JP2003204317A - Wireless transmission device and wireless communication method - Google Patents

Abstract

(57) [Summary] [PROBLEMS] To further improve frequency use efficiency and transmission speed while maintaining communication quality. SOLUTION: Different information (transmission signal A ≠ transmission signal B) is transmitted at the same frequency from a plurality of antennas 106 and 116 (spatial multiplexing), or different information (transmission signal A ≠ transmission signal B) is transmitted from a plurality of antennas 106 and 116. B) at a different frequency (frequency multiplexing) or a plurality of antennas 10
6 and 116 transmit the same information (transmission signal A = transmission signal B) at the same frequency (spatial diversity), or transmit the same information (transmission signal A = transmission signal B) at different frequencies from a plurality of antennas 106 and 116. (Frequency diversity) is adaptively switched according to the state of the propagation path. At this time, a frequency where no interference wave exists is detected from a plurality of usable frequencies, and the transmission frequencies of the plurality of antennas 106 and 116 are set from the detected frequencies.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless transmitter and a wireless communication method used in a digital wireless communication system.

[0002]

2. Description of the Related Art At present, a broadband wireless access system is being developed with the aim of becoming a unified global standard. Furthermore, for the quasi-millimeter wave band, it is desired to establish a next-generation mobile broadband wireless access system that utilizes abundant frequency resources.

The current broadband wireless access system is as follows:
Under the unified world, 5 GHz band is used and the modulation method is orthogonal frequency multi-frequency type (OFDM: Orthogonal Frequency Divisio).
n Multiplex), and there is one that adaptively controls the modulation multilevel number for each subcarrier depending on the quality of the propagation path. According to this method, a large number of modulation levels can be obtained under favorable conditions for the propagation path.
A value of QAM can be used to achieve a transmission rate of 54 Mbps.

In recent years, in order to further effectively use the frequency, application of an SDM (Space Division Multiplex) method in which a plurality of antennas are used to perform space division multiplexing at the same frequency has been studied (for example, non-patent document). 1). In this type of system, the modulation system is the same as the conventional one, but since different information is transmitted from a plurality of antennas at the same frequency and multiplexed in space, for example, when using two antennas, the frequency band to be used is The transmission capacity is doubled without increasing, and thus the transmission speed is also doubled.

[0005]

[Non-Patent Document 1] Sugiyama, Ryo Umehira, "Proposal of wideband PDM-COFDM system using orthogonal polarization", 2001 IEICE Communications Society Conference, SB-3-7

[0006]

However, in the above-mentioned conventional method, in principle, there is a case where the spatially multiplexed transmission signal cannot be separated and reproduced on the receiving side depending on the interference from other cells and the condition of the propagation path. Therefore, the communication capacity does not always increase, and not only may there be a case where the expected transmission speed requirement cannot be satisfied,
In some cases, communication may be lost.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a wireless transmission device and a wireless communication method capable of further improving frequency utilization efficiency and transmission speed while maintaining communication quality. To aim.

[0008]

(1) A radio transmitting apparatus according to the present invention comprises a transmitting means for transmitting the same or different information by using a plurality of antennas, an acquiring means for acquiring the state of a propagation path, and the acquiring. A control unit that controls each transmission frequency of the plurality of antennas and the number of pieces of information transmitted from the plurality of antennas in accordance with the propagation path condition acquired by the unit.

According to this configuration, when the same or different information is transmitted using a plurality of antennas, the transmission frequencies of the plurality of antennas and the information transmitted from the plurality of antennas can be changed depending on the situation of the propagation path. To control the number, for example, different information may be transmitted from multiple antennas at the same frequency (spatial multiplexing), different information may be transmitted from multiple antennas at different frequencies (frequency multiplexing), or the same information may be transmitted from multiple antennas. It is possible to adaptively switch between transmitting data at the same frequency (spatial diversity) or transmitting the same information from multiple antennas at different frequencies (frequency diversity) according to the conditions of the propagation path. It is possible to further improve the frequency utilization efficiency and the transmission rate while maintaining the above.

