JP7284028B2 - Wireless communication system and wireless relay station device - Google Patents

Description

The present invention relates to a wireless communication system in which a wireless approach station and terminal stations communicate via a wireless relay station.

When installing a base station of a wireless communication system, a wireless approach system that configures an approach line wirelessly is installed in a place where it is difficult to connect to the central unit with a wired line. A wireless approach system is generally composed of a wireless approach station (for example, a base station) installed in the same manner as a base station, and a wireless relay station. The radio relay station provides a radio interface equivalent to that of the base station on the terminal station (for example, mobile station) side, and provides a radio interface for the radio approach station on the radio approach station side. Various inventions have been proposed for radio relay stations. For example, an invention for canceling propagation delay associated with booster relay has been proposed (see Patent Document 1).

FIG. 5 shows, as an example of conventional technology, a configuration example of a radio communication system that realizes communication between an operator console and a mobile station terminal using a radio circuit. The radio communication system in the figure includes an operator console 501, a central device 510, a radio approach station 520 and a radio relay station 530, and a mobile station 540, which constitute a radio approach system.

The operator console 501 is installed at the command base and connected to the central device 510 . The central unit 510 has a line control unit 511 that controls a plurality of communication lines. The radio approach station 520 includes a control unit 521 having a wired line interface function with the central unit 510, a radio unit 522 converting the output of the control unit 521 into a radio signal, and a master oscillator generating a reference clock for the radio unit 522. 523.

The radio relay station 530 includes a first radio unit 531 having a radio line interface function with the radio approach station 520 , a first master oscillator 532 generating a reference clock for the first radio unit 531 , and a mobile station 540 . It has a second radio section 534 having a line interface function, and a second master clock 535 for generating a reference clock for the second radio section 534 . The mobile station 540 is a terminal station that is carried by personnel on site away from the command base or mounted on a vehicle such as an automobile.

FIG. 6 shows a configuration example of the first radio section 531 included in the radio relay station 530 of FIG.
The first radio section 531 includes an RF (Radio Frequency) section 611 that transmits and receives radio signals to and from the radio approach station 520, converts them into IF (Intermediate Frequency) signals, and receives signals output from the RF section 611. Output from a reception ADC (Analog to Digital Converter) 612 that converts an analog signal to a digital signal, a transmission DAC (Digital to Analog Converter) 613 that converts a transmission digital signal to an analog signal and outputs it to an RF unit 611, and a reception ADC 612 a signal processing unit 614 for extracting communication line data from the digital signal received and outputting a phase control signal for adjusting the frame timing of the first radio unit 531; A frame counter 615 for generating a radio frame signal indicating the frame timing of the first radio section 531 based on , and a signal processing section 614 for monitoring the audio of the communication line. and a speaker 617 for ringing analog audio output from the audio DAC 616 .

Japanese Patent Application Laid-Open No. 2001-103559

Problems when the prior art shown in FIGS. 5 and 6 are employed will be described.
In order to realize communication between an operator console and a mobile station, it is necessary to establish synchronization of radio frame signals of each device within the service area. Methods for establishing synchronization include, for example, a method using GPS (Global Positioning System) and a dedicated line for synchronization. If the radio relay station cannot use these methods from the viewpoint of cost, the radio relay station adjusts the reference frame timing by controlling the phase of the internal frame counter according to the demodulation result of the radio frame signal. There is a need.

However, even if the radio repeater station adjusts the frame timing as described above, the frequency of the original oscillation, which is the source of the reference clock for each device, is asynchronous, so the accuracy of the frequency of the original oscillation prevents the frame counter from keeping accurate time. As a result, the following adverse effects occur.
(1) The conversion period of the transmission DAC is disrupted, generating spurious signals in the transmission waveform, violating the specifications of wireless standards.
(2) The conversion cycle of the audio DAC is disrupted, resulting in noise.
(3) Depending on the IC (Integrated Circuit) that performs processing periodically, when an illegal timing is input, the processing may not be completed within a specified period and the IC may deadlock. Such ICs include, for example, voice codec ICs.

FIG. 7 shows an example of occurrence of the adverse effect (1) described above. As shown in the figure, when the wireless frame signal is not synchronized between the wireless approach station and the wireless relay station, the phase of the frame counter is adjusted inside the wireless relay station based on the phase control signal from the signal processing unit. control is performed. Then, a discontinuity occurs in the transmission waveform at the timing of this phase control, generating spurious, which may violate the specifications of the radio standard.

