JP4546567B2 - Wireless base station - Google Patents

Description

  The present invention relates to a plurality of radio base stations having different interface types with a control device, for example, a general radio base station of a PHS radio base station, an IP connection type radio base station, or a digital cordless base unit, and the plurality of radio base stations. For example, time-division multiple access (hereinafter simply referred to as “time-division multiple access”), which has a wireless handset that is wirelessly connected to a station and a private branch exchange that is wiredly connected to the plurality of wireless base stations. The present invention relates to a radio base station (referred to as TDMA).

  Conventionally, as such a TDMA type mobile communication system, a general wireless base station, a digital cordless base unit, and a private branch exchange equipped with a control device for controlling the general type wireless base station and the digital cordless base unit, A wireless slave device that is wirelessly connected to a general-type wireless base station and a digital cordless slave device that is wirelessly connected to a digital cordless master device, and the wireless slave device can be connected for communication through the general-type wireless base station The digital cordless slave can be connected for communication through the digital cordless master (see, for example, Patent Document 1).

  FIG. 16 is a block diagram showing a schematic configuration inside a conventional TDMA type mobile communication system.

  A mobile communication system 200 shown in FIG. 16 is arranged in a private area such as an office or a factory for private use, and is generally connected through a plurality of general wireless base stations 1, a plurality of digital cordless master units 2 for offices, and an ISDN line 3. A private branch exchange 4 having a control device for communication connection with the digital wireless base station 1 and a communication connection with the digital cordless base unit 2, and a wireless slave unit (hereinafter simply referred to as a slave unit) for wireless connection with the general type wireless base station 1 5A and a digital cordless slave unit (hereinafter simply referred to as a slave unit) 5B wirelessly connected to the digital cordless master unit 2.

  The general wireless base station 1 executes a call control procedure in the wireless section based on the RCR standard which is the Radio Industry Association (ARIB) standard, and provides services such as voice communication and data communication to the handset 5A. Can be provided.

  Further, since the digital cordless master unit 2 has a one-to-one direct communication method with respect to the slave unit 5B, the digital cordless master unit 2 does not synchronize with other general-type radio base stations 1 and transmits radio waves at a self-running timing. Services such as voice calls can be provided to the handset 5B.

  Further, in the RCR standard, for example, the communication frequency band between the handset 5A and the general radio base station 1, the carrier number, and the information structure of the control CH signal as a call control signal used for frame synchronization are defined. Yes. However, since the control CH signal is commonly assigned to 12ch and 18ch in the mobile communication system in which the two frequencies have the same system, there is an obligation to avoid radio interference with other systems of the same system.

  For example, if the general radio base stations 1 (1A, 1B) in the same system transmit radio waves at arbitrary timings and the radio waves interfere with each other, the use efficiency of the radio waves decreases. Therefore, in order to prevent a decrease in radio wave use efficiency, the general radio base stations 1 (1A, 1B) are combined with the radio transmission timing of the TDMA-TDD frame between the general radio base stations 1 (1A, 1B). It is necessary to ensure frame synchronization.

  FIG. 17 is an explanatory diagram showing the concept of a TDMA-TDD frame used in a radio section of a TDMA mobile communication system.

  A TDMA-TDD frame 300 shown in FIG. 17 has a slot configuration of a radio section of the second generation cordless telephone system standard standardized by ARIB, and one slot as a minimum unit is configured by 240 bits (625 μs), 8 One frame (5 ms) is used for the slot.

  One slot 310 includes a 4-bit transient response ramp time 311, 220-bit control information data 312, and 16-bit guard bits 313, and guard bits (16 Bit) 313 and transient response ramp time (4 bits) 311, which is a total of 20 bits, that is, up to 52.1 μs is a tolerance for absorbing a shift between slots.

  Also, when the general wireless base station 1 (1A, 1B) is in a frame synchronization state, as shown in FIG. 17, the TDMA-TDD frames of the general wireless base station 1A and the general wireless base station 1B are the same. This is a state in which radio waves are transmitted at the timing. In order to maintain these synchronization states, it is necessary to keep the amount of deviation between the TDMA-TDD frame of the general radio base station 1A and the TDMA-TDD frame of the general radio base station 1B within an allowable range.

  Next, the operation until the conventional general radio base stations 1 ensure frame synchronization will be described.

  Each general-type radio base station 1 receives a synchronization signal serving as a frame synchronization reference through the ISDN line 3 of the private branch exchange 4, and matches the transmission timing of the TDMA-TDD frame with the received synchronization signal, so that the general-type radio Frame synchronization between the base stations 1 (1A, 1B) is established.

  Also, according to the conventional TDMA mobile communication system 200, when frame synchronization between the general radio base stations 1 (1A, 1B) is established, it is necessary to determine the timing for transmitting the control CH signal. The transmission position of the control CH signal needs to be controlled so that the general radio base stations 1 (1A, 1B) do not overlap each other.

  Therefore, the control CH signal transmission position sorting process for controlling the transmission positions of the control CH signals so as not to overlap between general wireless base stations 1 will be described. FIG. 18 is an explanatory diagram conceptually showing a general control CH transmission cycle.

  The control CH transmission cycle shown in FIG. 18 is a cycle of 1 frame of 5 ms for N frames (25 ≦ N ≦ 60). That is, each general radio base station 1 has 1 to N in this N interval cycle. The control channel signal of the own station is transmitted at an arbitrary frame position.

  For example, when the general radio base station 1A transmits the control CH signal at the timing “1”, the transmission timing of the next control CH signal is the control CH signal transmitted at the timing “N + 1”. That is, each general radio base station 1 transmits its own control CH signal once every N intervals.

  Since the general-type radio base station 1 uses its own control CH signal in order of start-up completion when the power is turned on or the like, the transmission position of its own control CH signal is notified within the interval range. In the general radio base station 1 that rises from the base station, the control CH signal between the general radio base stations 1 is avoided based on the broadcast information, avoiding the transmission position of the control CH signal used by the other general radio base stations 1. The transmission position of the control CH signal of the own station is determined within the same interval range so that the transmission positions of the signals do not overlap.

  According to the conventional TDMA type mobile communication system 200 as described above, the synchronization signal is distributed from the private branch exchange 4 to each general radio base station 1 through the ISDN line 3. -Frame synchronization between general-type wireless base stations 1 under the same system can be established by adjusting the transmission timing of the TDD frame.

  Further, according to the conventional TDMA type mobile communication system 200, when frame synchronization between the general radio base stations 1 is established, it does not overlap with the transmission position of the control CH signal of the other general radio base stations 1. The control CH signal transmission position used by the local station is searched within the interval range, and the service operation is started after the transmission position of the control CH signal is determined.

Further, according to the conventional TDMA type mobile communication system 200, since the digital cordless master unit 2 has a one-to-one direct communication method with respect to the slave unit 5, it is synchronized with other general radio base stations 1. Instead, radio waves are transmitted at the self-running timing.
JP 2001-145155 A (refer to paragraph numbers “0001” to “0004”)

  However, according to the conventional TDMA mobile communication system 200, after establishing frame synchronization between the general radio base stations 1 (1A, 1B) using the synchronization signal from the private branch exchange 4, the general radio base station The segregation control is performed so that the control CH signal transmission positions of the stations 1 (1A, 1B) do not overlap. For example, in the case of an IP connection type radio base station connected to the private branch exchange 4 through a LAN line, In order to ensure synchronization in the wireless section with the wireless base station 1, it is possible to transmit the synchronization signal from the private branch exchange 4 to each IP connection wireless base station by using a data packet. Data packet delays and fluctuations occur on the LAN line, and all IP connection type radio base stations cannot receive the synchronization signal at the same timing, and the IP connection type radio base station It is not possible to establish synchronization in the radio section between the IP connection type radio base station and the general type radio base station 1 as well as the master, and accordingly, segregation control for determining the transmission position of the control CH signal is also executed. It is not possible to ensure efficient and efficient use of radio waves.

  Also, according to the conventional TDMA mobile communication system 200, since the digital cordless master unit 2 uses a one-to-one direct communication method with respect to the slave unit 5B, it is synchronized with other general-type radio base stations 1. However, since the digital coreless base unit 2 and the general wireless base station 1 use the same frequency band, for example, a service that operates the general wireless base station 1 is used. When the digital cordless master unit 2 is arranged in the area, the slave unit 5B is affected by the radio waves of the general type radio base station 1 and the digital cordless master unit 2 in the vicinity. There is a high possibility of radio wave interference between the wireless base station 1 and the digital cordless base unit 2, and as a result, the service quality may be degraded.

