JP5277919B2 - Reference signal oscillation device and reference signal oscillation method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily and quickly correct a frequency of a reference signal, and achieve stable operation of a radio base station. <P>SOLUTION: The apparatus includes: a GPS unit 14; an oscillation source 22 which oscillates the reference signal, and changes the frequency of the reference signal by applying voltage; a control unit 11 which measures a pulse number of the reference signal in a predetermined measuring time, and measures frequency deviation tf showing an error of the measured pulse number from the predetermined reference pulse number; a RAM 17 which memorizes an adjustment reference value showing an index of a voltage value to be applied to the oscillator source 22 in order to exclude frequency deviation; and a control unit 11 which corrects the frequency of the reference signal using the adjustment reference value when the frequency deviation tf exceeds a threshold value B, and repeatedly corrects the frequency of the reference signal by applying a voltage value which excludes the frequency deviation tf when the frequency deviation tf does not exceed the threshold value B. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a reference signal oscillation device and a reference signal oscillation method.

  Conventionally, as a wireless device that relays wireless communication between wireless mobile stations (wireless communication terminals such as handy devices, vehicle-mounted devices) and wireless communication between fixed stations (for example, a fixed terminal that performs wireless communication with an antenna set up at home) Wireless base stations are known. The radio base station includes a plurality of fixed radio stations (repeaters). Each repeater relays wireless communication between wireless mobile stations. Specifically, each repeater receives a reference signal from a reference signal oscillator, and performs processing related to wireless reception and transmission based on the received reference signal.

  The reference signal oscillator generates a reference signal based on oscillation of a crystal resonator or the like. When generating the reference signal, it is necessary to periodically calibrate the reference signal in order to prevent an error in the frequency of the reference signal due to deterioration over time. Therefore, a GPS signal is received from a GPS (Global Positioning System) satellite, and a 1 second signal (hereinafter referred to as 1 PPS (Pulse Per Second)) synchronized with UTC (Coordinated Universal Time) obtained from the GPS signal is used. Based on this, a reference signal oscillator that calibrates a reference signal generated from an oscillation source has been considered (for example, see Patent Document 1). For example, when 1 PPS cannot be received, the reference signal is calibrated using error data estimated from the temperature.

In addition, the accuracy of the frequency of wireless communication that can be used in the repeater is determined by the standard depending on the frequency band of the wireless communication to be used, and use with an accuracy that does not satisfy the standard is not permitted by law. The accuracy of the frequency of wireless communication that can be used in the repeater depends on the accuracy of the frequency of the reference signal generated from the oscillation source. For this reason, in order to maintain the accuracy of the frequency determined by the standard, whether or not there is an abnormality in the frequency of the reference signal generated from the oscillation source is detected, and there is an abnormality in the frequency only when there is an abnormality. There is known a configuration for generating an alarm (alarm) indicating this.
JP 2002-217722 A

  However, in the configuration in which an alarm is generated only when there is an abnormality in the frequency of the reference signal generated from the oscillation source, it takes time to calibrate the reference signal. For example, when the accuracy of the frequency band of wireless communication used in the repeater is high, calibration of the reference signal acquires and calibrates the error in the number of pulses, so that it takes time to recalibrate the reference signal. If the radio base station is operated during recalibration of the reference signal, the radio base station is operated in a state where the accuracy of the radio communication frequency that can be used by the repeater is poor (the operation of the radio base station is unstable). Have to do. When such an operation is performed, there is a possibility that the frequency oscillated from the oscillation source is shifted and the standard of the frequency band of the wireless communication to be used is not satisfied.

  Also, if there is an abnormality in the frequency of the reference signal generated from the oscillation source that does not meet the standards for the frequency band of wireless communication, the operation of the reference signal oscillator is not stopped in order to perform maintenance (calibration). must not. Once the reference signal oscillator stops operating, recalibration takes time (for example, when rubidium is used as the oscillation source, recalibration takes several hours to several tens of hours). For this reason, the operation of the radio base station has been hindered.

Moreover, in the calibration method of the technique of the above-mentioned patent document 1, since oscillation sources have individual differences, calibration data must be prepared for each oscillation source. In addition, due to aging of the oscillation source, the calibration data that was calibrated first may not be used as it is for subsequent calibrations, so it may be necessary to re-calibrate the calibration data that was calibrated first. Took time and effort.
For this reason, there has been a demand to calibrate the frequency of the reference signal easily and quickly to realize stable operation of the radio base station.

An object of the present invention is to easily and quickly calibrate the frequency of a reference signal to realize a stable operation of a radio base station.

