JP4663556B2 - Wireless system - Google Patents

Description

  The present invention relates to a radio system such as a digital mobile radio communication system, for example, and more particularly to a technology for countermeasures against frequency aging in a simple radio system that does not have a reference radio station apparatus such as a base station apparatus.

  In a wireless system having a reference wireless station device such as a base station device, for example, a technique for correcting a secular change in frequency is disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2002-305442).

For example, a radio such as a digital mobile radio communication system that does not have a base station apparatus and performs 1-to-N (N is an integer of 1 or more) communication between simple wireless station apparatuses by communication using the same frequency. The system is used.
FIG. 4 shows four radio station apparatuses 21 to 24 as an example of such a radio system.
In FIG. 5, the example of a structure of the radio | wireless machine of each radio station apparatus 21-24 is shown, and the structure of each radio station apparatus 21-24 is the same.
In FIG. 5, the same reference numerals are given to the processing units that are substantially the same as those shown in FIG. 1 according to the embodiment of the present invention to be described later, but the intention is to limit the present invention unnecessarily. There is no.

  5 includes a transmission / reception antenna 1, an antenna switch (transmission / reception changeover switch) 2, a D / A converter (DAC: Digital Analog Converter) 3, and an oscillator (in this example, (VCTCXO: Voltage Controlled Compensated Crystal Oscillator) 4, transmission processing unit 5, transmission high frequency unit 6, reception high frequency unit 7, reception processing unit 8, antenna control unit 9, external interface 10, and storage device 11 And a control unit 31.

FIG. 6 shows a configuration example of a frame of a synchronization burst.
The frame of the synchronous burst of this example is a radio information channel consisting of a preamble (LP) for linearizer consisting of a total of 40 bits and a guard time (R) for transient response, a preamble (P) consisting of 88 bits, and a 56 bits. (RICH), a 32-bit synchronization word (SW), a 14-bit radio information channel (RICH), a 26-bit preamble (P), a 120-bit parameter information channel (PICH), And a guard time consisting of 8 bits.

FIG. 7 shows a configuration example of a communication channel frame.
The frame of the communication channel in this example includes a 30-bit linearizer preamble (LP) and a transient response guard time (R), a 2-bit preamble (P), and a 96-bit communication channel ( TCH), a 56-bit radio information channel (RICH), a 20-bit synchronization word (SW), a 14-bit radio information channel (RICH), and a 4-bit undefined portion (UD) , And a 160-bit communication channel (TCH).

Here, the linearizer preamble (LP) and the transient response guard time (R) are used as a training signal at the time of transmission, and the preamble (P) is a fixed pattern used for timing synchronization at the time of reception, etc. (RICH) is a signal for identifying whether the information of the current communication is voice or data, and the synchronization word (SW) is a unique pattern for specifying the position of the frame. Parameter information The channel (PICH) has shared information of a radio-specific group or a group that performs radio communication, and the guard time (G) is a signal assigned to absorb a transmission timing shift.
The communication channel (TCH) is an area in which voice and data are stored, and the undefined part (UD) is an area that is not used at all.

FIG. 8 shows an example of a communication protocol.
FIG. 8 shows a case where the wireless station device A wirelessly transmits voice and data to other wireless station devices by press talk communication.
First, when a predetermined button for press talk is pressed by the user in the radio station apparatus A, the state of the press talk communication is turned on (ON), and the radio station apparatus A communicates with another radio station apparatus as a communication partner. In contrast, the frame signal of the synchronization burst is wirelessly transmitted twice continuously. Thereafter, the wireless station device A wirelessly transmits a frame signal of the communication channel to other wireless station devices. When the user depresses a predetermined button for press talk in the radio station apparatus A, the state of the press talk communication is turned off (OFF), and another radio from the radio station apparatus A as a communication partner is set. A communication channel (empty line) is wirelessly transmitted twice to the station device.

An example of the transmission / reception process performed in the radio | wireless machine of each radio station apparatus 21-24 is shown.
First, the transmission process will be described.
When a transmission instruction input by a user or the like is input to the control unit 31, voice or data to be transmitted is input to the control unit 31 via the external interface 10. The control unit 31 holds the input voice or data, outputs the radio channel information stored in the RICH unit and the information stored in the PICH unit to the transmission processing unit 5, and instructs to create and transmit a synchronization burst. . Further, the control unit 31 controls the antenna switch 2 through the antenna control unit 9 so that the transmission high-frequency unit 6 and the transmission / reception antenna 1 are connected. At the same time, the control unit 31 reads out a control value for controlling the oscillator 4 from the storage device 11 and outputs the control value to the oscillator 4 via the D / A converter 3 for control.
The transmission processing unit 5 generates a synchronization burst, performs modulation processing, and outputs a transmission signal to the transmission high-frequency unit 6. The transmission high-frequency unit 6 generates a transmission carrier wave based on the frequency information input from the oscillator 4 and outputs a modulated signal wirelessly via the transmission / reception antenna 1.

