JP3522704B2 - Wireless synchronization method and apparatus - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless synchronization method between a base station device and a terminal device, which is suitable for providing a service by an integrated digital network such as ISDN using a low speed communication service such as PHS. And the device.

[0002]

2. Description of the Related Art FIG. 10 is a block diagram showing a configuration of a conventional PHS base station and a PHS terminal. In the figure, 100 is a PHS terminal, 200 is a PHS base station,
101 is a PHS for synchronizing with the PHS base station 200
The timing control unit of the terminal 100, 102 is a wireless transmission / reception unit, 103 is a frequency dividing circuit, 104 is a transmission circuit, 105 is a synthesizer for switching channels, 106 is a CPU that controls each unit, 107 is a wireless antenna, and 201 is P.
It is a wireless antenna of the HS base station 200.

FIG. 11 shows a PHS in this PHS system.
FIG. 5 is an explanatory diagram showing an example of transmission slot and reception slot for transmitting and receiving information between the base station 200 and the PHS terminal 100, and assignment of frequencies.

Next, the operation will be described. In this PHS system, the communication service is currently available at a transmission rate of 64 Kbps, and the PHS terminal 100 is synchronized with the PHS base station 200 by the one-line radio transmission / reception unit 102, the synthesizer 105, and the like. Then, it is possible to transmit and receive information between the PHS base station 200 and the PHS terminal 100 in units of one frame having 4 transmission slots and 4 reception slots. In transmitting and receiving information between the PHS base station 200 and the PHS terminal 100, as shown in FIG. 11 (a), the PHS base station 200 and the PHS terminal 200 are assigned with two slots allocated with different frequency assignments. Information can be sent to and received from 100. In addition, FIG.
As shown in (b), when the same frequency is assigned,
It is possible to transmit and receive information between the PHS base station 200 and the PHS terminal 100 by assigning consecutive slots without opening slots. Thus, in the PHS communication system, the PHS base station 200 and the PHS terminal 10
There are limits on transmission rates between 0 and slot and frequency assignments.

[0005]

By the way, in order to provide a service by an integrated digital network such as ISDN using the PHS system, synchronization using a maximum of 5 slots is indispensable. In the PHS system, the PHS base station 200 is used. Is synchronized with the PHS terminal 100 with 4 transmission slots and 4 reception slots as described above.
Regarding the slot allocation between the PHS terminal 100 and the PHS base station 200 at this time, continuous slot allocation is performed with the same frequency as shown in FIG. 11B due to the restriction of the synthesizer 105 on the PHS terminal 100 side. There was a problem that it was difficult except for the case. Also, P
Information is transmitted and received between the HS base station 200 and the PHS terminal 100 by assigning 2 slots of transmission slots and 2 slots of reception slots.
In order to provide a service by the integrated digital network such as SDN, the transmission speed of the integrated digital network such as ISDN is high, so that the PHS base station 200 and the PHS
There has been a problem that the limitation with the S terminal 100 becomes a bottleneck.

The present invention has been made to solve the above problems, and it is an object of the present invention to obtain a radio synchronization method and apparatus which enable continuous slot allocation between a base station apparatus and a terminal apparatus. To aim.

It is another object of the present invention to provide a wireless synchronization method and device capable of substantially expanding the number of slots for wirelessly communicating between a base station device and a terminal device and increasing the number of slots.

[0008]

SUMMARY OF THE INVENTION A wireless synchronization method according to the present invention is provided with a plurality of wireless / timing control units constituting a terminal device.
Of the radio station that is synchronized with the base station device
The terminal device detects the operation timing of the imming control unit.
Operation of other radio / timing controller that composes
To the operation timing of the desired wireless / timing control unit
While matching, the slot transmitted from the base station device
When multiple radio / timing control units receive respectively,
These slots are multiplexed and sent to the high speed communication service network.
And the multiplexed slots from the high speed communication service network.
When received, the multiplexed slot is separated and
Slots separated in parallel from a number of radio and timing controls
Is transmitted to the base station device.

A radio synchronization method according to the present invention is a radio synchronization method in radio communication between a base station device and a terminal device, and is a radio / timing control unit which is a component of the terminal device synchronized with the base station device. The detection signal of the control slot or the communication slot is extracted from, and the frame timing of the other radio / timing control unit of the terminal device is extracted, and the detection signal is synchronized with the radio / timing control unit, and the communication of the other radio / timing control unit is performed. For slots,
Synchronize with the base station device independently of the timing control unit,
Each slot synchronized with the base station device is multiplexed with the slot received by the timing control unit and output to the high-speed communication service network, while the slots transmitted from the high-speed communication service network are separated to separate each radio The timing control unit transmits the data to the base station device in parallel.

A terminal device according to the present invention comprises a plurality of wireless
Of the timing control units, the units that are synchronized with the base station device
Detects the operation timing of the desired wireless / timing control unit
Control the operation timing of other wireless / timing control units.
Match the operation timing of your wireless / timing control unit
The timing generation means that causes the base station device to transmit
Slots are received by multiple radio and timing control units, respectively.
Then, the slots are multiplexed and the high-speed communication server
While transmitting to the service network, multiplexing from the high-speed communication service network
Received, the multiplexed slot
Output to multiple radio / timing control units
And a data demultiplexing unit.

