Source: https://patents.google.com/patent/JP5108902B2/en
Timestamp: 2020-04-05 11:27:38
Document Index: 604740479

Matched Legal Cases: ['art 103', 'art 104', 'art 105', 'art 201', 'art 203', 'art 204']

JP5108902B2 - Base station apparatus and radio communication control method - Google Patents
Base station apparatus and radio communication control method Download PDF
JP5108902B2
JP5108902B2 JP2010003494A JP2010003494A JP5108902B2 JP 5108902 B2 JP5108902 B2 JP 5108902B2 JP 2010003494 A JP2010003494 A JP 2010003494A JP 2010003494 A JP2010003494 A JP 2010003494A JP 5108902 B2 JP5108902 B2 JP 5108902B2
JP2010003494A
JP2011142598A (en
2010-01-11 Application filed by 株式会社エヌ・ティ・ティ・ドコモ filed Critical 株式会社エヌ・ティ・ティ・ドコモ
2010-01-11 Priority to JP2010003494A priority Critical patent/JP5108902B2/en
2011-07-21 Publication of JP2011142598A publication Critical patent/JP2011142598A/en
2012-12-26 Publication of JP5108902B2 publication Critical patent/JP5108902B2/en
The present invention provides a radio communication control method, in a communication system in which the system band is widened by aggregating a plurality of fundamental frequency blocks, that is suitable to transmit a downlink shared channel and its downlink control channel in different fundamental frequency blocks. According to this radio communication control method, a normal component carrier and an concatenated component carrier are selected for radio communication with a user terminal, and resources are allocated such that, in the event the user terminal is a terminal of LTE specifications which can support up to a fundamental frequency block, communication is made possible based on the LTE specifications using only the fundamental frequency block, and, in the event the user terminal is a terminal of the LTE-A specifications which can support up to the concatenated frequency block, communication is performed based on the LTE specifications using the concatenated frequency block.
The present invention relates to a radio communication control method, a base station apparatus, and a mobile terminal apparatus in a next generation mobile communication system.
In a UMTS (Universal Mobile Telecommunications System) network, HSDPA (High Speed Downlink Packet Access) and HSUPA (High Speed Uplink Packet Access) are adopted for the purpose of improving frequency utilization efficiency and data rate. A feature of the third generation system based on CDMA (Wideband Code Division Multiple Access) is being maximally extracted. For this UMTS network, Long Term Evolution (LTE) has been studied for the purpose of further high data rate and low delay (Non-Patent Document 1). In LTE, as a multiplexing method, OFDMA (Orthogonal Frequency Division Multiple Access) different from W-CDMA is used for the downlink (downlink), and SC-FDMA (Single Carrier Frequency Division Multiple Access) is used for the uplink (uplink). Used.
The third generation mobile communication system can generally realize a transmission rate of about 2 Mbps at the maximum on the downlink using a fixed band of 5 MHz. On the other hand, an LTE (Release 8) system called 3.5 generation can realize a transmission rate of about 300 Mbps at the maximum on the downlink and about 75 Mbps on the uplink using a variable band of 1.4 MHz to 20 MHz. In addition, in the UMTS network, a successor system of LTE is also being studied for the purpose of further broadbandization and higher speed (for example, LTE advanced (LTE-A or Release 10)). In the future, these multiple mobile communication systems are expected to coexist. The LTE-A system currently under study is required to ensure backward compatibility with LTE.
By the way, in the LTE-A system, in order to satisfy the requirements of LTE-A, it is essential to increase the bandwidth up to about 100 MHz. On the other hand, in the system band (all signal bands) of the LTE-A system, it is necessary to support (backward compatibility) of LTE terminals (terminals that meet the LTE specifications but do not support the LTE-A specifications). Become. Therefore, the system band of LTE-A is composed of a plurality of basic frequency blocks (referred to as “component carriers” in LTE-A), and each component carrier is determined to have a bandwidth that can be used in LTE (maximum 20 MHz). It has been.
In LTE-A, a guard band is inserted between adjacent component carriers, and a plurality of component carriers are arranged in the system band so that the interval between the center frequencies of the component carriers is a multiple of 300 kHz. When a plurality of component carriers are arranged in the system band, some free bands exist due to the influence of the bandwidths of the component carrier and the guard band. How to utilize this free band has not been fully studied.
The present invention has been made in view of the above points, and provides a radio communication control method, a base station apparatus, and a mobile terminal apparatus capable of effectively utilizing a vacant band generated when a plurality of component carriers are arranged in a system band. The purpose is to provide.
In the base station apparatus of the present invention, a basic frequency block corresponding to an existing system band and a combined frequency block formed by combining an additional carrier with the existing system band are arranged on the frequency axis, and the basic frequency block or the combination Selection means for selecting a frequency block for wireless communication with a user terminal, and if the user terminal is a terminal of the first specification capable of supporting up to the basic frequency block, only the basic frequency block is used for the first specification. Resource allocation means for allocating resources so that communication can be performed based on the second specification using the combined frequency block if the user terminal is a terminal of the second specification capable of supporting up to the combined frequency block; A communication operator that performs wireless communication with the user terminal in accordance with resource allocation by the resource allocation means If, comprising a, the resource allocation means determines according to the minimum allocation becomes signaling unit of the resource block is a unit RBG (Resource Block Group) previously prepared table the size of the radio resource, wherein the table of the plurality The RBG size is defined in stages corresponding to the system band, and the basic frequency block and the combined frequency block are determined to have the same RBG size .
According to the present invention, it is possible to provide a radio communication control method, a base station apparatus, and a mobile terminal apparatus capable of effectively utilizing a vacant band in a widened system band.
The figure which shows the hierarchical bandwidth structure defined by LTE-A The figure which shows the example of arrangement | positioning of the several component carrier containing a coupling | bonding component carrier (A) The figure which shows the system band which an LTE terminal recognizes with respect to a coupling | bonding component carrier, (B) The figure which shows the system band which an LTE-A terminal recognizes with respect to a coupling | bonding component carrier Table structure diagram defined by LTE (A) Configuration diagram of coupled component carrier, (B) Configuration diagram of normal component carrier, (C) Conceptual diagram in which coupled component carrier is divided by RBG size 3, (D) Combined component carrier and normal component carrier have the same size A figure showing that it is classified by RBG Table configuration diagram according to this embodiment The figure which shows the mapping method which makes the head RB of a carrier segment the starting position of a shared data channel in this Embodiment The figure which shows the method of aligning the start position of PDSCH of a carrier segment in alignment with a normal component carrier in this Embodiment Conceptual diagram of PDCCH transmission according to LTE specifications Conceptual diagram of PDCCH reception according to LTE specifications The figure which shows the user common search space by the LTE specification and the user individual search space (A) The figure which shows a virtual resource block, (B) The conceptual diagram of localized transmission, (C) The conceptual diagram of distributed transmission Conceptual diagram of distributed transmission in this embodiment The figure which shows the uplink control channel structure in this Embodiment. The figure which shows schematic structure of the mobile communication system which concerns on the Example of this invention. The figure which shows schematic structure of the wireless base station apparatus which concerns on embodiment of this invention The figure which shows schematic structure of the mobile terminal device which concerns on embodiment of this invention Functional block diagram of the baseband processing unit of the radio base station apparatus shown in FIG. Functional block diagram of the baseband processing unit of the mobile terminal apparatus shown in FIG.