The control unit 31 outputs a synchronization burst generation instruction to the transmission processing unit 5 twice. Thereafter, the control unit 31 outputs the held voice or data and RICH information to the transmission processing unit 5 and instructs to create and transmit a communication channel.
Thus, in this example, when a certain radio station apparatus performs press talk communication, the communication channel is transmitted after the synchronization burst is first transmitted twice and synchronization is ensured by another radio station apparatus. To send voice and data.
The transmission processing unit 5 creates a communication channel according to the instruction, and performs transmission processing in the same manner as when a synchronization burst is transmitted.

When the voice or data transmission instruction is finished, the control unit 31 sends dummy data (unspecified data entering the TCH unit) and RICH information indicating “empty line” to the transmission processing unit 5, and the communication channel of the empty line. Instruct to create. The transmission processing unit 5 creates an empty communication channel and performs transmission processing.
When the control unit 31 transmits the communication channel storing the “sky line” information in the RICH information twice, the transmission / reception antenna 1 and the reception high-frequency unit 7 are connected via the antenna control unit 9 in order to end the transmission. The antenna switch 2 is controlled so as to be connected.

Next, the reception process will be described.
The control unit 31 controls the antenna switch 2 so that the transmission / reception antenna 1 and the reception high-frequency unit 7 are always connected via the antenna control unit 9 when no transmission instruction is received. Further, the control unit 31 controls the oscillator 4 via the D / A converter 3 using the control value stored in the storage device 11.
For this reason, the received wave is input from the transmission / reception antenna 1 to the reception high-frequency unit 7 via the antenna switch 2. The reception high-frequency unit 7 performs band limitation processing on the received high-frequency signal based on the signal input from the oscillator 4 to obtain a baseband signal, and outputs the baseband signal to the reception processing unit 8.

The reception processing unit 8 first performs timing synchronization and frequency synchronization using a synchronization burst. The timing synchronization is corrected in the reception processing unit 8. For frequency synchronization, error information is output from the reception processing unit 8 to the control unit 31, and the control unit 31 corrects the error information to the current control value and controls the oscillator 4 via the D / A converter 3. It is realized by doing.
When these synchronizations are established, it becomes possible to grasp the frame position and extract each information. From the synchronization burst, the RICH information and the PICH information are extracted and output from the reception processing unit 8 to the control unit 31 for communication. RICH information and TCH information are extracted from the channel and output from the reception processing unit 8 to the control unit 31.
The control unit 31 outputs the received information via the external interface 10 and enables voice and data communication.
Finally, when the communication channel having the “sky line” information is received, the control unit 31 recognizes the end of the communication.

JP 2002-305442 A

  However, in the radio station apparatus of the radio system as described above, the oscillator 4 is always controlled by the control value at the time of shipment from the factory at the time of transmission or reception waiting. For example, a frequency error due to secular change has occurred. In this case, a deviation occurs in the transmission frequency, and a deviation also occurs in the standby frequency. If communication is performed between such wireless station apparatuses, communication may not be established in the worst case. In order to correct this frequency shift, for example, a maintenance work such as performing a periodic check to correct the control value to an appropriate value is required, which is a burden on both the user and the manufacturer.

Here, FIG. 9 shows an example of the displacement of the oscillator 4 due to the secular change of the oscillation frequency with respect to the control value (control voltage in this example).
The horizontal axis of the graph shown in FIG. 9 represents the control voltage, and the vertical axis represents the oscillation frequency.
Specifically, when a predetermined control voltage is applied at the time of shipment, a predetermined oscillation frequency is obtained. However, when a secular change occurs, a frequency error occurs, and even when the same control voltage is applied, an oscillation frequency ( A) after the change or a large oscillation frequency (B after the change) can be obtained.

The present invention has been made to solve such a conventional problem, and an object of the present invention is to provide a wireless system capable of correcting a secular change of an oscillation frequency by an oscillator.
Specifically, in the radio station apparatus, it is possible to automatically detect and correct the frequency error of the oscillation frequency due to secular change.

In order to achieve the above object, in the wireless system according to the present invention, a plurality of wireless station apparatuses perform wireless communication with the following configuration.
That is, in the transmission-side radio station apparatus, the transmission-side oscillator oscillates a frequency signal used in communication processing. The transmission side control means controls the oscillation frequency of the oscillator by a control value. The transmission side specifying unit specifies the reliability of the control value for controlling the oscillator. The transmitting side transmitting unit transmits the reliability information specified by the transmitting side specifying unit to the radio station apparatus on the receiving side.
In the receiving-side radio station apparatus, the receiving-side oscillator oscillates a frequency signal used in communication processing. The receiving side control means controls the oscillation frequency of the oscillator by a control value. The receiving side receiving means receives a signal transmitted from the transmitting side radio station apparatus. The receiving side correcting means corrects the control value for controlling the oscillator based on the signal received by the receiving side receiving means. The receiving side specifying unit specifies the reliability of the control value for controlling the oscillator. The receiving side detecting means detects the reliability in the transmitting side radio station apparatus based on the signal received by the receiving side receiving means. The reliability (reliability in the communication partner station device) detected by the reception-side detection unit compared with the reliability (reliability in the local station device) specified by the reception-side specifying unit in the reception side update unit If the predetermined condition is high, the control value corrected by the reception side correction unit is updated as the control value used by the reception side control unit.

