KR20070119246A - Method for generating a temporary identifier of a mobile station for resource allocation and transmitting/receiving apparatus and method of resource allocation information using the same - Google Patents

Abstract

A temporary identifier generation method of a mobile terminal for resource allocation in a mobile communication system, a resource allocation information transceiving device using the method, and a method thereof are provided to reduce the number of requested bits of an identifier of a terminal allocated with a lot of resources, thereby more saving an amount of data of resource allocation information. Plural nodes are generated according to each node identifier for indicating plural mobile terminals, and the generated nodes are arranged on the basis of frequency information of resource allocation(501,503). At least one internal node which has two nodes having the smallest frequency information values as child nodes is generated, and frequency information of the internal nodes is calculated(505,507). Until the at least one internal node becomes one route node, nodes which include the internal nodes are repeatedly arranged according to the frequency information except the child nodes(509). A path which reaches nodes located at an end portion from the route node is configured as binary information in a tree structure of the generated nodes, to generate temporary identifiers(511-517).

Description

TECHNICAL FIELD OF GENERATING IDENTIFIER OF A MOBILE STATION FOR RESOURCE ALLOCATION AND TRANSMITTING / RECEIVING APPARATUS AND METHOD OF RESOURCE ALLOCATION INFORMATION USING THE SAME}

1 illustrates an example of resources allocated to terminals in a time and frequency domain in a typical OFDM system

2 is a diagram illustrating an example of a temporary identifier of a terminal assigned when resource allocation in a conventional mobile communication system;

3A and 3B illustrate a process of generating a temporary identifier for resource allocation in a mobile communication system according to an embodiment of the present invention.

4 is a diagram illustrating a method of allocating a temporary identifier for each mobile terminal using a binary tree generated according to the embodiments of FIGS. 3A and 3B.

5 is a flowchart illustrating a process of generating a temporary identifier in a base station according to an embodiment of the present invention.

6 is a diagram illustrating an example of configuration of resource allocation information according to an embodiment of the present invention.

7 is a block diagram illustrating a configuration of a transmitter 700 of a base station for transmitting resource allocation information according to an embodiment of the present invention.

8 is a block diagram illustrating a configuration of a receiver 800 of a mobile terminal receiving resource allocation information according to an exemplary embodiment of the present invention.

The present invention relates to a method and apparatus for resource allocation of a terminal in a mobile communication system, and in particular, to a method of generating a temporary identifier of a mobile terminal capable of reducing the amount of data of resource allocation information, and an apparatus and method for transmitting and receiving resource allocation information using the same. will be.

In general, mobile communication systems have been developed based on voice communication. The mobile communication system is currently providing a broadband data service capable of transmitting a large amount of digital data such as an e-mail or a still image, as well as a video to a mobile terminal as well as a general voice service due to the rapid development of users' demands and technologies. have. In such a mobile communication system, a base station performs scheduling to allocate resources to a plurality of terminals in a service area to determine which resource to allocate to a terminal, and transmits resource allocation information of each terminal through a control channel. Here, the resource may vary depending on the type of mobile communication system. For example, a resource in a code division multiple access (CDMA) system may be a code resource such as a Walsh code, a resource in a frequency division multiple access (FDMA) system may be a frequency band resource, and orthogonal frequency A resource in a division multiple access system may be a sub-carrier resource, and a resource in a time division multiple access (TDMA) system may be a time slot, that is, a time resource. The subcarrier resources are included in frequency band resources. Therefore, in the following description, a resource refers to a combination or part of the code, frequency, and time according to the type of system.

On the other hand, orthogonal frequency division multiplexing (OFDM), which is suitable for a broadcast service capable of transmitting a large amount of packet data to a large number of users, has been actively researched and utilized in a wireless communication system. The OFDM method is a method for transmitting packet data using a multi-carrier, and the OFDM method converts a serially input symbol string into a parallel signal, and converts each of the parallel signals into orthogonality. It is a type of multi-carrier modulation (MCM) that modulates and transmits a plurality of sub-carriers, that is, a plurality of sub-carrier channels.

Hereinafter, a resource allocation scheme for a mobile terminal will be described, for example, in an OFDM system.

First, FIG. 1 illustrates an example of resources allocated to terminals in a time and frequency domain in a typical OFDM system. In a typical OFDM system, since one modulation symbol (for example, QPSK or 16 QAM, etc.) is generally transmitted through one subcarrier, the subcarrier in an OFDM system is a basic resource allocated to terminals. have. In Figure 1 the horizontal axis represents the time axis and the vertical axis represents the frequency axis. In FIG. 1, reference numeral 101 denotes one subcarrier, and reference numeral 102 denotes one OFDM symbol. As shown in FIG. 1, one OFDM symbol is typically composed of a plurality of subcarriers. In addition, in the conventional OFDM system, a plurality of OFDM symbols are grouped into one and configured as a basic transmission unit, as indicated by reference numeral 103. A basic transmission unit composed of the plurality of OFDM symbols will be referred to as a transmission time interval (TTI).