FIG. 1 is a diagram illustrating a hierarchical bandwidth configuration defined in LTE-A. The example shown in FIG. 1 is an LTE-A system that is a first mobile communication system having a first system band composed of a plurality of basic frequency blocks, and a second system band that is composed of one component carrier. This is a hierarchical bandwidth configuration when an LTE system, which is a mobile communication system, coexists. In the LTE-A system, for example, wireless communication is performed with a variable system bandwidth of 100 MHz or less, and in the LTE system, wireless communication is performed with a variable system bandwidth of 20 MHz or less. The system band of the LTE-A system is at least one component carrier with the system band of the LTE system as one unit. Collecting a plurality of component carriers in this way to increase the bandwidth is called carrier aggregation.
For example, in FIG. 1, the system band of the LTE-A system is a system band (20 MHz × 5 = 100 MHz) including a band of five component carriers, where the system band (base band: 20 MHz) of the LTE system is one component carrier. ). In FIG. 1, a mobile terminal apparatus UE (User Equipment) # 1 is a mobile terminal apparatus compatible with the LTE-A system (also compatible with the LTE system), and can support a system band up to 100 MHz. The UE # 2 is a mobile terminal device compatible with the LTE-A system (also supports the LTE system), and can support a system band up to 40 MHz (20 MHz × 2 = 40 MHz). The UE # 3 is a mobile terminal device compatible with the LTE system (not compatible with the LTE-A system), and can support a system band up to 20 MHz (base band).
The present inventor pays attention to the fact that a vacant band is generated when a plurality of component carriers are arranged in a widened system band, and connects one additional carrier to the component carrier so as to efficiently fill the vacant band. The present invention has been reached by considering a system configuration for handling as a component carrier. By connecting an additional carrier to an existing component carrier, a communication control method capable of solving the problems caused by exceeding the maximum bandwidth (20 MHz) that can be used by the LTE terminal is realized.
Hereinafter, an additional carrier connected to an existing component carrier is referred to as a “carrier segment”, and a component carrier in which a carrier segment is connected to an existing component carrier is referred to as a “combined component carrier”. An independent existing component carrier to which no carrier segment is connected is referred to as a “normal component carrier” or an “independent component carrier”.
In one aspect of the present invention, the carrier segment is not treated as an independent carrier, but is always arranged to be coupled to the end of the normal component carrier so as to form one component carrier together with the normal component carrier. The normal component carrier is allocated without distinction to the LTE terminal and the LTE-A terminal, and the LTE terminal to which the combined component carrier is allocated can respond in the same manner as when the normal component carrier is allocated, and the combined component carrier is allocated. The LTE-A terminal thus configured performs downlink and / or uplink communication control so that the entire carrier segment can be utilized.
As a result, even if a normal component carrier that can be used by the LTE terminal and a combined component carrier that exceeds the maximum width that can be used by the LTE terminal are mixed, both the LTE terminal and the LTE-A terminal can support the system. Efficient utilization of carriers can be achieved by efficiently filling the available bandwidth.
Next, a specific description will be given of a communication control method for efficiently filling a vacant band generated when a plurality of component carriers are arranged in a widened system band.
FIGS. 2A, 2B, and 2C are diagrams illustrating examples of arrangement of a plurality of component carriers including combined component carriers.
In the component carrier arrangement example shown in FIG. 2A, two independent component carriers CC # 1 and CC # 2 and one combined component carrier CC # 3 are arranged so as to cover the entire signal band. . The three component carriers CC # 1 to # 3 are arranged over the entire signal band so that the interval between the center frequencies of the normal component carrier portions is a multiple of 300 kHz. In the combined component carrier CC # 3 arranged at the right end of the entire signal band, a carrier segment (eg, 1.4 MHz) as an additional carrier is continuously arranged at the right end of the normal component carrier portion (eg, 20 MHz). For example, a combined component carrier CC # 3 of 21.4 MHz is configured.
In the component carrier arrangement example shown in FIG. 2B, there are three component carriers CC # 1 to CC # 3 as in FIG. 2A, but two combined component carriers CC # 1 and CC # 3, One independent component carrier CC # 2 is combined. The three component carriers CC # 1 to # 3 are arranged in the entire signal band so that the interval between the center frequencies of the normal component carrier portions is a multiple of 300 kHz. The combined component carriers CC # 1 and CC # 3 are arranged at both ends of the entire signal band, and the low-frequency-side combined component carrier CC # 1 has a carrier segment continuously arranged at the low-frequency side end, The coupled component carrier CC # 3 has carrier segments arranged continuously at the high frequency side end.
In the component carrier arrangement example shown in FIG. 2C, three independent component carriers CC # 1 to CC # 3 and one combined component carrier CC # 4 are combined. The four component carriers CC # 1 to # 4 are arranged in the entire signal band so that the center frequency intervals of the normal component carrier portions are multiples of 300 kHz. In the combined component carrier CC # 4 arranged at the right end in the entire signal band, carrier segments are continuously arranged at the high frequency side end of the normal component carrier.
As shown in FIGS. 2A, 2B, and 2C, the carrier segments are always continuously arranged adjacent to the normal component carrier and are connected to the normal component carrier to constitute one component carrier.
In this way, if the carrier segment is connected to the normal component carrier to form one component carrier, it is not necessary to newly define the carrier segment as an independent component carrier, and the number of options can be reduced.
Also, even if a carrier component is connected to a normal component carrier to form a combined component carrier, the LTE terminal recognizes the combined component carrier as a normal component carrier as shown in FIG. As shown, if the LTE-A terminal can be recognized as a combined component carrier, backward compatibility with LTE can be realized, and effective use of the carrier can be realized.
The radio base station performs communication control so that the LTE terminal recognizes the combined component carrier as a normal component carrier and realizes an operation according to the LTE specification even if the combined component carrier is allocated to the LTE terminal (resources). Control), when a combined component carrier is allocated to an LTE-A terminal, communication control (resource control) is performed so that the LTE-A terminal can effectively use the entire combined component carrier. Hereinafter, specific examples of resource operations will be described.
When allocating combined component carriers without distinguishing between LTE terminals and LTE-A terminals, resource block allocation signaling becomes complicated if the LTE specifications are applied as they are.
For PDSCH and PUSCH, which are physical channels that transmit user data, localized transmission is basically applied. However, in order to efficiently allocate localized transmission type radio resources, continuous subcarriers are blocked. A minimum unit of radio resource allocation called a resource block (RB) is defined. In LTE, one RB is composed of 12 subcarriers × 14 OFDM symbols, and six types of {6, 15, 25, 50, 75, 100} are defined as the number of RBs serving as a system band. For example, if the system bandwidth is 5 MHz, 25 consecutive RBs are assigned, and if the system bandwidth is 20 MHz, 100 consecutive RBs are assigned.