  Therefore, in the radio station apparatus on the receiving side, when the reliability of the oscillation frequency in the transmitting radio station apparatus that is the communication partner is higher than the reliability of the oscillation frequency in the local station apparatus, The control value of the oscillation frequency corrected based on the signal received from the radio station apparatus is updated as a new control value. For example, the secular change of the oscillation frequency by the oscillator can be corrected. Therefore, the frequency error of the oscillation frequency due to secular change can be automatically detected and corrected without performing inspection work.

Here, various modes may be used as a mode in which a plurality of radio station apparatuses perform radio communication. For example, one-to-one communication may be used, or one-to-multiple communication may be used. Good. Also, press talk communication may be used, or other types of communication may be used.
In addition, the transmitting-side radio station apparatus and the receiving-side radio station apparatus may communicate in both directions. In this case, for example, both the transmitting-side radio station apparatus and the receiving-side radio station apparatus are Similar functions (transmission side function and reception side function) are provided.
The frequency signal oscillated by the oscillator is used for converting the frequency of the signal in, for example, transmission processing or reception processing.
Further, the oscillation frequency of the oscillator is controlled, for example, by controlling a control voltage applied as a control value.
Moreover, as a mode for correcting the control value of the oscillator based on the received signal, for example, a mode for correcting the error by performing frequency synchronization on the received signal can be used.

Further, as the reliability of the control value for controlling the oscillator, for example, the presence or absence of reliability may be used, or the degree of reliability (level) may be used.
As an example, the time elapsed since the control value was updated is counted, and when the time is less than a predetermined threshold (or less than the predetermined threshold), the reliability is considered to be greater than or equal to the predetermined threshold. When (or exceeds a predetermined threshold), an aspect in which there is no reliability can be used.
As another example, a mode in which the reliability decreases as the length of time that has elapsed since the control value has been updated can be used.

The receiving-side radio station apparatus detects the reliability of the transmitting-side radio station apparatus based on the reliability information included in the signal received from the transmitting-side radio station apparatus.
In addition, various conditions are used as the predetermined condition in which the reliability in the transmitting-side radio station apparatus (communication counterpart station apparatus) is higher than the reliability in the receiving-side radio station apparatus (own station apparatus). As an example, when there is no reliability in the local station device and there is reliability in the communication counterpart station device, the control value is updated to match the communication counterpart station device, and the reliability in the local station device is If there is, a condition that does not update the control value can be used.

The radio system according to the present invention has the following configuration as an example configuration.
That is, in the radio station apparatus on the receiving side, the reception history storage means includes the reliability specified by the receiving side specifying means (reliability in the local station apparatus) and the reliability detected by the receiving side detection means (communication) In the case where a predetermined condition that both the reliability of the counterpart station device is low is satisfied, the control value corrected by the receiving side correction means is stored. The reception side update unit updates a value determined based on a plurality of control values stored in the reception history storage unit as a control value used by the reception side control unit.

Therefore, in the radio station apparatus on the receiving side, even when the reliability in the local station apparatus is low and the reliability in the communication counterpart station apparatus is also low, a new control value is set based on a plurality of control values corrected in the past. By determining and updating, for example, it is possible to avoid or reduce a situation in which communication with the communication partner station device becomes impossible.
In addition, in the update of the control value in such a case, since it is not always clear whether a value with high reliability is set, for example, an aspect that does not recover the original high value for reliability is used. it can.

Here, various conditions may be used as the predetermined condition in which both the reliability in the local station apparatus and the reliability in the communication counterpart station apparatus are low. For example, there is no reliability in the local station apparatus and communication is performed. Conditions such that there is no reliability in the counterpart station device can be used.
Moreover, as an aspect which determines an update value based on the memorize | stored several control value, the aspect which determines an update value by averaging can be used, for example.
Various timings may be used as the timing for updating the control values based on the plurality of stored control values. For example, the timing at which the number of stored control values reaches a predetermined number, or the previous time The timing at which a predetermined period has elapsed since the update of can be used.

