JP4794085B2 - Data transmission apparatus and wireless communication system - Google Patents

Description

すなわち、調整時間Ｔｄ（＝ｔ７−ｔ６）は次式
Ｔｄ＝Ｔ２−２×Ｔｗ ＝ Ｔ２−（ｔ４−ｔ１−Ｔ１）……… （４）
と表すことができる。
【０４１９】
このように、送信局の送信タイミングのための調整時間Ｔｄは、送信局にとって既知の時点ｔ１、ｔ４と共有時間情報Ｔ１、Ｔ２で表すことができるので送信局は（４）式に基づいて時点ｔ８に受信局に秘匿情報が到達するような送信タイミングで秘匿情報を含む送信データを送出できる。
【０４２０】
【発明の効果】
以上説明したように、本発明によれば、第１の無線局から第２の無線局に秘匿情報を含む送信データを無線伝送する場合、当該秘匿情報を伝送する前に、第１の無線局と第２の無線局の間で信号の送受信を行うことにより、第１の無線局と第２の無線局の間でのみ共有する無線伝搬路環境を推定し、推定した無線伝搬路環境を考慮して、第１の無線局から第２の無線局に秘匿情報を伝送するようにしたことにより、無線回線を介して特定の無線局に秘匿情報を伝送する場合に、高いセキュリティで秘匿情報を伝送し得るデータ伝送装置、無線通信システム及び無線通信方法を実現できる。
【図面の簡単な説明】
【図１】本発明の実施の形態１に係る無線通信システムの構成を示すブロック図
【図２】図１の送信局の構成を示すブロック図
【図３】図１の受信局の構成を示すブロック図
【図４】実施の形態１、３の無線通信システムにおける通信手順を示すシーケンス図
【図５】実施の形態１、３の通信信号の伝搬状態を示す図
【図６】実施の形態４のバースト信号形成部の構成を示すブロック図
【図７】実施の形態４の復調部及びストリーム形成部の構成を示すブロック図
【図８】実施の形態４の時間同期／ユニークワード抽出回路の構成を示すブロック図
【図９】図８の時間同期／ユニークワード抽出回路の動作の説明に供する信号波形図
【図１０】実施の形態４の通信信号の伝搬状態を示す図
【図１１】実施の形態５の無線通信システムの構成を示すブロック図
【図１２】実施の形態５、６、７の無線通信システムにおける通信手順を示すシーケンス図
【図１３】実施の形態５の通信信号の伝搬状態を示す図
【図１４】実施の形態６、７，９の通信信号の伝搬状態を示す図
【図１５】実施の形態８の無線通信システムの構成を示すブロック図
【図１６】実施の形態８、９の無線通信システムにおける通信手順を示すシーケンス図
【図１７】実施の形態９の無線通信システムの構成を示すブロック図
【図１８】図１７の送信局の構成を示すブロック図
【図１９】実施の形態１０の無線通信システムの構成を示すブロック図
【図２０】図１９の送信局の構成を示すブロック図
【図２１】図２０の伝搬環境推定部の構成を示すブロック図
【図２２】図２０の放射特性制御部の構成を示すブロック図
【図２３】偏波面と電界強度、位相差の説明に供する図
【図２４】実施の形態１０、１１の無線通信システムにおける通信手順を示すシーケンス図
【図２５】実施の形態１０の動作の説明に供する図
【図２６】アンテナの位置と偏波面との説明に供する図
【図２７】アンテナの位置と偏波面との説明に供する図
【図２８】実施の形態１１の無線通信システムの構成を示すブロック図
【図２９】実施の形態１２の無線通信システムの構成を示すブロック図
【図３０】図２９の送信局の構成を示すブロック図
【図３１】図３０のバースト信号形成部、ビームフォーマ、変調部の構成を示すブロック図
【図３２】図３０の復調部及びストリーム形成部の構成を示すブロック図
【図３３】実施の形態１２の無線通信システムにおける通信手順を示すシーケンス図
【図３４】電磁波の空間合成の説明に供する図
【図３５】他の実施の形態に係る無線通信システムの構成を示すブロック図
【図３６】他の実施の形態に係る通信手順を示すシーケンス図
【符号の説明】
１００、５００、８００、９００、１０００、１１００、１２００、１３００
無線通信システム
１０１、５０１、８０１、８０２、９０１、１００１、１２０１、１３０１ 送信局
１０１ａ、１０２ａ、５０２、５０３、１０１２、１２２０ 送信部
１０１ｂ、１０２ｂ、１０１３、１２４０ 受信部
１０１ｃ、９０４、１００６、１２０５、１３０３ 伝搬環境推定部
１０１ｄ、９０５、１２０６、１３０４ 伝搬環境適応部
１０２、１００２、１０４０、１１０１、１２０２ 受信局
１０２ｃ、１００７、１０１０ 時間制御部
１０３、５０４、５０５、８０６、８０７、９０６、９０７、１０４１、１０４２、１２０７、１２０８、１３０５、１３０６、１３０７ 伝搬路
１１５、１３２、３００、１２２１ バースト信号形成部
１１６、１３４、１２２３ 変調部
１１８、９０５ａ タイミングコントロール部
１２０、９０４ａ 遅延量推定部
１２２、１４１、３１０ 復調部
１２３、１４２、３２０ ストリーム形成部
３３０ コンボルバ回路
３１２ 時間同期／ユニークワード抽出回路
３３３ ピーク探索回路
３３４ 探索範囲設定回路
３３５ ユニークワード選択回路
８０３、８０４ 網接続部
８０５ ネットワーク
９０２、９０３、１００５、１００９、１２０３、１２０４、１３０２ 送受信部
９０４ｂ 電力測定部
９０５ｂ 電力制御部
１００３、１００４、１１０２、１１０３ アンテナ部
１００８、１１０４ 放射特性制御部
１２１０ 到来方向推定部
１２２２ ビームフォーマ
ＡＮ、ＡＮ１１、ＡＮ１２、ＡＮ１３、ＡＮ２０、ＡＮ２１、ＡＮ３０、ＡＮ６０、ＡＮ６１ アンテナ
Ｄ１、Ｄ２、Ｄ３ ユーザデータ
Ｄ４ スクランブルパンクチュアデータ[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a data transmission apparatus.as well asThe present invention relates to a radio communication system, and is particularly suitable for application when secret information is transmitted to a specific radio station via a radio line.
[0002]
[Prior art]
In recent years, digital wireless communication has come to occupy an important position in the communication field due to a dramatic improvement in transmission speed and transmission quality. On the other hand, since wireless communication uses a radio wave space that is a public good, there is a fundamental drawback that reception by a third party is possible from the viewpoint of confidentiality. That is, there is always a possibility that the contents of communication are intercepted by a third party and information is leaked.
[0003]
Therefore, in the conventional wireless communication, the secret information is encrypted so that even if transmission data is intercepted by a third party, the contents of the secret information are not understood by the third party. Encryption has been studied in various fields and applied in various fields. This is because encryption has an advantage that a certain level of security can be secured without changing the wireless communication system.
[0004]
[Problems to be solved by the invention]
However, in the information encryption, there is a problem that if the code for encryption and the encryption procedure are known, the information is relatively easily deciphered. In particular, in the current situation where high-speed computers are generally widespread, security cannot be ensured unless fairly complicated encryption processing is performed.
[0005]
Particularly in arithmetic encryption, in order to decrypt encrypted information, an encryption key which is common information for encryption and decryption is required. When it is necessary to exchange the encryption key, if the encryption key is intercepted by a third party, there is always a possibility that the secret information is easily deciphered from the encryption key and the secret text. In particular, when an encryption key or encryption information is transmitted via a wireless line as described above, the risk becomes even greater.
[0006]
  The present invention has been made in view of the above points, and a data transmission apparatus capable of transmitting confidential information with high security when transmitting the confidential information to a specific wireless station via a wireless line.as well asAn object is to provide a wireless communication system.
[0007]
[Means for Solving the Problems]
  In order to solve such a problem, the data transmission device of the present invention is a data transmission device that wirelessly transmits transmission data including confidential information to a wireless station,Arranged at different positions, the radio stationReceive signals sent byFirst and secondReceiving means;The first and secondObtained by means of receivingEach received signalOn the basis of the, A first signal propagation time in a first wireless propagation path between the wireless station and the first receiving means and a second wireless propagation path between the wireless station and the second receiving means Estimate second signal propagation timeAre arranged at the same position as the first and second receiving means, respectively, and the first and second receiving means,Based on signal propagation time, Including the confidential informationEach transmission data is transmitted at the timing when the first and second transmission data arrive at the radio station at the same time.First and second transmission means,The first and second transmission data are formed in the same format.Take the configuration.
[0008]
  The data transmission apparatus according to the present invention is a data transmission apparatus that wirelessly transmits transmission data including confidential information to a wireless station, and is arranged at different positions and receives a signal transmitted by the wireless station. And a second receiving means and a first radio propagation path between the radio station and the first receiving means based on each received signal obtained by the first and second receiving means. An estimation means for estimating a first signal propagation time and a second signal propagation time in a second radio propagation path between the radio station and the second receiving means; and a unit of the first and second transmission data A pseudo-symbol with very low power is added to the secret symbol in the first and second transmission data so that the secret symbols forming the secret information do not overlap when communication frames are arranged. Pseudo The first transmission data and the second transmission data, which are arranged at the same position as the first and second reception units, respectively, and include the confidential information based on the first and second signal propagation times. First and second transmission means for transmitting each transmission data to the wireless station at a timing at which the wireless station reaches the wireless station at the same time;
  The structure which comprises is taken.
[0009]
  The data transmission apparatus of the present inventionA data transmission device for wirelessly transmitting transmission data including confidential information to a wireless station, the first and second receiving means disposed at different positions and receiving signals transmitted by the wireless station, Based on each received signal obtained by the first and second receiving means, the first signal propagation time in the first radio propagation path between the radio station and the first receiving means and the radio station The second signal propagation time in the second wireless propagation path between the first wireless propagation path and the second reception means, and the first signal power attenuation amount and the second wireless propagation in the first wireless propagation path An estimation means for estimating the second signal power attenuation amount in the propagation path is disposed at the same position as the first and second reception means, respectively, and is based on the first and second signal propagation times. And second transmission data at the same time Each transmission data is transmitted to the wireless station at a timing when the wireless station arrives at the wireless station, and the wireless station transmits the first and second transmission data based on the first and second signal power attenuation amounts. First and second transmission means for transmitting the first and second transmission data to the radio station with transmission power close to the lowest level that can be demodulated upon combined reception, The two pieces of transmission data have a configuration formed in the same format.
[0010]
  The data transmission apparatus according to the present invention is a data transmission apparatus that wirelessly transmits transmission data including confidential information to a wireless station, and is arranged at different positions and receives a signal transmitted by the wireless station. And a second receiving means and a first radio propagation path between the radio station and the first receiving means based on each received signal obtained by the first and second receiving means. 1 signal propagation time and a second signal propagation time in the second wireless propagation path between the wireless station and the second receiving means, and a first signal in the first wireless propagation path An estimation means for estimating a power attenuation amount and a second signal power attenuation amount in the second radio propagation path; and a first spreading signal obtained by spreading the secret information using a predetermined spreading code. Spreading means and the spreading code Each of the second spreading means using a different spreading code and spreading the pseudo information to obtain a second spreading signal so as to obtain a spreading gain equivalent to the spreading gain by the first spreading means, The first and second receiving means are arranged at the same position, and the first and second spread signals reach the radio station at a time set in advance with the radio station. First and second transmission means for transmitting the first and second spread signals to the radio station at a timing that takes into account the first and second signal propagation times, the first and second The transmission means, based on the first and second signal power attenuation amounts, when the first and second spread signals reach the radio station, the received power value of the first spread signal and the A difference of a certain level or more is generated in the reception power value of the second spread signal. A configuration for controlling the transmission power.
[0011]
  The data transmission apparatus of the present inventionA data transmission apparatus for wirelessly transmitting transmission data including confidential information to a wireless station, wherein a reception means for receiving a signal transmitted by the wireless station, and a received wave based on a reception signal obtained by the reception means The radio propagation path environment between the radio station and the radio station is estimated by detecting the plane of polarization of the radio signal, the estimation means for estimating the arrival direction of the received signal, and the secret information using the predetermined spreading code. By using the first spreading means for forming the first spread signal and a spreading code different from the spreading code, a spreading gain equivalent to the spreading gain by the first spreading means can be obtained. The second spreading means for forming the second spread signal by spreading the pseudo information and the polarization plane detected by the estimating means are predetermined between the radio stations. Transmitting means for transmitting the first and second spread signals to the radio station by a transmission wave having the polarization plane rotated by an amount, and the transmitting means is an arrival estimated by the estimating means Based on the direction, the first and second spread signals are transmitted in a direction in which a difference of a certain level or more occurs between the received power value of the first spread signal and the received power value of the second spread signal, A configuration is adopted in which pseudo data is transmitted in a direction different from that of the wireless station.
[0012]
  The wireless communication system of the present invention is a wireless communication system that wirelessly transmits transmission data including confidential information from a first wireless station to a second wireless station, wherein the first wireless station includes the second wireless station Receiving means for receiving a signal transmitted by a radio station, polarization plane detecting means for detecting the polarization plane of the received wave based on the received signal obtained by the receiving means, and for the detected polarization plane, Transmission means for transmitting transmission data including the confidential information to the second radio station by a transmission wave obtained by rotating the polarization plane by a predetermined amount between the first and second radio stations. The second radio station outputs the polarization plane detection signal to the first radio station and receives the transmission data including the confidential information transmitted by the first radio station. Characteristics of the polarization plane detection signal Between by force until receiving transmission data including the confidential information, a configuration for rotating by a predetermined amount between the first and second radio stations.
[0079]
DETAILED DESCRIPTION OF THE INVENTION
The main point of the present invention is that when wirelessly transmitting transmission data including confidential information from a first wireless station to a second wireless station, the first wireless station and the second wireless station are transmitted before transmitting the confidential information. By performing signal transmission / reception between the first wireless station and the second wireless station, the wireless propagation path environment shared only between the first wireless station and the second wireless station is estimated. The secret information is transmitted from the radio station to the second radio station. As a result, the secret information cannot be restored in other radio stations having different radio propagation path environments.
[0080]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0081]
(Embodiment 1)
In FIG. 1, reference numeral 100 denotes a radio communication system according to Embodiment 1 of the present invention as a whole. The wireless communication system 100 includes a transmitting station 101 and a receiving station 102. Here, the transmitting station 101 and the receiving station 102 simply refer to the side that transmits confidential information as the transmitting station 101, and the side that receives the confidential information as the receiving station 102. Part.
[0082]
The transmission station 101 includes a propagation environment estimation unit 101c and a propagation environment adaptation unit 101d in addition to the transmission unit 101a and the reception unit 101b. The propagation environment estimation unit 101c estimates the propagation environment of the transmission path 103 based on the received signal. The propagation environment adaptation unit 101d controls the transmission operation of the transmission unit 101a according to the estimation result obtained by the propagation environment estimation unit 101c.
[0083]
The reception station 102 includes a time control unit 102c in addition to the transmission unit 102a and the reception unit 102b. The time control unit 102c gives a predetermined delay time to transmission and temporally controls the reception operation with reference to the reception time point of the reception unit 102b.
[0084]
Here, the specific configuration of the transmitting station 101 is shown in FIG. 2, and the specific configuration of the receiving station 102 is shown in FIG. The transmitting station 101 inputs user data D1 to the encryption unit 111 as shown in FIG. The encryption unit 111 receives the encryption key generated by the encryption key generation unit 112 and the reference clock generated by the reference clock generation unit 113 via the control channel unit 114. The encryption unit 111 forms encrypted data by encrypting the user data D1 using the encryption key, and sends this to the burst signal forming unit 115.
[0085]
The burst signal forming unit 115 receives an encryption key and a control channel signal. The burst signal formed by the burst signal forming unit 115 is input to the modulation unit 116. The modulation unit 116 performs predetermined digital modulation processing such as TDMA (Time Division Multiple Access) modulation on the input signal and sends the processed signal to the buffer 117.
[0086]
The buffer 117 outputs the temporarily stored transmission signal to the wireless transmission unit (transmission RF) 119 that continues at the timing of the output control signal input from the timing control unit 118. The wireless transmission unit 119 performs wireless transmission processing such as digital-analog conversion processing and up-conversion on the transmission signal, and supplies the processed signal to the antenna AN11.
[0087]
Here, the timing control unit 118 corresponds to the propagation environment adaptation unit 101 d in FIG. 1 and receives the network reference time from the reference clock generation unit 113 and the transmission delay amount from the delay amount estimation unit 120. Here, the delay amount estimation unit 120 corresponds to the propagation environment estimation unit 101c in FIG.
[0088]
Then, the timing control unit 118 controls the output timing of the buffer 117 in consideration of the network reference time and the transmission delay amount so that the receiving station 102 can receive the confidential information signal at the network reference time set in advance between both stations. To do.
[0089]
The transmitting station 101 transmits the network reference time before transmitting the confidential information, and then transmits the confidential information including the encrypted user data and the encryption key in consideration of the signal propagation time on the transmission path 103. It is supposed to send in.
[0090]
The reception unit 101b of the transmission station 101 inputs the reception signal obtained by the antenna AN11 to the wireless reception unit (reception RF) 121. The wireless reception unit 121 performs wireless processing such as down-conversion and analog-digital conversion processing on the received signal, and sends the processed signal to the demodulation unit 122. The demodulating unit 122 performs predetermined digital demodulation processing such as TDMA demodulation on the input signal, and sends the processed signal to the stream forming unit 123 and the delay amount estimating unit 120.
[0091]
The stream forming unit 123 converts the burst signal into the original data stream by performing processing reverse to that of the burst signal forming unit 115 described above. The decryption unit 124 inputs the data stream and also inputs the encryption key from the encryption key generation unit 112, and decrypts the encrypted data stream using the encryption key.
[0092]
Next, a specific configuration of the receiving station 102 will be described with reference to FIG. As described above, the reception station 102 includes the transmission unit 102a, the reception unit 102b, and the time control unit 102c. The transmission unit 102a inputs the user data D2 to the encryption unit 130. Further, the encryption key extracted by the encryption key extraction unit 131 of the reception unit 102b is input to the encryption unit 130. As a result, the encryption unit 130 encrypts the user data D <b> 2 using an encryption key common to the transmitting station 101.
[0093]
In addition to the encrypted user data, the synchronization signal generated by the synchronization code generation unit 133 is input to the burst signal forming unit 132. The burst signal forming unit 132 converts the encrypted data and the synchronization code into a burst-like transmission signal and sends it to the modulation unit 134. The modulation unit 134 performs predetermined digital modulation such as TDMA modulation on the input signal, and sends the modulated signal to the buffer 135.
[0094]
The buffer 135 outputs the temporarily stored transmission signal to the wireless transmission unit (transmission RF) 136 that follows the timing of the output control signal input from the timing control unit 137 of the time control unit 102c. The wireless transmission unit 136 performs wireless transmission processing such as digital-analog conversion processing and up-conversion on the transmission signal, and supplies the processed signal to the antenna AN12.
[0095]
The receiving unit 102b of the receiving station 102 inputs the received signal obtained by the antenna AN12 to the wireless receiving unit (received RF) 140. Radio receiving section 140 performs radio processing such as down-conversion and analog-digital conversion processing on the received signal, and sends the processed signal to demodulation section 141. The demodulator 141 performs predetermined digital demodulation processing such as TDMA demodulation on the input signal, and sends the processed signal to the stream forming unit 142.
[0096]
The stream forming unit 142 converts the burst signal into the original data stream by performing the reverse process of the burst signal forming unit 132 described above. The decryption unit 143 receives the data stream and the encryption key extracted by the encryption key extraction unit 131, and decrypts the encrypted data stream using the encryption key.