Although it is necessary to notify the RB allocation information from the radio base station to the terminal, RBG (Resource Block Group) is defined to reduce overhead. That is, as shown in FIG. 4, a table in which system bandwidth (number of RBs) is associated with RBG size is defined, and RB allocation information is notified as a group of RB groups defined by the RBG size. However, if the RBG size is determined using the table shown in FIG. 4 (LTE specifications), the RBG size changes between the normal component carrier and the combined component carrier depending on the system band. For example, as shown in FIG. 5A, in the case of a combined component carrier configured by adding a carrier segment of 1.4 MHz to a normal component carrier of 5 MHz, the number of RBs is 25 for the normal component carrier portion. According to the table of 4, the RBG size is 2 (FIG. 5B). On the other hand, since the total including the carrier segment (combined component carrier) has 31 RBs (= 25 + 6), the RBG size is 3 according to the table of FIG. 4 (FIG. 5C). Therefore, although 2 is reported as the RBG size to the LTE terminal, it is necessary to notify 3 as the RBG size to the LTE-A terminal. As described above, when the RBG size is determined using the LTE specification table shown in FIG. 4, resource block allocation is complicated in the scheduler, or RBs that are not allocated are generated, and efficiency is deteriorated.
The present invention proposes an improved table configuration to eliminate the complexity and low efficiency of resource block allocation signaling. That is, with the normal component carrier (NsRB number) and the combined component carrier (RB number = Ns + Ncs) in which the normal component carrier (RB number = Ns) is combined with the carrier segment (RB number = Ncs), the RBG size is The correspondence between the system band (number of RBs) and the RBG size is corrected so as not to change (see FIG. 6).
By determining the RBG size based on such a table, as shown in FIG. 5D, the RBG size determined corresponding to the system band of the normal component carrier (5 MHz) is “2” ( The RBG size determined corresponding to the system band of the LTE component and the combined component carrier (5.14 MHz) is “2”. Therefore, the RBG size can be the same between the LTE terminal and the LTE-A terminal.
FIG. 6 is a diagram illustrating a table configuration improved so that the RBG allocation is the same RBG size between the LTE terminal and the LTE-A terminal. In LTE, the system bandwidth (number of RBs) is RB number = 6 (1.4 MHz), RB number = 15 (3 MHz), RB number = 25 (5 MHz), RB number = 50 (10 MHz), RB number = 75 (15 MHz) ), The number of RBs = 100 (20 MHz). Therefore, in the region where the system band (number of RBs) is higher than the number of RBs = 11, control is performed so that the RBG size is not changed until the system band (number of RBs) reaches the next stage.
Thereby, if the carrier segment is within a range that does not exceed the size of the normal component carrier of the connection destination, LTE and LTE-A have the same RBG size. If the carrier segment exceeds the size of the normal component carrier of the connection destination, it is only necessary to add one normal component carrier of the same size, so the carrier segment does not exceed the size of the normal component carrier of the connection destination. .
For example, in the table shown in FIG. 6, since the RBG size is maintained at 2 until the system band exceeds the number of RBs = 10 and the number of RBs = 50 (10 MHz), the system band is equal to the number of RBs = 25. Even if a carrier segment with the number of RBs = 6 is added to the normal component carrier, the RBGs allocated by the LTE terminal and the LTE-A terminal have the same size.
Therefore, when the radio base station allocates the combined component carrier to the terminal, the RBG size at the time of resource block allocation becomes the same size in the LTE terminal and the LTE-A terminal, so that the resource block allocation becomes complicated and low efficiency Can be prevented.
Also, the PDCCH for transmitting the downlink control information is arranged in the first to third OFDM symbols of the component carrier. If PDCCH is transmitted in the carrier segment of the combined component carrier, PDSCH and PUSCH cannot be decoded because the LTE terminal cannot receive PDCCH. Therefore, it is necessary to control so that PDCCH is transmitted only in the normal component carrier part and not transmitted in the carrier segment. However, when the PDCCH is not allocated to the carrier segment, a case where the PDSCH start position differs between RBs occurs.
The present invention assigns a control channel only to the normal component carrier part and shares the head RB of the carrier segment to the LTE-A terminal when the combined component carrier is configured by connecting the carrier segment to the normal component carrier. User data is mapped in order as the start position of the data channel. Alternatively, no transmission is performed up to the symbol position to which the control channel is allocated in the carrier segment, and the PDSCH start position of the carrier segment is aligned with the normal component carrier.
FIG. 7 shows a method of sequentially mapping the first RE (Rerouce Element, composed of 1 subcarrier × 1 OFDM symbol) of the carrier segment as the start position of the shared data channel. In the resource allocation method shown in the figure, the control channel PDCCH is transmitted using the first first and second OFDM symbols of the normal component carrier, but the carrier segment does not transmit the PDCCH using the first first and second OFDM symbols. Controls allocation. PDSCH, which is a shared data channel, is mapped in order starting from the start RE of the carrier segment. After mapping to the end of the carrier segment (RE = 144), the mapping position is the third OFDM symbol (the next succeeding symbol of the first and second OFDM symbols to which the control channel is assigned) and the head in the frequency direction of the normal component carrier Mapping is performed in order from the position (RB = 145) in the frequency direction. PDSCH maps up to the carrier segment. However, in the case of an LTE terminal, since the carrier segment cannot be recognized, the shared data channel is not mapped to the carrier segment.
In this way, in the case of a combined component carrier in which a carrier segment is connected to a normal component carrier, the control channel is transmitted only in the normal component carrier part (from the first 1 to 3 OFDM symbols) as in the LTE specification. Since the control channel is not transmitted, the control channel can be accommodated in the normal component carrier in any component carrier configuration.
FIGS. 8A and 8B show a resource allocation method in which the PDSCH start position of the carrier segment is mapped in alignment with the normal component carrier. FIG. 8A shows an example in which 2 OFDM symbols are assigned to the control channel, and FIG. 8B shows an example in which 3 OFDM symbols are assigned to the control channel. In this resource allocation method, the PDCCH that is the control channel is transmitted in the normal component carrier part (first 1-3 OFDM symbol), but the PDCCH is not transmitted in the carrier segment. In addition, as a non-transmission period in which PDSCH which is a shared data channel is not transmitted from the position of the OFDM symbol (the second or third OFDM symbol from the beginning of the carrier segment) to the same OFDM symbol to which the control channel is assigned in the normal component carrier Yes. Then, the PDSCH start position of the carrier segment is aligned with that of the normal component carrier to form the second OFDM symbol (FIG. (A)) or the third OFDM symbol ((B)). However, in the case of an LTE terminal, since the carrier segment cannot be recognized, the shared data channel is not mapped to the carrier segment.
Thus, up to the first number of OFDM symbols to which the control channel is assigned in the normal component carrier part, the shared segment is not transmitted in the carrier segment, and the PDSCH start position is determined by the carrier segment and the normal component carrier. By performing resource allocation control so as to align, resource allocation following the LTE specification becomes possible.
In the LTE specification, two types of control information, user common control information and user specific control information, are defined. As will be described later, since the number of bits of this control information is determined by the number of RBs, if the number of bits of user common control information including the carrier segment is determined, there is a problem that the LTE terminal cannot receive. Therefore, it is considered that the user common control information is transmitted only on the normal component carrier, and the user-specific PDCCH is transmitted using only the carrier segment only to the LTE-A terminal. This will be specifically described below.
