JP4119926B2 - Wireless system and wireless communication method - Google Patents

Description

  The present invention relates to a TDMA radio system and radio communication method for performing voice group communication loopback in a multi-zone, and more particularly to a radio system and radio communication method to which site diversity is applied.

  In non-voice communication, site diversity reception can be performed on a packet basis by adding a transmission station ID for each packet. On the other hand, in voice group communication, there is usually no room for adding a transmission station ID to each burst, and if transmission right control is not performed, the transmission station is not limited to one station. If this is done, there is a risk of mixing signals from a plurality of mobile stations. Therefore, in the multi-zone method = distributed reception method, the route selection for each press is performed by comparing the reception input level (RSSI (Received Signal Strength Indicator)) of each base station at the start of transmission of the mobile station.

  Normally, site diversity uses a plurality of diversity branches on the receiving side and combines them into one received signal. In this reception diversity, the influence of fading can be reduced by the control station selecting a branch (in this case, a base station) having the maximum received signal strength from the mobile station.

  Hereinafter, an example of site diversity will be described. FIG. 8 is a diagram illustrating an example of conventional wireless communication. In FIG. 8, the control station 10 performs control related to communication and communication using a base station 21, a base station 31, and a base station 41 and a link line such as a micro-multiplex line or a wired line. The base station 21 covers wireless communication in the wireless zone 22. The mobile station 23 in the radio zone 22 communicates with the base station 21. Similarly, the base station 31 communicates with the mobile station 33 in the radio zone 32, and the base station 41 communicates with the mobile station 43 in the radio zone 42.

  Here, the transmission signal of the mobile station 53 existing in the overlapping part of the wireless zone 32 and the wireless zone 42 reaches the base station 31 and the base station 41, and the control station selects one according to the propagation path environment. Communicate.

  Hereinafter, configurations of the control station and the base station will be described. FIG. 9 is a block diagram illustrating configurations of a control station and a base station. The control station 10, base station 21, base station 31, base station 41, mobile station 23, and mobile station 53 shown in FIG. 9 are the control station, mobile station, and base station shown in FIG. 8, respectively.

  In FIG. 9, the control station 10 includes a link line channel codec unit 11, an RSSI comparison unit 12, a D / A conversion unit 14, a speaker 15, a microphone 16, an A / D conversion unit 17, and a selector 18. The interrupt circuit 19 is mainly configured.

  The base station 21 is mainly composed of an antenna 24, a duplexer 25, a receiving unit 26, and a transmitting unit 27. Similarly, the base station 31 mainly includes an antenna 34, a duplexer 35, a reception unit 36, and a transmission unit 37. The base station 41 mainly includes an antenna 44, a duplexer 45, a reception unit 46, and a transmission unit 47.

  First, a case where the mobile station communicates with one base station will be described. Here, a case where the mobile station 23 communicates with the base station 21 will be described. The high-frequency signal transmitted by the mobile station 23 is received via the antenna 24 and the duplexer 25, and the receiving unit 26 performs processing such as demodulation to convert it into a received signal. The received signal is multiplexed with a received signal strength indicator (RSSI) and a control signal and output to the link channel channel codec unit 11.

  The received signal is output to the D / A conversion unit 14 via the link line channel codec unit 11 and the selector 18, is digital-analog converted by the D / A conversion unit 14, and is output from the speaker 15 as sound.

  The audio input from the microphone 16 is converted from analog to digital by the A / D converter 17 and output to the transmitter 27 via the interrupt circuit 19, where the transmitter 27 performs processing such as modulation and conversion to radio frequency. Performed and converted to a high frequency signal. This high frequency signal is transmitted to the mobile station 23 via the duplexer 25 and the antenna 24.

  Next, a case where the mobile station can communicate with a plurality of base stations will be described. Here, a case will be described in which the control station 10 selects one of the signals received by the base station 31 and the base station 41 as the transmission wave of the mobile station 53.

  The high frequency signal transmitted by the mobile station 53 can be received by both the base station 31 and the base station 41. This signal is received through the antenna 34 and the duplexer 35, and is subjected to processing such as demodulation in the receiving unit 36 and converted into a received signal. The received signal is output to the link line channel codec unit 11. Similarly, this signal is received via the antenna 44 and the duplexer 45, and the receiving unit 46 performs processing such as demodulation and converts it into a received signal. The received signal is output to the link line channel codec unit 11.