As shown in FIG. 1, a plurality of OFDM symbols are transmitted in one TTI. The smallest rectangle shown in FIG. 1 will be referred to as a "time-frequency bin". Thus, one TTI includes a plurality of "time-frequency bins". On the other hand, in a conventional OFDM system, the one TTI is generally composed of a plurality of physical channels.

Here, the physical channel refers to channels for transmitting various kinds of information, such as a paging channel, a packet data channel, a packet data control channel, and a reverse scheduling channel, which are required in a conventional mobile communication system. For example, referring to FIG. 1, in one TTI, some resources, that is, some "time-frequency bins" are used for a paging channel, some resources are used as a common control channel for providing system information, and some resources are used. It is used as a packet data channel for transmitting user data, and some resources are also used as a packet data control channel for transmitting control information for demodulation of the packet data channel. Although not mentioned above, it should be noted that other physical channels may exist for other purposes.

As described above, the conventional OFDM-based wireless communication system has two-dimensional resources in the time and frequency domain, and these time-frequency two-dimensional resources may be divided into small chunks and allocated to a plurality of terminals. In this case, since the amount of resources required for different terminals are different, it should be efficiently promised and indicated between the transceivers of the resources allocated to each terminal, that is, the time-frequency bin. For example, if there are 5000 time-frequency bins in one TTI, the transmitter assigns 1 to 100 time-frequency bins to the first receiver and 101 to 600 time-frequency bins to the second receiver. It should be possible to effectively convey to the receiver that it has been allocated.

To this end, when indicating one allocated resource as described above, a method of individually indicating one subcarrier such as a second subcarrier in a few OFDM symbols is very inefficient. This is because, in such a method, too much information is required to inform which terminal is assigned what resource.

In order to solve this problem, a channel is formed by grouping two-dimensional resources in one TTI, that is, a plurality of time-frequency bins, adjacent resources among two-dimensional resources in the TTI, and indicating this. The allocated resources can be indicated by using a resources channel (DRCH) method and a distributed resources channel (DRCH) method of configuring a channel by combining resources separated from each other with a specific rule among two-dimensional resources in a TTI. .

The OFDM system may allocate the DRCH and LRCH data channels thus configured to the terminals through a specific data control channel received by all mobile terminals. For example, an identifier of each terminal (hereinafter referred to as a "terminal identifier") and a time-frequency resource such as DRCH or LRCH allocated to the terminal are allocated to all the terminals by repeating the method of writing the common data control channel. It can point to resources that have been created. In this method, n bits are required to indicate a specific time-frequency resource, and a size of demodulation and coding information (MCS) for receiving a data channel is m bits, and one terminal identifier is k bits. In case of, resource allocation information corresponding to the number X (k + n + m) of the terminal should be transmitted through a common data control channel. For example, if the number of terminals is 40, n is 8 bits, m is 4 bits, and k is 10 bits, a total of 40X (10 + 8 + 4), that is, 880 bits is used to transmit resource allocation information for 40 terminals. Information shall be transmitted through a common control channel. However, since a common data control channel must be received from a terminal far from the transmitter, there is a problem in carrying such a large amount of resource allocation information.

In order to solve such a problem, in the related art, in addition to a long terminal identifier, mobile terminals allocated resources in a specific slot are given a short length identifier (hereinafter referred to as a "temporary identifier") that is valid only in the slot. A proposal was made. That is, a terminal allocated with a resource in a specific slot has a relatively small number of terminals allocated with a resource in that slot instead of a long length (eg, 10-bit) terminal identifier that distinguishes the terminal from all other terminals. It is possible to give a temporary identifier of shorter length (eg 2 bits) that distinguishes it from other terminals. In addition, various resource allocation patterns may be indicated in a shorter length through a method of writing a temporary identifier of a terminal to which the resource is allocated to all resource units.

FIG. 2 is a diagram illustrating an example of a temporary identifier of a terminal assigned when resource allocation in a conventional mobile communication system.

FIG. 2 configures resource allocation information 201 according to the prior art, for example, when six units of resource units 203 are allocated to three terminals identified by a temporary identifier, “01, 10, 11”. An example is shown. First, the base station lists, in a row, temporary identifiers (eg, Short MAC IDs) of terminals allocated resources in a corresponding slot through a data control channel. In this case, the length of the temporary identifier is determined according to the number of terminals, and if the number of terminals ^is greater than or equal to 2 ^(n-1) and smaller than 2 ⁿ , an identifier of n bits is used. In the example of FIG. 2, since the number of terminals allocated with resources is three, a 2-bit temporary identifier is used.

