JP5048094B2 - Mobile station, base station, communication system, and communication method - Google Patents

Description

  The present invention relates to a mobile station, a base station, a communication system, and a communication method for communicating packet data on a CDMA (Code Division Multiple Access) mobile communication system.

As a high-speed mobile communication system adopting the CDMA system, a communication standard called the third generation is adopted as IMT-2000 by the International Electric Union (ITU). W-CDMA (FDD: Frequency Division Duplex) started commercial service in Japan in 2001. The W-CDMA (FDD) system is a third generation mobile communication system, and aims to obtain a communication speed of about 2 Mbps at the maximum per mobile station. Regarding the W-CDMA (FDD) system, the first specification has been determined in the release 1999 version compiled by the standardization organization 3GPP (3rd. Generation Partnership Project) in 1999.
In addition, the various standards of the above release can be found on the Internet <URL: http: // www. 3 gpp. org / ftp / Specs / archive />. Currently, Release 4 and Release 5 are defined as other new versions of Release 1999, and Release 6 is being created.

The above-mentioned standards originally assumed continuous data services such as voice data. Therefore, even when burst transmission such as packet transmission is performed from the mobile station to the base station, a dedicated channel DCH (Dedicated Channel) dedicated to each mobile station is always secured as a radio resource. This is problematic from the viewpoint that effective use of radio resources is required with the recent increase in packet data usage due to the spread of the Internet.
Further, since data transmission from the mobile station is performed by autonomous transmission control (Autonomous Transmission) by the mobile station, the transmission timing from each mobile station is arbitrary or random. For this reason, in the CDMA communication system, all transmissions from other mobile stations become interference sources, but the base station can only predict statistically the amount of interference noise during reception and its fluctuation amount. Therefore, in the radio resource management, it is necessary to perform radio resource allocation control that suppresses the throughput and the maximum transmission speed of the mobile station and secures a margin on the assumption that the fluctuation amount of interference noise is large.
Radio resource management for mobile station transmission (uplink) in the W-CDMA standard is actually performed by a base station controller (RNC: Radio Network Controller) that collects a plurality of base stations, not the base station itself. Hereinafter, the base station and the base station controller are collectively referred to as the base station side. The radio resource management performed by the base station controller (RNC) for the mobile station and the exchange of the management information require a relatively long processing time of about several hundred msec. For this reason, there has been a problem that high-speed radio resource allocation control cannot be performed while monitoring changes in the high-speed radio propagation environment and the amount of interference from other mobile stations.

Non-Patent Document 1 proposes an on-demand channel allocation scheme in the uplink as a technique for improving uplink performance / functional expansion based on the above-mentioned current standard (releases 1999, 4, 5).
FIG. 1, first, a mobile station (UE: User Equipment) having a packet to be transmitted receives, as a packet data transmission request, information on the data amount of an untransmitted packet (Queue size) and mobile station transmission power. Margin information (Power Margin) is notified to the base station (NodeB) via a transmission request channel (USICCH: Uplink Scheduling Information Control Channel). Upon receiving this request, the base station notifies the mobile station of a radio resource allocation result (scheduling result) such as a transmission timing via a downlink allocation channel (DSACCH: Downlink Scheduling Assignment Control Channel). The mobile station transmits packet data to the base station via a data transmission channel (EUDCH: Enhanced Uplink Transport Channel) according to the received scheduling result. Information such as a modulation method at the time of packet data transmission is separately transmitted to the base station via a modulation format information channel (UTCCH: Uplink TFRI Control Channel). The base station determines reception of packet data, and notifies the mobile station of ACK / NACK of the determination result via a notification channel (DANCCH: Downlink Ack / Nack Control Channel). These channels are assumed to be expansions of conventional standard channels or introduction of new channels, and details thereof have not been determined yet.

