RU2414063C2 - Apparatus and method of supporting relay service in multi-link relay broadband wireless access communication system - Google Patents

Abstract

FIELD: information technology. ^ SUBSTANCE: apparatus has at least a subframe for the base station (BS)- mobile station (MS) communication line, a subsframe for the primary relay station (RS)-MS communication line or a subframe for the BS- secondary RS communication line, which are formed in the first period of the subframe, and at least a subframe for the RS-primary RS communication line, a subframe for the RS-RS communication line or a subframe for the RS-MS communication line, which are formed in the second period of the subframe. ^ EFFECT: eliminating noise from neighbouring stations. ^ 31 cl, 21 dwg

Description

FIELD OF THE INVENTION

The present invention, in General, relates to a multi-link relay communication system with broadband wireless access (BWA) and, in particular, to a device and method for providing synchronization channels for mobile stations (MS) and relay stations (RS) and eliminating interference of neighboring stations between the service direct communication and relay service in a multi-link relay communication system with BWA.

BACKGROUND

One of the most critical requirements for deploying a 4th generation (4G) communication system should be the construction of a self-forming wireless network. A self-forming wireless network refers to a wireless network configured to provide mobile communications services in a stand-alone or distributed manner without control from a central system. For a 4G communication system, cells with a very small radius are defined in order to enable high-speed communication and accommodate a large number of requests. Therefore, the traditional centralized communication network system is not viable here. Rather, a wireless communication network should be built that works under distributed control and actively copes with environmental changes, such as the addition of new base stations (BS). As a result, a 4G communication system requires a self-forming wireless network.

For the actual deployment of a self-forming wireless network, the methods used for a narrow application network must be implemented in a wireless access communication system. Such a large example is a multi-link relay communication system with a BWA, configured to use a multi-link relay circuit used for a narrow application network in a network with a BWA with fixed BSs.

In general, since BSs and MSs communicate with each other through a direct link, a highly reliable radio link can easily be established between them in the BWA communication system. However, since the BSs are fixed, the wireless network structure is inflexible, making it difficult to provide efficient service to a radio environment experiencing fluctuating traffic distribution and a large change in the number of calls required.

The aforementioned disadvantage can be overcome with the help of relay service, which transmits data on multiple links through many neighboring MS or neighboring RS. The use of a multi-link relay circuit facilitates a quick change in the structure of the network, adaptive to environmental changes, and makes the overall operation of the wireless network efficient. Also, the radio channel with the best channel condition can be provided by the MS, establishing an RS between the BS and the MS and, thus, organizing a multi-link relay path through the RS. Thus, high-speed data channels can be provided by the MS in shading zones or in areas where communications with the BS are not available. Cell coverage can also be expanded.

Figure 1 shows the service provided in a typical multi-link relay communication system with a BWA.

As shown in FIG. 1, in a multi-link relay communication system with a BWA, MS 140-170 (MS1-MS4) can receive BWA services through BS 100, primary RS (RS1) 110 and secondary RS (RS2) 120 and 130.

MSI and MS2 within the service area 101 of the BS 100 communicates with the BS 100 via the forward link L1. MS2, which is located at the cell boundary of BS 100 and thus has a poor channel condition, can receive a higher speed data channel through the RS-MS link L2 between MS2 and RS2 130 than through the forward link L1.

MS3 and MS4 located outside the BS 101 service area 101 communicate with the BS 100 via RS-MS L3 lines provided by RS1 110. Communication lines between the BS 100 and MS3 and MS4 via RS1 110 extend the cell coverage area. MS4, which is located at the cell boundary of RS1 110 and thus has a poor channel condition, can increase its throughput using the RS-MS link L4 between MS4 and RS2 120.

As described above, when on the MS at the border of the BS cell or in the shading zone suffering from a strong shading effect due to, for example, buildings, the channel condition is poor, the BWA communication system allows the MS to communicate with the BS, providing a radio channel with better quality for the MS through RS. In other words, the BS can provide high-speed data channels at the cell-shadow boundary and expand its coverage area using a multi-link relay circuit. RS 110, 120, and 130 are classified in RS1 (RS 110), which expands the cell coverage, and RS2 (RS 120 and 130), which increases throughput in accordance with its relay capabilities.

Typically, transmission / reception is performed between the BS and the MS in frames having the structure shown in FIG. 2 in the BWA communication system. Figure 2 shows the time division duplex (TDD) frame structure according to the Institute of Electrical and Electronics Engineers (IEEE) 802.16 document for transmitting / receiving data between a BS and an MS.

2, a TDD frame 200 is divided into a downlink (DL) subframe 210 and an uplink (UL) subframe 220 with a guard region called a transmit to receive transition gap (TTG) between them. The protection area, called the reception to transmit (RTG) transition gap, is inserted between TDD frames.

The DL subframe 210 comprises a preamble and a common control channel at mandatory time intervals. The MS within the BS service area receives synchronization and control information from the preamble and the common control channel.

As described above, the BWA communication system provides MS or RSS services beyond the cell coverage of the BS or in the shading zone using RS stations. In order to guarantee backward compatibility for MS stations, communication is carried out in frames made as shown in FIG. That is, the RS station operates in exactly the same way as the MS during initial access and coordinates relay operation with the BS so that the BS can provide relay services to the MS stations in frames having the structure shown in FIG. 2. Since RS provides relay service using the same frame structure as the BS, it has difficulty communicating simultaneously with the BS and the MSs in the same frequency range in one frame. In order to prevent the problem of decoupling at the radio frequency (RF) caused by the frame structure shown in FIG. 2, frames are formed as shown in FIG. 3 so that the transmission to RS and reception from RS are parallel in time.

FIG. 3 shows a TDD frame structure in a conventional multi-link relay station of a BWA communication system.

3, the DL subframe 300 is divided into a first zone 301 and a second zone 303, and the UL subframe 310 is divided into a first zone 311 and a second zone 313. For transitions in RS operation, the first zones 301 and 311 are different from the second zones 311 and 313 in time separation. The durations of the first zones 301 and 311 and the durations of the second zones 311 and 313 are fixed or adaptively adjusted in accordance with the environment of the cell.

The BWA communication system provides a direct line service in the first zones 301 and 311 and a relay line service in the second zones 303 and 313. Therefore, the BS station provides a synchronization channel, a control channel and a traffic channel for the MS station connected to it by a direct communication line in the first zones 301 and 311, and a synchronization channel, a control channel and a traffic channel of the RS station in the second zones 303 and 313.

Since the RS station can move, as shown in FIG. 4, the BWA communication system must take into account the mobility of the RS station.

Figure 4 shows the movement of the RS station of the traditional multi-link relay station of the communication system with the BWA.

In figure 4, located on a vehicle, such as a bus or train, station RS1 420 has mobility. Therefore, the BWA communication system must provide a synchronization channel for RS1 420 for synchronization and cell search, given its mobility.

In the case of the frame structure shown in FIG. 3, the duration of the first and second zones 301 and 303 of the DL subframe 300 may vary depending on the environment of the cell. The resulting change in the position of the synchronization channel at the beginning of the second zone 303 is superimposed because RS1 420 must determine the location of the synchronization channels of the neighboring BSs. Increased interference between neighboring cells due to increased power of the synchronization channels, the transmission of information about the neighboring BS stations and the search for the synchronization channel of each neighboring BS is added on top of the RS.

Without providing synchronization channels, stations RS2 120 and 130, as shown in FIG. 1, provide relay service in conjunction with the BS through multiple communications in the cell. In this case, the MS experiences interference from neighboring stations due to the power difference between the signal received from the BS 100 or RS1 110 and the signal received from the RS2 120 or 130, as shown in FIG.

Figure 5 shows the signal flow for the relay service from RS in a traditional multi-link relay station of a BWA communication system.

In FIG. 5, within the area of the BS 500 cell, the first MS 530 (MSI), having a good channel condition, receives service from the BS 500 through a forward link, and the second MS 520 (MS2) having a poor channel condition, receives service via RS2 510.