  The reception signal of the base station 31 and the reception signal of the base station 41 are output to the RSSI comparison unit 12 and the selector 18 via the link line channel codec unit 11, respectively. The RSSI comparison unit 12 compares the quality of received signals output from a plurality of base stations, for example, RSSI, and selects a base station with high received signal quality as the communication path of the mobile station 53. Then, as a result of selecting the base station, the RSSI comparison unit 12 outputs information on the selected base station of the base station 31 or the base station 41 to the selector 18.

  The selector 18 outputs the received signal received by the base station selected as the communication path of the mobile station 53 to the D / A converter 14 according to the information output from the RSSI comparator 12. The interrupt circuit 19 outputs the output of the selector 18 to the base station 21, the base station 31, and the base station 41 as a transmission signal.

  In the base station 21, the transmission signal is subjected to processing such as modulation and conversion to a radio frequency in the transmission unit 27, and converted into a high frequency signal. This high frequency signal is transmitted to the mobile station 23 via the duplexer 25 and the antenna 24.

  Similarly, in the base station 31, the transmission signal is subjected to processing such as modulation and conversion to a radio frequency in the transmission unit 37, and converted into a high frequency signal. This high frequency signal is transmitted to the mobile station 23 via the duplexer 35 and the antenna 34. Similarly, the base station 41 transmits a transmission signal to the mobile station 53.

  As described above, in radio communication using site diversity, a plurality of base stations receive signals transmitted from mobile stations, and the control station selects a base station having the maximum RSSI of the received signal.

  In mobile communication, a mobile station may have a built-in battery to supply power to a communication device. Since there is a limit to the amount of power that can be supplied by the battery, the time during which the mobile station can communicate is limited when the power consumption of the communication device built in the mobile station is large. Therefore, when the mobile station is not communicating, the power consumption is reduced as a so-called standby state for a portion not used in the communication device, for example, a DSP (Digital Signal Processor), in a state where power supply is stopped. .

  When making a call, the signal is changed according to the presence or absence of the call to notify the communication partner of the transmission, and the communication apparatus receives the notification and turns on the DSP to switch from the standby state to the receivable state. For example, the signal processing circuit at the subsequent stage of the wireless processing circuit consumes several tens of times the power of the wireless processing circuit. Therefore, when processing is not performed, power consumption can be reduced by stopping power supply to the signal processing circuit. Can be reduced.

  However, in the conventional apparatus, when a base station for communication is selected, a route with poor channel quality may be selected by mistake. In the press talk type communication, there is a problem that it is necessary to select a route only at the moment of start of communication, and it is difficult to determine that good line quality can be maintained during one press period.

  Further, in the conventional apparatus, when a signal for starting a call is recognized and a part of the apparatus is turned on to be usable, there is a problem that it takes a long time to start the apparatus and the signal at the beginning of the call cannot be reproduced correctly there were.

  The present invention has been made in view of this point, and a first object of the present invention is to provide a base station device, a control station device, a communication terminal device, and a wireless communication method for selecting a route with good channel quality. A second object of the present invention is to provide a base station device, a control station device, a communication terminal device, and a wireless communication method that enable signal reproduction at the beginning of a call.

A radio system of the present invention is a radio system that performs site diversity in a multi-zone scheme configured by a plurality of base station apparatuses and control station apparatuses, and the base station apparatus includes a receiving unit that receives radio signals; initially extracting the maximum value of the received signal strength from the second burst received in the first burst and a second received by the receiving means, the extracted the maximum value to the control station apparatus as the selection information of the diversity branches anda maximum value retrieving means for outputting, the control station apparatus, take you select configuration the maximum value and the base station apparatus becomes therein by comparing said selection information for each of the diversity branches.

Wireless communication method of the present invention is a wireless communication method for performing site diversity in a multi-zone system constituted by a plurality of base stations and a control station apparatus, said base station apparatus, and Luz step to receive the radio signal , the base station apparatus, first extracts the maximum value of the received signal strength from the second burst received in the first burst and the second received, the control extracted the maximum value as the selection information of the diversity branches has a Luz step to output to the station apparatus, wherein the control station apparatus, and a Luz step to select the maximum value as it was the base station apparatus therein by comparing said selection information for each of the diversity branches I did it.

  According to the radio system and radio communication method of the present invention, when selecting a communication path (base station apparatus) in site diversity, the quality of the signal received by each base station apparatus is compared, and the base with the best signal quality is obtained. By selecting the station apparatus as a communication path for receiving a signal from the communication terminal apparatus, a path with good channel quality can be selected.