FIG. 9 is a conceptual diagram of PDCCH transmission according to LTE specifications, and FIG. 10 is a conceptual diagram of PDCCH reception. As shown in FIG. 9, the radio base station assigns a CRC masked with a user ID (UE-ID) to downlink control information (DCI: Downlink Control Information) of user terminals multiplexed in the same subframe. After that, channel coding is performed. Also, rate matching is performed on 72, 144, 288, and 576 bits according to the reception quality of each user terminal (corresponding to a coding rate of 2/3 and 1/12 in the case of 72 bits or 576 bits). Here, 72 bits are defined as a basic unit (CCE: Control Channel Element), and the optimum number of CCEs is determined from the defined four types of CCEs = {1, 2, 4, 8} according to the reception quality Is done. Furthermore, after QPSK modulation, the control information of multiple user terminals is multiplexed (CCE multiplexing), and interleaved in units of REG (abbreviation of Resource Element Group, consisting of 4RE) (CCE interleaving) in order to obtain the frequency diversity effect. . Then, it maps to the head of a sub-frame.
As illustrated in FIG. 10, the user terminal deinterleaves the PDCCH mapped to the first to third OFDM symbols of the subframe. Since the user terminal does not know the rate matching parameter (the number of CCEs) and the start position of the CCE, the user terminal performs blind decoding in units of CCE and searches for a CCE in which the CRC masked with the user ID is OK. The example shown in FIG. 10 is the case of the terminal UE # 3, where all the possibilities are tried and the detection is successful in CCE # 4.
Here, if the component carrier has a system bandwidth of 20 MHz, the number of CCEs is as large as 84, and thus searching for all possibilities is a heavy load on the terminal. Therefore, a technique called a search space for reducing the load on the terminal by limiting the positions for blind decoding is adopted.
FIG. 11 exemplifies two types of search spaces that are ranges for blind decoding. As described above, two types of control information are defined in LTE. User common control information is a control channel that transmits information that all user terminals connected to the same cell need to receive simultaneously, such as broadcast information, paging information, resource allocation information for transmission power control signal transmission, etc. Is transmitted. The user-specific control information is a control channel for transmitting information that needs to be received by only one user terminal, and resource allocation information for transmitting a shared data channel for uplink and downlink is transmitted. As shown in FIG. 11, two types of search spaces, a user shared search space and a user specific search space, are defined corresponding to the two types of control information. The user shared search space is arranged at a common position in all user terminals (arranged in CCE # 1 and CCE # 2 which are the first two CCEs). The user-specific search space is arranged at an independent position on the user terminal (randomly arranged by the user ID and the subframe number). In particular, the user shared search space supports two types of formats (1A, 1C), and uses only 4, 8 CCE aggregation so that the user terminal at the cell edge can receive with high quality. The blind decoding numbers are 4 and 2, respectively. Therefore, the total number of blind decodings is 12 (2 sizes × (4 + 2)).
In the PDCCH transmission described above, the LTE terminal determines the number of bits of DCI format 1A / 1C by the number of RBs (Ns) of normal component carriers, and the LTE-A terminal has the number of RBs of concatenated component carriers in which a carrier segment is added to the normal component carrier. (Ns + Ncs) determines the number of bits of the DCI format 1A / 1C. Therefore, although the number of bits is different between the normal component carrier and the connected component carrier, the number of bits of the user shared search space is calculated according to the number of bits of the assigned connected component carrier. Information may not be received. Therefore, it is desirable to take the following measures to solve this problem.
In the present invention, when a PDCCH is transmitted for an LTE terminal that supports only a normal component carrier and an LTE-A terminal that can support even a connected component carrier, the user shared search space and the user specific search space are in the normal component carrier. The number of bits of control information to be transmitted in the allocation and user shared search space is calculated based on the size of the normal component carrier, and the allocation bits of information (PDSCH, PUSCH, etc.) for which the allocation information is notified in the user-specific search space The number is calculated based on the size of each system band that can be handled by the user terminal.
Thereby, the information of the user shared search space can be reliably received in the LTE terminal that has received the PDCCH.
In addition, there are distributed transmission methods and localized transmission methods as physical channel transmission methods in wireless communication having a wide system bandwidth such as LTE.
FIG. 12 shows an overview of distributed transmission and localized transmission methods.
FIG. 12A shows an array of virtual resource blocks (VRB). In the localized transmission method, as shown in FIG. 12B, virtual resource blocks are mapped to physical resource blocks in the index order with respect to the system band.
In the case of the distributed transmission method, as shown in FIG. 12C, two VRBs that are separated from each other are divided into two, and the two divided VRBs are paired and mapped to physical resource blocks. FIG. 12C shows a case where 1 RB is allocated. 0VRB, which is a virtual resource block with index 0, is divided into two, and is mapped to 0PRB of the physical resource block in the first slot, and in the second slot. It is mapped to 12 PRBs at physical resource block positions separated by N gap. The paired 2VRBs are also divided into two, which are mapped to physical resource block 12PRB in the first slot and mapped to physical resource block 0PRB in the second slot. Although not shown, for example, when 2 RBs are allocated, 0 and 1 VRB are mapped to PRBs 0 and 6 of physical resource blocks in the first slot, and are mapped to PRBs 12 and 18 of physical resource blocks in the second slot. . As described above, in the case of the distributed transmission method, it is possible to obtain the second and fourth frequency diversity effects by assigning 1 and 2 RBs. Further, the value of Ngap needs to be set larger as the number of RBs is larger, and therefore depends on the number of RBs.
In the above-described connected component carrier, when distributed transmission is performed, the first slot may be mapped to a normal component carrier, and the second slot may be mapped to a carrier segment. There is a problem that the LTE terminal cannot recognize the portion mapped to the carrier segment. As a solution to this problem, it is also possible to enable distributed transmission including the carrier segment for LTE-A terminals and to enable distributed transmission closed to normal component carriers for LTE terminals. . However, the difference in the configuration for distributed transmission between LTE and LTE-A is complicated.
In the present invention, when a carrier segment is connected to one end of a normal component carrier to form a connected component carrier, distributed transmission is supported only within the range of the normal component carrier, and distributed transmission is not performed in the carrier segment. Allocate resources.
FIG. 13 is a conceptual diagram for supporting distributed transmission only in the normal component carrier portion for the connected component carriers. 0VRB, which is the virtual resource block with index 0 shown in FIG. 12A, is divided into two, mapped to 0PRB of the physical resource block in the first slot, and mapped to 12PRB of the physical resource block position separated by Ngap in the second slot. Has been. Further, 6VRB is also divided into two, mapped to 6PRB of the physical resource block in the first slot, and mapped to 19PRB of the physical resource block in the second slot. In this way, all virtual resource blocks are allocated physical resource blocks in the normal component carrier (25 RB), and control is performed so that distributed transmission is not performed in the carrier segment (6 RB).
As a result, complications due to different configurations at the time of distributed transmission can be eliminated, and a signal transmitted in a distributed manner in an LTE terminal can be correctly decoded.
In the above description, an improvement measure has been described for downlink communication control when a carrier segment is added, but the following improvement measure is also proposed for the uplink.