The present invention has been made in view of the conventional circumstances as described above, and enables a radio repeater station to be frequency-synchronized with a radio approach station without using GPS or a dedicated line for synchronization. It is an object of the present invention to provide a wireless communication system.

In order to achieve the above objects, the present invention configures a wireless communication system as follows.
That is, in a wireless communication system in which a wireless approach station and a terminal station communicate via a wireless relay station, the wireless relay station performs wireless communication with the wireless approach station, and according to the frame timing of the wireless approach station. A first radio unit that performs phase control of its own frame timing, a first source oscillator that oscillates a reference clock that serves as a reference for the frame timing of the first radio unit, and a state of execution of phase control in the first radio unit. wirelessly communicates with the terminal station, and performs phase control of its own frame timing according to the frame timing of the first radio unit. a second radio unit that oscillates a reference clock that serves as a frame timing reference for the second radio unit; and a second original oscillation control unit that adjusts the oscillation frequency of the original oscillation.

Here, as one configuration example, the first radio unit generates a phase control signal for instructing execution of phase control of frame timing of the first radio unit, based on a signal received from the radio approach station. and a frame for generating a radio frame signal indicating frame timing of the first radio section and executing phase control of the frame timing of the first radio section based on a phase control signal from the signal processing section. and a counter, wherein the first original oscillation control unit recognizes the execution status of phase control of the frame timing of the first radio unit by monitoring the phase control signal, and determines the phase of the frame timing of the first radio unit. The higher the frequency of phase control in the direction of advancing the first, the higher the frequency of phase control in the direction of delaying the phase of the frame timing of the first radio unit. Adjustments may be made to reduce the oscillation frequency of the original oscillation.

In this case, the first original oscillation control unit monitors the phase control signal, and outputs an addition signal when phase control in the direction of advancing the phase of the frame timing of the first radio unit is detected. a second monitor unit that monitors the phase control signal and outputs a subtraction signal when phase control in the direction of delaying the phase of the frame timing of the first radio unit is detected; an accumulator for cumulatively adding the signal and the subtraction signal from the second monitor; a divider for dividing the result of calculation by the accumulator by a predetermined value; A potentiometer for controlling the input voltage of the first original vibration, a first register for storing the previous set value of the potentiometer, and an addition unit for adding the stored value of the first register and the operation result of the division unit. , and a second register for storing the next set value of the potentiometer based on the operation result of the addition unit.

Further, as one configuration example, the first radio section has a frame counter for generating a radio frame signal indicating frame timing of the first radio section, and the second radio section has a frame counter of the second radio section. a frame counter that generates a radio frame signal indicating timing and performs phase control of the frame timing of the second radio section based on the radio frame signal from the first radio section; a comparison unit that generates a phase control signal indicating the execution status of phase control of frame timing of the second radio unit based on a comparison between the radio frame signal and the counter value of the frame counter of the second radio unit. , the second original oscillation control unit recognizes the execution status of phase control of the frame timing of the second radio unit by monitoring the phase control signal, and adjusts the phase in the direction to advance the phase of the frame timing of the second radio unit. The higher the frequency of control, the more the oscillation frequency of the second original oscillation is adjusted, and the higher the frequency of phase control in the direction of delaying the phase of the frame timing of the second radio unit, the higher the oscillation frequency of the second original oscillation. Adjustments may be made to reduce the

In this case, the second original oscillation control unit monitors the phase control signal, and outputs an addition signal when phase control in the direction of advancing the phase of the frame timing of the second radio unit is detected. a second monitor unit that monitors the phase control signal and outputs a subtraction signal when phase control in the direction of delaying the phase of the frame timing of the second radio unit is detected; an accumulator for cumulatively adding the signal and the subtraction signal from the second monitor; a divider for dividing the result of calculation by the accumulator by a predetermined value; A potentiometer for controlling the input voltage of the second original vibration, a first register for storing the previous setting value of the potentiometer, and an addition unit for adding the stored value of the first register and the operation result of the division unit. , and a second register for storing the next set value of the potentiometer based on the operation result of the addition unit.

According to the present invention, it is possible to provide a wireless communication system capable of frequency-synchronizing a wireless relay station with a wireless approach station without using GPS or a dedicated line for synchronization.