Although the BS 500 and RS2 510 make numerous communications using orthogonal resources in the same time interval, the signal of the BS communication line in the air overlaps with the signal of the RS communication line. Thus, MS1 can be affected by interference from neighboring stations because it receives a stronger interference signal from nearby RS2 510 than the signal from BS 510. Interference from neighboring stations can also occur in the uplink because RS2 510 receives stronger from MS1 interference signal than the signal from MS2.

SUMMARY OF THE INVENTION

Technical solution

One aspect of the present invention is to essentially solve at least the aforementioned problems and / or eliminate the listed disadvantages and provide at least the following advantages. Accordingly, one feature of the present invention should be the provision of a device and method for effectively supporting cell search and synchronization in accordance with RS mobility in a multi-link relay communication system with a BWA.

Another aspect of the present invention is the provision of a device and method for efficiently supporting cell search and synchronization in accordance with RS mobility by providing synchronization channels in a multi-link relay communication system with a BWA.

Another aspect of the present invention is the provision of a device and method for reducing interference from neighboring stations caused by multiple intra-cell communications in a multi-link relay communication system with a BWA.

Another aspect of the present invention is the provision of a device and method for eliminating interference from neighboring stations between relay communications and direct communications in a cell by temporarily sealing relay communications and direct communications in a multi-link relay communication system with a BWA.

Another aspect of the present invention is the provision of a method for forming a frame in such a way as to provide synchronization channels and eliminate interference from neighboring stations, and a device supporting the same in a multi-link relay communication system with BWA.

According to aspects of the present invention, there is provided a method of forming a subframe for maintaining relay service in a multi-link relay communication system (BWA). The method comprises generating at least one MS-BS link subframe, a primary RS-MS link subframe, and a BS-secondary RS link subframe formed in a first period of a subframe, a BS-MS link subframe being a subframe for the communication line between the BS and the MS, a primary RS-MS link link subframe, which is a subframe for communication between the primary RS that provides a synchronization channel; and the formation of the MS, and the sub-frame of the communication line BS-secondary RS, which is a subframe of the communication line between the BS and the secondary RS, which does not provide a synchronization channel, and at least a subframe of the communication line BS-primary RS or a subframe of the RS-RS communication line or a secondary RS-MS link subframe is formed in a second period of a subframe, a BS-primary RS link subframe, a subframe being a subframe for a communication link between a BS and a primary RS, an RS-RS communication subframe being a subframe for a communication link between RS and another RS, and sub-frame of the communication line secondary RS-MS, I a subframe for communication between the secondary RS and the MS.

In accordance with another aspect of the present invention, a method is provided for forming a subframe in a downlink to support relay service in a multi-link relay communication system (with BWA). The method comprises generating a sub-frame of a communication line of a BS-MS and a sub-frame of a communication line of RS-MS, which are provided in a first period of a sub-frame in a downlink, a sub-frame of a communication line BS-MS, which is a sub-frame for a communication line between a BS and an MS, and a sub-frame of a communication line RS -MS, which is a subframe for the communication link between RS and MS; the formation of a subframe for the RS link of the 1st group-RS of the next link of the 2nd group, which are formed in the second period of the subframe in the downlink, the RS subframe of the 1st group-RS of the next link of the 2nd group, the subframe being a subframe for communication lines between the RS of the first group containing the RS stations of the odd link and the RS of the next link of the second group containing the RS stations of the even link; and the formation of a subframe of the communication link BS-RS of the l-th link and a subframe of the communication link RS of the 2nd group-RS of the next link of the l-th group are formed in the third period of the subframe in the downlink, the subframe in the communication link of the BS-RS of the 1st link , which is a subframe for the communication link between the BS and the RS of the 1st link, and a subframe for the communication link of the RS of the 2nd group-RS of the next link of the 1st group, which is a subframe for the communication link between the RS of the second group and the RS of the next link of the first group.

In accordance with another aspect of the present invention, a method is provided for forming a subframe in an uplink to support relay service in a multi-link relay communication system with a BWA. The method comprises generating a subframe for the BS-MS communication line and an RS-MS line subframe that are generated in the first period of the subframe in the downlink, a subframe for the BS-MS communication line, which is a subframe for communication between the BS and MS, and a subframe for the communication line RS-MS, which is a subframe for the communication line between RS and MS; the formation of a subframe for the BS-RS link of the 1st link and the RS subframe of the 2nd group-RS of the next link of the 1st group, which are formed in the second period of the subframe in the downlink, the subframe for the BS-RS link of the 1st link being a subframe for the communication link between the BS and the RS of the 1st link, and a subframe for the communication link of the RS of the 2nd group-RS of the next link of the 1st group, which is a subframe for the communication link of the RS of the second group containing the RS stations of the even link, and RS of the next link of the 1st group containing the odd link RS stations, and the formation of a subframe for line c RS link of the 1st group-RS of the next link of the 2nd group, which is formed in the third period of the downlink subframe, subframe for the RS communication link of the 1st group-RS of the next link of the 2nd group, which is a subframe for the communication line between RS 1st group and RS next link of the second group.

According to another aspect of the present invention, a method for forming a subframe in an uplink in a multi-link relay communication system with a BWA is provided. The method comprises forming a subframe for the MS-BS communication line and a subframe for the MS-RS communication line, which are generated in the first period of the subframe in the uplink, a subframe for the MS-BS communication line, which is a subframe for the communication line between the MS and the BS, and a subframe for the communication line MS-RS, which is a subframe for the communication line between MS and RS; the formation of a subframe for the RS link of the 2nd group-RS of the previous link of the l-th group, which is formed in the second period of the subframe of the ascending link, subframe for the RS link of the 2nd group-RS of the previous link of the 1st group, which is a subframe for communication lines between the RS of the second group containing the RS stations of the even link and the RS of the previous link of the first group containing the RS stations of the odd link; and forming a subframe for the RS communication link of the 1st link-BS and a subframe for the RS communication link of the 1st group-RS of the previous link of the 2nd group, which is formed in the third period of the uplink subframe of the communication link, subframe for the RS communication link of the 1st link-BS, which is a subframe for the communication line between the RS of the 1st group and the BS, and a subframe for the communication line RS of the 1st group-RS of the previous link of the 2nd group, which is a subframe for the communication line between the RS of the first group and the RS of the previous link second group.

According to another aspect of the present invention, a method for forming a subframe in an uplink in a multi-link relay communication system with a BWA is provided. The method comprises forming a subframe for the MS-BS communication line and a subframe for the MS-RS communication line, which are formed in the first period of the subframe in the uplink, a subframe for the MS-BS communication line, which is a subframe for the communication line between the MS and RS: for the RS communication line of the 1st link-BS and subframe for the RS communication line of the 1st group-RS of the previous link of the 2nd group, which is formed in the second period of the subframe in the uplink, the subframe for the RS communication link of the 1st link- A BS being a subframe for a communication link between the RS of the 1st link and the BS, and a subframe d For the RS communication link of the 1st group-RS of the previous link of the 2nd group, which is a subframe for the communication line between the RS of the 1st group containing the odd-link RS stations and the RS station of the previous link of the second group containing the even RS stations; and forming a subframe for the RS link of the 2nd group-RS of the previous link of the 1st group, which is formed in the third period of the subframe in the uplink, and a subframe for the RS link of the 2nd group-RS of the previous link of the first group, which is the subframe for the link between the RS of the second group and the RS of the previous link of the first group.

According to another aspect of the present invention, a method for using a BS in a BWA multi-link relay communication system is provided. The method comprises BS allocated resources for a first period and a second period of a subframe, a first period for communication with at least one MS and a secondary RS that does not provide a synchronization channel, and a second period for communication with a primary RS that provides a synchronization channel; for communicating with at least one MS and a secondary RS in a first period of a subframe; and for communication with a primary RS in a second period of a subframe.