In the uplink physical channel configuration in LTE, PUCCH that is a control channel is arranged at both ends of the system band, and intra-subframe frequency hopping is applied in order to obtain a frequency diversity effect. In the case of a connected component carrier in which a carrier segment is connected to one end of a normal component carrier, when PUCCH is arranged at both ends of the system band in accordance with LTE specifications, at least one PUCCH is arranged on the carrier segment. Since the LTE terminal cannot transmit in the carrier segment, there arises a disadvantage that PUCCH cannot be sent correctly.
In the present invention, when a carrier segment is connected to one end of a normal component carrier to form a connected component carrier, uplink control channels are arranged at both ends of the normal component carrier, and intra-subframe frequency hopping is performed only on the normal component carrier. Support.
FIG. 14A is a diagram illustrating an example in which uplink control channels are arranged at both ends of a normal component carrier when a carrier segment is connected to one end of a normal component carrier to form a connected component carrier. Intra-frame frequency hopping is applied between PUCCHs arranged at both ends of the normal component carrier. PUSCH is allocated to the carrier segment. PUSCH transmission in the carrier segment is supported only by Clustered DFT (Discrete Fourier Transform) -spread OFDM. Clustered DFT-spread OFDM converts the transmission signal to the frequency domain by DFT spreading before OFDM modulation, and divides each frequency component of the transmission signal encoded data symbol after DFT into multiple frequency blocks (Cluster) After that, it is inserted at the IFFT subcarrier position having a bandwidth corresponding to the system bandwidth, and 0 is set for the other frequency components.
Thereby, since the position of PUCCH which is an uplink control channel is shared by LTE and LTE-A, an overhead can be made small.
Further, in the uplink physical channel, PUSCH is also subjected to frequency hopping in order to obtain a frequency diversity effect. At this time, if the PUSCH hopping destination is a carrier segment, the LTE terminal cannot transmit the PUSCH.
The present invention supports PUSCH intra-subframe frequency hopping only for normal component carriers, and performs resource control so that the carrier segment is not a hopping destination.
FIG. 14B shows an example in which radio resources are allocated so that the PUSCH frequency hopping destination is within the range of the normal component carrier when a carrier segment is connected to one end of the normal component carrier to form a connected component carrier. Show.
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Here, a radio base station apparatus and a mobile terminal apparatus in a mobile communication system in which the LTE system and the LTE-A system are constructed in an overlapping manner will be described.
A mobile communication system 1 having a mobile terminal apparatus (UE) 10 and a base station apparatus (Node B) 20 according to an embodiment of the present invention will be described with reference to FIG. FIG. 15 is a diagram for explaining a configuration of mobile communication system 1 having mobile terminal apparatus 10 and base station apparatus 20 according to the present embodiment. Note that the mobile communication system 1 shown in FIG. 15 is a system including the LTE system and the LTE-A system as described above. LTE-A may be called IMT-Advanced or may be called 4G.
As shown in FIG. 15, the mobile communication system 1 includes a base station device 20 and a plurality of mobile terminal devices 10 (10 1 , 10 2 , 10 3 ,... 10 n , n communicating with the base station device 20. Is an integer of n> 0). The base station apparatus 20 is connected to the higher station apparatus 30, and the higher station apparatus 30 is connected to the core network 40. The mobile terminal apparatus 10 communicates with the base station apparatus 20 in the cell 50. The upper station device 30 includes, for example, an access gateway device, a radio network controller (RNC), a mobility management entity (MME), and the like, but is not limited thereto.
Each mobile terminal device (10 1 , 10 2 , 10 3 ,... 10 n ) includes an LTE terminal and an LTE-A terminal. In the following description, unless otherwise specified, the mobile terminal device 10 is described. Proceed. For convenience of explanation, it is assumed that the mobile terminal device 10 is in radio communication with the base station device 20, but more generally, user equipment (UE: User Equipment) including both the mobile terminal device and the fixed terminal device. It's okay.
Here, a communication channel in the LTE system will be described. For downlink, PDSCH shared by each mobile terminal apparatus 10 and downlink L1 / L2 control channels (PDCCH, PCFICH, PHICH) are used. User data, that is, a normal data signal is transmitted by this PDSCH. Transmission data is included in this user data. The component carrier information and scheduling information allocated to the mobile terminal apparatus 10 by the base station apparatus 20 are notified to the mobile terminal apparatus 10 through the L1 / L2 control channel.
For the uplink, a PUSCH shared and used by each mobile terminal apparatus 10 and a PUCCH (Physical Uplink Control Channel) that is an uplink control channel are used. User data is transmitted by this PUSCH. Also, intra-subframe frequency hopping is applied to PUCCH, and downlink radio quality information (CQI: Channel Quality Indicator), ACK / NACK, and the like are transmitted.
The overall configuration of base station apparatus 20 according to the present embodiment will be described with reference to FIG. The base station apparatus 20 includes a transmission / reception antenna 201, an amplifier unit 202, a transmission / reception unit 203, a baseband signal processing unit 204, a call processing unit 205, and a transmission path interface 206.
User data transmitted from the base station apparatus 20 to the mobile terminal apparatus 10 via the downlink is input to the baseband signal processing unit 204 from the upper station apparatus 30 positioned above the base station apparatus 20 via the transmission path interface 206. The
In the baseband signal processing unit 204, PDCP layer processing, user data division / combination, RLC layer transmission processing such as RLC (radio link control) retransmission control transmission processing, MAC (Medium Access Control) retransmission control, HARQ (Hybrid Automatic Repeat reQuest) transmission processing, scheduling, transmission format selection, channel coding, inverse fast Fourier transform (IFFT) processing, and precoding processing are performed. Also, transmission processing such as channel coding and inverse fast Fourier transform is performed on the signal of the physical downlink control channel, which is the downlink control channel, and is transferred to the transmission / reception section 203.
In addition, the baseband signal processing unit 204 transmits control information for each mobile terminal device 10 to perform wireless communication with the base station device 20 to the mobile terminal device 10 connected to the same cell 50 using the broadcast channel described above. Notice. The broadcast information for communication in the cell 50 includes, for example, system bandwidth in the uplink or downlink, root sequence identification information (Root Sequence Index) for generating a random access preamble signal in the PRACH, and the like. included.
In the transmission / reception unit 203, frequency conversion processing for converting the baseband signal output from the baseband signal processing unit 204 into a radio frequency band is performed, and then amplified by the amplifier unit 202 and transmitted from the transmission / reception antenna 201.
On the other hand, for a signal transmitted from the mobile terminal apparatus 10 to the base station apparatus 20 through the uplink, a radio frequency signal received by the transmission / reception antenna 201 is amplified by the amplifier unit 202 and is frequency-converted by the transmission / reception unit 203 to be baseband. The signal is converted into a signal and input to the baseband signal processing unit 204.
The baseband signal processing unit 204 performs FFT processing, IDFT processing, error correction decoding, MAC retransmission control reception processing, RLC layer, and PDCP layer reception processing on user data included in the input baseband signal. Then, the data is transferred to the higher station apparatus 30 via the transmission path interface 206.
