Description METHOD FOR ALLOCATING AND ACCESSING RADIO RESOURCES IN OFDMA SYSTEM Technical Field
[1] The present invention relates to an efficient resource allocation method in an orthogonal frequency division multiple access (OFDMA)-based wireless portable Internet system. More specifically, the present invention relates to a resource allocation method for saving power consumption of a subscriber station and reducing overheads and residual resources in an OFDM system. Background Art
[2] The wireless portable Internet system for further supporting mobility of a subscriber station to the wireless data communication system based on fixed access points such as the wireless LAN has recently been developed.
[3] The IEEE 802.16 standard has adopted the OFDMA for a communication method of physical layers.
[4] The OFDMA, which is an OFDM-FDMA communication method precisely, uses a plurality of subcarriers as a plurality of subchannels, and the wireless portable Internet system transmits with the same modulation level and channel coding scheme as a single burst, differing from the OFDM-TDMA system which transmits data to a subscriber station for each time slot. For ease of description, the OFDM-FDMA will be referred to as an OFDMA system hereinafter in an exemplary embodiment of the present invention. The OFDMA system is resistant against the lading generated by multipaths, and supports high data rates.
[5] FIG. 1 shows a single-carrier resource allocation scheme.
[6] As shown, a base station transmits data only to a single mobile station in the same symbol interval in the downlink according to the single carrier method, in which the symbol interval can be represented as a time slot. The base station uses predetermined burst profiles (including combinations of modulation methods and coding schemes) to arrange the burst profiles in the order from the most robust burst profile to the least robust one, and transmits the arranged burst profiles. Therefore, the subscriber station receives the bursts up to its operational burst profile, and ignores subsequent bursts having less robust burst profiles, thus minimizing power consumption caused by not processing the subsequent bursts. The OFDM-TDMA scheme follows the above- described power saving process for the plural carriers.
[7] However, the OFDMA applied to the wireless portable Internet system allows the data to be transmitted to a plurality of subscriber stations in the same symbol period, and hence, the subscriber station must receive undesired bursts even though the received bursts are less robust burst profiles than that of the operational burst profile.
[8] An OFDM communication scheme of the conventional wireless portable Internet system will be described.
[9] FIG. 2 shows a hierarchical diagram of the IEEE 820.16 wireless portable Internet system including a physical layer L10 and media access control (MAC) layers L21, L22, and L23.
[10] The physical layer L10 performs a wireless communication function such as modulation/demodulation, coding/decoding, etc. as performed by a normal physical layer. According to the IEEE 802.16e, the wireless portable Internet system does not have function-specific MAC layers as a wired Internet system, but a single MAC layer in charge of different functions. The MAC layer includes a privacy sublayer L21, a MAC common part sublayer L22, and a service specific convergence sublayer L23.
[11] The service specific convergence sublayer L23 performs payload header suppression and CpS mapping functions in consecutive data communication.
[12] The MAC common part sublayer L22 is the core of the MAC layer which is in charge of system access, bandwidth allocation, connection establishment and maintenance, and C S control. The privacy sublayer L21 performs functions of equipment authentication and security key exchange, and encryption. The device authentication is carried on by the privacy sublayer L21, and the user authentication by an upper layer of the MAC (not illustrated).
[13] FIG. 3 shows a schematic of a connection structure between a base station and a subscriber station in the wireless portable Internet system. A connection is provided between the MAC layers of the subscriber station (SS) and the base station (BS.) The term "connection CI" as used herein does not refer to a physical connection but a logical connection that is defined as a mapping relationship between the MAC peers of the subscriber station SS and the base station BS for traffic transmission of one service flow.
[14] Hence, the parameter/message as defined on the connection CI refers to a function executed between the MAC peers. Actually, the parameter/message is processed into a frame, which is transferred through the physical layer and analyzed so as to enable the MAC layer to execute the function corresponding to the parameter/message.
[15] The frames representing radio resources allocated by the OFDMA scheme include a
downlink sub-frame and an uplink sub-frame.
[16] FIG. 4 shows a frame diagram for resource allocation in a downlink of the conventional OFDMA system.
[17] A downlink sub-frame includes a downlink (DL) frame prefix, MAP information, and a plurality of bursts. In the frame diagram, the ordinate axis represents subchannels comprising orthogonal frequencies while the abscissa axis represents the time-divided symbol axis. The downlink bursts form a 2-dimensional square with respect to the symbol and subchannel axes. The MAP information has common control information including burst profile information, such as modulation and channel coding information, and the offset information, such as subchannel offsets and symbol offsets of burst to be received by the subscriber station.