[0097]
Here, the output of the wireless reception unit 140 is also output to the reference clock extraction unit 144. The reference clock extraction unit 144 extracts the control channel signal and the network reference time from the received signal, and sends them to the timing control unit 137 and the timer 145. The timing control unit 137 first synchronizes the operation timing with the control channel signal. Next, the timing control unit 137 transmits a transmission signal by transmitting an output control signal to the buffer 135 after a predetermined time Td with reference to the network reference time. Incidentally, the processing delay generated in the receiving station 102 is adjusted by the time Td.
[0098]
As a result, the transmitting station 101 can calculate the signal propagation time in the transmission path from the network reference time, the delay time Td, and the synchronization code reception time.
[0099]
The timer 145 first synchronizes the operation timing with the control channel signal. Next, the timer 145 sends a control signal for causing the demodulator 141 to start the demodulation operation at the network time Tk. Thus, the receiving station 102 performs reception demodulation at the network time Tk without performing time synchronization (or limiting to a narrow synchronization range).
[0100]
Here, since the synchronization has already been performed on the transmitting station 101 side (that is, the network time Tk itself is the time when the synchronization is established), the receiving station can perform normal demodulation processing at the network time Tk.
[0101]
The encryption key extraction unit 131 receives the data stream from the stream formation unit 142 and the network time information from the timer 145, and extracts the encryption key from the data stream at the network time Tk.
[0102]
In practice, the transmitting station 101 first transmits information including the network reference time formed by the control channel unit 114. In some cases, this transmission is performed a plurality of times. As a result, the receiving station 102 can perform a receiving operation synchronized with high accuracy with respect to the network reference time.
[0103]
When a response signal arrives from the receiving station 102, the transmitting station 101 estimates the signal propagation time in the transmission path 103 from the reception time and the network reference time in the delay amount estimation unit 120. The transmitting station 101 may receive the response signal from the receiving station 102 a plurality of times in order to improve the estimation accuracy (for example, the error is 1 symbol time or less).
[0104]
Further, when transmitting the encryption key, the transmission station 101 transmits to the reception station 102 by the timing control unit 118 so as to reach the network time Tk from the network time Tk at which the reception station starts the reception operation and the propagation delay. Control timing. Accordingly, since the encryption key arrives at the predetermined network time Tk, the receiving station 102 can obtain the encryption key by demodulating the signal in synchronization with the time. Thereafter, the transmitting station 101 uses the encryption key to decrypt the sequentially received encrypted data and transmits the user data D2 while encrypting it.
[0105]
Next, the operation of the wireless communication system 100 according to this embodiment will be described. Communication of the wireless communication system 100 is performed according to the procedure shown in FIG.
[0106]
First, the transmission station 101 transmits a control signal including the network reference time (transmission 1B) as a signal (communication 1) for synchronizing with the reception station 102. When receiving the communication 1 (reception 1T), the receiving station 102 uses the time and the given network reference time as a reference, a delay time (T1) until the next transmission (transmission 2T), and a certain time (T2) The receiving terminal reference time (that is, the network time Tk described above) for the subsequent communication 3 is set. The reception station 102 transmits (transmission 2T) a response signal (communication 2) to the transmission station 101 after a delay time (T1) has elapsed from reception 1T.
[0107]
Incidentally, the transmitting station 101 and the receiving station 102 hold the information of the delay time T1 and the fixed time T2 as shared information in advance.
[0108]
The transmission station 101 receives the communication 2 (reception 2B), and at the same time, the propagation environment estimation unit 101c estimates the propagation path 103 from the control signal output by the transmission 1B and the response signal received by the reception 2B. Specifically, the delay amount estimation unit 120 provided in the transmission station 101 propagates from the time of transmission 1B and reception 2B, the delay time (T1) at the reception station, and the processing delay generated in each device. The signal propagation time on the path 103 is calculated.
[0109]
Here, the processing delay in the apparatus at the transmitting station 101 and the receiving station 102 is almost constant depending on the configuration of the apparatus, and can be handled as known information during system operation. The propagation environment adaptation unit 101d (that is, the timing control unit 118) of the transmission station 101 uses a signal (communication) at a timing synchronized with the reception terminal reference time (that is, the network time Tk) of the reception station 102 from the signal propagation time and the processing delay. 3) is transmitted (transmission 3B).
[0110]
The communication 3 includes confidential information that is not to be leaked to other than the receiving station 102 (in this embodiment, an encryption key). Information of communication 3 is received (received 3T) by the receiving station 102 after being delayed by a time obtained by adding the signal propagation time of the propagation path 103 to the processing delay of the transmitting station 101. The receiving station 102 starts reception 3T and performs demodulation based on the reception terminal reference time set in reception 1T. Thereafter, the transmitting station 101 and the receiving station 102 perform communication after communication 4 while performing encryption and decryption of information using the encryption key transmitted in communication 3.
[0111]
Here, the communication 3 will be described in more detail with reference to FIG. In FIG. 5, the receiving terminal 1 is the receiving station 102 to which the secret information is transmitted by the transmitting station 101, and the receiving terminal 2 is the other terminal.
[0112]
If the time from communication 1 to communication 3 is sufficiently short, the transmission speed of the radio wave is very high with respect to the moving speed of the receiving station (receiving terminal 1) 102. Therefore, the positional relationship between the transmitting station 101 and the receiving station 102 Even if there is a change, the environment of the propagation path 103, particularly the signal propagation time (propagation delay 1) does not change significantly.
[0113]
For example, assuming that it takes 1 second from communication 1 to communication 3, and assuming that the receiving station 102 is moving at 100 [km] per hour, the change in the propagation path delay 1 is about 100 [ns]. For this reason, the reception terminal reference time 1 set by the reception station (reception terminal 1) 102 at reception 1T and the transmission 3B adjusted by the propagation environment adaptation unit 101d of the transmission station 101 are transmitted via the propagation path 103 to the reception station 102. The time of the reception 3T received at is almost synchronized, and there is no need to adjust the time.
[0114]
Thereby, the receiving terminal 1 can restore the communication information by starting reception and demodulation at the receiving terminal reference time 1 and sequentially demodulating the received receiving end 1 communication signal.
[0115]
On the other hand, consider a case where a third party (receiving terminal 2) other than the receiving station (receiving terminal 1) 102 intercepts the communication 3 and tries to restore information. The receiving terminal 2 can receive information between the communication 1 and the communication 2, but the signal of the communication 3 includes reference time information (network time Tk) indicating reception and demodulation start times. Information cannot be restored.
[0116]
This reference time information is calculated by the receiving terminal 1 based on the reception 1T, and the transmitting station 101 estimates the signal propagation time (propagation path delay 1) of the propagation path 103 by the communication 1 and the communication 2 and transmits the signal at the reference time. Is a target time for transmission control so as to reach. This reference time differs depending on the propagation path environment (that is, propagation path). As a result, it is impossible for the receiving terminal 2 to know the correct propagation path delay time 2 in advance or by measuring.
[0117]
Thus, the receiving terminal 2 cannot know the time when the communication 3 is sent. Therefore, the correct receiving terminal reference time 2 cannot be set for the receiving end 2 communication signal. As a result, the information of communication 3 cannot be correctly restored. Thereby, the communication 3 can ensure high security.
[0118]
According to the above configuration, the transmitting station 101 and the receiving station 102 share the same reference time (network reference time) and estimate the signal propagation time between the transmitting station 101 and the receiving station 102. A transmission signal is transmitted at a timing considering the signal propagation time so that the signal is received at the receiving station 102 at time Tk, and the receiving station 102 receives and demodulates the signal transmitted at the network time Tk. Thus, the wireless communication system 100 with high security can be realized.
[0119]
(Embodiment 2)
The wireless communication system according to the present embodiment has the same configuration as that of the wireless communication system 100 according to the first embodiment, except that secret information is rearranged in accordance with a predetermined format. Thereby, the wireless communication system of this embodiment can perform communication with higher security.
[0120]
In practice, the rearrangement of the information order may be performed by the burst signal forming unit 115 (FIG. 2) of the transmitting station 101. Then, the process of returning the rearranged signals to the original state may be performed by the stream forming unit 142 (FIG. 3) of the receiving station 102. Here, it is assumed that the order rearrangement rule is determined only between the transmitting station 101 and the receiving station 102 in advance.
[0121]
Thus, in the wireless communication system of this embodiment, the transmitting station 101 and the receiving station 102 share the same reference time, and the signal propagation time in the transmission path 103 is estimated, and the transmitting station 101 considers the signal propagation time. The transmission signal is transmitted at the timing, and in addition to demodulating the signal received at the network time Tk at the receiving station 102, the transmission data is rearranged in a known format only between stations communicating with each other. Thus, in addition to the effects of the first embodiment, a wireless communication system with higher security can be realized.
[0122]
Incidentally, it is not necessary to limit the format in which the order of information is determined to one, and if a plurality of types of formats are prepared, security for a third party can be further improved.
[0123]
(Embodiment 3)
In addition to the configuration of the first embodiment described above, the wireless communication system according to this embodiment has a configuration in which pseudo information symbols are mixed and transmitted with confidential information symbols. In practice, the process of mixing pseudo symbols with confidential information symbols is performed by burst signal forming sections 115 and 132 (FIGS. 2 and 3). Further, the process of removing the pseudo symbol from the received signal is performed by the stream forming units 123 and 142 (FIGS. 2 and 3). Thereby, the radio | wireless communications system of this Embodiment can improve a security further than the radio | wireless communications system 100 of Embodiment 1. FIG.
[0124]
The operation of the wireless communication system according to this embodiment will be described with reference to FIGS. 4 and 5 used in the first embodiment again.
[0125]
In the wireless communication system of this embodiment, confidential information and pseudo information are arranged in communication 3 (FIG. 4) according to a predetermined format. Here, it is assumed that symbols 0, 2, 5, and 9 in FIG. 5 are pseudo-symbols and others are secret symbols. At this time, the transmitting station sets the regular information in the secret symbol and sets the pseudo information in the pseudo symbol, and transmits the communication 3 (transmission 3T).
[0126]
Information of communication 3 is received (received 3T) by the receiving station 102 after being delayed by a time obtained by adding the signal propagation time of the propagation path 103 to the processing delay of the transmitting station 101. The receiving station 102 starts reception 3T with reference to the reception terminal reference time (network time Tk) set in reception 1T.
[0127]
In the receiving terminal 1, since the symbol 0 of the receiving end 1 communication signal is the same time as the receiving terminal reference time 1, only the secret symbol is extracted by demodulating and decoding by selecting and removing the pseudo symbol according to the format, and demodulating and decoding it. be able to. Thereafter, the transmitting station 101 and the receiving station 102 perform communication after communication 4 while performing encryption based on the information transmitted in communication 3.
[0128]
In the receiving terminal 2, since the symbol 0 of the receiving end 2 communication signal and the receiving terminal reference signal 2 are not at the same time, synchronization necessary for demodulation cannot be obtained. As a result, the received signal cannot be demodulated.
[0129]
In addition to this, even if the received signal can be demodulated and decoded, it is impossible to obtain regular secret data. For example, when performing burst communication, it is possible to estimate the synchronization time from the waveform of the received power, but it is possible for a third party to perform synchronization by inserting a pseudo symbol as in this embodiment. It becomes very difficult. Thereby, the communication 3 can ensure higher security.
[0130]
Thus, according to the above configuration, in addition to the configuration of the first embodiment, pseudo information is mixed and transmitted in the confidential information, thereby realizing a communication system with higher security.
[0131]
(Embodiment 4)
In this embodiment, in addition to mixing pseudo information in confidential information, a synchronization sequence is further mixed and transmitted. This makes it more difficult to restore confidential information at a receiving station that is not the target of transmission of confidential information, whereas the receiving station that is the target of transmission of confidential information uses confidential information to provide confidential information with good reception quality. Obtainable.
[0132]
In practice, the radio communication system according to this embodiment is configured such that the burst signal forming unit 115 of FIG. 2 is configured as shown in FIG. 6, and the demodulating unit 141 and the stream forming unit 142 shown in FIG. By configuring as described above, mixing of pseudo signals and removal of pseudo signals are realized. In this embodiment, only the case where encrypted data is transmitted as confidential information will be described in order to simplify the description.
[0133]
As shown in FIG. 6, the burst signal forming unit 300 of this embodiment inputs the encrypted user data D3 to the burst signal generating circuit 301. The burst signal generation circuit 301 receives the unique word sequence generated by the unique word generation circuit 302 and the pseudo signal sequence generated by the pseudo signal generation circuit 303. The burst signal generation circuit 301 converts the user data series, unique word series, and pseudo signal series into burst signals, and sends the converted signals to the scramble circuit 304.
[0134]
The scramble circuit 304 scrambles the burst signal with the scramble pattern generated by the scramble pattern generation circuit 306, and sends the scrambled signal to the puncture circuit 305. The puncture circuit 305 punctures the scrambled signal with the puncture pattern generated by the puncture pattern generation circuit 307. As a result, as shown in FIG. 6, the signal D4 after the puncture processing is made into a state in which a pseudo signal and a unique word are randomly mixed in the user data and the tooth is missing. The signal D4 after puncture processing is sent to the modulation circuit 116 (FIG. 2). In the puncture process, a specific symbol may be inserted instead of setting the tooth missing state.
[0135]
Next, the configuration of the receiving station that extracts only the user data D3 from the scrambled and punctured signal D4 will be described with reference to FIG. Demodulation circuit 310 inputs received signal D4, which has been subjected to scramble processing and puncture processing, output from radio reception section (reception RF) 140 (FIG. 3) to phase and gain adjustment circuit (phase / gain adjustment) 311. At the same time, it is input to the time synchronization and unique word extraction circuit (time synchronization / unique word extraction) 312.
[0136]
The time synchronization / unique word extraction circuit 312 receives the network time Tk described in the first embodiment from the timer 145, and extracts a unique word sequence from the received signal D4 based on the timing of the network time Tk. The extracted unique word sequence is sent to the frequency synchronization circuit 313 and also sent to the phase and gain detection circuit (phase / gain detection) 314.
[0137]
The frequency synchronization circuit 313 detects a frequency error from the extracted unique word sequence, and sends the frequency information to the phase and gain adjustment circuit (phase / gain adjustment) 311. The phase / gain detection circuit 314 detects the amount of phase rotation and the gain from the unique word sequence, and sends the detection result to the phase / gain adjustment circuit 311. Incidentally, the frequency information detected by the frequency synchronization circuit 313 is also used as a synchronization signal for other circuits.
[0138]
As a result, the phase / gain adjustment circuit 311 can perform phase adjustment and gain adjustment using the phase rotation amount and gain accurately detected based on the unique word sequence, so that the scramble puncture including phase fluctuation and gain fluctuation at the time of transmission can be achieved. The Chua data D4 can be accurately corrected.
[0139]
The scramble puncture data whose phase and gain have been adjusted is sent to the data selector 321 of the stream forming unit 320. The data selector 321 receives the network time Tk from the timer 145 and also receives phase information and signal amplitude information from the phase / gain detection circuit 314. Based on these pieces of information, the bursty signal is returned to the original data stream, and the gap between the signals formed by the puncture process is filled. This data stream is sent to the descrambling circuit 322.
[0140]
The descrambling circuit 322 receives the network time Tk from the timer 145 and also receives a scramble pattern from the scramble pattern generation circuit 323. The scramble pattern generation circuit 323 generates the same scramble pattern as the scramble pattern generation circuit 306 (FIG. 6) of the transmitting station. As a result, the descrambling circuit 322 can remove the pseudo signal sequence and the unique word sequence from the data stream and output only the user data D3.
[0141]
FIG. 8 shows a detailed configuration of the time synchronization / unique word extraction circuit 312. The time synchronization / unique word extraction circuit 312 inputs the scramble puncture data D4 to the convolver circuit 330. Further, the network time Tk from the timer 145 (FIG. 7) is input to the controller 331. The convolver circuit 330 is time-controlled by the controller 331. The correlation value between the unique word sequence extracted from the scrambled puncture data according to the format and the unique word sequence generated by the unique word generation circuit 332 is obtained for a fixed time with the network time Tk as a reference. Incidentally, the unique word generation circuit 332 generates the same unique word sequence as that on the transmitting station side. The convolver circuit 330 sends the correlation value obtained thereby to the peak search circuit 333.
[0142]
The peak search circuit 333 searches for the peak of the correlation value within the search range set by the search range setting circuit 334. The search range setting circuit 334 sets a search range having a predetermined time width centering on a time point after a predetermined time from the network time Tk output from the controller 331. Here, since the receiving station knows in advance the arrangement of the unique word sequence and the pseudo signal sequence, it can also know roughly how much the data of the unique word sequence is demodulated at a time point behind the network time Tk. Accordingly, the search range setting circuit 334 sets a search range centered on this approximate time point.
[0143]
The peak search circuit 333 searches for the peak of the correlation value within the search range. The peak search result is sent to the unique word selection circuit 335. The unique word selection circuit 335 selects a signal sequence corresponding to the correlation value peak as a unique word.
[0144]
FIG. 9 shows the relationship between the correlation value obtained by the convolver circuit 330 and the unique word (synchronization word). FIG. 9A shows an example in which there is one unique word (A in the figure is a unique word). For example, a network reference time is transmitted. In such a case, only one large peak appears, and a search for time synchronization can be performed over a wide range such as a time width T10. That is, when a third party tries to obtain a synchronization signal for the purpose of communication interception, the synchronization signal may be detected relatively easily.
[0145]
On the other hand, the relationship between the correlation integral value obtained by the convolver circuit 330 and the unique word when a signal in which a unique word sequence and a pseudo signal sequence are mixed as in this embodiment is shown in FIG. Shown in (b). Here, it is assumed that the pseudo signal sequence is shifted from the unique word sequence by a predetermined time, and the pseudo signal sequence is a signal sequence having a high correlation with the unique word sequence. As described above with reference to FIG. 6, since the unique word sequence and the pseudo signal sequence have a high correlation, the correlation value output from the convolver circuit 330 shows a high value for the unique word sequence and the pseudo signal sequence. For example, when one unique word sequence and four pseudo signal sequences are present in the scrambling puncture data, a plurality of peaks (five A to E in the figure) appear at substantially equal levels in the correlation value. When the peak of the unique word is C (A, B, D, and E are based on the pseudo signal), the unique word for time synchronization is detected by performing peak search only in the narrow time width T11 in the figure. be able to.
[0146]
That is, in the receiving station of this embodiment, the search range setting unit 334 sets a narrow search range T11 centering on the network time Tk that only the receiving station can know, thereby detecting time synchronization and phase fluctuation. In addition, it is possible to accurately extract a unique word that is a basis for detecting gain fluctuations. By the way, since there is a pseudo signal highly correlated with the unique word in other receiving stations, the distinction between the unique word and the pseudo signal cannot be made, so that time synchronization, phase fluctuation correction and gain correction are correct. It cannot be performed, and it becomes difficult to intercept communication. In this embodiment, a unique word sequence composed of a plurality of symbols is taken as an example, but it may be replaced with a pilot signal composed of one symbol unit.
[0147]
Next, the operation of the wireless communication system of this embodiment will be described with reference to FIG. 10, focusing on the synchronization operation on the receiving station 102 side. That is, since the communication 1 and the communication 2 perform the same operation as that of the first embodiment described above, the description thereof is omitted here.
[0148]
The propagation environment adaptation unit 101d of the transmission station 101 synchronizes with the reception terminal reference time (network time Tk) of the reception station 102 based on the signal propagation time estimated by the propagation environment estimation unit 101c and the processing delay. Communication 3) is transmitted (transmission 3B). In communication 3, based on a preset format, a synchronization sequence, a pseudo-synchronization sequence (the pseudo-signal sequence described above, but in this embodiment, it functions as a pseudo-signal for the synchronization sequence rather than a pseudo-signal for confidential information. The secret information is arranged and transmitted.