Next, the overall configuration of mobile terminal apparatus 10 according to the present embodiment will be described with reference to FIG. Since the LTE main unit and the LTE-A terminal have the same hardware configuration, they will be described without distinction. The mobile terminal device 10 includes a transmission / reception antenna 101, an amplifier unit 102, a transmission / reception unit 103, a baseband signal processing unit 104, and an application unit 105.
As for downlink data, a radio frequency signal received by the transmission / reception antenna 101 is amplified by the amplifier unit 102, frequency-converted by the transmission / reception unit 103, and converted into a baseband signal. The baseband signal is subjected to FFT processing, error correction decoding, retransmission control reception processing, and the like by the baseband signal processing unit 104. Among the downlink data, downlink user data is transferred to the application unit 105. The application unit 105 performs processing related to layers higher than the physical layer and the MAC layer. Also, the broadcast information in the downlink data is also transferred to the application unit 105.
On the other hand, uplink user data is input from the application unit 105 to the baseband signal processing unit 104. In the baseband signal processing unit 104, transmission processing for retransmission control (H-ARQ (Hybrid ARQ)), channel coding, DFT processing, IFFT processing, and the like are performed and transferred to the transmission / reception unit 103. In the transmission / reception unit 103, frequency conversion processing for converting the baseband signal output from the baseband signal processing unit 104 into a radio frequency band is performed, and then amplified by the amplifier unit 102 and transmitted from the transmission / reception antenna 101.
FIG. 18 is a functional block diagram of baseband signal processing section 204 included in base station apparatus 20 according to the present embodiment, and mainly shows functional blocks of a transmission processing section in baseband signal processing section 204. Transmission data for the mobile terminal apparatus 10 under the control of the base station apparatus 20 is transferred from the upper station apparatus 30 to the base station apparatus 20.
The data generation unit 301 outputs the transmission data transferred from the higher station apparatus 30 as user data for each user. The component carrier selection unit 302 selects a component carrier used for wireless communication with the mobile terminal device 10 for each user.
FIG. 18 illustrates a base station configuration corresponding to the mobile communication system 1 having M (CC # 1 to CC # M) component carriers. Component carriers CC # 1 to CC # M include a component carrier composed of combined component carriers and a component carrier composed only of normal component carriers. For example, component carrier CC # 1 is a combined component carrier in which a carrier segment is connected to one end of a normal component carrier as shown in FIG.
The scheduling unit 300 controls resource allocation regarding the component carrier CC # 1 (combined component carrier), and performs scheduling by distinguishing between LTE terminal users and LTE-A terminal users. In addition, the scheduling unit 300 considers the carrier segment in resource allocation of the uplink / downlink shared control channel. In addition, the scheduling unit 300 receives transmission data and a retransmission instruction from the higher station apparatus 30, and receives a channel estimation value and a CQI of a resource block from a receiving unit that measures an uplink signal. The scheduling unit 300 performs scheduling of the up / down control signal and the up / down shared channel signal while referring to the retransmission instruction, the channel estimation value, and the CQI input from the higher station apparatus 30. The propagation path in mobile communication varies depending on the frequency due to frequency selective fading. Therefore, when transmitting user data to the user terminal, adaptive frequency scheduling that assigns resource blocks with good communication quality for each subframe to each user terminal is applied. In adaptive frequency scheduling, a user terminal with good channel quality is selected and assigned to each resource block. Therefore, the scheduling unit 300 allocates resource blocks using CQI for each resource block fed back from each user terminal. Also, an MCS (coding rate, modulation scheme) that satisfies a predetermined block error rate with the allocated resource block is determined.
The baseband signal processing unit 204 of the base station apparatus 20 performs channel coding on a shared data channel (PDSCH) for transmitting user data (may include some control signals) output from the data generation unit 301 for each user. A channel encoding unit 303 that modulates channel-coded user data for each user, and a mapping unit 305 that maps the modulated user data to radio resources.
Also, the baseband signal processing unit 204 includes a downlink control information generation unit 306 that generates downlink shared data channel control information that is user-specific downlink control information, and a downlink common control channel control that is user-specific downlink control information. And a downlink common channel control information generating unit 307 that generates information. The downlink control information generation section 306 generates a downlink control signal (DCI) from resource allocation information, MCS information, HARQ information, PUCCH transmission power control command, etc. determined for each user. At this time, the downlink control information generation section 306 generates control information by distinguishing between LTE terminal users and LTE-A terminal users. However, the downlink common channel control information generation section 307 uses only the normal component carrier and the downlink common control channel. Control information is generated. The baseband signal processing unit 204 includes a channel coding unit 308 that channel-codes the control information generated by the downlink control information generation unit 306 and the downlink common channel control information generation unit 307 for each user, and the channel coding A modulation unit 309 that modulates downlink control information.
Further, the baseband signal processing unit 204 includes an uplink control information generation unit 311 that generates, for each user, control information for uplink shared data channel, which is control information for controlling the uplink shared data channel (PUSCH), and the generated uplink control information. A channel coding unit 312 that performs channel coding of the shared data channel control information for each user, and a modulation unit 313 that modulates the channel-coded uplink shared data channel control information for each user. The uplink control information generation unit 311 generates uplink shared data channel control information by distinguishing between LTE terminal users and LTE-A terminal users.
The control information modulated for each user by the modulation units 309 and 313 is multiplexed by the control channel multiplexing unit 314 and further interleaved by the interleaving unit 315. The control signal output from the interleaving unit 315 and the user data output from the mapping unit 305 are input to the IFFT unit 316 as downlink channel signals. The IFFT unit 316 converts the downlink channel signal from a frequency domain signal to a time-series signal by performing inverse fast Fourier transform. The cyclic prefix insertion unit 317 inserts a cyclic prefix into the time-series signal of the downlink channel signal. The cyclic prefix functions as a guard interval for absorbing a difference in multipath propagation delay. The transmission data to which the cyclic prefix is added is sent to the transmission / reception unit 203.
FIG. 19 is a functional block diagram of the baseband signal processing unit 104 included in the mobile terminal apparatus 10, and shows functional blocks of an LTE-A terminal that supports LTE-A.
The baseband signal processing unit 104 includes a CP removal unit 401, an FFT unit 402, a demapping unit 403, a deinterleaving unit 404, a control information demodulation unit 405, and a data demodulation unit 406 as functional blocks of the reception processing system. CP removing section 401 removes a cyclic prefix that is a guard interval from the received signal received by transmission / reception section 103. The FFT unit 402 performs fast Fourier transform on the received signal (OFDM signal) from which the cyclic prefix has been removed, and converts the time component waveform into a frequency component orthogonal multicarrier signal. The demapping unit 403 receives the reception signal converted into the frequency domain by the FFT unit 402, selects only the subcarriers included in the communication band of the target data communication, thins out the unnecessary subcarriers, and receives The signal is output as a signal band reception signal. The deinterleaving unit 404 rearranges the control information and the user data in the original order by reversing the interleaving performed on the transmission side. The control information demodulator 405 includes a common control channel control information demodulator 405a that demodulates common control channel control information, an uplink shared data channel control information demodulator 405b that demodulates uplink shared data channel control information, and a downlink A downlink shared data channel control information demodulator 405c that demodulates the shared data channel control information. The common control channel control information demodulator 405a demodulates the common control channel control information according to LTE specifications (process closed to normal component carrier) so that both the LTE terminal and the LTE-A terminal can recognize the control information. To do. The uplink shared data channel control information demodulator 405b and the downlink shared data channel control information demodulator 405c demodulate the control information for LTE-A. The data demodulation unit 406 includes a downlink shared data demodulation unit 406a that demodulates a PDSCH that is a downlink shared data channel, and a downlink common channel data demodulation unit 406b that demodulates broadcast information and paging information that are downlink common channel data. .