[18] As to the DL Burst #N, the less the number of N becomes, the more robust burst it is. That is, DL Burst #3 is more robust than DL Burst #4 and less robust than DL Burst #2.
[19] Regarding to resource allocation method shown in FIG. 4, since the resource is allocated as an additional 2-dimensional square format for each burst, it frequently occurs that the more robust bursts are allocated until a later time. For example, DL Burst #2 and DL Burst #3 are transmitted until the later time in the temporal manner compared to DL Burst #4 and DL Burst #5.
[20] Therefore, even when the subscriber station knows what bursts to receive (e.g., DL Burst #2), the subscriber station must receive other bursts that have less robust burst profiles (e.g., DL Burst #3, DL Burst #4, and DL Burst #5) in order to receive the burst to which the subscriber belongs, thereby generating undesired power consumption.
[21] Also, the receiver processes DL Burst #2 later than DL Burst #4, and therefore, DL Burst #2 and DL Burst #4 may be transmitted to the upper layer in the wrong order. The burst which reaches a temporally subsequent symbol interval has a delayed processing time, and a corresponding response is accordingly delayed.
[22] Further, since the resource is divided into non-uniform squares in the prior art, it may be possible that all the resources are not allocated and some resources remain.
[23] FIG. 5 shows a conventional method for processing downlink resources for power saving.
[24] A pipeline delay for default processing (which is a minimum processing time for the DL-MAP) is inevitable because of features of the OFDMA physical layers, the fast Fourier transform (FFT) is only performed during the pipeline delay, and the subsequent stages including demapping and channel decoding are difficult to execute.
[25] As to managing the power saving, the subscriber station is controlled to process desired bursts and turn off the receiver when subsequent bursts are provided, thereby saving the power.
[26] A designated burst (D-burst) may be allocated at a later time in the conventional resource allocation method shown in FIG. 4. That is, the burst which is less robust than the designated burst may be allocated prior to or concurrently with the designated burst.
[27] Therefore, unnecessary bursts are also received while the designated burst is decoded, which is inefficient in the viewpoint of power saving. That is, further power is consumed for a useless process since the subscriber station receives bursts which are less robust than the general operational burst profile.
[28] In addition, a surplus resource may be generated since the resources are allocated in the 2-dimensional square format in the prior art, and overhead may be larger since information on each burst in the MAP has symbol offset information and subchannel offset information. Disclosure of Invention Technical Problem
[29] It is an advantage of the present invention to provide a resource allocation method for saving power consumption used for processing undesired bursts in an OFDM system.
[30] It is an advantage of the present invention to provide a resource allocation method for using minimum signaling overheads to the MAP (Frame Configuration) Information which is a broadcast signaling. And, it is better to save power of a subscriber station and minimize residual resources by using the remaining resources as sequentially. Technical Solution
[31] In one aspect of the present invention, a method for allocating a downlink radio resource in an orthogonal frequency division multiple access (OFDMA) communication system, comprises: (a) obtaining a characteristic of a radio channel; (b) determining a modulation and channel coding level; (c) allocating a radio resource according to a temporal order predefined to bursts corresponding to the determined modulation and channel coding level; (d) generating information on the allocated radio resource and mapping the information to a common control block; and (e) transmitting the allocated radio resource in a downlink.
[32] The information on the radio resource is allocated to the burst by the number of the unit resources. The unit resource is generally called by a slot (DL or UL slot) which is a predetermined symbol interval times a predetermined number of subchannels. The resource allocation is performed as the same order of the common control information (MAP information), and therefore, the currently allocated resources are started from the last resource of the previous one.
[33] The radio resources are sequentially allocated in the order of subchannels in the same symbol axis by unit resource. After filling up all the remaining subchannels in the same symbol axis, the next configuring unit resource starts from the first subchannel in the next corresponding symbols axis. (If the unit resource comprises one subchannel by three symbols, then the next corresponding symbol is next to the third symbol.) Therefore, the more robust bursts are started in the less symbol and subchannel index.
[34] In another aspect of the present invention, a method for a subscriber station to access a radio resource in an orthogonal frequency division multiple access (OFDMA) communication system, comprises: (a) retrieving designated burst information in a common control block (MAP information); (b) checking the number of unit resources allocated to the designated burst from the designated burst information; (c) retrieving the designated burst based on the number of the allocated unit resources previously allocated in the common control block (MAP Information), and receiving the designated burst; and (d) terminating the receiving operation when the designated burst is received.