  The present invention has been made in view of the above points, and the object of the present invention is to establish synchronization in a wireless section even between different types of wireless base stations to ensure efficient and efficient use of radio waves. In addition, an object of the present invention is to provide a radio base station that can greatly improve service quality.

  In order to achieve the above object, the wireless base station of the present invention is connected to a LAN, and performs wireless communication with the slave unit, thereby enabling wireless communication to connect the switching device and the slave unit via the LAN. In the base station, mode storage means for storing whether the operation mode is a self-running mode or a synchronous mode, a recognition means for recognizing the operation mode by the mode storage means when the power is turned on, a control means for controlling transmission of a radio signal, The control means, when the recognizing means recognizes the self-running mode, the wireless signal is transmitted at an arbitrary transmission timing of the local station, and the recognizing means recognizes the synchronous mode, the predetermined means When a frame signal including a control CH signal is received from a wireless base station that is a reference for frame synchronization among wireless base stations other than the own station within a given time, there is no communication between the own base station and the reference wireless base station A radio base station serving as a frame synchronization reference among radio base stations other than its own station within a predetermined time when a radio signal synchronized in frame is transmitted and the recognition means recognizes the synchronization mode When the frame signal including the control CH signal is not received from the mobile station, the radio signal is transmitted at an arbitrary transmission timing of the own station. Further, the control means is the case where the recognizing means recognizes the synchronous mode, and when the wireless signal is transmitted at an arbitrary transmission timing of the own station, among the wireless base stations other than the own station, the control means When a frame signal including a control CH signal is received from a radio base station that is a reference for synchronization, a radio signal that is frame-synchronized in a radio section between the local station and the reference radio base station is transmitted.

  According to the radio base station of the present invention configured as described above, when the synchronization mode setting is detected, the control CH is controlled from the radio base station that is the reference for the selected frame synchronization among the plurality of radio base stations other than the own station. A frame signal including a signal is received, and the control channel transmission timing of the frame signal of the local station is aligned with the transmission position of the control channel signal in the frame signal, and the base station and the reference radio are synchronized by performing frame synchronization. Since the frame synchronization in the wireless section with the base station is established, for example, a general-type wireless base station connected to the private branch exchange through the ISDN line, an IP connection type wireless base station connected to the private branch exchange connected through the LAN line, Even if wireless base stations of different types such as digital cordless base stations are established, synchronization is established in the wireless section, and the transmission position of the control CH signal after synchronization is established By implementing the segregation control to be determined at a queuing timing that absorbs the time difference of activation by synchronous control, it is possible to ensure efficient use of radio waves and to prevent radio interference between radio base stations, and to improve service quality Can be greatly improved.

  The reference radio base station is preferably a general radio base station capable of receiving a synchronization signal from the private branch exchange through the ISDN line from the viewpoint of establishing the overall synchronization within the same system.

  According to the radio base station of the present invention, when a frame signal including a control CH signal is received from a radio base station other than the own station, the frame signal is transmitted based on the control information included in the control CH signal of the frame signal. The call code, reception level and additional ID of the transmitted radio base station are detected, the call codes of the radio base station and the local station match, the reception level between the radio base station and the local station is equal to or higher than the threshold level, and the radio When it is determined that the radio base station satisfies all the conditions based on the comparison of the additional IDs of the base station and the own station, this radio base station is determined as the radio base station serving as the frame synchronization reference. The radio base station having the optimum radio synchronization condition can be used as a reference radio base station.

  According to the radio base station of the present invention, even if it is impossible to maintain the synchronization state in the radio section between the own station and the reference radio base station, when the current time reaches a predetermined time, Since the wireless synchronization operation for establishing frame synchronization in the wireless section with the selected reference wireless base station is executed, the synchronization state between the local station and the wireless base station can be restored autonomously. it can.

  According to the radio base station of the present invention, when the synchronization mode setting is detected, a predetermined time timer is started, and until the predetermined time timer expires, the local station and the reference radio base station cannot be detected or When frame synchronization in the wireless section with the reference wireless base station cannot be established, start operation in the free-running mode, which outputs the radio wave of the frame signal at any transmission timing of the local station Therefore, it is possible to reliably avoid a situation in which frame synchronization cannot be established in the wireless section between the reference wireless base station and the own station and the service operation cannot be started.

  According to the radio base station of the present invention, the self-running mode in which the radio signal of the frame signal is output at an arbitrary transmission timing of the own station and the frame synchronization in the radio section between the own station and the reference radio base station are established. Wireless base station operation mode including a synchronization mode for outputting the radio wave of the frame signal after, and each radio according to a predetermined operation of the private branch exchange, for example, a predetermined operation from a maintenance terminal connected to the control device of the private branch exchange Since the setting of the operation mode of the base station can be changed, even if the setting of the operation mode of the radio base station needs to be changed after system operation, such a setting change can be sufficiently dealt with.

  According to the radio base station of the present invention, after establishing synchronization in the radio section between the own station and the reference radio base station, the start timing of the segregation control for determining the transmission position of the control CH signal of the own station Is controlled based on a timer time that is a result of integrating the lower effective bits of the additional ID of the own station and the reference timer time, for example, the additional ID of the own station is “2”, the reference timer When the time is 30 seconds, the timer time is 60 seconds. Therefore, the start timing of the segregation control is controlled to wait for 60 seconds. It is possible to avoid a situation where the stations perform the segregation control in which the stations simultaneously determine the transmission position of the control CH signal, and as a result, the smooth segregation control can be provided.

  A TDMA radio base station showing an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration inside a TDMA radio base station according to the present embodiment. The same components as those in the TDMA mobile communication system 200 shown in FIG. 16 are denoted by the same reference numerals, and the description of the overlapping configuration and operation is omitted.

  A TDMA type mobile communication system 100 shown in FIG. 1 includes a plurality of general wireless base stations 1, a plurality of IP connection wireless base stations 10, a plurality of digital cordless base units 2, and an ISDN line 3. A private branch exchange 4 having a control device for communication connection with the base station 1, communication connection with the IP connection type radio base station 10 through the LAN line 6 and communication connection with the digital cordless base unit 2, and a general type radio base station 1 and a handset 5A that is wirelessly connected to the IP connection type wireless base station 10, and a handset 5B that is wirelessly connected to the digital cordless base unit 2.

  In the private branch exchange 4, it is assumed that a plurality of IP connection type wireless base stations 10 are connected to a LAN line 6 via a switching HUB 7.

  These general type radio base station 1 and IP connection type radio base station 10 perform the same call control procedure in the radio section based on the RCR STD-28 standard which is the ARIB standard. It is possible to provide services such as a telephone call and data communication by the wireless communication method.

  That is, the slave unit 5A does not identify the general type radio base station 1 and the IP connection type radio base station 10, and any general type radio base station 1 or IP connection type radio base station 10 arranged in the same system. Communication with is possible.

  FIG. 2 is a block diagram showing a schematic configuration inside the IP connection type radio base station 10.

  The IP connection type radio base station 10 shown in FIG. 2 has a radio function block 20 and a LAN function block 30.

  The radio functional block 20 includes two antennas 20A that transmit and receive radio waves, an antenna switching unit 21 that switches between the two antennas 20A, a transmission unit 22 that transmits radio waves, a reception unit 23 that receives radio waves, and a transmission A synthesizer unit 24 that generates a frequency used by the unit 22 and the reception unit 23, a modem unit 25 that modulates or demodulates data, a TDMA-TDD processing unit 26 that converts the data into a TDMA-TDD frame, and a radio functional block 20 An information notification unit 27 such as an LCD or LED that notifies various information, a wireless function memory unit 28 that stores various contents related to the wireless function block 20, and a wireless side CPU 29 that controls the entire wireless function block 20 Have.

  The LAN function block 30 includes a wireless interface unit 31 that controls an interface with the wireless function block 20, a DSP 32 that performs packet processing of voice data received on both the wireless side and the LAN side, and ADPCM that compresses and decompresses 32k ADPCM voice data. A codec 33, a LAN function memory unit 34 for storing various information related to the LAN function block 30, a LAN interface function for communication connection with the LAN line 6, and a LAN side CPU 35 for controlling the LAN function block 30; The power supply unit 36 supplies power to both the functional block 20 and the LAN functional block 30.

  First, the invention point of the TDMA type mobile communication system 100 according to the present embodiment will be described. FIG. 3 is an explanatory diagram briefly showing the contents of the invention points related to the TDMA type mobile communication system 100 according to the present embodiment.