(2) The radio transmitting apparatus according to the present invention further comprises, in the above configuration, a detecting means for detecting a frequency not assigned to another user from a plurality of usable frequencies, and the control means. Is configured to set each transmission frequency of the plurality of antennas from the frequencies detected by the detection means.

According to this structure, a frequency that is not assigned to another user is detected from a plurality of usable frequencies, and the transmission frequencies of the plurality of antennas are set from the detected frequencies. Without being affected by interference from other users, that is, while maintaining communication quality,
It is possible to further improve frequency utilization efficiency and transmission speed.

(3) In the radio transmitting apparatus according to the present invention, in the above configuration, the control means sets the transmission frequencies of the plurality of antennas to the same frequency when the propagation path condition acquired by the acquisition means is good. And the different information is transmitted from the plurality of antennas.

According to this configuration, when the propagation path condition is good, the transmission frequencies of the plurality of antennas are set to the same frequency, and different information is transmitted from the plurality of antennas (spatial multiplexing). It is possible to maximize the further improvement of the frequency utilization efficiency and the transmission rate without increasing the frequency, that is, while maintaining the frequency band to be used.

(4) In the radio transmitter according to the present invention, in the above-mentioned configuration, the control means sets the transmission frequencies of the plurality of antennas to different frequencies when the propagation path condition acquired by the acquisition means is poor. And the different information is transmitted from the plurality of antennas.

According to this configuration, when the propagation path condition is poor, the transmission frequencies of the plurality of antennas are set to different frequencies, and different information is transmitted from the plurality of antennas (frequency multiplexing). It is possible to further improve the frequency utilization efficiency and the transmission rate without being affected by the deterioration of communication quality due to, that is, while maintaining the communication quality.

(5) In the radio transmitting apparatus according to the present invention, in the above configuration, the control means sets the transmission frequencies of the plurality of antennas to the same frequency when the propagation path status acquired by the acquisition means is poor. The configuration is adopted and the same information is transmitted from the plurality of antennas.

According to this configuration, when the propagation path condition is poor, the transmission frequencies of the plurality of antennas are set to the same frequency and the same information is transmitted from the plurality of antennas (spatial diversity). Even if the channel condition is so bad that different information cannot be transmitted from the antenna, the communication quality can be maintained by the diversity.

(6) In the radio transmitter according to the present invention, in the above-mentioned configuration, the control means sets the transmission frequencies of the plurality of antennas to different frequencies when the propagation path condition acquired by the acquisition means is poor. The configuration is adopted and the same information is transmitted from the plurality of antennas.

According to this configuration, when the propagation path condition is poor, the transmission frequencies of the plurality of antennas are set to different frequencies and the same information is transmitted from the plurality of antennas (frequency diversity). Even if the channel condition is so bad that different information cannot be transmitted from the antenna, the communication quality can be maintained by the diversity.

(7) The radio transmitting apparatus of the present invention comprises transmitting means for transmitting information using a plurality of antennas, and detecting means for detecting the presence or absence of an interference wave for each of a plurality of usable frequencies. And a control unit that sets each transmission frequency of the plurality of antennas to a different frequency by using a frequency in which no interference wave exists.

According to this configuration, the transmission frequencies of the plurality of antennas are set to different frequencies by using the frequencies in which no interference wave exists, regardless of the state of the propagation path, so that they are not assigned, that is, are vacant. The existing frequency can be used freely, and the influence of interference from other users can be reduced.

(8) The radio base station apparatus of the present invention has a configuration including any one of the radio transmission apparatuses described above.

According to this structure, it is possible to provide a radio base station apparatus having the same effects as the above.

(9) The wireless terminal device of the present invention has a configuration including any one of the wireless transmission devices described above.

With this configuration, it is possible to provide a wireless terminal device having the same effects as the above.

(10) In the wireless communication method of the present invention, a transmitting step of transmitting the same or different information by using a plurality of antennas, an acquiring step of acquiring the condition of the propagation path,
A control step of controlling each transmission frequency of the plurality of antennas and the number of pieces of information transmitted from the plurality of antennas according to the propagation path situation obtained in the obtaining step.