The radio system according to the present invention has the following configuration as an example configuration.
That is, in the transmitting-side radio station apparatus, the identification information storage unit stores identification information. The transmission side transmission unit transmits the identification information stored in the identification information storage unit.
In the reception-side radio station apparatus, the reception-side detection unit detects identification information of the transmission-side radio station apparatus based on a signal received by the reception-side reception unit. The reception history storage unit stores the identification information detected by the reception side detection unit together with the control value corrected by the reception side correction unit. The receiving side updating unit averages the plurality of control values stored in the reception history storage unit for each piece of identification information, and then averages the averaged result for a plurality of pieces of identification information to determine a value determined by the receiving side. It is updated as a control value used by the control means.

Therefore, identification information is provided for each wireless station device, and when receiving the update value by averaging the stored control values, the receiving-side wireless station device first performs the averaging for each identification information, By performing averaging for a plurality of pieces of identification information after that, for example, it is possible to prevent a control value corresponding to specific identification information from greatly affecting the averaging result, and good averaging can be performed. It can be carried out.
Here, as the identification information, for example, information such as a number unique to each wireless station device (each device) can be used.

In the wireless communication method according to the present invention, the following processing is performed when a plurality of wireless station apparatuses perform wireless communication.
That is, when the reception-side radio station apparatus controls the oscillation frequency with the control value and receives a signal from the transmission-side radio station apparatus, the reception-side radio station apparatus has low reliability of the oscillation frequency and the transmission When a predetermined condition with high reliability of the oscillation frequency in the radio station apparatus on the side is satisfied, the radio station apparatus on the reception side has the oscillation frequency corrected based on the signal received from the radio station apparatus on the transmission side The control value is updated as a new control value.
Therefore, the radio station apparatus on the receiving side can correct, for example, the secular change of the oscillation frequency by the oscillator and automatically detect the frequency error of the oscillation frequency due to the secular change without any inspection work by a person. It can be corrected.

  As described above, according to the present invention, when the receiving radio station apparatus controls the oscillation frequency with the control value and receives a signal from the transmitting radio station apparatus, the oscillation frequency in the receiving radio station apparatus is received. The oscillation frequency corrected by the reception-side radio station apparatus based on the signal received from the transmission-side radio station apparatus when the reliability of the transmission-side radio station apparatus is high and the reliability of the oscillation frequency in the transmission-side radio station apparatus is high Since the control value is updated as a new control value, the radio station device on the receiving side can correct the secular change of the oscillation frequency by the oscillator, for example, without the need for inspection work by a person. The frequency error of the oscillation frequency due to can be automatically detected and corrected.

Embodiments according to the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration example of a radio of a radio station apparatus provided in a radio system according to an embodiment of the present invention.
The radio system of this example is a digital mobile radio communication system having a configuration similar to that shown in FIG. 4, for example.
Further, in the wireless system of this example, as shown in FIG. 8 using the same frequency using the frame of the synchronization burst as shown in FIG. 6 and the frame of the communication channel as shown in FIG. According to the communication protocol, press talk communication is performed wirelessly between wireless station apparatuses in a 1 to N manner (N is an integer of 1 or more).

  The radio of the radio station apparatus of this example includes a transmission / reception antenna 1, an antenna switch (transmission / reception changeover switch) 2, a D / A converter 3, an oscillator (VCTCXO in this example) 4, and a transmission processing unit 5. A transmission high-frequency unit 6, a reception high-frequency unit 7, a reception processing unit 8, an antenna control unit 9, an external interface 10, a storage device 11, a timer 12, a reception history storage device 13, and a machine body unique number. A storage device 14 and a control unit 15 are provided.

  In the radio of the radio station apparatus of this example, the reliability of the frequency accuracy related to the oscillator 4 of the local station apparatus and the reliability of the frequency accuracy related to the oscillator of the radio station apparatus of the communication counterpart are verified. If it is determined that the frequency accuracy related to the oscillator is more reliable, the control value related to the oscillator 4 is updated to correct the frequency accuracy in the oscillator 4 of the local station device. At this time, in the wireless device of the wireless station device of this example, in order to verify the reliability of the frequency accuracy in the oscillator 4 of the local station device, the timer 12 that measures the time elapsed after the control value of the oscillator 4 is updated. Is used.

The phenomenon that communication is impossible due to secular change usually occurs in units of several years after the control value of the oscillator 4 is updated to an appropriate value. Assuming that the reliability of the station device is lost, information on the elapsed time when the reliability is lost is set in the wireless device.
Then, as a method of notifying such information to the communication partner radio station apparatus, in this example, the TCH portion of the communication channel in which the “vacant line” information transmitted at the end of communication is stored in the RICH portion is used. To do. Normally, the information content of this part is not determined by the standard and can be used freely.
In this example, a plurality of wireless station devices communicating with each other notify the communication partner of information on the oscillation frequency of the local station device, so that even one wireless station device with sufficient reliability participates in communication. In this case, it is possible to correct the oscillation frequency in each radio station apparatus based on the information.