In order to solve the above-mentioned problem, a reference signal oscillation device according to claim 1 is provided.
A GPS signal receiving unit for receiving a GPS signal and acquiring a time signal synchronized with UTC;
A reference signal oscillating unit that oscillates a reference signal and varies the frequency of the reference signal by applying a voltage;
Based on the time signal acquired by the GPS signal receiver, the number of pulses of the reference signal at a predetermined measurement time is measured, and an error in the measured number of pulses from a predetermined reference pulse number is measured. A measuring unit for measuring the frequency deviation shown;
A storage unit for storing an adjustment reference value indicating an index of a voltage value applied to the reference signal oscillation unit in order to eliminate the frequency deviation;
The range of the first frequency deviation measured by the measuring unit repeatedly if the threshold is not exceeded the frequency deviation corresponding to the boundary level of the frequency deviation measured by the measuring unit is the reference signal oscillator unit operates stably A voltage value to be eliminated is applied to the reference signal oscillation unit, and an average value of voltage values derived from the voltage value applied to the reference signal oscillation unit is stored in the storage unit as the adjustment reference value.
The GPS when the third threshold that is equal to or lower than the second threshold of the frequency deviation corresponding to the boundary level of the frequency accuracy defined by the standard of wireless communication and exceeds the first threshold is exceeded. If it is determined whether the GPS signal can be received via the signal receiving unit, and the GPS signal can be received,
And, when the third threshold value is not exceeded and the first threshold value is exceeded, the adjustment reference value stored in the storage unit is applied to the reference signal oscillation unit, and the frequency of the reference signal is applied. To correct
When the frequency deviation exceeds the second threshold, stop the operation of the reference signal oscillation unit,
It is determined whether or not the GPS signal can be received via the GPS signal receiver, and when it is determined that the GPS signal cannot be received, it is determined that the GPS signal is abnormally received, and the reference signal oscillator is A control unit that operates as a free-run operation that does not use the adjustment reference value;
It is provided with.

According to a second aspect of the invention, the reference signal oscillator according to claim 1,
It has an operation unit that accepts operation inputs,
The controller is
When the measurement time is received via the operation unit, the frequency of the reference signal is corrected with the received measurement time.

According to a third aspect of the present invention, in the reference signal oscillation device according to the second aspect ,
The controller is
When the frequency deviation exceeds the first threshold and does not exceed the second threshold, when an operation input of the measurement time is received via the operation unit, the frequency measured by the measurement unit The frequency of the reference signal is corrected so as to eliminate the deviation.

According to a fourth aspect of the present invention, there is provided a reference signal oscillating method.
A GPS signal receiving unit for receiving a GPS signal and acquiring a time signal synchronized with UTC; and
A reference signal oscillating unit that oscillates the reference signal and applies a voltage to vary the frequency of the reference signal; and
The measurement unit measures the number of pulses of the reference signal at a predetermined measurement time based on the time signal acquired by the GPS signal receiving step, and the measured number of pulses from the predetermined reference pulse number A measurement process for measuring a frequency deviation indicating an error of
A storage step in which a storage unit stores an adjustment reference value indicating an index of a voltage value applied to the reference signal oscillation unit in order to eliminate the frequency deviation;
When the control unit does not exceed the first threshold of the frequency deviation corresponding to the boundary level of the range in which the frequency deviation measured by the measurement process and the reference signal oscillation unit stably operate, the measurement unit repeatedly measures A voltage value that eliminates the frequency deviation is applied to the reference signal oscillating unit, and an average value of voltage values derived from the voltage value applied to the reference signal oscillating unit is used as the adjustment reference value in the storage unit. Remember,
The GPS when the third threshold that is equal to or lower than the second threshold of the frequency deviation corresponding to the boundary level of the frequency accuracy defined by the standard of wireless communication and exceeds the first threshold is exceeded. If it is determined whether the GPS signal can be received via the signal receiving unit, and the GPS signal can be received,
And, when the third threshold value is not exceeded and the first threshold value is exceeded, the adjustment reference value stored in the storage unit is applied to the reference signal oscillation unit, and the frequency of the reference signal is applied. To correct
When the frequency deviation exceeds the second threshold, stop the operation of the reference signal oscillation unit,
It is determined whether or not the GPS signal can be received via the GPS signal receiver, and when it is determined that the GPS signal cannot be received, it is determined that the GPS signal is abnormally received, and the reference signal oscillator is A control step of operating as a free-run operation without using the adjustment reference value,
It is characterized by including.

ADVANTAGE OF THE INVENTION According to this invention, the frequency of a reference signal can be calibrated easily and quickly, and the stable operation | movement of a wireless base station is realizable.

  Embodiments according to the present invention will be described below in detail with reference to the accompanying drawings. However, the scope of the invention is not limited to the illustrated examples.

  Embodiments according to the present invention will be described with reference to FIGS. First, the apparatus configuration of the radio base station 1 according to the present embodiment will be described with reference to FIG. FIG. 1 shows an external configuration of a radio base station 1 according to the present embodiment. FIG. 2 shows a configuration of a reference signal oscillator 10, repeaters 20 </ b> A, 20 </ b> B, 20 </ b> C, 20 </ b> D as a reference signal oscillation device mounted on the radio base station 1 and a radio antenna 30 a.