  First, the point of the present invention is to establish synchronization in the radio section among the general type radio base station 1, the IP connection type radio base station 10, and the digital cordless base unit 2. For example, the general radio base station 1 is used as a reference station, and the IP connection type radio base station 10 and the digital cordless base unit 2 have their own radio wave transmission timing (TDMA-TDMA frame transmission timing) (TDMA-TDD frame transmission timing). -Synchronization in the wireless section of the general type wireless base station 1, the IP connection type wireless base station 10, and the digital cordless base unit 2 is established by sequentially adjusting the transmission timing of -TDD frames).

  Now, a case where the IP connection type radio base station 10 (10A, 10B) is synchronized with the general type radio base station 1A as a reference station will be described as an example with reference to FIG.

  The IP connection type radio base station 10A receives the radio wave from the reference station 1A, matches the radio wave transmission timing of the local station 10A with the radio wave transmission timing of the reference station 1A, and transmits the radio wave of the local station 10A.

  The other IP connection type radio base station 10B receives the radio wave of the IP connection type radio base station 10A, and matches the radio wave transmission timing of the own station 10B with the radio wave transmission timing of the IP connection type radio base station 10A. Send out radio waves. In this way, by synchronizing the radio wave transmission timing of the own station sequentially with the radio wave transmission timing of the reference station 1A, synchronization in the wireless section among the general type radio base station 1, the IP connection type radio base station 10 and the digital cordless base unit 2 is performed. Can be secured.

  By setting the reference station serving as a reference for radio synchronization to the general type radio base station 1, even if there are a plurality of general type radio base stations 1 in the same system, the general type radio base station 1 is connected to the private branch exchange 4. Since the radio wave is transmitted in synchronization with the synchronization signal from, the same timing can be obtained no matter what the general radio base station 1 radio wave transmission timing is, so there is no problem.

  In addition, in the case of the IP connection type radio base station 10C having a single arrangement in which the radio area does not directly overlap with other radio base stations, an arbitrary radio wave transmission timing is set by setting an operation mode (self-running mode) described later. In some cases, radio wave transmission may be performed, and it is possible to operate in an asynchronous state.

  Further, even if synchronization between the general type radio base station 1A and the IP connection type radio base station 10A is established, the IP connection type radio base station 10 actually uses a highly accurate timing clock for radio waves received as a synchronization signal. However, a deviation within a certain range occurs in the hardware of the built-in circuit.

  When such a deviation occurs in both the IP connection type radio base station 10A that is synchronized with the general type radio base station 1A serving as a reference station, for example, the TDMA-TDD frame and the IP connection of the general type radio base station 1A, for example The timing shift with the TDMA-TDD frame of the type wireless base station 10A occurs with time on the time axis.

  Therefore, in order to cope with such a situation, in order to ensure stable operation by radio synchronization, to which radio base station synchronization can ensure the most stable operation state, and the stable state of the entire system Therefore, it is necessary to perform a control related to synchronization control and control to keep the synchronization state even after the system starts operating.

  Furthermore, a synchronization state cannot be maintained due to a failure of a synchronization-destination wireless base station in operation or radio wave interference from a wireless base station or a repeater of another system, and processing when a loss of synchronization is caused is also necessary. Therefore, specific processing contents for dealing with this situation will be described below.

  First, the general-type radio base station 1, the IP connection type radio base station 10 and the digital cordless base unit 2 have various radio synchronizations that define the conditions of the synchronization-destination radio base station in order to ensure stable operation by radio synchronization. The conditions are set. FIG. 4 is an explanatory diagram briefly showing the contents of the wireless synchronization condition.

  The radio synchronization condition shown in FIG. 4 includes a call code indicating a radio base station (general type radio base station 1, IP connection type radio base station 10 and digital cordless base unit 2) in the same system group, There are three conditions: a reception level specification indicating a threshold level for determining whether or not the reception level between stations is good, and a local station additional ID assigned to each group of radio base stations.

  The call code recognizes that it is a radio base station in the same system group when the call codes match.

  The reception level regulation determines that the reception level between radio base stations is equal to or higher than the threshold level, and that the reception level with the radio base station is good, and the stability of periodic radio wave reception in synchronous operation This is a condition for ensuring operation.

  The own station additional ID is determined for each group of each radio base station in consideration of the arrangement of devices in the actual service area of the radio base station (general type radio base station 1, digital cordless base unit 2, and IP connection type radio base station 10). For example, a general wireless base station 1 that can obtain a stable synchronization signal from the private branch exchange 4 is assigned a small number, and further, in the order of arrangement close to the general wireless base station 1, a digital cordless parent station is provided. A number is assigned to the machine 2 and the IP connection type radio base station 10. That is, in the physical arrangement of the radio base stations, the reference radio base station is set as the youngest additional ID, and other IP connection type radio base stations 10 synchronized with the radio base station have a higher number. For example, the IP connection type radio base station 10 physically located far away from the base radio base station as a reference is placed so that the additional ID has a larger number.

  Comparing the additional ID of the own station and the additional ID of the radio base station, and selecting the same radio base station as the synchronization target radio base station when the additional ID of the radio base station is smaller than the additional ID of the own station is there.

  That is, it can be determined that the conditions of the synchronization destination radio base station are satisfied when all the radio synchronization conditions such as the call code, the reception level specification, and the own station additional ID are satisfied.

  Further, when the system is started, an IP connection type radio base station 10 arranged in the vicinity of the reference type general radio base station 1 starting from the reference type radio base station, for example, the general type radio base station 1 is used. The wireless synchronization operation is started in order, and the startup sequence is such that the far-end IP connection type wireless base station 10 and the digital cordless master unit 2 operate synchronously last.

  As a result, the entire system forms pyramid-shaped wireless synchronization with the reference wireless base station as shown in FIG. 3 as the apex, so that the synchronization state can be easily grasped. In addition, even when out-of-synchronization occurs and the self-running mode is entered, other radio base stations that are based on the radio base station where out-of-synchronization has occurred by continuing to transmit radio waves at the timing before becoming out-of-synchronization Synchronous operation can be continued and the scope of influence can be partially limited. Further, the recovery from the out-of-synchronization state can be performed autonomously and partially without affecting the entire system.

  The general type radio base station 1, the IP connection type radio base station 10, and the digital cordless base unit 2 have individual setting information related to radio synchronization control. FIG. 5 is an explanatory diagram briefly showing the contents of individual setting information related to wireless synchronization control.

  The setting information shown in FIG. 5 is assumed to be stored in the designated address of the built-in ID-ROM inside each general type radio base station 1, IP connection type radio base station 10, and digital cordless base unit 2.

  The setting information shown in FIG. 5 includes a reference timer time (timer unit) that is a parameter for the start mode time for starting the segregation control for determining the operation mode set for the own station and the transmission position of the control CH signal of the own station. And the lower effective number of bits of the additional ID of the own station, and the synchronous retry control execution time for executing the synchronous retry control which is a maintenance function of the wireless synchronization control described later of the own station.

  The operation mode is a self-running mode that outputs radio waves at any transmission timing of its own station, and outputs radio waves after establishing radio synchronization between its own station and the reference wireless base station, that is, wirelessly to other wireless base stations There is a synchronization mode for synchronizing.

  The reference timer time is set between 0 and 60 seconds, the number of lower significant bits of the additional ID is set between 00 and 04, the reference timer time is 30 seconds, and the number of lower significant bits is “4”. The divided waiting timing time is 30 seconds × 4, 120 seconds. The number of lower significant bits of the additional ID corresponds to the group number.

  The synchronous retry control execution time is set between 00 and 23:00. For example, if it is set at 2 am, it is “02”. When the synchronous retry execution time is set to a value other than “00 to 23”, for example, XX, it is assumed that no time is set for the synchronous retry control execution time.

  The wireless synchronization conditions shown in FIG. 4 and the setting information shown in FIG. 5 can be arbitrarily changed by a command operation from a maintenance terminal connected to the control device of the private branch exchange 4, for example.

  The mobile communication system described in the claims corresponds to the TDMA mobile communication system 100, and the radio base station corresponds to the general radio base station 1, the IP connection radio base station 10, and the digital cordless base unit 2. .

  Next, the operation of the TDMA mobile communication system 100 according to the present embodiment will be described. Note that the software control shown in each flowchart regarding the wireless synchronization control described in the present embodiment is communication control of a private standard system established in the ARIB second generation cordless telephone system standard (RCR STD-28 standard). It is done according to the method. For convenience of explanation, the reference station is assumed to be a general radio base station 1, and the radio base station that is radio-synchronized with the reference station is assumed to be an IP connection type radio base station 10.