In this case, the temporary identifiers received by the respective terminals may be a temporary identifier having a value of "00" to indicate a resource not allocated to any terminal (hereinafter, referred to as a temporary identifier used to indicate a resource not allocated to any terminal ". NULL identifier ". In addition, a temporary identifier having values of" 01 "," 10 ", and" 11 "is assigned in the order of the temporary identifiers listed in the data control channel. Thereafter, for each of the six resource units 203, resources are allocated by assigning temporary identifiers of terminals that are allocated the resources or by assigning a value of NULL identifier "00", which means that the resource is not allocated to any terminals. By configuring the information 201 and transmitting the resource allocation information 201 through the data control channel, the base station can inform each terminal of what resources have been allocated.

As described above, when the temporary identifier is used when allocating resources, the amount of data of the resource allocation information required can be efficiently reduced. However, in a system having a large number of resource units to be allocated and a number of terminals to which resources are allocated, such as an OFDM system, data control is performed. Since the amount of resource allocation information to be transmitted through the channel is considerable, a more efficient temporary identifier allocation method is desired. In addition, according to the above-described prior art, the identifier of a terminal to which resources are allocated a lot and the identifier of a terminal to which resources are allocated a little have the same number of bits. Therefore, if the required number of bits of the identifier of the terminal that is allocated a lot of resources can be reduced, the amount of data of the resource allocation information can be further reduced.

The present invention provides a method of generating a temporary identifier for a mobile terminal that can reduce the amount of data of resource allocation information transmitted when allocating resources in a mobile communication system.

In addition, the present invention provides an apparatus and method for transmitting and receiving resource allocation information that can reduce the amount of data required for resource allocation information transmitted when allocating resources in a mobile communication system.

In a mobile communication system according to the present invention, a method for generating a temporary identifier for resource allocation to a plurality of mobile terminals by a base station generates a plurality of nodes corresponding to each node identifier indicating the plurality of mobile terminals and allocates the resources. A first process of sorting the generated nodes based on the frequency information of the at least one node, and generating at least one internal node having two nodes having the smallest value of the frequency information among the sorted nodes as child nodes; A second step of calculating node frequency information, and reordering nodes including the internal nodes except the child nodes according to the frequency information until the at least one internal node becomes one root node; And a root node in a tree structure of nodes created according to a third process and the first to third processes. Since by configuring the path leading to the node located at the ends to the binary information comprises a fourth step of generating the temporary identification.

In addition, the base station apparatus of the mobile communication system for transmitting the resource allocation information for the plurality of mobile terminals according to the present invention is based on the frequency information of the resource allocation for each of the plurality of mobile terminals for the plurality of mobile terminals A controller for generating temporary identifiers, generating resource allocation information including the generated temporary identifiers, and generating control information for decrypting the resource allocation information, the resource allocation information and the control generated through the controller The transmitter includes a transmitter for transmitting information to the wireless network at every resource allocation.

In addition, the method for transmitting the resource allocation information for a plurality of mobile terminals in the base station of the mobile communication system according to the present invention to the plurality of mobile terminals based on the frequency information of the resource allocation for each of the plurality of mobile terminals Generating temporary identifiers for the resource; generating resource allocation information including the generated temporary identifiers; and control information for reading the resource allocation information; and for each resource allocation, the resource allocation information and the control information. The process includes transmitting to a wireless network.

In addition, the mobile terminal device receiving resource allocation information from the base station of the mobile communication system according to the present invention includes the plurality of mobile units generated based on the frequency information of the resource allocation for each of the plurality of mobile terminals in the service area of the base station. A receiver for receiving resource allocation information including temporary identifiers for terminals and control information for reading the resource allocation information through a control channel, a control channel decoder for decoding the received control information and resource allocation information, respectively; And a controller configured to read the resource allocation information based on the control information and to allocate a resource.

In addition, the method for receiving the resource allocation information transmitted from the base station by the mobile terminal of the mobile communication system according to the present invention is generated based on the frequency information of the resource allocation for each of the plurality of mobile terminals in the service area of the base station Receiving resource allocation information including temporary identifiers for a plurality of mobile terminals and control information for reading the resource allocation information through a control channel, and decoding the received control information and resource allocation information, respectively And reading the resource allocation information based on the control information and allocating a resource.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

First, the basic concept of the present invention will be described. According to the present invention, each terminal has a different length but is distinguishable from each other based on information such as the number of terminals and the frequency with which each terminal is allocated resources (Short MAC ID). We propose a way to allocate. To this end, the present invention proposes a method of allocating a temporary identifier of a short length to a terminal having a high resource allocation frequency, and assigning a temporary identifier of a length equal to or longer than a previously allocated temporary identifier to a terminal having a low resource allocation frequency.