[0149]
The communication 3 information is received by the receiving station 102 (receiving 3T) at the receiving terminal reference time after being delayed by the time obtained by adding the signal propagation time to the processing delay time of the transmitting station 101. The receiving station 102 starts reception 3T with reference to the reception terminal reference time set in reception 1T, and extracts a synchronization sequence (unique word sequence) from the received signal based on the format. This is used to synchronize time, frequency, phase, and the like. Thereafter, the confidential information is separated from the received signal received by the reception 3T, and the information is demodulated and decoded. Thereafter, the transmitting station 101 and the receiving station 102 perform communication after communication 4 while performing encryption based on information (for example, an encryption key) transmitted in communication 3.
[0150]
Here, the communication 3 will be described in more detail with reference to FIG. In FIG. 10, symbols 4, 8, and F are assumed to be synchronization sequences, and symbols 3, 7, and E are assumed to be pseudo synchronization sequences. The transmitting station 101 uses the receiving terminal 1 as a receiving station 102 as a transmission destination, and the receiving terminal 2 serves as another terminal.
[0151]
When a frame arranged as shown in FIG. 10 is transmitted, the receiving terminal 1 receives the synchronization sequence almost in synchronization with the receiving terminal reference time 1, and therefore follows the preset format to obtain the synchronization sequence (symbol 4). , 8, F) and pseudo-synchronous sequences (symbols 3, 7, E) can be easily selected and selected.
[0152]
The receiving station 102 synchronizes time, frequency, and phase using this synchronization sequence. Even if the signal received by the receiving terminal 1 (receiving end 1 communication signal) has an error with respect to the receiving terminal reference time 1, if the error is such that the pseudo-synchronous sequence is not erroneously selected, it is corrected by this synchronizing sequence. be able to. Thereby, reception quality can be improved.
[0153]
In addition, when phase information is modulated by a synchronization sequence, phase synchronization can also be performed, so that synchronous detection or similar detection can be performed on the information transmitted at the same time. Communication with higher quality than the communication method described in 1 can be performed.
[0154]
On the other hand, the receiving terminal 2 cannot know the time when the communication 3 is sent and cannot detect a correct synchronization sequence for the receiving end 2 communication signal. For example, if a sequence similar to or the same as the synchronization sequence is used for the pseudo-synchronization sequence, the receiving terminal 2 uses the pseudo-synchronization sequence (symbols 3, 7, E) close to the receiving terminal reference time 2 to synchronize. Become. As a result, the information transmitted by communication 3 cannot be correctly demodulated and decoded. Thereby, the communication 3 can ensure high security.
[0155]
Thus, according to the above configuration, in addition to the configuration of the first embodiment, the synchronization side and the pseudo synchronization sequence are mixed in the confidential information on the transmission side, so that the security can be further improved and the reception quality can be improved. A wireless communication system can be realized.
[0156]
Incidentally, in this embodiment, since the receiving station 102 starts demodulation and decoding of the received signal with reference to the receiving terminal reference time 1, the transmitting station 101 does not need to set a frame format or the like in advance. A pseudo symbol can be arbitrarily added before 0 or after symbol 9. By doing so, since the burst length becomes variable, it becomes difficult to estimate the position of the synchronization sequence from the shape of the signal amplitude, and the secrecy from a third party can be further enhanced. Furthermore, if the amplitude of the symbol inserted by the puncture circuit 305 is changed, the estimation from the shape of the signal amplitude can be made more difficult.
[0157]
(Embodiment 5)
In FIG. 11, in which parts corresponding to those in FIG. 1 are assigned the same reference numerals, 500 indicates a wireless communication system according to Embodiment 5 of the present invention as a whole. The wireless communication system 500 has substantially the same configuration as the wireless communication system 100 of the first embodiment described above except that the transmission station 501 has two transmission units 502 and 503.
[0158]
That is, the transmission station 501 of the wireless communication system 500 includes a propagation environment estimation unit 101c, a propagation environment adaptation unit 101d, a first transmission unit 502, a second transmission unit 503, and a reception unit 101b. Actually, the first transmitter 502 and the second transmitter 503 do not have the transmitter 101a as shown in FIG. 2, but two antennas are arranged at different positions, and the signal processing is the same as that of the transmitter 101a. This processing is performed by one processing unit having the configuration described above. The receiving station 102 includes a transmitting unit 102a, a receiving unit 102b, and a time control unit 102c. Communication is performed through the first transmission path 504 and the second transmission path 505 in the communication procedure shown in FIG.
[0159]
First, the transmitting station 501 transmits (transmits 10B) a control signal (communication 10) including the network reference time while controlling the output from the first transmitting unit 502 so as to pass through the first propagation path 504. When receiving the communication 10 (reception 10T), the receiving station 102 receives a delay time (T10) until the next transmission (transmission 20T) and the reception of the next communication 30 after a certain time (T20) with reference to the time. Terminal reference time 10 is set. The reception station 102 transmits (transmission 20T) a response signal (communication 20) to the transmission station 501 after a delay time (T10) has elapsed from the reception 10T.
[0160]
Incidentally, the transmitting station 501 and the receiving station 102 hold the information of the delay time T10 and the fixed time T20 and the information of the delay time T11 and the fixed time T21 described later as shared information in advance.
[0161]
The transmission station 501 receives the communication 20 (reception 20B), and at the same time, the propagation environment estimation unit 101c estimates the state of the first propagation path 504 from the control signal transmitted by the transmission 10B and the response signal received by the reception 20B. Specifically, the delay amount estimation unit provided in the transmission station 501 propagates from the time of transmission 10B and reception 20B, the delay time (T10) at the reception station 102, and the processing delay generated in each device. The signal propagation time on the path 504 is calculated. Incidentally, the processing up to this point is the same as the processing described in the first embodiment.
[0162]
Similarly, the transmitting station 501 transmits (transmits 11B) a signal (communication 11) from the second transmitting unit 503 while controlling the output so as to pass through the second propagation path 505. When receiving the communication 11 (reception 11T), the receiving station 102 receives the delay time (T11) until the next transmission (transmission 21T) and the reception of the next communication 31 after a certain time (T21) based on the time. Terminal reference time 20 is set. The reception station 102 transmits (transmission 21T) a response signal (communication 21) to the transmission station 501 after a delay time (T11) has elapsed from reception 20T.
[0163]
The transmission station 501 receives the communication 21 (reception 21B), and at the same time, the propagation environment estimation unit 101c receives the second propagation path 505 from the signal (communication 11) transmitted by the transmission 11B and the response signal (communication 21) received by the reception 21B. Is estimated. Specifically, the delay amount estimation unit provided in the transmission station 501 propagates from the time of transmission 11B and reception 21B, the delay time (T11) at the reception station 102, and the processing delay generated in each device. The signal propagation time in the path 505 is calculated.
[0164]
The propagation environment adaptation unit 101d of the transmission station 501 sends a signal (communication 30) to the first transmission unit 502 in synchronization with the reception terminal reference time 10 of the reception station 102 from the signal propagation time and processing delay of the first propagation path 504. To transmit via the first propagation path 504 while controlling the output (transmission 30B).
[0165]
Similarly, the propagation environment adaptation unit 101d of the transmission station 501 transmits the signal (communication 31) to be synchronized with the reception terminal reference time 20 of the reception station 102 from the signal propagation time of the second propagation path 505 and the processing delay. 2 Transmitting (transmitting 31B) while controlling the output from the transmitting unit 503 via the second propagation path 505.
[0166]
Here, the communication 30 and the communication 31 include confidential information such as an encryption key. Information of the communication 30 is received by the receiving station 102 (reception 30T) after being delayed by a time obtained by adding the signal propagation time in the first propagation path 504 to the processing delay of the transmission station 501. Similarly, the information of the communication 31 is also received (received 31T) by the receiving station 102 after being delayed by the time obtained by adding the signal propagation time in the second propagation path 505 to the processing delay.
[0167]
The reception station 102 starts reception 30T and reception 31T with reference to the reception terminal reference time 10 and reception terminal reference time 20 set in reception 10T and reception 11T, and demodulates and decodes reception data. Thereafter, the transmitting station 501 and the receiving station 102 perform communication after communication 4 while performing encryption and decryption based on information (encryption key) transmitted by the communication 30 and communication 31.
[0168]
The communication 30 and the communication 31 will be described in more detail with reference to FIG. In FIG. 13, the transmitting station 501 uses the receiving terminal 1 as the receiving station 102 as the transmission destination and the receiving terminal 2 as the other terminals.
[0169]
If the time from communication 10 and communication 11 to communication 30 and communication 31 is sufficiently short, the propagation speed of the radio wave is very high with respect to the moving speed of the receiving station (receiving terminal 1) 102. Even if there is a change in the positional relationship between the stations 102, there is no significant change in the propagation path environment, particularly the delays of the first propagation path 504 and the second propagation path 505 (the propagation path delay 10 and the propagation path delay 20).
[0170]
Therefore, the receiving station reference time 10 and the receiving terminal reference time 20 set by the receiving station (receiving terminal 1) 102 at the receiving 10T and the receiving 11T, respectively, and the transmission 30B adjusted by the propagation environment adaptation unit 101d of the transmitting station 501; The transmission 31B is substantially synchronized with the receiving terminal reference times 10 and 20 received by the receiving station 201 via the propagation paths 504 and 505, and it is not necessary to adjust the time.
[0171]
Therefore, the receiving terminal 1 sequentially demodulates the received receiving end 1 communication signal with respect to the communication 30 with reference to the receiving terminal reference time 10 and with respect to the communication 31 with respect to the receiving terminal reference time 20. The secret information can be restored.
[0172]
On the other hand, a case where a third party (receiving terminal 2) who is not a transmission destination intercepts the communication 30 and the communication 31 and tries to restore information will be considered. The receiving terminal 2 can receive the information of the communication 10, the communication 11, the communication 20, and the communication 21, but the signals of the communication 30 and the communication 31 include the receiving terminal reference times 10 and 20 indicating the start of communication. Because it is not included, confidential information cannot be restored.
[0173]
This reference time information is calculated based on the reception 10T and 11T by the reception terminal 1, and the transmission station 501 uses the communication 10, 11, 20, and 21 to transmit the first and second propagation paths 504 and 505 to the signal propagation time (propagation time). This is a target time for estimating transmission delay 10 and 20) and controlling transmission so that the signal reaches the reference time. This reference time differs depending on the propagation path environment (that is, propagation path). As a result, the correct propagation path delay times 10 and 20 cannot be known by the receiving terminal 2 in advance or by measurement.
[0174]
Therefore, the receiving terminal 1 communication signal received by the receiving terminal 1 reaches the scheduled time set by the receiving terminal 1 for both the communication 30 and the communication 31, so that the receiving terminal 1 can restore the receiving end 1 communication signal. On the other hand, the receiving terminal 2 that receives a signal from the transmitting station 501 through a different propagation path from the first propagation path 504 and the second propagation path 505 cannot receive the receiving end 2 communication signal synchronously.
[0175]
In addition, the receiving terminal 2 cannot know the correct propagation path delay time 11 and propagation path delay time 21 in advance or by measurement. Thereby, the receiving terminal 2 cannot know the arrival times of the communication 30 and the communication 31. As a result, the correct receiving terminal reference time 11 and receiving terminal reference time 21 cannot be set for the receiving end 2 communication signal, and it is almost impossible to receive the communication 30 and the communication 31 correctly.
[0176]
In particular, if confidential information is distributed and transmitted to the transmission unit 502 and the transmission unit 503, a remarkable effect can be obtained in terms of security.
[0177]
Thus, according to the above configuration, in addition to the configuration of the first embodiment, a plurality of transmission units 502 and 503 are provided on the transmission side to form a plurality of propagation paths 504 and 505, and each propagation path 504, Since the confidential information reaches the predetermined time (reception terminal reference time 10, 20) of the receiving station 201 via 505, the wireless communication system 500 with higher security can be realized.
[0178]
(Embodiment 6)
In this embodiment, the transmission data transmission / reception is performed at a timing that can be known only by the stations communicating with each other proposed in the first embodiment, and the communication proposed in the second embodiment is performed. A configuration in which transmission data is rearranged in a known format only between stations, a configuration in which pseudo-symbols are mixed in communication information proposed in the third embodiment, and communication via a plurality of propagation paths proposed in the fifth embodiment A wireless communication system combined with a configuration for performing is proposed. In addition to such a configuration, unlike the fifth embodiment, the radio communication system according to this embodiment receives and synthesizes signals passing through two propagation paths at the same time.
Hereinafter, the communication method of this embodiment will be described with reference to FIGS.
[0179]
Here, the outline from communication 10 to communication 21 in FIG. 12 is the same as the contents described in the fifth embodiment. That is, the transmission station 501 and the reception station 102 estimate the signal propagation time in the first and second propagation paths 504 and 505 and synchronize the operation between the two stations by communication from the communication 10 to the communication 21. Set network reference time and receiving terminal reference time.
[0180]
That is, first, the transmitting station 501 transmits (transmits 10B) a control signal (communication 10) including the network reference time while controlling the output from the first transmitting unit 502 so as to pass through the first propagation path 504. When receiving the communication 10 (reception 10T), the receiving station 102 receives a delay time (T10) until the next transmission (transmission 20T) and the reception of the next communication 30 after a certain time (T20) with reference to the time. Terminal reference time 10 is set. The reception station 102 transmits (transmission 20T) a response signal (communication 20) to the transmission station 501 after a delay time (T10) has elapsed from the reception 10T.
[0181]
The transmission station 501 receives the communication 20 (reception 20B), and at the same time, the propagation environment estimation unit 101c estimates the state of the first propagation path 504 from the control signal transmitted by the transmission 10B and the response signal received by the reception 20B. Specifically, the delay amount estimation unit provided in the transmission station 501 propagates from the time of transmission 10B and reception 20B, the delay time (T10) at the reception station 102, and the processing delay generated in each device. The signal propagation time on the path 504 is calculated.
[0182]
Similarly, the transmitting station 501 transmits (transmits 11B) a signal (communication 11) from the second transmitting unit 503 while controlling the output so as to pass through the second propagation path 505. When receiving the communication 11 (reception 11T), the receiving station 102 receives the delay time (T11) until the next transmission (transmission 21T) and the reception of the next communication 31 after a certain time (T21) based on the time. Terminal reference time 20 is set.
[0183]
In the case of this embodiment, unlike the above-described fifth embodiment, this receiving terminal reference time 20 is set to the same time as the receiving terminal reference time 10.
[0184]
The reception station 102 transmits (transmission 21T) a response signal (communication 21) to the transmission station 501 after a delay time (T11) has elapsed from reception 20T.
[0185]
The transmission station 501 receives the communication 21 (reception 21B), and at the same time, the propagation environment estimation unit 101c receives the second propagation path from the control signal (communication 11) transmitted by the transmission 11B and the response signal (communication 21) received by the reception 21B. The state of 505 is estimated. Specifically, the delay amount estimation unit provided in the transmission station 501 propagates from the time of transmission 11B and reception 21B, the delay time (T11) at the reception station 102, and the processing delay generated in each device. The signal propagation time in the path 505 is calculated.
[0186]
The propagation environment adaptation unit 101d of the transmission station 501 sends a signal (communication 30) to the first transmission unit 502 in synchronization with the reception terminal reference time 10 of the reception station 102 from the signal propagation time and processing delay of the first propagation path 504. To transmit via the first propagation path 504 while controlling the output (transmission 30B).
[0187]
Similarly, the propagation environment adaptation unit 101d of the transmission station 501 transmits the signal (communication 31) to be synchronized with the reception terminal reference time 20 of the reception station 102 from the signal propagation time of the second propagation path 505 and the processing delay. 2 Transmitting (transmitting 31B) while controlling the output from the transmitting unit 503 via the second propagation path 505.
[0188]
Here, the communication 30 and the communication 31 include confidential information such as an encryption key. Information of the communication 30 is received by the receiving station 102 (reception 30T) after being delayed by a time obtained by adding the signal propagation time in the first propagation path 504 to the processing delay of the transmission station 501. Similarly, the information of the communication 31 is also received (received 31T) by the receiving station 102 after being delayed by the time obtained by adding the signal propagation time in the second propagation path 505 to the processing delay.
[0189]
The receiving station 102 starts receiving 30T and 31T with reference to the receiving terminal reference times 10 and 20. At this time, since the receiving terminal reference times 10 and 20 of the communication 30 and the communication 31 are set at the same time, transmission data from the transmitting station 501 is received by the receiving station 102 at the same time.
[0190]
As a result, the communication 30 and the communication 31 interfere with each other at the receiving station 102, and the combined result is received at the receiving station 102. Here, the communication information of the communication 30 and the communication 31 is configured by mixing information symbols (confidential information) and pseudo symbols according to a preset format.
[0191]
First, in order to simplify the explanation, it is assumed that all the pseudo symbols are symbols with power 0. With reference to the receiving terminal reference time 10 of the receiving station 102, only the symbol at the time when the pseudo symbol of the communication 31 overlaps among all the symbols of the communication 30 is not affected by the interference of the communication 31. Conversely, only the symbols at the time when the pseudo symbols of communication 30 overlap among all the symbols of communication 31 are not affected by interference of communication 30.
[0192]
Therefore, if a format in which both information symbols do not interfere with each other is set in advance, a signal free from degradation due to interference can be received from both communication 30 and communication 31. The receiving station 102 demodulates and decodes the reception signal synthesized in this way.
[0193]
The communication 30 and communication 31 of this embodiment will be described in more detail with reference to FIG. In FIG. 14, symbols 0, 3, 6, 7, and 9 and symbols B, C, E, F, and I are assumed to be pseudo symbols. The transmitting station 501 uses the receiving terminal 1 as a receiving station 102 as a transmission destination, and the receiving terminal 2 serves as another terminal.
[0194]
Here, the receiving station reference time 10 set by the receiving station (receiving terminal 1) 102 at the receiving 10T and the receiving 11T, the transmission 30B and the transmission 31B whose timing is adjusted by the propagation environment adaptation unit 101d of the transmitting station 501 are the propagation paths 504. , 505, and the time received by the receiving station 102 are almost synchronized with each other, and the communication 30 and the communication 31 are received at the same time, so that the reception end 1 communication signals interfere with each other.
[0195]
In FIG. 14, symbols 1, 2, 4, 5, and 8 are combined with symbols B, C, E, F, and I, respectively, and symbols A, D, G, H, and J are combined with symbols 0, 3, 6, 7, 9 is synthesized. However, since symbols 0, 3, 6, 7, and 9 and symbols B, C, E, F, and I are pseudo-symbols and their power is 0, the combined reception end 1 communication signal is A, 1 2, D, 4, 5, G, H, 8, and J.
[0196]
Since all these information symbols are not interfered with each other by communication, communication information (confidential information) can be acquired by sequentially demodulating the received reception end 1 communication signal.
[0197]
On the other hand, a case where a third party (receiving terminal 2) who is not a transmission destination intercepts the communication 30 and the communication 31 and tries to restore information will be considered. The receiving terminal 2 can receive the communication 10, the communication 11, the communication 20, and the communication 21, but the communication 30 and the communication 31 are controlled to be received by the receiving terminal 1 at the same time. The terminal 2 receives the signals at different timings. Therefore, the receiving terminal 2 does not know the receiving terminal reference time 10 indicating the start of communication, and the information symbols interfere with each other, so that the confidential information cannot be restored.
[0198]
This reference time information is calculated based on the reception 10T and 11T by the reception terminal 1, and the transmission station 501 uses the communication 10, 11, 20, and 21 to transmit the first and second propagation paths 504 and 505 to the signal propagation time (propagation time). This is a target time for estimating transmission delay 10 and 20) and controlling transmission so that the signal reaches the reference time. This reference time differs depending on the propagation path environment (that is, propagation path). As a result, the receiving terminal 2 cannot know the correct propagation path delay time 10 in advance or by measurement.
[0199]
Therefore, the receiving terminal 1 communication signal received by the receiving terminal 1 reaches the scheduled time set by the receiving terminal 1 for both the communication 30 and the communication 31, so that the receiving terminal 1 can restore the receiving end 1 communication signal. On the other hand, the receiving terminal 2 that receives a signal from the transmitting station 501 through a different propagation path from the first propagation path 504 and the second propagation path 505 cannot receive the receiving end 2 communication signal synchronously.