Non-Patent Document 2 proposes a technique created based on Non-Patent Document 1.
In addition, as a conventional example of the technique for notifying the transmission data amount information from the mobile station to the base station, the mobile station responds to polling from the base station, for example, as in the packet communication method described in Patent Document 1. Based on the packet size notified by the mobile station, the mobile station notifies the base station of the packet size to be transmitted, as in the case of notifying the amount of data to be transmitted or the packet transmission method described in Patent Document 2. Wireless resources are allocated by the base station based on available transmission power, transmission data amount, QoS, etc. notified from the mobile station, as disclosed in Patent Document 3. .

Japanese Patent Laid-Open No. 64-42951 JP 2002-374321 A JP 2003-46482 A “AH64: Reduced control channel overhead for Enhanced Uplink”, [online], January, 7th-11th, 2003, 3GPPRAN1 # 30, [January 7, 2004 search], Internet <URL: http: // www 3 gpp. org / ftp / tsg_ran / WG1_RL1 / TSGR1_30 / Docs / Zips / R1-030067. zip> “3rd Generation Partnership Project; Technical Specification Group Radio Access Network; 4th, 4th, 6th, 6th, 4th, 6th, 4th, 6th, 4th, 6th, 4th, 6th, every year. ] <Internet: <URL: http: // www. 3 gpp. org / ftp / Specs / 2004-03 / Rel-6 / 25_series / 25896-600. zip> “Uplink signaling of scheduling information”, [online], [January 7, 2004 search], Internet <URL: http: // www. 3 gpp. org / ftp / tsg_ran / WG1_RL1 / TSGR1_34 / Docs / Zips / R1-031056. zip>

However, Patent Documents 1 to 3 and Non-Patent Documents 1 and 2 do not describe specific methods such as a format at the time of transmission data information transmission.
In the conventional W-CDMA standard, information on the amount of untransmitted data transmitted from a mobile station is notified to the base station controller (RNC) as it is once received by the base station. For this reason, the base station cannot grasp information relating to the amount of untransmitted data. Therefore, uplink radio resource control by the base station as described in Patent Documents 1 to 3 and Non-Patent Documents 1 and 2 cannot be realized. Further, in the conventional W-CDMA standard, there is no means for notifying the base station (NodeB) of information related to the untransmitted data amount of the mobile station from the base station controller. Even if it is possible to provide means for sending information obtained by the base station control device to the base station, the transmission cycle of untransmitted data amount information from the mobile station to the base station control device is 250 ms / 500 ms / ... / 6000 ms for a long time, there is a problem that high-speed radio resource control cannot be performed in the base station.

Non-Patent Document 3 proposes a technique related to the notification timing of mobile station information such as data amount information of untransmitted data and transmission power margin, which is related to the on-demand channel allocation method described in Non-Patent Document 1. ing. Non-Patent Document 3 describes various transmission methods such as a periodic transmission method.
However, Non-Patent Document 3 describes only a proposal related to notification timing, and does not describe a specific method for format, transmission channel designation, and the like at the time of transmission.
Further, Non-Patent Document 2 discloses, as another method of on-demand channel allocation, as a packet data transmission request, the transmission transmission rate (Rate) desired by the mobile station rather than the data amount of the above-mentioned untransmitted packet of the mobile station. A method for reporting (Request) to the base station in the uplink is also described (Rate control scheduling). The base station performs scheduling based on the transmission transmission rate request from each mobile station in the cell, and then notifies each mobile station of the permitted transmission transmission rate (Rate Grant) as a scheduling result on the downlink. However, as in Non-Patent Document 1, a specific method for the format at the time of transmission, transmission channel designation, etc. is not described.

  The present invention has been made to solve the above-described problems, and reports information from a mobile station required for uplink radio resource control in a base station directly from the mobile station to the base station. An object of the present invention is to obtain a mobile station, a base station, a communication system, and a communication method suitable for high-speed notification.

