KR20080058026A - Time synchronization apparatus and method in a wireless communication system - Google Patents

Abstract

An apparatus and a method for executing time synchronization in wireless communication systems are provided to execute precisely synchronization among plural base stations by broadcasting synchronization signals using a wireless interval. An apparatus for executing time synchronization includes first and second synchronization units(411,412), and a mode determining unit(420). The first synchronization unit transmits a first synchronization signal including first hop information. The second synchronization unit executes a multi-frame synchronization according to a reception time of a second synchronization signal and second hop information in response to the receiving of the second synchronization signal including the second hop information. The mode determining unit determines whether the apparatus is set in a master or slave mode.

Description

Time synchronization device and method of wireless communication system {TIME SYNCHRONIZATION APPARATUS AND METHOD IN A WIRELESS COMMUNICATION SYSTEM}

1 is a conceptual diagram of an Internet Protocol (IP) -based Digital Enhanced Cordless Telephone (DECT) system according to an embodiment of the present invention.

2 is a conceptual diagram of a multi-frame used in the DECT protocol according to an embodiment of the present invention.

3 is a conceptual diagram illustrating a synchronization procedure between a plurality of base stations according to an embodiment of the present invention.

4 is a block diagram of a base station according to an embodiment of the present invention.

5 is a flowchart illustrating a time synchronization method in a DECT system according to an embodiment of the present invention.

The present invention relates to an apparatus and method for time synchronization in a wireless communication system, and more particularly, to a method and apparatus for performing time synchronization between base stations in real time through a wireless section.

The DECT (Digital Enhanced Cordless Telephone) system is a wireless communication system that is standardized by the European Telecommunication Standards Institute (ETSI), and is characterized by the addition of handover and automatic roaming functions by developing a cordless telephone (CT) -2. A general DECT system includes a terminal, a plurality of base stations that provide a wireless access service to the terminals, and a private branch exchange that is connected to the plurality of base stations to perform switching operations therebetween and connect them to a public telephone network. Each of these base stations maintains an independent reference timer. When a terminal is connected to one base station and performs wireless communication and enters a zone of another base station, a handover procedure of disconnecting an existing base station and establishing a connection with a new base station in charge of the entered zone Will be performed. At this time, when the timers maintained by both base stations are not synchronized with each other, a problem that the call being performed by the terminal is momentarily disconnected is issued. In particular, in order to prevent such disconnection, the time difference between timers of both base stations should be within 4 μsec.

In the conventional case, a wireless controller located in a private branch exchange is connected to each base station via a wire (E1 Framer) in a one-to-one manner, and a timer is periodically synchronized between the base stations by periodically transmitting a synchronization signal from the private branch exchange to each base station. Recently, however, an IP-based private branch exchange system in which a private branch exchange and a plurality of base stations are connected to a LAN, for example, Ethernet, has been used in a DECT system. However, when the IP-based private branch exchange transmits the synchronization signal to each base station via Ethernet, unlike the one-to-one connection through the E1 Framer, the synchronization signal is not immediately transmitted to each base station in real time due to the delay characteristics of the Ethernet. Each time arrives at a different time. Accordingly, there is a problem in that synchronization between each base station cannot be performed accurately and effectively, and call disconnection occurs when the terminal is handed off.

Accordingly, an object of the present invention is to provide a method and apparatus for precisely and effectively performing synchronization between base stations in a DECT system using an IP-based private branch exchange.

According to one embodiment, a time synchronization apparatus at a base station for transmitting and receiving multiple frames including a series of frames is provided. The apparatus may further include a first synchronization unit for transmitting a first synchronization signal including first hop information, and a time when the second synchronization signal is received in response to receiving a second synchronization signal including second hop information. And a second synchronizer for performing multi-frame synchronization according to the second hop information, and a mode determiner configured to determine whether the time synchronizer is set to a master or slave mode.

According to another embodiment, a time synchronization method at a base station for transmitting and receiving multiple frames including a series of frames is provided. The method includes receiving a first synchronization signal comprising first hop information, and performing multi-frame synchronization according to the time at which the first synchronization signal was received and the first hop information.