1 is a diagram showing a configuration example of a radio communication system according to an embodiment of the present invention; FIG. 2 is a diagram showing a configuration example of a first radio section and a first source vibration control section of a radio relay station in the radio communication system of FIG. 1; FIG. 2 is a diagram showing a configuration example of a second radio unit and a second source control unit of a radio relay station in the radio communication system of FIG. 1; FIG. It is a figure explaining the effect at the time of applying the method of this invention. 1 is a diagram showing a configuration example of a wireless communication system according to conventional technology; FIG. 6 is a diagram showing a configuration example of a first radio section of a radio relay station in the radio communication system of FIG. 5; FIG. It is a figure explaining the problem of a conventional system.

A wireless communication system according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration example of a wireless communication system according to one embodiment of the present invention. The radio communication system shown in the figure comprises an operator console 101, a central unit 110, a radio approach station 120 and a radio relay station 130 which constitute a radio approach system, and a mobile station 140. there is

The operator console 101 is installed at the command base and connected to the central device 110 . The central unit 110 has a line control unit 111 that controls a plurality of communication lines. The wireless approach station 120 includes a control unit 121 having a wired line interface function with the central unit 110, a radio unit 122 converting the output of the control unit 121 into a radio signal, and a master oscillator generating a reference clock for the radio unit 122. 123.

The radio relay station 130 includes a first radio section 131 having a radio line interface function with the radio approach station 120, a first master oscillator 132 generating a reference clock for the first radio section 131, and a A first oscillator control unit 133 that adjusts the first oscillator 132 based on the output phase control information, a second radio unit 134 that has a radio line interface function with the mobile station 140, and a second radio unit 134 and a second oscillator control section 136 that adjusts the second oscillator 135 based on the phase control information output from the second radio section 134 . The mobile station 140 is a terminal station that is carried by personnel on site away from the command base or mounted on a vehicle such as an automobile. In addition to such a mobile terminal station, a stationary terminal station installed at a predetermined location can also be used.

Next, details of the first radio section 131 and the first source vibration control section 133 included in the radio relay station 130 will be described with reference to FIG.
First radio section 131 has RF section 211 , reception ADC 212 , transmission DAC 213 , signal processing section 214 , frame counter 215 , audio DAC 216 , and speaker 217 .

The RF unit 211 transmits/receives radio signals to/from the radio approach station 120 and converts them into IF signals. Receiving ADC 212 converts the received analog signal output from RF section 211 into a digital signal and outputs the digital signal to signal processing section 214 . The transmission DAC 213 converts the transmission digital signal output from the signal processing section 214 into an analog signal and outputs the analog signal to the RF section 211 .

The signal processing unit 214 processes the received digital signal output from the reception ADC 212 and extracts communication line data. It also generates a phase control signal for adjusting the frame timing of the first radio section 131 so as to match the frame timing of the radio approach station 120 and outputs it to the frame counter 215 . As the phase control, there are "phase advance" control for advancing the phase of the frame timing and "phase delay" control for delaying the phase of the frame timing.

The frame counter 215 counts up according to the reference clock oscillated from the first original oscillator 132 and generates a radio frame signal indicating the frame timing of the first radio section 131 . This radio frame signal is output to reception ADC 212 , transmission DAC 213 , audio DAC 216 , etc., and is also output to second radio section 134 .

Frame counter 215 also adjusts the frame timing of first radio section 131 based on the phase control signal output from signal processing section 214 . In other words, phase advance or phase delay control is performed with respect to the frame timing of the first radio section 131 . As a result, the frame timing of the first radio section 131 is matched with the frame timing of the radio approach station 120 .

The audio DAC 216 converts the audio data extracted by the signal processing unit 214 into an analog signal and outputs the analog signal to the speaker 217 in order to monitor the audio of the communication line. The speaker 217 sounds analog audio output from the audio DAC 216 .

The first source oscillator 132 that generates a reference clock that serves as a frame timing reference for the first radio section 131 is, for example, a Voltage-Controlled Crystal Oscillator that can control the oscillation frequency by setting the input voltage. ; VCXO). It should be noted that other types of reference oscillation sources can be used as the first source oscillation 132 as long as the oscillation frequency can be controlled.

The first original oscillation control unit 133 includes a first monitor unit 221, a second monitor unit 222, an accumulator unit 223, a division unit 224, an addition unit 225, a first register 226, and a second register 227. , a potentiometer (variable resistor) 228 .