Means and effects for solving the problem

The mobile station according to the present invention provides a radio link control unit for inputting / outputting data to / from the base station via a radio channel with a higher protocol layer, and a radio link control unit via a logical channel. A physical layer control unit that inputs / outputs data via a transport channel and controls wireless communication with a base station between a media access control unit that performs data input / output and a media access control unit; A radio resource control unit that inputs and outputs control data between the radio link control unit, the media access control unit, and the physical layer control unit is provided. The media access control unit is used by the base station for scheduling of uplink transmission. The report information is multiplexed on the packet data transmission channel and transmitted to the base station.

  This enables uplink radio resource control in the base station, and enables higher-speed control than radio resource control by the base station control apparatus, thereby improving the efficiency of the communication system and improving the throughput of the entire cell. Will improve.

The base station according to the present invention includes a radio link control unit that inputs / outputs data to / from a mobile station via a radio channel with a higher protocol layer, and a radio link control unit via a logical channel. A physical layer control unit that inputs / outputs data via a transport channel and controls wireless communication with a mobile station, and a media access control unit that performs data input / output, and a media access control unit; A radio resource control unit for inputting / outputting control data to / from the radio link control unit, media access control unit, and physical layer control unit. The media access control unit is transmitted from the mobile station through a packet data transmission channel. were multiplexed in the data, the base station using the report information used for scheduling uplink transmission, to perform a radio resource allocation A.

  This enables uplink radio resource control in the base station, and enables higher-speed control than radio resource control by the base station control apparatus, thereby improving the efficiency of the communication system and improving the throughput of the entire cell. Will improve.

The communication system according to the present invention includes a radio link control unit that inputs / outputs data to / from a higher protocol layer via a radio channel, and a radio link control unit that transmits / receives data via a logical channel. A physical layer control unit, a radio link control unit, a medium for performing radio I / O control by inputting / outputting data via a transport channel between the media access control unit that performs input / output and the media access control unit A mobile station having a radio resource control unit that inputs / outputs control data between the access control unit and the physical layer control unit and a base station, the mobile station reports to the base station for uplink transmission scheduling transmits to the base station by multiplexing the information in the packet data transmission channel, the base station was received from the move station, the base station uplink transmission scheduling And it performs radio resource allocation using the report information used.

  This enables uplink radio resource control in the base station, and enables higher-speed control than radio resource control by the base station control apparatus, thereby improving the efficiency of the communication system and improving the throughput of the entire cell. Will improve.

A communication method according to the present invention provides a logical channel between a radio link controller and a radio link controller that inputs / outputs data to / from a base station via a radio channel with an upper protocol layer. A media access control unit that inputs / outputs data via the physical access control unit and a physical layer control unit that performs data input / output via the transport channel and controls wireless communication with the base station A mobile station equipped with a radio resource control unit for inputting / outputting control data to / from the radio link control unit, media access control unit, and physical layer control unit, a report used by the base station for scheduling of uplink transmission transmits to the base station by multiplexing the information in the packet data transmission channel, the base station receives from the moving station, the base station is to use for scheduling uplink transmission Using report information and performs radio resource allocation.

  This enables uplink radio resource control in the base station, and enables higher-speed control than radio resource control by the base station control apparatus, thereby improving the efficiency of the communication system and improving the throughput of the entire cell. Will improve.