1 is a conceptual diagram of an Internet Protocol (IP) -based Digital Enhanced Cordless Telephone (DECT) system according to an embodiment of the present invention. Referring to FIG. 1, the DECT system 100 according to an embodiment of the present invention includes a terminal 110 and a plurality of base stations (BSs) 120a-120g providing a wireless access service to the terminal 110. The Ethernet 130 connects the plurality of base stations 120a-120g to each other and the plurality of base stations 120a-120g through the Ethernet 130 to perform a switching operation between the plurality of base stations 120a-120g. IP that provides connectivity to a plurality of base stations (120a-120g) with external networks (e.g., Public Switched Telephone Network (PSTN) (not shown) and Integrated Services Digital Network (ISDN) (not shown) A private branch exchange (PBX) 140. In one embodiment of the present invention, for convenience of description, the DECT system 100 includes one terminal 110. However, in another embodiment of the present invention, the DECT system may include a plurality of terminals. Of course.

The terminal 110 establishes a wireless connection with one of the plurality of base stations 120a-120g, for example, the first base station 120a using the DECT protocol, and thus, the other base stations 120b-120g and the private branch exchanger 140. Connected with When the terminal 110 moves from the zone of the first base station 120a to the other base stations 120b-120g, for example, the zone of the second base station 120b as the terminal 110 moves its position, the terminal 110 moves to the first zone 120b. A handoff procedure or a handover procedure is performed to disconnect the radio connection with the first base station 120a and establish a new radio connection with the second base station 120b. At this time, when the time difference between the reference timers maintained by the first and second base stations 120a and b, respectively, is 4 μsec or more (that is, when they are not sufficiently synchronized), the terminal 110 determines the first base station 120a. ) Is disconnected and the call is momentarily disconnected as the second base station 120b is connected. The plurality of base stations 120a-120g not only provide a wireless access service to the terminal 110 using the DECT protocol, but also wirelessly generate a synchronization signal using the DECT protocol in order to prevent a disconnection during handover. Broadcast between base stations 120a-120g to synchronize the reference timers with each other.

2 is a conceptual diagram of a multi-frame used in the DECT protocol according to an embodiment of the present invention. Referring to FIG. 2, the DECT protocol is a frame-based protocol of TDM (Time Division Muliplex) method. The multi-frame according to an embodiment of the present invention is a 160msec section, each consisting of a series of 16 frames consisting of a 10msec section. The frame is divided into 24 slots of equal length. The terminal 110 and the plurality of base stations 120a-120g transmit and receive signals in each slot section to perform wireless communication. Since the length of each frame and slot is constant, when the terminal 110 and the plurality of base stations 120a-120g set only the starting point of the multi-frame (that is, the starting point of the first slot of the first frame) to each other equally, It is possible to achieve synchronization with each other. The terminal 110 and the plurality of base stations 120a-120g set a reference timer according to the start point of the multi-frame to achieve synchronization with each other.

3 is a conceptual diagram illustrating a synchronization procedure between a plurality of base stations according to an embodiment of the present invention. Referring to FIG. 3, one of a plurality of base stations 120a-120g, for example, a first base station 120a according to an embodiment of the present invention is preset as a master base station and the other is set to an idle level as slave base stations. It is. When the first base station 120a is set as the master base station, the first base station 120a broadcasts the first synchronization signal including the first hop information to a predetermined output in the first slot section of the first frame of the multi-frame. As shown in FIG. 3, the first synchronization signal is received only by base stations located within a predetermined distance from the first base station 120a, for example, the second to fourth base stations 120b-120d. The reception distance of the first synchronization signal is determined by the output of the first base station 120a. The first hop information included in the first synchronization signal is information indicating a hop number or distance between the master base station 120a that generated the first synchronization signal and the base station that receives the first synchronization signal. In the case of the first hop information generated in 120a), it may be set to indicate 0. Here, a value obtained by multiplying the number of hops by the frame time is defined as a hop delay time described later.

Each of the second to fourth base stations 120b to 120d that have received the first synchronization signal receives the first synchronization signal, and the first synchronization signal is included in the first synchronization signal when it is set to an idle level. Set your own level according to the hop information. That is, when the first hop information indicates the number of 0 hops, each of the second to fourth base stations 120b to 120d sets itself to level 1. Each of the second to fourth base stations 120b to 120d calculates a first hop delay time according to the first hop information, and before the calculated first hop delay time from the time when the first synchronization signal is received. Set the time of to the time at which the multi-frame starts. Since the first hop information indicates 0, the first hop delay time is calculated as 0x10msec = 0. Each of the second to fourth base stations 120b to 120d determines the time at which the first synchronization signal is received as a start point of a multi frame, that is, a start point of a first slot of a first frame, and sets its own reference timer accordingly. do. According to the operation described above, each of the second to fourth base stations 120b to 120d is synchronized with the first base station 120a. Each of the second to fourth base stations 120b to 120d broadcasts a second synchronization signal including second hop information to a predetermined output in a first slot section of a second frame of the multi-frame. That is, after receiving the first synchronization signal, the second synchronization signal is broadcasted to a predetermined output at a time elapsed after 10 msec. The second hop information indicates hop number or distance between the master base station 120a and the base station receiving the second synchronization signal and indicates a hop number greater than the first hop information, and in the case of the second hop information. It can be set to indicate one. The second synchronization signal is received only by base stations located within a predetermined distance from each of the second to fourth base stations 120b-120d. The second synchronization signal broadcast by the fourth base station 120d is received by the first and fifth base stations 120e as shown in FIG. 3.