Further, depending on the environment, there may be a case where reliability of frequency accuracy is lost in all of the local station device and the communication counterpart station device.
As a countermeasure, in this example, a radio signal of each radio station apparatus is provided with a machine body unique number storage device 14 for storing information on a unique number, and the frame signal of the communication channel including the information of “empty line” also for the information. Is notified to the communication partner station apparatus.
Further, as a reception-side function, the radio equipment of each radio station apparatus is provided with a reception history storage device 13 that stores information on the unique number in association with the control value of the oscillator 4 at the time of reception. And the situation where communication becomes impossible is avoided by updating the control value of the oscillator 4 based on the information accumulated in the reception history storage device 13.

Here, the storage device 11 stores a control value for controlling the oscillation frequency of the oscillator 4.
The timer 12 measures the time, and in this example, measures the time that has elapsed since the control value of the oscillator 4 stored in the storage device 11 is updated. In this example, a threshold of 1 year is set for this time measurement.
The machine body unique number storage device 14 stores number information unique to each wireless station device (each device).
FIG. 2 shows an example of a reception history storage table that is information stored in the reception history storage device 13.
In the reception history storage table of this example, item numbers (1 to N) that are serial numbers, unique number information (reception unique number information) of other wireless station devices received from other wireless station devices, and reception thereof The information of the control value of the oscillator 4 at the time (reception time VCTCXO control value) is stored in association with each other.

FIG. 3 shows an example of data in the TCH section that is generated when the radio equipment of the radio station apparatus of this example transmits a frame signal of the communication line of the sky line.
(A) First, a 1-bit frequency reliability flag (FLG) and a 16-bit unique number (NUM) are generated. Here, as the frequency reliability flag, 0 value is set when there is no reliability, and 1 value is set when there is reliability.
(B) Next, a 6-bit CRC code is added using, for example, a generator polynomial such as (1 + X + X ⁶ ).
(C) Next, fixed data (T) consisting of 5 bits, all of which are 0 values (ALL 0), is added.
(D) Next, using a generator polynomial such as {G1 (D) = 1 + D + D ³ + D ⁶ } and {G2 (D) = 1 + D ² + D ³ + D ⁴ + D ⁵ }, the coding rate is (1/2 ) Is performed. As a result, 56-bit convolutionally encoded data is generated.
(E) Then, dummy data consisting of 200 bits, all of which are 0 values (ALL 0), is added. The 256-bit data generated in this way is used as data to be stored in the TCH part of the communication channel of the empty line.

An example of transmission / reception processing performed in the wireless device of the wireless station apparatus of this example is shown.
First, the transmission process will be described.
When a transmission instruction input by a user or the like is input to the control unit 15, voice or data to be transmitted is input to the control unit 15 via the external interface 10. The control unit 15 holds the input voice or data, outputs radio channel information stored in the RICH unit and information stored in the PICH unit to the transmission processing unit 5, and instructs to create and transmit a synchronization burst. . Further, the control unit 15 controls the antenna switch 2 via the antenna control unit 9 so that the transmission high-frequency unit 6 and the transmission / reception antenna 1 are connected. At the same time, the control unit 15 reads out a control value for controlling the oscillator 4 from the storage device 11 and outputs the control value to the oscillator 4 via the D / A converter 3 for control.
The transmission processing unit 5 generates a synchronization burst, performs modulation processing, and outputs a transmission signal to the transmission high-frequency unit 6. The transmission high-frequency unit 6 generates a transmission carrier wave based on the frequency information input from the oscillator 4 and outputs a modulated signal wirelessly via the transmission / reception antenna 1.

The control unit 15 outputs a synchronization burst generation instruction to the transmission processing unit 5 twice. Thereafter, the control unit 15 outputs the held voice or data and RICH information to the transmission processing unit 5 and instructs to create and transmit a communication channel.
Thus, in this example, when a certain radio station apparatus performs press talk communication, the communication channel is transmitted after the synchronization burst is first transmitted twice and synchronization is ensured by another radio station apparatus. To send voice and data.
The transmission processing unit 5 creates a communication channel according to the instruction, and performs transmission processing in the same manner as when a synchronization burst is transmitted.

  When the voice or data transmission instruction is completed, the control unit 15 refers to the time counted by the timer 12 so that the control value of the oscillator 4 in the local station apparatus is updated, and a predetermined threshold period (this time) In the example, it is verified whether one year or more has passed, and the value of the frequency reliability flag (FLG) shown in FIG. 3 is set according to the result. In this example, if a threshold period (one year in this example) has elapsed since the control value of the oscillator 4 has been updated, a zero value indicating no reliability is set in the frequency reliability flag. When the control value of the oscillator 4 has been updated, if the threshold period (in this example, 1 year) has elapsed, 1 value indicating that there is reliability is set in the frequency reliability flag.