The first monitor unit 221 monitors the phase control signal output from the signal processing unit 214 of the first radio unit 131 to detect execution of phase lead control. When the execution of the phase lead control is detected, the addition signal is output from the first monitor section 221 to the cumulative addition section 223 . The second monitor unit 222 monitors the phase control signal output from the signal processing unit 214 of the first radio unit 131 to detect execution of phase delay control. When execution of the phase delay control is detected, a subtraction signal is output from the second monitor section 222 to the cumulative addition section 223 . In this example, a signal representing "+1" is used as the addition signal and a signal representing "-1" is used as the subtraction signal, but these values are arbitrary.

The cumulative addition unit 223 cumulatively adds the addition signal output from the first monitor unit 221 and the subtraction signal output from the second monitor unit 222 within a certain period of time, and corrects the input voltage of the potentiometer 228 based on the result. It is output to the division unit 224 as a value. The correction value increases in the positive direction as the frequency (number of times) of phase lead control increases, and increases in the negative direction as the frequency (number of times) of phase lag control increases. The division unit 224 divides (1/X) the correction value calculated by the cumulative addition unit 223 by a predetermined value for adjustment.

The potentiometer 228 controls the input voltage of the first original oscillator 132 according to the set value of the second register 227 in order to adjust the oscillation frequency of the first original oscillator 132 (VCXO in this example). A first register 226 stores the previous setting of potentiometer 228 . The adder 225 adds the stored value (previous set value) of the first register 226 and the correction value after adjustment by the divider 224 . The second register 227 stores the result of calculation by the adder 225 as the next set value of the potentiometer 228 .

In this way, the first original vibration control unit 133 monitors the phase control signal (instruction for phase control to the frame counter 215) output from the signal processing unit 214 to recognize the execution status of the phase control in the frame counter 215. do. When the frequency of phase lead control is high, the frequency of the reference clock of the first radio section 131 is lower than the frequency of the reference clock of the follow-up source (radio approach station 120). By increasing the input voltage, the frequency of the reference clock of the first radio section 131 (oscillation frequency of the first source oscillator 132) is increased. On the other hand, when the frequency of phase delay control is high, the frequency of the reference clock of the first radio section 131 is higher than the frequency of the reference clock of the follow-up source (radio approach station 120). By lowering the input voltage, the frequency of the reference clock of the first radio section 131 (oscillation frequency of the first source oscillator 132) is reduced. By performing such control, the frequency of phase control in the first radio section 131 gradually decreases, and as a result, the first radio section 131 of the radio relay station 130 is frequency-synchronized with the radio approach station 120. become.

Next, the details of the second radio section 134 and the second source vibration control section 136 included in the radio relay station 130 will be described with reference to FIG.
Second radio section 134 has RF section 311 , reception ADC 312 , transmission DAC 313 , signal processing section 314 , frame counter 315 , audio DAC 316 , speaker 317 , and comparison section 318 .

The RF unit 311 transmits and receives radio signals to and from the mobile station 140 and converts them into IF signals. Receiving ADC 312 converts the received analog signal output from RF section 311 into a digital signal and outputs the digital signal to signal processing section 314 . The transmission DAC 313 converts the transmission digital signal output from the signal processing section 314 into an analog signal and outputs the analog signal to the RF section 311 .

The signal processing unit 314 processes the received digital signal output from the reception ADC 212 and extracts communication line data. The frame counter 315 counts up according to the reference clock oscillated from the second original oscillator 135 and generates a radio frame signal indicating the frame timing of the second radio section 134 . This radio frame signal is output to reception ADC 312, transmission DAC 313, audio DAC 316, and the like.

Frame counter 315 also adjusts the frame timing of second radio section 134 based on the radio frame signal output from first radio section 131 . That is, the frame counter 315 also clears its own counter value in response to receiving the radio frame signal indicating the timing of clearing the counter value of the frame counter 215 in the first radio section 131 . Thereby, the frame timing of the second radio section 134 is matched with the frame timing of the first radio section 131 .

Comparing section 318 compares the radio frame signal (counter value clearing timing) output from first radio section 131 with the counter value of frame counter 315, and performs clearing (phase advance control) after the frame counter has run out. ) and clear before the frame counter runs out (phase delay control) are detected and output as a phase control signal.

The audio DAC 316 converts the audio data extracted by the signal processing unit 314 into an analog signal and outputs it to the speaker 317 in order to monitor the audio of the communication line. The speaker 317 sounds analog audio output from the audio DAC 316 .

The second oscillator 135, which generates a reference clock that serves as a reference for the frame timing of the second radio unit 134, is, for example, similar to the first oscillator 132, is a voltage capable of controlling the oscillation frequency by setting the input voltage. It can be realized by a controlled crystal oscillator (VCXO). It should be noted that another type of reference oscillation source can be used as the second source oscillation 135 as long as the oscillation frequency can be controlled.