[0200]
In addition, the receiving terminal 2 cannot know the correct propagation path delay time 11 and propagation path delay time 21 in advance or by measurement. Thereby, the receiving terminal 2 cannot know the arrival times of the communication 30 and the communication 31. As a result, the correct receiving terminal reference time 11 cannot be set for the receiving end 2 communication signal, and it is almost impossible to correctly receive the communication 30 and the communication 31.
[0201]
Further, in the communication method of this embodiment, even if the correct propagation path delay time 11 can be measured by the receiving terminal 2 (third party) and the correct receiving terminal reference time 11 can be set for the communication 30, Confidential information cannot be restored. This is because the communication 31 reaches the reception terminal 2 at a time different from the reception terminal reference time 11 in the reception terminal 2 located at a different location from the reception terminal 1. As a result, the signal of the communication 30 and the signal of the communication 31 cause interference at the time of reception, and the signal deteriorates.
[0202]
In this embodiment, on the assumption that the communication 30 and the communication 31 reach the receiving station at the same time, a format in which information symbols do not overlap when the head of the signal of the communication 30 and the head of the signal of the communication 31 coincide with each other. The information symbol and the pseudo symbol are arranged. As a result, at the receiving station that cannot receive the communication 30 and the communication 31 at the same time, intersymbol interference occurs and the signal deteriorates.
[0203]
Specifically, in the receiving end 2 communication signal of FIG. 14, information symbols 2 and A, 5 and D, 8 and G, etc. of communication 30 and communication 31 cause interference with each other. As a result, the signal deteriorates due to mutual interference of symbols, and the information symbol cannot be restored.
[0204]
Thus, according to the above configuration, the transmission timings of the two transmission units 502 and 503 of the transmission station 501 are controlled so that the two signals are received by the reception station 102 at the same time, and are not received at the same time. Information symbols (confidential information) of the two signals are arranged and transmitted in a format that deteriorates due to mutual interference, so that the information symbol (confidential information) is transmitted to a location other than the location of the receiving station 102 to which the confidential information is transmitted. It is impossible to restore confidential information at the receiving station. As a result, a wireless communication system with further improved security can be realized.
[0205]
(Embodiment 7)
In this embodiment, in addition to the configuration of the sixth embodiment, there is a configuration in which synchronization sequence data is mixed with confidential information and transmitted. Examples of the synchronous sequence data include the unique word described in the first embodiment. Thereby, in this embodiment, in addition to the effects of Embodiment 6, it is possible to improve the reception quality at the receiving station that is the transmission target of the confidential information.
[0206]
This embodiment will be described with reference to FIGS. 11, 12, and 14. FIG. The data transmitted by the communication 30 and the communication 31 is confidential data that is not desired to be leaked to a receiving station other than the receiving station 102 to which confidential information is to be transmitted. Symbols are arranged and configured.
[0207]
The information on the communication 30 is received by the receiving station 102 at the receiving terminal reference time 10 (received 30T) after being delayed by the time obtained by adding the signal propagation time of the first propagation path 504 to the processing delay of the transmitting station 501. Similarly, the information of the communication 31 is also received by the receiving station 102 at the receiving terminal reference time 10 after being delayed by a time obtained by adding the signal propagation time of the second propagation path 505 to the processing delay of the transmitting station 501. The receiving station 102 starts reception 30T with reference to the receiving terminal reference time 10.
[0208]
At this time, since the receiving terminal reference time 10 for the communication 30 and the communication 31 is set at the same time, the communication 30 and the communication 31 are received simultaneously at the receiving station 102. Therefore, both are combined in space and received by the receiving station 102.
[0209]
On the other hand, the data of communication 30 and communication 31 has a configuration in which information symbols, pseudo symbols, and synchronization sequences are arranged according to a preset format. Here, to simplify the explanation, it is assumed that all the pseudo symbols are symbols with power 0. With reference to the receiving terminal reference time 10 of the receiving station 102, only the symbol at the time when the pseudo symbol of the communication 31 overlaps among all the symbols of the communication 30 is not affected by the interference of the communication 31. Conversely, only the symbols at the time when the pseudo symbols of communication 30 overlap among all the symbols of communication 31 are not affected by interference of communication 30.
[0210]
As described above, assuming that two signals from the communication 30 and the communication 31 are received by the transmitting station 501 at the same time in advance, the formats are set so that they do not interfere with each other. At the same time, the receiving station 102 can receive a signal that is not deteriorated due to interference between both signals.
[0211]
When receiving these signals, the receiving station 102 first demodulates the information symbols of the communication 30 by synchronizing the time, frequency, phase and the like with the symbols of the communication 30 using the synchronization sequence of the communication 30. Similarly, the receiving station 102 synchronizes the time, frequency, phase, and the like with the symbols of the communication 31 using the synchronization sequence of the communication 31, and demodulates the information symbols of the communication 31.
[0212]
Next, the two demodulated information symbols are combined and decoded. Thereafter, the transmitting station 501 and the receiving station 102 perform communication after communication 4 while performing encryption and decryption based on information (for example, encryption key) transmitted by the communication 30 and communication 31.
[0213]
The communication 30 and communication 31 of this embodiment will be described in more detail with reference to FIG. In FIG. 14, symbols 0, 3, 6, 7, and 9 and symbols B, C, E, F, and I are pseudo-symbols, symbols 1 and 8 and symbols A and G are synchronous sequences, and symbols 2, 4 5, D, H, and J are information symbols.
[0214]
Here, the receiving station reference time 10 set by the receiving station (receiving terminal 1) 102 at the receiving 10T and the receiving 11T, the transmission 30B adjusted by the propagation environment adaptation unit 101d of the transmitting station 501, and the transmission 31B are the propagation paths 504, The time of reception 30T and reception 31T received by the receiving station 102 via 505 is almost synchronized. As a result, since the communication 30 and the communication 31 are received at the same time, the reception end 1 communication signal interferes with each other.
[0215]
In FIG. 14, symbols 1, 2, 4, 5, and 8 and symbols B, C, E, F, and I are synthesized according to the format, and symbols A, D, G, H, and J, and symbols 0, 3, 6 are combined. , 7 and 9 are combined, but symbols 0, 3, 6, 7, and 9 and symbols B, C, E, F, and I are pseudo symbols and their power is 0. One communication signal is A, 1, 2, D, 4, 5, G, H, 8, J.
[0216]
Since all information symbols and synchronization sequences are not interfered with each other in this way, communication information including confidential information can be restored by sequentially demodulating the received reception end 1 communication signal.
[0217]
Thus, according to the above configuration, in addition to the configuration of the sixth embodiment, the synchronization sequence data is mixed in the transmission data including the confidential information. The station 102 can realize a wireless communication system that can further improve the reception quality.
[0218]
(Embodiment 8)
In FIG. 15, reference numeral 800 generally indicates a radio communication system according to the eighth embodiment of the present invention. The wireless communication system 800 includes first and second transmission stations 801 and 802, and the transmission stations 801 and 802 are connected to a network 805 via network connection units 803 and 804. The first transmitting station 801 communicates with the receiving station 102 via the first propagation path 806, and the second transmitting station 802 communicates with the receiving station 102 via the second propagation path 807.
[0219]
Here, the configuration of each of the first and second transmission stations 801 and 802 is substantially the same as that of the transmission station 101 described in Embodiment 1, except that the network connection units 803 and 804 are provided. The receiving station 102 has substantially the same configuration as that of the receiving station 102 described in Embodiment 1 except that the receiving station 102 communicates with the second transmitting station 802 in addition to the first transmitting station 801.
[0220]
Furthermore, the first and second transmitting stations 801 and 802 transmit transmission data including confidential information at the timing when the receiving terminal reference time set by the receiving station is reached, and as described in the sixth embodiment, The transmission data is transmitted at the timing so that the same reception terminal reference time is reached.
[0221]
That is, when the wireless communication system 800 of this embodiment is compared with the wireless communication system described in the sixth embodiment, the wireless communication system of the sixth embodiment receives the receiving station 102 from the same transmitting station via a different propagation path. However, the wireless communication system 800 is different in that information is transmitted from different transmitting stations 801 and 802 to different receiving stations 102 via different propagation paths 806 and 807.
[0222]
Here, the communication 800 of the wireless communication system is performed through the first propagation path 806 and the second propagation path 807 in the communication procedure as shown in FIG.
[0223]
The first transmitting station 801 transmits (transmits 10B) a control signal (communication 10) including the network reference time while controlling the output from the transmitting unit 101a so as to pass through the first propagation path 806. When receiving the communication 10 (reception 10T), the receiving station 102 sets a predetermined delay time (T10) controlled by the time control unit 102c. The reception station 102 transmits (transmission 20T) a response signal (communication 20) to the first transmission station 801 after a delay time (T10) has elapsed from the reception 10T.
[0224]
Incidentally, the transmitting station 801 and the receiving station 102 hold the delay time T10 as shared information in advance.
[0225]
The first transmission station 801 receives the communication 20 (reception 20B), and at the same time, the propagation environment estimation unit 101c determines the first propagation path 806 from the control signal (communication 10) transmitted by the transmission 10B and the response signal received by the reception 20B. Estimate the state. Specifically, the propagation environment estimation unit 101c provided in the transmission station 801 uses the time of transmission 10B and reception 20B, the delay time (T10) at the reception station 102, the processing delay generated in each device, and the like. The signal propagation time in the first propagation path 806 is calculated.
[0226]
Similarly, the second transmitting station 802 transmits (transmits 11B) a control signal (communication 11) including the network reference time while controlling the output from the transmitting unit 101a so as to pass through the second propagation path 807. When receiving the communication 11 (reception 11T), the receiving station 102 sets a predetermined delay time (T11) controlled by the time control unit 102c. The reception station 102 transmits (transmission 21T) a response signal (communication 21) to the second transmission station 802 after a delay time (T11) has elapsed from reception 11T.
[0227]
Incidentally, the transmitting station 802 and the receiving station 102 hold the delay time T11 as shared information in advance.
[0228]
The second transmission station 802 receives the communication 21 (reception 21B), and at the same time, the propagation environment estimation unit 101c uses the control signal (communication 11) transmitted by the transmission 11B and the response signal received by the reception 21B. Estimate the state. Specifically, the propagation environment estimation unit 101c provided in the transmission station 802 is based on the transmission 11B and reception 21B times, the delay time (T11) in the reception station 102, the processing delay generated in each device, and the like. The signal propagation time in the second propagation path 807 is calculated.
[0229]
As described above, when the estimation of the signal propagation time between the first transmitting station 801 and the receiving station 102 and the signal propagation time between the second transmitting station 802 and the receiving station 102 are completed, the receiving station 102 next determines the time control unit 102c. Is used to set the receiving terminal reference signal 10 after a certain time (T20), and transmit (transmit 30T) a reference time notification signal (communication 30) to the first transmitting station 801 and the second transmitting station 802. .
[0230]
The first transmitting station 801 acquires confidential information to be transmitted to the receiving station 102 from the network 805 via the network connection unit 803. Similarly, the second transmitting station 802 acquires confidential information to be transmitted to the receiving station 102 from the network 805 via the network connection unit 804.
[0231]
When the first transmission station 801 receives the communication 30 (reception 30B), the propagation environment adaptation unit 101d of the first transmission station 801 receives the signal from the signal propagation time of the first propagation path 806, the processing delay, and the time of reception 30B. The transmission timing of the communication 40 is controlled so as to reach the receiving terminal reference time 10 of the station 102. The first transmitting station 801 transmits (transmits 40B) the signal (communication 40) from the transmitting unit 101a via the first propagation path 806.
[0232]
Similarly, when the second transmission station 802 receives the communication 30 (reception 31B), the propagation environment adaptation unit 101d of the second transmission station 802 determines the signal propagation time of the second propagation path 807, the processing delay, and the time of reception 31B. Then, the transmission timing of the communication 40 is controlled so as to reach the receiving terminal reference time 10 of the receiving station 102. The second transmitting station 802 transmits (transmits 41B) a signal (communication 41) from the transmitting unit 101a via the second propagation path 807.
[0233]
Information of the communication 40 is received by the receiving station 102 at the receiving terminal reference time 10 (received 40T) after being delayed by a time obtained by adding the signal propagation time of the first propagation path 806 to the processing delay of the first transmitting station 801. . Similarly, the information of the communication 41 is also received by the receiving station 102 at the receiving terminal reference time 10 after being delayed by the time obtained by adding the signal propagation time of the second propagation path 807 to the processing delay of the second transmitting station 802. The receiving station 102 starts reception 40T with reference to the receiving terminal reference time 10.
[0234]
At this time, since the receiving terminal reference time 10 of the communication 40 and the communication 41 is set at the same time, the communication 40 and the communication 41 are received at the receiving station 102 at the same time. That is, both are received by the receiving station 102 as a combined result.
[0235]
Here, the data transmitted by communication 40 and communication 41, when transmitted at the same time as in the transmission data of the seventh embodiment, causes information symbols, pseudo symbols and synchronization sequence symbols to interfere with each other. They are arranged so that they do not fit together. As a result, as in the seventh embodiment, the contents of the communication 40 and the communication 41 can be demodulated and decoded only by the receiving station 102. Incidentally, if the first half of the communication 40 is set as a pseudo-symbol and the second half of the communication 41 is set as a pseudo-symbol (or provided at the arrival times of the communication 40 and the communication 41 at regular intervals), the receiving station 102 can And the information from the second receiving stations 801 and 802 can be continuously received.
[0236]
Thus, according to the above configuration, the confidential information is divided into a plurality of information blocks, and the divided confidential information is distributed to a plurality of transmitting stations using a high-security communication line such as a dedicated line. By transmitting to the receiving station, it is possible to realize a wireless communication system 800 that can transmit confidential information with higher security.
[0237]
(Embodiment 9)
In FIG. 17, in which parts corresponding to those in FIG. 1 are assigned the same reference numerals, 900 denotes a wireless communication system according to Embodiment 9 of the present invention as a whole. The wireless communication system 900 includes first and second transmission / reception units 902 and 903 each including the transmission unit 101a and the reception unit 101b described above with reference to FIG. The first transmission / reception unit 902 communicates with the reception station 102 via the first propagation path 906, and the second transmission / reception unit 903 communicates with the reception station 102 via the second propagation path 907.
[0238]
Here, the communication operation between the transmitting station 901 and the receiving station 102 estimates the received power received by the transmitting station 901 via the first and second propagation paths 906 and 907 and the estimated power, as will be described later. 11 is the same as that of the wireless communication system 500 according to the fifth embodiment described with reference to FIG. 11 except that the transmission power is controlled in response to the signal transmission to the receiving station 102.
[0239]
FIG. 18 shows a detailed configuration of the transmitting station 901 according to this embodiment. In FIG. 18, parts corresponding to those in FIG. In the case of this embodiment, the propagation environment estimation unit 904 includes a delay amount estimation unit 904a and a power measurement unit 904b. The propagation environment adaptation unit 905 includes a timing control unit 905a and a power control unit 905b.
[0240]
Then, a known signal such as a unique word extracted by the demodulation unit 122 of the first transmission / reception unit 902 is input to the delay amount estimation unit 904a and extracted by a demodulation unit (not shown) of the second transmission / reception unit 903. A known signal such as a unique word is input to the delay amount estimation unit 904a. The delay amount estimation unit 904a estimates the signal propagation time from the network time and the known signal as described in the first embodiment. In the case of this embodiment, the signal propagation times of the first and second propagation paths 906 and 907 are estimated.
[0241]
Then, the signal from the first transmission / reception unit 902 is determined in advance via the first propagation path 906 in consideration of the signal propagation time of the first propagation path 906 obtained by the delay amount estimation unit 904a. The output timing of the buffer 117 is adjusted so as to reach the receiving station 102 at the network time.
[0242]
Similarly, the timing control unit 905a determines in advance the signal from the second transmission / reception unit 903 via the second propagation path 907 in consideration of the signal propagation time of the second propagation path 907 obtained by the delay amount estimation unit 904a. The output timing of a buffer (not shown) is adjusted so as to reach the receiving station 102 at the specified network time.
[0243]
The power measurement unit 904 b of the propagation environment estimation unit 904 receives the output of the wireless reception unit (reception RF) 121 of the first transmission / reception unit 902 and measures the power of the received signal received by the first transmission / reception unit 902. Similarly, the power measurement unit 904b receives the output of a radio reception unit (not shown) of the second transmission / reception unit 903, and measures the power of the reception signal received by the second transmission / reception unit 903.
[0244]
The power control unit 905b of the propagation environment adaptation unit 905 compares the preset power value with the received power measurement result obtained by the power measurement unit 904b, and based on the comparison result, the first and second transmission / reception stations The transmission power of 902 and 903 is controlled. Specifically, when the reception power received by the first or second transmission / reception unit 902 or 903 is smaller than a predetermined value, the transmission power is controlled by controlling the radio transmission unit (transmission RF) 119 of each transmission unit 101a. Control to increase. On the contrary, when the reception power received by the first or second transmission / reception unit 902 or 903 is larger than a predetermined value, the transmission is performed by controlling the wireless transmission unit (transmission RF) 119 of each transmission unit 101a. Control to reduce power.
[0245]
As a result, in the wireless communication system 900, only the receiving station 102 that is the transmission target of the confidential information can receive the reception signal with the optimum reception level from the first transmitting / receiving unit 902 and the second transmitting / receiving unit 903 of the transmitting station 901. .
[0246]
As a result, the reception station 102 can obtain a combined result of two signals that reach the same time in which the reception level is optimally adapted to the propagation paths 906 and 906 and is synchronized with the reception operation. As a result, the receiving station 102 can reliably demodulate the confidential information.
[0247]
On the other hand, since the third party receives information from the transmitting station 901 at a location different from the receiving station 102, it is difficult to obtain an appropriate reception level and appropriate reception timing for demodulating the signal. Therefore, it is difficult to demodulate the received signal.
[0248]
Next, the operation of the wireless communication system 900 will be described with reference to FIGS. 14 and 16 again.
[0249]
First, the transmitting station 901 transmits (transmits 10B) a signal (communication 10) including the network reference time while controlling the output from the first transmitting unit 902 so as to pass through the first propagation path 906. When receiving the communication 10 (reception 10T), the receiving station 102 sets a predetermined delay time (T10) controlled by the time control unit 102c. The receiver station 102 transmits a response signal (communication 20) to the transmitter station 901 with a predetermined power (transmission 20T) after a delay time (T10) has elapsed from the reception 10T. Incidentally, the transmitting station 901 and the receiving station 102 hold the delay time T10 as shared information in advance.
[0250]
The transmission station 901 receives the communication 20 (reception 20B), and at the same time, the propagation environment estimation unit 904 receives the propagation path estimation signal (communication 10) transmitted by the transmission 10B and the response signal (communication 20) received by the reception 20B. The state of one propagation path 906 is estimated. Specifically, the signal propagation time and power attenuation amount in the first propagation path 906 are estimated. The power attenuation amount in the propagation path 906 is estimated based on the difference between the value of the reception 20B and the output power of the response signal (communication 20) determined in advance.
[0251]
Similarly, the transmitting station 901 transmits (transmits 11B) a signal (communication 11) including the network reference time while controlling the output from the second transmitting unit 903 so as to pass through the second propagation path 907. When receiving the communication 11 (reception 11T), the receiving station 102 sets a predetermined delay time (T11) controlled by the time control unit 102c. The reception station 102 transmits a response signal (communication 21) to the transmission station 901 with a predetermined power (transmission 21T) after a delay time (T11) has elapsed from the reception 11T. Incidentally, the transmitting station 901 and the receiving station 102 hold the delay time T11 as shared information in advance.
[0252]
The transmission station 901 receives the communication 21 (reception 21B), and at the same time, the propagation environment estimation unit 904 generates a first response from the propagation path estimation signal (communication 11) transmitted by the transmission 11B and the response signal (communication 21) received by the reception 21B. 2 The state of the propagation path 907 is estimated. Specifically, the signal propagation time and power attenuation amount in the second propagation path 907 are estimated. The power attenuation amount in the propagation path 907 is estimated based on the difference between the value of the reception 21B and the output power of the response signal (communication 21) determined in advance.