  FIG. 6 is a flowchart showing processing operations related to the wireless synchronization control processing of the IP connection type wireless base station 10.

  The wireless synchronization control process shown in FIG. 6 starts up the power supply of the IP connection type wireless base station 10 and performs various processes until the IP connection type wireless base station 10 operates the self-running mode service or the synchronous mode service. In addition, it has a maintenance function for stabilizing the service operation.

  In FIG. 6, when the power is turned on (step S11), the wireless-side CPU 29 of the IP connection type wireless base station 10 executes an internal software initialization process (step S12), and then the internal ID-ROM (wireless) shown in FIG. The operation mode set in the function memory unit 28), that is, the operation mode setting of the own station is confirmed (step S13).

  When it is determined in step S13 that the operation mode is the synchronization mode “01”, the wireless CPU 29 searches for nearby wireless base stations and sends out the control CH signal of the detected synchronization destination candidate wireless base station. A control CH signal scanning process for scanning the position is executed (step S14). This control CH signal scanning process is a process for detecting the transmission position of the control CH signal in the interval range of the control CH transmission cycle shown in FIG.

  The radio side CPU 29 is a synchronization destination candidate radio base that simultaneously satisfies the radio synchronization condition shown in FIG. 4 within the interval range of the control CH transmission cycle shown in FIG. 7 during the control CH signal scan processing in step S14. It is determined whether or not the control CH signal of the station has been detected (step S15).

  If the control CH signal is not detected in step S15, the radio side CPU 29 determines whether or not the detection execution time Tx for detecting the control CH signal has elapsed (step S16). Note that the detection execution time Tx starts the time measuring operation when the control CH signal scanning process is activated.

  If the detection execution time Tx has elapsed, the radio side CPU 29 detects the control CH signal of the radio base station that is the synchronization destination candidate that simultaneously satisfies the radio synchronization conditions shown in FIG. 4 within the detection execution time Tx. Therefore, it is determined that the wireless synchronization has failed, and the operation in the self-running mode service is forcibly started (step S17). In the self-running mode service, the segregation control process is executed to determine the transmission position of the control CH signal of the local station at an arbitrary radio timing of the local station without synchronizing with other radio base stations. In this way, the service operation in the self-running mode is started.

  If the detection execution time Tx has not elapsed in step S16, the radio side CPU 29 proceeds to step S15 in order to detect the control CH signal of the synchronization destination candidate radio base station within the interval range.

  If the radio side CPU 29 detects the transmission position of the control CH signal of the radio base station that is the synchronization destination candidate in step S15, the radio side CPU 29 sets the control CH signal of the radio base station that is the synchronization destination candidate to the transmission position of the own station. A control CH alignment process for adjusting the transmission position of the control CH signal is executed (step S18). This control CH positioning process is a process for matching the timings of the TDMA-TDD frame of the synchronization target candidate radio base station and the TDMA-TDD frame of the local station.

  In step S18, the wireless side CPU 29 matches the transmission destination of the control CH signal of the synchronization destination candidate radio base station and the own station, and then measures the amount of time deviation from the synchronization destination control CH signal for each specified period. Then, a basic deviation amount measurement process is performed in which the basic deviation amount data is integrated in the basic deviation amount accumulation counter as basic deviation amount data in bit units (step S19).

  After executing the control CH signal scan process in step S14, the control CH alignment process in step S18, and the basic deviation amount measurement process in step S19, the radio side CPU 29 performs frame synchronization between the radio base station that is the synchronization destination and its own station. To establish.

  After executing the basic deviation amount measurement process in step S19, the radio side CPU 29 executes a segregation start waiting process for the control CH signal transmission position of the local station (step S20). In this segregation start waiting process, the start timing of segregation control for determining the transmission position of the control CH signal of the own station is shifted in time, and thereafter the transmission position of the control CH signal of the other radio base station. In this process, the transmission position of the control CH signal of the own station is determined as an optimal transmission position.

  When the segregation start waiting process is completed in step S20, the radio side CPU 29 completes all processes related to radio synchronization control, and monitors and synchronizes the synchronization destination radio base station in order to maintain the synchronization operation state. The service operation in the wireless synchronization mode is started while continuing the deviation correction process (step S21).

  On the other hand, if it is determined in step S13 that the operation mode is the free-running mode “00”, the wireless-side CPU 29 does not perform wireless synchronization control such as a single arrangement in which radio waves do not overlap with other wireless base stations. The operation using the mode service is started (step S22). In the self-running mode service, the segregation control process is executed to determine the transmission position of the control CH signal of the local station at an arbitrary radio timing of the local station without synchronizing with other radio base stations. In this way, the service operation in the self-running mode is started.

  In addition, during the self-running mode service in step S17 due to a failure in wireless synchronization, the wireless CPU 29 executes a synchronous retry control process that is a maintenance function when the current time reaches the synchronous retry control execution time shown in FIG. 5 (step S23). ). This synchronous retry control process executes the wireless synchronous control process again by autonomously resetting and restarting the device at the synchronous retry control execution time set in the internal ID-ROM. is there.

  The wireless side CPU 29, after executing a synchronization retry control process in step S23, restarts, and then proceeds to step S12 to execute the wireless synchronization control process again.

  In addition, the wireless synchronization retry control process in step S23 is not limited to the self-running mode service in step S17, but after the service operation is started in the wireless synchronization mode in step S21, the synchronization-destination wireless base station malfunctions or external radio waves. Even when a loss of synchronization occurs due to factors such as interference and the process shifts to the self-running mode service in step S17, the synchronous retry control process is started when the current time reaches the synchronous retry control execution time described above. is there.

  Next, the control CH signal scan process of step S14 in the wireless synchronization control process of FIG. 6 will be described. FIG. 8 is a flowchart showing a processing operation related to the control CH signal scanning process of the IP connection type radio base station 10.

  In FIG. 8, the radio side CPU 29 initializes the maximum reception level for the set control CH signal frequency (step S31), and sets the maximum number of receptions of the control CH signal to the control CH transmission cycle (N = 25 to 60) defined in the RCR standard. ) Is set to an arbitrary value N (step S32), and then the control CH signal reception operation is started within the N interval range (step S33).

  The radio side CPU 29 determines whether or not the call code of the received control CH signal matches the call code of its own station related to the radio synchronization condition shown in FIG. 4 (step S34). Note that the call code of the control CH signal is acquired by control information (hereinafter simply referred to as control CH information) included in the control CH signal periodically broadcast at N intervals.

  When it is determined that the call codes match, the radio side CPU 29 determines whether or not the reception level of the received control CH signal is equal to or higher than the threshold level defined for the reception level related to the radio synchronization condition shown in FIG. (Step S35). The reception level of the control CH signal is acquired by control CH information that is periodically broadcast at N intervals.

  If the radio side CPU 29 determines that the reception level is equal to or higher than the threshold level, the additional ID of the radio base station related to the received control CH signal is more than the additional ID of the own station related to the radio synchronization condition shown in FIG. It is determined whether the number is a young number (step S36). The additional ID of the radio base station related to the control CH signal is obtained from control CH information periodically broadcast at N intervals.

  When it is determined that the additional ID of the received control CH signal is a lower number than that of the own station, the radio side CPU 29 determines that the control CH signal satisfies all the radio synchronization conditions shown in FIG. The control CH signal is determined as the control CH signal of the synchronization destination candidate radio base station.

  Further, the radio side CPU 29 performs a correction process for matching the timings of the detected synchronization destination candidate radio base station and the own station in units of frames (step S37). In this correction process, the shift amount is sequentially corrected every time the control CH signal is received. The radio side CPU 29 determines whether or not the absolute slot position information has been received with the control CH information periodically notified at N intervals (step S38). The absolute slot position information is the transmission slot position of the control CH signal in the TDMA-TDD frame of the synchronization target candidate radio base station, and this absolute slot position information is all control CH information transmitted every N intervals. It is broadcast as radio channel information in a superframe, which is a component unit.

  If the wireless side CPU 29 has received the absolute slot position information, the wireless side CPU 29 recognizes the transmission position of the control CH signal of the synchronization destination candidate radio base station in slot units, and adds the additional ID and reception level of the synchronization destination candidate radio base station. The transmission position of the control CH signal is stored in the wireless function memory unit 28 (step S39).

  Further, the wireless side CPU 29 determines that the control CH signal has been successfully received at this scan timing, and forcibly sets the number of receptions to avoid unnecessary reception operation of the control CH signal in the prescribed interval range. To the maximum number of receptions (step S40).