The second original vibration control unit 136 includes a first monitor unit 321, a second monitor unit 322, an accumulator unit 323, a division unit 324, an addition unit 325, a first register 326, and a second register 327. , potentiometer 328 .

First monitor section 321 monitors the phase control signal output from comparison section 318 of second radio section 134 to detect execution of phase lead control. When the execution of the phase advance control is detected, the addition signal is output from the first monitor section 321 to the cumulative addition section 323 . Second monitor section 322 monitors the phase control signal output from comparison section 318 of second radio section 134 to detect execution of phase delay control. When execution of the phase delay control is detected, a subtraction signal is output from the second monitor section 322 to the cumulative addition section 323 . In this example, a signal representing "+1" is used as the addition signal and a signal representing "-1" is used as the subtraction signal, but these values are arbitrary.

The cumulative addition unit 323 cumulatively adds the addition signal output from the first monitor unit 321 and the subtraction signal output from the second monitor unit 322 within a certain fixed time range, and corrects the input voltage of the potentiometer 328 based on the result. It is output to the division unit 324 as a value. The correction value increases in the positive direction as the frequency (number of times) of phase lead control increases, and increases in the negative direction as the frequency (number of times) of phase lag control increases. The division unit 324 adjusts the correction value calculated by the cumulative addition unit 323 by dividing (1/X) by a predetermined value.

The potentiometer 328 controls the input voltage of the second original oscillator 135 according to the set value of the second register 327 in order to adjust the oscillation frequency of the second original oscillator 135 (VCXO in this example). A first register 326 stores the previous setting of potentiometer 328 . The adder 325 adds the stored value (previous set value) of the first register 326 and the correction value after adjustment by the divider 324 . The second register 327 stores the calculation result of the addition section 325 as the next set value of the potentiometer 328 .

In this way, in the second original oscillation control section 136, the phase control signal output from the comparison section 318 of the second radio section 134 (the radio frame signal output from the first radio section 131 and the counter value of the frame counter 315 (comparison result)), the execution status of the phase control in the frame counter 315 is recognized. When the frequency of phase lead control is high, the frequency of the reference clock of the second radio unit 134 is lower than the frequency of the reference clock of the follow-up source (first radio unit 131). By increasing the input voltage of , the frequency of the reference clock of the second radio unit 134 (oscillation frequency of the second source oscillator 135) is increased. On the other hand, when the frequency of phase delay control is high, the frequency of the reference clock of the second radio unit 134 is higher than the frequency of the reference clock of the follow-up source (first radio unit 131). By lowering the input voltage of , the frequency of the reference clock of the second radio unit 134 (oscillation frequency of the second source oscillator 135) is reduced. By performing such control, the frequency of phase control in the second radio section 134 is gradually reduced, and as a result, the second radio section 134 of the radio relay station 130 is frequency-synchronized with the first radio section 131. It will be.

Next, the effect of applying the method of the present invention will be described with reference to FIG.
FIG. 4 is a graph showing the relationship between the number of times of phase control per unit time by the second source vibration control unit 136, the cumulative addition value, and the frequency error when the frequency control of the method of the present invention is executed at predetermined time intervals. be. The horizontal axis of the graph represents the number of times frequency control is executed. When the radio frame cycle is 40 ms, frequency control is executed at intervals of about 40 seconds, for example. The vertical axis (first axis: left side) of the graph represents the number of times of phase control of the frame counter 315 and the internal state of the accumulator 323 . It should be noted that the number of times of phase control is irrelevant regardless of the direction of phase control (either phase lead control or phase lag control). The vertical axis (second axis: right side) of the graph indicates the oscillation frequency of the first source oscillator 132 that oscillates the reference clock of the first radio section 131 and the second source oscillator 135 that oscillates the reference clock of the second radio section 134. represents the frequency error (MHz) from the oscillation frequency of .

By implementing a function to update the correction value (cumulative addition value) for controlling the original oscillation according to the number of times of phase control, as shown in FIG. It can be confirmed that the frequency error of the oscillation frequency becomes smaller and the number of times of phase control decreases. By reducing the number of times of phase control, it is possible to suppress the occurrence of harmful effects such as transmission spectrum distortion and voice noise. FIG. 4 shows the effect of synchronizing the frequency of the second radio section 134 in the radio relay station 130 with the first radio section 131. Needless to say, similar effects can be obtained when frequency synchronization is performed with the wireless approach station 120. FIG.