Further, the control unit 15 refers to the stored contents of the machine body unique number storage device 14 and reads the information on the unique number of the own station device.
Then, as shown in FIGS. 3A to 3E, the control unit 15 performs error detection coding processing and error correction on the information of the frequency reliability flag (FLG) and the information of the unique number (NUM). After processing, the data is output to the transmission processing unit 5. In addition, the control unit 15 sends RICH information indicating “empty line” to the transmission processing unit 5 and instructs to create a communication channel of the empty line.
The transmission processing unit 5 creates an empty communication channel and performs transmission processing.
When transmitting the communication channel storing the “sky” information in the RICH information twice, the control unit 15 causes the transmission / reception antenna 1 and the reception high-frequency unit 7 to communicate with each other via the antenna control unit 9 in order to end the transmission. The antenna switch 2 is controlled so as to be connected.

Next, the reception process will be described.
The control unit 15 controls the antenna switch 2 so that the transmission / reception antenna 1 and the reception high-frequency unit 7 are always connected via the antenna control unit 9 when no transmission instruction is received. Further, the control unit 31 controls the oscillator 4 via the D / A converter 3 using the control value stored in the storage device 11.
For this reason, the received wave is input from the transmission / reception antenna 1 to the reception high-frequency unit 7 via the antenna switch 2. The reception high-frequency unit 7 performs band limitation processing on the received high-frequency signal based on the signal input from the oscillator 4 to obtain a baseband signal, and outputs the baseband signal to the reception processing unit 8.

The reception processing unit 8 first performs timing synchronization and frequency synchronization using a synchronization burst. The timing synchronization is corrected in the reception processing unit 8. For frequency synchronization, error information is output from the reception processing unit 8 to the control unit 15, and the control unit 15 corrects the error information to the current control value and controls the oscillator 4 via the D / A converter 3. It is realized by doing.
When these synchronizations are established, the frame position can be grasped and each information can be extracted. From the synchronization burst, the RICH information and the PICH information are extracted and output from the reception processing unit 8 to the control unit 15 for communication. RICH information and TCH information are extracted from the channel and output from the reception processing unit 8 to the control unit 15.
The control unit 15 outputs the received information via the external interface 10 and enables voice and data communication.
Finally, when the communication channel having the “sky line” information is received, the control unit 15 recognizes the end of the communication.

When information indicating an empty line is input from the reception processing unit 8 as information on the RICH portion of the communication channel, the control unit 15 performs error detection processing on the data passed as information on the TCH portion of the communication channel. If an error is not detected, the frequency reliability flag is verified. As a result of such verification, when it is determined that there is no frequency reliability of the control value in the local station apparatus and there is frequency reliability of the control value in the communication counterpart station apparatus, the control unit 15 currently sets the oscillator 4 to The correction value obtained by adding the correction for the given error information to the current control value is stored in the storage device 11 as a new control value, the time counted by the timer 12 is reset to zero (0), and the local station device It is assumed that the frequency reliability in is restored.
On the other hand, if it is determined that the frequency reliability of the control value in the local station device is present, the control unit 15 determines whether the control value in the local station device is the same regardless of the presence or absence of the frequency reliability of the control value in the communication counterpart station device. No change processing is performed.
Here, the presence or absence of the frequency reliability of the control value in the local station apparatus is determined according to whether or not the time measured by the timer 12 is less than the threshold period. It is determined according to the value of the frequency reliability flag received from the communication counterpart station apparatus.

When it is determined that there is no frequency reliability of the control value in the local station device and no frequency reliability of the control value in the communication counterpart station device, the control unit 15 stores the item number in the reception history storage device 13. The information of the unique number of the receiving partner station device and the information of the control value of the oscillator 4 at that time (for example, the value obtained by correcting the error information) are stored. Such information is sequentially stored in the reception history storage device 13.
When the number of pieces of information (item number value) stored in the reception history storage table reaches a predetermined amount M set in advance, the control unit 15 stores information stored in the reception history storage table. Based on the above, the average value of the control values stored for each unique number is obtained, then the average value of the average values (average value for all unique numbers) is obtained, and the average value is used as a new control value. Store in the storage device 11.
Here, an integer value of 2 or more is used as the predetermined amount M serving as a threshold for the item number, and is variably set according to the scale of the system, for example.

Further, the process of updating and setting the control value using the information stored in the reception history storage table in this way is a temporary process for avoiding a state in which communication is disabled. Is not reset to zero (0), and the frequency reliability in the local station apparatus is not recovered.
Further, even when the frequency reliability is lost in all the radio station devices provided in the radio system, for example, when a new radio station device is added to the radio system, the new radio Since the frequency information of the station device has reliability, it is possible to appropriately correct the control value by other radio station devices and recover the frequency reliability.