It is the schematic which shows the structure of the communication system by Embodiment 1 of this invention. It is a block diagram which shows the structure of the mobile station by Embodiment 1 of this invention. It is a figure which shows the multiplex relationship between the channels in each part of the mobile station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the radio | wireless link control part of the mobile station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the media access control part of the mobile station by Embodiment 1 of this invention. It is a figure which shows the input / output data between the radio link control part and the media access control part at the time of transmission of the mobile station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the physical layer control part of the mobile station by Embodiment 1 of this invention. It is a figure which shows the principle of the mutual multiplexing of the channel in the media access control part and physical layer control part of the mobile station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the base station side (base station, base station control apparatus) by Embodiment 1 of this invention. It is a block diagram which shows the structure of the media access control part by the side of the base station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the physical layer control part by the side of the base station by Embodiment 1 of this invention. It is a figure which shows the flow of the packet transmission from the mobile station by Embodiment 1 of this invention to a base station. It is a block diagram which shows the structure of the MAC-e part of the mobile station by Embodiment 1 of this invention. It is a figure which shows the format of MAC-e PDU by Embodiment 1 of this invention. It is a figure which shows the modification of the MAC-e PDU format by Embodiment 1 of this invention. It is a figure which shows the MAC-e PDU format by Embodiment 2 of this invention. It is a figure which shows the MAC-e PDU format by Embodiment 3 of this invention. It is a figure which shows the MAC-e PDU format by Embodiment 4 of this invention. It is a figure which shows the MAC-e PDU format by Embodiment 5 of this invention. It is a block diagram which shows the structural example of the media access control part of the mobile station by Embodiment 5 of this invention. It is a figure which shows the flow of parameter setting by Embodiment 1-5 of this invention. It is a figure which shows the transmission flow of STATUS PDU between the base station control apparatus and mobile station by Embodiment 6 of this invention. It is a block diagram which shows the structure of the media access control part of the mobile station by Embodiment 6 of this invention.

Hereinafter, in order to describe the present invention in more detail, the best mode for carrying out the present invention will be described with reference to the accompanying drawings.
Embodiment 1 FIG.
FIG. 1 is a schematic diagram showing a configuration of a communication system 101 according to Embodiment 1 of the present invention.
As shown in the figure, the communication system 101 includes a mobile station 102, a base station 103, and a base station control device 104. The base station 103 communicates with a plurality of mobile stations 102 within a certain range. The communication range of the base station 103 is called a sector or a cell. In the figure, only one mobile station 102 is shown.
The base station control device 104 is connected to a communication network 105 such as a public telephone network or the Internet, and relays packet communication between the base station 103 and the communication network 105.
In the W-CDMA standard, the mobile station 102 is called UE (User Equipment), the base station 103 is called NodeB, and the base station controller 104 is called RNC (Radio Network Controller).

Data communication between the mobile station 102 and the base station 103 is performed using a plurality of radio links (channels).
The physical control channel (Physical Control Channel) includes a DPCCH 106 (Dedicated Physical Control Channel) used for uplink from the mobile station 102 to the base station 103 and a DPCCH 107 used for downlink from the base station 103 to the mobile station 102. is there. The DPCCHs 106 and 107 are used to perform transmission / reception timing synchronization control between the mobile station 102 and the base station 103, thereby maintaining physical wireless communication.
The physical channel for data transmission includes DPDCH (DCH) 108 used for uplink and DPDCH (DCH) 109 used for downlink. Data corresponding to the conventional standard channel (DCH) is transmitted and received between the mobile station 102 and the base station 103 using the DPDCH (DCH) 108 and 109.
DPDCH (E-DCH) / DPCCH (E-DCH) 110 is a data transmission physical channel / transmission channel for transmitting E-DCH data and modulation information at the time of E-DCH data transmission in the uplink. It is a physical control channel. DPDCH (E-DCH) and DPCCH (E-DCH) are transmitted in pairs.
The E-DPCCH 111 is used when notifying the mobile station 102 of the result of radio resource allocation in the base station 103 and the result of data reception determination (ACK / NACK) at the base station 103 in the downlink.
Here, DPDCH (DCH) 108 and DPDCH (E-DCH) 110 can transmit a total of up to six by using a plurality of channel separation spreading codes simultaneously. It is also possible to use DPDCH of a certain channel separation spreading code for DCH or E-DCH.
Note that these channels are channels that are not used in the conventional standard, and when newly set, in a new release of the standard TS25.211, consistency with the conventional standard (Backward Compatibility) The format is additionally specified while ensuring

FIG. 2 is a block diagram showing a configuration of mobile station 102 according to Embodiment 1 of the present invention.
As shown in the figure, the mobile station 102 includes an upper layer block 201, a radio link control unit 202, a media access control unit 203, a physical layer control unit 204, an antenna 205, and a radio resource control unit 206.