As described above, the radio relay station 130 of this example uses the first radio section 131 for radio communication with the radio approach station 120 and the second radio section 134 for radio communication with the mobile station 140, It relays communication between the wireless approach station 120 and the terminal station 140 . The first radio section 131 has a function of performing phase control of its own frame timing according to the frame timing of the radio approach station 120. The oscillation frequency of the first source oscillator 132 that oscillates the reference clock supplied to the first radio unit 131 is adjusted according to the execution status. Further, the second radio unit 134 has a function of performing phase control of its own frame timing according to the frame timing of the first radio unit 131, The oscillation frequency of the second source oscillator 135 that oscillates the reference clock to be supplied to the second radio section 134 is adjusted according to the phase control execution status.

In this way, by adjusting the oscillation frequency of the first source oscillator 132 according to the state of execution of phase control in the first radio unit 131, the number of times of phase control in the first radio unit 131 gradually decreases. The first radio section 131 can be frequency-synchronized with the radio approach station 120 . Similarly, by adjusting the oscillation frequency of the second source oscillator 135 according to the state of execution of phase control in the second radio section 134, the number of times of phase control in the second radio section 134 gradually decreases. The second radio section 134 can be frequency-synchronized with the first radio section 131 . Therefore, the radio repeater station 130 can be frequency-synchronized with the radio approach station 120 as a whole device.

Further, in this example, the first radio section 131 generates a phase control signal for instructing execution of phase control of the frame timing of the first radio section 131 based on the received signal from the radio approach station 120. 214 and a frame counter that generates a radio frame signal indicating the frame timing of the first radio section 131 and executes phase control of the frame timing of the first radio section 131 based on the phase control signal from the signal processing section 214. 215. Then, the first original oscillation control unit 133 monitors the phase control signal from the signal processing unit 214 to recognize the execution status of the phase control of the frame timing of the first radio unit 131, and the phase in the direction to advance the phase of the frame timing. The higher the frequency of control, the higher the oscillation frequency of the first source oscillator 132 is adjusted, and the higher the frequency of phase control in the direction of delaying the phase of the frame timing, the higher the adjustment that decreases the oscillation frequency of the first source oscillator 132. It is configured.

Thus, by adjusting the oscillation frequency of the first source oscillator 132 in consideration of the direction and frequency of phase control of the frame timing of the first radio unit 131, the frequency of occurrence of phase control in the first radio unit 131 is can be effectively reduced, and the frequency of the first radio unit 131 can be quickly synchronized with the radio approach station 120 .

Here, the first original oscillation control unit 133 in this example monitors the phase control signal from the signal processing unit 214, and adds A first monitor unit 221 that outputs a signal and a phase control signal from the signal processing unit 214 are monitored, and a subtraction signal is output when phase control in the direction of delaying the phase of the frame timing of the first radio unit 131 is detected. a second monitor unit 222; an accumulator unit 223 that cumulatively adds the addition signal from the first monitor unit 221 and the subtraction signal from the second monitor unit 222; a potentiometer 228 that controls the input voltage of the first source 132 to adjust the oscillation frequency of the first source 132; a first register 226 that stores the previous setting of the potentiometer 228; It is implemented using an addition unit 225 that adds the stored value of the register 226 and the calculation result of the division unit 224, and a second register 227 that saves the calculation result of the addition unit 225 as the next set value of the potentiometer 228. .

The configuration of the first source vibration control unit 133 described above is merely an example, and it goes without saying that the first source vibration control unit 133 can be realized by other configurations. For example, the phase control signal from the signal processing unit 214 may be monitored, and the oscillation frequency of the first source vibration 132 may be adjusted each time the execution of phase control is detected.

Further, in this example, the second radio section generates a radio frame signal indicating the frame timing of the second radio section 134, and based on the radio frame signal from the first radio section 131, the second radio section 134 A frame counter 315 that executes phase control of frame timing, and executes phase control of the frame timing of the second radio unit 134 based on a comparison between the radio frame signal from the first radio unit 131 and the counter value of the frame counter 315. and a comparator 318 for generating a phase control signal indicative of the status. Then, the second original oscillation control unit 136 recognizes the execution status of the frame timing phase control of the second radio unit 134 by monitoring the phase control signal from the comparison unit 318, and performs phase control in the direction to advance the phase of the frame timing. is adjusted to increase the oscillation frequency of the second source oscillation 135 as the frequency of is higher, and the oscillation frequency of the second source oscillation 135 is adjusted to be decreased as the frequency of phase control in the direction of delaying the phase of the frame timing is higher. It has become.