  A wireless base station 1 shown in FIG. 1 uses wireless communication in a predetermined frequency band, wireless communication between wireless mobile stations (wireless communication terminals such as handheld devices, in-vehicle devices, etc.) and a fixed station (for example, an antenna at home). It is a device that relays a plurality of wireless communications between fixed terminals that stand up and perform wireless communications simultaneously. The same frequency band is used in all of the wireless communication that relays a plurality of times.

  Next, the configuration of the radio base station 1 will be described. As shown in FIG. 2, the radio base station 1 includes a reference signal oscillator 10, repeaters 20A, 20B, 20C, and 20D, and a radio antenna 30a.

  The reference signal oscillator 10 oscillates a wireless communication relay function for relaying wireless communication in a predetermined frequency band between wireless mobile stations (not shown), and a reference signal used for processing of a wireless communication transmission unit and reception unit. A reference signal oscillation function for output (generation).

  The reference signal oscillator 10 is connected to the repeaters 20A, 20B, 20C, and 20D by wire communication, and transmits the generated reference signals to the repeaters 20A, 20B, 20C, and 20D.

  Unlike the mobile radio station, the reference signal oscillator 10 and the repeaters 20A, 20B, 20C, and 20D can simultaneously perform transmission and reception. The reference signal oscillator 10 and the repeaters 20A, 20B, 20C, and 20D generally have a larger transmission output than a mobile radio station and have a higher reception capability, and are used as relay stations between mobile radio stations. Further, the accuracy of the frequency of the reference signal is determined by the frequency band of wireless communication.

  The repeaters 20A, 20B, 20C, and 20D each have a wireless communication relay function that relays wireless communication in a predetermined frequency band between wireless mobile stations (not shown). The repeaters 20A, 20B, 20C, and 20D each perform processing related to transmission and reception of a radio signal based on the reference signal received from the reference signal oscillator 10 in the wireless communication relay. The repeaters 20A, 20B, 20C, and 20D are wireless devices that are assumed to be fixedly installed, and each relays one-to-one wireless communication between mobile wireless stations. The number of reference signal oscillators 10 and repeaters 20A, 20B, 20C, and 20D in the radio base station is not limited to the number shown.

  The radio antenna 30a receives radio waves in a predetermined frequency band transmitted from a mobile radio station on the transmission side, and transmits radio waves in a predetermined frequency band to the mobile radio station on the reception side based on a signal to be transmitted. .

  Next, the internal configuration of the reference signal oscillator 10 will be described. FIG. 3 shows the internal configuration of the reference signal oscillator 10.

  As shown in FIG. 3, the reference signal oscillator 10 includes a measurement unit, a control unit 11 as a control unit, a reception unit 12, a transmission unit 13, a GPS unit 14 as a GPS signal reception unit, an operation unit 15, and an I / F ( Interface) 16, a RAM (Random Access Memory) 17 as a storage unit, a reference signal unit 18, and the like. The radio antenna 30a includes a reception antenna 31a, a transmission antenna 32a, and a GPS antenna 33a.

  The control unit 11 is a unit that controls each unit of the reference signal oscillator 10. The control unit 11 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and the like, and controls each unit of the reference signal oscillator 10. In the control unit 11, a program stored in the ROM is expanded in the RAM 17, and various processes are executed in cooperation with the program expanded in the RAM 17 and the CPU.

  The control unit 11 causes the reference signal unit 18 to generate a reference signal and transmit it to the repeaters 20A, 20B, 20C, and 20D via the communication connection terminal 18a. In addition, the control unit 11 demodulates the signal received by the receiving antenna 31a to the receiving unit 12, and after correcting and amplifying the demodulated signal, the control unit 11 modulates the demodulated signal to the transmitting unit 13 and transmits it to the transmitting antenna 32a. Thus, the radio signal is relayed. Further, the control unit 11 transmits / receives operation status information to / from the repeaters 20A, 20B, 20C, and 20D via the I / F 16, and shares the operation status with each other.

  The receiving antenna 31 a receives a radio wave in a predetermined frequency band from the mobile radio station on the transmission side, and outputs the received signal to the receiving unit 12. The receiving unit 12 performs processing such as demodulation processing that demodulates and outputs the received signal input from the receiving antenna 31a under the control of the control unit 11. The receiving unit 12 performs the processing using the reference signal input from the reference signal unit 18. The demodulated signal output from the receiving unit 12 is corrected and amplified by a DSP (Digital Signal Processor) (not shown) or the like and then input to the transmitting unit 13.

The transmission unit 13 modulates the demodulated signal input from the DSP or the like under the control of the control unit 11 and performs processing such as modulation that is output to the transmission antenna 32a. Further, the transmission unit 13 performs the processing using the reference signal input from the reference signal unit 18. The transmission antenna 32a transmits a radio wave in a predetermined frequency band to the mobile radio station on the reception side based on the modulated signal input from the transmission unit 13.