The input / output relationship of each part of the mobile station 102 will be outlined.
The upper layer block 201 is an upper layer block of the mobile station 102, and performs predetermined processing by a known technique in an upper protocol layer such as an application or a TCP / IP layer. Also, one or more data (TXdata) to be transmitted to the base station 103 is output to the radio link control unit 202. Similarly, one or more data (RXdata) received from the base station 103 via the radio link control unit 202 is input.
The radio link control unit 202 further exchanges data with the media access control unit 203 through one or more logical channels LOGch set with the media access control unit 203. Further, the radio link control unit 202 outputs the untransmitted data amount information LOGbuffer of the transmission buffer to the media access control unit 203.
The media access control unit 203 further exchanges data with the physical layer control unit 204 through one or more transport channels TRch set with the physical layer control unit 204.
The physical layer control unit 204 further performs radio communication with the base station 103 by transmitting and receiving radio frequency signals via the antenna 205.
The radio resource control unit 206 includes an upper layer block 201, a radio link control unit 202, a media access control unit 203, a physical layer control unit 204, various control information UPcont, RLC (Radio Link Control) cont, MAC (Media Access Control). ) Cont and PHY (Physical) cont are exchanged. These are information used in the publicly known technology and information specific to the first embodiment.

FIG. 3 is a diagram illustrating the multiplex relationship between each block of the mobile station 102 and each channel assumed in the first embodiment.
In the first embodiment, it is assumed that one communication service is performed. Also, it is assumed that service transmission / reception data (TXdata, RXdata) is assigned to a logical channel DTCH (Dedicated Traffic Channel).

In the uplink, transmission data (TXdata) is assigned to the logical channel DTCH. The DTCH data is assigned to E-DCH which is a transport channel. The E-DCH data is allocated to the uplink DPDCH (E-DCH) 110. On the other hand, various control information transmitted from the radio resource control unit 206 to the base station control apparatus 104 via the base station 103 is assigned to a logical channel DCCH (Dedicated Control Channel) in the radio link control unit 202. The DCCH data is assigned to the uplink DCH. The assignment method in the first embodiment is an example, and the setting is set prior to data communication or during communication.
The physical layer control unit 204 generates data for the DPCCH 106 and DPCCH (E-DCH) 110, which are uplink control channels.
On the other hand, in downlink, downlink DPDCH (DCH) 109 data is allocated to DCH. DCH data is allocated to DTCH and DCCH. Received data (RXdata) is extracted from the DTCH. In the physical layer control unit 204, downlink DPCCH 107 and E-DPCCH 111 are used.

  FIG. 4 is a block diagram illustrating a configuration of the radio link control unit 202 of the mobile station 102. As shown in the figure, the radio link control unit 202 includes a reception buffer 501a, a reception buffer 501b, a transmission buffer 502a, a transmission buffer 502b, an RLC control unit 503, and a buffer monitoring unit 504.

The input / output relationship of each part of the radio link control unit 202 will be outlined.
The reception buffer 501 a receives DTCH data from the media access control unit 203 and outputs reception data (RXdata) to the upper layer block 201. The reception buffer 501b inputs DCCH data from the media access control unit 203 and outputs control information (RXcontrol) to the RLC control unit 503. The transmission buffer 502 a receives transmission data (TXdata) from the upper layer block 201 and outputs DTCH data (RLC PDU) to the media access control unit 203. The transmission buffer 502 b receives control information (TXcontrol) from the RLC control unit 503 and outputs DCCH data (RLC PDU) to the media access control unit 203. Further, the transmission buffers 502 a and 502 b output information (Data info) related to the amount of data stored in each buffer to the buffer monitoring unit 504.
Based on the data amount information (Data info), the buffer monitoring unit 504 includes data amount information (DCH LOGbuffer) of each logical channel multiplexed on the DCH and the data amount of each logical channel multiplexed on the E-DCH. Information (EDCH LOGbuffer) is output to the media access control unit 203. There are a plurality of pieces of data amount information because the data amount information of the logical channel assigned to the DCH and the data amount information of the logical channel assigned to the E-DCH are separately transmitted to the media access control unit 203. It is. As described above, the function of measuring data amount information for each transport channel is called “Traffic volume measurement” in the conventional standard, and is defined in the standard document TS25.331. In the first embodiment, the traffic volume measurement is applied to the E-DCH as well as the DCH that is a conventional channel.
The RLC control unit 503 controls the entire radio link control unit 202. Further, it exchanges control information RLCcont with the radio resource control unit 206. The RLCcont includes information used in a known technique and information according to the present invention.