In accordance with another aspect of the present invention, there is provided a method of using RS providing a synchronization channel in a BWA multi-link relay communication system. The method comprises installing on the RS a first period and a second period in accordance with control information received from an upper node, a first period for communicating with an MS, and a second period for communicating with at least an upper node or a lower RS; communication with MS in the first period; and communication with at least the upper node or lower RS in the second period.

In accordance with another aspect of the present invention, there is provided a method of using RS that does not provide a synchronization channel in a BWA multi-link relay communication system. The method comprises installing on the RS a first period and a second period in accordance with the control information received from the upper node, the first period intended for communication with the upper node, and the second period intended for communication with the MS for communication with the upper node in the first period and for communication with MS in the second period.

In accordance with another aspect of the present invention, a BS device is provided in a multi-link relay communication system with a BWA. The device comprises a synchronization controller for providing a transmission and reception synchronization signal according to the structure of a subframe in which a first period and a second period are defined, a first period for communicating with at least an MS or secondary RS that does not provide a synchronization channel, and a second period designed to communicate with the primary RS, which provides a synchronization channel, a transmitter for creating a first period signal or a second period signal in accordance with the synchronization and transmission signal a signal and a receiver for receiving a signal of the first period and a signal of the second period in accordance with the synchronization signal and restore the received signal.

In accordance with another aspect of the present invention, an RS device is provided that provides a synchronization channel in a multi-link relay communication system with a BWA. The device comprises a synchronization controller for providing a transmission and reception synchronization signal according to the structure of a subframe in which a first period and a second period are defined, a first period for communicating with at least an MS or secondary RS that does not provide a synchronization channel, and a second period intended for communication with the upper node; a transmitter for generating a first period signal or a second period signal in accordance with a synchronization signal and transmitting the generated signal; and a receiver for receiving a first period signal and a second period signal in accordance with a synchronization signal and recovering the received signal.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description when considered in conjunction with the accompanying drawings, in which:

figure 1 - signal flow for relay service in a typical multi-link relay communication system with BWA;

figure 2 - frame structure in a typical IEEE 802.16 system;

figure 3 - frame structure in a traditional multi-link relay communication system with BWA;

figure 4 - RS movement in a conventional multi-link relay communication system with BWA;

5 is a signal flow for relay service from RS in a conventional multi-link relay communication system with BWA;

6 is a frame structure with synchronization channels in a multi-link relay communication system with a BWA in accordance with the present invention;

7 is a frame structure in a multi-link relay communication system with a BWA in accordance with the present invention;

Fig. 8 is a diagram showing synchronization of signal transmission and reception in accordance with the frame structure shown in Fig. 7;

Fig.9 is a frame structure in a multi-link relay communication system with a BWA in accordance with the present invention;

figure 10 - structure of a multi-link relay communication system with a BWA in accordance with the present invention;

11 is a structure of a DL subframe in a multi-link relay communication system with a BWA in accordance with the present invention;

Fig - the position of the synchronization channels in the DL subframe shown in Fig.11, in a multi-link relay communication system with a BWA in accordance with the present invention;

FIG. 13 is a structure of a DL subframe in a multi-link relay communication system with a BWA in accordance with the present invention; FIG.

Fig. 14 shows the positions of synchronization channels in the DL subframe shown in Fig. 13 in a multi-link relay communication system with a BWA in accordance with the present invention;

FIG. 15 illustrates a structure of a UL subframe in a multi-link relay communication system with a BWA in accordance with the present invention; FIG.

FIG. 16 illustrates a structure of a UL subframe in a multi-link relay communication system with a BWA in accordance with the present invention; FIG.

FIG. 17 is a flowchart of a BS process flowchart in a multi-link relay communication system with a BWA in accordance with the present invention; FIG.

FIG. 18 is a flowchart of an RS1 process flowchart in a multi-link relay communication system with a BWA in accordance with the present invention; FIG.

Fig is a block diagram of a program sequence of operations of the RS2 process in a multi-link relay communication system with BWA in accordance with the present invention;

FIG. 20 is a flowchart of an MS process flowchart in a multi-link relay communication system with a BWA in accordance with the present invention; FIG. and

21 is a block diagram of a BS in a multi-link relay communication system with a BWA in accordance with the present invention.

Preferred Embodiment

Preferred embodiments of the present invention will be described hereinafter with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they may obscure the invention in unnecessary detail.

The present invention provides a method for providing a synchronization channel for supporting RS mobility and eliminating interference from neighboring stations caused by multiple intra-cell communications in a multi-link relay communication system with a BWA. The following description will be made in the context of a time division multiplexed wireless duplex (TDD) system, orthogonal frequency division multiplexing (OFDM) multiple access systems, although the present invention is also applicable to a communication system using any other multiple access system or any other duplex separation scheme.

The term "primary RS" or "RS1" is defined as RS, which extends the cell coverage, and the term "secondary RS" or "RS2" is defined as RS, which increases throughput. Therefore, RS1 provides a synchronization channel, a control channel, and traffic channels for MS or RS stations located outside the cell area of the BS station, while RS2 provides individual control and traffic channels for MS stations in the poor state of the channel, although they are located in the cell area of the BS station .

Although it says that for communications between a BS and RS, a subframe is configured in accordance with the IEEE 802.16 standard, it should be obvious that advanced technology with new features and applications can be applied. The same is true for connections to the upper RS (or superior RS) and lower RS.

6 shows a frame structure providing synchronization channels for MS and RS stations in a multi-link relay communication system with a BWA in accordance with the present invention.

6, the frame is composed of a DL subframe 610 and a UL subframe 620. The DL subframe 610 comprises first and second temporary compression zones 611 and 613, and the UL subframe 620 comprises first and second temporary compression zones 621 and 623. The duration of the first zones 611 and 621 and the duration of the second zones 621 and 623 may be unchanged or vary depending on the environment of the cell.

The BS communicates with an MS connected to it via a forward link in the first zones 611 and 621, and communicates with RS in the second zones 613 and 623. Since the durations of the first zones 611 and 621 and the second zones 613 and 623 can dynamically change in accordance with the environment cells, as mentioned above, the BS assigns synchronization channels to the beginning of the first zone 611 and to the end of the second zone 613, so that the MS and RS can synchronize. The BS also assigns ranking channels to the beginning of the first zone 621 and to the end of the second zone 623 for ranking from the MS stations. The positions of the ranking channels (or ranking timeslots) in the UL subframe 620 may be indicated by the control channel, if they are not constant.

To facilitate synchronization and cell search, the BS provides for the MS a synchronization channel (referred to as a BS synchronization channel) in the form of a preamble and for RS, a synchronization channel (referred to as an RS synchronization channel) in a conclusion form. Since the synchronization channels are constantly at the beginning and end of the DL subframe 610, the MS and RS can acquire information for synchronization and information of the neighboring BS from the established synchronization channels. The RS sync channel can optionally be used to measure interference.

Numerous communications take place among BS, RS1, RS2 and MS in a multi-link relay communication system with BWA.

Since the BS and RS2 provide service to the MS within the BS service area, they use orthogonal resources to avoid interference between the two communication lines, that is, between the BS-MS communication line and the RS2-MS communication line. When there are many RS2 stations in a cell, the orthogonal resources allocated by RS2 can be reused multiple times by spatial multiplexing.

Therefore, the signal of the communication line BS-MS is different from the signal of the communication line RS2-MS in the frequency zone, but they overlap each other in the time domain. When the BS and RS2 communicate with the MS stations at the same time, interference from neighboring stations occurs.

In this context, the same temporary resources are not assigned by the BS-MS and the RS2-MS, as shown in FIG. 7. Specifically, the communication system with the BWA assigns predetermined resources to the second zones 613 and 623 of the RS2-MS communication line.