  Actually, in the receiving unit 12 and the transmitting unit 13, the reference signal which is an electric signal having a constant frequency inputted from the reference signal unit 18 is an internal reference signal having a different frequency due to a PLL (Phase Locked Loop) (not shown) or the like. The internal reference signal is input to the receiving unit 12 and the transmitting unit 13, and the processing of the receiving unit 12 and the transmitting unit 13 is executed.

  The GPS antenna 33 a receives a GPS signal from a GPS satellite and outputs it to the GPS unit 14. Under the control of the control unit 11, the GPS unit 14 acquires 1 PPS, which is a 1-second signal synchronized with UTC, based on the GPS signal input from the GPS antenna 33 a and outputs the 1 PPS to the control unit 11.

  The operation unit 15 has an operation panel, receives an operation input from the user to the operation panel, and outputs the operation information to the control unit 11 as operation information. Specifically, the operation unit 15 receives an operation input of a measurement time for measuring the number of pulses of the reference signal from the user.

  The I / F 16 is a circuit that mediates communication between the reference signal oscillator 10 and an external device (not shown) that analyzes the adjustment reference value.

  The RAM 17 has a work area for storing various programs to be executed and data related to these various programs. Specifically, the RAM 17 stores adjustment reference values and adjustment data. The adjustment reference value is a voltage value input (applied) to the oscillation source 22 in order to adjust (calibrate) the frequency of the reference signal. The adjustment data is data of a voltage value applied to the oscillation source 22 so as to eliminate the frequency deviation tf. The adjustment reference value is obtained from the average value of the adjustment data. The frequency deviation tf corresponds to an error in the number of measured pulses from a predetermined reference pulse number (accurate pulse number) in a predetermined measurement time.

  The communication connection terminal 18a is connected to the reference signal unit 18 and is connected to the repeaters 20A, 20B, 20C, and 20D via a cable.

  Next, the internal configuration of the reference signal unit 18 will be described. FIG. 4 shows the internal configuration of the reference signal unit 18.

As shown in FIG. 4, the reference signal unit 18 includes a DAC (DA (Digital to Analog) converter) 21 and an oscillation source 22 as a reference signal oscillation unit.

  The DAC 21 is a circuit that converts an input digital voltage signal into an analog voltage signal and outputs the analog voltage signal. The volume of the output voltage signal is adjusted under the control of the control unit 11. The voltage output from the DAC 21 is input to a frequency adjustment terminal (not shown) of the oscillation source 22.

  The oscillation source 22 includes rubidium, a crystal resonator, and the like, generates a reference signal having a constant frequency (for example, 10 MHz), and outputs the reference signal to the communication connection terminal 18a. The oscillation source 22 includes a frequency adjustment terminal (not shown), and the frequency adjustment terminal is connected to the output terminal of the DAC 21. The oscillation source 22 adjusts (varies) the frequency of the reference signal to be output in accordance with the voltage value input to the frequency adjustment terminal.

  As shown in FIG. 4, in the reference signal unit 18, the control unit 11 controls the DAC 21 based on 1PPS input from the GPS unit 14 and the reference signal input from the oscillation source 22 of the reference signal unit 18. The input voltage value is adjusted, and the frequency of the reference signal is adjusted to be constant. On the other hand, in the reference signal oscillator 10, the control unit 11 adjusts the voltage value input to the DAC 21 of the reference signal unit 18 to adjust the frequency of the reference signal to be constant.

  Next, the operation of the reference signal oscillator 10 will be described. FIG. 5 shows a flow of calibration processing executed by the reference signal oscillator 10. The calibration process is a process of measuring the frequency deviation tf and calibrating the frequency of the reference signal so as to eliminate the measured frequency deviation tf.

  For example, after the reference signal unit 18 is turned on (powered on) via the operation unit 15, the control unit 11 performs the calibration by using, for example, a calibration process execution instruction input to the operation unit 15. Processing is executed.

  It is assumed that adjustment data and adjustment reference values used when the power was turned off last time (when the power was turned off immediately before the current power was turned on) are stored in the RAM 17 in advance.

  First, the adjustment reference value (adjustment reference value when the power was turned off last time) used when the power was turned off last time is read from the RAM 17 (step S1). The read adjustment reference value is used in step S16 described later.

After step S1, the GPS signal reception standby state (GPS reception standby state) is entered (step S2). Then, it is determined whether or not the GPS signal cannot be received for a certain period of time, or whether or not the GPS unit is faulty (step S3). Whether the GPS signal cannot be received for a certain period of time is determined by determining whether the time (time) when the GPS signal transmitted from the GPS satellite cannot be received exceeds a preset time (set_time) (time > Set_time) is determined. Here, whether or not a GPS signal has been received is determined based on supplementary information of GPS satellites output by the GPS unit 14 (information on how many GPS satellites are supplemented). Specifically, if the supplementary information of the GPS satellite is information indicating that four or more GPS satellites have been supplemented, it is determined that a GPS signal has been received. On the other hand, if the supplementary information of the GPS satellite is information indicating that only three or less GPS satellites have been supplemented, it is determined that the GPS signal has not been received. Therefore, in step S3, the supplementary information of GPS satellites is information that only three or less GPS satellites can be supplemented, and the time (time) during which the information is received is set in advance (set_time). ) Is exceeded.
In step S3, it is also determined whether or not the GPS unit 14 is out of order. Specifically, it is determined whether or not the GPS unit 14 has failed based on the signal level of the 1PPS signal output from the GPS unit 14. For example, when the signal level is higher than a predetermined level or too low, it is determined that the GPS unit 14 has failed.