  In addition, according to the wireless system and wireless communication method of the present invention, the signal at the beginning of the call can be reproduced by transmitting a signal for notifying the communication in advance before transmitting the transmission signal including data. Furthermore, since the DSP operating time during standby can be greatly reduced, the mobile station can be used for a long time.

  The fluctuation distribution of the reception input level of the mobile radio link is classified into a long interval median value fluctuation, a short interval median value fluctuation, and an instantaneous value fluctuation. It is known that the median fluctuation in the long section follows an Okumura curve (秦 approximation formula), the median fluctuation in the short section follows a lognormal distribution with a different standard deviation for each line frequency band, and the instantaneous value fluctuation follows a Rayleigh distribution.

  In a press talk call, since the transmission time is short, the fluctuation of the propagation path during this time can be ignored, so the median value of the short section during transmission can be regarded as almost constant, and its instantaneous value Can be expected to follow the Rayleigh distribution.

  This instantaneous value fluctuation is also called Doppler fading, and it is also known that it has a spectral characteristic defined by a Doppler frequency determined by the traveling speed and the line frequency of the mobile station.

  That is, the instantaneous value fluctuation is an irregular fluctuation whose fundamental period is the reciprocal of the Doppler frequency. Therefore, when attempting to estimate the average value of the distribution, at least an observation time longer than the above basic period is required. Therefore, when the Doppler frequency is 5 Hz, an observation time of at least 200 msec is required.

  On the other hand, when estimating the shortest median between multiple distributions, it is most accurate to compare the sample values collected within the observation time. It was confirmed by simulation.

  The present inventor pays attention to the above points and makes it possible to select a route with good channel quality even in short-time observation by comparing the reception quality of the portion not affected by fading. I found.

  That is, the first essence of the present invention is that when selecting a communication path in site diversity, the base station apparatus compares the best quality parts of the signals received by each base station apparatus, and the quality of this signal is the best. A certain part is to select the base station apparatus having the best quality as the communication partner of the communication terminal apparatus. Specifically, the maximum value of the received signal strength is compared, and the base station having the largest value is selected as the communication path.

  In addition, when a communication device in a standby state for reducing power consumption supplies power to a circuit that is turned off in order to shift from a standby state to a reception state, the reception operation can be sufficiently performed. take time.

  The inventor has paid attention to the above points and found that the signal can be reproduced at the beginning of the call by shifting the circuit from the standby state to the reception state before the communication apparatus receives the signal in advance.

  That is, the second essence of the present invention is that a signal processing circuit is provided when a signal for notifying communication is transmitted in advance and a signal for notifying communication is received on the receiving side before transmitting a transmission signal including data. Is to be able to operate.

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

  First, the configuration of the control station of the present invention will be described. FIG. 1 is a block diagram showing an example of a configuration of a control station according to an embodiment of the present invention.

  In FIG. 1, the control station 100 communicates with base stations 200-1, 200-2, ..., 200-n. The base stations 200-1, 200-2, ..., 200-n perform wireless communication with the mobile station 300-1 and the mobile station 300-2, respectively, and control with the mobile station 300-1 and the mobile station 300-2. The communication of the station 100 is relayed.

  1 includes a link line channel codec unit 101, an RSSI comparison unit 102, a D / A conversion unit 104, a speaker 105, a microphone 106, an A / D conversion unit 107, a selector 108, It is mainly composed of an interrupt circuit 109.

  The link line channel codec unit 101 separates the signals transmitted from the base stations 200-1 to 200-n into RSSI and data included in the header, outputs the RSSI value to the RSSI comparison unit 102, and selects voice information as a selector. It outputs to 108.

  The RSSI comparison unit 102 compares the RSSI output from the link line channel codec unit 101 and gives the route number of the base station having the largest RSSI value to the selector 108 as control information. Once the route number is confirmed, no change is made until the communication (press talk) is completed. When there is a signal to be transmitted from the control station to the mobile station, the interrupt circuit 109 prioritizes the uplink signal from the selector 108 and sends it to each base station.

  The D / A conversion unit 104 converts the audio information output from the selector 108 from digital to analog and outputs it to the speaker 105. The speaker 105 outputs the reception signal output from the D / A conversion unit 104 as sound. The microphone 106 inputs sound and outputs a sound signal to the A / D conversion unit 107. The A / D converter 107 converts the audio signal output from the microphone 106 from analog to digital and outputs a transmission signal to the interrupt circuit 109.

