JP2015154106A - Mobile station device, and base station device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mobile station device and a base station device, capable of reducing power consumption in a single uplink connection.SOLUTION: A mobile station device which communicates with a first and a second base station devices, simultaneously connects with the first and second base station devices. The mobile station communicates with the first base station device through a predetermined first sub-frame, and communicates with the second base station device through a predetermined second frame different from the first sub-frame, using first control information.

Description

  The present invention relates to a mobile station apparatus and a base station apparatus.

  A scalability function related to a single uplink function has been proposed by dual connection of a macro cell base station apparatus, a small cell base station apparatus, and a mobile station apparatus. This is because the mobile station apparatus transmits HARQ (hybrid automatic repeat request) feedback to the macro cell base station apparatus and the small cell base station apparatus in a time division multiplexing manner, and the mobile station apparatus is connected in an uplink connection for only one cell. And transferring information between cells. Also, in the single uplink connection method of HARQ feedback, when the dual downlink connection between the macro cell base station apparatus and the small cell base station apparatus, the uplink is a single uplink connection using a time division multiplexing system, and the macro cell base station The data rate of the macro cell base station device and the small cell base station device is increased by performing HARQ feedback for a plurality of frames alternately between the station device and the small cell base station device (see Non-Patent Document 1).

  Further, for example, the technique described in Patent Document 1 detects that the iterative encoding method is used for transmission of the data burst, and at least the transmission of the data burst not using the iterative encoding method, A part of which is compliant with a hybrid automatic repeat request (HARQ) signaling protocol and is notified in each of a plurality of consecutive frames.

Special table 2012-533929 gazette

AUSTeK, “Discussion on dual connectivity for single UL CC capable UEs”, 3GPP TSG-RAN WG2 Meeting # 82 R2-131848

  However, in a single uplink connection, HARQ_ACK (HARQ Acknowledgment) that is a response to HARQ feedback to the macro cell base station apparatus and HARQ_ACK that is a response to HARQ feedback to the small cell base station apparatus are alternately used in one radio system. Therefore, there is a problem that power consumption increases due to switching to a frequency for each base station apparatus.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a mobile station apparatus and a base station apparatus that can reduce power consumption in a single uplink connection.

  The present invention has been made to solve the above problems, and a first aspect of the present invention is a mobile station apparatus that communicates with a first base station apparatus and a second base station apparatus. The first base station apparatus and the second base station apparatus are connected simultaneously to communicate with the first base station apparatus in a predetermined first subframe, and the second base station apparatus is connected to the first base station apparatus. A mobile station apparatus characterized by using first control information for performing communication in a predetermined second subframe different from the subframe.

  According to the mobile station apparatus and the base station apparatus of the present invention, it is possible to reduce power consumption in a single uplink connection.

It is explanatory drawing explaining an example of the communication condition of the communication system which concerns on the 1st Embodiment of this invention. It is explanatory drawing explaining another example of the communication condition of the communication system which concerns on the 1st Embodiment of this invention. It is explanatory drawing explaining another example of the communication condition of the communication system which concerns on the 1st Embodiment of this invention. It is a schematic block diagram which shows an example of a structure of the macrocell base station apparatus which concerns on the 1st Embodiment of this invention. It is a schematic block diagram which shows an example of a structure of the small cell base station apparatus which concerns on the 1st Embodiment of this invention. It is a schematic block diagram which shows an example of a structure of the mobile station apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows an example of the process at the time of the start of the data communication of the mobile station apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows an example of the process at the time of the data communication of the mobile station apparatus which concerns on the 1st Embodiment of this invention. It is a sequence diagram which shows an example of the uplink switching process which concerns on the 1st Embodiment of this invention. It is a flowchart which shows an example of the process in the mobile station apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows an example of the process in the macrocell base station apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows an example of the process in the small cell base station apparatus which concerns on the 1st Embodiment of this invention.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic diagram illustrating an example of a communication status S1 of the communication system S according to the first embodiment of the present invention.
The communication system S includes a first base station device, a second base station device, and a mobile station device 3. The first base station device is, for example, the macro cell base station device 1. The second base station device is, for example, the small cell base station device 2.

  The macro cell base station apparatus 1 uses the cell CM as a communication range, and communicates with the mobile station apparatus 3 in the cell CM. Further, the small cell base station device 2 uses the cell CS as a communication range, and communicates with the mobile station device 3 in the cell CS. In the illustrated example, the cell CS overlaps with a part of the cell CM, and the mobile station device 3 exists in the overlapping portion. Therefore, the mobile station device 3 includes the macro cell base station device 1, the small cell base station device 2, Communicate.

Here, DL in the figure represents the downlink, that is, the direction of communication from each base station apparatus to the mobile station apparatus 3, and UL represents the uplink, that is, communication from the mobile station apparatus 3 to each base station apparatus. Represents the direction.
In this example, the mobile station apparatus 3 is connected to the macrocell base station apparatus 1 and the small cell base station apparatus 2 by a plurality of links in the downlink DL, for example, two links (hereinafter also referred to as dual links), and performs dual communication. In the mode, communication is performed simultaneously with the two base station apparatuses. Similarly, in the uplink UL, the mobile station apparatus 3 is connected to the macro cell base station apparatus 1 and the small cell base station apparatus 2 by a plurality of links, for example, dual links, and is connected to a plurality of communication modes (hereinafter referred to as dual communication modes). Communication) with the two base station apparatuses.

That is, in the communication status S1 of the communication system S, the mobile station device 3 communicates simultaneously with the macro cell base station device 1 and the small cell base station device 2 in the downlink DL in the dual communication mode, and the macro cell base station device 1 and the small cell base station device 1 Communication with each cell base station apparatus 2 is performed in uplink UL in a dual communication mode using HARQ (hybrid automatic repeat request) feedback simultaneously.
An example of the HARQ feedback data format (subframe configuration in the uplink multiple communication mode) used at this time is the table T1.
In the following description, the HARQ feedback format shown in the table T1 is also referred to as a multiple UL format.

  In the illustrated example, the table T1 includes subframe numbers, a macro cell HARQ process (DL) representing the downlink HARQ process of the macro cell base station device 1, and a small HARQ process representing the downlink HARQ process of the small cell base station device 2. HARQ process (DL) of the cell, HARQ ACK (UL) to the macro cell indicating uplink HARQ ACK from the mobile station device 3 to the macro cell base station device 1, and from the mobile station device 3 to the small cell base station device 2 Small cell HARQ ACK (UL) representing uplink HARQ ACK, and a row and a column having each item row of subframe numbers n, n + 1, n + 2,..., N + 15 corresponding to each item row Is a two-dimensional table format table.