The first base station 120a receiving the second synchronization signal discards the received second synchronization signal since it is set as a master base station rather than an idle level of a slave base station. Meanwhile, when the second base station 120e receives the second synchronization signal, the fifth base station 120e sets its level according to the second hop information included in the second synchronization signal when it is set to the idle level. That is, when the second hop information indicates the number of hops, the fifth base station 120e sets itself to level 2. Then, the fifth base station 120e calculates a second hop delay time according to the second hop information. Since the second hop information indicates 1, the second hop delay time is calculated as 1x10 msec = 10 msec. Each of the second to fourth base stations 120b to 120d determines the time before the calculated hop delay time (10 msec) from the time when the second synchronization signal is received as the time at which the multi-frame starts. Set your own reference timer. According to the operation described above, the fifth base station 120e is synchronized with the first base station 120a.

Thereafter, the fifth base station 120e broadcasts the third synchronization signal including the third hop information to the predetermined output in the first slot section of the third frame of the multi-frame. That is, after receiving the second synchronization signal, the third synchronization signal is broadcast at a time elapsed after 10 msec. The third hop information indicates hop number or distance between the master base station 120a and the base station receiving the third synchronization signal and indicates a hop number greater than the second hop information, and in the case of the third hop information. It can be set to indicate two. The third synchronization signal is received only by the base stations located within a predetermined distance from the fifth base station 120e. The third synchronization signal broadcast by the fifth base station 120e is received by the fourth, sixth and seventh base stations 120d, 120f, and 120g as shown in FIG.

The fourth base station 120d, which has received the third synchronization signal, discards the received third synchronization signal since it is set to the first level instead of the idle level of the slave base station. Meanwhile, each of the sixth and seventh base stations 120f and 120g receiving the third synchronization signal has its own level according to the third hop information included in the third synchronization signal when it is set to an idle level. Set, the start point of the multi-frame to the same as the first base station (120a) performs a synchronization operation, and broadcasts a fourth synchronization signal including the fourth hop information through the first slot interval of the fourth frame do. As such, the synchronization operation initiated by the first base station 120a, which is the master base station, is sequentially propagated to the other base stations 120b-120g of the DECT system 100 so that the other base stations 120b-120g are the first base station 120a. ) And the reference timer are synchronized.

In summary, the master base station broadcasts a synchronization signal to a predetermined output in the first slot of the first frame of the multi-frame to inform the base stations within a predetermined distance from the master base station of the start of the multi-frame. Thereafter, the base stations receiving the synchronization signal also broadcast the synchronization signal to a predetermined output in the first slot of the next frame of the frame in which the synchronization signal is received. The base stations receiving the synchronization signal may know that the time at which the synchronization signal is received is the start point of the frame, and the number of frames, i.e., the number of hops, is determined by the hop information included in the received synchronization signal. Accordingly, each base station can know the starting point of the multi-frame, thereby setting a reference timer to achieve synchronization with the master base station. The master base station may update a reference timer of each base station by broadcasting a synchronization signal at the start of every multi-frame. Accordingly, the difference in time between the reference timers between the plurality of base stations 120a-120g is maintained within 4 μsec, so that even when the terminal 110 hands off between the plurality of base stations 120a-120g, the call can be made smoothly without interruption. You can continue. In addition, the private branch exchange 140 is a wireless transmission capable of real-time transmission between the base stations (120a-120g), rather than the method of transmitting the synchronization information to each base station (120a-120g) through the Ethernet 130 is not guaranteed real-time transmission By adopting a method of broadcasting the synchronization signal through the interval it is possible to perform a more precise synchronization between the plurality of base stations (120a-120g).

4 is a block diagram of a base station according to an embodiment of the present invention. 4, the base station 400 according to an embodiment of the present invention DECT signals transmitted and received through the RF unit 410, RF unit 120 performing wireless communication with the terminal 110 and other base stations The Ethernet unit 430 is connected to the DECT unit 420 and the Ethernet 130 and performs wired communication with the other base station and the private branch exchange 140, which processes in a predetermined manner according to the protocol and performs synchronization with other base stations. ).