As described above, in the radio device of the radio station apparatus provided in the radio system of this example, the frequency deviation due to secular change is corrected using the received signal as the frequency deviation correction method.
Specifically, the transmitting-side radio device has a timer 12 as a function for detecting the degree of aging in the local station device, and terminates information obtained by the timer 12 (in this example, the frequency reliability flag). The data is transmitted to the communication partner station apparatus using a dummy data portion of a signal transmitted at the time of talking. The wireless device on the communication counterpart station apparatus side includes a timer 12 as a function of detecting the degree of aging in the communication counterpart station apparatus, and information (frequency reliability) obtained by the timer 12 of the communication counterpart station apparatus. Frequency deviation is corrected based on the received information as necessary.

In addition, in the wireless device of this example, when a large frequency deviation occurs due to secular change in both the local station device and the communication counterpart station device, the deviation when information is received from the communication counterpart station device is recorded. When the amount of recording reaches a certain amount, the recorded deviation is averaged to calculate the frequency deviation in the own station apparatus, and the calculated value is used to correct the frequency deviation.
In addition, the transmitting-side radio device includes a machine-specific number storage device 14 that stores a unique number for each radio station device (each radio device), and transmits information on the unique number of the own station device to the communication partner station device. introduce. In the radio device on the receiving side, the deviation number at the time of reception from another radio station device is recorded together with the information on the unique number of the other radio station device, and when performing the averaging process of the deviation, After the averaging process is performed for each number information, the average result is further averaged to avoid correction depending only on a specific communication partner station apparatus.
Therefore, in the radio of the radio station apparatus provided in the radio system of this example, the frequency deviation of the oscillator 4 due to secular change can be automatically corrected, or the state where transmission / reception becomes impossible can be reduced. It becomes possible.

  Note that, in the radio of the radio station apparatus provided in the radio system of this example, the control unit 15 controls the oscillator 4 via the D / A converter 3 using the control value stored in the storage device 11. The control means (transmission-side control means, reception-side control means) is configured by the control unit 15 with the function of specifying the reliability based on the time measured by the timer 12, and the specifying means (transmission-side specification means, reception) Side specifying means), and the control unit 15, the transmission processing unit 5, the transmission high-frequency unit 6, and the antenna 1 transmit functions (transmission side) by the function of transmitting reliability information and unique number information in the local station device. Transmitting means), the receiving means (receiving side receiving means) is configured by the function that the antenna 1, the reception high frequency unit 7 and the reception processing unit 8 receive signals, and the reception processing unit 8 performs frequency synchronization. Go The correction means (reception side correction means) is configured by the function of correcting the control value used by the unit 15, and the control unit 15 has a function of detecting the reliability and unique number in the communication partner station apparatus based on the received signal. A function of updating a control value stored in the storage device 11 when a detection unit (reception side detection unit) is configured and the control unit 15 satisfies a predetermined condition regarding reliability in the local station device or the communication partner station device Thus, the update means (reception side update means) is configured, and the reception history storage unit 13 is configured by the function that the reception history storage device 13 stores the history of control values in the past, and the machine specific number storage device 14 is unique. The identification information storage means is configured by the function of storing the number information.

Here, the configuration of the system or apparatus (device) according to the present invention is not necessarily limited to the configuration described above, and various configurations may be used. The present invention can also be provided as, for example, a method or method for executing the processing according to the present invention, a program for realizing such a method or method, or a recording medium for recording the program. It is also possible to provide various systems and devices.
The application field of the present invention is not necessarily limited to the above-described fields, and the present invention can be applied to various fields.
In addition, as various processes performed in the system or apparatus (device) according to the present invention, for example, the processor executes a control program stored in a ROM (Read Only Memory) in a hardware resource including a processor and a memory. The configuration controlled by doing so may be used, and for example, each functional means for executing the processing may be configured as an independent hardware circuit.
The present invention can also be understood as a computer-readable recording medium such as a floppy (registered trademark) disk or a CD (Compact Disc) -ROM storing the control program, and the program (itself). The processing according to the present invention can be performed by inputting the program from the recording medium to the computer and causing the processor to execute the program.

It is a figure which shows the structural example of the radio | wireless apparatus which concerns on one Example of this invention. It is a figure which shows an example of a reception log | history memory table. It is a figure which shows an example of the data of the TCH part at the time of empty line transmission. 1 is a diagram illustrating an example of a wireless system. It is a figure which shows the structural example of a radio | wireless machine. It is a figure which shows the structural example of the flame | frame of a synchronous burst. It is a figure which shows the structural example of the flame | frame of a communication channel. It is a figure which shows an example of a communication protocol. It is a figure which shows an example of the displacement by the secular change of the oscillation frequency with respect to a control voltage.