That is, in the related art, when allocating resources to five terminals, for example, six short temporary identifiers including a NULL identifier are required, and the base station has a 3-bit NULL identifier "000" and a 3-bit terminal to each terminal. Temporary identifiers "001", "010", "011", "100", and "101" are assigned. However, in the method proposed in the present invention, a NULL identifier and temporary identifiers having different lengths for five terminals, for example, "10", "11", "000", "001", "010", and "011" You can use the temporary identifier of. Of the five temporary identifiers, the base station may allocate a temporary identifier of a short length in order of a NULL identifier and a frequency of resource allocation among the terminals. For example, if there are more NULL identifiers in resource allocation information than other temporary identifiers, using shorter temporary identifiers "00" or "01" as NULL identifiers can help reduce the amount of data in the resource allocation information. .

In the scheme proposed by the present invention, a base station for generating and transmitting a temporary identifier having a different length based on a resource allocation frequency and a mobile terminal receiving the generated temporary identifier and allocating resources are, for example, promised between the base station and the mobile terminal. Use prefix-free code. Temporary identifiers having the feature of the prefix precode have the feature that no temporary identifier is a prefix of another temporary identifier. That is, when five prefix identifiers, '00', '01', '10', '110', and '111' are configured using a certain prefix code, no temporary identifier is a prefix of another temporary identifier. For example, if there is a temporary identifier '00', there is no other temporary identifier consisting of '00x', and this property holds true for the other four temporary identifiers as well.

In addition, in the scheme proposed by the present invention, the base station and the mobile station use the frequency of resource allocation to generate temporary identifiers of different lengths. In this way, a shorter length code may be allocated to a symbol having a high resource allocation frequency, that is, a terminal having a high resource allocation frequency, thereby minimizing the size of the coded result. Accordingly, the present invention assigns a temporary identifier of a short length to a mobile terminal allocated with more resources, and assigns a temporary identifier of a long length to a mobile terminal assigned to less resources.

Hereinafter, a method of generating a temporary identifier according to the present invention will be described in detail.

An embodiment of the method for generating a temporary identifier by the base station in the present invention is as follows. First, the base station generates leaf nodes by adding the number of temporary identifiers required in a specific slot, that is, the number of mobile terminals allocated resources and the NULL identifier, and assigns the identifier and NULL identifier of each mobile terminal to each terminal node. Random assignment The terminal nodes generated in this way should have resource allocation frequency number (hereinafter, frequency information) for the corresponding mobile terminal, terminal identifier or NULL identifier (hereinafter, referred to as "node identifier") information and frequency information allocated to the terminal node. .

The NULL identifier is assumed to have a value of identifier "0" for convenience. The base station that generates the end nodes generates an ordered list by sorting all the end nodes in ascending order based on the frequency information stored by each end node. In the sorting, if the frequency information stored in two or more nodes is the same, the nodes having the small node identifier value are arranged in front.

 The base station then selects the two nodes with the lowest frequency of resource allocation among the nodes sorted in ascending order, that is, the first and second nodes in the sort list, and selects the first node as the child node on the left and the second node. Create a new parent node, which is the child node on the right. For example, if the end nodes are arranged such as {frequency 1 (terminal 2), frequency 2 (terminal 1), frequency 2 (terminal 3), frequency 3 (terminal 4} based on the frequency information, When selecting two nodes with the lowest allocation frequency, {frequency 1 (terminal 2) and frequency 2 (terminal 1)} can be selected.

The parent node has its frequency information plus the frequency of the child node on the left and the child node on the right, and the smaller value of the node identifiers of the child node on the left and the child node on the right is the node identifier information of the parent node. Used as.

The base station configuring the parent node in the above manner excludes the two selected child nodes from the sort list and newly sorts the nodes in ascending order according to the frequency information stored by each node for the remaining nodes in the parent node and the sort list. Create a sort list. In the sorting, if the frequency information stored by the two or more nodes is the same, the high-priority nodes are arranged in front according to the following conditions.

Condition 1. The node with the lowest height (depth) of the tree rooted at that node among nodes of the same frequency.

Condition 2. If there are multiple nodes that satisfy condition 1, the node with the smallest node identifier stored in each node

The base station repeats the process of selecting and combining two nodes from the front of the sort list in the above manner until only one node included in the sort list remains. If there is only one node included in the sort list, the binary tree rooted at that node becomes the temporary identifier tree completed according to the present invention. In the binary tree thus generated, a temporary identifier is composed of binary information represented by each of the end nodes. For example, the base station repeats '0' when moving to the right child node and '1' when moving to the left child node from the root node to the end node, and temporarily converts the generated binary number until it reaches the end node. Used as an identifier.

