterized by Rukoto is determined by the arrangement of the plurality of antennas Communication terminal. The converting means includes
Perform serial-parallel conversion to convert serial string signals to parallel string signals,
The communication terminal of claim 1, wherein the parallel string signal is divided to generate a plurality of signal groups.   The communication terminal according to claim 1 or 2, wherein frequencies of the subcarriers are orthogonal to each other. The communication terminal according to any one of claims 1 to 3, wherein the plurality of transmission units perform inverse Fourier transform for each signal group. The communication terminal according to claim 1, wherein the plurality of transmission units perform frequency conversion using different intermediate frequencies for each signal group. The communication terminal according to any one of claims 1 to 5, wherein the plurality of transmission means include amplification means independent for each signal group corresponding to a subcarrier.

Images