According to this method, when the same or different information is transmitted using a plurality of antennas, the transmission frequencies of the plurality of antennas and the information transmitted from the plurality of antennas can be changed according to the situation of the propagation path. To control the number, for example, different information may be transmitted from multiple antennas at the same frequency (spatial multiplexing), different information may be transmitted from multiple antennas at different frequencies (frequency multiplexing), or the same information may be transmitted from multiple antennas. It is possible to adaptively switch between transmitting data at the same frequency (spatial diversity) or transmitting the same information from multiple antennas at different frequencies (frequency diversity) according to the conditions of the propagation path. It is possible to further improve the frequency utilization efficiency and the transmission rate while maintaining the above.

(11) In the wireless communication method of the present invention, a transmitting step of transmitting information using a plurality of antennas, and a detecting step of detecting the presence or absence of an interference wave for each of a plurality of usable frequencies, And a control step of setting each transmission frequency of the plurality of antennas to different frequencies by using a frequency in which no interference wave exists.

According to this method, the transmission frequencies of the plurality of antennas are set to different frequencies by using the frequencies in which the interference wave does not exist, regardless of the state of the propagation path, so that they are not assigned, that is, are vacant. The existing frequency can be used freely, and the influence of interference from other users can be reduced.

[0030]

BEST MODE FOR CARRYING OUT THE INVENTION The essence of the present invention is that, when the same or different information is transmitted by using a plurality of antennas, the transmission frequencies of the plurality of antennas and the plurality of antennas are transmitted depending on the situation of the propagation path. Controlling the number of information to be transmitted, for example, different information is transmitted from a plurality of antennas at the same frequency (spatial multiplexing), different information is transmitted from a plurality of antennas at different frequencies (frequency multiplexing), It is to adaptively switch between transmitting the same information from the antenna at the same frequency (spatial diversity) and transmitting the same information from multiple antennas at different frequencies (frequency diversity) according to the conditions of the propagation path. .

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

FIG. 1 is a block diagram showing a configuration of a radio transmitting apparatus according to an embodiment of the present invention, and FIG. 2 is a block showing a configuration of a radio receiving apparatus performing radio communication with the radio transmitting apparatus shown in FIG. It is a figure. The wireless transmission device shown in FIG. 1 and the wireless reception device shown in FIG. 2 can be mounted in the same wireless communication device.

This wireless communication device is, for example, OFDM.
1 is a transmitter of an OFDM signal, and a radio receiving device 200 shown in FIG. 2 is a receiver of an OFDM signal. O
The FDM system has been attracting attention as a next-generation mobile broadband wireless access system because it can reduce the influence of multipath delay spread in high-speed digital signal transmission by using multiple carriers and inserting guard intervals. Here, the OFDM signal is a multiplexed signal of a plurality of orthogonal carrier waves (subcarriers).

In this embodiment, in the OFDM system, when the same or different information is transmitted using a plurality of antennas, the transmission frequencies of the plurality of antennas and the transmission from the plurality of antennas are transmitted according to the situation of the propagation path. By controlling the number of pieces of information to be transmitted, frequency utilization efficiency and transmission speed are further improved while maintaining communication quality. Here, a case where the number of antennas is two will be described as an example.

A wireless transmitter (transmitter) 100 shown in FIG.
Has a system 1 for transmitting the transmission signal A and a system 2 for transmitting the transmission signal B. The system 1 includes an encoding unit 101, a subcarrier modulation unit 102, an inverse fast Fourier transform (IFF).
T) section 103, slot assembly section 104, frequency conversion section 1
05 and the antenna 106, the system 2
Encoding section 111, subcarrier modulation section 112, inverse fast Fourier transform (IFFT) section 113, slot assembly section 11
4, a frequency conversion unit 115, and an antenna 116. The transmitter 100 also includes a carrier frequency control unit 121, a transmission signal switching unit 122, and an overall control unit 123.