  If it is determined in step S3 that the GPS signal cannot be received for a certain time (step S3; YES), the free run mode is set, the adjustment reference value and the adjustment data stored in the RAM 17 are reset, and FLAG = 0 is set. Set. (Step S4). The free-run mode refers to a mode in which the oscillation source 22 is operated based on the frequency oscillated by the crystal resonator or the like of the oscillation source 22 without correcting the reference signal based on 1PPS. FLAG is a flag that is set when calibration is completed (that is, FLAG = 1 is set).

If it is determined in step S3 that the GPS signal cannot be received for a certain time (step S3; NO), frequency adjustment is performed (step S5). For example, assume that the frequency of the accurate reference signal is 10 MHz, and the measurement time is set to 1 second by the operation of the operation unit 15 by the user. In this case, the measurement time is converted into a measurement time in seconds (measurement time [S]), and the measurement time [S] is counted in units of 1 PPS (that is, 1 PPS × 1 [S] is counted), 1PPS × 1 During [S], the number of pulses of the reference signal generated from the oscillation source 22 is counted. At this time, the number of counted pulses (measurement time 1 [measurement time 1 [S]) from the exact number of pulses (number of accurate reference signals per second (= frequency [Hz]: 10 × 10 ⁶ × measurement time 1 [S])). S], the error (frequency deviation tf) of the number of pulses emitted from the oscillation source 22 is measured, and a control signal that eliminates the error is output by the control unit 11. Then, the control is performed by the DAC 21. A voltage value corresponding to the control signal input from the unit 11 is input to the adjustment voltage terminal of the oscillation source 22, and the frequency of the reference signal output from the oscillation source 22 is corrected (adjusted).
At this time, if calibration of the frequency of the reference signal is not performed even after a predetermined time has elapsed, an error is output (alarm is generated).

  After execution of step S5, it is determined whether or not the output level is abnormal (step S6). The output level refers to the level of the reference signal output from the oscillation source 22. Specifically, in this step, is the output level (out_level) smaller than the allowable minimum level (out_min) (out_level <out_min) or whether the output level (out_level) exceeds the maximum allowable level (out_max) (out_level) > Out_max) is determined.

  If it is determined in step S6 that the output level is abnormal (step S6; YES), the operation of the oscillation source 22 is stopped (output is stopped), and the adjustment data is reset (step S7). After completion of step S7, the calibration process is terminated.

  If it is determined in step S6 that the output level is not abnormal (step S6; NO), it is determined whether or not the 1PPS output level is abnormal (step S8). The 1PPS output level is the level of the GPS signal per 1PPS. Specifically, in this step, the 1PPS output level (1PPS_level) is smaller than the allowable minimum level (min) of the 1PPS output level (1PPS_level <min), or the 1PPS level (1PPS_level) is the allowable maximum level of 1PPS level ( max) is exceeded (1PPS_level> max).

If it is determined in step S8 that the 1PPS output level is abnormal (step S8; YES), the process proceeds to step S4. When it is determined in step S8 that the 1PPS output level is not abnormal (step S8; NO), a calibration investigation is performed, and when calibration is completed, FLAG = 1 is set (step S9). The calibration investigation is to determine whether or not calibration (correction of the frequency of the reference signal) has been completed. Judgment of the end of calibration is made based on whether or not it is within the threshold B.
Specifically, in the calibration investigation, FLAG = 0 is set at the first calibration after the power is turned on. When it is detected that FLAG = 0, it is determined whether or not the frequency deviation is within the threshold value B. If it is greater than or equal to the threshold value B, it is determined that calibration has not been completed. If it is within the threshold value B, it is determined that the calibration is completed. When it is determined that the calibration is completed, FLAG = 1 is set. After FLAG = 1 is set, no calibration check is performed.

After execution of step S9, it is determined whether or not frequency deviation tf> allowable error (step S10). Specifically, it is determined whether or not the frequency deviation tf measured in step S5 exceeds an allowable error. The allowable error as the second threshold indicates a boundary level of frequency accuracy defined by the standard in the frequency band of wireless communication. When the frequency deviation tf exceeds the allowable error, it indicates that the frequency accuracy determined by the standard is not satisfied.
Further, in this step, when FLAG = 0 (during the first calibration after turning on the power), it is forcibly determined that the frequency deviation tf does not exceed the allowable error (step S10; NO).