[0253]
As described above, the transmission station 901 estimates the signal propagation time and the signal power attenuation amount in the first and second propagation paths 906 and 907 based on the communication 30 and the communication 31.
[0254]
The receiving station 102 sets the receiving terminal reference signal 10 after a certain time (T20) by using the time control unit 102c, and transmits (transmits 30T) a reference time notification signal (communication 30) to the transmitting station 901.
[0255]
Next, the transmission station 901 transmits a signal including confidential information from the first transmission / reception unit 902 via the communication 40 (transmission 40B), and transmits a signal including confidential information from the second transmission / reception unit 903 via the communication 41 (transmission 41B). To do. At this time, the transmitting station 901 controls the transmission timing so that the two signals arrive at the receiving terminal reference time 10 set by the receiving station 102 at the same time, and the receiving station 102 can receive the two signals with optimum power. So that the transmission power is controlled.
[0256]
The receiving station 102 starts reception 40T with reference to the receiving terminal reference time 10. At this time, since the receiving terminal reference time 10 of the communication 40 and the communication 41 is set at the same time, the communication 40 and the communication 41 are simultaneously received by the receiving station 102. That is, both are received by the receiving station 102 as a combined result.
[0257]
In the case of this embodiment, the same information is transmitted in communication 40 and communication 41. As a result, the receiving station 102 can obtain a path diversity effect. In this embodiment, the transmission station 901 transmits the communication 40 and the communication 41 with very low power. As a result, the receiving station 102 that can receive the combined symbols of the two signals can obtain a signal level sufficient for demodulation, while other receiving stations located at different locations from the receiving station 102. Then, the signal level necessary for demodulation cannot be obtained from the communication 40 and the communication 41.
[0258]
Thus, according to the above configuration, a plurality of transmission / reception units 902 and 903 are provided in the transmission station 901, thereby forming a plurality of propagation paths 906 and 907 between the transmission station 901 and the reception station 102. The power attenuation amount in the case of performing communication at 907 is estimated, and the transmission power at the lowest level that can be demodulated when the receiving station 102 combines and receives the received signals that arrive via the plurality of propagation paths 906 and 907 Since the confidential information is transmitted from the plurality of transmission / reception units 902 and 903, it is difficult for other receiving stations located at locations other than the receiving station 102 to demodulate the confidential information. As a result, the wireless communication system 900 that can perform communication with higher security can be realized.
[0259]
(Embodiment 10)
In FIG. 19, reference numeral 1000 denotes a radio communication system according to Embodiment 10 of the present invention as a whole. A transmitting station 1001 of the wireless communication system 1000 includes an antenna unit 1003 including two linearly polarized antennas AN20 and AN21 having orthogonal polarization planes. The antenna unit 1004 of the receiving station 1002 has one linearly polarized antenna AN30.
[0260]
Thereby, in the radio communication system 1000, the polarization plane of the antenna AN30 of the receiving station 1002 is received from the transmitting station 1001 in consideration of this propagation path environment as a propagation path environment shared only by the transmitting station 1001 and the receiving station 1002. Secret information is transmitted to the station 1002.
[0261]
That is, first, based on the transmission wave sent from the receiving station 1002, the propagation environment estimation unit 1006 of the transmitting station 1001 estimates the plane of polarization of the antenna AN30 of the receiving station 1002. Next, based on the estimation result obtained by the propagation environment estimation unit 1006, the antenna unit 1003 is controlled so that the radiation characteristic control unit 1008 of the transmission station 1001 forms a radiation characteristic that can be received only by the reception station 1002. It has become.
[0262]
In addition, time control units 1007 and 1010 are provided in the transmission station 1001 and the reception station 1002 of the wireless communication system 1000, and the time control units 1007 and 1010 use the time control units 1007 and 1010 in the same manner as in the first embodiment. The secret information is transmitted from the transmitting station 1001 to the receiving station 1002 at a transmission timing that takes into account the signal propagation time on the propagation path 1011 that can be shared only by the transmitting station 1001. As a result, only the receiving station 1002 can receive and restore the confidential information.
[0263]
Accordingly, the time control unit 1007 in FIG. 19 corresponds to the propagation environment estimation unit 101c and the propagation environment adaptation unit 101d in FIG. Since the receiving station 1002 has the same configuration as that in FIG. 3, detailed description thereof is omitted here. Briefly, the antenna AN30 corresponds to the antenna AN12, the transmission / reception unit 1009 corresponds to the transmission unit 102a and the reception unit 102b, and the time control unit 1010 corresponds to the time control unit 102c.
[0264]
A specific configuration of the transmitting station 1001 is shown in FIG. In FIG. 20, in which parts corresponding to those in FIG. 2 are assigned the same reference numerals, the transmitting station 1001 is roughly composed of a transmitting unit 1012, a receiving unit 1013, a propagation environment estimating unit 1006, and a time control unit 1007. . Here, the transmission / reception unit 1005 in FIG. 19 corresponds to the transmission unit 1012 and the reception unit 1013.
[0265]
The transmitting station 1001 receives radio waves from the receiving station 1002 by two linearly polarized antennas AN20 and AN21 provided so that their polarization planes are orthogonal to each other. Each antenna output is input to the radio reception unit (reception RF) 121. The radio reception unit 121 performs radio processing such as down-conversion and analog-digital conversion processing on each antenna output, and sends the processed signal to the demodulation unit 122 and the propagation environment estimation unit 1006.
[0266]
The propagation environment estimation unit 1006 estimates the polarization plane of the antenna of the receiving station 1002 based on the two antenna outputs subjected to the wireless communication processing, and sends the estimation result to the radiation characteristic control unit 1008. Based on the estimation result, the radiation characteristic control unit 1008 controls the wireless transmission unit (transmission RF) 119 so that the reception power at the reception station 1002 is maximized.
[0267]
The propagation environment estimation unit 1006 is configured as shown in FIG. The radiation characteristic control unit 1008 is configured as shown in FIG.
[0268]
The propagation environment estimation unit 1006 includes an electric field strength detection unit 1020 and a phase difference detection unit 1021. The electric field strength detection unit 1020 detects the electric field strength of each antenna output based on the two antenna outputs. Further, the phase difference detection unit 1021 obtains the phase difference between the respective antenna outputs based on the two antenna outputs. The polarization estimation unit 1022 estimates the polarization state of the received signal from the electric field strength and phase difference between the two antenna outputs.
[0269]
In general, when two antennas (V, H) having orthogonal planes of polarization are used, as shown in FIG. 23, the polarization of electromagnetic waves (p in the figure) is the plane of polarization (in the figure, given by the radiation characteristics of the antenna). V, H) can be obtained from the electric field intensity projected on (Ev, Eh in the figure) and the phase difference between both received signals. For example, when the polarization p is an elliptical polarization, the angle and flatness of the major axis and the antennas (V, H) can be obtained using the electric field strength (Ev, Eh) and the phase difference φ. The angle can also be approximated from Ev and Eh.
[0270]
The propagation environment estimation unit 1006 of this embodiment uses this fact to estimate the polarization state composed of information such as the angle between the major axis of the polarization p and the antenna, and the flatness. Yes.
[0271]
As shown in FIG. 22, the radiation characteristic control unit 1008 inputs the transmission signal and the estimated value signal obtained by the polarization estimation unit 1022 to the electric field intensity control unit 1030 and the phase control unit 1031, respectively. The combining unit 1032 generates signal vectors (V vector, H vector) corresponding to the antennas AN20 and AN21 orthogonal to each other from the electric field strength and the phase. Then, a transmission signal corresponding to the amplitude and phase of the V direction vector is output to the V direction antenna AN21 via the wireless transmission unit 119, and a transmission signal corresponding to the amplitude and phase of the H direction vector is transmitted via the wireless transmission unit 119. Output to the H direction antenna AN20.
[0272]
  Thus, based on the polarization state estimated by the propagation environment estimation unit 1020, the reception power at the antenna unit 1004 of the reception station 1002 is maximized.NaIn other words, the polarization plane of the transmission signal can be controlled so that the major axis of the polarization p coincides with the axis of the polarization plane given by the radiation characteristic of the antenna.
[0273]
Next, the operation of the wireless communication system 1000 will be described with reference to FIG. Here, since the transmission / reception timing between the transmitting station 1001 and the receiving station 1002 is the same as that in Embodiment 1, the description will be made focusing only on the adjustment of the polarization plane of the radio wave.
[0274]
First, the receiving station 1002 transmits (transmits 1T) a polarization estimation signal (communication 1). Here, since the antenna unit 1004 of the receiving station 1002 is configured by the antenna AN30 having a linear polarization characteristic as a radiation characteristic, the electromagnetic wave transmitted by the antenna AN30 has a specific polarization plane.
[0275]
This transmission signal is received by the antenna unit 1003 of the transmission station 1001 in a state where the plane of polarization is rotated due to reflection or diffraction on the propagation path 1011 and a delay is added. The antenna unit 1003 of the transmitting station 1001 is provided with antennas AN20 and AN21 having radiation characteristics of linear polarization so that their planes of polarization are orthogonal to each other, so that stable reception is performed regardless of the plane of polarization of the received signal. be able to.
[0276]
When the transmission station 1001 receives the communication 1 by the antenna unit 1003 (reception 1B), the propagation environment estimation unit 1006a calculates each received signal received by the two antennas AN20 and AN21 to estimate the polarization state of the received signal. To do.
[0277]
Next, based on the polarization state estimated by the propagation environment estimation unit 1006, the radiation characteristic control unit 1008 maximizes the received power at the antenna unit 1004 of the receiving station 1002, that is, the long axis of the polarization p and the antenna The communication 2 is transmitted (transmission 2B) by controlling the polarization plane of the transmission signal so that the axis of polarization plane given by the radiation characteristic of the AN 30 coincides. This polarization plane control can be realized by performing a calculation reverse to the estimation method at the time of reception.
[0278]
When the transmission plane is output by controlling the polarization plane in this way, the antenna unit 1004 of the reception station 1002 can receive the communication 2 signal from the transmission station 1001 with the optimal polarization plane. The receiving station 1002 receives the communication 2 by the antenna unit 1004 (reception 2T). Incidentally, the transmitting station 1001 transmits transmission data including confidential information to the receiving station 1002 by communication 2. Thereafter, the wireless communication system 100 performs communication after communication 3 between the transmitting station 1001 and the receiving station 1002 in the same manner.
[0279]
Here, when the transmitting station 1001 and the receiving station 1002 communicate in an environment with a good line of sight, the polarization plane is kept stable, so that communication according to this embodiment can be performed stably. On the other hand, in an environment where there is an obstacle between the two communication paths and communication cannot be performed using only direct waves, the polarization plane is disturbed due to the influence of surrounding conditions. However, if the interval between the time when the propagation path environment (which corresponds to the polarization plane in this embodiment) is estimated and the time when the communication is actually performed using the propagation path environment is sufficiently short, the propagation path environment is quasi-static. There is no problem because it can be considered.
[0280]
For example, this corresponds to a case where both the transmitting station 1001 and the receiving station 1002 are fixed, and an obstacle with a low moving speed such as a person exists on the communication path of the both. Further, for example, even when there is no obstacle between the communication paths of the transmitting station 1001 and the receiving station 1002 as in the case where the transmitting station 1001 is arranged on a road and the receiving station 1002 is mounted on an automobile, it may be biased due to a change in situation. This is equivalent to the wavefront being disturbed.
[0281]
In these cases, even if one or both of the transmitting station 1001 and the receiving station 1002 are moving, there is a sufficient interval between the time when the propagation path environment is estimated and the time when communication is actually performed using the propagation path environment. The propagation path environment can be regarded as quasi-static.
[0282]
On the other hand, consider a case where a third party who is not a valid communication partner intercepts communication 1 and communication 2 and tries to extract information. In this case, in order for an unauthorized receiving terminal to receive the communication 2 information, it is necessary to appropriately adjust the polarization plane.
[0283]
The transmitting station 1001 and the receiving station 1002 perform polarization plane alignment by communication 1, but since communication 1 is an output signal from the receiving station 1002, an unauthorized receiving terminal changes the polarization plane from the transmitting station 1001. It cannot be estimated. That is, since the polarization state of the communication 2 at the antenna end of the receiving station 1002 cannot be known in advance, it cannot be intercepted.
[0284]
As a result, even if an unauthorized receiving station can intercept the communication 1, the communication 2 is controlled and transmitted in conformity with the polarization plane in the communication 1, so that the unauthorized receiving station outputs from the transmitting station 1001. It is impossible to know in advance the polarization plane of the electromagnetic wave.
[0285]
This will be described in detail with reference to FIG. Communication 1 and communication 2 in FIG. 25 are the same as those in FIG. In FIG. 25, a receiving station 1040 indicates an unauthorized receiving station that is not a transmission target of confidential information.
[0286]
Here, the transmitting station 1001 and the receiving station 1002 perform communication 1 and communication 2 via the propagation path 1011. Consider a case where an unauthorized receiving station 1040 receives these communication 1 and communication 2. Between the transmitting station 1001 and the receiving station 1002, both communication 1 and communication 2 are performed via the propagation path 1011. On the other hand, in the receiving station 1040, the communication 1 is received via the propagation path 1041, and the communication 2 is received via the propagation path 1042.
[0287]
As described above, the propagation path 1041 when the reception station 1040 receives the communication 1 output from the reception station 1002 and the propagation path 1042 when the reception station 1040 receives the communication 2 output from the transmission station 1001 are the propagation path. Different from 1011. As a result, even if the receiving station 1040 can estimate the propagation path 1041 formed with the receiving station 1002 by intercepting the communication 1, the propagation path 1041 is formed with the transmitting station 1001. Therefore, the communication 2 cannot be received correctly. For this reason, it is impossible for an unauthorized receiving station 1040 to stably obtain information of either one of the communication 1 and the communication 2 or both of the information.
[0288]
In general, in a radio communication system using electromagnetic waves, it is necessary to match the polarization characteristics of an antenna or the like between a transmission side and a reception side. If this is not performed correctly, characteristics such as communication quality are deteriorated. For example, if the polarization characteristics of the antenna radiation characteristics are uniform in the horizontal direction, the polarization plane of the antenna radiation characteristics is perpendicular to the ground plane at both the transmitting and receiving stations. The adjustment may be performed. In the case of vertical polarization with the polarization plane perpendicular to the ground surface, it is easy to design radiation characteristics uniformly in the horizontal direction.
[0289]
On the other hand, when the radiation characteristics of the antenna are not uniform in the horizontal direction, it is necessary to adjust the plane of polarization between the transmitting station and the receiving station. This will be specifically described with reference to FIGS. In a wireless communication system in which electromagnetic waves propagate in a direction parallel to the ground surface direction, as shown in FIG. 26 (a), by arranging the antenna AN of the transmitter and receiver perpendicular to the ground plane, The radiation characteristic of the antenna AN can be set to vertical polarization. Here, it is assumed that the ground plane is kept almost horizontal, and the radiation characteristics in the horizontal direction are assumed to be uniform.
[0290]
Next, a specific example in which the antenna AN is installed in the horizontal direction as shown in FIG. If the antenna in the figure is a dipole antenna, the radiation characteristics are not uniform in the horizontal direction, and the plane of polarization varies depending on the positional relationship with the apparatus main body 1050. Consider a system that transmits radio waves in the height direction with this configuration as an example.
[0291]
Suppose that 1050 in FIG. 27 is a transmitting device, and 1051 and 1052 are receiving devices, and that the radiation characteristics of the antennas of the devices 1050, 1051 and 1052 are such that their planes of polarization are in the direction of the arrows in the figure. Here, a state in which the transmitting apparatus 1050 is replaced with the transmitting station 1001 and the receiving apparatus 1052 is replaced with the receiving station 1002, the transmitting apparatus 1050 estimates the polarization plane of the receiving apparatus 1052, and the polarization plane of the transmitting apparatus 1050 is controlled based on the estimation result. This applies to the wireless communication system 1000 of this embodiment.
[0292]
As shown in FIG. 27, even when the ground plane of the reception device 1052 is kept horizontal with respect to the polarization plane of the transmission device 1050, the communication environment varies greatly depending on the situation because of the degree of freedom seen from the polarization plane. Come.
[0293]
Therefore, when the polarization planes are aligned on the same axis as in the transmission device 1050 and the reception device 1052, the reception device 1052 can receive with high sensitivity, but the polarization plane is orthogonal to the transmission device 1050 as in the reception device 1051. If it is arranged, the reception power is not sufficient due to the radiation characteristics of the antenna, so that the reception quality is deteriorated.
[0294]
Here, the explanation was made on the assumption that the polarization plane does not rotate in the radio propagation path between transmission and reception, but it is known that the axis of the polarization plane changes due to reflection or the like. Even in such a case, the same can be said about the polarization plane at the antenna end of each device. Even in such a state, according to the configuration of this embodiment, the transmission device 1101 controls the transmission wave so as to be the same as the polarization plane of the reception device 1102, so that the polarization planes on the transmission side and the reception side are adjusted. Stable communication can be performed without the need for communication.
[0295]
Furthermore, a case where a third party attempts to intercept communication between the transmission device 1050 and the reception device 1052 using the reception device 1051 will be described. As described above, it is necessary to install the polarization plane of the reception apparatus 1051 in accordance with the polarization plane transmitted from the transmission apparatus 1050 so that the reception state is improved. However, since the polarization plane of the transmission wave is controlled in conformity with the polarization plane of the reception device 1052, it cannot be known from the reception device 1051.
[0296]
Further, as described above, since the plane of polarization varies depending on the installation direction of the receiving apparatus 1052, it is impossible to always know it. Further, even if the state of the polarization plane is estimated from the installation status of the custom receiving device 1052, the propagation path between the transmission device 1050 and the reception device 1052 and the propagation path between the transmission device 1050 and the reception device 1051 are different. It is impossible to know the correct state. Therefore, it is impossible for a third party to intercept the communication between the transmission device 1050 and the reception device 1052.
[0297]
Further, as described above, when a phenomenon such as reflection or diffraction occurs on the propagation path, the polarization plane of the electromagnetic wave changes, and it is difficult for a third party to estimate the polarization plane. Environments where reflection and diffraction occur frequently are well known indoors, indoors, and places like offices where there are many obstacles such as partitions.
[0298]
Incidentally, in the case of this embodiment, the transmitting station 1001 transmits and superimposes true information including confidential information on a linearly polarized electromagnetic wave having an optimal polarization plane with respect to the antenna AN30 of the receiving station 1002, and It is also conceivable to transmit pseudo information superimposed on a linearly polarized electromagnetic wave having a plane of polarization parallel to an orthogonal axis.
[0299]
Thereby, in the wireless communication system 1000, the true information is normally received by the receiving station 1002 due to the characteristics of the antenna AN30, but the pseudo information is not received. Thereby, only true information can be selectively received without using a complicated configuration.
[0300]
That is, the receiving station 1002 does not need to know in advance which signal is confidential information and which signal is pseudo information. Further, the transmitting station 1001 can freely conceal without performing data arrangement in consideration of data separation on the receiving side. Furthermore, since the third party cannot theoretically separate confidential information and pseudo information, high security can be ensured.
[0301]
The wireless communication system 1000 performs communication after communication 3 while matching the polarization plane in the same manner as communication 1 and communication 2 described above. Incidentally, in communication 3 and later, all transmission data may be transmitted with the polarization plane matched. However, after transmitting only particularly important secret information such as an encryption key with the polarization plane matched, You may make it transmit only after performing an encryption process.
[0302]
Thus, according to the above configuration, in addition to the configuration of the first embodiment, the propagation environment estimation unit 1006 of the transmitting station 1001 uses the polarization plane of the antenna AN30 of the receiving station 1002 based on the transmission wave transmitted from the receiving station 1002. The transmission station 1001 forms a transmission wave having a radiation characteristic that can be received only by the reception station 1002 based on the estimation result, and transmits the transmission wave to the reception station 1002 by superimposing confidential information on the transmission wave. By doing so, in addition to the effects of the first embodiment, the wireless communication system 1000 with higher security can be realized.