Thus, by adjusting the oscillation frequency of the second source oscillator 135 in consideration of the direction and frequency of phase control of the frame timing of the second radio section 134, the occurrence frequency of phase control in the second radio section 134 is can be effectively reduced, and the frequency of the second radio unit 134 can be rapidly synchronized with the first radio unit 131 .

Here, the second original oscillation control unit 136 of this example monitors the phase control signal from the comparison unit 318, and when the phase control in the direction to advance the phase of the frame timing of the second radio unit 134 is detected, the addition signal and the phase control signal from the comparison unit 318, and outputs a subtraction signal when the phase control in the direction of delaying the phase of the frame timing of the second radio unit 134 is detected. A monitor unit 322, an accumulator unit 323 that cumulatively adds the addition signal from the first monitor unit 321 and the subtraction signal from the second monitor unit 322, and a division unit 324 that divides the calculation result of the cumulative addition unit 323 by a predetermined value. , a potentiometer 328 that controls the input voltage of the second source 135 to adjust the oscillation frequency of the second source 135, a first register 326 that stores the previous set value of the potentiometer 328, and a first register 326 and the calculation result of the division unit 324, and a second register 327 that saves the calculation result of the addition unit 325 as the next set value of the potentiometer 328.

The configuration of the second original vibration control unit 136 described above is merely an example, and it goes without saying that the second original vibration control unit 136 can be realized by other configurations. For example, the phase control signal from the comparison unit 318 may be monitored, and the oscillation frequency of the second source vibration 135 may be adjusted each time the execution of phase control is detected.

Although the present invention has been described in detail above, it goes without saying that the present invention is not limited to the configuration described above, and may be realized by configurations other than those described above.
Further, the present invention provides, for example, a method or system for executing processing according to the present invention, a program for realizing such a method or system by a computer having hardware resources such as a processor and a memory, and such a program. It is also possible to provide it as a storage medium for storing.

INDUSTRIAL APPLICABILITY The present invention can be used in various wireless communication systems in which wireless approach stations and terminal stations communicate via wireless relay stations.

101: Operation Console 110: Central Unit 111: Line Control Unit 120: Radio Approach Station 121: Control Unit 122: Radio Unit 123: Original Sound 130: Radio Relay Station 131: First Radio Unit 132: First original vibration 133: First original vibration control unit 134: Second radio unit 135: Second original vibration 136: Second original vibration control unit 140: Mobile station
211: RF unit, 212: reception ADC, 213: transmission DAC, 214: signal processing unit, 215: frame counter, 216: audio DAC, 217: speaker, 221: first monitor unit, 222: second monitor unit, 223 : Accumulator 224: Divider 225: Adder 226: First register 227: Second register 228: Potentiometer
311: RF unit, 312: reception ADC, 313: transmission DAC, 314: signal processing unit, 315: frame counter, 316: audio DAC, 317: speaker, 318: comparison unit, 321: first monitor unit, 322: second 2 monitor section 323: accumulation section 324: division section 325: addition section 326: first register 327: second register 328: potentiometer
501: Operation console 510: Central device 511: Line control unit 520: Radio approach station 521: Control unit 522: Radio unit 523: Original transmission 530: Radio relay station 531: First radio unit 532: First source, 534: Second radio section, 535: Second source, 540: Mobile station,
611: RF unit, 612: reception ADC, 613: transmission DAC, 614: signal processing unit, 615: frame counter, 616: audio DAC, 617: speaker

Claims (6)