7 shows a frame structure in a multi-link relay communication system with a BWA in accordance with the present invention. In accordance with the structure of the frame, the frame is formed in such a way that resources are assigned to RS1 and RS2 in the frequency division.

7, each frame is composed of a DL subframe 720 and a UL subframe 730. The DL subframe 720 comprises first and second time zones 721 and 723 separated in time, and the UL subframe 730 contains time and first and second zones 731 and 733 divided in time. The durations of the first zones 721 and 731 and the durations of the second zones 723 and 733 are fixed or dynamically changed depending on the cell environment.

In RS2 frame 710, the RS2 station communicates with the BS in the first zones 721 and 731 and communicates with the MS in the predetermined parts 711 and 713 of the second zones 723 and 733. If there are many RS2 stations, the second zones 723 and 733 are used multiple times by spatial multiplexing. separation. RS1 provides transparent relay service for the MS in the first zones 721 and 731 and communicates with the BS in the second zones 723 and 733.

When a frame is formed using spatial multiplexing and time multiplexing, as described above, the transmission and reception of the BS, RS1, RS2 and the MSs have the relationships shown in FIG.

On Fig shows a diagram illustrating the synchronization of the transmission and reception of signals in accordance with the frame structure shown in Fig.7.

In FIG. 8, in DL DL subframe 720, the BS 800 sends a synchronization channel, a control channel, and a traffic packet to the RS2 820 station or to the MS 830 station connected to the BS 800 station with a forward link in the first zone 721, and then sends the control channel, a traffic packet and a synchronization channel to the RS1 810 station in the second zone 723. The BS 800 provides the BS synchronization channel and the RS synchronization channel for the MS 830 and RS 810 and 820 stations at the beginning of the first zone 721 and at the end of the second zone 723, respectively.

RS1 810 sends a synchronization channel, a control channel and a traffic packet to RS2 820 station or MS 830 station connected to RS1 810 via a relay line in the first zone 721. Then RS1 810 receives a synchronization channel, a control channel and a traffic packet from BS 800 in the second zone 723 .

RS2 820 receives the control channel and traffic packet necessary for relay service from the BS 800 in the first zone 721. Then, RS2 820 sends a traffic packet to the MS 830 station connected to RS2 via the relay line in a predetermined part 711 of the second zone 723.

MS 830 receives a synchronization channel, a control channel, a traffic packet from BS 800 or from RS1 810 in the first zone 721. Then, MS 830 receives a signal from RS1 810 or RS2 820 in the second zone 723. In particular, MS 830 receives a traffic packet from RS2 820 in part of the second zone 723.

To avoid interference from neighboring stations, the second zones 723 and 733 are assigned by the RS2-MS link and the BS-RS1 link by frequency division. In another embodiment of the present invention, the second zones 723 and 733 are assigned by the RS2-MS link and the BS-RS1 link by time division.

FIG. 9 shows a frame structure in a multi-link relay communication system with a BWA in accordance with the present invention. Frame 700 BS and frame 710 RS2 are shown.

9, each of frames 700 and 710 consists of a DL subframe 720 and a UL subframe 730. DL subframe 720 comprises first and second time zones 721 and 723 multiplexed in time, and UL subframe 730 contains first and second time zones 731 and 733 multiplexed. The second zones 723 and 733 are divided into zones 900 and 920 of the RS2-MS communication line and zones 910 and 930 of the BS-RS1 communication line. The BS provides the RS1 station with an RS synchronization channel, which takes the form of a conclusion in a fixed place. Therefore, the RS2-MS communication lines zones 900 and 920 precede the BS-RS1 communication zones 910 and 930 in the second zones 723 and 733.

The BS communicates with RS2 or with MS in the first zones 721 and 731 and communicates with RS1 in the second zones 723 and 733. Interestingly, the BS leaves the RS2-MS communication zones 900 and 920, which is empty in the second zones 723 and 733 to avoid interference inside the cell. Accordingly, the BS communicates with RS1 in zones 910 and 930 of the communication line BS-RS1.

For RS1, the BS provides an RS synchronization channel and a ranking channel at the end of the BS-RS1 communication zones 910 and 930.

In frame 710, RS RS2 communicates with the BS in the first zones 721 and 731 and then communicates with the MS in zones 900 and 920 of the RS2-MS communication line of the second zones 723 and 733. Interestingly, RS2 does not use the BS-RS1 communication zones 910 and 930 to avoid interference inside the cell.

The above description was made in the context of a multi-link relay communication system with a BWA having two links. The communication system with the BWA may be configured such that the MS communicates with the BS in multiple links, as shown in FIG. 10.

10 shows the structure of a multi-link relay communication system with a BWA according to the present invention.

10, BS 1001 communicates with MS 1019 via relay lines formed by a plurality of RS stations 1011, 1013, 1015, and 1017.

Stations RS 1011, 1013, 1015 and 1017 can be grouped into the 1st group and the 2nd group. For example, if BS 1001 is installed as RS of the 0th link, the 1st group is a group with even links, including BS 1001, RS 1013 of the 2nd link, RS of the 4th link and other RS of even links, and 2- I group is a group with odd links, including RS 1011 of the 1st link, RS 1015 of the 3rd link and other RS of odd links.

If BS 1001 is not classified as RS of the 0th link, the 1st group is a group with odd links, including RS 1011 of the 1st link, RS 1015 of the 3rd link and other RS of odd links, and the 2nd group is a group with even links, including RS 1013 of the 2nd link, RS of the 4th link and other RS of even links.

When multi-link communication lines are thus grouped into the first and second groups, communication is carried out in frames having the structures shown in FIGS. 11-16 in the communication system with the BWA. The following description is made under the condition that the 1st group is an odd-link group and the second zone shown in FIG. 6 is further divided into the second and third zones.

The DL subframe in the communication system with the BWA has the structure shown in FIG. 11 or FIG. 13.

11 shows the structure of a DL subframe in a multi-link relay communication system with a BWA in accordance with the present invention.

With reference to FIG. 11, each DL subframe 1100 comprises first, second, and third zones 1101, 1103, and 1105, respectively, with time multiplexing.

In the BS subframe 1110, the BS station sends downlink subframes to the MS within its coverage area in the first and second zones 1101 and 1103. To avoid interference between the MS and the RS, the second zone 1103 may be filled with null data instead of the downlink subframe communication. The BS provides the MS with the preamble as the synchronization channel at the beginning of the first zone 1101. The BS sends a subframe in the downlink to the RS of the 1st link of the 1st group in the third zone 1105. The BS provides the RS of the 1st link with the conclusion as the synchronization channel in end of third zone 1105.

In sub-frame 1120, Group 1 RS The group 1 RS sends the sub-frame downlink to the MS within its coverage area in the first zone 1101. Group 1 RS provides the MS with a synchronization channel in the form of a preamble at the beginning of the first zone 1101. The RS of the 1st group sends a subframe on the RS downlink to the next link of the 2nd group in the second zone 1103. The RS of the 1st group provides the RS of the next link the synchronization channel in the form of a conclusion at the end of the second zone 1103. The RS of the 1st group receives the subframe on the downlink from RS of the previous link of the 2nd group in the third zone 110 5. If the RS of the 1st group is the RS of the 1st link, the RS of the 1st group receives a downlink subframe from the BS in the third zone 1105. A TTG is inserted between the second zone 1103 and the third zone 1105 to switch the RS 1st operations groups. Therefore, the RS of the 1st group sends a synchronization channel before the TTG to the RS of the 2nd group, using the resources of the second zone 1103.

In group 2 RS subframe 1130, group 2 RS station sends the MS subframe downlink within its service area in the first zone 1101. Group 2 RS provides the MS a synchronization channel in the form of a preamble at the beginning of the first zone 1101. RS 2nd group receives a downlink subframe from RS of the previous link of the 1st group in the second zone 1103. RS of the 2nd group sends a subframe on the downlink RS of the next link of the 1st group in the third zone 1105. RS 2nd the group provides for the next link RS the synchronization channel in the form of a conclusion at the end of the third they are 1105. A TTG is inserted between the first zone 1101 and the second zone to switch the RS operations of the 2nd group and an RTG is inserted between the second zone 1103 and the third zone 1105.