A terminal device according to the present invention is a terminal device that wirelessly communicates with a base station device, and includes a plurality of radio / timing control units including a radio / timing control unit that synchronizes with the base station device, and the base station device. The detection signal of the control slot or the communication slot is extracted from the radio / timing control unit that synchronizes with the radio timing controller, and the frame timing of the radio / timing control unit other than the radio / timing control unit that synchronizes with the base station device is extracted. A synchronization control unit that synchronizes with the radio / timing control unit and synchronizes communication slots of other radio / timing control units with the base station device independently of the radio / timing control unit, and a plurality of radio / timing control units. While the slots received in parallel from the base station equipment are multiplexed and output to the high speed communication service network, Is obtained so as to include a data demultiplexing unit for outputting separating slots sent are multiplexed to a plurality of wireless timing control unit.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below. Embodiment 1. FIG. 1 is a terminal device to which the wireless synchronization method according to the first embodiment is applied (hereinafter referred to as a terminal device for high-speed communication service).
FIG. 3 is a block diagram showing a base station device and a base station device. In the figure,
1 is ISDN using a radio / timing control unit equivalent to that used in low speed communication services such as PHS.
It is a terminal device (terminal device) for high-speed communication service when providing high-speed communication service by a comprehensive digital network such as, and is attached to, for example, a telephone pole. Two
Reference numeral 1 is a base station device that wirelessly communicates with the high-speed communication service terminal device 1. This base station device 21 is a PHS.
Multiple pieces of hardware as a base station are provided.

Reference numerals 2, 3, 4, and 5 are radio / timing control units that perform radio / timing control equivalent to those used in PHS terminals, and are provided from system 1 to system N.
These radio / timing control units 2, 3, 4, and 5 are independently synchronized with the base station device 21, and the transmission slots of the radio / timing control units 2, 3, 4, and 5 between the respective systems. , The operation timings including the receiving slots are the same, but the timings are not matched with each other.

Reference numeral 6 is a radio antenna of the radio / timing control unit 2, 7 is a radio antenna of the radio / timing control unit 3,
Reference numeral 8 is a wireless antenna of the wireless / timing control unit 4, and 9 is a wireless antenna of the wireless / timing control unit 5. Reference numeral 10 denotes a data multiplexing / demultiplexing unit that multiplexes or demultiplexes transmission / reception information including information on communication channels transmitted / received by the radio / timing control units 2, 3, 4, ... Reference numeral 11 denotes an integrated digital network (high speed communication service network) such as ISDN that provides high speed communication services. Reference numeral 22 is a radio antenna of the base station device 21, 23 is a public network, and the base station device 21 is connected to the public network 23.

FIG. 2 shows radio / timing control units 2, 3, 4, 5 and base station apparatus 2 provided from system 1 to system N.
1 is an explanatory diagram showing a frame configuration in wireless communication seen from the base station device 21 side between the base station device 1 and the base station device 1, and FIG. The frame configuration viewed from the side of the wireless communication base station device 21 shown in FIG. 1B is the base station device 2 of the wireless communication performed between the wireless / timing control unit 3 of the system 2 and the base station device 21.
The frame structure viewed from the side 1 is shown in FIG.
It is a frame configuration seen from the base station device 21 side of wireless communication performed between the timing control unit 4 and the base station device 21.

Next, the operation will be described. Each radio / timing control unit 2, 3, of the terminal device 1 for high-speed communication service
4 and 5 are independently synchronized with the base station device 21. As shown in the frame configuration of FIG. 2A, the base station device 21 has communication channels such as a transmission slot TS1 and a reception slot RS1 to which the frequency f1 is assigned, and a transmission slot TS3 and a reception slot RS3 to which the frequency f2 is assigned. The Tch and the control channel Cch are used to communicate with the radio / timing control unit 2 of the system 1. In this way, when the frequency assignments are different, the base station device 21 communicates with the radio / timing control unit 2 of the system 1 by using two slots that are one slot apart. Also, FIG.
As shown in, the base station apparatus 21 communicates with the radio / timing controller 3 of the system 2 using the communication channel Tch such as the transmission slot TS2 and the reception slot RS2, the transmission slot TS3 and the reception slot RS3, and the control channel Cch. To do. In this case, since the slots are assigned in consecutive slots, the frequency is assigned to the same frequency (frequency f3). Further, as shown in FIG. 7C, the base station device 21 has a transmission slot TS2 and a reception slot RS2 assigned at the frequency f4, and a transmission slot TS4 and a reception slot RS assigned at the frequency f5.
4 and other communication channels Tch and control channel Cch are used to communicate with the radio / timing controller 4 of the system 3.
In this way, when the frequency assignments are different, the base station device 21 communicates with the radio / timing controller 4 of the system 3 by using two slots that are one slot apart.

The information transmitted from the base station device 21 to the radio / timing control unit 2 of the system 1 of the terminal device 1 for high speed communication service by the communication channel Tch of the transmission slot TS1 to which the frequency f1 is assigned is data multiplexing / demultiplexing. Part 1
It is multiplexed with 0 and output to the integrated digital network 11. Further, the information sent from the integrated digital network 11 to the radio / timing control unit 2 of the system 1 of the terminal device 1 for high speed communication service is separated by the data multiplexing / separating unit 10 and the reception slot to which the frequency f1 is assigned. From the radio / timing control unit 2 to the base station device 21 using the communication channel of RS1.
Sent to. In addition, the base station device 2 uses the communication channel Tch of the transmission slot TS3 to which the frequency f2 is assigned.
Information transmitted from 1 to the radio / timing control unit 2 of the system 1 of the terminal device 1 for high-speed communication service is multiplexed by the data multiplexing / demultiplexing unit 10 and output to the integrated digital network 11. Further, the information sent from the integrated digital network 11 to the radio / timing control unit 2 of the system 1 of the terminal device 1 for high speed communication service is separated by the data multiplexing / separating unit 10,
The signal is sent from the radio / timing controller 2 to the base station apparatus 21 through the communication channel of the reception slot RS3 to which the frequency f2 is assigned.