  The selector 108 outputs the signal output from the link line channel codec unit 101 to the D / A conversion unit 104 according to the comparison result of the RSSI comparison unit 102. When there is a signal to be transmitted from the control station to the mobile station, the interrupt circuit 109 performs communication by giving priority to the transmission signal.

  Next, a radio communication apparatus provided in the base station will be described. FIG. 2 is a block diagram showing a configuration of a wireless communication apparatus according to an embodiment of the present invention. The radio communication device 200 in FIG. 2 is a radio communication device mounted on each of the base stations 200-1 to 200-n in FIG.

  2 includes an antenna 201, a duplexer 202, a front end unit 203, an orthogonal demodulation unit 204, an A / D conversion unit 205, a synchronization unit 206, a demodulation unit 207, and a decoding unit. 208, maximum value search unit 209, memory 210, magnitude comparison unit 211, encoding unit 212, notice burst creation unit 213, modulation unit 214, D / A conversion unit 215, and orthogonal modulation unit 216. And a PA unit 217, a synthesizer 218, and an interface 219 for the control station.

  The wireless communication device 200 relays communication with the mobile station 300 and the control station 100. Note that the control station 100 may be a device that operates as an upper base station.

  In FIG. 2, an antenna 201 converts a high-frequency signal transmitted from a communication partner (mobile station) into an electric signal and outputs a received signal to the duplexer 202. Further, the antenna 201 radiates the transmission signal output from the duplexer 202 toward the mobile station as a high frequency signal. The duplexer 202 outputs the reception signal output from the antenna 201 to the front end unit 203. In addition, the transmission signal output from PA section 217 is output to antenna 201.

  The front end unit 203 amplifies the reception signal and outputs it to the quadrature demodulation unit 204. The quadrature demodulation unit 204 multiplies the reception signal amplified in the front end unit 203 by the carrier signal output from the synthesizer 218 to perform quadrature demodulation, and outputs the result to the A / D conversion unit 205. The A / D conversion unit 205 performs analog-digital conversion on the reception signal output from the quadrature demodulation unit 204 and outputs the result to the synchronization unit 206.

  The synchronization unit 206 captures synchronization of the received signal output from the A / D conversion unit 205. Synchronization section 206 outputs the received signal to demodulation section 207. Demodulation section 207 demodulates the received signal output from synchronization section 206 and outputs it to decoding section 208 and maximum value search section 209. The decoding unit 208 decodes the reception signal output from the demodulation unit 207, extracts reception data and a channel identifier, and outputs the received data and the channel identifier to the control station 100 via the control station interface 219.

  Maximum value search section 209 finds the maximum value of the reception level for the received signal sampled at a predetermined code identification point, and outputs this maximum value to memory 210. In the case of TDMA wireless communication, the maximum value search unit 209 searches for the maximum value of the reception level in units of bursts and outputs it to the memory 210.

  The memory 210 stores the maximum value of the reception level output from the maximum value search unit 209. Then, the memory 210 outputs the stored maximum values to the magnitude comparison unit 211. For example, the maximum value of the first burst received first and the maximum value of the second burst received second are output to the magnitude comparison unit 211.

  The magnitude comparison unit 211 compares the two maximum values output from the memory 210 and outputs the maximum value having a large reception level to the control station 100 as a route selection signal. The control station 100 compares the values of the route selection signals output from the plurality of base stations, and selects the base station that has output the route selection signal having the largest value as the communication partner with the mobile station.

  The encoding unit 212 encodes the transmission data and channel identifier output from the control station 100 and outputs them to the modulation unit 214. The notice burst creation unit 213 creates a notice burst from the channel identifier output from the encoding unit 212 and outputs the notice burst to the modulation unit 214. Modulation section 214 modulates the transmission signal and outputs it to D / A conversion section 215.

  The D / A conversion unit 215 converts the transmission signal output from the modulation unit 214 from digital to analog and outputs the result to the quadrature modulation unit 216. The quadrature modulation unit 216 multiplies the transmission signal output from the D / A conversion unit 215 by a carrier signal to convert it to a high frequency signal, and outputs the high frequency signal to the PA unit 217. PA section 217 amplifies the transmission signal output from quadrature modulation section 216 and outputs the amplified signal to duplexer 202. The synthesizer 218 generates a high frequency carrier signal and outputs it to the quadrature demodulator 204 and the quadrature modulator 216. The control station interface 219 communicates with the control station 100.