On the other hand, the radio receiver (receiver) shown in FIG.
The system 200 has a system 1 that receives the transmission signal A from the transmitter 100 and obtains the reception signal A, and a system 2 that receives the transmission signal B from the transmitter 100 and obtains the reception signal B. However, when the transmission signal A and the transmission signal B have the same frequency, both the transmission signal A and the transmission signal B are received in each system. System 1 is composed of antenna 201, frequency conversion unit 202, fast Fourier transform (FFT) unit 203, subcarrier demodulation unit 204, and decoding unit 205, and system 2 is antenna 211, frequency conversion unit 21.
2, a fast Fourier transform (FFT) unit 213, a subcarrier demodulation unit 214, and a decoding unit 215. Further, the receiver 200 has the carrier frequency control unit 22.
1, symbol synchronization timing unit 222, interference compensation unit 22
3, an interference detection unit 224, and an error detection unit 225.

The transmitter 100 is connected to the same wireless communication device.
If the receiver 200 is installed, the transmitter 10
The antennas 106 and 116 for 0 and the antennas 201 and 211 for the receiver 200 may be of a transmission / reception shared type.

Next, each operation of the transmitter 100 and the receiver 200 having the above configuration will be described.

First, the operation of the transmitter 100 is as follows.

The transmission signal A of system 1 is encoded by the encoding unit 101.
, For example, convolutionally encoded. The coded signal is modulated by subcarrier modulation section 102 for each subcarrier and then output to IFFT section 103. IF
The FT unit 103 performs an inverse fast Fourier transform (IFFT) on the output signal of the subcarrier modulation unit 102 to generate an OFDM signal. The generated OFDM signal is output to frequency conversion section 105 after the slot assembling section 104 inserts a guard interval and a preamble. The frequency conversion section 105 up-converts the output signal of the slot assembly section 104 into a radio frequency (transmission frequency) independently controlled by the carrier frequency control section 121. The up-converted transmission signal is transmitted via the antenna 106. In addition, regarding the transmission signal B of system 2,
The same processing as in the case of the transmission signal A of system 1 is performed, and the frequency conversion unit 115 up-converts the output signal of the slot assembly unit 114 into a radio frequency (transmission frequency) independently controlled by the carrier frequency control unit 121. Then, the signal is transmitted from the antenna 116. At this time, the transmission signal switching unit 122 switches whether the transmission signal A of the system 1 and the transmission signal B of the system 2 are the same or not. Carrier frequency control unit 121 and transmission signal switching unit 12
All of 2 are adaptively controlled by the control unit 123. Regarding the contents of the adaptive control by the control unit 123,
More on this later.

Next, the operation of the receiver 200 is as follows.

The OFDM signal received via the antenna 201 of the system 1 is a radio frequency controlled independently by the carrier frequency control section 221 in the frequency conversion section 202 (a transmission frequency of the antenna 106 transmitting the transmission signal A and After being down-converted using the same frequency), a FFT unit 203 is passed through a guard interval removing unit (not shown).
Is output to. The FFT unit 203 uses the timing signal output from the symbol synchronization timing unit 222 to perform a fast Fourier transform (FFT) on the OFDM signal after the guard interval is removed. Similar processing is performed on the OFDM signal received via the antenna 211 of the system 2, and the frequency conversion unit 212 causes the carrier frequency control unit 2
Radio frequency independently controlled by 21 (transmit signal B
Is down-converted using the same frequency as the transmission frequency of the antenna 116 that has transmitted (1), the guard interval is removed, and FFT processing is performed. The interference compensating unit 223 estimates the transfer function between the antennas 201 and 211 to separate the spatially multiplexed signal. In the system 1 and the system 2, the separated signals are demodulated by the subcarrier demodulation units 204 and 214 for each subcarrier, and then decoded by the decoding units 205 and 215. As a result, the reception signal A and the reception signal B are obtained.