FIG. 5 is a block diagram illustrating a configuration of the media access control unit 203 of the mobile station 102.
The media access control unit 203 includes a reception buffer 601, a reception system MAC-d unit 602, a transmission system MAC-d unit 603, a transmission buffer 604a, an E-DCH buffer 604b, a MAC-e unit 605, a MAC control unit 607, a communication A quantity measuring unit 608 is provided.
The MAC-e unit 605 includes a data amount information unit 606 and a control information multiplexing unit 610.

The input / output relationship of each unit of the media access control unit 203 will be outlined.
The reception buffer 601 receives the DCH data from the physical layer control unit 204 and outputs the reception DCH data to the reception MAC-d unit 602. The reception system MAC-d unit 602 separates the data of the logical channels DTCH and DCCH multiplexed on the input DCH using a known technique and outputs the separated data to the reception buffers 501a and 501b of the radio link control unit 202, respectively. The transmission-system MAC-d unit 603 multiplexes or distributes the data of the logical channels DTCH and DCCH using a known technique and outputs the data to the transmission buffer 604a as DCH data, or sends the MAC-d flow data (MAC-d) to the MAC-e unit 605. d PDU). The communication amount measurement unit 608 receives the data amount information DCH LOGbuffer and EDCH LOGbuffer from the radio link control unit 202. Further, the traffic volume measurement unit 608 outputs traffic volume report information (Traffic Report) to the MAC control unit 607 in order to notify the base station control apparatus 104 of the data volume information via the base station 103.
The MAC-e unit 605 inputs MAC-d flow data from the transmission system MAC-d unit 603 and outputs E-DCH data (MAC-e PDU) to the E-DCH buffer 604b. Further, the MAC-e unit 605 inputs E-DCH data amount information (EDCH LOGbuffer) from the radio link control unit 202 to the data amount information unit 606, and the data amount information unit 606 receives second data amount information ( TRbuffer) is output to the control information multiplexing unit 610. Details of the operation of the MAC-e unit 605 will be described later.
The MAC control unit 607 controls the entire media access control unit 203. At the same time, control information (MACcont) including information necessary for known technology and information necessary for the present invention is exchanged with the radio resource control unit 206.

FIG. 6 is a diagram illustrating input / output data of the mobile station 102 between the radio link control unit 202 and the media access control unit 203 at the time of transmission. Here, what is related to E-DCH will be described, and what is related to DCH is not directly related to the present invention, so description thereof will be omitted.
In the media access control unit 203, the MAC-d unit 603 is a part existing in the conventional standard. The MAC-e unit 605 is a part related to E-DCH.
When transmission data (TXdata) is supplied from the upper layer block 201 to the radio link control unit 202, it is output as DTCH data to the media access control unit 203 after various processes. The DTCH data input to the media access control unit 203 is input to the MAC-d unit 603 in the media access control unit 203, and then input to the MAC-e unit 605 as MAC-d flow through various processes. Next, the MAC-d flow data (MAC-d PDU) input to the MAC-e unit 605 is output as E-DCH data from the MAC-e unit 605 through various processes.
The data input to the radio link control unit 202 is referred to as RLC SDU (Service Data Unit) in the radio link control unit 202. Data output from the radio link control unit 202 is referred to as RLC PDU (Protocol Data Unit) in the radio link control unit 202.
Data input to the MAC-d unit 603 is called a MAC-d SDU in the MAC-d unit 603. Data output from the MAC-d unit 603 is called a MAC-d PDU in the MAC-d unit 603.
Data input to the MAC-e unit 605 is called a MAC-e SDU in the MAC-e unit 605. Data output from the MAC-e unit 605 is called a MAC-e PDU in the MAC-e unit 605.