  Next, a radio communication apparatus provided in the mobile station will be described. FIG. 3 is a block diagram showing a configuration of the wireless communication apparatus according to the embodiment of the present invention. A wireless communication device 300 in FIG. 3 is a wireless communication device mounted on the mobile stations 300-1 and 300-2 in FIG.

  3 includes an antenna 301, an antenna switch 302, a reception unit 303, a reception detection unit 304, a power supply control unit 305, a signal processing unit 306, a D / A conversion unit 307, a speaker. 308, a microphone 309, an A / D converter 310, a controller 311, a synthesizer 312, a transmitter 313, and a press talk switch 314.

  In FIG. 3, an antenna 301 receives a high-frequency signal transmitted from a communication partner (base station) and outputs a received signal to the antenna switch 302. The antenna 301 transmits the transmission signal output from the antenna switch 302 as a high frequency signal. The antenna switch 302 outputs the reception signal output from the antenna 301 to the reception unit 303 at the time of signal reception in accordance with an instruction from the control unit 311. Further, the antenna switch 302 outputs the transmission signal output from the transmission unit 313 to the antenna 301 at the time of signal transmission according to the instruction of the control unit 311.

  The reception unit 303 amplifies the reception signal output from the antenna switch 302, multiplies the carrier signal output from the synthesizer 312, performs frequency conversion, and outputs the result to the reception detection unit 304 and the signal processing unit 306. The reception detection unit 304 determines whether the reception signal output from the reception unit 303 is a signal indicating an empty line state or a warning signal for starting a call, and when the warning signal is detected from the reception signal, the power supply control unit In step 305, the wireless communication apparatus 300 is instructed to transition from the standby state to the call state.

  As an example of the TDMA communication method, there is a method of distinguishing between an idle state in which data transmission is not performed by a burst length of a signal to be transmitted and a communication state in which data communication is performed. In this method, the reception detection unit 304 determines that the reception signal is in a standby state when the burst length of the reception signal output from the reception unit 303 is less than a predetermined length. If the burst length of the reception signal output from the reception unit 303 is equal to or longer than a predetermined length in the standby state, the notification signal is determined.

  The power supply control unit 305 supplies power to the signal processing unit 306 in accordance with an instruction from the reception detection unit 304 in a call state. Then, the power supply control unit 305 stops supplying power to the signal processing unit 306 in the standby state according to the instruction of the reception detection unit 304.

  The signal processing unit 306 is configured by a DSP or the like, demodulates and decodes the reception signal output from the reception unit 303, and outputs the demodulated signal to the D / A conversion unit 307. The signal processing unit 306 encodes and modulates the transmission signal output from the A / D conversion unit 310 and outputs the encoded signal to the transmission unit 313. Further, the signal processing unit 306 outputs the received signal demodulation and decoding results to the control unit 311.

  The D / A conversion unit 307 converts the received signal output from the signal processing unit 306 from digital to analog and outputs the result to the speaker 308. The speaker 308 outputs the reception signal output from the D / A conversion unit 307 as sound. The microphone 309 outputs the input voice to the A / D conversion unit 310 as a voice signal. The A / D conversion unit 310 performs analog-to-digital conversion on the audio signal output from the microphone 309 and outputs the transmission signal to the signal processing unit 306.

  The control unit 311 instructs the synthesizer 312 to switch the oscillation frequency from the synchronization acquisition result of the signal processing unit 306. The synthesizer 312 generates a high frequency carrier signal and outputs it to the reception unit 303 and the transmission unit 313.

  In addition, when signal transmission is instructed from the press talk switch 314, the control unit 311 outputs an instruction to perform processing at the time of signal transmission to the synthesizer 312 and the antenna switch 302. The synthesizer 312 generates a high frequency carrier signal and outputs it to the reception unit 303 and the transmission unit 313. When receiving an instruction to perform processing at the time of signal transmission from the control unit 311, the synthesizer 312 generates a high frequency carrier signal used for transmission and outputs it to the transmission unit 313. When an instruction to perform processing at the time of signal transmission is not received from the control unit 311, the synthesizer 312 generates a high-frequency local signal used for reception and outputs it to the reception unit 303.

  The transmission unit 313 multiplies the transmission signal output from the signal processing unit 306 by a carrier signal, converts the frequency to a carrier frequency, amplifies it, and outputs the amplified signal to the antenna switch 302. The press talk switch 314 receives an input of a signal transmission instruction. When a signal transmission instruction is input, the press talk switch 314 outputs this instruction to the control unit 311.