Further, the base station device 2 is provided by the communication channel Tch of the transmission slot TS2 to which the frequency f3 is assigned.
Information transmitted from 1 to the radio / timing control unit 3 of the system 2 of the terminal device 1 for high-speed communication service is multiplexed by the data multiplexing / demultiplexing unit 10 and output to the integrated digital network 11. Further, the information sent from the integrated digital network 11 to the radio / timing control unit 3 of the system 2 of the terminal device 1 for high speed communication service is separated by the data multiplexing / separating unit 10 and the reception slot to which the frequency f3 is assigned. It is sent from the radio / timing control unit 2 to the base station device 21 via the communication channel of RS2. Also, the transmission slot TS2
And a transmission slot T to which a frequency f3 continuous with is assigned
The information transmitted from the base station device 21 to the radio / timing control unit 3 of the system 2 of the terminal device 1 for high speed communication service via the communication channel Tch of S3 is the data multiplexing / demultiplexing unit 10.
Are multiplexed and output to the integrated digital network 11. The information sent from the integrated digital network 11 to the radio / timing controller 3 of the system 2 of the terminal device 1 for high speed communication service is separated by the data multiplexer / separator 10 and has a frequency continuous with the reception slot RS2. It is sent from the radio / timing control unit 3 to the base station apparatus 21 through the communication channel of the reception slot RS3 to which f3 is assigned.

Further, the base station apparatus 2 is provided by the communication channel Tch of the transmission slot TS2 to which the frequency f4 is assigned.
The information transmitted from 1 to the radio / timing controller 4 of the system 3 of the terminal device 1 for high-speed communication service is multiplexed by the data multiplexer / demultiplexer 10 and output to the integrated digital network 11. Further, the information sent from the integrated digital network 11 to the radio / timing control unit 4 of the system 3 of the terminal device 1 for high speed communication service is separated by the data multiplexing / separating unit 10,
The signal is sent from the radio / timing controller 4 to the base station apparatus 21 through the communication channel of the reception slot RS2 to which the frequency f4 is assigned. The information transmitted from the base station device 21 to the radio / timing control unit 4 of the system 3 of the terminal device 1 for high-speed communication service by the communication channel Tch of the transmission slot TS4 to which the frequency f5 is assigned is the data multiplexing / demultiplexing unit. It is multiplexed at 10 and output to the integrated digital network 11. Also, from the integrated digital network 11 to the wireless / timing control unit 4 of the system 3 of the terminal device 1 for high-speed communication service.
The information sent to the receiving slot RS4 demultiplexed by the data demultiplexing / demultiplexing unit 10 and assigned the frequency f5.
Is transmitted from the radio / timing control unit 4 to the base station device 21 via the communication channel of.

As a result, the terminal device 1 for high-speed communication service
No continuous slot assignment is possible between the radio / timing control unit of each system and the base station apparatus 21 unless the frequencies to be assigned are the same. In terms of the relationship between the service terminal device 1 and the base station device 21, the number of slots used for wireless communication performed between the high-speed communication service terminal device 1 and the base station device 21 is equal to the number of slots arranged in parallel. -IS will be substantially expanded and increased according to the number of timing control units, so IS using a communication system such as PHS.
It is possible to provide a wireless synchronization method and apparatus that realizes substantial expansion of the number of transmission slots and the number of reception slots and multi-slots when providing a service by an integrated digital network such as DN, and using a low speed communication service such as PHS. I
There is an effect that a service can be provided by an integrated digital network having a high transmission rate such as SDN.

Embodiment 2. FIG. 3 is a block diagram showing a high speed communication service terminal apparatus and a base station apparatus to which the wireless synchronization method of the second embodiment is applied. 3, parts that are the same as or correspond to those in FIG. 1 are assigned the same reference numerals and explanations thereof are omitted. In the figure, 31 is an IS using a radio / timing control unit equivalent to that used in a communication system such as PHS.
This is a terminal device (terminal device) for high-speed communication service when providing high-speed communication service by a comprehensive digital network such as DN, and is attached to, for example, a telephone pole. Reference numeral 41 is a base station device that wirelessly communicates with the high-speed communication service terminal device 31. This base station device 41
Is equipped with a plurality of hardware as PHS base stations.

Reference numeral 32 is a radio / timing control unit of the system 1 for performing radio / timing control equivalent to that of the PHS terminal. Three
Reference numeral 3 denotes a radio / timing control unit of a system 2 that performs radio / timing control equivalent to that of a PHS base station, has two synthesizer systems, and can assign continuous 4 slots at different frequencies. Reference numeral 34 denotes a radio / timing control unit of a system N that performs radio / timing control equivalent to that of a PHS base station, has two synthesizer systems like the radio / timing control unit 33, and has four consecutive slots at different frequencies. Can be assigned. 35 is PHS
A signal (a detection pulse of a control channel Cch or a communication channel Tch) synchronized with the timing of the base station device 41 is extracted from the wireless / timing control unit 32 of the system 1 equivalent to the terminal, and the system 2 is extracted by the extracted signal. The operation timing (frame timing and slot timing) in the wireless / timing control units 33 and 34 thereafter is
It is a timing generation means for matching with the radio / timing control unit 32 of the system 1. Reference numeral 36 is a wireless antenna of the wireless / timing control unit 33, 37 is a wireless antenna of the wireless / timing control unit 34, and 42 is a wireless antenna of the base station device 41.