If it is determined in step S10 that the frequency deviation tf> the allowable error (step S10; YES), the process proceeds to step S7. If it is determined in step S10 that the frequency deviation tf> the allowable error is not satisfied (step S10; NO), it is determined whether or not the frequency deviation tf> the threshold A (step S11). The threshold value A as the third threshold value is set to a value not less than the threshold value B and not more than the allowable deviation value. When the frequency deviation tf exceeds the threshold A and does not exceed the allowable error, it indicates that the frequency accuracy within the standard is satisfied but does not occur in normal operation.
In this step, if FLAG = 0 (during the first calibration after the power is turned on), it is forcibly determined that the frequency deviation tf does not exceed the allowable error (step S11; NO).

  If it is determined in step S11 that the frequency deviation tf> threshold A (step S11; YES), the GPS signal received from the GPS is confirmed, and it is determined whether or not reception is OK (step S12). Specifically, in this step, processing similar to that in step S3 is performed.

  If it is determined in step S12 that the reception is not OK (step S12; NO), the free run mode is set, and the adjustment reference value and adjustment data stored in the RAM 17 are reset (step S13). After execution of step S13, the process proceeds to step S6.

  In step S12, when it is determined that the reception is OK (step S12; YES), it is determined whether the operation mode switch is ON or OFF (step S14). The operation mode changeover switch is a switch for selecting whether correction is performed automatically or manually when the frequency of the reference signal is calibrated (corrected).

  In step S14, when the operation mode changeover switch is ON (step S14; ON), manual correction is performed (step S15). Manual correction means that the user adjusts the measurement time for correcting the frequency of the reference signal via the operation unit 15. By shortening the measurement time, the correction time can be shortened. In this step, if the user shortens the measurement time via the operation unit 15, the frequency accuracy decreases if the measurement time is shortened. Therefore, it is necessary to return to the measurement time before the change after correction.

  After execution of step S15, frequency adjustment is performed (step S15A). The frequency adjustment in this step is performed in the same manner as in step S5. In step S5, the measurement time is 1 second. However, in this step, frequency adjustment is performed based on the measurement time manually corrected in step S15. After execution of step S15A, the process proceeds to step S11.

  In step S14, when the operation mode switch is OFF (step S14; OFF), frequency adjustment is performed using the adjustment reference value (step S16). Specifically, the frequency of the reference signal is corrected using the adjustment reference value read from the RAM 17 in step S1 or the adjustment reference value stored in the RAM 17 in the adjustment data saving process described later. Therefore, in this step, the process of step S5 (counting of the number of pulses of the reference signal generated from the oscillation source 22 with 1 PPS as a reference) is not performed, and the frequency is obtained by applying the adjustment reference value to the oscillation source 22. Adjustments are made. After execution of step S16, the process proceeds to step S11.

  Here, with reference to FIG. 8, a description will be given of a comparison between the case where the frequency of the reference signal is corrected using the adjustment reference value and the case where the frequency of the reference signal is corrected without using the adjustment reference value. To do. The vertical axis shown in FIG. 8 indicates the frequency deviation tf. The convergence value corresponds to the case where the frequency deviation tf is zero. The horizontal axis shown in FIG. 8 indicates time. The waveform shows the waveform of the frequency deviation tf. The arrow in the figure follows the waveform curve of the frequency deviation tf when the frequency deviation of the reference signal is corrected using the adjustment reference value from when the frequency deviation tf is within the range between the threshold A and the threshold B. It is an arrow. The broken line in the figure shows a waveform curve when the frequency of the reference signal is corrected without using the adjustment reference value. As shown in FIG. 8, when the correction is performed using the adjustment reference value, the convergence value is approached faster than when the correction is performed without using the adjustment reference value. That is, when the frequency of the reference signal is corrected using the adjustment reference value, the reference signal generated from the oscillation source 22 based on 1 PPS is more effective than when the correction is performed without using the adjustment reference value. Since the number of pulses is not counted, the frequency of the reference signal can be corrected quickly.

If it is determined in step S11 that the frequency deviation tf> threshold A is not satisfied (step S11; NO), it is determined whether or not frequency deviation tf> threshold B is satisfied (step S17). The threshold value B as the first threshold value indicates a boundary level in a range where the oscillation source stably operates. The specific value is set to a value obtained by measuring a frequency deviation by an experiment and taking a little margin from a stable value. If the frequency deviation tf exceeds the threshold B, it indicates that the frequency of the reference signal needs to be corrected.
In this step, if FLAG = 0 (during the first calibration after the power is turned on), it is forcibly determined that the frequency deviation tf> the allowable error is not satisfied (step S17; NO).

  If it is determined in step S17 that the frequency deviation tf> the threshold value B (step S17; YES), the process proceeds to step S14. If it is determined in step S17 that the frequency deviation tf is not greater than the threshold value B (step S17; NO), an adjustment data storage process is executed (step S18). If FLAG = 0 (during the first calibration after the power is turned on), this step is not executed and the process proceeds to step S5.