The RF unit 410 is a second RF unit 412 for transmitting and receiving a synchronization signal associated with the synchronization operation of the first RF unit 411 and the base station 400 for transmitting and receiving a wireless signal related to the general wireless communication service from the terminal 110. It includes. The first RF unit 411 receives a general radio communication service related radio signal belonging to a high frequency band through ANT1, converts the radio signal into a base band signal, and converts a general radio communication service related signal belonging to the base band from the DECT unit 420. It receives the input and converts it into a radio signal of high frequency band and transmits it to the terminal 110. The second RF unit 412 receives the synchronization signal belonging to the high frequency band through ANT2 and converts it into the baseband synchronization signal, and receives the synchronization signal belonging to the base band from the DECT unit 420 to the synchronization signal of the high frequency band. It converts and transmits it to a predetermined output.

The DECT unit 420 receives a signal from the RF unit 410 or the Ethernet unit 430 and performs a predetermined process as described in the ETSI EN 300 175 recommendation to perform the Ethernet unit 410 or the RF unit 420, respectively. Will output The DECT unit 420 sets and maintains a reference timer indicating a start point of the multi-frame in order to process a signal according to the multi-frame structure shown in FIG. 2. When the base station 400 is set as a master base station, the DECT unit 420 may apply a first synchronization signal including first hop information having a hop number of zero to a start point (first slot of the first frame) of each multi-frame. 2 broadcast through the RF unit (412).

When the base station 400 is configured as a slave base station instead of the master base station, the DECT unit 420 receives the second synchronization signal including the second hop information from another base station, and sets the base station 400 to an idle level. Judge whether it is. If the determination result is not set to the idle level, the DECT unit 420 determines the hop number and the second hop information indicated by the delay level of the base station 400 whether to perform multi-frame synchronization according to the second synchronization signal. Decide accordingly. For example, the DECT unit 420 performs the multi-frame synchronization only when the delay level of the base station 400 and the number of hops indicated by the second hop information are the same.

On the other hand, when the determination result is set to the idle level, the DECT unit 420 sets the delay level of the base station 400 according to the second hop information, the time when the second synchronization signal is received and the second Multi-frame synchronization is performed according to the hop information. That is, the DECT unit 420 calculates a hop delay time according to the number of hops indicated by the second hop information, and multiplies the time before the calculated hop delay time from the time when the second synchronization signal is received. Set to the time when it starts. After completing the multi-frame synchronization, the DECT unit 420 generates a third synchronization signal including the third hop information and broadcasts it through the second RF unit 142. The third hop information indicates a larger hop number than the second hop information.

5 is a flowchart illustrating a time synchronization method of a DECT system according to an embodiment of the present invention. 5, the DECT unit 420 of the base station 400 according to an embodiment of the present invention determines whether the base station 400 is set as a master base station (S500). When the determination result in step S500 is set to the master base station, the DECT unit 420 generates a first synchronization signal including first hop information (S505), and the generated first synchronization signal is a starting point of the multi-frame, that is, In the first slot section of the first frame, the broadcast is broadcast through the second RF unit 412 (S510). The first hop information indicates the hop number 0.

On the other hand, if the determination result of step S500 is not set as the master base station (ie, set as the slave base station), the DECT unit 420 is waiting for the second hop information through the second RF unit 412. In operation S515, a second synchronization signal is received. Thereafter, the DECT unit 420 determines whether the base station 400 is set to an idle level (S520). When the base station 400 determines that the idle level is not set in step S520, the DECT unit 420 determines the number of hops indicated by the delay level of the base station 400 currently set by the second hop information. For example, in the case of the first level, it is determined whether the number of hops is equal to 1) (S525). In step S525, if the number of hops indicated by the second hop information is not the same as the number of hops indicated by the delay level of the base station 400, the procedure ends.

On the other hand, if the base station 400 is set to the idle level as a result of step S520, or if the number of hops indicated by the second hop information is the same as the number of hops indicated by the delay level of the base station 400, the DECT unit 420 sets the base station 400 to a delay level corresponding to the number of hops indicated by the second hop information (S530). The DECT unit 420 calculates a hop delay time according to the second hop information (S535). For example, if the number of hops indicated by the second hop information is 2 and the length of each frame is 10 msec, the hop delay time is 2x10 msec = 20 msec. The DECT unit 420 sets the start time of the multi-frame according to the time when the second synchronization signal is received and the calculated hop delay time (S540). That is, the time before the calculated hop delay time is set as the time at which the multi-frame starts based on the time when the second synchronization signal is received.