FIG. 4 shows the radio / timing control units 32, 3
3, 34 and the timing generation means 35 shown in FIG.
4 is a functional block diagram, and in FIG. 4, parts that are the same as or equivalent to those in FIG. 3 are assigned the same reference numerals and explanations thereof are omitted. In the figure, 351 is, for example, 19
-Oscillator that outputs the reference clock of MHz, 352 is 1
This is a frequency dividing circuit for performing a frequency division of 96,000. Reference numeral 353 denotes a system clock / timing generation unit that periodically finely adjusts the phase of the system clock according to the position of the detection pulse of the control channel Cch or the communication channel Tch to the extent that communication with the base station device 41 is not interrupted. Is.
Reference numeral 354 denotes a CPU, which periodically checks the reception state of the radio / timing control unit 32, and detects a detection pulse of the control channel Cch or the communication channel Tch (the radio of the system 1 equivalent to the PHS terminal according to the reception state. A signal synchronized with the timing of the base station device 41 extracted from the timing control unit 32) is used to establish synchronization,
Alternatively, the CPU has a function of setting whether synchronization is established using the output of the frequency dividing circuit 352.

FIG. 5 shows a mode in which synchronization is established by using the output of the frequency dividing circuit 352, that is, a synchronization establishing mode (self-running mode) performed by hardware control, or a control channel Cch or by a software control by the CPU 354. FIG. 7 is a mode transition diagram showing that any one of the synchronization establishment modes using the detection pulse of the communication channel Tch is switched according to the reception state of the wireless / timing control unit 32.

FIG. 6 shows the base station apparatus 4 between the radio / timing control section 32 and the radio / timing control sections 33 and 34 provided from the system 1 to the system N and the base station apparatus 41.
FIG. 1 is an explanatory diagram showing a frame configuration in wireless communication viewed from the first side. FIG. 1A shows one frame allocated to wireless communication between a wireless / timing control unit 32 of a system 1 and a base station device 41. 2B is a transmission slot per frame allocated to wireless communication between the wireless / timing control unit 33 of the system 2 and the base station device 41. FIG. FIG. 9 is an explanatory diagram showing a slot configuration of a reception slot.

Next, the operation will be described. The CPU 354 of the timing generation means 35 periodically checks the reception state of the radio / timing control unit 32, and in the reception state in which the detection pulse of the control channel Cch or the communication channel Tch cannot be detected, the frequency dividing circuit 352.
The timing generation means 35 is switched to the free-running mode in which the synchronization is established using the output of. Also, the control channel Cc
When h is received, the timing generation means 35 is switched to the synchronization establishment mode using the detection pulse. When the communication channel Tch is received, the timing generation means 3 is switched to the synchronization establishment mode using the detection pulse.
Switch 5 Then, the clock phase timing is finely adjusted according to the position of the detection pulse so that the communication with the base station device 41 is not disconnected. Note that this fine adjustment is periodically performed. Further, the fine adjustment of the clock phase timing according to the position of the detection pulse is performed by counting from the previous reception timing and adjusting by the count number.If it is smaller than the previous count value, the clock phase timing is finely delayed. If the count value is larger than the previous count value, the clock phase timing is finely adjusted. In this way, the timing generation means 35
Then, a signal (control channel Cch or communication channel T) corresponding to the radio synchronization clock of the radio / timing control unit 32 of the system 1 synchronized with the operation timing of the base station device 41.
based on the ch detection pulse), the operation timings of the wireless / timing control units 33 and 34 of the system 2 and thereafter are set to the base station device 4
A timing control signal for synchronizing with the operation timing of No. 1 is generated and output to the radio / timing control units 33 and 34. Then, the radio / timing control unit 3 of the system 2 and thereafter
Phases between the wireless / timing control unit 32 of the system 1 and the wireless / timing control units 33, 34 of the system 2 and thereafter are synchronized with the operation timing of the wireless / timing control unit 32 of the system 1. Prevent misalignment.

Between the radio / timing controller 32 of the system 1 and the base station device 41, one slot is left empty when assigning different frequencies, as in the slot configuration in the radio communication between the base station and the PHS terminal. For example, in FIG.
Information is transmitted and received through a communication channel and a control channel with the frequency and the assignment of 2 slots as shown in (a). This control channel is shared by the base station device 41, the radio / timing control unit 32 of the system 1 and the radio / timing control unit of the system 2 and thereafter. Between the base station device 41 and the radio / timing control unit 32 of the system 1, transmission and reception using the transmission slot TS1 to which the frequency f1 is assigned and the reception slot RS1 to which the frequency f1 is assigned, and the frequency f2 are assigned. Transmission and reception are performed using the transmission slot TS3 and the reception slot RS3 to which the frequency f2 is assigned.