  In the illustrated example, the uplink UL is in the dual communication mode, that is, the mobile station device 3 and the macro cell base station device 1 are connected to each other, and the mobile station device 3 and the small cell base station device 2 are connected to perform communication in the communication mode. Is going. That is, the HARQ ACK corresponding to each subframe number indicated in the macro cell HARQ process (DL) or the small cell HARQ process (DL) is the HARQ ACK (UL) to the macro cell or the HARQ ACK (UL) to the small cell. This indicates that transmission is performed with each subframe number indicated in (). For example, the HARQ ACK corresponding to the HARQ process (DL) 0 of the macro cell of the subframe number n indicates that the HARQ ACK (UL) 0 is transmitted to the macro cell of the subframe number n + 4.

FIG. 2 is a schematic diagram illustrating an example of a communication status S2 of the communication system S according to the first embodiment of the present invention.
The configuration of the communication system S is the same as that shown in FIG. In the illustrated example, the mobile station device 3 is connected to the macro cell base station device 1 and the small cell base station device 2 in the downlink DL in the same way as in FIG. 1, and is connected to the two base station devices in the dual communication mode. Communicate with. On the other hand, the mobile station apparatus 3 employs a time division multiplexing method in the uplink UL, and alternately connects one of the macrocell base station apparatus 1 and the small cell base station apparatus 2 and the other to a single link (hereinafter referred to as a single link). And also communicates with one of the macrocell base station apparatus 1 or the small cell base station apparatus 2 in a single communication mode (hereinafter also referred to as a single communication mode).

That is, the mobile station apparatus 3 communicates with the macro cell base station apparatus 1 and the small cell base station apparatus 2 simultaneously in the downlink DL in the dual communication mode, and performs time division multiplexing with the macro cell base station apparatus 1 and the small cell base station apparatus 2. Using the method, communication is performed in uplink UL in a single communication mode using HARQ feedback alternately with each base station apparatus. An example of the HARQ feedback data format (subframe configuration in the uplink single communication mode) used at this time is the table T2.
In the following description, the HARQ feedback format shown in the table T2 is also referred to as a single UL format.

  In the illustrated example, the table T2 includes subframe numbers, a macro cell HARQ process (DL) representing the downlink HARQ process of the macro cell base station device 1, and a small HARQ process representing the downlink HARQ process of the small cell base station device 2. HARQ process (DL) of the cell, HARQ ACK (UL) to the macro cell indicating uplink HARQ ACK from the mobile station device 3 to the macro cell base station device 1, and from the mobile station device 3 to the small cell base station device 2 Small cell HARQ ACK (UL) representing uplink HARQ ACK, and a row and a column having each item row of subframe numbers n, n + 1, n + 2,..., N + 15 corresponding to each item row Is a two-dimensional table format table.

  In the illustrated example, the uplink UL is in a single communication mode, that is, either the mobile station device 3 and the macro cell base station device 1 or the mobile station device 3 and the small cell base station device 2 are alternately time-division multiplexed. Communication is in progress. That is, the HARQ ACK corresponding to each subframe number indicated in the HARQ process (DL) of the macro cell is collectively transmitted with each subframe number indicated in the HARQ ACK (UL) to the macro cell. Yes. For example, HARQ ACK corresponding to HARQ process (DL) 0, 1, 2, 3 of the macro cell of subframe number n to n + 4 is transmitted by HARQ ACK (UL) 0123 to the macro cell of subframe number n + 4. Represents. Similarly, HARQ ACKs corresponding to HARQ processes (DL) 0, 1, 2, and 3 of the small cells of subframe numbers n to n + 4 are transmitted by HARQ ACK (UL) 0123 to the macro cell of subframe number n + 6. Represents that.

  That is, the mobile station apparatus 3 transmits HARQ ACKs with subframe numbers 0, 1, 2, and 3 to the macro cell base station apparatus 1 in, for example, HARQ ACK (UL) to the macro cell with subframe number n + 4. , RF retune for switching the frequency from the frequency of the macro cell base station apparatus 1 to the frequency of the small cell base station apparatus 2 using HARQ ACK (UL) to the macro cell of subframe number n + 5 and HARQ ACK (UL) to the small cell Do. Then, the mobile station device 3 transmits HARQ ACKs of subframe numbers 0, 1, 2, and 3 to the small cell base station device 2 in HARQ ACK (UL) to the macro cell of subframe number n + 6, RF retune is performed to switch the frequency from the frequency of the small cell base station apparatus 2 to the frequency of the macro cell base station apparatus 1 using HARQ ACK (UL) to the macro cell of subframe number n + 7 and HARQ ACK (UL) to the small cell. . In this way, the mobile station apparatus 3 transmits HARQ ACK to each base station apparatus while switching the frequency of the macrocell base station apparatus 1 and the frequency of the small cell base station apparatus 2.

FIG. 3 is a schematic diagram illustrating an example of a communication status S3 of the communication system S according to the first embodiment of the present invention.
The configuration of the communication system S is the same as that shown in FIG. In the illustrated example, the mobile station device 3 is connected to the macro cell base station device 1 and the small cell base station device 2 in the downlink DL in the same way as in FIG. 1, and is connected to the two base station devices in the dual communication mode. Communicate with. Also in the uplink UL, the mobile station apparatus 3 is connected to the macro cell base station apparatus 1 and the small cell base station apparatus 2 in a dual link and communicates with the two base station apparatuses in the dual communication mode, as in FIG. I do.

That is, in the communication status S3 of the communication system S, the mobile station apparatus 3 communicates with the macro cell base station apparatus 1 and the small cell base station apparatus 2 simultaneously in the downlink DL in the dual communication mode, and the macro cell base station apparatus 1 and the small cell base station apparatus 1 Communication with each cell base station apparatus 2 is performed in uplink UL in the dual communication mode using HARQ feedback at the same time.
An example of the data format of HARQ feedback used at this time (subframe configuration in the uplink multiple communication mode) is table T3.
In the illustrated example, the table T3 includes a subframe number, a macro cell HARQ process (DL) representing the downlink HARQ process of the macro cell base station apparatus 1, and a small HAq process representing the downlink HARQ process of the small cell base station apparatus 2. HARQ process (DL) of the cell, HARQ ACK (UL) to the macro cell indicating uplink HARQ ACK from the mobile station device 3 to the macro cell base station device 1, and from the mobile station device 3 to the small cell base station device 2 Small cell HARQ ACK (UL) representing uplink HARQ ACK, and a row and a column having each item row of subframe numbers n, n + 1, n + 2,..., N + 15 corresponding to each item row Is a two-dimensional table format table.

In the illustrated example, the uplink UL is in the dual communication mode, that is, the mobile station device 3 and the macro cell base station device 1 and the mobile station device 3 and the small cell base station device 2 are connected to perform communication. HARQ ACK transmission to the macro cell base station apparatus 1 and the small cell base station apparatus 2 in the link UL is performed alternately to each base station apparatus.
HARQ ACK corresponding to each subframe number indicated in the HARQ process (DL) of the macro cell is transmitted together with each subframe number indicated in the HARQ ACK (UL) to the macro cell, and subframe numbers n to n + 4 HARQ ACKs corresponding to HARQ processes (DL) 0, 1, 2, and 3 of the macro cell are transmitted as HARQ ACK (UL) 0123 to the macro cell of subframe number n + 4. Similarly, HARQ ACKs corresponding to HARQ processes (DL) 0, 1, 2, and 3 of the small cells of subframe numbers n to n + 4 are transmitted by HARQ ACK (UL) 0123 to the macro cell of subframe number n + 6. .