[0303]
In this embodiment, vertical polarization and horizontal polarization are given as examples. However, when a polarization plane inclined by a certain angle with respect to the ground surface is considered, it is more difficult for a third party to receive confidential information. For example, when installing a dipole antenna with linear polarization characteristics at an angle to the ground surface, the radiation characteristics of the antenna differ from the horizontal direction as described above, and the radiation characteristics depend on the apparent angle of the antenna. Change. That is, the radiation characteristic changes depending on the relative positional relationship between the transmission device 1050 and the reception device 1052 shown in FIG. As a result, it becomes more difficult to estimate the polarization plane from a third party.
[0304]
Further, if the amplitude and phase of the radiation signal to the orthogonal polarization plane are controlled using an antenna such as a helical antenna having orthogonal polarization plane characteristics, the polarization plane can be electrically controlled. By adopting such a configuration, it is difficult to visually estimate the plane of polarization, and a system with higher security can be realized.
[0305]
Further, in the above description, a case where the transmitting station 1001 outputs a linearly polarized electromagnetic wave having an optimal polarization plane to the antenna AN30 of the receiving station 1002 from the beginning has been described. Until the characteristics of the antenna AN30 are estimated, electromagnetic waves that are circularly polarized waves may be radiated from the transmitting station 1001. In this way, the receiving station 1002 can stably receive a signal for establishing a radio link such as RACH (Random Access Channel) regardless of the radiation characteristics of the antenna AN30.
[0306]
In this embodiment, when a modulation method in which symbols are independent in time is used, it is possible to set whether or not to conceal information by controlling the polarization plane described above for each symbol. . Thereby, it becomes possible to perform more stable communication by concealing a part of the symbol.
[0307]
(Embodiment 11)
In FIG. 28, in which parts corresponding to those in FIG. 19 are assigned the same reference numerals, 1100 indicates a wireless communication system according to Embodiment 11 of the present invention as a whole. The radio communication system 1100 includes a receiving station 1101 having an antenna unit 1102 including two linearly polarized antennas AN60 and AN61 having orthogonal planes of polarization, and the receiving station 1101 controls the radiation characteristic of the antenna unit 1102. Except for the point that 1104 is provided, it has the same configuration as the wireless communication system of FIG.
[0308]
Next, the operation of the wireless communication system 1100 will be described using FIG. Here, since the transmission / reception timing between the transmitting station 1001 and the receiving station 1101 is the same as that of the first embodiment, only the point of adjusting the polarization plane of the radio wave will be described.
[0309]
First, the receiving station 1101 transmits (transmits 1T) a polarization estimation signal (communication 1). At this time, the radiation characteristic control unit 1104 controls the radiation characteristic of the antenna unit 1102 via the transmission / reception unit 1103 so that the reference polarization plane is output from the antenna unit 1102. This transmission signal is received by the antenna unit 1003 of the transmission station 1001 in a state where the plane of polarization is rotated by reflection or diffraction on the propagation path 1011 and a delay is added.
[0310]
The transmission station 1001 estimates the polarization plane that the reception station 1101 uses as a reference from the reception (reception 1B) signal of the communication 1 in the propagation environment estimation unit 1006, and holds the estimation result. Next, the radiation characteristic control unit 1008 controls to rotate the polarization plane by a preset angle with respect to the reference polarization plane estimated by the propagation environment estimation unit 1006, and transmits communication 2 (transmission 2B).
[0311]
The receiving station 1101 controls the communication 2 by controlling the radiation characteristic of the antenna unit 1102 by the radiation characteristic control unit 1104 so that the radiation characteristic control unit 1008 rotates from the reference polarization plane by the angle that the polarization plane is rotated. Receive (receive 2T).
[0312]
That is, the radiation characteristic control unit 1008 of the transmitting station 1001 and the radiation characteristic control unit 1104 of the receiving station 1101 store polarization plane rotation information shared in advance only by each other station. Accordingly, since the polarization plane of communication 2 from the transmission station 1001 and the polarization plane of the radiation characteristic controlled by the reception station 1101 are rotated by the same angle from the reference polarization plane, the reception station 1101 communicates with the optimal radiation characteristic. Can be received (reception 2T). Thereafter, the transmitting station 1001 and the receiving station 1101 perform communication in the same manner.
[0313]
Thus, according to the above configuration, in addition to the configuration of the tenth embodiment, the receiving station 1101 is configured so that the radiation characteristics can be adaptively changed on the receiving station 1101 side, and the transmitting station 1001 and the receiving station 1101 In addition to sharing the rotation information of the polarization plane and communicating with each other by combining the polarization planes, in addition to the effects obtained by the tenth embodiment, the wireless communication system 1100 with higher security can be realized.
[0314]
That is, even if the third person knows the polarization plane in the communication 1, the polarization plane is changed in the communication 2, so that it is difficult to know the changed polarization plane. Further, if the plane of polarization is rotated for each communication, security can be further improved.
[0315]
Further, independent information can be added to two orthogonal polarization planes, and each information can be separated on the basis of the polarization plane given in communication 1. In this way, it is possible to realize a highly confidential communication in which the transmission amount can be doubled and cannot be estimated from a third party.
[0316]
In general, the transmitting station 1001 notifies the receiving station 1101 of frequencies and times that can be used for communication, and the receiving station 1101 performs communication using these resources. In general, the receiving station 1101 uses these resources to monitor the state of the carrier and starts communication at a time when the carrier is free. As these conditions, frequency and time are two major factors, but in this embodiment, by adding polarization to these, the capacity of communication itself can be increased up to twice.
[0317]
However, in this case, the frequency and time have spatial identity, but the environment varies depending on the location because the polarization state changes depending on the propagation path. Therefore, there is a problem that the polarization interference situation differs between the transmitting station 1001 and the receiving station 1101. However, when the transmitting station 1001 and the receiving station 1101 are in an environment where the polarization states in the propagation path 1011 are almost the same, such as an environment where the transmitting station 1001 and the receiving station 1101 can be seen, or an environment close thereto. In addition, multiplexing by polarization as described above is also possible.
[0318]
Thus, in the case where the two communications of the communication between the transmitting station 1001 and the receiving station 1101 and the communication between the transmitting station 1001 and another receiving station are polarization multiplexed at the same time and the same frequency, If the two planes of communication are synchronized and the plane of polarization is switched every certain time, it is difficult for a third party to separate the two communications, so that security can be improved.
[0319]
On the other hand, in an environment where the line of sight cannot be seen, in order to avoid mutual communication interference, the receiving station 1101 monitors the communication status emitted from other surrounding receiving stations, notifies the transmitting station 1001 of monitoring information, and does not interfere with each other. If transmission is performed when the conditions are satisfied, the same communication as in the condition where the line of sight can be seen is possible.
[0320]
When considering a multipath environment, the polarization planes from the paths are different because the rotation directions and angles of the polarization planes of the paths are different. In this embodiment, the receiving station 1101 selectively receives a specific path according to the state of the polarization plane. As a result, the propagation path 1011 from the transmitting station 1001 to the receiving station 1101 is limited, so that an effect of reducing the influence of multipath can be obtained.
[0321]
(Embodiment 12)
As shown in FIG. 29, the wireless communication system 1200 of this embodiment includes two transmission / reception units 1203 and 1204 in which transmission stations 1201 that transmit confidential information are arranged at different positions. In addition, optimal transmission power and directional transmission from which only the receiving station 1202 can obtain confidential information through two different transmission paths 1207 and 1208 from the two transmission / reception units 1203 and 1204 are performed.
[0322]
The received signals received by the transmission / reception units 1203 and 1204 are sent to the propagation environment estimation unit 1205. The propagation environment estimation unit 1205 estimates the environments of the two propagation paths 1207 and 1208 based on the two received signals. Specifically, the signal propagation time and the signal arrival direction in each of the propagation paths 1207 and 1208 are estimated.
[0323]
Based on the estimation result of the propagation environment estimation unit 1205, the propagation environment adaptation unit 1206 controls the transmission operation when the transmission / reception units 1203 and 1204 transmit confidential information to the receiving station 1202. Specifically, first, the transmission timing of each of the transmission / reception units 1203 and 1204 is controlled so that the signal transmitted from each of the transmission / reception units 1203 and 1208 is received by the reception station 1202 at a preset reception time. Second, directional transmission is performed so that the directivity at the time of transmission in each of the transmission / reception units 1203 and 1204 is directed to the receiving station 1202.
[0324]
FIG. 30, in which parts corresponding to those in FIG. 2 are assigned the same reference numerals, shows the detailed configuration of the transmitting station 1201. As can be seen from FIG. 30, the two transmitting / receiving units 1203 and 1204 shown in FIG. 29 are simply provided with two array antennas AN70 and AN71 at different positions, and the signal processing parts are the same. It has become. 30 corresponds to the propagation environment estimation unit 1205 in FIG. 29, and the beam former 1222 and the timing control unit 118 in FIG. 30 correspond to the propagation environment adaptation unit 1206 in FIG. Equivalent to.
[0325]
Here, since the transmission timing of the confidential information by the transmitting station 1201 has been described in detail in the above-described embodiment, in this embodiment, the directional transmission of the confidential information will be described mainly.
[0326]
When the arrival direction estimation unit 1210 receives two array antenna outputs via the wireless reception unit (reception RF) 121, the arrival direction estimation unit 1210 determines the arrival direction of the signal transmitted from the reception station 1202 based on the amplitude and phase of the reception signals. presume. Specifically, the arrival direction is estimated by sequentially changing the weighting coefficients to be multiplied by the received signals of the two array antennas AN70 and AN71 and obtaining the weighting coefficient that maximizes the weighted addition value. Then, the estimation result estimated by the arrival direction estimation unit 1210 (that is, the weighting coefficient for each of the array antennas AN70 and AN71) is sent to the beam former 1222 of the transmission unit 1220.
[0327]
Here, the burst signal forming unit 1221, the beam former 1222, and the modulation unit 1223 of the transmission unit 1220 are configured as shown in FIG. 31. Incidentally, the transmission unit 1220 of this embodiment is configured to code-spread and multiplex transmission data.
[0328]
The burst signal forming unit 1221 inputs an encryption key and encrypted user data to the data dividing circuit 1230. The data dividing circuit 1230 divides the input data into a plurality of data (two in this embodiment) and sends them to the subsequent convolver circuits 1231a and 1231b. In practice, the data dividing circuit 1230 divides the input data into a plurality of data D12a and D12b and sends them to the subsequent convolver circuits 1231a and 1231b. Here, the spread code is shared between transmission and reception, but it is not necessary to share in advance which code each of the divided data D12a and D12b corresponds to. However, a signal with large received power is determined as data D12a, and the other as data D12b. Here, confidential data such as an encryption key and encrypted data is data D12a, and the other information data is data D12b.
[0329]
The convolver circuits 1231a and 1231b code-spread the input data by performing a convolution operation using the input data and the code generated by the code generation circuit 1232. Each code-spread data is input to gain control (GC) circuits 1234b and 1234c of the beamformer 1222. The gain control circuit 1234a receives the pseudo signal generated by the pseudo signal generation circuit 1233.
[0330]
The gain control circuits 1234a to 1234c control the gain of each input data based on the estimated value from the arrival direction estimation unit 1210. The outputs of the gain control circuits 1234a to 1234c are input to the antenna matrix circuits 1235a to 1235c. The estimated values from the arrival direction estimation unit 1210 are also input to the antenna matrix circuits 1235a to 1235c.
[0331]
Each of the antenna matrix circuits 1235a to 1235c outputs an estimated value (optimum weight coefficient) from the arrival direction estimation unit 1210 and a reception state (reception power, delay dispersion, etc.) at the receiving station 1202 to outputs of the corresponding gain control circuits 1234a to 1234c. Multiply vector values based on and. Specifically, based on the estimated propagation path environment, the receiving station 1202 performs signal power control to maximize or minimize the received power.
[0332]
Here, in the antenna matrix circuit 1235b to which the confidential information is input, the data D12a is set so that the reception level at the receiving station 1202 becomes maximum based on the estimated value obtained by the arrival direction estimating unit 1210. Similarly, in the antenna matrix circuit 1235c to which the data D12b is input, the data D12b is set so that the reception level at the receiving station 1202 is sufficiently high and smaller than the data D12a based on the estimated value. The confidential information divided in this way is received at the receiving station 1202 at different reception levels.
[0333]
On the other hand, in the antenna matrix circuit 1235a to which the pseudo information is input, a null (a portion where the power becomes 0 due to wave interference) is received at the receiving station 1202 based on the estimation result obtained by the arrival direction estimation unit 1210. Control to form. As a result, the receiving station 1202 does not receive the pseudo signal, and the other receiving station at a position different from the receiving station 1202 receives the pseudo signal.
[0334]
Each transmission data vectorized by the antenna matrix circuits 1235a to 1235c is vector-added by the synthesis / frequency conversion circuit 1237 of the modulation unit 1223, and each element value obtained thereby is a frequency at the frequency obtained by the local oscillator 1236. Converted. The frequency-converted element signals are output from corresponding element antennas of the array antennas AN70 and AN71.
[0335]
As described above, the transmitting station 1201 controls the reception state at the receiving station 1202 by assigning the data D12 to the main lobe of the radiation characteristic of the antenna, assigning the data D12b to the side lobe, and assigning pseudo information to null. As a result, the receiving station 1202 that is the transmission target of the confidential information can satisfactorily receive the data D12a and D12b that are the divided confidential information with a power difference between them, but the other receiving stations can receive the data D12a and D12b. The secret information cannot be received because the power difference between the two is reversed or the pseudo information is disturbed.
[0336]
FIG. 32 shows the configuration of demodulating section 1241 and stream forming section 1242 in receiving section 1240 of receiving station 1202. Incidentally, the other configuration of the receiving station 1202 is the same as the configuration of the receiving station 102 shown in FIG. The demodulation unit 1241 inputs the output of the reception RF unit 140 (FIG. 3) to the convolver circuit 1243. Each convolver circuit 1243 receives the same code as the spreading code used in the transmission station 1201 from the code generation circuit 1244.
[0337]
The convolver circuit 1243 performs a convolution operation at the timing designated by the timer 145. Thus, each convolver circuit 1243 outputs data D12a and D12b corresponding to the spread code together with each reception level information. For example, confidential information is output from one convolver circuit 1243, significant information other than the confidential information is output from another convolver circuit 1243, and pseudo information is output from another convolver circuit 1243. Each piece of data is selected / separated using the output data and the reception level. Incidentally, in other receiving stations, it is difficult to know the optimum timing for convolution calculation using a spreading code, and even if it can be obtained, it is received at different reception levels, so each of these data is selected / separated. I don't get it.
[0338]
Each data output from the convolver circuit 1243 is sent to the data rearrangement / selection circuit 1247 of the stream forming circuit 1242 via the detector 1245 and also sent to the amplitude detection circuit 1246. The amplitude detection circuit 1246 detects the amplitude of each data. Here, the transmission station 1201 controls the transmission so that the data 12a is at the maximum level, the data D12b is at a lower level, and the pseudo information is at the minimum reception level with respect to the reception station 1202. Information on the reception level corresponding to each data is output from the detection circuit 1246.
[0339]
The detection result obtained by the amplitude detection circuit 1246 is sent to the data rearrangement / selection circuit 1247. The data rearrangement / selection circuit 1247 rearranges the data output from the detector 1245 according to the magnitude of the amplitude value based on the detection result obtained by the amplitude detection circuit 1246. A data string is output with D12a being the maximum amplitude value data and D12b being the second data.
[0340]
Next, the operation of the wireless communication system 1200 of this embodiment will be described using FIG.
[0341]
First, the receiving station 1202 outputs a predetermined propagation path estimation signal to the transmitting station 1201 by communication 1 (transmission 1T). The transmitting station 1201 uses the first transmission / reception unit 1203 (array antenna AN70 in FIG. 30) for the signal that has passed through the first propagation path 1207, and the second transmission / reception unit 1204 (in the array in FIG. 30) for the signal that has passed through the second propagation path 1208. Received by the antenna AN71).
[0342]
At this time, the transmission station 1201 receives the propagation path estimation signal as a known signal by the first transmission / reception unit 1203 and the second transmission / reception unit 1204, thereby transmitting the propagation paths of the first propagation path 1207 and the second propagation path 1208. Estimate the environment.
[0343]
The transmitting station 1201 controls the signals output from the first transmitting / receiving unit 1203 and the second transmitting / receiving unit 1204 by using the propagation path environment estimated from the signal output from the receiving station 1202 in reverse. Specifically, according to the propagation path environment (the arrival direction of the received wave) estimated by the propagation environment adaptation unit 1206 of the transmission station 1201, the signal power of the confidential information at the reception end of the reception station 1202 is increased. The first transmitter / receiver 1203 and the second transmitter / receiver 1204 are controlled to output (transmit 2B) a signal (communication 2). Thereafter, the communication 3 and later are performed in the same manner.
[0344]
In communication 2, confidential information is transmitted from the transmitting station 1201 to the receiving station 1202. The communication 2 information is obtained as a result of combining the information transmitted from the first transmission / reception unit 1203 of the transmission station 1201 via the first propagation path 1207 and the information transmitted from the second transmission / reception unit 1204 via the second propagation path 1208. Received at 1202 (reception 2T). As described above, since the communication 2 is controlled so that the signal power at the receiving end of the receiving station 1202 is increased, the receiving station 1202 can stably perform the reception 2T and can demodulate the confidential information.
[0345]
In addition, since the signal (communication 2) output in this way is output at two locations of the first transmission / reception unit 1203 and the second transmission / reception unit 1204, the signal resulting from the spatial synthesis differs depending on the receiving location. come. According to the above description, the transmission control is performed so that the reception power at the reception end of the receiving station 1202 is maximized, but it is important to control the communication quality so that the communication quality is deteriorated due to a delayed wave or the like. In this case, it is also effective to reduce the multipath component by lowering the reception power.
[0346]
On the other hand, when a third party who is not the transmission destination intercepts the communication 2 including the confidential information and tries to extract the information, even if the information can be intercepted by the communication 1, the communication 2 is optimal at the receiving end of the receiving station 1202. Since transmission control is performed so that the received signal is spatially synthesized, even if a third party receives this signal, the reception level is different and it is difficult to obtain information.
[0347]
In the case of this embodiment, in communication 2, pseudo information is code division multiplexed and transmitted in addition to the confidential information at the same time. Then, the receiving station 1202 restores each information data using the same spreading code as that of the transmitting station 1201. Here, when the code sequence is changed for each data as in the embodiment, since the frequency elements of the code sequence are different, the influence on the propagation path environment is also different.
[0348]
As a result, by distributing the confidential information to the multiplexed channels as in this embodiment, the influence due to the propagation status of the channels differs, making it more difficult for a third party to obtain the confidential information. .
[0349]
Note that the description so far has focused on controlling the transmission signals of the first transmission / reception unit 1203 and the second transmission / reception unit 1204 so that the optimal reception signal reaches the reception end of the reception station 1202. In the following, two channels (confidential information and pseudo information) are superimposed on the same time and the same frequency, spatially synthesized using a transmission signal composed of two or more, and the received power at the receiving end of the receiving station 1202 A description will be given focusing on the point of independent control for the channel.
[0350]
The transmission station 1201 estimates the first propagation path 1207 and the second propagation path 1208 based on the propagation path estimation signal that is a known signal received (reception 1B) from the reception station 1202. Next, the transmitting station 1201 performs code division multiplexing of two types of information for two channels and transmits the information to the receiving station 1202.
[0351]
Here, the channels assigned to each are selected so that the spreading gains are equal and have an orthogonal relationship. At this time, the confidential information is transmitted as the first information so that the reception state of the receiving station 1202 is in an optimal reception state based on the estimated propagation path state. Here, control is performed so that the reception power is maximized as an optimal reception state. As the second information, the pseudo information is transmitted by controlling the received power at the receiving end of the receiving station 1202 to be smaller than the first information based on the estimated propagation path condition.