Further, in the radio / timing control units 33 and 34 of the system 2 and later, only the communication channel Tch is assigned, and the radio / timing control units 33 and 34 of the system 2 and later are set to P.
It is equivalent to an HS base station, and because it has two synthesizers, it can switch channels to which different frequencies are assigned at high speed and can use 4 slots, that is, 4 channels, so different frequencies can be assigned. 6 (b) by continuously using the created slots.
As shown in, for example, transmission / reception using the transmission slot TS1 assigned the frequency f3 and the reception slot RS1 assigned the frequency f5 between the radio / timing control unit 33 of the system 2 and the base station device 41. , Frequency f
Transmission and reception using the transmission slot TS2 assigned 4 and the reception slot RS1 assigned the frequency f5, transmission and reception using the transmission slot TS2 assigned the frequency f4 and the reception slot RS2 assigned the frequency f6, and the frequency A transmission slot TS3 to which f5 is assigned and a reception slot R to which a frequency f7 is assigned
Transmission / reception using S3 and transmission / reception using only the communication channel Tch using the transmission slot TS4 to which the frequency f6 is assigned and the reception slot RS4 to which the frequency f8 is assigned are performed.

As described above, theoretically, it is possible to increase the capacity of the transmission rate by arranging the radio / timing control units 33 and 34 of the system 2 and thereafter in an infinite system in parallel.
The order of slot assignment is T in system 2.
S1 (RS1), TS2 (RS2), TS3 (RS
3), TS4 (RS4) are assigned in this order (in no particular order), then TS3 (RS3) of system 1 is assigned, and finally T of system 1 is assigned.
The S1 (RS1) (control channel Cch) is switched to the communication channel Tch. In addition, TS3 (RS3) and TS1 (RS1), TS4 (RS4) and TS2 (RS of the system 1
2) The (control channel Cch) may be replaced.
It depends on the slot in which the control channel from the base station is transmitted and received. If the control channel is TS1, the rest is TS
3, if the control channel is TS3, the rest is TS1, and if the control channel is TS2, the rest is TS4. In any case, the slot finally assigned to the control channel Cch of the system 1 is switched to the communication channel Tch.

As described above, according to the second embodiment, the operation timing of the radio / timing control units 33 and 34 of the system 2 and thereafter is synchronized with the radio / timing control unit 32 of the system 1 by the timing generation means 35. , Base station device 41
The communication channel Tch and the control channel Cch are used between the system and the radio / timing controller 32 of the system 1, and the system 2
Only the communication channel Tch is used as a trial with the subsequent radio / timing control unit, and the control channel Cch is continuously shared by the radio / timing control unit of system 1 and the radio / timing control unit of system 2 and thereafter. Wireless synchronization method for substantially expanding the number of transmission slots and the number of reception slots and providing a large number of slots when a communication system such as PHS is used to provide services by an integrated digital network such as ISDN Also, there is an effect that a device can be obtained and a service can be provided by an integrated digital network having a high transmission rate such as ISDN using a low speed communication service such as PHS.

Embodiment 3. FIG. 7 is a block diagram showing a high speed communication service terminal apparatus and a base station apparatus to which the wireless synchronization method of the third embodiment is applied. 7, parts that are the same as or correspond to those in FIG. 3 are assigned the same reference numerals and explanations thereof are omitted. In the figure, 51 is an IS using a radio / timing control unit equivalent to that used in a communication system such as PHS.
This is a terminal device (terminal device) for high-speed communication service when providing high-speed communication service by a comprehensive digital network such as DN, and is attached to, for example, a telephone pole. Reference numeral 53 is a radio / timing control unit of the system 2 for performing radio / timing control equivalent to that of the PHS base station, which is provided with two synthesizers and is capable of assigning continuous 4 slots at different frequencies. Reference numeral 54 denotes a radio / timing control unit of a system N that performs radio / timing control equivalent to that of a PHS base station. Like the radio / timing control unit 53, it has two synthesizer systems and four consecutive slots at different frequencies. Can be assigned.

Reference numeral 57 is a radio / timing control unit 53 of system 2.
Based on the control channel detection pulse output from the wireless / timing control unit 32 of the system 1, and then synchronized with the wireless / timing control unit 32 of the system 1, and then the wireless / timing control unit of the system 2 It is a synchronization control means for synchronizing the slot timing (communication channel timing) at 53 with the base station device 41 independently of the radio / timing control unit 32 of the system 1.

Reference numeral 58 is a system N radio / timing control unit 54.
Based on the control channel detection pulse output from the radio / timing control unit 32 of the system 1, and then synchronized with the radio / timing control unit 32 of the system 1, and then the radio / timing control unit of the system N. It is a synchronization control means for synchronizing the slot timing (communication channel timing) in 54 with the base station apparatus 41 independently of the radio / timing control section 32 of the system 1. 55 is a radio antenna of the system 2 radio / timing control unit 53, and 5
Reference numeral 6 denotes a wireless antenna of the wireless / timing control unit 54 of the system N.

FIG. 8 shows the base station apparatus 4 between the radio / timing control section 32 and the radio / timing control sections 53 and 54 provided in the systems 1 to N and the base station apparatus 41.
FIG. 1 is an explanatory diagram showing a frame configuration in wireless communication viewed from the first side. FIG. 1A shows one frame allocated to wireless communication between a wireless / timing control unit 32 of a system 1 and a base station device 41. 2B is an explanatory view showing the slot configuration of the transmission slot and the reception slot of FIG. 1B. The transmission slot per frame assigned to the wireless communication between the wireless / timing control unit 53 of the system 2 and the base station device 41 FIG. 9 is an explanatory diagram showing a slot configuration of a reception slot.