That is, the mobile station apparatus 3 transmits HARQ ACKs with subframe numbers 0, 1, 2, and 3 to the macro cell base station apparatus 1 in, for example, HARQ ACK (UL) to the macro cell with subframe number n + 4. In subframe number n + 5, without performing RF Retune as shown in table T2 of FIG. 2, in HARQ ACK (UL) to the macro cell of subframe number n + 6, to small cell base station apparatus 2, HARQ ACKs with subframe numbers 0, 1, 2, and 3 are transmitted. As described above, when the mobile station device 3 is connected to each of the macro cell base station device 1 and the small cell base station device 2, the mobile station device 3 does not switch to the respective frequency, Switch.
Accordingly, even when the uplink UL is in the dual communication mode, it is not necessary to switch the frequency such as RF Retune, so that power consumption can be reduced.

  That is, in the communication status S3 of the communication system S, the mobile station apparatus 3 communicates with the macro cell base station apparatus 1 and the small cell base station apparatus 2 simultaneously in the downlink DL in the dual communication mode, and the macro cell base station apparatus 1 and the small cell base station apparatus 1 A single UL format shown in Table T3 is used as the HARQ feedback data format for each base station device while switching the base station device to be a communication partner while being in contact with each cell base station device 2. Communication in the uplink UL in the dual communication mode.

  From the above, according to FIGS. 1 to 3, the mobile station apparatus 3 uses different data formats for HARQ feedback depending on whether the uplink UL communication mode is the dual communication mode or the single communication mode. Specifically, in the single communication mode, the mobile station device 3 uses a data format of HARQ feedback in a single UL format. On the other hand, in the dual communication mode, the mobile station device 3 selects either the multiple UL format or the single UL format, and the HARQ feedback data format is one of the selected multiple UL format or single UL format. HARQ feedback data to be used depending on the battery status of the mobile station device 3, the distance between the mobile station device 3 and the cell (macrocell base station device 1 or small cell base station device 2), the communication status such as the HARQ retransmission frequency, etc. Switch the format.

  In the following description, it is assumed that the mobile station apparatus 3 can communicate in the dual communication mode, and the mobile station apparatus 3 uses the HARQ feedback in which the uplink UL as shown in FIG. 1 is in the dual communication mode and has a plurality of UL formats. There are two cases: a case where communication is performed using a data format of the same, and a case where communication is performed using a data format of HARQ feedback in which the uplink UL as shown in FIG. 3 is in a dual communication mode and a single UL format. The case of switching will be described. In the following description, the case where the uplink UL performs communication using the dual communication mode and the HARQ feedback data format which is a plurality of UL formats is referred to as “dual UL”, and the uplink UL is in the dual communication mode. A case where communication is performed using the HARQ feedback data format which is a single UL format is referred to as “single UL format dual UL”.

FIG. 4 is a schematic block diagram showing an example of the configuration of the macro cell base station apparatus 1 according to the first embodiment of the present invention.
The macrocell base station apparatus 1 includes a communication unit 101, an inquiry reception unit 102, a confirmation unit 103, a network communication unit 104, a response reception unit 105, a response transmission unit 106, a request reception unit 107, and a request transmission unit. 108, a response reception unit 109, a response transmission unit 110, and a switching execution unit 111.

  The communication unit 101 communicates with the mobile station device 3 via the network N1. The communication unit 101 performs communication processing such as data encoding / decoding, modulation / demodulation, AD (Analog to Digital) / DA (Digital to Analog) conversion, frequency conversion, and transmission / reception of data signals by radio waves.

  The inquiry reception unit 102 receives an inquiry as to whether or not the uplink UL control information in the uplink UL can be switched from the mobile station device 3 via the communication unit 101. For example, the inquiry receiving unit 102 receives an inquiry from the mobile station device 3 via the communication unit 101 as to whether switching from dual UL to single UL format dual UL, or single UL format dual UL to dual UL is possible. To do. That is, the inquiry receiving unit 102 receives an inquiry as to whether or not the HARQ feedback data format can be switched from a plurality of UL formats to a single UL format and from a single UL format to a plurality of UL formats. The inquiry receiving unit 102 outputs the received inquiry to the confirmation unit 103.

  When the inquiry is input from the inquiry reception unit 102, the confirmation unit 103 determines whether or not the control information of the uplink UL of the own device can be switched. Specifically, when an inquiry is input from the inquiry reception unit 102, the confirmation unit 103 determines whether or not the HARQ feedback data format of the own apparatus can be switched. When the data format of the HARQ feedback of the own device can be switched, the confirmation unit 103 transmits the inquiry input from the inquiry reception unit 102 to the small cell base station device 2 via the network communication unit 104. The cell base station apparatus 2 is confirmed whether or not switching from dual UL to single UL format dual UL, or single UL format dual UL to dual UL is possible. On the other hand, when the data format of the HARQ feedback of the own device cannot be switched, the confirmation unit 103 cannot switch the data format of the HARQ feedback indicating that the HARQ feedback data format of the own device cannot be switched. A possibility notification is generated as a switchability reply, and the generated switchability reply is transmitted to the mobile station device 3 via the communication unit 101 and the network N1.

The network communication unit 104 is connected to the network N1, and communicates with the small cell base station apparatus 2 via the network N1.
As a response to the inquiry by the confirmation unit 103, the response reception unit 105 receives a response as to whether or not the uplink UL control information can be switched from the small cell base station device 2 via the network N1 and the network communication unit 104. To do. Specifically, the response receiving unit 105 receives, from the small cell base station apparatus 2 via the network N1 and the network communication unit 104 as a response to the inquiry from the confirmation unit 103, from the dual UL to the single UL format dual UL. A response indicating whether the data format of HARQ feedback from one UL format dual UL to dual UL can be switched is received. The answer receiving unit 105 outputs the received answer to the answer sending unit 106.

The reply transmission unit 106 transmits the reply input from the reply reception unit 105 to the mobile station device 3 via the communication unit 101 and the network N1.
The request reception unit 107 receives an uplink UL control information switching request from the mobile station apparatus 3 via the network N1 and the communication unit 101 as a response to the response transmitted by the response transmission unit 106. Specifically, the request reception unit 107 receives a HARQ feedback data format switching request from the mobile station apparatus 3 via the network N1 and the communication unit 101 as a response to the response transmitted by the response transmission unit 106. The request reception unit 107 outputs the received HARQ feedback data format switching request to the request transmission unit 108.

  The request transmission unit 108 transmits the uplink UL control information switching request input from the request reception unit 107 to the small cell base station apparatus 2 via the network communication unit 104 and the network N1. Specifically, the HARQ feedback data format switching request input from the request receiving unit 107 is transmitted to the small cell base station apparatus 2 via the network communication unit 104 and the network N1.