Although not shown in the drawing, if the RS of the 1st group is the RS of the last link, the RS of the 1st group sends downlink subframes to the MS within its service area in the first and second zones 1101 and 1103. In order to avoid interference between stations MS and RS, the second zone 1103 may have zero data. Then, the RS of the last link receives a downlink subframe from the RS of the previous link of the 2nd group in the third zone 1105.

If the RS of the last link is RS of the 2nd group, the RS of the 1st group sends subframes in the downlink to the MS station inside its service area in the first and third zones 1101 and 1105. To avoid interference between the MS and RS stations, the third zone 1105 may have zero data. The RS of the last link receives a downlink subframe from the RS of the previous link of the 1st group in the second zone 1103.

According to the DL frame structure shown in FIG. 11, subframes of the first, second, and third zones of the DL subframe can be formed in accordance with the IEEE 802.16 standard, as shown in FIG.

FIG. 12 shows the positions of the synchronization channels in the DL subframe shown in FIG. 11 in a multi-link relay communication system with a BWA in accordance with the present invention.

12, the DL subframe 1200 comprises first, second, and third zones 1201, 1203, and 1205, respectively, time-multiplexed.

The BS subframe 1210 transfers the synchronization channel, the control channel, and the DL packet to the MS station within the BS service area. The BS places the synchronization channel for the MS in the form of a preamble at the beginning of the first zone 1201. If the BS uses the second zone 1203, the BS frame 1210 contains a DL packet in the second zone 1203. The third zone 1205 has a control channel, a DL packet, and a synchronization channel for RS 1st link. Thus, the BS provides the synchronization channel for the 1st link RS in the form of a conclusion at the end of the third zone 1205.

In group 1 RS subframe 1220, the first zone 1201 carries a synchronization channel, a control channel, and a DL packet for the MS within the group 1 RS service area. Group 1 RS provides the MS for the synchronization channel in the form of a preamble at the beginning of the first zone 1201. The second zone 1203 has a control channel, a DL packet, and a synchronization channel for the RS of the next link of the 2nd group. Thus, the RS of the 1st group provides for the RS of the next link a synchronization channel in the form of a conclusion at the end of the second zone 1203. The RS of the 1st group receives a subframe on the downlink from the RS of the previous link or from the BS in the third zone 1205.

In the frame 230 of the RS of the 2nd group, the first zone 1201 contains a synchronization channel, a control channel and a DL packet for the MS within the RS service area of the 2nd group. That is, the RS of the 2nd group provides a synchronization channel for the MS in the form of a preamble at the beginning of the first zone 1201. The third zone 1205 carries a synchronization channel, a control channel, and a DL packet for the RS of the next link of the 1st group. That is, the RS of the 2nd group provides for the RS of the next link of the 1st group the synchronization channel in the form of a conclusion at the end of the third zone 1205. The RS of the 2nd group receives a downlink from the RS of the previous link in the second zone 1203.

13 shows the structure of a DL subframe in a multi-link relay communication system with a BWA in accordance with the present invention.

13, each DL subframe 1300 comprises a first, second, and third time multiplexed zone 1301, 1303, and 1305.

In BS subframe 1310, the BS station sends downlink subframes to the MS within its service area in the first and third zones 1301 and 1305. To avoid interference between the MS and the RS, the third zone 1305 may be filled with null data instead of the downlink subframe . The BS provides a preamble as a synchronization channel at the beginning of the first zone 1301 for MS stations. The BS sends a subframe downlink to the RS of the 1st link of the 1st group in the second zone 1303. The BS provides the RS of the 1st link to conclude as a synchronization channel at the end of the second zone 1303. Since between the second zone 1303 and the third zone 1305 there is RTG in the subframe 1320 of the RS of the 1st group, the BS sends a synchronization channel to the RS of the 1st link before the RTG in the second zone 1303.

In a subframe 1320, the RS of the 1st group The RS of the 1st group sends downlink the subframe to the MS inside its service area in the first zone 1301. The RS of the 1st group provides for the MS a synchronization channel in the form of a preamble at the beginning of the first zone 1301. RS The 1st group receives the downlink from the RS of the previous link of the 2nd group in the second zone 1303. If the RS of the 1st group is the RS of the 1st link, the RS of the 1st group receives the downlink from the BS to the second zone 1303. The RS of the 1st group sends a subframe on the downlink to the RS of the next link of the 2nd group in the third zone 1305. The RS of the 1st group provides a synchronization channel for the RS of the next link at the end of the third zone 1305. A TTG is inserted between the first zone 1301 and the third zone 1303 to switch the RS operations of the 1st group, and an RTG is present between the second zone 1303 and the third zone 1305 in the subframe 1320 RS of the 1st group.

In subgroup 1330, RS of the 2nd group RS of the 2nd group sends downlink a subframe for the MS inside its service area in the first zone 1301. The RS of the 2nd group provides the synchronization channel for the MS in the form of a preamble at the beginning of the first zone 1301. RS The 2nd group sends a downlink for the RS of the next link of the 1st group in the second zone 1303. The RS of the 2nd group provides the synchronization channel for the next link of the RS in the form of a conclusion at the end of the second zone 1303. The RS of the 2nd group receives on the downlink RS subframe of the previous link of the 1st group in the third zone 1 305.

Although not shown if the RS of the last link belongs to the 1st group, the RS of the last link sends downlink subframes for MS stations within its coverage area in the first and third zones 1301 and 1305. To avoid interference between the MS and RS stations, the third zone 1305 may have null data. The RS of the last link receives in a downlink a subframe from the RS of the previous link of the 2nd group in the second zone 1303.

If the RS of the last link is the RS of the 2nd group, the RS of the last link sends downlink subframes for the MS stations within its service area in the first and second zones 1301 and 1303. To avoid interference between the MS and the RS stations, the second zone 1303 may have null data. The RS of the last link receives a subframe from the RS of the previous link of the 1st group in the third zone 1305 on the downlink.

According to the DL frame structure shown in FIG. 13, subframes of the first, second, and third zones in the DL subframe can be formed in accordance with the IEEE 802.16 standard, as shown in FIG.

FIG. 14 shows the positions of the synchronization channels in the DL subframe shown in FIG. 13 in a multi-link relay communication system with a BWA in accordance with the present invention.

14, a DL subframe 1400 comprises first, second, and third time multiplexed zones 1401, 1403, and 1405.

The BS subframe 1410 carries a synchronization channel, a control channel, and a DL packet for the MS within the BS coverage area. That is, the BS places the synchronization channel for the MS in the form of a preamble at the beginning of the first zone 1401. If the BS uses the third zone 1405, the BS, the subframe 1410 contains a packet for downlink transmission in the third zone 1405. The second zone 1403 of the BS subframe 1410 has a control channel , DL packet and synchronization channel for RS 1st link. Thus, the BS provides the 1st link RS with a synchronization channel in the form of a conclusion at the end of the second zone 1403.

In the RS group 1 subframe 1420, the first zone 1401 carries a synchronization channel, a control channel, and a DL packet for the MS within the RS group 1 service area. The 1st group RS provides the MS for the synchronization channel in the form of a preamble at the beginning of the first zone 1401. The third zone 1405 has a control channel, a DL packet and a synchronization channel for the RS of the next link of the 2nd group. Thus, the RS of the 1st group provides for the RS of the next link a synchronization channel in the form of a conclusion at the end of the third zone 1405. The RS of the 1st group receives in a downlink a subframe from the RS of the previous link or BS in the second zone 1403.