FIG. 9 shows the base station device 41 and the wireless system 1
FIG. 10 is a block diagram showing a configuration of a timing control unit 32 and a radio / timing control unit 53 of system 2 and a synchronization control means 57 of the radio / timing control unit 53 of system 2, which is the same as or equivalent to FIG. 7 in FIG. 9. Are denoted by the same reference numerals and description thereof will be omitted. In the figure, 62 is a first base station device, 63 is a radio antenna of the first base station device 62,
64 is a second base station device, 65 is a second base station device 64
Wireless antenna. In the third embodiment, the base station device 41 includes a first base station device 62 and a second base station device 64, and the high speed communication service terminal device 51 is provided.
The second base station device 64 is provided in addition to the first base station device 62 as a resource source of information transmitted and received between the first base station device 62 and the second base station device 64.
Reference numeral 71 is a wireless transmission / reception unit in the wireless / timing control unit 32 of the system 1, 72 is a timing control unit, and 73 is a synthesizer for switching channels. Reference numeral 81 is a wireless transmission / reception unit in a wireless / timing control unit 53 of a system 2 equivalent to a PHS base station having two systems of synthesizers, 82 is a timing control unit, 83 is a first synthesizer for switching channels, and 84 is a channel. Is a second synthesizer for switching between, and 85 is an oscillation circuit (free-running clock source).

Reference numeral 92 denotes an absolute timing signal generation section in the synchronization control means 57, which is the timing control section 72 of the system 1.
An absolute timing signal is output based on the detection pulse of the control channel Cch output from. This absolute timing signal indicates the frame timing (the timing of the beginning of the frame) in the radio / timing control unit 53 of the system 2
The radio / timing control unit 32 of the system 2 is matched with that of the radio / timing control unit 32.
Frame and radio / timing controller 32 of system 1
The phase matches that of the frame. Reference numeral 93 is a first PLL circuit, which outputs a demodulation clock synchronized with the second base station device 64 using the free-running clock output from the oscillation circuit 85. Reference numeral 94 denotes a free-running / demodulation clock switching unit that switches the free-running clock output from the oscillation circuit 85 and the demodulation clock based on the detection pulse of the communication channel Tch. Reference numeral 95 denotes a frequency division ratio switching unit, which is a timing control unit 82.
The frequency division ratio is switched in order to correct the phase shift based on the reception timing of the detection pulse of the communication channel Tch detected in (1). A second PLL circuit 96 adjusts the frame timing generated by the timing control unit 82 to change the reception timing of the communication channel Tch based on the frequency division ratio switched by the frequency division ratio switching unit 95. Is. Reference numeral 97 denotes the communication channel T based on the detection pulse of the communication channel Tch output from the timing control unit 82.
It is a communication channel reception position calculation unit that calculates the reception position of ch.

Next, the operation will be described. System 1 radio
The synchronization of the communication channel Tch of the timing control unit 32 is the same as that of a normal slave unit (terminal station), and is assigned for transmission / reception of wireless communication between the base station device 41 and the wireless / timing control unit 32 of the system 1. The slots and frequencies are, for example, as shown in FIG. 8A as in the above embodiments. Wireless / timing control units 53 and 54 for system 2 and later
The procedure for establishing synchronization is as follows. Radio of system 2
The procedure until the synchronization is established by the timing control unit 53 will be described. When the radio / timing control unit 32 of the system 1 receives the control channel Cch, the timing control unit 72 sends the control channel detection pulse to the absolute timing signal generation unit 92.
Output to. The absolute timing signal generation unit 92 outputs the absolute timing signal based on the control channel detection pulse to the timing control unit 8 of the wireless / timing control unit 53 of the system 2.
Output to 2. The timing control unit 82 determines the head of the frame based on the absolute timing signal, and the radio of the system 1 / the timing control unit 32 and the system 2
The phases of the frame timing with the timing control unit 53 match. In this state, the radio / timing control unit 53 of the system 2 is operating with the free-running clock, so it is necessary to constantly perform phase alignment with the radio / timing control unit 32 of the system 1.

Next, the radio / timing controller 53 of system 2
The synchronization of the communication channel Tch in will be described.
The radio / timing control unit 53 of the system 2 uses the free-running clock and synchronizes with the base station device 41 based on the demodulated clock output from the timing control unit 82. Then, when the wireless / timing control unit 53 of the system 2 starts to receive the communication channel Tch with the base station device 41, the demodulated clock output from the timing control unit 82 becomes stable. On the other hand, the detection pulse of the communication channel Tch is sent from the timing control unit 82 to the communication channel reception position calculation unit 97 and self-running /
It is output to the demodulation clock switching unit 94. The free-running / demodulation clock switching unit 94 switches the free-running clock to the demodulation clock based on the detection pulse of the communication channel Tch,
The free-running clock drive up to that point is switched to the demodulation clock drive. At this point, the radio / timing controller 5 of the system 2
3 is independent of the radio / timing controller 32 of system 1,
The synchronization state with the base station device 41 is entered. This eliminates the need for complementarity, which was used when the free-running clock was driven, and prevents data errors.