At this time, the interference detection unit 224 measures the interference level for each system and detects the presence or absence of an interference wave, thereby selecting a frequency not assigned to another user from a plurality of usable frequencies. To detect. The error detection unit 225 also detects, for example, an error rate (eg, BER (Bit Error Rate)) as an index indicating the state of the propagation path. The interference detection result by the interference detection unit 224 (presence or absence of interference wave in each system) and the error detection result by the error detection unit 225 (error rate in each system) are the transmitter installed in the same wireless communication device (see FIG. (Not shown) and a receiver (not shown) mounted on the wireless communication apparatus of the communication partner, and is given to the control unit 123 of the transmitter 100 of the communication partner.

Next, the contents of the adaptive control in the transmitter 100 will be described in detail with reference to FIGS. 3 to 6. Here, as the usable frequency (more strictly speaking, the frequency band), for example, channel 1 (CH
The case where there are four channels (frequency bands) from 1) to channel 4 (CH4) will be described as an example. 3 to 6, the antenna # 1 is the antenna 106 of the system 1 and the antenna # 2 is the antenna 116 of the system 2.

In this embodiment, the transmitter 100 can employ four wireless communication systems. The first is the case of spatial multiplexing, that is, the case where different information (transmission signal A ≠ transmission signal B) is transmitted from the two antennas 106 and 116 at the same frequency (for example, see FIG. 3), and the second is , In the case of frequency multiplexing, that is, two antennas 106 and 11
6 to transmit different information (transmission signal A ≠ transmission signal B) at different frequencies (for example, see FIG. 4),
The third is the case of space diversity, that is, the case of transmitting the same information (transmission signal A = transmission signal B) from the two antennas 106 and 116 at the same frequency (for example,
Fourth, in the case of frequency diversity, that is, in the case of transmitting the same information (transmission signal A = transmission signal B) from two antennas 106 and 116 at different frequencies (see, for example, FIG. 6). ). Based on the interference detection result (presence or absence of an interference wave in each system) and the error detection result (error rate in each system) from the receiver 200 mounted in the wireless communication device of the communication partner, the control unit 123 performs these operations. The four wireless communication systems are adaptively switched.

Specifically, for example, when the error detection result is good, that is, when the condition of the propagation path is good, FIG.
As shown in (2), spatial multiplexing is performed by transmitting different information (transmission signal A ≠ transmission signal B) from the two antennas 106 and 116 at the same frequency. In the example shown in FIG. 3, avoiding CH1, CH2, and CH4 where interference waves exist, that is, frequencies (channels) assigned to other users,
Different transmission signals A and B are multiplexed and transmitted from the antenna 106 of the system 1 and the antenna 116 of the system 2 using the vacant same channel (CH3). At this time, the receiver 200 performs the receiving operation using the frequency used in the transmitter 100 (CH3 frequency in the example of FIG. 3).

According to this method, when the condition of the propagation path is good, spatial multiplexing is performed, so that the frequency utilization efficiency and the transmission are increased without increasing the frequency to be used, that is, while maintaining the frequency band to be used. Further improvement in speed can be maximized. Moreover, a frequency in which no interference wave exists is detected from a plurality of (here, four) usable frequencies (CH1 to CH4), and a plurality (here, two) of antennas are detected from among the detected frequencies. Since each transmission frequency is set, it is possible to further improve frequency utilization efficiency and transmission rate without being affected by interference from other users, that is, while maintaining communication quality.

Further, for example, when the error detection result is bad, that is, when the condition of the propagation path is bad, different information (transmission signal A ≠ transmission from the two antennas 106 and 116) is transmitted as shown in FIG. Frequency multiplexing is performed by transmitting signal B) at different frequencies. In the example shown in FIG. 4, CH1 and CH4 in which an interference wave exists, that is, frequencies (channels) assigned to other users are avoided, and antenna 106 of system 1 out of two vacant channels CH2 and CH3. Transmit the transmission signal A using one channel (CH2), and transmit the transmission signal B different from system 1 from the antenna 116 of system 2 using the other channel (CH3) different from system 1. To do. At this time,
The receiver 200 uses the frequency of each system used in the transmitter 100 (in the example of FIG. 4, the system 1 is the frequency of CH2, the system 2 is
Performs the receiving operation using the CH3 frequency).