  In response to the uplink UL control information switching request transmitted by the request transmitting unit 108, the response receiving unit 109 performs switching of the uplink UL control information, and the small cell base station apparatus 2 performs switching of the uplink UL control information. A completion response indicating that the switching of the control information is completed is received via the network N1 and the network communication unit 104. Specifically, as a response to the HARQ feedback data format switching request transmitted by the request transmitting unit 108, the response receiving unit 109 performs switching of the HARQ feedback data format by the small cell base station apparatus 2, and the HARQ feedback A completion response indicating that the switching of the feedback data format has been completed is received via the network N1 and the network communication unit 104. The response reception unit 109 outputs the received completion response to the switching execution unit 111.

  When the completion response is input from the response reception unit 109, the switching execution unit 111 performs switching of the uplink UL control information of the own device. Then, the switching execution unit 111 sends a completion response indicating completion of switching of the uplink UL control information of the own device and switching of the uplink UL control information of the small cell base station device 2 to the response transmitting unit 110. Output. Specifically, when the completion response is input from the response reception unit 109, the switching execution unit 111 performs switching of the uplink UL control information of the own device. Then, the switching execution unit 111 sends a completion response indicating completion of switching of the uplink UL control information of the own device and switching of the uplink UL control information of the small cell base station device 2 to the response transmitting unit 110. Output.

  Specifically, when the completion response is input from the response reception unit 109, the switching execution unit 111 performs switching of the HARQ feedback data format of the own device. Then, the switching execution unit 111 outputs a completion response indicating that the switching of the HARQ feedback data format of the own device and the switching of the HARQ feedback data format of the small cell base station device 2 to the response transmitting unit 110. . Specifically, when the completion response is input from the response reception unit 109, the switching execution unit 111 performs switching of the HARQ feedback data format of the own device. Then, the switching execution unit 111 outputs a completion response indicating that the switching of the HARQ feedback data format of the own device and the switching of the HARQ feedback data format of the small cell base station device 2 to the response transmitting unit 110. .

  The response transmission unit 110 transmits the completion response input from the switching execution unit 111 to the mobile station device 3 via the communication unit 101 and the network N1.

FIG. 5 is a schematic block diagram showing an example of the configuration of the small cell base station apparatus 2 according to the first embodiment of the present invention.
The small cell base station apparatus 2 includes a network communication unit 201, an inquiry reception unit 202, an answer transmission unit 203, a request reception unit 204, a switching execution unit 205, and a notification unit 206. The small cell base station device 2 includes a communication unit that communicates with the mobile station device 3 in addition, but illustration and description thereof are omitted.
The network communication unit 201 is connected to the network N1 and communicates with the macrocell base station apparatus 1 via the network N1.
The inquiry receiving unit 202 transmits the HARQ feedback data format (uplink UL) from the dual UL to the single UL format dual UL and the single UL format dual UL to the dual UL via the network communication unit 201. An inquiry is received as to whether switching of control information is possible. The inquiry reception unit 202 outputs the received inquiry to the response transmission unit 203.

  When the inquiry is input from the inquiry reception unit 202, the response transmission unit 203 determines whether or not the data format of HARQ feedback can be switched from dual UL to single UL format dual UL, or single UL format dual UL to dual UL. If the change is possible, a changeable notification is generated, and if the change is impossible, a changeable notification is generated. The response transmission unit 203 transmits the generated changeable notification or non-changeable notification as a response to the inquiry received by the inquiry reception unit 202 to the macrocell base station apparatus 1 via the network communication unit 201 and the network N1.

The request receiving unit 204 receives a request for switching the data format of the uplink UL HARQ feedback from the macro cell base station apparatus 1 via the network N1 and the network communication unit 201. The request reception unit 204 outputs the received switching request to the switching execution unit 205.
When a request for switching the HARQ feedback data format is input from the request receiving unit 204, the switching execution unit 205 refers to the type of the HARQ feedback data format included in the switching request and switches the data format of the HARQ feedback. Execute. When executing the switching of the HARQ feedback data format, the switching execution unit 205 outputs a switching completion notification to the notification unit 206.
When the switching completion notification is input from the switching execution unit 205, the notification unit 206 generates a completion response indicating that the switching of the HARQ feedback data format has been completed. The notification unit 206 transmits the generated completion response to the macro cell base station apparatus 1 via the network communication unit 201 and the network N1.

FIG. 6 is a schematic block diagram showing an example of the configuration of the mobile station apparatus 3 according to the first embodiment of the present invention.
The mobile station apparatus 3 includes receiving antennas 301-1,..., 301-N, a first receiving unit 302-1,..., An Nth receiving unit 302-N, a control unit 303, and a first transmission. , 308-N, and transmitting antennas 309-1,..., 309-N. The control unit 303 includes a HARQ processing unit 3031. The HARQ processing unit 3031 includes a single HARQ feedback processing unit 304, a multiple HARQ feedback processing unit 305, a retransmission frequency determination unit 306, a switching trigger determination unit 307, a user setting storage unit 310, and a battery state detection unit 311. The battery state determination unit 312 and the threshold storage unit 313 are included. The single HARQ feedback processing unit 304 includes a switching inquiry unit 3041, a reception unit 3042, and a request unit 3043. The multiple HARQ feedback processing unit 305 includes a switching inquiry unit 3051, a reception unit 3052, and a request unit 3053.
In the following description, the receiving antennas 301-1,..., 301-N are referred to as the receiving antenna 301, and the first receiving unit 302-1,. The first transmission unit 308-1,..., The Nth transmission unit 308-N are referred to as a transmission unit 308, and the transmission antennas 309-1,.

The threshold value storage unit 313 stores various threshold values such as a threshold value related to a battery and a threshold value related to a retransmission frequency described later.
The user setting storage unit 310 stores user settings as to whether to prioritize the data rate set by the user or whether to prioritize the remaining battery level.
The receiving unit 302 communicates with the macro cell base station apparatus 1 and the small cell base station apparatus 2 via the network N1 and the receiving antenna 301. The receiving unit 302 performs communication processing such as data encoding / decoding, modulation / demodulation, AD / DA conversion, frequency conversion, and transmission / reception of data signals by radio waves. Then, the reception unit 302 outputs the signal subjected to communication processing to the control unit 303.

The single HARQ feedback processing unit 304 performs various processes such as error detection, retransmission processing, and HARQ feedback in a single UL format dual UL. In addition, the single HARQ feedback processing unit 304 executes processing related to switching of the data format of HARQ feedback. Processing related to switching of the HARQ feedback data format will be described in detail below.
When switching from dual UL communication to single UL format dual UL communication, the switching inquiry unit 3041 transmits an inquiry as to whether switching from dual UL to single UL format dual UL is possible. It transmits to the macrocell base station apparatus 1 via the antenna 309 and the network N1.