In the RS subgroup 1430 of the 2nd group, the first zone 1401 comprises a synchronization channel, a control channel, and a DL packet for the MS within the RS coverage area of the 2nd group. That is, the RS of the 2nd group provides a synchronization channel for the MS in the form of a preamble at the beginning of the first zone 1401. The second zone 1403 carries a synchronization channel, a control channel and a DL packet for the RS of the next link of the 1st group. The 2nd group RS provides a synchronization channel for the RS of the next link of the 1st group in the form of a conclusion at the end of the second zone 1403. The RS of the 2nd group receives in a downlink a subframe from the RS of the previous link in the third zone 1405.

The communication system with the BWA forms a UL subframe, as shown in FIG. 15 or FIG. 16.

FIG. 15 shows the structure of a UL subframe in a multi-link relay communication system with a BWA in accordance with the present invention.

15, each UL subframe 1500 comprises first, second, and third time multiplexed zones 1501, 1503, and 1505.

In the BS subframe 1510, the BS station receives uplink subframes from the MSs within its coverage area in the first and second zones 1501 and 1503. To avoid interference between the MS and RS stations, the second zone 1503 may be filled with zero data instead of the subframe transmitted over uplink communication. The BS receives an uplink subframe from the RS of the 1st zone of the 1st group in the third zone 1505.

In the RS of the 1st group, the subframes 1520 and 1540 of the RS of the 1st group receive a subframe from the MS on the uplink from the MS within its service area in the first zone 1501. The RS of the 1st group receives the uplink from the RS of the next link of the 2nd link in the uplink groups in the second zone 1503. For example, the RS of the 1st link of the first group receives an uplink from the RS of the 2nd link of the second group on the uplink. The RS of the 3rd link of the first group receives an uplink from the 4th link of the second group on the uplink. The RS of the 1st group sends an upframe to the RS of the previous link of the second group in the third zone 1505. If the RS of the 1st group is the RS of the 1st link, the RS of the 1st group sends an uplink to the BS in the third zone 1505. To switch the RS operations of the 1st group, an RTG is inserted between the second zone 1503 and the third zone 1505.

In the frame 1530 of the RS of the 2nd group, the RS station of the 2nd group receives the subframe from the MS on the uplink, inside its service area in the first zone 1501. The RS of the 2nd group sends the uplink to the RS of the previous link of the 1st group in the second zone 1503. The RS of the 2nd group receives a subframe from the RS of the next link of the 1st group in the third zone 1505 on the uplink. To switch the RS operations of the 2nd group between the first zone 1501 and the second zone 1503, RTG is present, and a TTG is inserted between the second zone 1503 and the third zone 1505.

Although not shown in the drawing if the RS of the last link belongs to the first group, the RS of the last link receives uplink subframes from the MS within its service area in the first and second zones 1501 and 1503. To avoid interference between the MS and the RS stations, the second zone 1503 may have zero data. The RS of the last link sends uplink a subframe for the RS of the previous link of the 2nd group in the third zone 1505.

If the RS of the last link is the RS of the 2nd group, it receives uplink subframes from the MSs within its service area in the first and third zones 1501 and 1505. To avoid interference between the MSs and the RS, the third zone 1505 may have zero data . The RS of the last zone sends an uplink RS subframe of the previous link of the 1st group in the second zone 1503.

16 shows the structure of a UL subframe in a multi-link relay communication system with a BWA in accordance with the present invention.

In FIG. 16, each UL subframe 1600 comprises a first, second, and third time multiplexed zones 1601, 1603, and 1605.

In the BS subframe 1610, the BS receives uplink subframes from the MSs within its coverage area in the first and third zones 1601 and 1605. To avoid interference between the MS and the RS, the third zone 1605 may be filled with null data instead of the UL subframe. The BS receives, on the uplink, a subframe from RS of the 1st link of the 1st group in the second zone 1603.

In subframes 1620 and 1640 of the RS of the 1st group, the RS station of the 1st group receives an uplink from the MS in the first zone 1601. The RS of the 1st group sends an RS subframe of the previous link of the second group in the uplink the second zone 1603. If the RS of the 1st group is the RS of the 1st link, then the RS of the 1st group sends a subframe for the BS in the second zone 1603. In the third zone 1605, the RS of the 1st group receives the uplink subframe from RS of the next link of the 2nd group. To switch the RS operations of the 1st group between the first zone 1601 and the second zone 1303, an RTG is inserted, and a TTG is present between the second zone 1603 and the third zone 1605.

In frame 1630, RS of the 2nd group, the RS of the second group receives uplink a subframe from the MS inside its service area in the first zone 1601. The RS of the 2nd group receives uplink a subframe from the RS of the next link of the 1st group in the second zone 1603 and sends an uplink subframe for RS of the previous link of the 1st group in the third zone 1605.

Although not shown in the drawing, if the RS of the last link belongs to the first group, the RS of the last link receives uplink subframes from the MS stations within its service area in the first and third zones 1601 and 1605. To avoid interference between the MS and RS stations, the third zone 1605 may have null data. The RS of the last link sends uplink a subframe for the RS of the previous link of the 2nd group in the second zone 1603.

If the RS of the last link is the RS of the 2nd group, the RS of the last link receives uplink subframes from the MSs within its service area in the first and second zones 1601 and 1603. To avoid interference between the MS and RS stations, the second zone 1603 can have zero data. The RS of the last link sends uplink a subframe for the RS of the previous link of the 1st group in the third zone 1605.

A communication system with a BWA may form a frame by combining the DL subframe shown in FIG. 11 and the UL subframe shown in FIG. 15 or FIG. 16. On the other hand, the communication system with the BWA can form a frame by combining the DL subframe shown in FIG. 13 and the UL subframe shown in FIG. 15 or FIG. 16.

As described above, the BS sends the synchronization channel to the MS stations and the RS stations of the 1st link in accordance with the frame structure in the communication system with the BWA. Group 1 RS stations send synchronization channels for MS stations and Group 2 RS stations in accordance with the frame structure. Group 2 RS stations provide synchronization channels for MS stations and RS stations of the next link of the first group in accordance with the frame structure.

BS, RS stations of the 1st group and RS stations of the 2nd group send synchronization channels in each frame or in each predetermined number of frames. Alternatively, they may comprise synchronization channels in frames indicated by a control signal. The control signal comprises a Frame Control Header (FCH), a MAP protocol, and a downlink channel descriptor (DCD).

Next, operations of the BS, RS1, RS2 and MS stations will be described to communicate using the frame structure described above in the communication system with the BWA.

17 is a flowchart illustrating a process of operating a BS in a multi-link relay communication system with a BWA in accordance with the present invention.

17, in step 1701, the BS determines a direct communication zone and a relay communication zone in each of the DL and UL subframes. For example, if a communication system with a BWA spans two links, the first zone for the forward link and the second zone for the relay link are defined in each of the DL and UL subframes. If the communication system with the BWA spans three links, the first zone for the forward link and the second and third zones for the relay line are defined in each of the DL and UL subframes.

At step 1703, the BS communicates with the MS and RS2 within its service area in the forward link area. The BS provides a BS synchronization channel for the MS at the beginning of the forward link area. For example, if the frame has the structure shown in FIG. 6, FIG. 7 or FIG. 9, the BS communicates with the MS in the first zones.

If the DL subframe and UL subframe have the structures shown in FIG. 11 and FIG. 15, respectively, the BS communicates with the MS in the first zones or in the second zones. If the DL subframe and UL subframe have the structures shown in FIGS. 13 and 16, respectively, the BS communicates with the MS in the first zones or third zones.

At step 1705, the BS contacts the RS of the 1st link in the area of the relay link. For RS of the 1st link, the BS provides for RS a synchronization channel at the end of the relay link area.

For example, if the frame has the structure shown in Fig.6, Fig.7 or Fig.9, the BS communicates with the RS of the 1st link in the second zones. Thus, the BS provides a synchronization channel for the RS of the 1st link at the end of the second zone of the DL subframe.