[0352]
The communication 2 thus radiated is spatially synthesized and received by the receiving station 1202. As a result of spatial synthesis, at the receiving end, the first information is received as a signal with high power and the second information is received as a signal with low power in a code division multiplexed state. The received signal series can be extracted from each other by despreading using a spreading code. However, since the spreading gain is set equal, one of the signals has a higher power depending on the received power of each information. The other has less power. The receiving station 1202 can easily select the confidential information by selecting the information of the channel with the large received power as the confidential information and treating the information of the other channel as the pseudo information.
[0353]
On the other hand, even if a third party intercepts and restores this information, the reception state of the first information and the reception state of the second information vary depending on the place of reception. It is impossible to know from the line. For this reason, the third person cannot know the communication 2.
[0354]
By performing frequency spreading in this manner, the noise resistance is increased, so that the communication quality can be improved.
[0355]
Incidentally, although the case where control is performed so that the combined received power through the propagation paths 1207 and 1208 is reduced for the channel on which the pseudo information is superimposed, the received power of the channel on which the pseudo information is superimposed is set to 0, that is, mutually When controlling to cancel, there is a feature that the spatial area to be canceled is extremely narrow.
[0356]
FIG. 34 shows how the electromagnetic waves are spatially synthesized. FIG. 34 shows a standing wave by two waves. The horizontal axis represents position, and the vertical axis represents power. As can be seen from this figure, most positions are −10 dB or more when the maximum level is normalized to 0 dB. Further, due to the spatial synthesis of −20 dB or less, the portions where the radio waves are canceled and the power is low have a sharp peak, and the power increases rapidly even if the position is slightly shifted.
[0357]
Using this characteristic, for example, if the signal power of the first information is set to about −10 dBm and transmission control is performed so that the second information is canceled at the receiving end, the area where the disturbance of the second information can be ignored is limited. It can be seen that the first information cannot be received correctly in most areas. That is, the first information is disturbed by the second information at a place other than the place where the receiving station 1202 as the communication target is located. This makes it very difficult for a third party to obtain the first information.
[0358]
Thus, according to the above configuration, the confidential information is a transmission destination of the confidential information, in addition to transmitting the confidential information at the timing received by the receiving station 1202 at the time set via the plurality of propagation paths 1207 and 1208. By controlling the directivity at the transmitting station 1201 so that the reception power of the confidential information is maximized at the receiving station 1202, it becomes more difficult for the third party to obtain the confidential information and the communication quality at the receiving station 1202 is increased. Wireless communication system 1200 capable of obtaining highly confidential information can be realized.
[0359]
In addition, this embodiment has a high affinity with the array antenna technology. This technique has a great feature that the radiation characteristic can be controlled electrically, and this embodiment actively applies it.
[0360]
Therefore, the features of the array antenna itself can be used as they are. For example, when performing communication 2 in the description, communication on another channel toward a direction not related to communication with the receiving station 1202 Or the radiation characteristics can be controlled in communication in a multipath environment. By performing these, the communication capacity can be increased, or the influence of multipath can be reduced.
[0361]
(Other embodiments)
(1) In the above-described embodiment, the case has been described in which the time used as the reference of the receiving terminal reference time is the network reference time transmitted from the transmitting station to the receiving station by communication 1, but the present invention is not limited to this. In short, what is necessary is just to have the time which matched between the transmitting station and the receiving station. For example, a preset time can be used as a reference. Further, if the reference time notification signal is transmitted from the receiving station to the transmitting station, the transmitting station that can estimate the transmission path delay can adjust the reference time to the receiving station from the reception time of the reference time notification signal.
[0362]
(2) In the above-described fourth embodiment, the case has been described where transmission is performed at a transmission timing such that transmission data including confidential information arrives at the reception terminal reference time set by the transmission station at the reception station. However, the present invention is not limited to this, and transmission data including confidential information may be transmitted at a transmission timing shifted by a predetermined time with respect to the reception terminal reference time set by the transmission station at the reception station. In this case, as described above in the fourth embodiment, the receiving station performs reception processing using a synchronization sequence signal that can be extracted only by the receiving station that is the transmission target of the confidential information.
[0363]
This will be specifically described with reference to FIG. First, the transmitting station transmits a control signal including the network reference time to the receiving station (communication 1). Next, the receiving station transmits a response signal to the transmitting station after a predetermined time (T1) (communication 2) and sets the receiving end reference time (Tk). Next, the transmitting station estimates the state of the propagation path from communication 1 and communication 2. Specifically, the signal propagation time (Td) is estimated.
[0364]
Next, the transmitting station performs communication 3 with the receiving station. At this time, the transmitting station calculates the transmission time from the estimated signal propagation time (Td) and the processing delay time generated in the apparatus, and controls the transmission timing. The transmitting station performs time control so that the communication 3 reaches the receiving end reference time (Tk) to the receiving station. At this time, the delay amount (Ts) determined according to the additional information is added to the receiving end reference time (Tk). Communication 3 is transmitted.
As a result, the receiving station receives the communication 3 at time (Tk + Ts). The receiving station performs time synchronization by performing reception processing for the communication 3 over several symbols around the time (Tk). The reason why the time synchronization can be performed here is that the synchronization sequence signal is arranged in the transmission signal in a format known only between the transmitting station and the receiving station. That is, the receiving station having the configuration described above in Embodiment 4 can perform reception processing using a synchronization sequence signal even if transmission data does not arrive at the receiving end reference time (Tk).
[0365]
Then, the result of the time synchronization and the difference (Ts) between the times (Tk) are additionally transferred to the processing system as additional information. At this time, the following applications can be considered using the additional information.
[0366]
First, a plurality of scramble formats are defined between transmitting and receiving stations, and these are switched according to additional information. Secondly, secret information is divided into a plurality of pieces and the type is transmitted by additional information. That is, the transmitting station divides and transmits the confidential information into the first and second information, and the receiving station demodulates the first divided confidential information when the additional information (Ts) is positive, and when it is negative. Demodulates the second divided concealment information. Thirdly, a plurality of encryption patterns are prepared and switched according to additional information (Ts).
[0367]
As a result, it is difficult for other receiving stations to restore the confidential information. In addition, since the transmitting station and the receiving station that transmit and receive the confidential information can restore the confidential information even if it is not exactly the receiving end reference time (Tk), the degree of freedom in design is increased.
[0368]
(3) In the above-described embodiment, the transmission timing by the transmission station is controlled so that the signal transmitted from the transmission station reaches the reception terminal reference time set by the reception station for all information. However, the present invention is not limited to this, and such transmission / reception is performed only for transmission of particularly important confidential information such as an encryption key, and synchronization such as a pilot signal is performed for other information. Transmission may be performed at a normal timing by adding a signal. By doing so, it is possible to suppress the instability at the time of demodulation caused by not adding a synchronization signal and not performing the synchronization demodulation process, and to improve the communication quality as a whole.
[0369]
(4) In the above-described embodiment, the case where the synchronization sequence and the pseudo synchronization sequence are configured by a plurality of symbols has been described. However, the present invention is not limited to this, and each may be configured by one symbol. The pseudo synchronization sequence may also be used as a part of the pseudo symbol, information symbol, or synchronization sequence.
[0370]
Further, as the synchronization sequence, for example, a monotonous pattern repetition such as a sin wave may be used. In this case, the receiving terminal 1 that is the transmission target of the confidential information can estimate the start time of the synchronization sequence, whereas the receiving terminal 2 cannot estimate which pattern is the start time of the synchronization sequence. Therefore, even if a part of the synchronization sequence is a pseudo synchronization sequence, the reference phase obtained from the synchronization sequence changes (rotates) depending on the timing, so that the same effect as in the above embodiment can be obtained.
[0371]
Further, it is not necessary to limit the synchronization sequence to one type, and a plurality of types of synchronization sequences may be used. In this way, it becomes more difficult for a third party to demodulate and decode the secret information. Furthermore, if the format indicating the arrangement of information symbols and pseudo-symbols is changed depending on the type of synchronization sequence, higher security can be ensured.
[0372]
(5) Further, in the above-described embodiment, the case where the pseudo information is put on the pseudo symbol has been described. However, the present invention is not limited to this, and the pseudo symbol has an error detection function and an error correction function for the first regular information. You may make it mount as 2nd regular information. Further, it can be replaced with a convolutional code sequence, an information sequence represented by a block code sequence, and its pseudo information sequence.
[0373]
(6) In the above-described embodiment, the case where communication is performed via the two propagation paths of the first propagation path and the second propagation path by providing two transmission units in the transmission station has been described. The invention is not limited to this, and the number of transmission paths may be three or more by providing three or more transmission units.
[0374]
Furthermore, in the above-described embodiment, the case where two propagation path communications are realized by providing two transmission units in the transmission station has been described. However, the method for realizing a plurality of propagation path communications is not limited to this. Different propagation path communications can also be realized by arranging the transmitters at different positions. Moreover, the transmitting unit may be installed at the same position, and an antenna in which the directivity of each transmitting unit is narrowed may be applied. Further, a single transmission unit may be used, and an adaptive array antenna may be applied to the transmission unit, and different communication propagation paths may be formed by utilizing characteristics such as reflection and diffraction of radio waves. In short, it is only necessary to form a plurality of propagation paths that can be shared only between wireless communication stations that communicate secret information with each other.
[0375]
(7) In the above-described embodiment, for simplification of description, the description has been given assuming that the power of the pseudo symbol is 0. However, the power of the pseudo symbol does not have to be 0. In order to reduce interference with significant symbols, the pseudo symbol power may be sufficiently reduced. Further, the pseudo symbol may be divided into a plurality of parts so that the power resulting from the vector synthesis is sufficiently small.
[0376]
(8) In the above-described embodiment, as an example of the polarization state estimation, the angle formed by the major axis of the elliptically polarized wave p and the antenna and the flatness ratio are obtained, but the configuration shown in FIG. 21 and FIG. Of these, by using only the electric field intensity detection unit 1020 and the electric field intensity control unit 1021, only the approximate major axis angle may be obtained to control the polarization plane. As a method of controlling the polarization plane, A simple configuration may be used.
[0377]
In the above-described embodiment, the case of using linearly polarized waves has been described. However, the present invention is not limited to this, and the same effect can be obtained for circularly polarized waves. In this case, vertical polarization and horizontal polarization are replaced with right-handed and left-handed polarized waves.
[0378]
(9) In Embodiments 10 and 11 described above, the case where communication is performed using one propagation path between the transmitting station and the receiving station has been described. However, the present invention is not limited to this, and a plurality of propagation paths are also used. Obviously, similar communications can be achieved.
[0379]
In this case, if the communication using the first propagation path and the communication using the second propagation path are performed at different times, a time diversity effect can be obtained. Conversely, if both communications are performed at the same time, a path diversity effect can be obtained. Naturally, it is more difficult for a third party to estimate two or more propagation paths than to estimate a single propagation path. Therefore, if information is distributed to multiple propagation paths, the security of confidential information will be greatly increased. Can be expensive.
[0380]
(10) In the above-described tenth embodiment, the dipole antenna is exemplified as an antenna. However, the antenna is not limited to the type of antenna, and a helical antenna, a planar antenna, a parabolic antenna, a Yagi antenna, and all other antennas are used. Similar effects can be obtained. Furthermore, if pseudo information is emitted in a direction not related to communication using an adaptive array antenna technology that electrically controls directivity using a plurality of antennas, it becomes more difficult for a third party to intercept confidential information. can do. In addition, the angle of the polarization plane can be changed together with the radiation characteristics. In addition, if an antenna such as an array antenna that can control the directivity is used, application to a communication method using a plurality of propagation paths becomes easy.
[0381]
(11) In the above-described embodiment, the description has been made focusing on the security of the confidential information. However, in addition to the propagation environment estimation performed at the time of the communication of the confidential information described above, the propagation environment is also estimated in the subsequent communication. If the estimation results are compared, it is possible to authenticate whether or not the receiving station is a communication partner of confidential information at the transmitting station.
[0382]
(12) In the above-described tenth and eleventh embodiments, the case where a polarization estimation signal is output for propagation environment estimation has been described. However, the polarization estimation signal may be a sine wave, and may be one symbol or more. It may be a configured signal sequence.
[0383]
Furthermore, in the above-described Embodiments 10 and 11, the case where the polarization angle rotation angle and amplitude are detected in the propagation path by using the polarization estimation signal as a linear polarization has been described. For example, if the signal for estimating the polarization is transmitted at different times or the signals for estimating the polarization orthogonal to each other are assigned and multiplexed and transmitted, the signals for estimating the polarization can be separated. Even the rotation and phase difference of the polarization can be detected between the transmitting side and the receiving side.
[0384]
(13) Further, in the above-described Embodiment 12, the case where pseudo information is code division multiplexed and transmitted to a receiving station in addition to the confidential information using the spread code has been described, but the present invention is not limited to this, For example, each data may be frequency division multiplexed or orthogonal frequency division multiplexed for transmission.
[0385]
(14) In Embodiment 12 described above, the case where the spreading gains of the code sequences used for the first information (secret information) and the second information (pseudo information) are made equal is described. Also, orthogonality is not always necessary, and even if the same code sequence is given to the first information and the second information and spread if the reception power of the receiving station is controlled so that a sufficient difference in received power is generated. Alternatively, a configuration in which the code length is 1 (that is, no spreading) can be realized. In this case, in the received signal intercepted by the third party, the second information signal on which the pseudo information is superimposed becomes an interference wave, so the third party cannot obtain the first information.
[0386]
In addition, although it has been described here that the present invention can be implemented even if the same code is assigned to the first information and the second information, control is performed so that the reception power when the second information is spatially combined at the receiving end is sufficiently small. In this case, the received signal is almost only the first information, and there is no need to separate the multiplexed signals. That is, the same effect can be obtained without performing code spreading at the multiplexing stage.
[0387]
Therefore, the first information and the second information are superimposed only by controlling the received power at the receiving end of the receiving station to be large and the other power sufficiently small relative to the estimated propagation path condition. All you need to do is If it does in this way, confidential information can be transmitted by communication 2 without reducing transmission efficiency. In this case, if there is a power difference of about 1 dB or more with respect to the power of the signal having a large total power of the small signal, these can be separated on the receiving side.
[0388]
(15) In the above description, a code division multiplexing (CDMA) system in which a spreading code is assigned to each carrier is described as a multiplexing system. However, similar effects can be obtained even if OFDM multiplexing is used. That is, in the case of CDMA, the combined power for each spreading code is controlled, but in the case of applying OFDM, the combined power for each subcarrier may be controlled. For example, subcarriers may be divided into a plurality of groups (for example, odd subcarriers and even subcarriers), and the combined power for each subcarrier group may be controlled.
[0389]
(16) In the twelfth embodiment, the case where the multiplexed second information is used as pseudo information has been described. However, the second information is not limited to pseudo information, and may be information on other channels, for example. In this way, transmission efficiency can be increased. Also, both the first information and the second information can be transmitted as confidential information, and the first information and the second information can be separated and decoded at the receiving station according to the magnitude of the received power.
[0390]
Furthermore, in addition to the first information and the second information transmitted from the transmitting station, information such as the power values of both, the order of the magnitudes, or the power ratio of the both may be superimposed and transmitted. Further, the number of multiplexed data to be transmitted in communication 2 is not limited to two or three, and four or more pieces of information may be multiplexed and transmitted. In this case, the receiving station can separate and decode these signals into information of 1st to nth (n is a natural number of 2 or more) according to the magnitude of the received power. In this way, even if a third party tries to intercept, since the propagation path is different, the correct order of the received power cannot be obtained, so the confidentiality of information is improved.
[0390]
(17) In Embodiment 12 described above, the transmission station has two transmission / reception units, but the number of transmission / reception units is not limited to two. In addition, when controlling the radiation characteristics using an array antenna, it is known that if the antenna element is N, only N−1 null characteristics can be created such that the signal is canceled by spatial synthesis and the signal power becomes zero. . A method using this feature will be described with reference to FIG.
[0392]
As shown in FIG. 35 in which parts corresponding to those in FIG. 29 are assigned the same reference numerals, in the wireless communication system 1300, a third transmission / reception unit 1302 is added to the transmission station 1301, and a third propagation path 1307 is newly formed as a propagation path. Is done.
[0393]
Similarly to Embodiment 12 described above, the transmission station 1301 receives the propagation path estimation signal as a known signal from the reception station 1202, so that the propagation environment estimation unit 1303 performs the first propagation path 1305 and the second propagation path 1306. The propagation environment of the third propagation path 1307 is estimated.
[0394]
Next, the transmitting station 1301 performs code division multiplexing on three types of information for three channels and transmits the information to the receiving station 1202. The channels assigned to each are selected so that the spreading gains are equal and in an orthogonal relationship.
[0395]
At this time, the confidential information is used as the first information. Based on the estimation results of the first propagation path 1305, the second propagation path 1306, and the third propagation path 1307 in the estimated propagation path environment, the reception + reception end of the receiving station 1202 Send the data so that the reception status is optimal. Here, control is performed so that the reception power is maximized as the optimum reception state. Based on the estimation results of the first propagation path 1305, the second propagation path 1306, and the third propagation path 1307 out of the estimated propagation path environment, the received power is minimum at the receiving end of the receiving station 1202. Null control is performed so that
[0396]
At this time, one of the two controllable null characteristics is used, and the other null characteristic is set so that communication can be maintained in an appropriate state. Further, pseudo information is used as the third information. Based on the estimation results of the first propagation path 1305, the second propagation path 1306, and the third propagation path 1307 in the estimated propagation environment, the reception power is minimum at the receiving end of the receiving station 1202. Null control is performed so that At this time, of the two null characteristics, one null characteristic is the same as the second information, but the other null characteristic is transmitted under null control so as to be different from the second information.
[0397]
The three information signals radiated in this way are spatially synthesized and received by the receiving station 1202. As a result of spatial synthesis, at the receiving end, the first information is received as a signal having a high power, and the second information and the third information are received as a signal having a low power in a code division multiplexed state.
[0398]
The received signal series can be despread using a spreading code to extract each other's signals. Here, since the spreading gains are set equal, one has a large power and the other has a small power according to the received power of each information. The receiving station 1202 can easily extract only the confidential information by selecting the information of the channel with a large power as the confidential information and treating the information of the other channel as the pseudo information.
[0399]
Here, consider a case in which confidential information is intercepted and restored by a third party. In this case, the reception state of the first information and the reception state of the second and third information differ depending on the place of reception. If this reception state cannot be known in advance, it cannot be known from the received signal sequence.
[0400]
Further, the radiation characteristic of the multiplexed third information is controlled so that a null is formed at the receiving end of the receiving station 1202 as in the second information, but is controlled so that the null states are different from each other. Even when the null is controlled here, the null may be formed in addition to the control location depending on the condition. For example, even if the second information is near the null at the third party's reception position, the third information Are unlikely to be in a similar state. As a result, the probability that the secret information is leaked to a third party is greatly reduced. Thus, in the configuration in which three transmission / reception units are provided, the secrecy can be significantly improved as compared with the case where two transmission / reception units are used.
[0401]
Similarly, by increasing the number of transmission / reception units of the transmission station to 4, 5, and 6, it is possible to increase the number of multiplexing and further increase the secrecy. If the number of multiplexing is suppressed with respect to the number of transmission / reception units and the degree of freedom of null control per information to be multiplexed is improved, the accuracy can be improved and the control can be enhanced. Moreover, if the parameter setting used for null control is changed for each symbol so that null portions formed outside the control do not overlap, the possibility of confidential information leaking to a third party can be further suppressed.
[0402]
In addition, the case where the receiving station is controlled to reduce the reception power of the second information and the third information by performing the null control on the second information and the third information has been described. However, the reception of the second information and the third information is described. If the power is controlled differently from the first information and the magnitude information of the respective received power is added to the first to third information, higher confidentiality can be provided. Furthermore, if the control is changed every symbol, leakage can be further prevented.