  Hereinafter, operations of the control station 100, a base station including the wireless communication device 200, and a mobile station including the wireless communication device 300 will be described. First, an operation when a base station that communicates with a mobile station is selected will be described. FIG. 4 is a diagram illustrating an example of a signal waveform. In wireless communication using the TDMA system, signals are transmitted in time division, that is, signals are transmitted at predetermined intervals.

  FIG. 4A shows an example of a signal waveform transmitted by the mobile station. In FIG. 4A, the horizontal axis indicates time, and the vertical axis indicates transmission power. A solid line indicates a waveform of a signal transmitted by the mobile station. In this figure, the envelope fluctuation caused by the modulation is omitted. Further, as a modulation method, a case of π / 4 shift QPSK and root Nyquist characteristics is illustrated. The signal transmitted by the mobile station varies in attenuation of the transmission signal at each time due to the change in the state of the propagation path, that is, the influence of fading. In addition, the influence of fading is different for each base station to receive.

  FIG. 4B shows an example of a signal waveform received by the base station 200-1. FIG. 4C shows an example of a signal waveform received by the base station 200-2. In FIG. 4B and FIG. 4C, when the average value of the received power of the signal 401 indicating the aspect of the instantaneous value fluctuation due to Rayleigh fading is calculated, the broken line is 401-1. .

  On the other hand, the signal 402 received by the base station 200-2 is less attenuated due to fading fluctuations than the base station 200-1. When the received power value of this signal 402 is calculated, the average power value is 402-1.

  Therefore, the maximum value of the signal reception level is compared to select the base station that is the communication partner of the mobile station. For example, in FIG. 4B, the maximum value 401-2 of the reception level of the signal 401 is used as the reception level comparison target. Further, in FIG. 4C, the maximum value 402-2 of the reception level of the signal 402 is set as the reception level comparison target. By comparing the maximum value 401-2 and the maximum value 402-2, it is possible to reduce the influence of fading with a short period, compare the signal reception levels, and select a base station.

  Furthermore, by comparing the maximum value of the reception level among all samples of the first burst and the second burst and selecting the base station, one burst, that is, the reception signal of one reception unit time varies due to fading. Even in this case, the possibility of erroneously selecting a base station having a low average reception level as a communication partner of the mobile station can be reduced.

  For example, it is possible to select the base station that is the communication partner of the mobile station by comparing the maximum values of the reception levels of the first burst and the second burst. In FIG. 4B, the first burst is 401, the second burst is 403, and in FIG. 4C, the first burst is 402, and the second burst is 404. The maximum reception level 403-2 of the signals 401 and 403 is compared with the maximum reception level 404-2 of the signals 402 and 404. Then, the control station selects the base station having the maximum reception level of the two bursts as the communication path.

  The control station apparatus outputs the received signal from the selected base station as sound until signal transmission from the mobile station is completed. When a signal is transmitted from the mobile station next time, the base station is selected again by comparing the maximum values of the reception levels of the first burst and the second burst.

  Next, the effectiveness of the base station selection will be described. FIG. 5 is a diagram illustrating a simulation result of base station selection. FIG. 5 shows a simulation result when two base stations receive a radio signal transmitted from a mobile station and compare a reception level of the received signal to select a base station that communicates with the mobile station. In FIG. 5, the horizontal axis indicates the reception level difference between signals received by two base stations, and the vertical axis indicates the probability of selecting one of the two base stations.

  When the average reception level (short section median) difference is larger than 0 dB, the higher the probability of selecting the base station 1, the higher the average reception level is selected. If the average reception level difference is smaller than 0 dB, the lower the probability of selecting the base station 1, the higher the average reception level is selected.

  In FIG. 5, since the average reception level difference between the base station 1 and the base station 2 is shown, and the vertical axis shows the probability of selecting the base station 1, ideally, when the average reception level difference is larger than 0 dB, the base station The probability of selecting 1 is 100%.

  That is, when the average reception level difference is larger than 0 dB, the higher the probability of selecting the base station 1, the higher the control station selects a base station with a higher average reception level, that is, the better the channel quality during one press talk. Will choose.

  The simulation result 501 in FIG. 5 is a simulation result when comparing the time average values of the reception levels of the first burst received by the base station and selecting the base station having the largest average value. In the simulation result 501, when the average reception level difference is 2 dB, the probability of selecting the base station 1 is about 60%.