Next, the radio / timing controller 53 of system 2
The maintenance of synchronization of the communication channel Tch will be described. The communication channel reception position calculation unit 97 calculates the communication channel reception position based on the detection pulse in the communication channel Tch output from the timing control unit 82, and detects and outputs the deviation from the timing to be originally received. The frequency division ratio switching unit 95 performs switching correction of the frequency division ratio of the demodulation clock switched by the free-running / demodulation clock switching unit 94 based on the output of the communication channel reception position calculation unit 97, and the second PLL. By controlling the circuit and adjusting the frame timing generated by the timing control unit 82 to change the reception timing of the communication channel Tch,
Synchronize the reception timing of ch. in this case,
When the reception timing of the communication channel Tch is earlier than it should be, the frequency division ratio is increased and the frame timing generated by the timing control unit 82 is lengthened to delay the reception timing of the communication channel Tch. When the reception timing of the communication channel Tch is later than the original,
The frequency division ratio is reduced to accelerate the reception timing of the communication channel Tch. Since the phase of the demodulated clock is discontinuous in each slot in the conventional method, only the clock of one reference slot is used, and the phase is held in other cases. As a result, the phase between slots becomes continuous.

In the third embodiment, the radio / timing controller 53 of the system 2 first synchronizes the frame timing with the radio / timing controller 32 of the system 1, but
The subsequent synchronization of the reception timing of the communication channel Tch is synchronized with the base station device 41 independently of the radio / timing controller 32 of the system 1. That is, the radio / timing control unit 32 of system 1 and the radio / timing control unit 53 of system 2 are both synchronized with the base station device 41, but the radio / timing control unit 53 of system 2 is the radio / timing system 1 It is synchronized with the base station device 41 independently of the control unit 32. The frequency assigned to the wireless communication between the wireless / timing control unit 53 of the system 2 and the base station apparatus 41 is limited to the same frequency in all four slots. Further, all the communication channels Tch assigned to the wireless / timing control unit 53 of the system 2 are connected to the transceiver of the same base station device. Therefore, in the third embodiment also, although there is the above-mentioned restriction, continuous slot allocation is enabled and I
A wireless synchronization method and apparatus that realizes substantial expansion of the number of transmission slots and the number of reception slots and increase of the number of slots when providing a service by an integrated digital network such as SDN are obtained, and a low-speed communication service such as PHS is used. I
There is an effect that a service can be provided by an integrated digital network having a high transmission rate such as SDN.

[0041]

As described above, according to the present invention, the terminal
Of the multiple radio / timing control units that make up the device,
Arbitrary radio and timing control synchronized with base station equipment
Other than configuring the terminal device by detecting the operation timing of the unit
The operation timing of the wireless / timing control unit of
To match the operation timing of the line / timing controller
, The slot transmitted from the base station device
When each of the timing control units receives the
High-speed communication service network
When the multiplexed slot is received from the communication service network,
Separate the multiplexed slots to
Slots separated in parallel from the aiming controller are used as base stations.
Since it is configured to send to the device,
It is possible to prevent the phase shift between the
In addition, there is an effect that the slots used in the wireless communication between the terminal device and the base station device can be substantially expanded and the number of slots can be increased.

According to the present invention, the detection signal of the control slot or the communication slot is extracted from the radio / timing controller, which is a component of the terminal device synchronized with the base station device,
The radio / timing control unit is synchronized with the radio / timing control unit by the detection signal obtained by extracting the frame timing of the other radio / timing control unit of the terminal device, and the communication slot of the other radio / timing control unit is independent of the radio / timing control unit. Each radio that synchronizes with the base station device and synchronizes with the base station device.
The slots received by the timing control unit are multiplexed and output to the high-speed communication service network, while the slots multiplexed and sent from the high-speed communication service network are separated and each radio / timing control unit parallelizes the bases. Since the data is transmitted to the station device, there is an effect that the slot whose assignment is limited in the wireless communication between the base station device and the terminal device can be substantially expanded to have a large number of slots.

According to the present invention, a plurality of radio / timers
Any radio that is synchronized with the base station device in the control unit
・ Detects the operation timing of the timing control unit and
The operation timing of the wireless / timing control unit can be set to any wireless
・ Tie that matches the operation timing of the timing control unit
And a slot transmitted from the base station device.
Is received by each of the wireless and timing control units.
And those slots are multiplexed to create a high-speed communication service network.
While being transmitted from the high-speed communication service network
When it receives a slot, it splits the multiplexed slot.
Data to be separated and output to multiple wireless / timing control units
Since it is configured to include a demultiplexer, it is possible to
・ The phase shift between the timing control units can be prevented.
In addition, there is an effect that the slots used in wireless communication with the base station device can be substantially expanded and the number of slots can be increased.

According to the present invention, a control slot or a communication slot is detected from a plurality of radio / timing control sections including a radio / timing control section synchronized with the base station apparatus and the radio / timing control section synchronized with the base station apparatus. Other radio / timing control units are synchronized with the radio / timing control units by the detection signals that extract the signals and extract the frame timings of radio / timing control units other than the radio / timing control units that synchronize with the base station device. Regarding the communication slots of the radio / timing control unit, a synchronization control unit that synchronizes with the base station device independently of the radio / timing control unit and a slot received in parallel from the base station device by a plurality of radio / timing control units are provided in the high-speed communication service network. While multiplexing and outputting to multiple radios, the slots multiplexed and sent from the high-speed communication service network are separated. Since the data demultiplexing unit for outputting to the aiming control unit is provided, there is an effect that the slot for which the assignment used in the wireless communication with the base station device is limited can be substantially expanded to be multi-slotted. is there.

[Brief description of drawings]

FIG. 1 is a block diagram showing a high speed communication service terminal apparatus and a base station apparatus to which a wireless synchronization method according to a first embodiment of the present invention is applied.

FIG. 2 is a frame in wireless communication seen from the base station apparatus side between the wireless / timing control unit and the base station apparatus of the high-speed communication service terminal apparatus to which the wireless synchronization method according to the first embodiment of the present invention is applied. It is explanatory drawing which shows a structure.