  The wireless side CPU 29 determines whether or not the number of receptions has reached the maximum number of receptions (step S41). If the number of receptions reaches the maximum number of receptions, the radio side CPU 29 shifts the timing to delay the timing by 10 bits in 240 bits per slot (step S42), and this control CH signal is assigned. It is determined whether or not the search for the timing of all 240 bits in the slot has been completed (step S43).

  Note that the process of shifting the timing by 10 bits in step S42 in the direction of delaying the timing is defined by the bit width that can be scanned by one process according to the hardware performance of the device, and the set transmission position of the control CH signal In step S32, the control CH signal is repeatedly scanned until the timing of all 240 bits of the slot to which the control CH signal is allocated at the 10-bit interval is completed. To do.

  If the search for all 240 bits is completed for the N intervals in step S43, the radio side CPU 29 recognizes the transmission position of the control CH signal in slot units and bit units by the timing shift of 10 bits in step S42. The exact sending position of this control CH signal is stored in step S39.

  Accordingly, if all 240 bits have been searched in step S43, the radio side CPU 29 determines that the transmission position of the control CH signal of the synchronization target candidate radio base station has been scanned over the entire range of N intervals. Then, the timing is advanced by 240 bits to the search start position (step S44), the original position is restored, and the control CH signal is successfully received and the synchronization destination candidate radio base station is detected by a series of control CH signal scan processes. It is determined whether or not (step S45).

  The radio side CPU 29 detects the synchronization destination candidate radio base station, and if the reception of the absolute slot position of the control CH signal is successful, the control CH reception processing data (call code, reception level, reception) The timing deviation amount) is notified to the upper channel task (step S46), and the process proceeds to the control CH alignment process of step S19 in FIG. 6 (step S47).

  On the other hand, if it is determined that the absolute slot position information is not received despite the wireless synchronization condition being satisfied in step S38, the wireless CPU 29 continues to monitor the reception of the absolute slot position information. The maximum number of receptions is extended (step S48), and the reception number counter is incremented by +1 (step S49), as in the case where the wireless synchronization conditions in step S34, step S35 and step S36 are not satisfied. In order to determine whether or not the number of times has been reached, the process proceeds to step S41.

  If the number of receptions has not reached the maximum number of receptions in step S41, the wireless side CPU 29 proceeds to step S33 again to detect a control CH signal that satisfies the wireless synchronization condition.

  In addition, if the wireless side CPU 29 has not detected the synchronization destination candidate radio base station in step S45, the radio side CPU 29 determines whether or not the guard time (detection execution time) for Tx possessed by the control software has elapsed. (Step S50).

  If the radio time CPU 29 has passed the guard time (detection execution time) for Tx, the radio side CPU 29 forcibly notifies the upper channel task of the synchronization position detection failure (step S51), and forcibly executes step S17 in FIG. The running mode service is used (step S52).

  On the other hand, if the Tx guard time has not elapsed in step S50, the wireless CPU 29 determines whether or not the control CH mode is “3” (step S53). For the control CH mode, the setting when both the control CH signals assigned to the two frequencies of 12CH and 18CH are used is “3”, and the case where only the control CH signal of 12CH is used is “ The case where only 1 "and 18CH control CH signals are used is set as" 2 ".

  When it is determined that the control CH mode is “3”, the radio side CPU 29 switches the control CH signal to a frequency in which scanning is not performed (step S54), and controls the frequency in which scanning is not performed. In order to receive the CH signal, the process proceeds to step S32.

  On the other hand, if it is determined in step S53 that the control CH mode is not “3”, the wireless CPU 29 proceeds to step S32 to receive the same control CH signal again until Tx has elapsed.

  According to the control CH signal scan processing shown in FIG. 8, the accurate transmission position of the control CH signal related to the synchronization destination candidate radio base station that satisfies the radio synchronization condition within the interval range is determined not only in slot units but also in bit units. Can be detected.

  Next, the control CH positioning process of step S18 in the wireless synchronization control process of FIG. 6 will be described. FIG. 9 is a flowchart showing a processing operation related to the control CH positioning process of the IP connection type radio base station 10.

  In FIG. 9, the radio side CPU 29 initializes the retry counter (step S61), and then sets the control CH signal frequency of the synchronization destination radio base station instructed by the upper channel task (step S62).

  The radio side CPU 29 avoids the failure of the alignment process due to the shift of the transmission timing of the control CH signal of the synchronization destination radio base station due to the passage of time from the control CH signal scan process of FIG. 8 to the shift to the control CH alignment process. Therefore, the own station timing is shifted to one slot ahead of the transmission position of the control CH signal of the synchronization destination radio base station (step S63).

  Further, the radio side CPU 29 performs the control CH signal reception operation of the synchronization destination radio base station (step S64), and determines whether or not the control CH signal has been successfully received (step S65). Note that at the beginning of reception of the control CH signal, the own station timing is shifted one slot ahead of the synchronization destination in step S63, and therefore the control CH signal of the synchronization destination radio base station cannot be received.

  If the radio side CPU 29 has not successfully received the control CH signal at step S65, the radio side CPU 29 delays the reception timing by 10 bits so that the own station timing matches the transmission position of the control CH signal of the synchronization destination radio base station. (Step S66), and the retry counter is incremented by +1 for each shift (step S67).

  The radio side CPU 29 determines whether or not the retry counter has reached the number of times (25 times) exceeding the timing shift for one slot (240 bits), that is, whether or not the retry has been over (step S68).

  If the CPU 29 on the wireless side has retried over, the radio wave of the synchronization destination wireless base station cannot be received for some reason, and it is determined that the synchronization is impossible, and the device is forcibly reset and restarted. (Step S69), the process proceeds to step S64 in this process to receive the control CH signal of the synchronization destination radio base station again. At this time, since the device has been reset, the processing of the entire software is resumed from the wireless base station power ON in step S11 shown in FIG. If retry over is not performed in step S68, the process proceeds to step S64 to receive the control CH signal of the synchronization destination radio base station.

  If the CPU-side radio 29 succeeds in receiving the control CH signal in step S65, the radio-side CPU 29 determines that the transmission position of the control CH signal of the synchronization-destination radio base station and that of the own station match, By correcting the shift amount (step S70), the synchronization target radio base station and the own station are completely locked in a synchronized state.

  Further, the radio side CPU 29 initializes the retry counter, the measurement number counter, and the deviation amount accumulation counter (steps S71, 72, 73), and proceeds to the basic deviation amount measurement process shown in step S19 of FIG. 6 (step S74).

  According to the control CH positioning process shown in FIG. 9, the timing of the transmission position of the control CH signal of the local station is adjusted in bit units to the transmission position of the control CH signal of the synchronization target radio base station. The base station and the own station can be synchronized.

  Next, the basic deviation amount measurement process of step S19 in the wireless synchronization control process of FIG. 6 will be described. FIG. 10 is a flowchart showing processing operations related to the basic deviation amount measurement processing of the IP connection type radio base station 10.

  In radio synchronization, the time-acceptable deviation width in a TDMA-TDD frame is within 52.1 μS, but this tolerance inherently absorbs the transient response time for radio wave transmission and stop by the hardware of the radio equipment. Since it is necessary to consider about 40 μs as a hardware error, the allowable error range that can be assigned to this wireless synchronization software control is about 12 μs obtained by subtracting the hardware error 40 μs from 52.1 μs and converted into bits. Then it is 5 bits.

  The basic deviation amount measurement processing shown in FIG. 10 is to perform timing monitoring and correction processing of the synchronization target radio base station periodically after the start of actual operation in order to maintain the synchronization state within an allowable error range of a bit margin of 5 bits. The basic deviation amount m data is acquired.

  In FIG. 10, the radio side CPU 29 increments the measurement number counter initialized in step S72 of FIG. 9 by 1 (step S81), and again executes the control CH signal reception operation of the synchronization destination radio base station. It is determined whether or not the control destination radio base station has successfully received the control CH signal (step S82).

  If the radio side CPU 29 succeeds in receiving the control CH signal, the radio side CPU 29 clears the retry counter (step S83), and based on this reception information, the amount of deviation of the TDMA-TDD frame timing between the synchronization destination radio base station and its own station Is corrected in bit units (step S84).

  Further, the wireless side CPU 29 adds the timing shift amount based on the received information to the shift amount accumulation counter (step S85), and determines whether 30 seconds have elapsed (step S86).