3A and 3B illustrate a process of generating a temporary identifier for allocating resources in a mobile communication system according to an embodiment of the present invention. In particular, FIG. 3A and FIG. 3B are a diagram illustrating allocating a temporary identifier to terminals ID1 to ID5 and a NULL identifier (represented by ID0). The process is shown. In the example of FIGS. 3A and 3B, among a total of 12 resources, the terminal ID1 has a frequency of 1 allocated, the terminal ID2 has a frequency of 4, the terminal ID3 has a frequency of 3, and the terminal ID4 and the terminal ID5 have a frequency of 1 Assume that you have been assigned In addition, it is assumed that two of the 12 resources are not allocated and thus need to transmit two NULL identifiers (ID0). In addition, the steps 1 to 6 of generating a temporary identifier in FIGS. 3A and 3B are performed at the base station.

In FIG. 3A, the base station generates end nodes 301 to 311 corresponding to each terminal identifier and a NULL identifier in step 1, and arranges the end nodes 301 to 311 in ascending order according to the frequency as described above. do. At this time, the terminal nodes having the same frequency are sorted in ascending order based on the node identifier as described above. Therefore, a node with a small node identifier is located in front of a node with a large node identifier.

Thereafter, the base station creates a new parent node 313 in step 2 and selects ID1 node 301 and ID4 node 303, which are the first and second nodes on the left side, among the nodes arranged in step 1, and the parent node ( 313) to child nodes. At this time, the first node among the nodes arranged in Step 1 becomes the left child node of the parent node and the second node becomes the right child node. In Step 2, the parent node 313 has a frequency (1 + 1) obtained by adding the frequencies of the left child node 301 and the right child node 303 as its frequency information, and the left child node 301 and the right child. The smaller value of the node identifier of the node 303 is used as the node identifier of the parent node 313. The newly generated parent node 313 has a frequency of 2, which is the sum of the frequencies of the child nodes 301 and 303, and has ID1, which is a smaller value among the node identifiers of the two child nodes 301 and 303, as an identifier. Thereafter, the base station removes the previously selected two child nodes 301 and 303 from the sort list, and instead constructs a new sort list including the newly created parent node 313. As described above, when two nodes 307 and 313 store the same frequency when constructing a new sort list, the node having the lowest height (depth) of the tree rooted by the node among the nodes of the same frequency is preceded. Among the nodes of the same height and position, the sort list is constructed so that the node having the smallest node identifier is located in front. In FIG. 3A, the figure of Step 2 shows a sorting list constructed in the manner described above.

Subsequently, in step 3 of FIG. 3a, the base station again selects the first and second nodes ID5 node 305 and ID0 node 307 of the sort list of step 2 to create a new parent node 315 and the process described in step 2 above. Performs an operation of constructing a new sort list according to the method. The figure in Step 3 shows the sort list constructed after combining the two nodes 305 and 307 in Step 2.

Subsequently, in step 4 of FIG. 3A, the base station again selects Min ID1 node 313 and ID3 node 309, which are the first and second nodes of the sort list of Step 3, to create a new parent node 317, and then creates a new sort list. Perform the operation of configuring. The figure in Step 4 shows the sorted list constructed after combining the two nodes 313 and 309 in Step 3.

Subsequently, in step 5 of FIG. 3B, the base station selects Min ID0 node 315 and ID2 node 311, which are the first and second nodes of the sort list of Step 4 again, to create a new parent node 319, and then creates a new sort list. Perform the operation of configuring. The figure of Step 5 shows the sort list constructed after combining the two nodes 315 and 311 in Step 4.

Finally, in step 6 of FIG. 3b, the base station again selects Min ID1 node 317 and Min ID0 node 319, which are the first and second nodes of the sort list of Step 5, to create a new parent node 321. Performs an operation of constructing a sort list. The figure of Step 6 shows the sort list constructed after combining the two nodes 317 and 319 in Step 5.

The base station may construct a tree rooted at one node by performing the operations of Steps 1 to 6, and may use a binary number provided from the tree structure as a temporary identifier of each mobile terminal.

4 is a diagram illustrating a method of allocating a temporary identifier for each mobile terminal using a binary tree generated according to the embodiments of FIGS. 3A and 3B.

In FIG. 4, when the base station moves from the parent node to the right child node from the root node 321 to the specific end node 301, 303, 309, 305, 307, 311, the base station gives '0' and the left child When moving to a node, the operation of giving '1' is repeated, and the generated binary number is used as a temporary identifier of the mobile terminal corresponding to the corresponding end node until it reaches a specific end node from the root node.

In the embodiment of FIG. 4, the node 301 of the terminal ID1 is '000', the node 303 of the terminal ID4 is '001', the node 309 of the ID3 terminal is '01', and the node 305 of the ID5 terminal is located at the node 305 of the ID5 terminal. '100', a temporary identifier of '101' and a node 311 '11' of the ID2 terminal are allocated to the ID0 node 307 which is a NULL identifier and used as a temporary identifier of the corresponding terminal.

5 is a flowchart illustrating a process of generating a temporary identifier in a base station according to an embodiment of the present invention.