  The simulation result 502 in FIG. 5 is a simulation in which the time average value of the reception levels of the first burst and the second burst received by the base station is calculated and compared, and the base station having the largest average value is selected. It is a result. In the simulation result 502, when the average reception level difference is 2 dB, the probability of selecting the base station 1 is about 62%.

  The simulation result 503 in FIG. 5 compares the minimum values of the reception levels of the first burst and the second burst received by the base station, and selects the base station having the largest minimum value. It is a result. In the simulation result 503, when the average reception level difference is 2 dB, the probability of selecting the base station 1 is about 66%.

  Finally, a simulation result 504 in FIG. 5 is a simulation result when the maximum value of the reception levels of the first burst and the second burst received by the base station is compared and the base station having the largest maximum value is selected. . In the simulation result 504, when the average reception level difference is 2 dB, the probability of selecting the base station 1 is about 75%.

  Comparing the above four simulation results, the simulation result 504 has the highest probability of selecting the base station 1 when the average reception level of the base station 1 is high. Thus, the simulation results show that the method of selecting the communication path by comparing the maximum values of the reception levels of the first burst and the second burst received by the base station is excellent.

  As described above, according to the base station apparatus of the present embodiment, the maximum value of the received signal level is output as diversity branch selection information, so that a route with good channel quality can be selected in diversity branch selection. .

  Also, according to the control station apparatus of the present embodiment, it is possible to further improve the communication quality by adding the signal quality as information for selecting the base station apparatus in site diversity. That is, by comparing the quality of the signals received by each base station apparatus and selecting the base station apparatus having the best signal quality as the communication partner communicating with the communication terminal apparatus, it is possible to select a route with good channel quality in diversity branch selection. Can be selected.

  Note that the signal quality to be compared may be, for example, the synchronization word correlation value, the ratio of the external noise level to RSSI (CNR) immediately before and the error detection code determination result (CRC OK / NG). .

  Next, the operation when a notice burst is transmitted to shift the mobile station from the standby state to the call state will be described. FIG. 6 is a diagram illustrating an example of timing for transmitting a signal. FIG. 6 illustrates an example in which a mobile station and a base station communicate using the TDMA scheme.

  The mobile station transmits a signal through an uplink channel. In the TDMA scheme, the mobile station divides one TDMA frame into slots and transmits one burst. Here, a 40-ms frame is time-divided into four, and one burst is transmitted in units of 10 ms. In the example of FIG. 6, the mobile station divides data to be transmitted in one frame into two, and transmits the data in two frames. This is called interframe bit interleaving, and the error correction capability is improved when an error correction code is used by converting a burst error into a random error as much as possible.

  For example, transmission data 1 is divided into a first burst and a second burst and transmitted to the base station. Similarly, transmission data 2 is transmitted by being divided into a second burst and a third burst. Thereafter, the transmission data 3 and thereafter are similarly divided into two bursts and transmitted. A signal transmitted from the mobile station is received by the base station.

  When the base station receives the first burst transmitted from the mobile station, the base station notifies the control station that the first burst has been received. The control station that has received the first burst causes the base station to transmit a notice burst. Next, when the second burst is received, all transmission data 1 transmitted by the mobile station is received by the base station. The base station performs error correction processing on the transmission data 1 and sends it to the control station through the link line. After selecting the diversity branch, the control station sends transmission data back to the base station through the link line.

  The base station transmits the first communication burst to the mobile station after processing the communication burst to be transmitted to the mobile station. In addition, when there is no data to be transmitted from the control station to the mobile station, the base station transmits an empty-line burst that transmits a signal only for half the time of one burst to the mobile station. Since this empty line burst does not transmit a signal in half the time of one burst, the mobile station that receives the empty line burst cannot detect a carrier signal while receiving one burst signal. If there is more than one, it is determined that there is no data to be received and waits in a standby state.

  There is a delay due to interframe bit interleaving between the time when the base station receives the first burst and the time when the first communication burst is transmitted to the mobile station. Therefore, the base station apparatus of the present invention transmits a notice burst between the time when the first burst transmitted from the mobile station is received and the time when the first communication burst is transmitted.

  Specifically, there is a delay time until all the data distributed in a plurality of bursts is received, processed as one data such as error correction, and the return relay is performed. The base station apparatus of the present invention actively uses this delay time and transmits a notice burst for notice of communication. Then, the operation of the signal processing circuit of the communication partner is prompted to start.