  Here, the adjustment data storing process executed in step S18 will be described. First, adjustment data is stored in the RAM 17 (step S21).

  Then, it is determined whether or not FLAG = 1 (step S22). If it is determined that FLAG = 1 is not satisfied (step S22; NO), the adjustment storage data processing is terminated, and the process proceeds to step S5. When it is determined that FLAG = 1 (step S22; YES), the time measurement (timer) when Flag = 1 is set, and the predetermined time (flag time) of Flag = 1 is referred to. It is determined whether it is flag time (step S23).

  If it is determined in step S23 that timer = flag time is not satisfied (step S23; NO), the process proceeds to step S5. If it is determined in step S23 that timer = flag time is satisfied (step S23; YES), an adjustment reference value is generated based on the average value of the adjustment data (step S24). Then, the adjustment reference value is stored in the RAM 17 (step S25). At this time, if the adjustment reference value used at the time of the previous power-off is stored in the RAM 17, the adjustment reference value generated in this step is updated and stored. After execution of step S25, the adjustment data storage process is terminated, and the process proceeds to step S5. That is, when the frequency deviation tf does not exceed the threshold value B, the process of step S5 is executed.

As described above, according to the present embodiment, when the frequency deviation tf exceeds the threshold B, the adjustment reference value is applied to the reference signal oscillation unit to correct the frequency of the reference signal. For this reason, since the frequency of the reference signal is corrected using the adjustment reference value, the frequency of the reference signal can be calibrated easily and quickly. Further, by calibrating the reference signal, the oscillation source can realize a stable operation, and when the oscillation source operates stably, the stable operation of the radio base station can be realized. Therefore, the frequency of the reference signal can be calibrated easily and quickly, and the stable operation of the radio base station can be realized.

Further, when the frequency deviation tf does not exceed the allowable error and exceeds the threshold B, the adjustment reference value is applied to the reference signal oscillation unit to correct the frequency of the reference signal, and the frequency deviation tf exceeds the allowable error. If this happens, the operation of the oscillation source 22 is stopped. For this reason, since a response | compatibility method can be changed based on the threshold value B and tolerance, the process according to a condition is realizable.

  Further, when it is determined that the GPS signal cannot be received, it is determined that the GPS signal is abnormally received, and the oscillation source 22 is operated in a free-run operation. For this reason, even if the GPS signal reception is abnormal, the operation can be performed without stopping the operation of the oscillation source 22.

  If the frequency deviation tf exceeds (threshold A) and does not exceed the allowable error, it is determined whether or not a GPS signal can be received. For this reason, when the frequency deviation tf is within the allowable error range from the threshold value A, it is considered that the value does not occur in normal operation. Therefore, it is a GPS reception abnormality by determining whether or not the GPS is received. Or not. In addition, since the handling method can be changed based on the threshold A, processing according to the situation can be realized.

Further, when the frequency deviation tf does not exceed the threshold A and exceeds the threshold B, the adjustment reference value is applied to the reference signal oscillation unit to correct the frequency of the reference signal. For this reason, even if the frequency deviation does not exceed the threshold value A and exceeds the threshold value B, the frequency of the reference signal is corrected using the adjustment reference value, so that the frequency of the reference signal can be calibrated easily and quickly. .

Further, the frequency of the reference signal is corrected with the measurement time received via the operation unit 15. Therefore, when the user wants to shorten the measurement time, the user can shorten the correction time by inputting an arbitrary measurement time via the operation unit 15.

  Further, when the frequency deviation tf exceeds the threshold B and does not exceed the allowable error, when the operation input (manual correction) of the measurement time is received via the operation unit 15, the reference signal is set so as to eliminate the frequency deviation tf. Can be corrected.

  The description in the above embodiment is an example of the reference signal oscillator according to the present invention, and the present invention is not limited to this.

  For example, in the above embodiment, the adjustment reference value is read and acquired from the RAM 17 in step S1 of the calibration process in FIG. 5, but the present invention is not limited to this. For example, the adjustment reference value may be acquired from an external device. Specifically, when the adjustment data is transmitted to the external device, the adjustment reference value analyzed in the external device may be acquired via the I / F 16 when the power is turned on this time.

  In addition, the detailed configurations and detailed operations of the radio base station and the reference signal oscillator in the above embodiments can be changed as appropriate without departing from the spirit of the present invention.

It is a figure which shows the external appearance structure of the wireless base station of embodiment which concerns on this invention. It is a figure which shows the repeater mounted in the radio base station before the frequency band change of radio | wireless communication. It is a block diagram which shows the internal structure of a reference signal oscillator. It is a block diagram which shows the internal structure of a reference signal unit. It is a flowchart which shows the calibration process performed by a reference signal oscillator. It is a flowchart which shows the calibration process performed by a reference signal oscillator. It is a flowchart which shows the adjustment data preservation | save process performed by the reference signal oscillator. It is the figure which compared the case where the correction | amendment of the frequency of a reference signal is performed using an adjustment reference value, and the case where the frequency of a reference signal is corrected without using an adjustment reference value.