  Note that the series of processes does not require a lot of startup time at the start of actual operation, while operating the normal service function, minimizing the impact on the call quality on the service function, and stabilizing the wireless synchronization state This is repeatedly executed for the optimum 30 seconds for acquiring the data of the basic deviation amount necessary for continuing the operation.

  If 30 seconds have elapsed in step S86, the wireless side CPU 29 multiplies the accumulated value of the deviation amount accumulation counter by T / 30 (monitoring period T seconds shown in FIG. 7), thereby correcting the subsequent correction processing period. A basic deviation amount m corresponding to T seconds is calculated (step S87), and a measurement number counter and a deviation accumulation counter are initialized (step S88). The basic deviation amount m in step S87 is used as basic data for basic deviation amount prediction / correction processing in FIG.

  Thereafter, in order to monitor the synchronization timing of the TDMA-TDD frame with the synchronization target radio base station in parallel with the actual operation of the device, the radio CPU 29 controls the control CH signal of the synchronization target radio base station as shown in FIG. Is set to t1 seconds, which is the initial monitoring period after the start of actual operation (step S89), and the radio wave reception mode is set to all the control CH signals of the synchronization-destination radio base station with respect to the own-station hardware. After changing the setting from the reception mode to the normal reception mode (step S90), the upper channel task is notified of the completion of the radio synchronization control (step S91), and the process proceeds to the segregation start waiting process of step S20 shown in FIG. (Step S92).

  On the other hand, if the reception of the control CH signal is not successful in step S82, the wireless CPU 29 increments the retry counter by +1 (step S93) and determines whether the retry counter has reached the maximum value (step S93). S94).

  If the retry counter has not reached the maximum value, the radio side CPU 29 proceeds to step S81 to execute the control CH signal reception operation. If the retry counter reaches the maximum value in step S94, the radio side CPU 29 determines that the radio reception of the synchronization target radio base station has failed, resets the device of the own station, and executes the restart. (Step S95).

  According to the basic deviation amount measurement processing shown in FIG. 10, after matching the transmission position of the control CH signal of the synchronization destination candidate radio base station and the own station, the time difference between the synchronization destination control CH signal and the synchronization destination control CH signal for each specified period The deviation amount can be measured and held in the timing adjustment table as basic deviation amount data in bit units.

  Next, the sorting start waiting process of step S20 in the wireless synchronization control process of FIG. 6 will be described. FIG. 11 is a flowchart showing the processing operation related to the segregation start waiting process of the IP connection type radio base station 10.

  In the segregation start waiting process shown in FIG. 11, the start timing of segregation control for determining the transmission position of the control CH signal of the own station is shifted in time, and thereafter, the control CH signal of the other radio base station is controlled. In this process, the transmission position of the control CH signal of the own station is determined as an optimal transmission position so as not to overlap with the transmission position.

  After receiving the synchronization control completion notification from the lower-level program (step S101), the wireless CPU 29 shown in FIG. 11 waits for the sorting start set in the built-in ID-ROM address “106” described in FIG. The number of lower significant bit digits (up to 8 bits) of the own station additional ID that is a parameter of the timing time is stored (step S102), and the lower significant bit digit number of the own station additional ID and the address “105” of the ID-ROM are stored. By multiplying the set reference timer time, the start timer time of segregation control is calculated (step S103). For example, when the reference timer time is “30 seconds”, the number of lower significant bit digits is 4, the additional ID of the own station is “02”, the lower valid bit value is “2”. It is 60 seconds by calculating second × 2.

  The wireless CPU 29 determines whether or not the calculated start timer time is “0” (step S104). When it is determined that the start timer time is “0”, the radio side CPU 29 determines that there is no selection start waiting time, and immediately determines the transmission position of its own control CH signal within the interval range. The control operation is started (step S105), and the transmission position of the control CH signal of the own station is determined so as not to overlap with another IP-connected radio base station 10 within the interval range, and then shown in step S21 of FIG. Service operation in the wireless synchronization mode is started (step S106).

  On the other hand, if it is determined in step S104 that the start timer time is not “0”, the wireless CPU 29 activates the start timer time (step S106), and when the start timer times out (step S107), The process proceeds to step S105 in order to start the control operation for sorting the transmission positions of the control CH signal.

  According to the segregation start waiting process shown in FIG. 11, after establishing synchronization in the wireless section with the reference wireless base station, the lower effective bit number of the additional ID of the own station is multiplied by the reference timer time. The start timer time is calculated, and after starting the start timer time and the start timer time has elapsed, the processing operation of the segregation control for determining the transmission position of the control CH signal of the own station is executed. Situation where the start timing of the split control is shifted in time to perform the split control for determining the transmission position of the control CH signal simultaneously with other radio base stations, and the individual transmission positions are determined as overlapping positions Thus, smooth segregation control can be provided.

  Next, the state monitoring / correction control process in the wireless synchronization mode service process of step S21 in the wireless synchronization control process of FIG. 6 will be described. FIG. 12 is a flowchart showing processing operations related to the state monitoring / correction control processing of the IP connection type radio base station 10.

  The state monitoring / correction control process shown in FIG. 12 is for one cycle of the TDMA-TDD frame of the synchronization target wireless base station, as shown in FIG. 7, in order to maintain the wireless synchronization state in the synchronous mode service operation. The synchronization timing corresponding to the monitoring period (T seconds) is scanned every set scanning period t1 (or t2) seconds, and the frame timing of the synchronization destination radio base station obtained every scanning period t1 (or t2) And an updated value of the basic deviation amount m corresponding to one monitoring period (T seconds) is obtained based on the scanning result of the scanning period t1 (or t2). It can be processed. The updated value of the basic deviation amount m becomes basic data for the integrated value of the deviation amount counter in the deviation amount prediction / correction process of FIG.

  The radio side CPU 29 shown in FIG. 12 performs the reception operation to the control CH signal of the synchronization destination radio base station after the measurement number counter is incremented by 1 (step S112) during the operation of the synchronization mode service (step S111). It is determined whether or not the control CH signal has been successfully received (step S113).

  If the radio side CPU 29 succeeds in receiving the control CH signal, the radio side CPU 29 adds the deviation amount between the control CH signal of the synchronization destination radio base station and the control CH signal of the own station to the deviation amount accumulation counter for continuous monitoring (step S114).

  The radio side CPU 29 determines whether or not a bit shift of ± 3 bits or more has occurred between the control CH signal of the synchronization destination radio base station and the control CH signal of the local station (step S115). If it is determined that a bit shift of ± 3 bits or more has occurred, the wireless side CPU 29 corrects the bit shift amount (step S116). Note that the reason why the bit shift of less than ± 3 bits is allowed in step S115 is that sequential prediction correction is performed in the range of ± 1 bit by interruption for each slot in the basic shift amount prediction / correction processing of FIG. 14 described later. Because.

  When correcting the bit shift amount, the wireless side CPU 29 determines whether or not the number of measurements for one cycle of the monitoring period T (seconds) is equal to or greater than the specified number (T / t1) (step S117). When it is determined that the number of measurements is equal to or greater than the specified number (T / t1), the wireless CPU 29 determines whether or not the number of measurements is the specified number (T / t1) (step S118).

  When it is determined that the number of measurements is the specified number of times T / t1, the wireless side CPU 29 calculates the total data amount (1000 T / 5) corresponding to the monitoring cycle T seconds for one cycle shown in FIG. An updated value of the basic deviation amount m is calculated by dividing by the sum of the basic deviation amount m calculated in S87 and the accumulated value of the deviation amount accumulation counter measured this time (step S119).

  The radio side CPU 29 updates the basic deviation amount m held in the current timing adjustment table based on the calculation result of step S119.

  Further, after calculating the update value of the basic deviation amount m, the radio side CPU 29 determines the control CH signal reception interval of the destination radio base station from the scan cycle t1 second of the first cycle, as shown in FIG. The setting is changed to a scan period t2 seconds (= t1 × 10 seconds) after the second cycle in which the monitoring period becomes longer (step S120).

  There are two reasons for changing the scan period from t1 seconds to t2 seconds. First, even in an instantaneous time of 5 ms for scanning, since all reception modes are set only for synchronization monitoring, a communication error occurs in the wireless section during that period. This is to keep the error rate to a minimum and prevent the deterioration of the voice call quality of the normal service. Further, the second point is that the basic shift amount measurement process (see FIG. 10) and the first cycle process have already been successful in the monitoring after the second cycle, so that the wireless synchronization state can be reliably maintained. The point is that it can be determined that data of the basic deviation amount m has been acquired.