In FIG. 5, the base station generates leaf nodes as many as necessary temporary identifiers, including a terminal identifier and a NULL identifier, in step 501. The generation information of the end nodes generated in step 501 includes a frequency number of resource allocation for the corresponding mobile terminal and a node identifier (ie, a terminal identifier or a NULL identifier) assigned to the end node. It is assumed that the NULL identifier has identifier 0 for convenience. In step 501, the base station that has created the end nodes generates the sort list by sorting the end nodes in ascending order according to the frequency information stored in each end node. In the sorting process, when two nodes store the same frequency, the nodes having the smallest node identifier are arranged in front.

 Subsequently, in step 505, the base station creates a new internal node according to the method described with reference to FIGS. 3a and 3b to make the parent node of the first and second nodes of the sort list. In this case, a first node of the selected two nodes becomes a left child node of the parent node, and a second node becomes a right child node. In step 507, the base station sets the frequency value of the generated internal node plus the frequency of the left child node and the right child node, and uses the smaller value of the identifiers of the left child node and the right child node as the node identifier information. .

The base station that has generated the internal node removes the first and second nodes from the alignment list in step 509 and inserts the internal node created in step 507 instead. If the number of nodes remaining in the sort list is not one in step 511, the base station proceeds to step 513 and rearranges the sort list in ascending order again according to the frequency. If nodes of the same frequency exist in this reordering process, the nodes of the same frequency that have the lowest root height (depth) of the tree rooted in the node have priority, and nodes of the same frequency and same height (depth) If present, reorder the node whose stored node identifier is small. After performing step 513, the base station proceeds to step 505 and repeats the process of selecting and adding two nodes of the sort list until only one node included in the sort list remains.

When the number of nodes remaining in the sort list is one according to the operations of steps 505 to 513, the base station determines a temporary identifier tree rooted at the last node in step 515. In this temporary identifier tree, the binary number represented by each of the end nodes constitutes the temporary identifier. That is, in step 517, the base station repeats the operation of granting '0' to the right child node and moving to the left child node from the root node to the specific end node according to the method described with reference to FIG. 4. Then, the binary number generated until arriving at a specific leaf node is used as a temporary identifier of the mobile terminal corresponding to the corresponding end node. In the present invention, the base station generates a temporary identifier for each mobile terminal to which resources are allocated according to the above-described method, and then allocates the temporary identifier occupying the resource to each resource according to a specific rule. Assignment information can be configured.

That is, the base station may configure resource allocation information by using a method of sequentially ordering temporary identifiers occupying the corresponding resources for resources having an order relationship. For example, as shown in the example of FIG. 4, a total of six temporary identifiers generated by the base station, '01', '11', '000', '001', '100', and '101' When allocated using the BS, the base station of the present invention may generate resource allocation information using a binary sequence such as '11011000111111010000110111001' as illustrated in FIG. 6.

That is, the resource allocation information '11011000111111010000110111001' is assigned to the terminal ID2 having the first resource among the 12 resources, the temporary identifier '11', the terminal ID3 having the second resource '01', and the third resource being ' '101' to the NULL identifier representing the terminal ID5 of 100 ', the terminal ID3 of the fourth resource' 01 ', the terminal ID2 of the fifth and sixth resource' 11 ', and the seventh unallocated resource. , Terminal ID1 with the eighth resource '000', terminal ID3 with the ninth resource '01', '101' to the NULL identifier indicating the unallocated tenth resource, and '11' the eleventh resource Terminal ID2 and the twelfth resource are allocated to terminal ID4 that is '001'.

In the present invention, all mobile terminals assigned resources through the above process and the base station that generates the temporary identifier to the NULL identifier transmit resource allocation information including the generated temporary identifier through the data control channel.

Table 1 below shows an embodiment of the structure of a data control channel transmitted in a specific slot according to the present invention. In the following embodiment, it is assumed that the total amount of resources allocated to the mobile station in the corresponding slot is 16. However, the number of these resources may vary depending on the situation, and accordingly, the number of bits in Table 1 below may also change. .

In Table 1, the NumNullIncluded field is a field indicating whether frequency information of a NULL identifier is included in the data control channel. The NumNull field is a field indicating how many resources are not allocated to the terminal among 16 resources allocated in this slot, that is, frequency information of a NULL identifier.

In Table 1, the MACID field is a field indicating a terminal identifier of a mobile terminal to which resources have been allocated, and the frequency field indicates how many resources are allocated in a corresponding slot by the mobile terminal corresponding to the terminal identifier. Field to represent. The MCSLecelInd field is a field indicating demodulation and encoding information (MCS) of a packet transmitted through a resource allocated to a mobile terminal indicated by the MACID field. The resource allocation block composed of the MACID, Frequency, and MCSLevelInd fields is included a plurality of times until the total number of resources is equal to the value of the NumNull field and the value of the Frequency fields. For example, if the value of the NumNull field is 3 and the value of the first Frequency is 4, then the second resource allocation block is needed because the sum of the two values is 7, which is less than 16, the total number of resources. If the value of the second frequency is 5, the third resource allocation block is necessary because the number of resources occupied by the null and the UE is 12, which is smaller than the total number of resources. If the value of the third frequency is 4, the number of resources occupied by Null and the corresponding mobile terminal is 16, which is equal to 16, which is the total number of resources, and thus no further resource allocation block is included.