The receiving unit 3042 receives, as an answer to the inquiry transmitted by the switching inquiry unit 3041, an answer indicating whether or not switching from dual UL to single UL format dual UL is possible via the network N1, the receiving antenna 301, and the receiving unit 302.
When the request unit 3043 indicates that the HARQ feedback data format switching response received by the receiving unit 3042 can be switched, the request unit 3043 switches the HARQ feedback data format instructing switching to the single UL format dual UL. The request is transmitted to the macro cell base station apparatus 1 via the transmission unit 308, the transmission antenna 309, and the network N1. The request unit 3043 receives a HARQ feedback data format switching completion response via the network N1, the receiving antenna 301, and the receiving unit 302 as a response to the transmitted HARQ feedback data format switching request.

The multiple HARQ feedback processing unit 305 performs various processes such as error detection, retransmission processing, and HARQ feedback in dual UL. The multiple HARQ feedback processing unit 305 executes processing related to switching of the data format of HARQ feedback. Processing related to switching of the HARQ feedback data format will be described in detail below.
The switching inquiry unit 3051 transmits an inquiry as to whether switching from the single UL format dual UL to the dual UL is possible when switching from the single UL format dual UL communication to the single UL format dual UL communication. It transmits to the macrocell base station apparatus 1 via the part 308, the transmission antenna 309, and the network N1.

The receiving unit 3052 receives, as an answer to the inquiry transmitted by the switching inquiry unit 3051, an answer indicating whether switching from the single UL format dual UL to the dual UL is possible via the network N 1, the receiving antenna 301, and the receiving unit 302.
The request unit 3053 transmits a HARQ feedback data format switching request instructing switching to dual UL when the response indicating whether or not switching of the HARQ feedback data format received by the receiving unit 3042 is switchable. It transmits to the macrocell base station apparatus 1 via the part 308, the transmission antenna 309, and the network N1. The request unit 3043 receives a HARQ feedback data format switching completion response via the network N1, the receiving antenna 301, and the receiving unit 302 as a response to the transmitted HARQ feedback data format switching request.

  The retransmission frequency determination unit 306 measures the retransmission processing frequency in each HARQ feedback data format of the single UL format dual UL and dual UL. In addition, the retransmission frequency determination unit 306 reads a threshold related to the retransmission frequency from the threshold storage unit 313. When communication is performed in a single UL format dual UL, the retransmission frequency determination unit 306 determines whether or not the measured retransmission frequency is equal to or higher than a threshold, and switches to dual UL when the retransmission frequency is equal to or higher than the threshold. Is determined. In addition, when performing communication using dual UL, the retransmission frequency determination unit 306 determines whether or not the measured retransmission frequency is equal to or less than a threshold value. If the retransmission frequency is equal to or less than the threshold value, the single UL format dual UL is determined. It is determined to switch to.

The battery state detection unit 311 detects the amount of battery power provided in the mobile station device 3.
The battery state determination unit 312 compares the detected amount of battery power and a threshold value related to the battery to calculate the remaining battery level. For example, the threshold value regarding the battery stored in the threshold value storage unit 313 is a stepwise threshold value, for example, a threshold value of 10 steps. The battery state determination unit 312 determines that the remaining battery power is higher than the highest threshold value. If the amount is 100% and is equal to or greater than the first threshold and less than the highest threshold, the remaining battery level is determined to be 90%.
Based on the determination result of the battery state determination unit 312, the retransmission frequency determination unit 306, and the user setting stored in the user setting storage unit 310, the switching trigger determination unit 307 is switched from dual UL to single UL format dual UL, single UL. It is determined whether or not to switch the HARQ feedback data format, such as format dual UL to dual UL, and the HARQ feedback data format is sent to the single HARQ feedback processing unit 304 or the plurality of HARQ feedback processing units 305 according to the determination result. Execute processing related to switching.

FIG. 7 is a flowchart showing an example of processing at the start of data communication of the mobile station apparatus 3 according to the first embodiment of the present invention.
In step ST101, the switching trigger determination unit 307 determines whether or not the user setting stored in the user setting storage unit 310 is stored. When the user setting is stored, the process proceeds to step ST102. On the other hand, when the user setting is not stored, the process proceeds to step ST103.
In step ST102, when the user setting stored in the user setting storage unit 310 is a user setting that prioritizes the data rate, the switching trigger determination unit 307 proceeds to ST105. On the other hand, when the user setting is not the user setting giving priority to the data rate, the process proceeds to step ST106.

In step ST103, the switching trigger determination unit 307 determines whether or not the battery state is good, that is, whether or not the remaining battery level is equal to or greater than a predetermined threshold (for example, 50% or greater). If the remaining battery level is equal to or greater than the predetermined threshold, the process proceeds to step ST105. On the other hand, if the remaining battery level is less than the predetermined threshold, the process proceeds to step ST104.
In step ST104, the switching trigger determination unit 307 determines whether or not the transmission power is small, that is, whether or not the transmission power when the mobile station apparatus 3 transmits a signal is equal to or less than a predetermined value. When transmission power is below a predetermined value, it progresses to step ST105. On the other hand, when transmission power is not below a predetermined value, it progresses to step ST106.
In step ST105, the switching trigger determination unit 307 selects the uplink dual UL and starts communication. And the process at the time of the start of the data communication of the mobile station apparatus 3 which concerns on FIG. 7 is complete | finished.
In step ST106, the switching trigger determination unit 307 selects an uplink single UL format dual UL and starts communication. And the process at the time of the start of the data communication of the mobile station apparatus 3 which concerns on FIG. 7 is complete | finished.

FIG. 8 is a flowchart showing an example of processing during data communication of the mobile station device 3 according to the first embodiment of the present invention.
In step ST201, the switching trigger determination unit 307 determines whether or not the HARQ retransmission frequency has changed from the previous HARQ retransmission frequency. When the HARQ retransmission frequency changes from the HARQ retransmission frequency immediately before, the process proceeds to step ST202. On the other hand, if the HARQ retransmission frequency has not changed from the previous HARQ retransmission frequency, that is, if the previous HARQ retransmission frequency and the HARQ retransmission frequency are substantially the same, step ST201 is repeated.

In step ST202, the switching trigger determination unit 307 determines whether or not the user setting storage unit 310 stores user settings. If user settings are stored, the process returns to step ST201. On the other hand, when the user setting is not stored, the process proceeds to step ST203.
In step ST203, the switching trigger determination unit 307 determines whether or not the HARQ retransmission frequency is lower than the previous HARQ retransmission frequency. If the HARQ retransmission frequency is lower than the HARQ retransmission frequency immediately before, the process proceeds to step ST204. On the other hand, when the HARQ retransmission frequency is not lower than the previous HARQ retransmission frequency, the process proceeds to step ST205.

In step ST204, the switching trigger determination unit 307 determines whether or not the current HARQ feedback data format is dual UL. If the current HARQ feedback data format is dual UL, the process returns to step ST201. On the other hand, if the current HARQ feedback data format is not dual UL, the process proceeds to step ST207.
In step ST205, the switching trigger determination unit 307 determines whether or not the current HARQ feedback data format is a single UL format dual UL. When the data format of the current HARQ feedback is a single UL format dual UL, the process returns to step ST201. On the other hand, when the data format of the current HARQ feedback is not the single UL format dual UL, the process proceeds to step ST208.