Explanation of symbols

1 Radio base station 10 Reference signal oscillator 11 Control unit 12 Reception unit 13 Transmission unit 14 GPS unit 15 Operation unit 16 I / F
17 RAM
18 Reference signal unit 18a Communication connection terminal 20A, 20B, 20C, 20D Repeater 21 DAC
22 Oscillation source 30a Radio antenna 31a Reception antenna 32a Transmission antenna 33a GPS antenna

Claims (4)

A GPS signal receiving unit for receiving a GPS signal and acquiring a time signal synchronized with UTC;
A reference signal oscillating unit that oscillates a reference signal and varies the frequency of the reference signal by applying a voltage;
Based on the time signal acquired by the GPS signal receiver, the number of pulses of the reference signal at a predetermined measurement time is measured, and an error in the measured number of pulses from a predetermined reference pulse number is measured. A measuring unit for measuring the frequency deviation shown;
A storage unit for storing an adjustment reference value indicating an index of a voltage value applied to the reference signal oscillation unit in order to eliminate the frequency deviation;
The range of the first frequency deviation measured by the measuring unit repeatedly if the threshold is not exceeded the frequency deviation corresponding to the boundary level of the frequency deviation measured by the measuring unit is the reference signal oscillator unit operates stably A voltage value to be eliminated is applied to the reference signal oscillation unit, and an average value of voltage values derived from the voltage value applied to the reference signal oscillation unit is stored in the storage unit as the adjustment reference value.
The GPS when the third threshold that is equal to or lower than the second threshold of the frequency deviation corresponding to the boundary level of the frequency accuracy defined by the standard of wireless communication and exceeds the first threshold is exceeded. If it is determined whether the GPS signal can be received via the signal receiving unit, and the GPS signal can be received,
And, when the third threshold value is not exceeded and the first threshold value is exceeded, the adjustment reference value stored in the storage unit is applied to the reference signal oscillation unit, and the frequency of the reference signal is applied. To correct
When the frequency deviation exceeds the second threshold, stop the operation of the reference signal oscillation unit,
It is determined whether or not the GPS signal can be received via the GPS signal receiver, and when it is determined that the GPS signal cannot be received, it is determined that the GPS signal is abnormally received, and the reference signal oscillator is A control unit that operates as a free-run operation that does not use the adjustment reference value ;
Reference signal oscillator, characterized in that it comprises a. It has an operation unit that accepts operation inputs,
The controller is
2. The reference signal oscillation device according to claim 1, wherein when the measurement time is received via the operation unit, the frequency of the reference signal is corrected based on the received measurement time. The controller is
When the frequency deviation exceeds the first threshold and does not exceed the second threshold, when an operation input of the measurement time is received via the operation unit, the frequency measured by the measurement unit The reference signal oscillator according to claim 2, wherein the frequency of the reference signal is corrected so as to eliminate a deviation. A GPS signal receiving unit for receiving a GPS signal and acquiring a time signal synchronized with UTC; and
A reference signal oscillating unit that oscillates the reference signal and applies a voltage to vary the frequency of the reference signal; and
The measurement unit measures the number of pulses of the reference signal at a predetermined measurement time based on the time signal acquired by the GPS signal receiving step, and the measured number of pulses from the predetermined reference pulse number A measurement process for measuring a frequency deviation indicating an error of
A storage step in which a storage unit stores an adjustment reference value indicating an index of a voltage value applied to the reference signal oscillation unit in order to eliminate the frequency deviation;
When the control unit does not exceed the first threshold of the frequency deviation corresponding to the boundary level of the range in which the frequency deviation measured by the measurement process and the reference signal oscillation unit stably operate, the measurement unit repeatedly measures A voltage value that eliminates the frequency deviation is applied to the reference signal oscillating unit, and an average value of voltage values derived from the voltage value applied to the reference signal oscillating unit is used as the adjustment reference value in the storage unit. Remember,
The GPS when the third threshold that is equal to or lower than the second threshold of the frequency deviation corresponding to the boundary level of the frequency accuracy defined by the standard of wireless communication and exceeds the first threshold is exceeded. If it is determined whether the GPS signal can be received via the signal receiving unit, and the GPS signal can be received,
And, when the third threshold value is not exceeded and the first threshold value is exceeded, the adjustment reference value stored in the storage unit is applied to the reference signal oscillation unit, and the frequency of the reference signal is applied. To correct
When the frequency deviation exceeds the second threshold, stop the operation of the reference signal oscillation unit,
It is determined whether or not the GPS signal can be received via the GPS signal receiver, and when it is determined that the GPS signal cannot be received, it is determined that the GPS signal is abnormally received, and the reference signal oscillator is A control step of operating as a free-run operation without using the adjustment reference value,
A reference signal oscillation method comprising:

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