According to this method, when the condition of the propagation path is poor, frequency multiplexing is performed, so that there is no influence of deterioration of communication quality due to spatial multiplexing of each system, that is, while maintaining communication quality, It is possible to further improve frequency utilization efficiency and transmission speed. Moreover, a plurality (here, 4
Frequency) to detect a frequency in which no interference wave exists from the available frequencies (CH1 to CH4) and set each transmission frequency of a plurality of antennas (two in this case) from the detected frequencies. Further, it is possible to further improve the frequency utilization efficiency and the transmission rate without being affected by the interference from other users, that is, while maintaining the communication quality.

Further, for example, when the error detection result is extremely bad, that is, when the propagation path condition is so bad that different information cannot be transmitted from a plurality of antennas,
Alternatively, as shown in FIG. 5, two antennas 106,
By transmitting the same information (transmission signal A = transmission signal B) from 116 at the same frequency, spatial diversity is performed, or, as shown in FIG. 6, two antennas 106 and 11 are used.
Frequency diversity is performed by transmitting the same information (transmission signal A = transmission signal B) from 6 at different frequencies. In the example shown in FIG. 5, CH1, CH2, C in which interference waves exist
H4, that is, avoiding a frequency (channel) assigned to another user, and vacant same channel (CH
3), the same transmission signal (transmission signal A = transmission signal B) is spatially diversity-transmitted from the antenna 106 of system 1 and the antenna 116 of system 2. Further, in the example shown in FIG. 6, CH1 and CH4 in which an interference wave exists, that is, frequencies (channels) assigned to other users are avoided and, of the two vacant channels, CH2 and CH3,
From the antenna 106 of system 1, one channel (CH
2) is used to transmit a transmission signal, and the antenna 11 of the grid 2 is used.
From 6 onwards, the other channel (CH
3) is used to transmit the same transmission signal as in system 1 (transmission signal A = transmission signal B). At this time, the receiver 200
In the former case, the reception operation is performed using the frequency used in the transmitter 100 (CH3 frequency in the example of FIG. 5), and in the latter case, the frequency of each system used in the transmitter 100 (see FIG. In the example of 6, the frequency of the system 1 is CH2, the system 2 is
Performs the receiving operation using the CH3 frequency).

According to these methods, when the propagation path condition is extremely poor, that is, when it is necessary to secure the communication quality even at the expense of the improvement of the transmission rate, the space diversity or the frequency diversity is performed. Even if the propagation path condition is so bad that different information cannot be transmitted from a plurality of antennas, the communication quality can be maintained by diversity.

As described above, according to the present embodiment, when the same or different information is transmitted by using the plurality of antennas 106 and 116, each of the plurality of antennas 106 and 116 is selected according to the state of the propagation path. It controls the transmission frequency and the number of pieces of information transmitted from the plurality of antennas 106 and 116. For example, the communication quality is adaptively switched between spatial multiplexing, frequency multiplexing, spatial diversity, and frequency diversity according to the state of the propagation path. While maintaining
The frequency utilization efficiency and the transmission speed can be further improved. In other words, it is possible to maintain the communication quality and further improve the frequency utilization efficiency and the transmission rate.

In this embodiment, the adaptive control in the transmitter 100 first uses the same frequency even if there is a vacant frequency (to make it easier for other users to enter later). However, the control concept of adaptive control is not limited to this, although it is based on the idea of using a different frequency when it is not possible to secure (but it is necessary to detect the absence of an interference wave).

For example, it is possible to adopt the concept of transmitting at a different frequency when the interference wave does not exist regardless of the condition of the propagation path.
Specifically, for example, first, the presence or absence of an interference wave is detected,
If there is no interference wave, a different frequency is used, and if an interference wave is detected during operation, the same frequency is used. Then, after that, when it is detected that the interference wave is gone, a different frequency may be used again. In this case, regardless of the state of the propagation path, the transmission frequencies of the multiple antennas are set to different frequencies using frequencies that do not have interference waves, so frequencies that are not assigned, that is, free, can be used freely. Therefore, the influence of interference from other users can be reduced.