In step ST207, the switching trigger determination unit 307 determines switching to the uplink single UL format dual UL, and returns to step ST201.
In step ST208, the switching trigger determination unit 307 determines switching to the uplink dual UL, and returns to step ST201.

FIG. 9 is a sequence diagram showing an example of data format switching processing of uplink HARQ feedback according to the first embodiment of the present invention.
In Step ST301, the mobile station apparatus 3 transmits to the macro cell base station apparatus 1 a switchability inquiry as to whether or not the HARQ feedback data format (uplink UL control information) can be switched.
In Step ST302, the macro cell base station apparatus 1 transmits to the small cell base station apparatus 2 an inquiry about whether or not the HARQ feedback data format received from the mobile station apparatus 3 can be switched.
In step ST303, the small cell base station apparatus 2 determines whether or not the HARQ feedback data format can be switched, and whether or not to switch indicates whether or not the HARQ feedback data format can be switched according to the determination result. The answer is transmitted to the macro cell base station apparatus 1.

In Step ST304, the macro cell base station apparatus 1 transmits to the mobile station apparatus 3 a switchability response indicating whether or not the data format of the HARQ feedback received from the small cell base station apparatus 2 can be switched.
In Step ST305, the mobile station apparatus 3 sends a switching request for instructing switching of the HARQ feedback data format to the macro cell base station apparatus 1 based on the switchability answer indicating whether or not the HARQ feedback data format can be switched. Send.
In Step ST306, the macro cell base station apparatus 1 transmits to the small cell base station apparatus 2 a switching request instructing switching of the data format of the HARQ feedback received from the mobile station apparatus 3.

In Step ST307, the small cell base station apparatus 2 executes HARQ feedback data format switching based on the switching request received from the macro cell base station apparatus 1, and sends a switching completion response indicating that the switching is completed to the macro cell. It transmits to the base station apparatus 1.
In Step ST308, the macro cell base station apparatus 1 transmits the switching completion response received from the small cell base station apparatus 2 to the mobile station apparatus 3, and completes the HARQ feedback data format switching process.

FIG. 10 is a flowchart showing an example of processing in the mobile station apparatus 3 according to the first embodiment of the present invention.
In step ST401, the switching inquiry units 3041 and 3051 transmit to the macro cell base station apparatus 1 a switching availability inquiry as to whether or not switching of the HARQ feedback data format (uplink UL control information) is possible.
In Step ST402, the reception units 3042 and 3052 receive a switchability response from the macro cell base station apparatus 1 as a response to the switchability query.
In step ST403, the switching trigger determination unit 307 determines whether or not switching of the HARQ feedback data format is possible based on the switching availability answer. If the HARQ feedback data format can be switched, the process proceeds to step ST404. On the other hand, if the HARQ feedback data format cannot be switched, the HARQ feedback data format switching process is terminated.

In Step ST404, request sections 3043 and 3053 transmit a switching request instructing switching of the data format of HARQ feedback to macro cell base station apparatus 1.
In Step ST405, the request sections 3043 and 3053 receive from the macro cell base station apparatus 1 a switching completion response indicating that the HARQ feedback data format switching process of the small cell base station apparatus 2 has been completed.
In Step ST406, the request units 3043 and 3053 perform switching of the HARQ feedback data format of the own device based on the received switching completion response, and terminate the switching process.

FIG. 11 is a flowchart showing an example of processing in the macro cell base station apparatus 1 according to the first embodiment of the present invention.
In step ST501, the inquiry reception unit 102 receives, from the mobile station apparatus 3, a switchability inquiry as to whether or not the HARQ feedback data format (uplink UL control information) can be switched.
In step ST502, the confirmation unit 103 determines whether the HARQ feedback data format of the own apparatus can be switched. If the HARQ feedback data format of the own apparatus can be switched, the process proceeds to step ST504. On the other hand, if the HARQ feedback data format of the own apparatus cannot be switched, the process proceeds to step ST503.

In step ST503, the confirmation unit 103 generates a HARQ feedback data format switching impossible notification indicating that switching of the HARQ feedback data format of the own device is impossible as a switching permission response, and the generated switching permission response is generated. Transmit to mobile station apparatus 3.
In Step ST504, the confirmation unit 103 transmits to the small cell base station apparatus 2 an inquiry about whether or not to switch the data format of the HARQ feedback received from the mobile station apparatus 3.

In step ST505, the answer receiving unit 105 receives a switchability answer from the small cell base station apparatus 2.
In step ST506, the answer transmission unit 106 determines whether or not the HARQ feedback data format of the small cell base station apparatus 2 can be switched based on the switchability answer input from the answer receiving unit 105. When the data format of the HARQ feedback of the small cell base station apparatus 2 can be switched, the process proceeds to step ST507. On the other hand, when the HARQ feedback data format of the small cell base station apparatus 2 cannot be switched, the process returns to step ST503, and the response transmission unit 106 performs switching indicating that the HARQ feedback data format cannot be switched. An availability response is generated, and the generated switching availability response is transmitted to the mobile station apparatus 3.

In Step ST507, the response transmission unit 106 generates a switchability response indicating that the HARQ feedback data format can be switched, and transmits the generated switchability response to the mobile station apparatus 3.
In Step ST508, the request reception unit 107 receives from the mobile station apparatus 3 a switching request instructing switching of the data format of HARQ feedback.
In Step ST509, the request transmission unit 108 transmits to the small cell base station device 2 a switching request instructing switching of the data format of the HARQ feedback received from the mobile station device 3.

In Step ST510, the response reception unit 109 receives from the small cell base station apparatus 2 a switching completion response indicating that the switching of the HARQ feedback data format has been completed in the small cell base station apparatus 2.
In step ST511, the switching execution unit 111 switches the HARQ feedback data format of the own apparatus to the HARQ feedback data format indicated by the switching request. The switching execution unit 111 generates a switching completion response indicating that the switching of the data format of the HARQ feedback of the small cell base station apparatus 2 and the own apparatus has been completed.
In Step ST512, the response transmission unit 110 transmits a switching completion response indicating that switching of the HARQ feedback data format of the own device and the small cell base station device 2 is completed to the mobile station device 3, and the HARQ feedback data format This completes the switching process.

FIG. 12 is a flowchart showing an example of processing in the small cell base station apparatus 2 according to the first embodiment of the present invention.
In step ST601, the inquiry reception unit 202 receives, from the macro cell base station apparatus 1, a switchability inquiry as to whether or not the HARQ feedback data format (uplink UL control information) can be switched.
In step ST602, the answer transmission unit 203 determines whether or not the HARQ feedback data format of the own apparatus can be switched. If the HARQ feedback data format of the own apparatus can be switched, the process proceeds to step ST604. On the other hand, if it is not possible to switch the data format of the HARQ feedback of the own device, the process proceeds to step ST603.