  When the setting is changed to the monitoring cycle t2 seconds in step S120, the radio side CPU 29 initializes the measurement number counter and the deviation monitoring cumulative amount counter for continuous monitoring (step S121), and then shifts to the monitoring operation in the next cycle and thereafter. (Step S122).

  On the other hand, if it is determined in step S113 that the control CH signal has not been successfully received, the radio side CPU 29 increments the retry counter by +1 (step S123), and determines whether the retry counter has retried over (step S124). .

  When it is determined that the retry counter has retried over, the radio side CPU 29 forcibly sets the reception interval (scan cycle) to t2 seconds that does not affect the call quality (step S125), and then synchronizes as radio synchronization failure. The self-running mode service is operated in a disconnected state (step S126).

  On the other hand, when the radio side CPU 29 shifts to the monitoring operation of the next cycle in step S122, the radio side CPU 29 shifts to the processing operation of step S111. At this time, the specified number of times for the number of measurements in step S117 and step S118 is not T / t1, but T / t2. (T1 second applies only to the first cycle monitoring).

  According to the state monitoring / correction control process shown in FIG. 12, the synchronization timing corresponding to the monitoring period (T seconds) of one cycle of the TDMA-TDD frame of the synchronization target radio base station is set to the set scan period t1 (or t2) Scans every second, corrects the amount of bit deviation from the frame timing of the synchronization-destination radio base station obtained every scan period t1 (or t2), and displays the monitoring result of the scan period t1 (or t2). Based on this, since the update value of the basic deviation amount m corresponding to the monitoring cycle (T seconds) for one cycle is obtained, the wireless synchronization state in the synchronous mode service operation can be stably maintained.

  Next, the wireless synchronization retry control process of step S23 in the wireless synchronization control process of FIG. 6 will be described. FIG. 13 is a flowchart showing processing operations related to the wireless synchronization retry control processing of the IP connection type wireless base station 10.

  The wireless synchronization retry control process shown in FIG. 13 is a case where the synchronization state is lost due to failure or reset of the synchronization destination wireless base station, or due to radio wave interference by other wireless devices, and when synchronization is lost. When the current time becomes the retry control execution time, this is a process of executing a retry operation for wireless synchronization according to a predetermined condition.

  When the wireless CPU 29 shown in FIG. 13 executes an interrupt monitoring process at an arbitrary Y-second cycle (step S131), the operation mode setting set in the address “29” of the built-in ID-ROM shown in FIG. 5 is synchronized. It is determined whether or not the mode is selected (step S132).

  If it is determined that the operation mode setting is the synchronous mode, the wireless CPU 29 determines whether the synchronous retry control execution time set in the address “30” of the built-in ID-ROM shown in FIG. It is determined whether or not (step S132A).

  If it is determined that the synchronous retry control execution time is not other than 0 to 23, the wireless side CPU 29 determines whether or not the current time is the synchronous retry control execution time set in the address “30” of the ID-ROM. (Step S133).

  When it is determined that the current time is the synchronous retry control execution time, the radio side CPU 29 determines whether or not the own station currently holds the operation state in the synchronous mode (step S134).

  If it is determined that the local station does not currently hold the operation state in the synchronous mode, the wireless side CPU 29 determines that the voice CH in use by performing the reset when it is in the free-running mode due to loss of synchronization. In order to prevent forcible disconnection in advance, it is determined whether or not all voice channels are empty (step S135).

  If it is determined that all voice channels are empty, the wireless side CPU 29 has already performed the retry operation on the same day in order to prevent a problem that the service operation is stopped unnecessarily by repeating the reset operation. It is determined whether or not a reset execution flag indicating ON is ON (step S136).

  When it is determined that the reset execution flag is not ON, the wireless side CPU 29 determines that the same retry operation is not performed on the same day, sets the reset execution flag to ON (step S137), and performs wireless synchronization retry operation. The reset operation is executed by (Step S138), and this processing operation is terminated.

  If it is determined in step S132 that the mode is not the synchronization mode, or if it is determined in step S132A that the synchronous retry control execution time is other than 0 to 23, or the radio side CPU 29 is performing the synchronous operation in step S134. If it is determined that there is, or if it is determined in step S135 that all voice CHs are not empty, this processing operation is terminated without executing the reset operation by the wireless synchronization retry operation.

  When determining that the reset execution flag is ON in step S136, the wireless side CPU 29 determines that the same wireless synchronization retry operation has been performed on the same day, and executes the reset operation by this wireless synchronization retry operation. This processing operation is finished without.

  If it is determined in step S133 that the current time is not the synchronous retry control execution time, the wireless CPU 29 sets the reset execution flag to OFF (step S139), and ends this processing operation.

  According to the wireless synchronization retry control process shown in FIG. 13, if all the conditions of steps S132, 132A, 133, 134, 135, and 136 are satisfied when the current time becomes the retry control execution time during synchronization loss, By executing the reset of the device and executing the processing operation of the wireless synchronization control again, it is possible to autonomously recover to the synchronization mode and to guarantee the stable operation of the system.

  FIG. 14 is a flowchart showing processing operations related to the basic deviation amount prediction / correction processing of the synchronization timing of the IP connection type radio base station 10.

  The basic deviation amount prediction / correction process shown in FIG. 14 is always performed by an interrupt process using a subroutine program with built-in firmware, and the basic TDMA-TDD frame timing deviation between the own station and the synchronization target radio base station with respect to the next monitoring cycle is basically determined. Based on the deviation amount m, the value accumulated in the deviation amount accumulation counter is fed back to the frame correction register built in the hardware TDMA-TDD processing unit 26, and the timing deviation is within a range of ± 1 bit. This is a subroutine process for predictive correction.

  In FIG. 14, the radio side CPU 29 generates an interrupt process for each slot of the TDMA-TDD frame (step S141), and determines whether or not the value of the deviation accumulation counter is other than 0 (step S142).

  If it is determined that the value of the deviation amount accumulation counter is other than 0, the wireless side CPU 29 determines that correction control is necessary, increments the timing correction counter by +1 (step S143), and then performs this timing correction. It is determined whether or not the counter has reached the number of frames shifted by 1 bit (step S144).

  When determining that the timing correction counter has reached the number of frames shifted by 1 bit, the wireless CPU 29 determines whether or not the value of the shift amount accumulation counter is 0 or more (step S145).

  When it is determined that the value of the shift amount accumulation counter is 0 or more, the radio side CPU 29 determines that the shift is in the plus direction and sets 1 in the frame correction register built in the hardware TDMA-TDD processing unit 26. Addition is performed (step S146).

  When the radio side CPU 29 adds 1 to the frame correction register, the radio side CPU 29 corrects the bit width in the slot at the time when the timing shift occurs based on the predicted shift amount calculated for the frame width of the local station. By clearing the timing correction counter (step S147), this processing operation is terminated.

  On the other hand, if it is determined in step S145 that the value of the deviation amount accumulation counter is not greater than or equal to 0, the radio side CPU 29 determines that the deviation is in the minus direction and subtracts 1 from the frame correction register (step S148). Then, based on the predicted deviation amount calculated for the frame width of the own station, correction is performed in bit units in the slot at the time when timing deviation occurs, and after completion of this correction processing, the process proceeds to step S147 to clear the timing correction counter To do.

  According to the basic deviation amount prediction / correction process shown in FIG. 14, it is always performed by the interruption process, and the deviation of the TDMA-TDD frame timing between the local station and the synchronization destination radio base station with respect to the next monitoring period is set to the basic deviation amount m. Based on the value accumulated in the deviation accumulation counter, the result is fed back to the frame correction register built in the TDMA-TDD processing unit 26 of the hardware, and the timing deviation is predicted and corrected within a range of ± 1 bit. Can do.

  According to the present embodiment, when it is determined that the own station is in the synchronization mode, the control CH signal is included from the selected radio base station serving as a reference for frame synchronization among a plurality of radio base stations other than the own station. Receives the frame signal, matches the transmission timing of the frame signal of the local station to the transmission position of the control CH signal in the frame signal, and establishes frame synchronization in the radio section between the local station and the reference radio base station For example, the general wireless base station 1 connected to the private branch exchange 4 through the ISDN line 3, the IP connection wireless base station 10 connected to the private branch exchange 4 connected through the LAN line 6, the digital cordless base unit 2, etc. Even with different types of wireless base stations, frame synchronization is established in the wireless section, and segregation control for determining the transmission position of the control CH signal after synchronization is established by synchronization control. By performing the waiting time to absorb the time difference between start, while securing an efficient effective utilization of radio waves, it is possible to prevent interference between the radio base station, it is possible to greatly improve the service quality.