In step S540, the DECT unit 420, which finishes synchronization by setting the start time of the multi-frame, generates a third synchronization signal including third hop information (S545). The third hop information has a hop number larger than the hop number of the second hop information. In step S550, the DECT unit 420 broadcasts the third synchronization signal to the first slot of the frame following the frame in which the second synchronization signal is received (S550) and ends the procedure.

Although the present invention has been described with reference to the DECT system, the present invention can be applied to those skilled in the art in other frame-based wireless communication systems that perform wireless communication using TDM frames. Investigations used in describing one embodiment of the present invention, first, second and third, etc. are used to distinguish different configurations in the order described for convenience of description and do not have a special meaning in themselves. Investigations used in the components of the present specification, first, second and third, etc. do not necessarily correspond to the investigation used in the components of the claims.

In the above described the present invention with reference to the embodiments shown in the drawings for clarity, but this is merely exemplary, those skilled in the art that various modifications and equivalent other embodiments are possible from this. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the appended claims.

According to the above embodiments, it is possible to provide a method and apparatus for precisely and effectively performing synchronization between base stations in a DECT system using an IP-based private branch exchange.

Further, according to the embodiments, there is an effect that can provide a method and apparatus for preventing a call disconnection phenomenon in the handover of the terminal in the DECT system using the IP-based private branch exchange.

Claims (11)

A time synchronization device in a base station for transmitting and receiving a multi-frame including a series of frames, A first synchronizer for transmitting a first synchronization signal including first hop information, A second synchronizer for performing multi-frame synchronization according to a time when the second synchronization signal is received and the second hop information in response to receiving the second synchronization signal including second hop information, and Mode determination unit for determining whether the time synchronization device is set to the master or slave mode Comprising a time synchronization device. The method of claim 1, When the time synchronization device is set to the master mode, the first synchronization unit broadcasts the first synchronization signal through a frame specified in a predetermined order among the multi-frames, And the second synchronizer discards the second synchronization signal and does not perform the multi-frame synchronization. The method of claim 1, The mode determiner determines whether the time synchronizer is set to an idle level or a delay level when the time synchronizer is set to a slave mode. When the time synchronization device is set to the idle level, the first synchronizer indicates the number of hops greater than the first hop information-the first hop information in response to receiving the second synchronization signal. -Generate and broadcast the first synchronization signal comprising a. The method of claim 3, The mode determining unit compares the number of hops indicated by the delay level and the number of second hops when the time synchronization device is set to a delay level. The first synchronizer is the first hop information in response to receiving the second synchronization signal when the number of hops indicated by the delay level and the number of second hops are the same, wherein the first hop information is a hop larger than the second hop information. Indicating a number-generating and broadcasting the first synchronization signal comprising: a. The method of claim 4, wherein The first synchronizer does not generate the first synchronization signal when the number of hops indicated by the delay level and the number of second hops are different. And the second synchronization unit discards the second synchronization signal and does not perform the multi-frame synchronization when the hop number indicated by the delay level and the second hop number are different. The method according to claim 1, wherein The base station is a base station of a digital enhanced cordless telephone (DECT) system, and comprises a first RF unit for transmitting and receiving a DECT voice signal and a second RF unit for transmitting and receiving a DECT synchronization signal. A time synchronization method in a base station for transmitting and receiving multiple frames including a series of frames, Receiving a first synchronization signal comprising first hop information, And performing multi-frame synchronization according to the time at which the first synchronization signal is received and the first hop information. The method of claim 7, wherein performing the multi-frame synchronization Calculating a first hop delay time according to the first hop information; And Setting a time before the calculated hop delay time from a time when the first synchronization signal is received to a time at which the multi-frame starts. Including, time synchronization method. The method of claim 8, Generating a second synchronization signal including second hop information indicating a hop number greater than the first hop information; And broadcasting the generated second synchronization signal in a frame subsequent to the frame receiving the first synchronization signal. 10. The method of claim 9, wherein generating the second synchronization signal Determining whether the base station is set to a master mode or a slave mode; When the base station is set to a slave mode, determining whether the base station is set to an idle level or a delay level; And Generating the second synchronization signal when the base station is set to an idle level. The method of claim 10, Comparing the number of hops indicated by the delay level with the number of first hops when the base station is set to a delay level; And And generating the second synchronization signal if the delay level is equal to the hop number indicated and the first hop number.

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