If the DL subframe and UL subframe have the structures shown in FIG. 11 and FIG. 15, respectively, the BS communicates with the RS of the 1st link in the third zones. Thus, the BS provides a synchronization channel for the RS of the 1st link at the end of the third zone of the DL subframe.

If the DL subframe and UL subframe have the structures shown in FIGS. 13 and 16, respectively, the BS communicates with the RS from the 1st link in the second zones. Thus, the BS provides a synchronization channel for the RS of the 1st link at the end of the second zone of the DL subframe.

Then the BS completes the process.

FIG. 18 is a flowchart of a process for RS1 in a multi-link relay communication system with a BWA in accordance with the present invention.

In FIG. 18, at step 1801, RS1 checks subframe structure information, that is, information about forward link areas and relay link areas in DL and UL subframes received from the BS or upper RS. If the frame has the structure shown in FIG. 6, FIG. 7 or FIG. 9, RS1 checks the structure information regarding the first and second zones.

If the DL subframe has the structure shown in FIG. 11 or FIG. 13, and the UL subframe has the structure shown in FIG. 15 or FIG. 16, RS1 checks the structure information regarding the first, second and third zones.

At 1803, RS1 communicates with the MS or RS2 within its service area in the first areas for the forward link. For the MS station, the RS1 station provides a synchronization channel at the beginning of the first zone in the DL subframe.

At 1805, RS1 communicates with the BS or RS of various links in the areas of the relay link. For lower RS stations, station RS1 provides a synchronization channel at the end of the zone for communication with lower RS stations in the DL subframe. If the frame has the structure shown in Fig.6, Fig.7 or Fig.9, RS1 communicates with the BS in the second zones.

If the DL subframe and the UL subframe of the frame have the structures shown in FIG. 11 and FIG. 15, respectively, RS1 communicates with lower RS stations in second zones and communicates with a BS or upper RS stations in third zones. RS1 provides a synchronization channel to the lower RS at the end of the second zone in the DL subframe.

If the DL subframe and the UL subframe of the frame have the structures shown in FIGS. 13 and 16, respectively, RS1 communicates with lower RS stations in third zones and communicates with a BS or upper RS stations in second zones. RS1 provides a synchronization channel for the lower RSs at the end of the third zone in the DL subframe.

Then RS1 finishes the process.

FIG. 19 is a flowchart of RS2 operation in a multi-link relay communication system with a BWA in accordance with the present invention.

In FIG. 19, RS2 checks the control information and subframe structure information generated in accordance with the capabilities of its relay line obtained from the BS in step 1901. For example, if a frame is formed as shown in FIG. 7 or FIG. 9, RS2 checks the information, relating to the first and second zones and zones of the RS2-MS communication line of the second zones.

At step 1903, RS2 communicates with the BS in the first zone. RS2 then contacts the MS, which in 1905 receives relay service through RS2 in the second zone.

For example, RS2 receives a signal from a BS in a first zone and sends a signal to an MS in a second zone of a DL subframe. In the UL subframe, RS2 sends a signal to the BS in the first zone and receives a signal from the MS in the second zone.

Then RS2 finishes the process.

FIG. 20 is a flowchart of an MS operation in a multi-link relay communication system with a BWA in accordance with the present invention.

20, in step 2001, the MS contacts the BS or RS1 in the first zone.

In step 2003, the MS communicates with RS2 in the second zone. For example, in a DL subframe, an MS receives a signal from a BS or RS1 in a first zone and receives a signal from an RS2 in a second zone. In the UL subframe, the MS sends a signal to BS or RS1 in the first zone and a signal to RS2 in the second zone.

Then MS completes the process.

It has been described above that each unidirectional subframe is divided into first and second zones or into first, second and third zones, which are time division multiplexed in a TDD system. In another example embodiment of the present invention, a unidirectional subframe is divided into first and second zones or first, second and third zones that are frequency division multiplexed in a frequency division duplex (FDD) system. In the FDD system, the DL subframe and the UL subframe are sent / received simultaneously in different frequency ranges.

Next, BS and RS structures for providing relay service in a communication system with a BWA will be described. Since the BS and RS have the same construction, their structures will be described for the BS structure shown in FIG. The following description is made, assuming that the transmission and reception of signals are performed using a single transceiver on the BS and RS.

On Fig shows a block diagram of a BS in a multi-link relay communication system with a BWA in accordance with the present invention.

21, the BS comprises a transmitter 2101, a receiver 2103, a synchronizer 2105, and an RF switch 2107.

The transmitter 2101 has a frame generator 2109, a resource display device 2111, a modulator 2113, and a digital to analog converter 2115 (DAC).

In operation, the frame generator 2109 generates a DL subframe to send synchronization channels, control channels, and traffic packets to the MS and lower RS within the BS service area under the control of the synchronizer 2105. In particular, the frame generator 2109 provides a synchronization channel for the MS at the beginning of the subframe for the MS and a synchronization channel for the lower RS at the end of the subframe for the lower RS in the DL subframe.

If the communication system with the BWA spans two links, the frame generator 2109 forms a subframe to be sent by MS or RS2 in the first area of the DL subframe. Then, frame generator 2109 forms a subframe to be sent to the RS of the 1st link in the second zone of the DL subframe. A frame generator 2109 places synchronization channels at the beginning of a subframe in the first zone and at the end of the subframe in the second zone.

If the communication system with the BWA spans three or more links, the frame generator 2109 forms a subframe to be sent to the MS or RS2 in the first zone or in the first and second zones of the DL subframe. Then, the frame generator 2109 forms a subframe to be sent to the RS of the 1st link in the third zone of the DL subframe. A frame generator 2109 places the synchronization channels at the beginning of a subframe in the first zone and at the end of the subframe in the third zone.

Resource mapper 2111 displays subframes received from frame generator 2109 in packets for communication links corresponding to subframes.

Modulator 2113 modulates the mapped subframes in a predetermined modulation scheme.

The DAC 2115 converts the modulated digital signal into an analog signal and provides an analog signal for the RF switch 2107.

The receiver 2103 comprises an analog-to-digital converter 2117 (ADC), a demodulator 2119, a resource recovery device 2121, and a frame allocation device 2123.

The ADC 2117 converts the analog signal received through the radio frequency switch 2107 into a digital signal. Demodulator 2119 demodulates the digital signal in a predetermined demodulation scheme.

Resource recovery device 2121 extracts subframes from packets transmitted over a communication line received from a demodulator. A subframe allocator 2123 extracts a subframe intended for the BS from subframes.

An RF switch 2107 switches the signals to be sent or received from MS, RS1 and RS2 to a transmitter 2101 and a receiver 2103 under the control of a synchronizer 2105.

The synchronizer 2105 controls the timing of the transmission and reception when the BS communicates with the MS and the lower RS in accordance with the frame structure.

The structure of RS1 will be described with reference to FIG.

21, RS1 comprises a transmitter 2101, a receiver 2103, a synchronizer 2105, and an RF switch 2107.

The transmitter 2101 has a frame generator 2109, a resource mapper 2111, a modulator 2113, and a DAC 2115.

During operation, the frame generator 2109 generates a DL subframe to send synchronization channels, control channels, and traffic packets to the MS and lower RS within the coverage area RS1 under the control of the synchronizer 2105. In particular, the frame generator 2109 provides a synchronization channel for the MS at the beginning of the subframe for the MS and a synchronization channel for the lower RS at the end of the subframe for the lower RS in the DL subframe.

A frame generator 2109 also forms a UL subframe for communication with a BS or upper RS.

Resource mapper 2111 displays subframes received from frame generator 2109 in packets for communication links corresponding to subframes.

Modulator 2113 modulates the mapped subframes in a predetermined modulation scheme.

The DAC 2115 converts the modulated digital signal into an analog signal and provides an analog signal for the RF switch 2107.

The receiver 2103 comprises an ADC 2117, a demodulator 2119, a resource recovery device 2121, and a frame allocation device 2123.