[35] Advantageous Effects
[36] According to the present invention, the subscriber station in the OFDM system saves power consumption used for processing unnecessary bursts.
[37] Also, the resource allocation method according to the present invention uses minimum overheads and minimizes residual resources. Brief Description of the Drawings
[38] The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate an embodiment of the invention, and, together with the description, serve to explain the principles of the invention;
[39] FIG. 1 shows a single-carrier resource allocation scheme;
[40] FIG. 2 shows a hierarchical structure of the wireless portable Internet system;
[41] FIG. 3 shows a connection state between a subscriber station (SS) and a base station (BS) in the wireless portable Internet system;
[42] FIG. 4 shows a frame structure for resource allocation in a downlink of the conventional OFDMA system;
[43] FIG. 5 shows a conventional method for processing downlink resources for power saving;
[44] FTGs. 6 and 7 show radio resource allocation according to an exemplary embodiment of the present invention;
[45] FIG. 8 shows a method for processing downlink resources for power saving according to an exemplary embodiment of the present invention;
[46] FIG. 9 shows a flowchart for allocating radio resources in a downlink according to an exemplary embodiment of the present invention; and
[47] FIG. 10 shows a flowchart for receiving radio resources in a downlink according to an exemplary embodiment of the present invention. Best Mode for Carrying Out the Invention
[48] In the following detailed description, only the preferred embodiment of the invention has been shown and described, simply by way of illustration of the best mode contemplated by the inventor(s) of carrying out the invention. As will be realized, the invention is capable of modification in various obvious respects, all without departing from the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not restrictive. To clarify the present invention, parts which are not described in the specification are omitted, and parts for which similar descriptions are provided have the same reference numerals.
[49] A radio resource allocation method according to an exemplary embodiment of the present invention will be described with reference to drawings.
[50] FTGs. 6 and 7 show radio resource allocation according to an exemplary embodiment of the present invention.
[51] As to resource allocation according to an exemplary embodiment of the present invention, the bursts are arranged sequentially according to a specific rule. (The burst of starting from the less symbol index is the more robust one, and the burst started from the less subchannel index in each burst of starting from the same symbol index is the more robust one.) When compared to the bursts illustrated in FIG. 4, a burst shown in FTGs. 6 and 7 is not always configured to be a 2-dimensional square. That is, when subchannels of a burst are allocated in the same symbol interval, residual subchannels are contiguously allocated in the next symbol interval. The bursts are allocated in the
order of from the most robust burst to the least robust one with respect to the time axis.
[52] The subscriber station checks bursts to be received by the subscriber station when the number of unit resources allocated to the bursts is designated and allocated after the last resource of the previously allocated bursts.
[53] For example, in Figure 6, there are five slot groups having thirty-two subchannels by three symbols. When one subchannel by three symbol intervals is designated to be a unit resource, a total of 160 (=32 x 5) unit resources are provided. In this instance, twenty two unit resources are allocated to DL Burst #1, conesponding to eleventh to thirty-second unit resources.
[54] Therefore, when receiving information to receive the unit resources up to the thirty- second unit resource from the base station, the subscriber station designated to receive DL Burst #1 receives no further undesired bursts.
[55] When the base station attempts to provide further accurate position information on a designated burst to the subscriber station, the base station further provides a start index of the unit resource and an end index of the unit resource to the subscriber station only by designating the allocated number of unit resources.
[56] The subscriber station then reads the number of unit resources and the order thereof from MAP information to thus catch bursts to be received and a symbol, and reduce overheads for displaying burst information.
[57] FIG. 7 shows a frame for partially allocating the subchannels. When the system performs the resource allocating by using partial allocation on the total number of downlink subchannels, the same allocation scheme can be used by broadcasting the size information on the common control information, that is, number information of subchannels in use (partial loading factor) to the above-described resource allocation method.
[58] Hence, the information on the number of subchannels in use and information on unit resources in use are obtained from the common control information. Indexing information on DL Burst is produced by using a value generated by multiplying the partial loading factor to the total number of subchannels.
[59] The resource allocation method of FIG. 7 substantially conesponds to that of FIG. 6 except the reduced number of available subchannels.
[60] An unused radio resource is saved according to the resource allocation method of FIG. 7, adjacent cell interference is reduced since some subcarriers are not used, and hence, the burst profile with better transmission efficiency is used.
[61] When comparing the exemplary embodiment to the conventional resource
allocation method in the 2-D square format, the exemplary embodiment generates the residual resource equal to or less than that of the prior art in the case of transmitting the same bursts.