In Table 1, the ResourceAssignmentBlock field is a field for transmitting resource allocation information generated according to the present invention. The length of the ResourceAssignmentBlock field is determined by the number and frequency information of the terminal and the generated temporary identifier.

Meanwhile, in the present invention, the mobile terminal receives its own resource allocation in the corresponding slot by using the number of terminal identifiers transmitted through the data control channel, the number and frequency of NULL identifiers, and the resource allocation information according to the present invention. You can see whether it is available and what resources are allocated.

To this end, in the present invention, the mobile terminal receives control information including the number of terminals to which resources are allocated through the data control channel, and the number and frequency information of NULL identifiers. The mobile terminal receiving the control information and the resource allocation information of the present invention can generate a tree of temporary identifiers using the same method as the base station, and determine which temporary identifier is assigned to the mobile terminal. Thereafter, by determining the location of the temporary identifier assigned to the user from the resource allocation information included in the data control channel, it is possible to finally know which resource is allocated to the user.

In the present invention, the method for generating a temporary identifier by the mobile terminal should be the same as that of the base station described with reference to FIG. 5. That is, according to an embodiment of the present invention, the mobile terminal may configure a temporary identifier tree according to the flowchart of FIG. 5.

7 is a block diagram illustrating a configuration of a transmitter 700 of a base station for transmitting resource allocation information according to an embodiment of the present invention.

In FIG. 7, the controller 701 allocates resources for mobile terminals in the downlink using the method of generating a temporary identifier of FIG. 7 and generates resource allocation information therefor. In FIG. 7, the controller 701 includes a scheduler for scheduling resource allocation. In addition, the controller 701 controls / manage not only resource allocation information allocated to each terminal, but also control information such as information on symbol generation and demodulation of a data channel such as an error coding and modulation method for each terminal. The controller 701 uses a scheme proposed by the present invention to generate a short MAC ID that can be distinguished from each other by the terminal according to information such as the number of terminals and the number of resources allocated to each terminal. Can be assigned.

The controller 701 allocates a temporary identifier of a short length to a mobile terminal having a large number of allocated resources by using the scheme proposed by the present invention, and for a terminal having a small number of allocated resources, which is longer than the previously allocated temporary identifier. A data control channel as shown in Table 1 may be configured to allocate temporary identifiers to respective terminals using a method of allocating temporary identifiers of the same length. In addition, the controller 701 controls to transmit control information including the number of terminals to which resources are allocated through the data control channel, and the number and frequency information of NULL identifiers.

In FIG. 7, the symbol generator 703 is a control channel symbol generator 703 ₁ for generating data symbols transmitted through a data control channel for each terminal to which resources are allocated under the control of the controller 701 and data for each terminal. and a data channel symbol generator (703 ₂ ~ 703 _N) for generating a data symbol transmitted over a channel.

In addition, in FIG. 7, the symbol generator 703 may include blocks such as error correction coding, rate matching, interleaver, symbol modulator, and so on, and thus will be omitted. The serial data symbols generated by the symbol generator 703 are input to the serial-to-parallel converter (S / P) 705, converted into parallel signals, and then input to the mapper 707. The mapper 707 serves to map data symbols to actual frequency resources allocated to each terminal according to a predetermined modulation scheme such as QPSK, 16 QAM, and 64 QAM. Data symbols of all terminals mapped to subcarriers which are actual frequency resources through the mapper 707 are converted into time-domain signals by an Inverse Fast Fourier Transfer (IFFT) 709. The time domain signal, which is a parallel signal, is converted into OFDM samples, which are serial signals, by a parallel-to-serial converter (P / S) 711 and input to a cyclic prefix inserter 713. The CP inserter 713 inserts a guard interval for preventing inter-symbol interference (ISI), and the signal of the guard interval generally has a CP form of repeating some of the OFDM samples. The output signal of the CP inserter 713 is transmitted over a wireless channel through the transmit antenna 715.

Hereinafter, a receiver of a mobile terminal receiving resource allocation information transmitted through the transmitter configuration of FIG. 7 and allocating resources allocated thereto will be described.