[0403]
(18) In the above description, a case has been described in which the transmission power of the first information, which is confidential information, is equal to the transmission power of the other information multiplexed thereon. However, these are not necessarily equal. For example, if the transmission power of the first information is set lower than the other information, the confidentiality can be improved. On the contrary, if the transmission power of the first information is set higher than that of the other information, the communication of the confidential information can be stabilized. These may be adjusted as appropriate according to the environment of the wireless communication system to be provided.
[0404]
(19) In the above-described embodiment, the propagation path estimation signal is a known signal for the sake of explanation, but the propagation path can be estimated even if it is not a known signal. However, there is an advantage that the estimation is easy if it is a known signal and the influence of noise can be reduced. If the envelope is a constant signal, the CMA method, which is an adaptive array antenna estimation algorithm, can be applied. Further, the propagation path estimation signal is necessary when the propagation environment changes. If the propagation path formed between the transmitting station and the receiving station is fixed, the confidential communication is performed by measuring its characteristics in advance. It can be performed.
[0405]
(20) Although an array antenna has been described as an example of an antenna when a plurality of transmission / reception units are provided, the configuration of the array antenna is not limited. If the coherency of the modulated wave can be controlled, the same control can be performed using two or more transmitting stations. If an antenna that can control radiation characteristics electrically, such as an array antenna, is used, the transmitting station can communicate with another radio station independently of the communication with the receiving station that transmits confidential information. it can. In this case, as described above, the communication signals can be multiplexed and transmitted to the respective receiving stations at the same time and at the same frequency. Thus, the effect of preventing leakage of confidential information to a third party is further enhanced by increasing the number of multiplexing. When there is no other receiving station and communication is performed only with a pair of transmitting station and receiving station, the security of the confidential information can be maintained by multiplexing the pseudo information as described above.
[0406]
(21) In the above-described embodiment, code division multiplexing has been described as an example of a multiplexing method for multiplexing a plurality of types of information on confidential information. However, each information can be selected using the radiation characteristic control of the array antenna. Therefore, it is not particularly limited to the multiplexing method.
[0407]
(22) Further, the present invention can be used without limiting the modulation method and the multiplexing method. For example, communication 1, communication 2, communication 3, communication 4,... Described above in the first to fourth embodiments, and communication 10, communication 11, communication 20, described above in the fifth, sixth, and seventh embodiments. Different modulation schemes and multiplexing schemes can be applied to each of the communication 21, the communication 30, the communication 31, the communication 4, and so on. In particular, when estimating the propagation environment, applying spread spectrum to the communication 1 as in Embodiment 1 makes it possible to perform estimation processing that is strong against fading and has high estimation accuracy.
[0408]
Further, an ASK modulation method, FSK modulation method, differential code modulation method, or OFDM (Orthogonal Frequency Division Multiplexing) method may be applied. When these modulation methods are used, there is an advantage that it is not particularly necessary to perform phase synchronization.
[0409]
Also, PSK modulation, QAM modulation, pulse modulation, etc. can be applied. Furthermore, since it does not depend on the multiplexing system, FDMA multiple waves, CDMA multiple waves, OFDM multiple waves, and the like can be applied.
[0410]
That is, in the above-described embodiment, the case where transmission of confidential information is controlled in units of time or channels has been described, but if a multicarrier modulation scheme such as a CDMA multiple wave or an OFDM multiple wave is used, the polarization plane for each carrier. Can be controlled. Therefore, more sophisticated control can be performed by performing control by carrier in addition to control by time and channel. As a result, it is possible to dramatically improve the confidentiality of the third party.
[0411]
Further, if the symbol rate in communication 3 of the first embodiment is set lower than the symbol rates of communication 1 and communication 2, the accuracy of the propagation path delay can be relatively improved. At this time, the accuracy of the positional relationship between the transmitting station and the receiving station is determined by the symbol rate of the communication 3 and the processing time from the communication 1 to the communication 3, so if individual values are set according to the system design Good.
[0412]
Similarly, the positional relationship between the transmitting station and the receiving station according to the symbol rate of communication 30 and communication 31 in the fifth, sixth, and seventh embodiments and the processing time from communication 10 to communication 30 or communication 11 to communication 31. Therefore, it is only necessary to set individual values according to the system design.
[0413]
As described above, the present invention is not limited to the modulation scheme and the multiplexing scheme, and does not affect other information layers, and thus has high affinity with the conventional system. Further, since higher security can be realized by combining with encryption technology, it can be widely applied to the information communication field that requires high security such as personal information, financial information, and confidential information.
[0414]
(23) Further, in the above-described embodiment, by estimating the signal propagation time in the propagation path and using this signal propagation time to synchronize transmission / reception between transmission and reception, other users cannot restore confidential information. However, the same effect as that of the above-described embodiment can be obtained even if another propagation path environment that can be shared only by wireless stations performing communication is used. The propagation environment includes, for example, a multipath environment and a fading environment, and these may be used in combination. Further, higher security can be realized by applying to communication including a device difference between the transmitting station and the receiving station (for example, a difference in reference frequency).
[0415]
(24) In the above-described embodiment, for the sake of simplicity, the radio station that transmits information including confidential information is described as the transmitting station, and the radio station that receives the information is described as the receiving station. However, the present invention is not limited to this, and secret information may be transmitted and received mutually.
[0416]
(25) Further, in the above-described embodiment, the transmitting station and the receiving station share the same reference period by transmitting a control signal including the network reference time as a signal for the transmitting station to synchronize with the receiving station. However, although the case where the network time Tk is set as the arrival time of the confidential information has been described, the present invention is not limited to this, and even if the same reference time is not shared, it is set at the receiving station as in the above-described embodiment. Confidential information can be reached at the time when it is done.
[0417]
This will be described with reference to FIG. The transmitting station transmits communication 1 at time t1. It is assumed that the communication 1 does not include reference time information unlike the embodiment. The receiving station receives communication 1 at time t2. Then, the receiving station transmits the communication 2 at time t3 when the time T1 has elapsed. The transmitting station receives communication 2 at time t4. Further, after a certain time elapses (the time does not need to be shared between the transmission and reception), the receiving station transmits the communication 2 ′ at time t5. The transmitting station receives the communication 2 ′ at time t6. The transmitting station transmits communication 3 at time t7 after time Td has elapsed from time t6. Here, the transmitting station and the receiving station hold, as shared information, a time T1 from reception 1T to transmission 2T and a time T2 from transmission 2′T to reception 3T.
[0418]
Here, when the signal propagation time Tw is established, the following relationship is established.
t4−t1 = 2 × Tw + T1 (1)
Therefore, the signal propagation time Tw is given by
Tw = (t4-t1-T1) / 2 (2)
It can be expressed as. In order to reach the receiving end reference time 1 (time point t8), the time point t7 that the transmitting station should transmit is based on the relationship with the time points t5, t6, and T2.

That is, the adjustment time Td (= t7−t6) is
Td = T2-2 × Tw = T2- (t4-t1-T1) (4)
It can be expressed as.
[0419]
As described above, the adjustment time Td for the transmission timing of the transmission station can be expressed by the time points t1 and t4 known to the transmission station and the shared time information T1 and T2, so that the transmission station determines the time point based on the equation (4). Transmission data including confidential information can be transmitted at a transmission timing such that the confidential information reaches the receiving station at t8.
[0420]
【The invention's effect】
As described above, according to the present invention, when transmission data including confidential information is wirelessly transmitted from the first wireless station to the second wireless station, the first wireless station is transmitted before transmitting the confidential information. And the second radio station perform signal transmission / reception to estimate the radio channel environment shared only between the first radio station and the second radio station, and consider the estimated radio channel environment Since the confidential information is transmitted from the first wireless station to the second wireless station, the confidential information is transmitted with high security when transmitting the confidential information to the specific wireless station via the wireless line. A data transmission apparatus, a wireless communication system, and a wireless communication method that can be transmitted can be realized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a radio communication system according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing the configuration of the transmitting station in FIG.
FIG. 3 is a block diagram showing the configuration of the receiving station in FIG.
FIG. 4 is a sequence diagram showing a communication procedure in the radio communication system according to the first and third embodiments.
FIG. 5 is a diagram showing a propagation state of a communication signal according to the first and third embodiments
FIG. 6 is a block diagram showing a configuration of a burst signal forming unit according to the fourth embodiment.
7 is a block diagram showing configurations of a demodulation unit and a stream formation unit according to Embodiment 4. FIG.
FIG. 8 is a block diagram illustrating a configuration of a time synchronization / unique word extraction circuit according to a fourth embodiment;
9 is a signal waveform diagram for explaining the operation of the time synchronization / unique word extraction circuit of FIG. 8;
10 is a diagram illustrating a propagation state of a communication signal according to Embodiment 4. FIG.
11 is a block diagram showing a configuration of a wireless communication system according to a fifth embodiment.
FIG. 12 is a sequence diagram illustrating a communication procedure in the wireless communication system according to the fifth, sixth, and seventh embodiments.
FIG. 13 is a diagram illustrating a propagation state of a communication signal according to the fifth embodiment
FIG. 14 is a diagram showing a propagation state of communication signals according to the sixth, seventh and ninth embodiments
15 is a block diagram showing a configuration of a wireless communication system according to an eighth embodiment.
FIG. 16 is a sequence diagram showing a communication procedure in the radio communication system according to the eighth and ninth embodiments.
17 is a block diagram showing a configuration of a wireless communication system according to a ninth embodiment.
18 is a block diagram showing the configuration of the transmitting station in FIG.
19 is a block diagram showing a configuration of a wireless communication system according to a tenth embodiment.
20 is a block diagram showing the configuration of the transmitting station in FIG. 19;
21 is a block diagram showing a configuration of a propagation environment estimation unit in FIG.
22 is a block diagram showing the configuration of the radiation characteristic control unit of FIG.
FIG. 23 is a diagram for explaining the plane of polarization, electric field strength, and phase difference.
FIG. 24 is a sequence diagram showing a communication procedure in the radio communication system according to the tenth and eleventh embodiments.
FIG. 25 is a diagram for explaining the operation in the tenth embodiment;
FIG. 26 is a diagram for explaining an antenna position and a polarization plane;
FIG. 27 is a diagram for explaining an antenna position and a polarization plane;
28 is a block diagram showing a configuration of a wireless communication system according to an eleventh embodiment.
29 is a block diagram showing a configuration of a wireless communication system according to a twelfth embodiment. FIG.
30 is a block diagram showing the configuration of the transmitting station in FIG. 29. FIG.
31 is a block diagram showing a configuration of a burst signal forming unit, a beam former, and a modulating unit in FIG.
32 is a block diagram showing a configuration of a demodulation unit and a stream formation unit in FIG.
FIG. 33 is a sequence diagram illustrating a communication procedure in the wireless communication system according to the twelfth embodiment.
FIG. 34 is a diagram for explaining the spatial synthesis of electromagnetic waves.
FIG. 35 is a block diagram showing a configuration of a wireless communication system according to another embodiment.
FIG. 36 is a sequence diagram showing a communication procedure according to another embodiment.
[Explanation of symbols]
100, 500, 800, 900, 1000, 1100, 1200, 1300
Wireless communication system
101, 501, 801, 802, 901, 1001, 1201, 1301
101a, 102a, 502, 503, 1012, 1220 Transmitter
101b, 102b, 1013, 1240 receiver
101c, 904, 1006, 1205, 1303 propagation environment estimation unit
101d, 905, 1206, 1304 Propagation environment adaptation unit
102, 1002, 1040, 1101, 1202 Receiving station
102c, 1007, 1010 Time control unit
103, 504, 505, 806, 807, 906, 907, 1041, 1042, 1207, 1208, 1305, 1306, 1307
115, 132, 300, 1221 Burst signal forming section
116, 134, 1223 Modulator
118, 905a Timing control unit
120, 904a Delay amount estimation unit
122, 141, 310 Demodulator
123, 142, 320 Stream forming unit
330 Convolver circuit
312 Time synchronization / unique word extraction circuit
333 peak search circuit
334 Search range setting circuit
335 Unique word selection circuit
803, 804 network connection
805 network
902, 903, 1005, 1009, 1203, 1204, 1302
904b Power measurement unit
905b Power control unit
1003, 1004, 1102, 1103 Antenna section
1008, 1104 Radiation characteristic control unit
1210 Arrival direction estimation unit
1222 Beamformer
AN, AN11, AN12, AN13, AN20, AN21, AN30, AN60, AN61 Antenna
D1, D2, D3 User data
D4 Scramble puncture data

Claims (13)

A data transmission device that wirelessly transmits transmission data including confidential information to a wireless station,
First and second receiving means which are arranged at different positions and receive signals transmitted by the radio station;
Based on each received signal obtained by the first and second receiving means, a first signal propagation time in the first radio propagation path between the radio station and the first receiving means and the radio Estimating means for estimating a second signal propagation time in a second radio propagation path between a station and the second receiving means ;
The first and second transmission data, which are arranged at the same positions as the first and second receiving means, respectively, and contain the secret information based on the first and second signal propagation times, First and second transmission means for transmitting each transmission data at a timing of reaching the station ;
Equipped with,
The first and second transmission data are formed in the same format.
Data transmission equipment. A pseudo-symbol adding means for adding a pseudo-symbol at a position determined in advance with the wireless station in the first and second transmission data including the confidential information;
The first and second transmission means transmit the first and second transmission data to which a pseudo symbol is added to the radio station ,
The data transmission apparatus according to claim 1 . Synchronization signal adding means for adding synchronization sequence signals having a synchronous relationship to each other at a predetermined position with the wireless station in the first and second transmission data including the confidential information;
A pseudo-synchronization signal for the synchronization sequence signal, and a pseudo-synchronization signal adding means for adding pseudo-synchronization sequence signals that are in synchronization with each other ;
Data transmission apparatus according to claim 1, further comprising a. A data transmission device that wirelessly transmits transmission data including confidential information to a wireless station,
First and second receiving means which are arranged at different positions and receive signals transmitted by the radio station;
Based on each received signal obtained by the first and second receiving means, a first signal propagation time in the first radio propagation path between the radio station and the first receiving means and the radio Estimating means for estimating a second signal propagation time in a second radio propagation path between a station and the second receiving means;
When the unit communication frames of the first and second transmission data are arranged, a secret symbol is included in each of the first and second transmission data so that the secret symbols forming the secret information do not overlap each other. Pseudo symbol adding means for adding a pseudo symbol with very low power,
The first and second transmission data, which are arranged at the same positions as the first and second receiving means, respectively, and contain the confidential information based on the first and second signal propagation times, First and second transmission means for transmitting each transmission data to the wireless station at a timing of reaching the wireless station;
A data transmission apparatus comprising: A data transmission device that wirelessly transmits transmission data including confidential information to a wireless station,
First and second receiving means which are arranged at different positions and receive signals transmitted by the radio station;
Based on each received signal obtained by the first and second receiving means, a first signal propagation time in the first radio propagation path between the radio station and the first receiving means and the radio Estimating the second signal propagation time in the second radio propagation path between the station and the second receiving means, and the first signal power attenuation amount in the first radio propagation path and the second Estimating means for estimating a second signal power attenuation amount in the wireless propagation path;
Timings at which the first and second transmission data arrive at the radio station at the same time, based on the first and second signal propagation times, respectively, disposed at the same positions as the first and second receiving units, respectively. And transmitting each transmission data to the radio station and demodulating when the radio station combines and receives the first and second transmission data based on the first and second signal power attenuation amounts. First and second transmission means for transmitting the first and second transmission data to the radio station with transmission power close to a minimum level;
Comprising
The first and second transmission data are formed in the same format.
Data transmission equipment. A data transmission device that wirelessly transmits transmission data including confidential information to a wireless station,
First and second receiving means which are arranged at different positions and receive signals transmitted by the radio station;
Based on each received signal obtained by the first and second receiving means, a first signal propagation time in the first radio propagation path between the radio station and the first receiving means and the radio Estimating the second signal propagation time in the second radio propagation path between the station and the second receiving means, and the first signal power attenuation amount in the first radio propagation path and the second Estimating means for estimating a second signal power attenuation amount in the wireless propagation path;
First spreading means for spreading the secret information using a predetermined spreading code to obtain a first spread signal;
Second spreading that uses a spreading code different from the spreading code and obtains a second spreading signal by spreading the pseudo information so that a spreading gain equivalent to the spreading gain by the first spreading means can be obtained. Means,
The first and second receiving means are arranged at the same positions as the first and second receiving means, respectively, so that the first and second spread signals reach the radio station at a time set in advance with the radio station. First and second transmission means for transmitting the first and second spread signals to the radio station at a timing considering the first and second signal propagation times;
Comprising
The first and second transmission means, when the first and second spread signals reach the radio station, based on the first and second signal power attenuation amounts, The transmission power is controlled so that a difference of a certain level or more occurs between the received power value of the second spread signal and the received power value of the second spread signal,
Data transmission equipment. A data transmission device that wirelessly transmits transmission data including confidential information to a wireless station,
Receiving means for receiving a signal transmitted by the wireless station;
An estimation means for estimating a radio propagation path environment with the radio station by detecting a polarization plane of a reception wave based on a reception signal obtained by the reception means, and estimating an arrival direction of the reception signal; ,
First spreading means for forming a first spread signal by spreading the secret information using a predetermined spreading code;
A second spreading signal is formed by spreading the pseudo information using a spreading code different from the spreading code and spreading the pseudo information so as to obtain a spreading gain equivalent to the spreading gain by the first spreading means. Means of spreading,
With respect to the polarization plane detected by the estimation means, the first and second spread signals are transmitted to the radio station by a transmission wave obtained by rotating the polarization plane by a predetermined amount between the radio stations. A transmission means for transmitting to
Comprising
The transmitting means , based on the direction of arrival estimated by the estimating means, in a direction in which a difference of a certain level or more occurs between the received power value of the first spread signal and the received power value of the second spread signal. Transmitting the first and second spread signals and transmitting the pseudo data in a different direction from the wireless station;
Data transmission equipment. The estimating means further estimates the direction of arrival of the received signal,
The transmission unit, the data transmission apparatus according to any one of claims 1 to 6 for transmitting the transmission data including the confidential information in the direction considering the direction of arrival. The transmission means transmits transmission data including the confidential information in the direction of the radio station based on the direction of arrival estimated by the estimation means, and directs pseudo data in a direction different from the radio station. The data transmission device according to claim 8 . The transmission means includes an adaptive array antenna, and when transmitting transmission data including the confidential information, weights each array antenna so that directivity is directed in the arrival direction, and transmits the pseudo data. The data transmission device according to claim 9 , wherein each array antenna is weighted so that directivity is directed in a direction other than the arrival direction. Comprising data rearranging means for rearranging transmission data including the confidential information in a predetermined order with the wireless station;
The transmission unit, the data transmission apparatus according to any one of claims 10 to transmit data rearranged by the data reordering unit from claim 1 to be transmitted to the radio station. A wireless communication system for wirelessly transmitting transmission data including confidential information from a first wireless station to a second wireless station,
The first radio station includes a receiving unit that receives a signal transmitted from the second radio station, and a polarization plane detecting unit that detects a polarization plane of a received wave based on a received signal obtained by the receiving unit. And transmission data including the confidential information is transmitted by a transmission wave obtained by rotating the polarization plane by a predetermined amount between the first and second radio stations with respect to the detected polarization plane. Transmission means for transmitting to the wireless station of
The second radio station outputs the polarization plane detection signal to the first radio station and receives the transmission data including the confidential information transmitted by the first radio station. Rotate by a predetermined amount between the first and second radio stations between the time when the polarization plane detection signal is output and the time when transmission data including the confidential information is received .
Wireless communication system. The first and second radio stations have a predetermined process between the first and second radio stations to rotate the plane of polarization by a predetermined amount between the first and second radio stations. The wireless communication system according to claim 12 , wherein the wireless communication system is repeatedly performed at predetermined intervals.

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