[62] FIG. 8 shows a method for processing downlink resources for power saving according to an exemplary embodiment of the present invention.
[63] The resource allocation methods shown in FTGs. 6 and 7 follow the strict order of from the more robust burst to the less robust burst. When the base station determines that a conesponding frame has sufficient resources, the base station transmits data with more robust bursts to the subscriber station, and when the subscriber station detects a burst to be received by the subscriber station, the subscriber station processes the corresponding burst and does not process bursts in the subsequent symbol interval, and therefore, the subscriber station saves more power.
[64] In the exemplary embodiment, data to be transmitted to a plurality of subscriber stations having the same modulation and channel encoding level are combined to one burst and the combined data are transmitted thereto, and in addition, it is also possible to combine one burst to data to be transmitted to one subscriber station. The subscriber station retrieves a designated burst to be received by the subscriber station from the MAP information, receives the designated burst, and turns off the receiver so as to not process the bursts to be provided in the subsequent symbol interval. It is optimal to discard the burst transmitted by using a transmission scheme which is more efficient than the operational burst profile instead of receiving the burst since the conesponding subscriber station cannot normally receive the burst.
[65] When the unit resources are designated, the designated burst can be easily retrieved through the number information of unit resources.
[66] FIG. 9 shows a flowchart for allocating radio resources in a downlink according to an exemplary embodiment of the present invention.
[67] In order to perform a downlink communication, the initial base station receives a characteristic of a radio channel in step of S10 through an MAC message (e.g., a channel descriptor message) which describes characteristics of physical layers.
[68] The base station adaptively determines a modulation and channel encoding level according to the characteristic of the radio channel reported from the MAC message (or PHY channel COI report) in step of SI 1. For example, the base station determines a conesponding modulation and channel encoding level according to a signal-to-noise ratio (SNR) detected from the physical layer.
[69] Radio resources are allocated as follows when the modulation and channel
encoding level is determined. The size of the default resource to be used is designated in step of S 12 by designating the number of unit resources used for a downlink, and the step of S 12 is omitted when the previously designated default resource information (including unit resources and the partial loading factor) is used.
[70] The number of unit resources allocated to the burst is designated in step of S 13 since the unit resources have a constant symbol interval.
[71] When attempting to provide further accurate designated burst information, a start index of the unit resource and an end index of the unit resource of the burst are designated.
[72] When the radio resource is allocated, the number of the allocated unit resources and subscriber information are generated, and the generated number and subscriber information are mapped to a common control information block including MAP information in step of S14.
[73] When the radio resource is allocated and the information is mapped to the block, it is determined whether the burst conesponding to the determined modulation and channel encoding level have the least robustness in step S15. When the base station transmits data in the order from the most robust burst to the subscriber station, the subscriber station receives no bursts which are less robust than the operational burst profile, and thereby, power is saved and the data are transmitted in the order of from the most robust burst from the downlink sub-frame.
[74] When the allocation on the available radio resource is finished, the base station generates the radio resource into frames and performs downlink transmission in step of S16.
[75] FIG. 10 shows a flowchart for receiving radio resources in a downlink according to an exemplary embodiment of the present invention.
[76] The subscriber station retrieves designated burst information in the common control block (including MAP information) transmitted as broadcast information, the burst information including modulation and channel modulation level information of bursts in step αf S20.
[77] The subscriber station checks the default resource information (such as the unit resource information and the partial loading factor), and the number of unit resources conesponding to bursts in step of S21, and checks no default resource size when the available subchannels are used. The subscriber station automatically calculates the range of the symbol interval in which the subscriber station will receive data, by checking the number of allocated unit resources, and thus obtains the position of bursts
to be received by the subscriber station and symbol information.
[78] When desiring to obtain a further accurate position of the designated burst, the subscriber station checks the start index of the unit resource and the end index of the unit resource of the burst, and demodulates or decodes the designated burst according to the checked modulation and channel encoding level in step S22. The subscriber station checks whether to have the burst up to the symbol of the designated burst to be received by the subscriber station decoded, and continues to decode the same when the decoding is not finished in step of S23.
[79] When the decoding is finished, the receiver of the subscriber station is turned off in step S24 since it is useless to receive bursts which are less robust than the operational burst profile when the bursts are transmitted in the order of from the most robust burst. Accordingly, the subscriber station saves power used for receiving unnecessary bursts.
[80] While this invention has been described in connection with what is presently considered to be the most practical and prefened embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications an equivalent arrangements included within the spirit and scope of the appended claims.
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