In a wireless communication system in which a wireless approach station and a terminal station communicate via a wireless relay station,
The radio relay station performs radio communication with the radio approach station, and performs phase control of its own frame timing according to the frame timing of the radio approach station. a first oscillator that oscillates a reference clock serving as a reference; a first oscillator controller that adjusts an oscillation frequency of the first oscillator according to the state of execution of phase control in the first radio unit; a second radio unit that performs radio communication with a terminal station and performs phase control of its own frame timing according to the frame timing of the first radio unit; and a reference clock that serves as a reference for the frame timing of the second radio unit. and a second original oscillation control unit that adjusts the oscillation frequency of the second original oscillation according to the execution status of phase control in the second radio unit ,
a signal processing unit configured to generate a phase control signal instructing execution of phase control of frame timing of the first radio unit based on a signal received from the radio approach station; a frame counter for generating a radio frame signal indicating the frame timing of the first radio section and executing phase control of the frame timing of the first radio section based on the phase control signal from the signal processing section; transmitting a radio frame signal generated by a counter to the second radio unit;
The second radio section generates a radio frame signal indicating the frame timing of the second radio section, and based on the radio frame signal received from the first radio section, the phase of the frame timing of the second radio section. A wireless communication system comprising a frame counter for performing control . In the wireless communication system according to claim 1,
The first oscillator control unit recognizes the execution status of frame timing phase control of the first radio unit by monitoring the phase control signal of the first radio unit, and detects the phase of the frame timing of the first radio unit. The higher the frequency of phase control in the direction of advancing the first, the higher the frequency of phase control in the direction of delaying the phase of the frame timing of the first radio unit. 1. A wireless communication system characterized by performing adjustment to reduce the oscillation frequency of an original vibration. In the wireless communication system according to claim 2,
The first original oscillation control unit monitors the phase control signal of the first radio unit , and outputs an addition signal when phase control in a direction to advance the phase of the frame timing of the first radio unit is detected. a monitor unit, a second monitor unit that monitors the phase control signal of the first radio unit and outputs a subtraction signal when phase control in the direction of delaying the phase of the frame timing of the first radio unit is detected; an accumulator for cumulatively adding the addition signal from the first monitor unit and the subtraction signal from the second monitor unit; a division unit for dividing the calculation result of the accumulative addition unit by a predetermined value; A potentiometer for controlling the input voltage of the first original oscillation to adjust the oscillation frequency, a first register for storing the previous set value of the potentiometer, the stored value of the first register and the operation result of the division unit and a second register for storing the next setting value of the potentiometer based on the calculation result of the addition unit. In the wireless communication system according to claim 1,
The second radio unit checks the execution status of frame timing phase control of the second radio unit based on a comparison between the radio frame signal received from the first radio unit and the counter value of its own frame counter. further comprising a comparison unit that generates a phase control signal indicating
The second original oscillation control unit recognizes the execution status of frame timing phase control of the second radio unit by monitoring the phase control signal of the second radio unit, and adjusts the phase of the frame timing of the second radio unit. The higher the frequency of phase control in the advancing direction, the higher the frequency of phase control in the direction of delaying the phase of the frame timing of the second radio unit. 1. A wireless communication system, characterized in that an adjustment is made to reduce an oscillation frequency of vibration. In the wireless communication system according to claim 4 ,
The second original oscillation control unit monitors the phase control signal of the second radio unit and outputs an addition signal when phase control in a direction to advance the phase of the frame timing of the second radio unit is detected. a monitor unit for monitoring the phase control signal of the second radio unit and outputting a subtraction signal when phase control in a direction of delaying the phase of the frame timing of the second radio unit is detected; an accumulator for cumulatively adding the addition signal from the first monitor unit and the subtraction signal from the second monitor unit; a division unit for dividing the calculation result of the accumulative addition unit by a predetermined value; A potentiometer for controlling the input voltage of the second original oscillation to adjust the oscillation frequency, a first register for storing the previous set value of the potentiometer, the stored value of the first register and the operation result of the division unit and a second register for storing the next setting value of the potentiometer based on the calculation result of the addition unit. In a radio relay station device that relays communication between a radio approach station and a terminal station,
A first radio unit that performs radio communication with the radio approach station and performs phase control of its own frame timing according to the frame timing of the radio approach station; wireless communication between the oscillating first source vibration, a first source vibration control unit that adjusts the oscillation frequency of the first source vibration according to the execution status of phase control in the first radio unit, and the terminal station; and performing phase control of its own frame timing in accordance with the frame timing of the first radio unit; and a second source vibration control unit that adjusts the oscillation frequency of the second source vibration according to the state of execution of phase control in the second radio unit ,
a signal processing unit configured to generate a phase control signal instructing execution of phase control of frame timing of the first radio unit based on a signal received from the radio approach station; a frame counter for generating a radio frame signal indicating the frame timing of the first radio section and executing phase control of the frame timing of the first radio section based on the phase control signal from the signal processing section; transmitting a radio frame signal generated by a counter to the second radio unit;
The second radio section generates a radio frame signal indicating the frame timing of the second radio section, and based on the radio frame signal received from the first radio section, the phase of the frame timing of the second radio section. A radio relay station apparatus comprising a frame counter for executing control .

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