The baseband signal processing unit 104 includes a data generation unit 411, a channel encoding unit 412, a modulation unit 413, a DFT unit 414, a mapping unit 415, an IFFT unit 416, and a CP insertion unit 417 as functional blocks of the transmission processing system. I have. The data generation unit 411 generates transmission data from the bit data input from the application unit 105. The channel coding unit 412 performs channel coding processing such as error correction on the transmission data, and the modulation unit 413 modulates the channel-coded transmission data with QPSK or the like. The DFT unit 414 performs discrete Fourier transform on the modulated transmission data. Mapping section 415 maps each frequency component of the data symbol after DFT to a subcarrier position designated by the base station apparatus. That is, each frequency component of the data symbol is input to the subcarrier position of IFFT section 416 having a bandwidth corresponding to the system band, and 0 is set to the other frequency components. The IFFT unit 416 performs inverse fast Fourier transform on input data corresponding to the system band to convert it into time series data, and the CP insertion unit 417 inserts a cyclic prefix into the time series data at data delimiters.
Next, resource block allocation and RB allocation signaling for the mobile terminal apparatus 10 in the base station apparatus 20 will be described. One mobile terminal apparatus 10 to which a component carrier CC # 1 that is a connected component carrier is assigned will be described as an LTE-A terminal UE # 1 and an LTE terminal UE # 2.
In the base station apparatus 20, it is assumed that the component carrier selection unit 302 selects the component carrier CC # 1 for the LTE-A terminal UE # 1 and the LTE terminal UE # 2. The scheduling unit 300 performs scheduling by distinguishing between the LTE-A terminal UE # 1 and the LTE terminal UE # 2. The LTE-A terminal UE # 1 performs resource allocation using the entire connected component carrier including the carrier segment, and the LTE terminal UE # 2 uses only the normal component carrier part that does not include the carrier segment. Perform resource allocation. The resource block allocation is also performed by distinguishing between the LTE-A terminal UE # 1 and the LTE terminal UE # 2.
Scheduling section 300 determines an RBG size corresponding to the system band of component carrier CC # 1 for LTE-A terminal UE # 1 based on the table shown in FIG. Similarly, for LTE terminal UE # 2, the RBG size corresponding to the system band of component carrier CC # 1 is determined based on the table shown in FIG. As described above, the same RBG size is selected although the system bands recognized by the LTE-A terminal UE # 1 and the LTE terminal UE # 2 in the component carrier CC # 1 are different.
The downlink control information generation unit 306 (UE # 1) generates RB allocation information for the LTE-A terminal UE # 1 based on the resource allocation result for the LTE-A terminal UE # 1. Also, the downlink control information generation section 306 (UE # 2) generates RB allocation information for the LTE terminal UE # 2 based on the resource allocation result for the LTE terminal UE # 2. The RB allocation information is signaled together in RBG units.
The table shown in FIG. 6 includes normal component carriers (number of NsRBs), combined component carriers (number of RBs = Ns + Ncs) obtained by combining carrier segments (number of RBs = Ncs) with the normal component carriers (number of RBs = Ns). Thus, the correspondence between the system band (number of RBs) and the RBG size is determined so that the RBG size does not change.
In this way, by determining the RBG size based on the table shown in FIG. 6, the RBG sizes of the normal component carrier and the combined component carrier can always be matched, and the RB allocation overhead is reduced and complicated. Can be prevented.
In addition, the scheduling unit 300 controls the start position of the PDSCH by distinguishing between LTE terminals and LTE-A terminals. As shown in FIG. 7, resource allocation is performed for the mobile terminal apparatus UE # 1 so that the PDSCH start position is the first RB of the carrier segment. For LTE terminals, the PDSCH start position is the normal component. Control is performed so that the first RB of the carrier is aligned and neither PDCCH nor PDSCH is allocated to the carrier segment. The mapping unit 305 maps the PDSCH start position in order from the first RB of the carrier segment as shown in FIG.
Alternatively, as shown in FIG. 8, in the period during which PDCCH is transmitted to mobile terminal apparatus UE # 1, no transmission is performed in the carrier segment (PDSCH is not transmitted), and the PDSCH start position of the carrier segment is set as a normal component carrier. Control to align with the start position of PDSCH. As shown in FIG. 8, mapping section 305 performs mapping so that the PDSCH start position of the carrier segment is aligned with the normal component carrier. The PDSCH RB allocation information mapped as shown in FIG. 7 or FIG. 8 is generated by the downlink control information generation section 306 and transmitted to the mobile terminal apparatus UE # 1.
For the LTE terminal, PDSCH allocation to the carrier segment as shown in FIG. 7 and FIG. 8 is not performed, but PDCCH and PDSCH resource allocation is performed by closing to the normal component carrier.
In the mobile terminal apparatus UE # 1, the downlink shared data channel control information demodulator 405c demodulates the RB allocation information, and the downlink shared data demodulator 406a demodulates the PDSCH including the carrier segment according to the RB allocation information.
In addition, the scheduling unit 300 allocates the user shared search space and the user specific search space to the normal component carrier in the resource allocation for the LTE terminal and the LTE-A terminal. Also, the PDCCH size (number of CCEs) of the user shared search space is calculated based on the size of the normal component carrier part, and the allocation bits of information (PDSCH, PUSCH, etc.) that is notified of allocation information in the user-specific search space The number (CCE number) is calculated based on the size of each system band that can be handled by the user terminal.
In the case of distributed transmission, the scheduling unit 300 divides the VRB into two and assigns it to the first slot of one PRB and assigns the other to the second slot as shown in FIG. Resources are allocated so that the second slot is not allocated to the PRB of the carrier segment. That is, the radio resource is allocated so that the distributed transmission is supported only in the normal component carrier and the distributed transmission is not performed in the carrier segment.
The downlink control information generation unit 306 performs scheduling by the scheduling unit 300 on control information (PDSCH / PUSCH transmission control information) transmitted on a control channel (user dedicated PDCCH) that transmits information that needs to be received by only one user terminal. Generated for each user based on the result. Similarly to the scheduling unit 300, the LTE terminal and the LTE-A terminal are distinguished and the control information is generated. The scheduling unit 300 distinguishes between LTE terminals and LTE-A terminals, and calculates the PDCCH size (number of CCEs) of the user-specific search space. The LTE terminal calculates the number of CCEs only for the normal component carrier part, while the LTE-A terminal determines the number of CCEs for the entire combined component carrier including the carrier segment as a system band target. The downlink control information generation section 306 generates PDSCH / PUSCH transmission control information in which the user-specific search space calculated as described above is allocated to the normal component carrier part.