In step ST603, the response transmission unit 203 generates a HARQ feedback data format non-switchable notification indicating that switching of the HARQ feedback data format of its own device is impossible as a switchable / non-switchable response, and the generated switchable / non-switchable response Is transmitted to the macrocell base station apparatus 1.
In step ST604, the response transmission unit 203 generates a switchability response indicating that the HARQ feedback data format can be switched, and transmits the generated switchability response to the macro cell base station apparatus 1.
In Step ST605, the request reception unit 204 receives a switching request for instructing switching of the data format of HARQ feedback from the macro cell base station apparatus 1.

In step ST606, the switching execution unit 205 switches the HARQ feedback data format of the own apparatus to the HARQ feedback data format indicated by the switching request.
In Step ST607, the notification unit 206 generates a switching completion response indicating that the switching of the HARQ feedback data format of the own device is completed, transmits the generated switching completion response to the macro cell base station device 1, and performs HARQ feedback. This completes the data format switching process.

  Thus, according to this embodiment, in the mobile station apparatus 3 that communicates with the first base station apparatus (macrocell base station apparatus 1) and the second base station apparatus (small cell base station apparatus 2), The station apparatus 3 is connected simultaneously with the first base station apparatus (macrocell base station apparatus 1) and the second base station apparatus (small cell base station apparatus 2), and the first base station apparatus (macrocell base station apparatus 1). ) In a predetermined first subframe, and the second base station apparatus (small cell base station apparatus 2) communicates in a predetermined second subframe different from the first subframe. 1 control information (single UL format dual UL as a data format of HARQ feedback) is used.

  Thereby, the mobile station apparatus 3 uses the first control information (single UL format dual UL) to set the RF retune control, for example, the communication frequency of the mobile station apparatus 3 to the macro cell base station apparatus 1 or the small cell base station. Control (switching) to the frequency of the station apparatus 2 can be made unnecessary, and as a result, power consumption can be reduced.

  Unlike the first control information (single UL format dual UL as a data format of HARQ feedback) and the first control information, the mobile station device 3 is different from the first control information (the macro cell base station device 1). ) And the second base station apparatus (small cell base station apparatus 2), and the first base station apparatus (macrocell base station apparatus 1) and the second base station apparatus (small cell base station apparatus 2) A switching inquiry unit that transmits an inquiry to the first base station apparatus (macrocell base station apparatus 1) as to whether or not switching with the second control information (dual UL as the data format of HARQ feedback) is possible. 3041, 3051, and a switchability answer as an answer to the inquiry from the first base station apparatus (macrocell base station apparatus 1) The first control information (single UL format dual UL) and the second control information (dual UL) based on the receiving units 3042 and 3052 to be received, and the switchability answer received by the receiving units 3042 and 3052 Requesting units 3043 and 3053 for transmitting a switching request to the first base station apparatus (macrocell base station apparatus 1).

  Thereby, the mobile station apparatus 3 appropriately includes a plurality of pieces of control information, for example, HARQ feedback according to the communication state such as the battery state of the mobile station apparatus, the distance to the cell (base station apparatus), and the HARQ retransmission frequency. The data format can be switched to dual UL or single UL format dual UL. Further, the mobile station apparatus 3 switches the communication frequency of the mobile station apparatus 3 to the frequency of the macrocell base station apparatus 1 or the small cell base station apparatus 2 by using the single UL format dual UL, for example, the communication frequency of the mobile station apparatus 3 ( Control) can be made unnecessary, and as a result, power consumption can be reduced.

  In addition, you may make it implement | achieve a part or all of the macrocell base station apparatus 1, the small cell base station apparatus 2, and the mobile station apparatus 3 in each embodiment mentioned above with a computer. In that case, the program for realizing the control function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read by a computer system and executed. Here, the “computer system” is a computer system built in the macro cell base station device 1, the small cell base station device 2, and the mobile station device 3, and includes hardware such as an OS and peripheral devices. .

The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” is a medium that dynamically holds a program for a short time, such as a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line, In such a case, a volatile memory inside a computer system serving as a server or a client may be included and a program that holds a program for a certain period of time.
The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  Moreover, you may implement | achieve part or all of the macrocell base station apparatus 1, the small cell base station apparatus 2, and the mobile station apparatus 3 in each embodiment mentioned above as integrated circuits, such as LSI (Large Scale Integration). Each functional block of the macro cell base station apparatus 1, the small cell base station apparatus 2, and the mobile station apparatus 3 may be individually made into a processor, or a part or all of them may be integrated into a processor. Further, the method of circuit integration is not limited to LSI, and may be realized by a dedicated circuit or a general-purpose processor. Further, in the case where an integrated circuit technology that replaces LSI appears due to progress in semiconductor technology, an integrated circuit based on the technology may be used.

  As described above, the embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to that described above, and various design changes and the like can be made without departing from the scope of the present invention. It is possible to

  (Supplementary note 1) In a mobile station apparatus that communicates with a first base station apparatus and a second base station apparatus, the first base station apparatus and the second base station apparatus are connected simultaneously with the first base station apparatus and the second base station apparatus, First control information for communicating with a base station apparatus in a predetermined first subframe, and for communicating with the second base station apparatus in a predetermined second subframe different from the first subframe Is a mobile station device characterized by using

  (Supplementary Note 2) Unlike the first control information, the first control information is connected to the first base station apparatus and the second base station apparatus at the same time, and the first base station apparatus and the first control information From the first base station apparatus, a switching inquiry unit that transmits an inquiry to the first base station apparatus as to whether or not switching with second control information that communicates simultaneously with the second base station apparatus is possible A receiving unit that receives a switchability response as an answer to the inquiry, and a switching request between the first control information and the second control information based on the switchability response received by the receiving unit. The mobile station apparatus according to Supplementary Note 1, further comprising: a request unit that transmits to one base station apparatus.

  (Additional remark 3) The said switching inquiry part can switch between said 1st control information and said 2nd control information based on the electric energy of the said mobile station apparatus, or the resending frequency of the data in the said mobile station apparatus The mobile station apparatus according to Supplementary Note 2, wherein an inquiry as to whether or not is transmitted to the first base station apparatus.

  (Supplementary Note 4) Base using first control information connected to mobile station apparatus for communication in predetermined subframe and second control information connected to mobile station apparatus for communication in each subframe An inquiry receiving unit that receives an inquiry as to whether or not switching between the first control information and the second control information is possible, and based on the inquiry received by the inquiry receiving unit, A confirmation unit that makes an inquiry as to whether or not switching between the first control information and the second control information is possible to another base station device, and from the other base station device as a response to the inquiry by the confirmation unit A response receiving unit that receives a switchability response, and a response transmission unit that transmits a switchability response to the mobile station device based on the switchability response received by the response reception unit. It is a base station and wherein the obtaining.