  According to the present embodiment, as shown in the control CH signal scan process of FIG. 8, when a frame signal including a control CH signal is received from a radio base station other than its own station, the control signal included in this frame signal is used. Then, the call code, reception level and additional ID of the radio base station that sent this frame signal are detected, the call codes of the radio base station and the own station match, and the reception level between the radio base station and the own station is the threshold level. When it is determined that the wireless base station satisfies the reference condition for the wireless synchronization of the local station based on the comparison of the additional IDs of the wireless base station and the local station, the wireless base station is Since the reference radio base station is determined, each radio base station in the entire system can make the optimum radio base station the reference radio base station.

  According to the present embodiment, as shown in the wireless synchronization retry control process of FIG. 13, even if the synchronization state in the wireless section between the local station and the reference wireless base station cannot be maintained, the current time When the synchronization retry control execution time is reached, since the wireless synchronization processing for reestablishing synchronization in the wireless section between the own station and the reference wireless base station is executed, the own station and the wireless base station The synchronization state can be recovered autonomously.

  According to the present embodiment, as shown in the control CH signal scanning process of FIG. 8, when it is determined that the local station is in the synchronous mode, the timer for measuring the detection execution time Tx is started, and this detection execution time A self-running mode that outputs a radio wave of a frame signal at an arbitrary transmission timing of the local station when synchronization in the wireless section between the local station and the reference wireless base station cannot be established within Tx Since the operation in the radio section is started, it is possible to reliably avoid the situation where the synchronization between the base station and the base station cannot be established and the service operation cannot be started. Can do.

  According to the present embodiment, a self-running mode for outputting a radio wave of a frame signal at an arbitrary transmission timing of the local station, and a frame after establishing synchronization in the wireless section between the local station and the reference wireless base station It has an operation mode of the radio base station including a synchronous mode for outputting signal radio waves, and arbitrarily sets the operation mode of each radio base station according to a predetermined operation from a maintenance terminal connected to the control device of the private branch exchange 4 Since it can be changed, even if the necessity of changing the setting of the operation mode of the radio base station arises after the system operation, such setting change can be sufficiently dealt with.

  According to the present embodiment, as shown in the segregation start waiting process in FIG. 11, after establishing synchronization in the wireless section with the reference wireless base station, the additional ID (up to 8 bits) of the own station The start timer time is calculated by multiplying the number of lower significant bits of the reference time and the reference timer time, and after starting the start timer time, the transmission position of the control CH signal of the own station is determined. Since the processing operation of the control is executed, it is possible to perform the segregation control in which a plurality of radio base stations simultaneously determine the transmission position of the control CH signal by shifting the start timing of the segregation control in time. The situation can be avoided, and as a result, smooth segregation control can be provided.

  In the above embodiment, the embodiment has been described in which the reference station is the general wireless base station 1 and the wireless base station that is wirelessly synchronized with the reference station is the IP-connected wireless base station 10A. It goes without saying that the same effect can be obtained even if the wireless base station to be used is the digital cordless base unit 2.

  Further, in the above embodiment, setting information and status such as operation mode and additional ID being operated for each radio base station (general type radio base station 1, IP connection type radio base station 10 and digital cordless base unit 2). Information or the like may be set, and the setting information and status information of the radio base station may be identified by various checking means as shown in FIG.

  For example, when the operation mode and additional ID during operation of each radio base station are collectively managed by the control device of the private branch exchange 4 and a maintenance command is input from the maintenance terminal connected to the serial port of this control device, the maintenance terminal , The operation mode of a specific radio base station, status information such as starting, self-running mode, synchronous mode, blocking, failure or power off, additional ID of the synchronization target radio base station, Control CH information or the like may be displayed on the screen. Note that various information such as setting information and status information of a specific radio base station may be displayed on the screen from a PC terminal connected to the LAN line in accordance with a designation operation.

  Further, the information notification unit 27 of the IP connection type radio base station 10 includes an LED lamp and an LCD display unit. For example, the operation content during operation of the radio base station with the display content of the LED lamp, for example, blue and synchronous operation Medium, green may be informed of self-running operation, and red may be informed of closure, and the LCD display unit may be informed of the additional ID of the synchronization target wireless base station, the operation mode of the own station, and the like.

  The radio base station according to the present invention includes different types of radio base stations such as a general radio base station connected to a private branch exchange via an ISDN line, an IP connection radio base station connected to a private branch exchange connected via a LAN line, and a digital cordless base unit. Even between stations, synchronization is established in the wireless section, and by implementing segregation control for determining the transmission position of the control CH signal after the synchronization is established, the radio base By preventing radio wave interference between stations, the service quality can be greatly improved, which is useful for TDMA radio base stations and the like.

1 is a block diagram showing a schematic configuration inside a TDMA radio base station according to an embodiment of the present invention. FIG. It is a block diagram which shows schematic structure inside the IP connection type | mold base station regarding the radio | wireless base station of the TDMA system which shows this Embodiment. It is explanatory drawing which shows the synchronization establishment system between the base stations used as the point of the radio base station of the TDMA system which shows this Embodiment. It is explanatory drawing which shows the radio | wireless synchronization conditions of the radio base station in this Embodiment. It is explanatory drawing which shows the setting information of the wireless base station in this Embodiment. It is a flowchart which shows the processing operation in connection with the radio | wireless synchronous control process of the IP connection type | mold radio base station in this Embodiment. It is explanatory drawing which shows directly the relationship of each monitoring period in the control CH transmission period concerning this Embodiment. It is a flowchart which shows the processing operation regarding the control CH signal scanning process of the IP connection type | mold radio base station in this Embodiment. It is a flowchart which shows the processing operation regarding the control CH position alignment process of the IP connection type | mold radio base station in this Embodiment. It is a flowchart which shows the processing operation regarding the basic deviation | shift amount measurement process of the IP connection type | mold radio base station in this Embodiment. It is a flowchart which shows the processing operation in connection with the segregation start waiting process of the IP connection type | mold radio base station in this Embodiment. It is a flowchart which shows the processing operation in connection with the state monitoring and the correction | amendment process of the IP connection type | mold radio base station in this Embodiment. It is a flowchart which shows the processing operation in connection with the synchronous retry control process of the IP connection type | mold radio base station in this Embodiment. It is a flowchart which shows the processing operation regarding the basic deviation amount prediction / correction processing of the IP connection type radio base station in the present embodiment. It is explanatory drawing which shows the example for alerting | reporting the status information etc. of the wireless base station in connection with this Embodiment. It is a block diagram which shows schematic structure inside the radio base station of a general TDMA system. It is explanatory drawing which shows the concept of the TDMA-TDD frame used in the radio area of the radio base station of a general TDMA system. It is explanatory drawing which shows directly the control CH transmission period in the radio base station of a general TDMA system.

1 General radio base station (radio base station)
2 Digital cordless master unit (wireless base station)
4 Private branch exchange 5A, 5B Slave unit (wireless slave unit)
10 IP connection type wireless base station (wireless base station)
100 TDMA mobile communication system (mobile communication system)

Claims (2)

In the radio base station that enables the exchange device and the slave unit to be connected by performing radio communication with the slave unit,
When a radio signal is transmitted at an arbitrary transmission timing of the own station, a reception process of a frame signal including a control CH signal is performed from a reference radio base station, and the control CH signal can be stably received as a condition Determine whether it is possible to receive at a reception level equal to or higher than a predetermined threshold level,
If the reception level of the control CH signal is smaller than the threshold level, radio signal transmission at an arbitrary transmission timing of the own station is continued,
When the reception level of the control CH signal is equal to or higher than the threshold level and all communication channels of the own station are idle, a radio signal that is frame-synchronized between the reference radio base station and the own station is transmitted. ,
A wireless base station characterized by that. In the radio base station that enables the exchange device and the slave unit to be connected by performing radio communication with the slave unit,
When a radio signal is transmitted at an arbitrary transmission timing of the own station, a reception process of a frame signal including a control CH signal is performed from a reference radio base station, and the control CH signal can be stably received as a condition Determine whether it is possible to receive at a reception level equal to or higher than a predetermined threshold level,
If the reception level of the control CH signal is smaller than the threshold level, radio signal transmission at an arbitrary transmission timing of the own station is continued,
When the reception level of the control CH signal is equal to or higher than the threshold level, it is determined whether or not all communication channels of the own station are idle.
If all communication channels are not empty, wireless signal transmission at any transmission timing of the own station is continued,
When all communication CHs are idle, a radio signal that is frame-synchronized between the base radio base station and the own station is transmitted.
A wireless base station characterized by that.