  When the mobile station receives the notice burst, the mobile station shifts from a standby state in which a minimum circuit necessary for discriminating between an empty line burst and a notice burst is operated to a call state in which a circuit necessary for data transmission / reception is operated.

  After transmitting the notice burst to the mobile station, the base station transmits a signal including the first communication burst, the second communication burst, the third communication burst, and the fourth communication burst and the received data received by the mobile station. The data transmitted from the base station is transmitted by dividing one data and dispersing it into a plurality of bursts in the same manner as when the mobile station transmits data.

  In the example of FIG. 6, the base station uses a half burst signal that transmits a carrier signal only in the first half of one burst in an empty burst to be transmitted in a state where there is no data to be transmitted, and does not transmit a signal in the second half.

  The sky line burst (half burst) is not limited to this, and the carrier signal may be transmitted only in the latter half of one burst. FIG. 7 is a schematic diagram illustrating an example of a transmission signal.

  FIG. 7A is a diagram illustrating an example of a signal transmitted in a full burst state. A signal of one burst time (here, 10 ms) is transmitted. FIG. 7B is a diagram illustrating an example of a signal transmitted in a half burst state. The signal in FIG. 7B transmits the first half of one burst and does not transmit the second half. When the half burst signal of FIG. 7B is used, the receiving side uses the part including the first half carrier signal to synchronize the signal demodulation, and determines whether or not the carrier signal is detected in the second half part. Distinguish between burst and half burst signals.

  FIG. 7C is a diagram illustrating an example of a signal transmitted in a half burst state. The signal in FIG. 7C transmits the latter half of one burst and does not transmit the first half. When the half burst signal shown in FIG. 7C is used, the receiving side uses the portion including the latter half carrier signal to synchronize the signal demodulation and determines whether the carrier signal is detected in the first half portion. Distinguish between burst and half burst signals.

  As described above, according to the base station apparatus of the present embodiment, before transmitting a transmission signal including information by actively using the processing delay time of inter-frame bit interleaving, a signal for notifying the communication in advance is transmitted. By transmitting, the signal at the beginning of the call can be reproduced.

  Further, according to the communication terminal apparatus of the present embodiment, when a signal for notifying communication is received, the signal at the initial stage of the call can be reproduced by enabling the signal processing circuit.

  The wireless system and the wireless communication method according to the present invention are suitable for application to a TDMA system that performs repeated relaying of voice group communication in a multi-zone.

The block diagram which shows an example of a structure of the control station which concerns on one embodiment of this invention The block diagram which shows the structure of the radio | wireless communication apparatus which concerns on one embodiment of this invention The block diagram which shows the structure of the radio | wireless communication apparatus which concerns on one embodiment of this invention Diagram showing examples of signal waveforms The figure which shows the simulation result of base station selection The figure which shows an example of the timing which transmits a signal Schematic diagram showing an example of transmission signal The figure which shows an example of the conventional wireless communication Block diagram showing configurations of control station and base station

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 Link line channel codec part 102 RSSI comparison part 108 Selector 109 Interrupt circuit 209 Maximum value search part 210 Memory 211 Size comparison part 213 Notice burst creation part 304 Reception detection part 305 Power supply control part 306 Signal processing part

Claims (5)

A wireless system that performs site diversity in a multi-zone method configured by a plurality of base station devices and control station devices,
The base station device
Receiving means for receiving a radio signal;
The maximum value of the received signal strength is extracted from the first burst received first by the reception means and the second burst received second, and the extracted maximum value is used as diversity branch selection information to the control station apparatus. anda maximum value retrieving means for outputting,
The control station device
Radio system comprising a benzalkonium select the maximum value as the base station apparatus becomes therein by comparing said selection information for each of the diversity branches.   The base station apparatus used for the radio | wireless system of Claim 1.   The control station apparatus used for the radio | wireless system of Claim 1.   2. The radio system according to claim 1, wherein the control station apparatus sets the base station apparatus having the maximum selection information as a communication path, and does not change the communication path until the communication ends. In a wireless communication method for performing site diversity in a multi-zone method composed of a plurality of base station devices and control station devices,
The base station apparatus, and Luz step to receive the radio signals,
The base station apparatus, first extracts the maximum value of the received signal strength from the second burst received in the first burst and the second received, the control station the extracted said maximum value as the selection information of the diversity branches and Luz step be output to the device,
Wherein the control station apparatus, and Luz step to select the maximum value as the base station apparatus becomes therein by comparing said selection information for each of the diversity branches,
A wireless communication method comprising:

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