  (Supplementary Note 5) Base using first control information connected to mobile station apparatus for communication in predetermined subframe and second control information connected to mobile station apparatus for communication in each subframe A station device that receives a request for switching between the first control information and the second control information; and the first control based on the request received by the request receiver. When the switching between the first control information and the second control information is completed by the switching execution unit that switches information and the second control information, and another base station And a notification unit that notifies the apparatus.

  (Supplementary Note 6) In a communication system including a first base station apparatus, a second base station apparatus, and a mobile station apparatus that communicates with the first base station apparatus and the second base station apparatus, the mobile station An apparatus is simultaneously connected to the first base station apparatus and the second base station apparatus, communicates with the first base station apparatus in a predetermined first subframe, and the second base station apparatus Is different from the first subframe, the first control information is communicated in a predetermined second subframe, and unlike the first control information, the first base station apparatus and the second subframe An inquiry is made as to whether or not switching between the first base station apparatus and the second control information that communicates simultaneously with the first base station apparatus and the second base station apparatus is possible. A switching inquiry part to be transmitted to the device, and the first A receiving unit that receives a switchability response as an answer to the inquiry from the ground station device, and switching between the first control information and the second control information based on the switchability response received by the receiving unit A request unit that transmits a request to the first base station apparatus, wherein the first base station apparatus switches between the first control information and the second control information received from the mobile station apparatus. A confirmation unit that makes an inquiry as to whether or not switching between the first control information and the second control information is possible to the second base station apparatus based on an inquiry as to whether or not Receiving a switchability response from the second base station device as a response to the inquiry by the transmission unit, and transmitting a switchability response to the mobile station device based on the switchability response received by the reception unit And the second base station apparatus performs switching between the first control information and the second control information based on the switching request received from the mobile station apparatus. A switching execution unit that performs the notification, and when the switching between the first control information and the second control information by the switching execution unit is completed, a notification unit that notifies the first base station device of the completion of the switching, It is a communication system characterized by comprising.

  (Supplementary note 7) In a communication method in a communication system including a first base station device, a second base station device, and a mobile station device that communicates with the first base station device and the second base station device, The mobile station apparatus is simultaneously connected to the first base station apparatus and the second base station apparatus, communicates with the first base station apparatus in a predetermined first subframe, and the second base station apparatus Unlike the base station apparatus, the first control information for performing communication in a predetermined second subframe different from the first subframe, the first base station apparatus different from the first control information, and the The first base station apparatus is connected at the same time, and the first base station apparatus and the second base station apparatus make an inquiry as to whether switching with second control information that communicates simultaneously with the first base station apparatus is possible. Switching inquiry sent to the base station equipment And a reception process for receiving a switchability response as a response to the inquiry from the first base station apparatus, and the first control information and the first control information based on the switchability response received by the reception process. And a request process for transmitting a switching request to the first base station apparatus to the first base station apparatus, wherein the first base station apparatus receives the first control information received from the mobile station apparatus; Based on an inquiry as to whether switching with the second control information is possible, an inquiry is made to the second base station apparatus as to whether switching between the first control information and the second control information is possible. Based on the confirmation process, the reception process for receiving the switchability response from the second base station apparatus as a response to the inquiry by the confirmation process, and the switchability response received by the reception process. A response transmission process for transmitting a switchability response to the station device, and the second base station device receives the first control information and the first based on the switch request received from the mobile station device. When the switching between the first control information and the second control information in the switching execution process and switching in the switching execution process is completed, the completion of the first base information is completed. And a notification process for notifying a station apparatus.

DESCRIPTION OF SYMBOLS S ... Communication system, 1 ... Macrocell base station apparatus, 101 ... Communication part, 102 ... Inquiry reception part, 103 ... Confirmation part, 104 ... Network communication part, 105 ... Reply receiving unit 106 ... Reply sending unit 107 ... Request receiving unit 108 ... Request sending unit 109 ... Response receiving unit 110 ... Response sending unit 111 ... Switching execution , 2 ... small cell base station device, 201 ... network communication unit, 202 ... inquiry reception unit, 203 ... answer transmission unit, 204 ... request reception unit, 205 ... switching execution , 206... Notifying unit, 3... Mobile station apparatus, 301, 301-1, 301-2, 301 -N... Receiving antenna, 302, 302-1, 302-2, 302 -N ..Receiving unit, 303 Control unit, 304 ... single HARQ feedback processing unit, 3041, 3051 ... switching inquiry unit, 3042, 3052 ... receiving unit, 3043, 3053 ... request unit, 305 ... multiple HARQ feedback processing , 306... Retransmission frequency determination unit, 307... Switching trigger determination unit, 308, 308-1, 308-2, 308-N... Transmission unit, 309, 309-1, 309-2, 309 -N ... transmitting antenna, 310 ... user setting storage unit, 311 ... battery state detection unit, 312 ... battery state determination unit, 313 ... threshold storage unit, CS, CM ... cell

Claims (5)

In the mobile station apparatus that communicates with the first base station apparatus and the second base station apparatus,
The first base station apparatus and the second base station apparatus are connected simultaneously, communicate with the first base station apparatus in a predetermined first subframe, and the second base station apparatus Using first control information for performing communication in a predetermined second subframe different from the first subframe;
A mobile station apparatus characterized by the above. Unlike the first control information and the first control information, the first base station device and the second base station are connected simultaneously with the first base station device and the second base station device. A switching inquiry unit that transmits to the first base station device an inquiry as to whether switching with second control information that communicates simultaneously with the station device is possible;
A receiving unit that receives a switchability response as a response to the inquiry from the first base station device;
A request unit for transmitting a switching request between the first control information and the second control information to the first base station device based on the switchability response received by the receiving unit;
The mobile station apparatus according to claim 1, further comprising: The switching inquiry unit determines whether switching between the first control information and the second control information is possible based on an amount of power of the mobile station device or a frequency of data retransmission processing in the mobile station device. The mobile station apparatus according to claim 2, wherein the inquiry is transmitted to the first base station apparatus. A base station apparatus that uses first control information that is connected to a mobile station apparatus and performs communication in a predetermined subframe, and second control information that is connected to the mobile station apparatus and performs communication in each subframe. And
An inquiry receiving unit for receiving an inquiry as to whether or not switching between the first control information and the second control information is possible;
Based on the inquiry received by the inquiry reception unit, a confirmation unit that makes an inquiry as to whether or not switching between the first control information and the second control information is possible to another base station device;
A response reception unit that receives a switchability response from the other base station device as a response to the inquiry by the confirmation unit;
Based on the switchability response received by the response receiver, a response transmitter for transmitting a switchability response to the mobile station device;
A base station apparatus comprising: A base station apparatus that uses first control information that is connected to a mobile station apparatus and performs communication in a predetermined subframe, and second control information that is connected to the mobile station apparatus and performs communication in each subframe. And
A request receiving unit for receiving a request for switching between the first control information and the second control information;
A switching execution unit that switches between the first control information and the second control information based on the request received by the request reception unit;
When the switching between the first control information and the second control information by the switching execution unit is completed, a notification unit that notifies the other base station device of the completion,
A base station apparatus comprising:

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