  FIG. 7 is a block diagram illustrating a configuration of the physical layer control unit 204 of the mobile station 102. The physical layer control unit 204 includes a reception unit 701, a demodulation unit 702, a separation unit 703, a multiplexing unit 704, a modulation unit 705, a transmission unit 706, a PHY control unit 707, and an antenna 205.

The input / output relationship of each part of the physical layer control unit 204 will be outlined.
The receiving unit 701 converts a radio frequency signal received from the base station 103 via the antenna 205 into a baseband signal using a known technique, and then outputs the baseband signal to the demodulating unit 702. Demodulation section 702 demodulates the baseband signal input from reception section 701 using a known technique, and then outputs downlink physical channels DPDCH, DPCCH, and E-DPCCH to demultiplexing section 703. Separating section 703 separates DCH data and data for physical control channels DPCCH and E-DPCCH from the input DPDCH, DPCCH, and E-DPCCH using a known technique. Separation section 703 outputs DCH data and E-DPCCH data to media access control section 203 and also outputs DPCCH data to PHY control section 707. In the first embodiment, only the DCH is the transport channel multiplexed on the received DPDCH.
On the other hand, the multiplexing unit 704 inputs uplink DCH data and E-DCH data from the media access control unit 203. Further, the multiplexing unit 704 receives uplink DPCCH data and DPCCH (E-DCH) data from the PHY control unit 707. The multiplexing unit 704 multiplexes various input channel data using a known technique, and outputs the multiplexed data to the modulation unit 705 as data of transmission physical channels DPDCH, DPCCH, and DPCCH (E-DCH). Modulation section 705 modulates the input transmission physical channels DPDCH, DPCCH, and E-DPCCH data using a known technique, and then outputs the modulated data to transmission section 706 as a transmission baseband signal.
In Embodiment 1, DPDCH, DPCCH, and E-DPCCH are code-multiplexed using different spreading codes, but the multiplexing method itself is not limited to that of Embodiment 1.
The transmission unit 706 converts the input baseband signal into a radio frequency signal using a known technique. The converted radio frequency signal is transmitted to the base station 103 via the antenna 205. The PHY control unit 707 controls the entire physical layer control unit 204. Further, the PHY control unit 707 exchanges control information PHYcont including information necessary for known technology and information necessary for the present invention with the radio resource control unit 206.

FIG. 8 is a diagram illustrating the multiplexing relationship between the transport channel and the physical channel in the uplink and the principle of channel multiplexing according to the first embodiment. A similar channel multiplexing principle is defined in the standard TS25.213. Further, this multiplex processing is performed by the physical layer control unit 204 of the mobile station 102.
In the figure, DPDCH _{1 to} DPDCH ₆ correspond to DPDCH (DCH) 108 or DPDCH (E-DCH) 110. HS-DPCCH is a physical channel added in Release 5 and is not related to the present invention, so that the description thereof is omitted. C _d is a spreading code for channel separation for DPDCH (DCH). C _c is a spreading code for channel separation for DPCCH. C _T is the channel separation spreading code for DPCCH (E-DCH). _Chs is a spreading code for channel separation for HS-DPCCH. C _eu is a channel separation spreading code for DPDCH (E-DCH). β _d is a signal amplitude coefficient for DPDCH (DCH). β _c is a signal amplitude coefficient for DPCCH. β _hs is a signal amplitude coefficient for HS-DPCCH. beta _T is a signal amplitude coefficient for DPCCH (E-DCH). _βeu is a signal amplitude coefficient for DPDCH (E-DCH). S _{dpch, n} is a scramble code for mobile station identification.