FIG. 3 is a block diagram showing a high speed communication service terminal apparatus and a base station apparatus to which the wireless synchronization method according to the second embodiment of the present invention is applied.

FIG. 4 is a functional block diagram showing a timing generation unit of a high-speed communication service terminal device to which a wireless synchronization method according to a second embodiment of the present invention is applied together with a wireless / timing control unit.

FIG. 5 shows that in the wireless synchronization method according to the second embodiment of the present invention, either the free-running mode or the synchronization establishment mode using the detection pulse of the control channel Cch and the communication channel Tch can be switched according to the reception state. It is a mode transition diagram shown.

FIG. 6 is a frame in wireless communication seen from the base station apparatus side between the wireless / timing control unit and the base station apparatus of the high-speed communication service terminal apparatus to which the wireless synchronization method according to the second embodiment of the present invention is applied. It is explanatory drawing which shows a structure.

FIG. 7 is a block diagram showing a terminal device for high-speed communication service and a base station device to which the wireless synchronization method according to the third embodiment of the present invention is applied.

FIG. 8 is a frame in wireless communication seen from the base station apparatus side between the wireless / timing control unit and the base station apparatus of the high-speed communication service terminal apparatus to which the wireless synchronization method according to the third embodiment of the present invention is applied. It is explanatory drawing which shows a structure.

FIG. 9 is a block diagram showing a configuration of a synchronization control means in a high-speed communication service terminal device to which the wireless synchronization method according to the third embodiment of the present invention is applied.

FIG. 10: PHS base station and PHS of conventional PHS system
It is a block diagram which shows the structure of a terminal.

FIG. 11 is an explanatory diagram showing an example of assignments of transmission slots and reception slots and frequencies for transmitting and receiving information between a PHS base station and a PHS terminal in a conventional PHS system.

[Explanation of symbols]

1,31,51 High-speed communication service terminal device (terminal device), 2,3,4,5,32 Radio / timing control unit equivalent to PHS terminal, 11 Integrated digital network (high-speed communication service network) 21,41 Base station device, 23 Public network, 33, 34, 53, 54 Radio / timing control unit equivalent to PHS base station, 35 Timing generation means, 5
7,58 Synchronous control means.

Continuation of the front page (56) References JP 10-42359 (JP, A) JP 11-177482 (JP, A) JP 7-67171 (JP, A) (58) Fields investigated (Int .Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (4)

(57) [Claims] 1. A wireless synchronization method in wireless communication between a base station apparatus and a terminal apparatus, comprising: a plurality of wireless / timing control units constituting the terminal apparatus.
Of the wireless stations that are synchronized with the base station device.
The operation timing of the imming control unit is detected, and the terminal is
Operational timing of other radio and timing control units that make up the device
The timing of the operation of the optional radio / timing controller.
While the slot transmitted from the base station device is matched with the
When the line / timing control unit receives each,
The slot is multiplexed and transmitted to the high speed communication service network.
Receives multiplexed slots from high-speed communication service network
Then, the multiplexed slot is separated and the
Slots separated in parallel from a number of radio and timing controls
Wireless synchronization method for transmitting a packet to the base station device . 2. A wireless synchronization method in wireless communication between a base station apparatus and a terminal apparatus, comprising: a control slot or communication from a wireless / timing control unit which is a component of the terminal apparatus synchronized with the base station apparatus. A slot detection signal is extracted, the frame timing of the other radio / timing control unit of the terminal device is synchronized with the radio / timing control unit by the extracted detection signal, and a communication slot of the other radio / timing control unit is provided. With respect to, the radio / timing control unit is synchronized with the base station device independently, and the slots received by each of the radio / timing control units synchronized with the base station device are multiplexed to a high-speed communication service network. While outputting, the slots multiplexed and sent from the high-speed communication service network are separated to separate each radio / timing. Radio synchronization method for transmitting from the control unit to the base station device in parallel, respectively. 3. A terminal device that wirelessly communicates with a base station device , comprising a plurality of wireless devices that transmit and receive slots to and from the base station device.
A timing control unit, and the base station among the plurality of radio / timing control units
The operation of any radio / timing controller synchronized with the device
Other wireless / timing control unit that detects the operation timing
The operation timing of the wireless / timing control unit
Timing generating means for matching the operation timing of the base station apparatus with the slot generated by the base station apparatus.
When the line / timing control unit receives each,
One that multiplexes slots and transmits to high-speed communication service network
, The slots multiplexed from the high speed communication service network
, Separates its multiplexed slot and
Data multiplex output to multiple radio / timing control units
A terminal device, comprising: a separation unit . 4. A terminal device that wirelessly communicates with a base station device, comprising: a plurality of radio / timing control units including a radio / timing control unit that synchronizes with the base station device; and a radio that synchronizes with the base station device.・ Extract the detection signal of the control slot or communication slot from the timing control unit,
The frame timing of a radio / timing control unit other than the radio / timing control unit that synchronizes with the base station device is synchronized with the radio / timing control unit by the extracted detection signal. Regarding the communication slot, a synchronization control unit that synchronizes with the base station device independently of the radio / timing control unit, and a slot that the plurality of radio / timing control units receive in parallel from the base station device at high speed. While multiplexed and output to the communication service network, the slots multiplexed and sent from the high-speed communication service network are separated and the plurality of wireless
A terminal device, comprising: a data demultiplexing unit for outputting to a timing control unit.