The downlink common channel control information generation unit 307 is configured to control information (SIB / PCH) transmitted on a control channel (user common PDCCH) that transmits information that all user terminals connected to the same cell need to receive simultaneously. / TPC transmission control information) is generated for each user based on the scheduling result by the scheduling unit 300. The scheduling unit 300 calculates the PDCCH size (number of CCEs) of the user shared search space based on the size of the normal component carrier part without distinguishing between LTE terminals and LTE-A terminals. The downlink common channel control information generation section 307 generates SIB / PCH / TPC transmission control information in which the user common search space calculated as described above is allocated to the normal component carrier part.
The uplink control information generation unit 311 generates uplink shared data channel control information for each user. The scheduling unit 300 allocates resources for the uplink shared data channel by distinguishing between LTE terminals and LTE-A terminals. At this time, the scheduling unit 300 allocates PUSCH to the carrier segment as shown in FIG. 14 for the LTE-A terminal, but allocates PUSCH only to the normal component carrier part for the LTE terminal. The uplink control information generation unit 311 receives the resource allocation result of the uplink shared data channel, and generates user-specific shared data channel control information by distinguishing between the LTE terminal and the LTE-A terminal.
The user dedicated PDCCH and the user common PDCCH to which resources are allocated as described above are transmitted after being subjected to control channel multiplexing.
In the LTE-A terminal UE # 1, the common control channel control information demodulation section 405a demodulates the user common PDCCH by blind-decoding the user shared search space, and acquires SIB / PCH / TPC transmission control information. Also, the downlink shared data channel control information demodulator 405c blind-decodes the user dedicated search space to demodulate the user dedicated PDCCH, and obtains PDSCH / PUSCH transmission control information. The downlink shared data demodulation section 406a demodulates the PDSCH including the carrier segment according to the RB allocation information indicated in the PDSCH / PUSCH transmission control information. Further, the uplink shared data channel control information demodulating section 405b demodulates the user dedicated PDCCH and acquires the uplink shared data channel control information. The mapping unit 415 uses the control information for the common control channel (for example, broadcast information, paging information) and the control information for the uplink shared data channel and each frequency component of the uplink control information (PUCCH) and the uplink shared data channel (PUSCH). To map. As shown in FIG. 14A, when a carrier segment is allocated for the uplink shared data channel, PUSCH is mapped to the carrier segment region. Also in the LTE-A terminal, PUCCH is allocated to both ends of the normal component carrier, and is sent after being subjected to intra-subframe frequency hopping. Also, as shown in FIG. 14B, the PUSCH is frequency-hopped within the subframe only with the normal component carrier, and mapping is performed so that the carrier segment is not the hopping destination.
DESCRIPTION OF SYMBOLS 1 Mobile communication system 10 Mobile terminal apparatus 20 Base station apparatus 30 Host station apparatus 40 Core network 101 Transmission / reception antenna 102 Amplifier part 103 Transmission / reception part 104 Baseband signal processing part 105 Application part 201 Transmission / reception antenna 202 Amplifier part 203 Transmission / reception part 204 Baseband signal Processing unit 205 Call processing unit 206 Transmission path interface 300 Scheduling unit 301 Data generation unit 302 Component carrier selection unit 303, 308, 312 Channel encoding unit 304, 309, 313 Modulation unit 305 Mapping unit 306 Downlink control information generation unit 307 Downstream common Channel control information generator 311 Uplink control information generator
A basic frequency block corresponding to an existing system band and a combined frequency block formed by combining an additional carrier with the existing system band are arranged on the frequency axis, and the basic frequency block or the combined frequency block is connected to a user terminal. Selection means for selecting for wireless communication;
If the user terminal is a terminal of the first specification capable of supporting up to the fundamental frequency block, communication is performed based on the first specification using only the fundamental frequency block, and the user terminal is capable of supporting up to the combined frequency block. and resource allocation means you allocated resources to communicate on the basis of the second specification using the combined frequency block if terminal 2 specifications,
Communication means for wirelessly communicating with the user terminal according to resource allocation by the resource allocation means;
The resource allocation means determines an RBG (Resource Block Group) size that is a signaling unit of a resource block, which is a minimum allocation unit of radio resources, according to a table prepared in advance, and the table corresponds to a plurality of system bands. An RBG size is defined in a stepwise manner, and the base station apparatus is characterized in that the RBG size is determined to be the same in the basic frequency block and the combined frequency block .
A basic frequency block corresponding to an existing system band and a combined frequency block formed by combining an additional carrier with the existing system band are arranged on the frequency axis, and the basic frequency block or the combined frequency block is connected to a user terminal. Selecting for wireless communication; and
If the user terminal is a terminal of the first specification capable of supporting up to the fundamental frequency block, communication is performed based on the first specification using only the fundamental frequency block, and the user terminal is capable of supporting up to the combined frequency block. Assigning resources so that communication can be performed based on the second specification using the combined frequency block if the terminal has two specifications;
Wirelessly communicating with the user terminal according to the resource allocation by the resource allocation ,
In the step of allocating resources, an RBG (Resource Block Group) size that is a signaling unit of a resource block that is a minimum allocation unit of radio resources is determined according to a previously prepared table, and the table corresponds to a plurality of system bands. The RBG size is defined stepwise, and the RBG size is determined to be the same in the basic frequency block and the combined frequency block .
JP2010003494A 2010-01-11 2010-01-11 Base station apparatus and radio communication control method Expired - Fee Related JP5108902B2 (en)
JP2010003494A JP5108902B2 (en) 2010-01-11 2010-01-11 Base station apparatus and radio communication control method
PCT/JP2010/071839 WO2011083650A1 (en) 2010-01-11 2010-12-06 Wireless communication control method, base station device, and mobile terminal device
EP20100842163 EP2525615A1 (en) 2010-01-11 2010-12-06 Wireless communication control method, base station device, and mobile terminal device
US13/521,229 US9137803B2 (en) 2010-01-11 2010-12-06 Radio communication control method, base station apparatus and mobile terminal apparatus
JP2011142598A JP2011142598A (en) 2011-07-21
JP5108902B2 true JP5108902B2 (en) 2012-12-26
ID=44305388
JP2010003494A Expired - Fee Related JP5108902B2 (en) 2010-01-11 2010-01-11 Base station apparatus and radio communication control method
US (1) US9137803B2 (en)
EP (1) EP2525615A1 (en)
JP (1) JP5108902B2 (en)
WO (1) WO2011083650A1 (en)
KR101739214B1 (en) 2013-01-30 2017-05-23 후아웨이 테크놀러지 컴퍼니 리미티드 Data scheduling method and apparatus
ES2741973T3 (en) * 2008-06-19 2020-02-12 Huawei Tech Co Ltd Improved method and apparatus that allow carrier aggregation in radiocommunication systems
EP3595233A1 (en) * 2008-06-20 2020-01-15 NEC Corporation Resource allocation method, identification method, base station, mobile station, and program
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2010-12-06 WO PCT/JP2010/071839 patent/WO2011083650A1/en active Application Filing
2010-12-06 EP EP20100842163 patent/EP2525615A1/en not_active Withdrawn
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US20130070692A1 (en) 2013-03-21
WO2011083650A1 (en) 2011-07-14
JP2011142598A (en) 2011-07-21
US9137803B2 (en) 2015-09-15
EP2525615A1 (en) 2012-11-21