8 is a block diagram illustrating a configuration of a receiver 800 of a mobile terminal receiving resource allocation information according to an exemplary embodiment of the present invention. In FIG. 8, the received signal including the control information and the resource allocation information of the data control channel received through the receive antenna 801 removes the guard interval signal from the CP remover 803 and uses a serial-to-parallel converter (S / P). 805 is input and converted into a parallel signal. The output signal of the serial-to-parallel converter (S / P) 805 is converted into a frequency signal in a fast Fourier transfer (FFT) and output. Control information and resource allocation information received from the data control channel among the output signals of the FFT 807 are input to the control channel decoder 809 and decoded. The decoded control information and resource allocation information are transmitted to a controller 817, which controls the reception of a data channel according to the control information. The control information includes the number of mobile terminals to which resources are allocated, the number of NULL identifiers, and the frequency information as described above. Therefore, according to the present invention, the controller 817 includes the number of mobile terminals, the number and frequency information of NULL identifiers allocated to resources transmitted through the data control channel in a specific slot, and a temporary identifier generated by the method of FIG. 5. Resource allocation information may be used to determine whether a resource has been allocated to the corresponding slot and what resource has been allocated. That is, the controller 817 generates a tree of temporary identifiers as shown in FIG. 4 by using control information including the number of mobile terminals allocated to the resource, the number of NULL identifiers, and frequency information, and assigns a temporary identifier to itself. Can be determined. In addition, the location of the temporary identifier assigned to the user may be determined using the temporary identifier tree from the resource allocation information included in the data control channel, and finally, it may be known which resource is allocated to the user. Meanwhile, in FIG. 8, the demapper 811 receives the received signal converted from the FFT 807 into a signal in the frequency domain, and uses the control information transferred from the controller 817 to the frequency resource corresponding to the corresponding terminal. Extract the transmitted data. The received signal for the corresponding terminal separated by the demapper 811 is converted into a serial signal by the parallel-to-serial converter 813 and then decoded by the data channel decoder 815. When decoding data, control information received from a data control channel is used. Details thereof will be omitted since they are general contents.

Meanwhile, although the above-described embodiment of the present invention has been described with reference to an OFDM system for convenience, the present invention distinguishes terminals to which resources are allocated using a predetermined identifier, and various mobile communication systems for transmitting resource allocation information including the identifier. Can be applied to

As described above, according to the present invention, a method for generating a temporary identifier for a mobile terminal capable of reducing the amount of data of resource allocation information in a mobile communication system for allocating resources to a plurality of mobile terminals and a device for transmitting and receiving resource allocation information therefor And methods.

In addition, according to the present invention, it is possible to efficiently allocate the forward time-frequency resources to a plurality of mobile terminals in a system using a multiple access scheme based on the OFDM scheme.

Claims (5)

A method for generating a temporary identifier for resource allocation to a plurality of mobile terminals by a base station in a mobile communication system, Generating a plurality of nodes corresponding to each node identifier indicating the plurality of mobile terminals and sorting the generated nodes based on frequency information of the resource allocation; Generating at least one internal node having two nodes having the smallest value of the frequency information among the sorted nodes as child nodes, and calculating frequency information of the internal node; A third step of repeatedly rearranging nodes including the internal nodes except for the child node according to the frequency information until the at least one internal node becomes one root node; Generating a temporary identifier comprising a fourth step of generating the temporary identifier by configuring the path from the root node to the nodes located at the end in the tree structure of the nodes created according to the first to third process with binary information Way. In the base station apparatus of the mobile communication system for transmitting resource allocation information for a plurality of mobile terminals, Generate temporary identifiers for the plurality of mobile terminals based on frequency information of resource allocation for each of the plurality of mobile terminals, generate resource allocation information including the generated temporary identifiers, and generate the resource allocation information A controller for generating control information for decrypting the information; And a transmitter for transmitting the resource allocation information and the control information generated by the controller to a wireless network at every resource allocation. A method for transmitting resource allocation information for a plurality of mobile terminals in a base station of a mobile communication system, Generating temporary identifiers for the plurality of mobile terminals based on frequency information of resource allocation for each of the plurality of mobile terminals; Generating resource allocation information including the generated temporary identifiers and control information for reading the resource allocation information; And transmitting the resource allocation information and the control information to a wireless network for each resource allocation. A mobile terminal apparatus for receiving resource allocation information from a base station of a mobile communication system, Resource allocation information including the temporary identifiers for the plurality of mobile terminals generated based on the frequency information of the resource allocation for each of the plurality of mobile terminals in the service area of the base station for reading the resource allocation information A receiver for receiving control information through a control channel; A control channel decoder for decoding the received control information and resource allocation information, respectively; And a controller configured to read the resource allocation information based on the control information and to allocate a resource. In the method for the mobile terminal of the mobile communication system to receive the resource allocation information transmitted from the base station, Resource allocation information including the temporary identifiers for the plurality of mobile terminals generated based on the frequency information of the resource allocation for each of the plurality of mobile terminals in the service area of the base station for reading the resource allocation information Receiving control information through a control channel; Decoding the received control information and resource allocation information, respectively; Receiving the resource allocation information by reading the resource allocation information based on the control information.

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