The ADC 2117 converts the analog signal received through the radio frequency switch 2107 into a digital signal. Demodulator 2119 demodulates the digital signal in a predetermined demodulation scheme.

Resource recovery device 2121 extracts subframes from packets transmitted over a communication line received from a demodulator. A subframe allocator 2123 extracts a subframe intended for the BS from subframes.

An RF switch 2107 switches the signals to be sent or received from MS, RS1 and RS2 to a transmitter 2101 and a receiver 2103 under the control of a synchronizer 2105.

The synchronizer 2105 controls the timing of the transmission and reception when the BS communicates with the MS, lower RS of the upper RS in accordance with the frame structure.

As described above, the BWA multi-link relay communication system provides synchronization channels for MS and RS stations. Therefore, RSs facilitate cell search and synchronization. Also, time multiplexing between relay service and direct service inside the cell eliminates interference from neighboring stations between them.

Although the invention has been shown and described with reference to some preferred options for its implementation, specialists in this field of technology should be clear that it can be made various changes in form and in detail, without departing from the essence and scope of the invention defined by the attached claims .

Claims (31)

1. Implemented by a base station (BS), a method for providing communication using a relay service in a wireless communication system, comprising the steps of:
allocating resources for the first period and the second period of the subframe, the first period being designed to communicate with at least one of the mobile station (MS) and the secondary relay station (RS), which does not provide a synchronization channel, and the second period is intended to communicate with the primary RS which provides a synchronization channel;
contact this at least one of the MS and the secondary RS in the first period of the subframe and
bind to the primary RS in the second period of the subframe. 2. The method according to claim 1, in which the durations of the first period and the second period of the subframe are constant or dynamically changing in accordance with the channel environment. 3. The method according to claim 1, wherein the subframe is a downlink subframe, wherein the communication in a first period comprises providing a synchronization channel at the beginning of a first period in a downlink subframe and the communication in a second period comprises providing a synchronization channel at the end of a second period in a downlink subframe communication lines. 4. The method according to claim 1, wherein the subframe is an uplink subframe, wherein the communication in the first period comprises providing a ranking channel at the beginning of the first period in the uplink subframe and the communication in the second period comprises providing a ranking channel at the end of the second period in the subframe uplink communication. 5. The method according to claim 1, in which the first period and the second period are distinguished by time division or frequency division. 6. The method according to claim 1, in which, if RS is a multi-link RS, when allocating resources, the second period is divided into many periods and resources are distributed over this many periods. 7. The method implemented by the relay station (RS), which provides a synchronization channel in a wireless communication system, and designed to provide communication using a relay service, the method comprises the steps of:
set the first period and the second period according to the control information received from the upper node, the first period is designed to communicate with a mobile station (MS), and the second period is designed to communicate with at least one of the upper node and the lower RS;
contact MS in the first period and
associated with this at least one of the upper node and the lower RS in the second period. 8. The method according to claim 7, in which the durations of the first period and the second period are constant or dynamically changing according to the channel environment. 9. The method according to claim 1, in which the first period and the second period are distinguished by time division or frequency division. 10. The method according to claim 7, in which the upper node is a base station (BS) or upper RS. 11. The method according to claim 7, further comprising the step of communicating with the RS, which does not provide a synchronization channel, in the first period. 12. The method according to claim 7, in which if the multi-link relay communication system with the BWA overlaps at least three links, the communication in the second period comprises the steps of:
checking segmentation information of the second period according to management information;
bind to the lower RS in the first zone of the second period and
contact the upper node in the second zone of the second period. 13. The method according to item 12, in which when communicating in the first zone of the second period, a synchronization channel is provided at the end of the first zone. 14. The method according to claim 7, in which if the multi-link relay communication system with the BWA overlaps at least three links, the communication in the second period comprises the steps of:
checking segmentation information of the second period according to management information;
contact the upper node in the first zone of the second period and
bind to the lower RS in the second zone of the second period. 15. The method according to 14, in which when communicating in the second zone of the second period, a synchronization channel is provided at the end of the second zone. 16. The method implemented by the relay station (RS), which does not provide a synchronization channel in a wireless communication system, and designed to provide communication using a relay service, the method comprises the steps of:
set the first period and the second period according to the control information received from the upper node, the first period is designed to communicate with the upper node, and the second period is intended to communicate with a mobile station (MS);
bind to the top node in the first period and
contact MS in the second period. 17. The method according to clause 16, in which the durations of the first period and the second period are constant or dynamically changing according to the channel environment. 18. The method according to clause 16, in which the first period and the second period are distinguished by time division or frequency division. 19. The method according to clause 16, in which the upper node is a base station (BS) or upper RS. 20. The device is a base station (BS) for communication using relay services in a wireless communication system, comprising:
a synchronizer for providing a synchronization signal for transmission and reception in accordance with a subframe structure in which a first period and a second period are determined, the first period being for communicating with at least one of the mobile station (MS) and the secondary relay station (RS), which does not provide a synchronization channel, and the second period is intended for communication with the primary RS, which provides a synchronization channel;
a transmitter for generating a first period signal or a second period signal in accordance with the clock signal and for transmitting the generated signal and
a receiver for receiving a signal of the first period or a signal of the second period in accordance with the synchronization signal and to restore the received signal. 21. The device according to claim 20, in which the transmitter generates a signal for said at least one of the MS and the secondary RS and transmits the generated signal to this at least one of the MS and the secondary RS in the first period and generates a signal for the primary RS and transmits the generated signal in the primary RS in the second period. 22. The device according to claim 20, in which the transmitter transmits a synchronization channel at the beginning of the first period and a synchronization channel at the end of the second period. 23. The device according to claim 20, in which the receiver receives a signal from the at least MS and secondary RS in the first period and receives a signal from the primary RS in the second period. 24. The device of the relay station (RS), which provides a synchronization channel in a wireless communication system for communication using a relay service, comprising:
a synchronizer for providing a synchronization signal for transmission and reception in accordance with a subframe structure in which a first period and a second period are determined, the first period being for communicating with at least one of the mobile station (MS) and the secondary RS, which does not provide a synchronization channel , and the second period is intended for communication with the upper node;
a transmitter for generating a first period signal or a second period signal in accordance with the clock signal and for transmitting the generated signal and
a receiver for receiving a signal of the first period or a signal of the second period in accordance with the synchronization signal and to restore the received signal. 25. The device according to paragraph 24, in which the transmitter generates a signal for said at least one of the MS and the secondary RS and transmits the generated signal to this at least one of the MS and the secondary RS in the first period of the uplink subframe and generates a signal for the upper node and transmits the generated signal to the upper node in the second period of the uplink subframe. 26. The apparatus of claim 24, wherein the receiver receives a signal from said at least one of the MS and the secondary RS in a first period of a downlink subframe and receives a signal from a top node in a second period of a downlink subframe. 27. The device according to paragraph 24, in which the upper node is a base station (BS) or upper RS. 28. The device is a relay station (RS), which does not provide a synchronization channel in a wireless communication system, for communication using a relay service, comprising:
a synchronizer for providing a synchronization signal for transmission and reception in accordance with the structure of a subframe in which a first period and a second period are defined, the first period being for communication with the upper node and the second period is for communicating with a mobile station (MS);
a transmitter for generating a first period signal or a second period signal in accordance with the clock signal and for transmitting the generated signal and
a receiver for receiving a signal of the first period or a signal of the second period in accordance with the synchronization signal and to restore the received signal. 29. The device according to claim 28, wherein the transmitter generates a signal for the upper node and transmits the generated signal to the upper node in the first period of the uplink subframe and generates a signal for the upper node and transmits the generated signal to the upper node in the second period of the downlink subframe . 30. The apparatus of claim 28, wherein the receiver receives a signal from an upper node in a first period of a downlink subframe and receives a signal from an MS in a second period of an uplink subframe. 31. The device according to p, in which the upper node is a base station (BS) or upper RS.

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