Explanation of symbols

  1. ・ Transceiving antenna, 2. ・ Antenna switch, 3. ・ D / A converter, 4. ・ Oscillator, 5. ・ Transmission processing unit, 6. ・ Transmission high-frequency unit, 7. ・ Reception high-frequency unit, 8. ・ ・Reception processing unit, 9 ... Antenna control unit, 10 ... External interface, 11 ... Storage device, 12 ... Timer, 13 ... Reception history storage device, 14 ... Aircraft unique number storage device, 15, 31 ... Control unit, 21 to 24..radio station apparatus,

Claims (4)

In a wireless system in which a plurality of wireless station devices perform wireless communication,
If the time elapsed since the control value was updated is less than a predetermined threshold or less than or equal to a predetermined threshold, it is assumed that there is reliability. ,
The reliability is higher than the case where there is no reliability,
The transmitting-side radio station apparatus includes a transmitting-side oscillator that oscillates a frequency signal used in communication processing,
Transmitting-side control means for controlling the oscillation frequency of the oscillator by a control value;
Transmitting side specifying means for specifying the reliability of the control value for controlling the oscillator;
Transmission side transmission means for transmitting reliability information identified by the transmission side identification means to a reception-side radio station device, and
The receiving-side radio station apparatus includes a receiving-side oscillator that oscillates a frequency signal used in communication processing,
Receiving-side control means for controlling the oscillation frequency of the oscillator by a control value;
Receiving side receiving means for receiving a signal transmitted from the transmitting side radio station apparatus;
Receiving side correcting means for correcting a control value for controlling the oscillator based on a signal received by the receiving side receiving means;
Receiving side specifying means for specifying the reliability of the control value for controlling the oscillator;
Receiving side detecting means for detecting reliability in the transmitting side radio station apparatus based on a signal received by the receiving side receiving means;
The control value corrected by the receiving side correcting unit is set to the control value corrected by the receiving side correcting unit when the reliability detected by the receiving side detecting unit is higher than the reliability specified by the receiving side specifying unit. Receiving side updating means for updating as a control value used by the receiving side control means,
A wireless system characterized by that. In a wireless system in which a plurality of wireless station devices perform wireless communication,
As the length of time that has passed since the control value was updated increases, the reliability decreases.
The transmitting-side radio station apparatus includes a transmitting-side oscillator that oscillates a frequency signal used in communication processing,
Transmitting-side control means for controlling the oscillation frequency of the oscillator by a control value;
Transmitting side specifying means for specifying the reliability of the control value for controlling the oscillator;
Transmission side transmission means for transmitting reliability information identified by the transmission side identification means to a reception-side radio station device, and
The receiving-side radio station apparatus includes a receiving-side oscillator that oscillates a frequency signal used in communication processing,
Receiving-side control means for controlling the oscillation frequency of the oscillator by a control value;
Receiving side receiving means for receiving a signal transmitted from the transmitting side radio station apparatus;
Receiving side correcting means for correcting a control value for controlling the oscillator based on a signal received by the receiving side receiving means;
Receiving side specifying means for specifying the reliability of the control value for controlling the oscillator;
Receiving side detecting means for detecting reliability in the transmitting side radio station apparatus based on a signal received by the receiving side receiving means;
The control value corrected by the receiving side correcting unit is set to the control value corrected by the receiving side correcting unit when the reliability detected by the receiving side detecting unit is higher than the reliability specified by the receiving side specifying unit. Receiving-side updating means for updating as a control value used by the receiving-side control means,
A wireless system characterized by that. In a wireless communication method in which a plurality of wireless station devices perform wireless communication,
When the time elapsed since the control value was updated is less than the predetermined threshold or less than or equal to the predetermined threshold, it is assumed that there is reliability, and when the time is greater than or equal to the predetermined threshold or exceeds the predetermined threshold, there is no reliability. ,
The reliability is higher than the case where there is no reliability,
When the reception-side radio station apparatus controls the oscillation frequency with the control value and receives a signal from the transmission-side radio station apparatus, the reliability of the oscillation frequency in the reception-side radio station apparatus is low and the transmission-side radio station apparatus When a predetermined condition with high reliability of the oscillation frequency in the radio station apparatus is satisfied, the reception-side radio station apparatus corrects the oscillation frequency control value corrected based on the signal received from the transmission-side radio station apparatus Is updated as a new control value,
A wireless communication method. In a wireless communication method in which a plurality of wireless station devices perform wireless communication,
As the length of time that has passed since the control value was updated increases, the reliability decreases.
When the reception-side radio station apparatus controls the oscillation frequency with the control value and receives a signal from the transmission-side radio station apparatus, the reliability of the oscillation frequency in the reception-side radio station apparatus is low and the transmission-side radio station apparatus When a predetermined condition with high reliability of the oscillation frequency in the radio station apparatus is satisfied, the reception-side radio station apparatus corrects the oscillation frequency control value corrected based on the signal received from the transmission-side radio station apparatus Is updated as a new control value,
A wireless communication method.

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