Further, although the present embodiment has been described by taking an OFDM wireless communication apparatus as an example, the present invention is not limited to the case of being applied to the OFDM method, of course. For example, the present invention relates to a CDMA (Code Division Multiplex).
It is also applicable to an access type wireless communication device.

Further, the radio transmitting apparatus according to the present invention can be mounted on a radio communication apparatus in a mobile communication system, for example, a radio base station apparatus or a radio terminal apparatus.

[0057]

As described above, according to the present invention,
It is possible to further improve the frequency utilization efficiency and the transmission rate while maintaining the communication quality.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a wireless transmission device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing the configuration of a wireless reception device that performs wireless communication with the wireless transmission device shown in FIG.

FIG. 3 is a diagram for explaining the case of spatial multiplexing among the wireless communication systems that can be adopted by the wireless transmission device shown in FIG.

FIG. 4 is a diagram for explaining a case of frequency multiplexing among the wireless communication systems that can be adopted by the wireless transmission device shown in FIG.

5 is a diagram for explaining a case of space diversity among the wireless communication methods that can be adopted by the wireless transmission device shown in FIG.

FIG. 6 is a diagram for explaining a case of frequency diversity among the wireless communication methods that can be adopted by the wireless transmission device shown in FIG.

[Explanation of symbols]

100 wireless transmitter 105, 115, 202, 212 Frequency converter 106,116,201,211 antenna 121,221 Carrier frequency control unit 122 Transmission signal switching unit 123 control unit 200 wireless receiver 223 Interference compensator 224 Interference detector 225 Error detector

Claims (11)

[Claims] 1. A transmission means for transmitting the same or different information using a plurality of antennas, an acquisition means for acquiring the status of a propagation path, and a propagation path status acquired by the acquisition means,
And a control unit configured to control each transmission frequency of the plurality of antennas and the number of pieces of information transmitted from the plurality of antennas. 2. A detecting means for detecting a frequency not assigned to another user from a plurality of usable frequencies,
The wireless transmission device according to claim 1, further comprising: wherein the control unit sets each transmission frequency of the plurality of antennas from among the frequencies detected by the detection unit. 3. The control means sets each transmission frequency of the plurality of antennas to the same frequency when the channel condition acquired by the acquisition means is good, and sets different information from the plurality of antennas. The wireless transmission device according to claim 1, wherein the wireless transmission device is configured to transmit. 4. The control means sets each transmission frequency of the plurality of antennas to different frequencies when the propagation path condition acquired by the acquisition means is poor, and sets different information from the plurality of antennas. The wireless transmission device according to claim 1, wherein the wireless transmission device is configured to transmit. 5. The control means sets the transmission frequencies of the plurality of antennas to the same frequency and transmits the same information from the plurality of antennas when the propagation path condition acquired by the acquisition means is poor. The wireless transmission device according to claim 1, wherein 6. The control unit sets the transmission frequencies of the plurality of antennas to different frequencies and transmits the same information from the plurality of antennas when the propagation path condition acquired by the acquisition unit is poor. The wireless transmission device according to claim 1, wherein 7. A transmitting means for transmitting information using a plurality of antennas, a detecting means for detecting the presence or absence of an interference wave for each of a plurality of usable frequencies, and a frequency in which no interference wave exists. Control means for setting respective transmission frequencies of the plurality of antennas to different frequencies, and a radio transmitting device. 8. A radio base station apparatus comprising the radio transmission apparatus according to claim 1. Description: 9. A wireless terminal device comprising the wireless transmission device according to claim 1. Description: 10. A transmission step of transmitting the same or different information by using a plurality of antennas, an acquisition step of acquiring a status of a propagation path, and a plurality of antennas according to the propagation path status acquired in the acquisition step. And a control step of controlling the number of pieces of information transmitted from each of the plurality of antennas, and the radio communication method. 11. A transmission step of transmitting information using a plurality of antennas, a detection step of detecting the presence or absence of an interference wave for each of a plurality of usable frequencies, and a frequency using no interference wave. A control step of setting each transmission frequency of the plurality of antennas to different frequencies, the wireless communication method comprising: