Source: https://patents.google.com/patent/JPWO2012108046A1/en
Timestamp: 2020-01-29 03:40:21
Document Index: 740143621

Matched Legal Cases: ['art 31', 'art 11', 'art 61', 'art 43', 'art 61', 'art 64', 'art 43', 'art 35', 'art 11', 'art 34', 'art 12', 'art 11', 'art 11', 'art 65', 'art 43', 'art 61', 'art 64', 'art 43', 'art 64', 'art 43', 'art 43']

JPWO2012108046A1 - Wireless communication system, receiving apparatus, transmitting apparatus, and wireless communication method - Google Patents
Wireless communication system, receiving apparatus, transmitting apparatus, and wireless communication method Download PDF
JPWO2012108046A1
JPWO2012108046A1 JP2011052918A JP2012556722A JPWO2012108046A1 JP WO2012108046 A1 JPWO2012108046 A1 JP WO2012108046A1 JP 2011052918 A JP2011052918 A JP 2011052918A JP 2012556722 A JP2012556722 A JP 2012556722A JP WO2012108046 A1 JPWO2012108046 A1 JP WO2012108046A1
JP2011052918A
JP5565475B2 (en
田島　喜晴
2014-07-03 Publication of JPWO2012108046A1 publication Critical patent/JPWO2012108046A1/en
2014-08-06 Publication of JP5565475B2 publication Critical patent/JP5565475B2/en
An object of the present invention is to provide a wireless communication system capable of realizing high-speed communication. In the carrier aggregation, the BSR management unit of the transmission device transmits the BSR with the PCell, while the reception device determines whether the BSR management unit (62) that has received the BSR with the PCell performs data transmission / reception with the SCell. When the determination is made and it is determined to perform data transmission / reception in the SCell, the RA management unit (61) transmits Msg1 including the device-specific individual preamble.
The present invention relates to a wireless communication system capable of communication using a plurality of frequency carriers.
One conventional wireless communication method is data transmission by random access. For example, in a mobile communication system, when uplink data is generated, a mobile station performs random access using PRACH (Physical Random Access Channel) and requests uplink transmission permission from a base station. In random access, contention occurs when multiple mobile stations transmit the same shared preamble ID on the same PRACH. When contention occurs, the base station cannot detect a mobile station that has performed random access. Hereinafter, such random access is referred to as contention-based random access.
Here, the conventional competitive random access operation will be briefly described. For example, when uplink data is generated, the mobile station notifies the base station of Msg1 including a randomly selected shared preamble ID by PRACH. At this time, when a plurality of mobile stations transmit the same shared preamble ID on the same PRACH, contention occurs. Next, the base station returns a response to Msg1 together with a synchronization signal, transmission permission, etc. for uplink communication in Msg2. The mobile station acquires the uplink synchronization timing with this Msg2. Next, the mobile station transmits its own identifier and the like with Msg3. When the base station can detect the identifier of the mobile station, the base station transmits Msg4 to the mobile station to resolve the conflict. The mobile station starts data transmission / reception with the base station after the exchange of Msg1 to Msg4.
3GPP TS36.300, "Evolved Universal Terrestrial Radio Access (E-UTRA) and Evolved Universal Terrestrial Radio Access Network (E-UTRAN)", V10.0.0, Release 10, June 2010. 3GPP TS36.321, "Medium Access Control (MAC) protocol specification", V9.3.0, Release 9, June 2010.
However, the contention-type random access described above has a problem that the time required for securing synchronization (Msg1 to Msg4) is about 25 ms, and the time loss is large.
The disclosed technology has been made in view of the above, and an object thereof is to provide a wireless communication system capable of realizing further higher communication speed.
A wireless communication system disclosed in the present application is a wireless communication system capable of wireless communication using a plurality of wireless carriers, and a transmission device transmits a buffer state using a first wireless carrier; A first random access management unit for managing random access in the own device, wherein the receiving device receives the state of the buffer on the first radio carrier, and second based on the state of the buffer. A second control unit that performs data transmission / reception with a second wireless carrier, and a second random access management unit that manages random access in the own device, wherein the second control unit is the second wireless carrier. The second random access management unit transmits control information including a device-specific individual preamble, and transmits and receives the control information. As Riga, the first and second random access managing unit, at the second radio carrier to perform a random access of the non-competitive type using the dedicated preamble.
According to one aspect of the wireless communication system disclosed in the present application, it is possible to realize an increase in communication speed.
FIG. 1 is a diagram illustrating a configuration example of a mobile station (transmission apparatus) in the wireless communication system according to the first embodiment. FIG. 2 is a diagram illustrating a configuration example of a base station (reception device) in the wireless communication system according to the first embodiment. FIG. 3 is a diagram illustrating carrier aggregation. FIG. 4 is a diagram illustrating a state of data transmission / reception in a wireless communication system employing carrier aggregation. FIG. 5 is a diagram illustrating an example of a competitive random access method. FIG. 6 is a diagram illustrating an example of a non-contention type random access method. FIG. 7 is a diagram illustrating an example of a scheduling request method. FIG. 8 is a diagram illustrating an example when the competitive random access method is executed in the SCell. FIG. 9 is a diagram illustrating an example of a wireless communication method according to the first embodiment. FIG. 10 is a diagram illustrating the effect of the wireless communication method according to the first embodiment. FIG. 11 is a diagram illustrating an example of dedicated signaling for notifying the mobile station of the value of the parameter T. FIG. 12 is a diagram illustrating an example of dedicated signaling for notifying the mobile station of the value of the parameter T. FIG. 13 is a flowchart showing the operation of a mobile station (transmitting apparatus) that transmits UL data. FIG. 14 is a flowchart showing the operation of the base station (receiving apparatus) that receives UL data. FIG. 15 is a diagram illustrating an example of a wireless communication method when uplink transmission resources are not allocated in the PCell. FIG. 16 is a diagram illustrating a wireless communication method when Msg0 is transmitted by the SCell. FIG. 17 is a diagram illustrating a configuration example of a mobile station (transmission apparatus) in the wireless communication system according to the second embodiment. FIG. 18 is a diagram illustrating a configuration example of a base station (reception device) in the wireless communication system according to the second embodiment. FIG. 19 is a diagram illustrating an example of a wireless communication method according to the second embodiment. FIG. 20 is a diagram illustrating a “first method” in which a mobile station transmits a shared preamble ID using a PUSCH set on a PCell. FIG. 21 is a diagram illustrating a “second method” in which the mobile station transmits the shared preamble ID using the PUSCH set on the PCell. FIG. 22 is a diagram illustrating an example when the base station fails to receive the shared preamble ID in the PCell. FIG. 23 is a diagram illustrating an example when the base station cannot receive the shared preamble ID in the PCell. FIG. 24 is a flowchart showing the operation of the mobile station (transmitting apparatus) that transmits UL data. FIG. 25 is a flowchart showing the operation of the base station (receiving device) that receives UL data. FIG. 26 is a diagram illustrating the wireless communication method according to the second embodiment when Msg0 is transmitted by the SCell.
Embodiments of a wireless communication system disclosed in the present application will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.
FIG. 1 is a diagram illustrating a configuration example of a mobile station (transmission device) in a wireless communication system, and FIG. 2 is a diagram illustrating a configuration example of a base station (reception device) in the wireless communication system.
In FIG. 1, the mobile station includes a transmission / reception unit 11, an uplink transmission unit 12, a control unit 13 including a control plane unit 20 and a data plane unit 30, and an antenna 14. The transmission / reception unit 11 transmits / receives a wirelessly transmitted signal via the antenna 14. The uplink transmission unit 12 performs transmission processing of uplink data (data, confirmation response (ACK / NACK), etc.) based on the control from the control unit 13.
The control plane unit 20 of the control unit 13 is an RRC (Radio Resource Control) layer and controls all layers. Specifically, the control plane unit 20 includes a physical channel control unit 21 and a storage unit 22. The physical channel control unit 21 performs timing control and resource control such as PUSCH (Physical Uplink Shared Channel), PUCCH (Physical Uplink Control Channel), and PRACH. The storage unit 22 stores a parameter T indicating a time range from when the base station receives BSR (Buffer Status Reporting) until it transmits Msg0.
The data plane unit 30 of the control unit 13 controls each layer of PHY (Physical), MAC (Media Access Control), RLC (Radio Link Control), and PDCP (Packet Data Convergence Protocol). Specifically, the data plane unit 30 includes an RA (Random Access) management unit 31, a BSR management unit 32, a TA (timing adjustment) management unit 33, and a transmission / reception control unit 34. The RA management unit 31 controls processing related to the random access method. The BSR management unit 32 controls processing related to BSR transmission. The TA management unit 33 manages uplink synchronization timing. The transmission / reception control unit 34 controls transmission / reception of data and acknowledgment (ACK / NACK).
On the other hand, in FIG. 2, the base station includes a transmission / reception unit 41, a scheduling unit 42, a transmission / reception unit 43, a control unit 44 including a control plane unit 50 and a data plane unit 60, and an antenna 45. The transmission / reception unit 41 transmits / receives data to / from a higher station. The scheduling unit 42 performs radio transmission scheduling. The transmission / reception unit 43 transmits / receives a wirelessly transmitted signal via the antenna 45.
Further, the control plane unit 50 of the control unit 44 is an RRC layer and controls all layers. Specifically, the control plane unit 50 includes a physical channel control unit 51 and a storage unit 52. The physical channel control unit 51 performs timing control and resource control for PUSCH, PUCCH, PRACH, and the like. The storage unit 52 stores a parameter T indicating a time range from when the own station receives the BSR until it transmits Msg0.
Further, the data plane unit 60 of the control unit 44 controls each layer of PHY, MAC, RLC, and PDCP. Specifically, the data plane unit 60 includes an RA management unit 61, a BSR management unit 62, a TA management unit 63, and a transmission / reception control unit 64. The RA management unit 61 controls processing related to the random access method. The BSR management unit 62 controls processing related to BSR reception. The TA management unit 63 manages uplink synchronization timing. The transmission / reception control unit 64 controls transmission / reception of data and acknowledgment (ACK / NACK).
In this embodiment, as an example, a wireless communication method of a wireless communication system including a mobile station (transmitting device) and a base station (receiving device) will be described, but the relationship between the transmitting device and the receiving device is not limited thereto. is not. For example, the wireless communication method of this embodiment is similarly applied to a system including a relay station (transmitting device) and a base station (receiving device) or a system including a mobile station (transmitting device) and a relay station (receiving device). Applicable. Further, the above-described configuration examples of the mobile station and the base station are listed for the sake of convenience of description, and the configuration (each functional unit) related to the processing of the present embodiment is listed, and all the functions of the mobile station and the base station are expressed. It is not a thing. Each functional unit of the mobile station and the base station can be configured by, for example, a CPU (Central Processing Unit), an FPGA (Field Programmable Gate Array), a memory, and the like.
Here, before explaining the wireless communication method in the wireless communication system of the present embodiment, the system and the wireless communication method which are the premise thereof will be described.
In LTE (Long Term Evolution), which is a next-generation mobile communication system, a scheme based on OFDM (Orthogonal Frequency Division Multiplexing) is defined as a radio access technology. In LTE, high-speed wireless packet communication with a downstream peak transmission rate of 100 Mb / s or higher and an upstream peak transmission rate of 50 Mb / s or higher is possible. The 3rd Generation Partnership Project (3GPP), an international standardization organization, is currently examining the LTE-based mobile communication system LTE-A (LTE-Advanced) for realizing higher-speed communication. LTE-A aims at a downlink peak transmission rate of 1 Gb / s and an uplink peak transmission rate of 500 Mb / s, and various new technologies such as a radio access scheme and a network architecture are being studied.
In LTE-A (or LTE Rel-10), as a method for realizing high-speed communication, a plurality of radio carriers of the LTE system are aggregated, and radio data for transmitting a larger amount of data using the aggregated band is used. Methods are being studied. This is called carrier aggregation (frequency aggregation). FIG. 3 is a diagram illustrating carrier aggregation. In FIG. 3, each bundled LTE radio carrier is referred to as a component carrier. In carrier aggregation, a cell that performs various important controls (such as transmission of uplink control data) is called a PCell (Primary Cell). Other cells (# 1 to # 4) that can be bundled are called SCells (Secondary Cells) and are additional carriers for improving throughput. FIG. 4 is a diagram illustrating a state of data transmission / reception in a wireless communication system employing carrier aggregation. In LTE-A or the like, for example, a mobile station (UE) and a base station (eNB) transmit and receive data (corresponding to DL (Down Link) data shown) using a plurality of component carriers.
In addition, as a premise of the wireless communication method of this embodiment, LTE-A or the like defines a competitive random access method. For example, when uplink data (UL (Up Link) data) is generated, the mobile station performs contention-type random access if a scheduling request resource is not allocated, and requests uplink transmission permission from the base station. FIG. 5 is a diagram illustrating an example of a competitive random access method.
Specifically, the mobile station first transmits a randomly selected preamble ID with Msg1. Here, it is assumed that a plurality of mobile stations transmit the same preamble ID on the same PRACH, and in this case, contention occurs. Even when contention occurs, the base station cannot recognize an identifier of a valid mobile station at this stage, and thus it is not known which mobile station has contention for preamble ID. Next, the base station returns a response (RA response) to Msg1 together with a synchronization signal, transmission permission, etc. for uplink communication in Msg2. This Msg2 is returned to the plurality of mobile stations when a plurality of mobile stations transmit Msg1 at the same time. The mobile station acquires the uplink synchronization timing with this Msg2. Next, the mobile station transmits its own identifier (UE identifier) using Msg3. When the base station receives Msg3, it can recognize the identifier of the mobile station. Therefore, when a plurality of mobile stations transmit the same preamble ID on different PRACHs, the base station recognizes which mobile station has the preamble ID competing. be able to. On the other hand, when a plurality of mobile stations transmit the same preamble ID on the same PRACH, for example, only mobile stations with strong reception power are detected. Thereafter, the base station performs contention resolution by transmitting Msg4 to the detected mobile station. That is, in this contention type random access method, synchronization between devices is secured by Msg1 and Msg2 (uplink synchronization is secured), and mobile station identification is performed by Msg3 and Msg4.
The mobile station starts data transmission / reception (UL data, ACK / NACK) with the base station after completing “synchronization” and “mobile station identification” in Msg1 to Msg4. Note that the reception time is defined in Msg2. The value of the reception time is 2, 3, 4, 5, 6, 7, 8, and 10, and the unit is a subframe. For example, when the value is set to 2, the mobile station monitors Msg2 continuously for two subframes after three subframes from the subframe next to the subframe that transmitted Msg1. Also, the reception time is defined for Msg4. The value of the reception time is 8, 16, 24, 32, 40, 48, 56, 64. For example, if the value is set to 8, the mobile station monitors Msg4 continuously for a maximum of 8 subframes counting from the subframe that transmitted Msg3.
In LTE-A and the like, in addition to the contention-type random access method, a contention-free random access method is defined. For example, in a base station, when downlink data (DL (Down Link) data) addressed to a specific mobile station is generated, if the mobile station is not in uplink synchronization, the base station is not connected to the mobile station to ensure uplink synchronization. Make contention type random access. FIG. 6 is a diagram illustrating an example of a non-contention type random access method.
Specifically, the base station first assigns an individual preamble ID to the specific mobile station with Msg0. Next, the mobile station starts random access using the assigned individual preamble ID in Msg1. Next, the base station returns a response to Msg1 together with a synchronization signal, transmission permission, etc. for uplink communication in Msg2. The mobile station acquires the uplink synchronization timing with this Msg2. In this non-contention type random access method, synchronization between devices is ensured by Msg1 and Msg2 (uplink synchronization is ensured).
In the base station, after “synchronization is ensured” in Msg1 and Msg2, data transmission / reception (DL data, ACK / NACK) with the mobile station is started.
Note that, in the non-contention type random access method, it is assumed that the individual preamble ID used in Msg0 is insufficient. For example, this is a case where a large number of mobile stations are performing handover in the cell of the base station. In handover, an individual preamble ID is assigned with Msg0, random access is performed at the destination base station, and uplink synchronization timing is ensured at high speed. Therefore, when many mobile stations are performing handover, many individual preamble IDs are used. In this case, the base station cannot cause the mobile station to execute non-contention random access due to a lack of dedicated preamble IDs, and therefore transmits an empty preamble ID (specifically “000000”) with Msg0. Then, the mobile station that has received this Msg0 executes the contention type random access. At this time, it is specified that Msg1 is transmitted on the PRACH nearest to the subframe that received Msg0.
Moreover, in LTE-A etc., the scheduling request method is prescribed | regulated as a technique used as the premise of the radio | wireless communication method of a present Example. For example, when uplink data (UL data) is generated in a mobile station, when a scheduling request resource is allocated and uplink synchronization is ensured, an uplink data transmission request is made by the scheduling request method. FIG. 7 is a diagram illustrating an example of a scheduling request method. Note that resource allocation (assignment of subframes permitted to transmit “SR PUCCH” and radio resources to be used) is specified in an upper layer.
Specifically, the mobile station transmits a scheduling request message (D-SR) that is an uplink data transmission permission using a specified radio resource at a specified subframe timing. Unlike the contention type random access, the base station that has received the D-SR can recognize the mobile station that has transmitted the D-SR, and therefore returns an uplink transmission permission message (UL grant) to the mobile station. After receiving the UL grant, the mobile station performs uplink data transmission (UL data, ACK / NACK).
Note that the base station does not always return a UL grant to the mobile station when receiving the D-SR (not specified in the specification). Therefore, in the case where the UL grant cannot be received from the base station, the mobile station continues to transmit the D-SR repeatedly until the UL grant can be received using the designated D-SR transmission timing and resources. The number of D-SRs that can be transmitted is defined by a parameter (count value) called SR_COUNTER and its maximum value dsr-TransMax. This maximum value is specified by the base station. That is, when “SR_COUNTER <dsr−TransMax” is satisfied, the mobile station continues to transmit D-SR. On the other hand, when “SR_COUNTER ≧ dsr−TransMax” is satisfied, the mobile station cannot transmit the D-SR because the allowable number of transmissions has been exceeded, so the uplink data transmission request is switched to the contention type random access. Do.
Moreover, in carrier aggregation, PUCCH exists in PCell. This is because PUCCH resources are valuable. Therefore, the scheduling request method is also executed by PCell.
In addition, a rule is set for properly using the random access method and the scheduling request method. That is, when “SR PUCCH” is not assigned to the mobile station, the mobile station makes an uplink data transmission request by the contention random access method. On the other hand, when “SR PUCCH” is assigned, the mobile station first makes an uplink data transmission request by the scheduling request method. When the uplink transmission permission cannot be obtained from the base station within the specified number of transmissions (D-SR transmission), the mobile station switches to an uplink data transmission request by the competitive random access method. That is, the random access method and the scheduling request method are executed exclusively and are not executed simultaneously.
In addition, as a technique that is a premise of the wireless communication method of the present embodiment, a case where the competitive random access method is executed by SCell in carrier aggregation will be described last. FIG. 8 is a diagram illustrating an example when the competitive random access method is executed in the SCell. Here, it is assumed that synchronization is not ensured in the SCell, and a case is assumed in which competitive random access is executed in order to ensure synchronization.
For example, when uplink data is generated and a buffer amount report trigger is generated by BSR, the mobile station transmits Msg1 including a preamble ID selected at random using the PRACH set on the SCell. Next, the base station returns a response (RA response) to Msg1 together with a synchronization signal, transmission permission, etc. for uplink communication in Msg2. Next, the mobile station transmits its own identifier (UE identifier) using Msg3. Then, the base station performs contention resolution with Msg4. As described above, when the competitive random access method is executed in the SCell, synchronization between devices is ensured by the Msg1 and Msg2 (uplink synchronization is ensured), and mobile station identification is performed by the Msg3 and Msg4. Hereinafter, the time required from transmitting Msg1 to receiving Msg4 is referred to as “time required for ensuring synchronization”.
Thereafter, the base station transmits an uplink transmission permission message (UL grant) to the mobile station. The mobile station that has received this message transmits the BSR using the PUSCH set on the SCell. When the base station determines that the addition of the SCell is necessary due to the reception of the BSR, the base station returns an uplink transmission permission message (UL grant) to the mobile station. After receiving the UL grant, the mobile station starts data transmission / reception (UL data) with the base station using the SCell.
However, as described above, when the competitive random access method is executed by the SCell in the carrier aggregation, the time required for ensuring synchronization (Msg1 to Msg4) is about 25 ms. Further, since it is necessary to obtain uplink transmission permission after ensuring synchronization, it takes about 10 ms to transmit uplink data. That is, there is a delay of about 35 ms from when the uplink data is generated until the uplink data is transmitted.
Therefore, in this embodiment, a random access method (wireless communication method) in the SCell is devised in order to realize high-speed communication.
Next, the wireless communication method of this embodiment will be described. FIG. 9 is a diagram illustrating an example of a wireless communication method according to the first embodiment. In the present embodiment, when uplink data occurs, the base station and the mobile station execute non-contention type random access using BSR transmission by the mobile station as a trigger. In this embodiment, it is assumed that uplink synchronization is ensured and uplink transmission resources are allocated in the PCell. In this embodiment, it is assumed that uplink synchronization is not secured in the SCell.
In FIG. 9, when uplink data is generated and a trigger for buffer amount reporting by BSR occurs, the mobile station transmits a BSR using PUSCH set on the PCell. For example, when the periodic BSR is set, the base station gives a UL grant to the mobile station at an appropriate timing for reporting the BSR at a periodic timing. Therefore, the mobile station can report its own buffer amount to the base station at a given periodic timing.
Next, the base station determines whether or not an SCell needs to be added based on the BSR (reported buffer amount) received from the mobile station. That is, the base station determines whether or not the data retention amount in the uplink buffer of the mobile station is large. When it is determined that the amount of uplink buffer retention is large and the addition of the SCell is necessary, the base station transmits Msg0 (Dedicated Preamble) including the dedicated preamble ID to the mobile station using the PDCCH set on the PCell. In addition, CIF (Carrier Indicator Field) is set in this Msg0, and the cell identifier of the cell transmitting Msg1 is specified in this field. That is, SCell used for transmission of Msg1 is designated in Msg0. As a result, the base station can cause the mobile station to execute non-contention random access at the designated SCell.
Next, when Msg0 is received by the PCell, the mobile station starts non-contention type random access, and uses the dedicated preamble ID assigned by Msg0, Msg1 (Preamble ID) on the PRACH set on the designated SCell. ).
Next, the base station returns a response (RA response) to Msg1 together with a synchronization signal, transmission permission, etc. for uplink communication in Msg2. The mobile station acquires the uplink synchronization timing with this Msg2. In the wireless communication method of the present embodiment, the synchronization of SCells between devices is ensured (uplink synchronization is secured) by transmitting and receiving Msg1 and Msg2.
Moreover, after transmitting Msg2, a base station transmits an uplink transmission permission message (UL grant) with respect to a mobile station by SCell. The mobile station performs “synchronization” at the Msg1 and Msg2, and after receiving the UL grant at the SCell, starts data transmission / reception (UL data) with the base station at the SCell.
As described above, in the wireless communication method of the present embodiment, when uplink data occurs, the mobile station transmits a BSR, and when the base station receives the BSR report and determines that an SCell needs to be added, The base station and the mobile station perform non-contention type random access. Thereby, since Msg3 and Msg4 in the conventional competitive random access can be omitted, the speed of uplink transmission can be increased.
FIG. 10 is a diagram illustrating the effect of the wireless communication method of the present embodiment. By implementing the wireless communication method of the present embodiment, the time required for ensuring synchronization can be shortened to about 12 ms as compared to about 25 ms in FIG.
In the wireless communication method according to the present embodiment, the time from when the base station receives BSR until it transmits Msg0 (transmission timing range) can be defined as parameter T. The value of the parameter T is, for example, the number of subframes in units of subframes. In the present embodiment, as an example, the base station notifies the mobile station of the value of the parameter T by dedicated signaling before starting data communication. FIG. 11 is a diagram illustrating an example of the dedicated signaling. Here, a base station notifies the value of T to a mobile station using "RRC Connection Reconfiguration" transmitted / received at the time of a communication start. Then, the mobile station returns “RRC Connection Reconfiguration Complete” as a response. FIG. 12 is a diagram showing another example of the dedicated signaling. Here, the base station notifies the mobile station of the value of T using “MAC Control Element”. Then, the mobile station returns ACK as a response.
The parameter T may be determined each time by the base station scheduling algorithm, or may be uniquely determined by the system (uniquely defined in the specification).
In the wireless communication method of the present embodiment, the case where the base station and the mobile station execute non-contention type random access is described. However, when an individual preamble ID that can be allocated is insufficient at the time of transmission of Msg0 and an individual preamble ID cannot be allocated to the mobile station, the base station uses Msg0 and an empty preamble ID (specifically, “000000”). )). In this case, since the mobile station that has received Msg0 cannot receive the dedicated preamble ID, the mobile station performs uplink transmission by executing the contention type random access shown in FIG.
Next, operations of the base station and mobile station that implement the wireless communication method of this embodiment will be described with reference to flowcharts. FIG. 13 is a flowchart showing the operation of a mobile station (transmitting apparatus) that transmits UL data (UL data), and FIG. 14 shows the operation of a base station (receiving apparatus) that receives UL data (UL data). It is a flowchart. In this embodiment, it is assumed that uplink synchronization is not secured in the SCell.
The operation of the mobile station will be described with reference to FIG. First, the transmission / reception control unit 34 receives the parameter T transmitted by “RRC Connection Reconfiguration” via the transmission / reception unit 11 and stores the parameter T in the storage unit 22 (S1). Thereafter, when UL data is generated, the BSR management unit 32 transmits the BSR using the PUSCH set on the PCell via the uplink transmission unit 12 and the transmission / reception unit 11 (S2). Although not illustrated because it is assumed that SCell uplink synchronization is not secured, the TA management unit 33 actually secures SCell uplink synchronization at a predetermined timing before BSR transmission. Judgment is made.
Next, the RA management unit 31 receives Msg0 via the PDCCH set on the PCell via the transmission / reception unit 11 (S3). At this time, the RA management unit 31 receives Msg0 in which CIF is set in the parameter T. Then, the RA management unit 31 determines whether or not the individual preamble ID is included in the received Msg0 (S4). For example, when the individual preamble ID is not included (S4, No), the RA management unit 31 performs the contention type random access shown in FIG. 5 (S11). On the other hand, when the dedicated preamble ID is included (S4, Yes), the RA management unit 31 uses the PRACH set on the SCell specified by the CIF via the uplink transmission unit 12 and the transmission / reception unit 11, Msg1 is transmitted (S5). In addition, the above-mentioned “when the individual preamble ID is not included” means the case where the preamble ID: “000000” is included.
Next, RA management part 31 receives Msg2 by SCell via transmission / reception part 11 (S6). Then, the TA management unit 33 adjusts the uplink synchronization timing based on Msg2 received by the RA management unit 31 (S7).
In addition, after the RA management unit 31 receives Msg2, the transmission / reception control unit 34 receives the UL grant at the SCell via the transmission / reception unit 11 (S8). Thereafter, the transmission / reception control unit 34 transmits UL data by the SCell via the uplink transmission unit 12 and the transmission / reception unit 11 (S9), and receives an acknowledgment (ACK / NACK) by the SCell as a response (S10).
Subsequently, the operation of the base station will be described with reference to FIG. First, the transmission / reception control unit 64 reads a parameter T stored in advance in the storage unit 52, and transmits the parameter T using the “RRC Connection Reconfiguration” via the transmission / reception unit 43 (S21). After that, when UL data is generated in the mobile station, the BSR management unit 62 receives the BSR through the transmission / reception unit 43 using the PUSCH set on the PCell (S22).
Next, when the BSR management unit 62 determines that the addition of the SCell is necessary based on the BSR, the RA management unit 61 transmits Msg0 on the PDCCH set on the PCell via the transmission / reception unit 43 (S23). ). At this time, the RA management unit 61 transmits Msg0 in which CIF is set in the parameter T. Then, the RA management unit 61 confirms whether or not the individual preamble ID is included in Msg0 (S24). For example, when Msg0 is transmitted without including the dedicated preamble ID (S24, No), the RA management unit 61 performs the contention type random access shown in FIG. 5 (S31). On the other hand, when Msg0 including the dedicated preamble ID is transmitted (S24, Yes), the RA management unit 61 receives Msg1 transmitted on the PRACH set on the SCell via the transmission / reception unit 43 (S25). ). Note that “when Msg0 is transmitted without including the individual preamble ID” means that Msg0 including the preamble ID: “000000” is transmitted.
Next, the TA management unit 63 calculates an uplink synchronization timing correction value corresponding to the mobile station that has transmitted Msg1 (S26). And RA management part 61 transmits Msg2 including an uplink synchronous timing correction value by SCell via transmission / reception part 43 (S27).
Moreover, after the RA management part 61 transmits Msg2, the transmission / reception control part 64 transmits UL grant by SCell via the transmission / reception part 43 (S28). Then, the transmission / reception control unit 64 receives UL data by the SCell via the transmission / reception unit 43 (S29), and returns an acknowledgment (ACK / NACK) by the SCell as a response (S30).
In the description using the flowchart (S1, S21), the parameter T is transmitted and received by “RRC Connection Reconfiguration”, but the present invention is not limited to this. For example, the parameter T may be transmitted and received using “MAC Control Element”.
As described above, in this embodiment, when uplink data occurs, the mobile station transmits a BSR, and when the base station receives a report of the BSR and determines that an SCell needs to be added, The mobile station decided to execute non-contention type random access. As a result, Msg3 and Msg4 can be omitted as compared with the case where uplink transmission is performed by executing contention-type random access, so that the time required for ensuring synchronization can be shortened. That is, the communication speed can be increased as a whole system.
In this embodiment, it is assumed that uplink synchronization is ensured and uplink transmission resources are allocated in the PCell. However, the present invention is not limited to this, and the radio communication method of the present embodiment allocates uplink transmission resources. Even if not, it can be realized. FIG. 15 is a diagram illustrating an example of a wireless communication method when uplink transmission resources are not allocated in the PCell. In FIG. 15, the mobile station notifies the base station of the occurrence of uplink data by transmitting D-SR, which is an uplink data transmission permission request, on the PUCCH set on the PCell. And the base station which received D-SR returns an uplink transmission permission message (UL grant) with PCell with respect to a mobile station. As a result, the mobile station can execute the wireless communication method shown in FIG. 9 using the reception of this UL grant as a trigger. Such an operation is applied, for example, when uplink data with a high priority occurs.
In this embodiment, Msg0 (Dedicated Preamble) including the dedicated preamble ID is transmitted to the mobile station using the PDCCH set on the PCell. However, the present invention is not limited to this, and Msg0 may be transmitted by the SCell. Good. FIG. 16 is a diagram illustrating a wireless communication method when Msg0 is transmitted by the SCell. In FIG. 16, the base station determines whether or not the addition of the SCell is necessary based on the BSR received from the mobile station, and determines that the addition of the SCell is necessary. Msg0 (Dedicated Preamble) including the ID is transmitted. In addition, since Msg0 is transmitted by SCell here, it is not necessary to set CIF. Further, after transmitting the BSR, the mobile station sets the SCell in an active state in order to receive Msg0 by the SCell. As a result, the mobile station can execute non-contention random access in the SCell that has received Msg0.
A wireless communication method according to the second embodiment will be described. In the second embodiment, it is assumed that the individual preamble ID is insufficient in the wireless communication method of the first embodiment.
FIG. 17 is a diagram illustrating a configuration example of a mobile station (transmission device) in a wireless communication system, and FIG. 18 is a diagram illustrating a configuration example of a base station (reception device) in the wireless communication system. In addition, about the structure similar to the mobile station and base station of Example 1 mentioned above, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
In FIG. 17, the mobile station of the second embodiment has a control unit 13a instead of the control unit 13 of the first embodiment. The data plane unit 30a of the control unit 13a includes a PUSCH management unit 35 in addition to functions equivalent to those of the data plane unit 30 of the first embodiment. The PUSCH management unit 35 controls processing related to BSR transmission and processing related to shared preamble ID transmission.
In FIG. 18, the base station according to the second embodiment includes a control unit 44a instead of the control unit 44 according to the first embodiment. The data plane unit 60a of the control unit 44a has a PUSCH management unit 65 in addition to functions equivalent to those of the data plane unit 60 of the first embodiment. The PUSCH management unit 65 controls processing related to BSR reception and processing related to shared preamble ID reception.
In this embodiment, as an example, a wireless communication method of a wireless communication system including a mobile station (transmitting device) and a base station (receiving device) will be described, but the relationship between the transmitting device and the receiving device is not limited thereto. is not. For example, the wireless communication method of this embodiment is similarly applied to a system including a relay station (transmitting device) and a base station (receiving device) or a system including a mobile station (transmitting device) and a relay station (receiving device). Applicable. Further, the above-described configuration examples of the mobile station and the base station are listed for the sake of convenience of description, and the configuration (each functional unit) related to the processing of the present embodiment is listed, and all the functions of the mobile station and the base station are expressed. It is not a thing. In addition, each functional unit of the mobile station and the base station can be configured by, for example, a CPU, FPGA, memory, and the like.
Next, the wireless communication method of this embodiment will be described. FIG. 19 is a diagram illustrating an example of a wireless communication method according to the second embodiment. In this embodiment, when uplink data occurs, the base station and the mobile station execute predetermined random access using the BSR transmission by the mobile station as a trigger. In this embodiment, it is assumed that uplink synchronization is ensured and uplink transmission resources are allocated in the PCell. In this embodiment, it is assumed that uplink synchronization is not secured in the SCell. Further, in this embodiment, it is assumed that the dedicated preamble ID is insufficient and the base station transmits the preamble ID: “000000” with Msg0 (when transmitting Msg0 that does not include the dedicated preamble ID).
In FIG. 19, when uplink data is generated and a buffer amount report trigger is generated by the BSR, the mobile station transmits the BSR using the PUSCH set on the PCell.
Next, the base station determines whether or not an SCell needs to be added based on the BSR (reported buffer amount) received from the mobile station. When it is determined that there is a large amount of uplink buffer retention and it is necessary to add an SCell, the base station transmits Msg0 to the mobile station using the PDCCH set on the PCell. However, as described above, in this embodiment, since the individual preamble is insufficient, Msg0 includes “000000” as the preamble ID. That is, the base station transmits Msg0 not including the dedicated preamble ID to the mobile station. In addition, CIF is set in this Msg0, and a cell identifier for transmitting Msg1 (SCell identifier used for transmitting Msg1) is designated in this field.
In addition, the base station transmits a UL grant (“DCI format 0” is used as defined by LTE) to the mobile station in a subframe near the subframe that transmitted Msg0. That is, the base station transmits Msg0 and UL grant to the mobile station using PCell.
On the other hand, the mobile station that has received Msg0 and UL grant at the PCell starts competitive random access at the SCell using these receptions as triggers. That is, the mobile station transmits Msg1 including a randomly selected shared preamble ID to the base station using the PRACH set on the SCell. In addition, the mobile station transmits a shared preamble ID identical to the shared preamble ID included in Msg1 to the base station using the PUSCH set on the PCell. At this time, the mobile station transmits the shared preamble ID in a subframe that is the same as or close to the subframe that transmits Msg1. That is, the mobile station transmits Msg1 using SCell and the shared preamble ID using PCell to the base station.
Next, the base station that has received the Msg1 by the SCell and the shared preamble ID by the PCell determines that the mobile station that has transmitted the Msg1 is the same as the mobile station to which the PUSCH resource is allocated, and uniquely identifies the mobile station. To be specific. Although the base station cannot recognize the identifier of a valid mobile station only by Msg1, it can identify the mobile station that has transmitted Msg1 by receiving the shared preamble ID on the PUSCH set on the PCell. And a base station returns ACK by PCell, after receiving shared preamble ID by PCell.
Thereafter, in the same process as in the first embodiment, the base station transmits Msg2 and UL grant in the SCell, and the mobile station that has secured uplink synchronization in Msg2 receives the UL grant, and then transmits and receives data to and from the base station ( UL data) is started.
Thus, in this embodiment, the mobile station transmits Msg1 using the PRACH set on the SCell, and uses the same shared preamble ID as the shared preamble ID included in the Msg1 using the PUSCH set on the PCell. Send. On the other hand, the base station uniquely identifies the mobile station that has transmitted Msg1 by receiving Msg1 at the SCell, receiving the shared preamble ID at the PCell, and associating them. As a result, Msg3 and Msg4 (mobile station identification processing) in the conventional competitive random access can be deleted, so that the speed of uplink transmission can be increased.
In the wireless communication method of the present embodiment, the time from when the base station receives the BSR until it transmits Msg0 (range of transmission timing) is defined as the parameter T as in the first embodiment. Can do.
Further, in the wireless communication method of the present embodiment, the section (transmission timing range) in which the base station transmits Msg0 and UL grant in the PCell may be defined as the parameter X (including “X = 0”). it can. The value of the parameter X is, for example, the number of subframes in units of subframes. In the present embodiment, as shown in FIG. 11 or FIG. 12 described above, the base station notifies the mobile station of the value of the parameter X by dedicated signaling before starting data communication.
Further, in the wireless communication method of the present embodiment, the section (transmission timing range) in which the mobile station transmits Msg1 (SCell) and the shared preamble ID (PCell) is set to parameter Y (including “Y = 0”). As default. The value of parameter Y is, for example, the number of subframes in units of subframes. In the present embodiment, as shown in FIG. 11 or FIG. 12 described above, the base station notifies the mobile station of the value of the parameter Y by dedicated signaling before starting data communication.
In addition, as a method for realizing the above-mentioned process of “transmitting a shared preamble ID that is the same as the shared preamble ID included in Msg1 on the PUSCH set on the PCell”, the following two types of methods are used: There is. The first method explicitly includes the shared preamble ID in the PUSCH. For example, in order to notify the shared preamble ID, a new “MAC CE” is defined, and transmission is performed using this “MAC CE”. It is a method to do. FIG. 20 is a diagram illustrating a “first method” in which a mobile station transmits a shared preamble ID using a PUSCH set on a PCell. In the first method, the base station can easily detect that the shared preamble ID is included. The second method is a method of implicitly including the shared preamble ID, for example, a method of embedding the shared preamble ID in the PUSCH. An algorithm for embedding the shared preamble ID in the PUSCH is defined in advance in the specification. In the second method, after transmitting Msg0 and UL grant, the base station performs reception processing on the assumption that the shared preamble ID is received on the PUSCH. FIG. 21 is a diagram illustrating a “second method” in which the mobile station transmits the shared preamble ID using the PUSCH set on the PCell. In the second method, the signaling overhead can be reduced as compared with the first method.
Subsequently, in the wireless communication method of the present embodiment, an operation when the base station cannot receive the shared preamble ID on the PUSCH set on the PCell will be described. FIG. 22 is a diagram illustrating an example when the base station fails to receive the shared preamble ID in the PCell. Specifically, in the case where the mobile station transmits Msg1 with the SCell and the shared preamble ID with the PCell, respectively, the case where the base station has not received the shared preamble ID with the PCell is shown. .
For example, when reception of the shared preamble ID transmitted on the PUSCH set on the PCell fails, the base station cannot identify the mobile station that has transmitted Msg1, and therefore transmits a NACK on the PCell. Further, the base station transmits Msg2 including “Backoff Indicator” for instructing retransmission in SCell.
After transmitting Msg1 and the shared preamble ID, the mobile station receives NACK in the PCell and Msg2 including “Backoff Indicator” in the SCell, so that the base station fails to receive the shared preamble ID and can identify itself. Judge that it was not.
Therefore, in this embodiment, the mobile station retransmits Msg1 and the shared preamble ID as shown in FIG. That is, the mobile station retransmits Msg1 with the PRACH set on the SCell and the shared preamble ID with the PUSCH set on the PCell, respectively, to the base station.
Thereafter, the mobile station repeatedly performs retransmission of Msg1 and the shared preamble ID until receiving ACK at the PCell and normal Msg2 (Msg2 not including “Backoff Indicator”) at the SCell. And a mobile station receives ACK by PCell, normal Msg2 by SCell, and also after receiving UL grant by SCell, it starts data transmission / reception (UL data) with a base station.
In FIG. 22, the base station transmits NACK by PCell and transmits Msg2 including “Backoff Indicator” by SCell as an example. However, here, Msg2 including “Backoff Indicator” is transmitted. May be omitted. In this case, the mobile station determines that the base station failed to receive the shared preamble ID and could not identify itself with only the NACK received by the PCell.
FIG. 23 is a diagram illustrating an example of the case where the base station cannot receive the shared preamble ID in the PCell, as in FIG. 22, but the process between the mobile station and the base station is different from that in FIG. 22. To exchange data between. Here, processing different from FIG. 22 will be described.
After transmitting Msg1 and shared preamble ID, the mobile station receives NACK in PCell and Msg2 including “Backoff Indicator” in SCell, and the base station fails to receive the shared preamble ID and cannot identify itself. Judge that At this time, in FIG. 23, the mobile station starts the contention-type random access shown in FIG. That is, when the base station fails to receive the shared preamble ID transmitted on the PUSCH set on the PCell, the mobile station and the base station execute the processes of Msg1 to Msg4 in the competitive random access in the SCell. And a mobile station receives Msg4 by SCell from a base station, Furthermore, after receiving UL grant by SCell, it starts data transmission / reception (UL data) with a base station.
Further, in the present embodiment, the example of FIG. 22 or FIG. 23 is shown as the operation when the base station cannot receive the shared preamble ID through the PUSCH set on the PCell, but is not limited thereto. For example, the operations in FIGS. 22 and 23 may be combined. Specifically, the maximum number of retransmissions shown in FIG. 22 is defined, and when the maximum number of retransmissions is reached, the contention type random access (Msg1 to Msg4) of FIG. 23 may be performed. .
Next, operations of the base station and mobile station that implement the wireless communication method of this embodiment will be described with reference to flowcharts. FIG. 24 is a flowchart showing the operation of a mobile station (transmitting device) that transmits UL data (UL data), and FIG. 25 shows the operation of a base station (receiving device) that receives UL data (UL data). It is a flowchart. In this embodiment, it is assumed that uplink synchronization is not secured in the SCell. In this embodiment, it is assumed that the dedicated preamble ID is insufficient and the base station transmits the preamble ID: “000000” with Msg0.
The operation of the mobile station will be described with reference to FIG. First, the transmission / reception control unit 34 receives the parameters T, X, and Y sent by “RRC Connection Reconfiguration” via the transmission / reception unit 11 and stores them in the storage unit 22 (S41). Thereafter, when UL data is generated, the PUSCH management unit 35 transmits the BSR using the PUSCH set on the PCell via the uplink transmission unit 12 and the transmission / reception unit 11 (S42). Although not illustrated because it is assumed that SCell uplink synchronization is not secured, the TA management unit 33 actually secures SCell uplink synchronization at a predetermined timing before BSR transmission. Judgment is made.
Next, the RA management unit 31 receives Msg0 via the PDCCH set on the PCell via the transmission / reception unit 11 (S43). At this time, the RA management unit 31 receives Msg0 in which CIF is set in the parameter T. Further, the RA management unit 31 receives the UL grant in the subframe on the PCell in the vicinity (in X) of the subframe that has received Msg0 via the transmission / reception unit 11 (S43).
Next, the RA management unit 31 randomly selects a shared preamble ID (S44). Then, Msg1 including the selected shared preamble ID is transmitted via the PRACH set on the SCell designated by the CIF via the uplink transmission unit 12 and the transmission / reception unit 11 (S45). As a result, the mobile station starts contention-type random access. Also, the PUSCH management unit 35 transmits the shared preamble ID that is the same as the shared preamble ID included in Msg1 through the uplink transmission unit 12 and the transmission / reception unit 11 on the PUSCH set on the PCell (S45). At this time, the PUSCH management unit 35 transmits the shared preamble ID in a subframe that is the same as or close to (in Y) the subframe in which Msg1 is transmitted.
Next, the PUSCH management part 35 confirms the confirmation response (ACK, NACK) sent by PCell via the transmission / reception part 11 (S46). For example, when the confirmation response is ACK (S46, Yes), the RA management unit 31 receives Msg2 by the SCell via the transmission / reception unit 11 (S47). Then, the TA management unit 33 adjusts the uplink synchronization timing based on Msg2 received by the RA management unit 31 (S47).
In addition, after the RA management unit 31 receives Msg2, the transmission / reception control unit 34 receives the UL grant at the SCell via the transmission / reception unit 11 (S48). Thereafter, the transmission / reception control unit 34 transmits UL data by the SCell via the uplink transmission unit 12 and the transmission / reception unit 11 (S49), and receives an acknowledgment (ACK / NACK) by the SCell as a response (S50).
On the other hand, if the PCSCH receives a NACK in the PCell in the process of S46 (S46, No), the PUSCH management unit 35 determines whether the number of retransmissions of the shared preamble ID has reached a predetermined maximum number. (S51). For example, when the number of retransmissions of the shared preamble ID has not reached the predetermined maximum number (S51, No), the RA management unit 31 and the PUSCH management unit 35 execute the process of S45 again. That is, the RA management unit 31 transmits Msg1 including the shared preamble ID on the PRACH set on the SCell, and the PUSCH management unit 35 transmits the shared preamble ID on the PUSCH set on the PCell (S45).
Further, in the process of S51, when the number of times of retransmission of the shared preamble ID has reached a predetermined maximum number (S51, Yes), the RA management unit 31 executes the contention type random access shown in FIG. (S52). And the transmission / reception control part 34 transmits UL data by SCell via the uplink transmission part 12 and the transmission / reception part 11 after receiving UL grant by SCell via the transmission / reception part 11 (S48).
Subsequently, the operation of the base station will be described with reference to FIG. First, the transmission / reception control unit 64 reads parameters T, X, and Y stored in advance in the storage unit 52, and transmits these parameters using the “RRC Connection Reconfiguration” via the transmission / reception unit 43 (S61). . Thereafter, when UL data is generated in the mobile station, the PUSCH management unit 65 receives the BSR on the PUSCH set on the PCell via the transmission / reception unit 43 (S62).
Next, the RA management unit 61 transmits Msg0 on the PDCCH set on the PCell via the transmission / reception unit 43 (S63). At this time, the RA management unit 61 transmits Msg0 in which CIF is set in the parameter T. Further, the RA management unit 61 transmits a UL grant in a subframe on the PCell in the vicinity (in X) of the subframe that has transmitted Msg0 via the transmission / reception unit 43 (S63).
Next, the RA management unit 61 receives Msg1 including the shared preamble ID on the PRACH set on the SCell specified by the CIF via the transmission / reception unit 43 (S64). Further, the PUSCH management unit 65 executes a process for receiving the same shared preamble ID as the shared preamble ID included in Msg1 with the PUSCH set on the PCell (S64). At this time, the PUSCH management unit 65 executes a process for receiving the shared preamble ID in a subframe that is the same as or close to (in Y) the subframe in which Msg1 is placed.
Next, when the shared preamble ID reception process is successful (S65, Yes), the PUSCH management unit 65 determines that “the mobile station that transmitted Msg1 is the same as the mobile station to which the PUSCH resource is allocated”, and Msg1. Uniquely identifies the mobile station that transmitted. Then, the TA management unit 63 calculates an uplink synchronization timing correction value corresponding to the mobile station that has transmitted Msg1 (S66).
Next, the PUSCH management part 65 transmits ACK by PCell via the transmission / reception part 43 (S67). Further, the RA management unit 61 transmits Msg2 including the uplink synchronization timing correction value in the SCell via the transmission / reception unit 43 (S67).
Moreover, after the RA management part 61 transmits Msg2, the transmission / reception control part 64 transmits UL grant by SCell via the transmission / reception part 43 (S68). Then, the transmission / reception control unit 64 receives UL data in the SCell via the transmission / reception unit 43 (S69), and returns an acknowledgment (ACK / NACK) in response to the SCell (S70).
On the other hand, when the reception of the shared preamble ID has failed in the process of S65 (No in S65), the PUSCH management unit 65 determines whether the number of retransmissions of the shared preamble ID has reached a predetermined maximum number. (S71). For example, when the number of retransmissions of the shared preamble ID has not reached the predetermined maximum number (S71, No), the RA management unit 61 and the PUSCH management unit 65 execute the process of S64 again. That is, the RA management unit 61 receives Msg1 including the shared preamble ID on the PRACH set on the SCell, and the PUSCH management unit 65 performs processing for receiving the shared preamble ID on the PUSCH set on the PCell. Perform (S64).
Also, in the process of S71, when the number of retransmissions of the shared preamble ID has reached the predetermined maximum number (S71, Yes), the RA management unit 61 executes the contention type random access shown in FIG. (S72). And the transmission / reception control part 64 receives UL data by SCell via the transmission / reception part 43, after transmitting UL grant by SCell via the transmission / reception part 43 (S69).
In the description using the flowchart (S41, S61), each parameter is transmitted and received by “RRC Connection Reconfiguration”, but the present invention is not limited to this. For example, each parameter may be transmitted and received using “MAC Control Element”.
As described above, in this embodiment, when uplink data occurs, the mobile station transmits a BSR, and when the base station receives a report of the BSR and determines that an SCell needs to be added, The mobile station decides to execute competitive random access. At this time, the mobile station transmits Msg1 on the PRACH set on the SCell, and further transmits the same shared preamble ID as the shared preamble ID included in Msg1 on the PUSCH set on the PCell. did. Then, the base station determines that “the mobile station that transmitted Msg1 is the same as the mobile station to which the PUSCH resource is allocated”, and uniquely identifies the mobile station that transmitted Msg1. As a result, Msg3 and Msg4 (mobile station identification processing) in contention-type random access can be omitted, and the time required for ensuring synchronization can be shortened. That is, the communication speed can be increased as a whole system.
In this embodiment, Msg0 is transmitted to the mobile station using the PDCCH set on the PCell. However, the present invention is not limited to this, and Msg0 may be transmitted using the SCell. FIG. 26 is a diagram illustrating the wireless communication method according to the second embodiment when Msg0 is transmitted by the SCell. In FIG. 26, the base station determines whether or not the addition of the SCell is necessary based on the BSR received from the mobile station. Send. In addition, since Msg0 is transmitted by SCell here, it is not necessary to set CIF. Further, after transmitting the BSR, the mobile station sets the SCell in an active state in order to receive Msg0 by the SCell. As a result, the mobile station can execute contention-type random access on the SCell that has received Msg0.
11, 41, 43 Transmission / reception unit 12 Uplink transmission unit 13, 13a, 44, 44a Control unit 14, 45 Antenna 20, 50 Control plane unit 21, 51 Physical channel control unit 22, 52 Storage unit 30, 30a, 60, 60a Data Plain section 31, 61 RA management section 32, 62 BSR management section 33, 63 TA management section 34, 64 Transmission / reception control section 35, 65 PUSCH management section 42 Scheduling section
In a wireless communication system capable of wireless communication using a plurality of wireless carriers,
A first controller that transmits a buffer status on a first radio carrier;
A first random access management unit for managing random access in the own device;
A second controller that receives the state of the buffer on the first wireless carrier and performs data transmission / reception on the second wireless carrier based on the state of the buffer;
A second random access management unit for managing random access in the own device;
When the second control unit performs data transmission / reception on the second radio carrier, the second random access management unit transmits control information including a device-specific individual preamble,
Using the transmission and reception of the control information as a trigger, the first and second random access management units execute non-contention type random access using the dedicated preamble on the second radio carrier.
The second random access management unit transmits control information including the dedicated preamble on the first radio carrier.
The second random access management unit includes identification information for identifying the second radio carrier in the control information.
When a resource for transmitting the buffer state is not allocated in the first radio carrier, the transmitting device transmits a data transmission permission request message to the receiving device, and receives data from the receiving device as a response to the data transmission permission request message. Receive a send permission message,
The first control unit transmits the state of the buffer after receiving the data transmission permission message.
The second random access management unit transmits control information including the dedicated preamble on the second radio carrier.
The transmitter activates the second radio carrier to receive the control information after the first controller transmits the state of the buffer.
When the second control unit performs data transmission / reception on the second radio carrier and the dedicated preamble is insufficient, the second random access management unit sets an empty preamble. Send control information including,
In the transmission device, the first random access management unit performs contention type random access by transmitting a randomly selected shared preamble on the second radio carrier, triggered by reception of the control information. The first control unit transmits the shared preamble on the first radio carrier;
In the receiving device, the second random access management unit associates the shared preamble received on the second radio carrier with the shared preamble received on the first radio carrier by the second control unit. Identify the transmitting device that sent the shared preamble,
The transmitting device starts data transmission to the receiving device after the synchronization of the second radio carrier is ensured by execution of the contention type random access.
The first control unit transmits a shared preamble on a shared channel set in the first radio carrier;
The first control unit transmits a shared preamble in a subframe within a predetermined range from a subframe in which the first random access management unit transmits a shared preamble.
When the second control unit fails to receive the shared preamble sent on the first radio carrier,
In the transmission device, the transmission of the shared preamble by the first random access management unit and the transmission of the shared preamble by the first control unit are repeatedly performed until the second control unit can receive the shared preamble. To
When the second control unit performs data transmission / reception on the second radio carrier, the second random access management unit transmits control information including an empty preamble,
The wireless communication system according to claim 11.
When performing wireless communication by carrier aggregation,
The first radio carrier is a primary cell,
The second radio carrier is a secondary cell,
In a receiving apparatus capable of receiving data using a plurality of wireless carriers,
A control unit that receives a buffer state from the transmission device on the first wireless carrier and performs data transmission / reception on the second wireless carrier based on the buffer state;
A random access management unit that transmits control information including a device-specific dedicated preamble when the control unit performs data transmission and reception on the second wireless carrier;
The random access management unit transmits control information including the dedicated preamble on the first radio carrier.
The receiving apparatus according to claim 16.
The random access management unit transmits control information including the dedicated preamble on the second radio carrier.
When the control unit performs data transmission / reception on the second radio carrier, and when the dedicated preamble is insufficient, the random access management unit transmits control information including an empty preamble,
When the transmission apparatus transmits a shared preamble selected at random on the second radio carrier, triggered by reception of the control information, and further transmits the shared preamble on the first radio carrier,
The random access management unit identifies the transmission apparatus that has transmitted the shared preamble by associating the shared preamble received by the second radio carrier with the shared preamble received by the control unit on the first radio carrier. ,
A controller that receives the state of the buffer on the first wireless carrier and performs data transmission / reception on the second wireless carrier based on the state of the buffer;
A random access management unit for managing random access in its own device;
When the control unit performs data transmission / reception on the second radio carrier, the random access management unit transmits control information including an empty preamble,
The random access management unit identifies the transmission apparatus that has transmitted the shared preamble by associating the shared preamble received by the second radio carrier with the shared preamble received by the control unit on the first radio carrier. To
In a transmitter capable of transmitting data using a plurality of wireless carriers,
A controller that transmits the buffer status on a first radio carrier;
When the receiving apparatus performs data transmission / reception on the second radio carrier based on the state of the buffer and transmits control information including a dedicated preamble unique to the apparatus,
The random access management unit performs non-contention type random access using the dedicated preamble on the second radio carrier, triggered by reception of the control information.
The random access management unit receives control information including the dedicated preamble on the first radio carrier.
The transmitting apparatus according to claim 21, wherein:
The random access management unit receives control information including the dedicated preamble on the second radio carrier.
When the receiving device performs data transmission / reception on the second radio carrier and transmits control information including an empty preamble,
Using the reception of the control information as a trigger, the random access management unit transmits a randomly selected shared preamble on the second radio carrier, and further, the control unit transmits the shared radio on the first radio carrier. Send the preamble,
The control unit transmits a shared preamble on a shared channel set in the first radio carrier;
25. The transmission apparatus according to claim 24.
When the receiving apparatus fails to receive the shared preamble sent on the first wireless carrier,
Repeatedly executing the transmission of the shared preamble by the random access management unit and the transmission of the shared preamble by the control unit until the receiving apparatus can receive the shared preamble;
When the receiving apparatus performs data transmission / reception on the second radio carrier and transmits control information including an empty preamble,
Using the reception of the control information as a trigger, the random access management unit transmits a randomly selected shared preamble on the second radio carrier, and the control unit transmits the shared radio on the first radio carrier. Send the preamble,
The transmission apparatus according to claim 27.
A wireless communication method in a wireless communication system capable of wireless communication using a plurality of wireless carriers,
The transmitter transmits the buffer status on the first radio carrier,
When the receiving device receives the state of the buffer on the first wireless carrier and performs data transmission / reception on the second wireless carrier based on the state of the buffer, control information including a device-specific individual preamble is received. Send
Using the transmission / reception of the control information as a trigger, the transmission device and the reception signal execute non-contention type random access using the dedicated preamble on the second radio carrier.
In the case of performing data transmission / reception on the second wireless carrier and when the dedicated preamble is insufficient, the receiving device transmits control information including an empty preamble,
The transmission device starts a contention-type random access by transmitting a randomly selected shared preamble on the second radio carrier with the reception of the control information as a trigger, and further, the first radio Transmitting the shared preamble on a carrier,
The receiving apparatus identifies a transmitting apparatus that has transmitted a shared preamble by associating a shared preamble received on the second radio carrier with a shared preamble received on the first radio carrier;
When the receiving apparatus receives the state of the buffer on the first wireless carrier and performs data transmission / reception on the second wireless carrier based on the state of the buffer, the receiving apparatus transmits control information including an empty preamble. ,
The receiving apparatus identifies the transmitting apparatus that has transmitted the shared preamble by associating the shared preamble received on the second radio carrier with the shared preamble received on the first radio carrier;
The transmitting device starts data transmission to the receiving device after synchronization of the second radio carrier is ensured by execution of the contention-type random access;
JP2012556722A 2011-02-10 2011-02-10 Wireless communication system, receiving apparatus, transmitting apparatus, and wireless communication method Active JP5565475B2 (en)
JPWO2012108046A1 true JPWO2012108046A1 (en) 2014-07-03
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