DPDCH ₁ , DPDCH ₃ , DPDCH ₅ and DPCCH (E-DCH) are multiplied by respective channel separation spreading codes and signal amplitude coefficients, and then added by an I-axis adder (Σ). On the other hand, DPDCH ₂ , DPDCH ₄ , DPDCH ₆ , DPCCH, and HS-DPCCH are multiplied by each channel separation spreading code and signal amplitude coefficient, and then added by a Q-axis adder (Σ). The output of each adder becomes the I component and Q component of the complex signal (= I + jQ).
Next, DPDCH ₂ , DPDCH ₄ , DPDCH ₆ , DPCCH, and HS-DPCCH added by the Q-axis adder are multiplied by an imaginary number j so as to be assigned to the Q-axis side of the complex signal. This indicates that the mobile station 102 actually processes the Q component of the complex signal.
Thereafter, DPDCH ₁ , DPDCH ₃ , DPDCH ₅ and DPCCH (E-DCH) added by the I-axis adder are added by the adder (+). As a result, a so-called IQ multiplexed complex signal is obtained. Next, the IQ multiplexed complex signal is multiplied by a mobile station identification scramble code S _{dpch, n} by a multiplier (x). The generated signal is wirelessly transmitted from the physical layer control unit 204 to the base station 103 via the antenna 205. Note that, as new specifications (E-DCH) are added, specifications different from conventional standards may be specified for the spread codes for channel separation and signal amplitude coefficients. For example, when the PAR (Peak to Average) of the multiplexed signal increases as a result of additional code multiplexing of the E-DCH DPDCH, the increase in PAR is mitigated by changing the channel separation spreading code and the signal amplitude coefficient.

  Next, the configuration on the base station side will be described. The base station side includes a base station 103 and a base station control device 104. The basic configuration on the base station side is almost the same as the configuration of the mobile station 102 in which the uplink-related block and the downlink-related link block are exchanged, and therefore, the blocks different in configuration from the mobile station 102 will be mainly described.

FIG. 9 is a block diagram showing the configuration of the base station side (base station 103, base station control device 104). As shown in the figure, the base station side includes an upper layer block 1201, a radio link control unit 1202, a media access control unit 1203, a physical layer control unit 1204, an antenna 1205, and a radio resource control unit 1206. The media access control unit 1203 includes a MAC-e unit 1220 corresponding to the implementation of the present invention and a MAC-d unit 1221 corresponding to the conventional standard.
In the mobile station 102, all blocks are in the mobile station, but on the base station side, the base station controller 104 and the base station 103 are distributed. The distribution method varies depending on the implementation of the apparatus. In Embodiment 1, the upper layer block 1201, the radio link control unit 1202, and the radio resource control unit 1206 are arranged in the base station control apparatus 104.
Further, the media access control unit 1203 is distributed and arranged in both the base station control device 104 and the base station 103. The physical layer control unit 1204 is arranged in the base station 103. Since the configurations and operations of the upper layer block 1201, the radio link control unit 1202, and the radio resource control unit 1206 are the same as those of the mobile station 102, description thereof is omitted.

  FIG. 10 is a block diagram showing a configuration of the media access control unit 1203 on the base station side. As shown in the figure, the media access control unit 1203 includes a MAC-e unit 1220, a reception system MAC-d unit 1221-1, a transmission system MAC-d unit 1221-2, a reception buffer 1601a, an E-DCH buffer 1601b, A transmission buffer 1604 and a MAC control unit 1607 are provided.

Next, the input / output relationship of each part of the media access control unit 1203 will be outlined.
Regarding the operations of the reception system MAC-d unit 1221-1, transmission system MAC-d unit 1221-2, reception buffer 1601a, E-DCH buffer 1601b, transmission buffer 1604, and MAC control unit 1607, the media access of the mobile station 102 In the control unit 203, the uplink block and the downlink block are exchanged, and the configuration is the same as that of the configuration in which the MAC-e unit 605 is omitted.
The MAC-e unit 1220 inputs the reception determination result ACK / NACK from the physical layer control unit 1204 and the report information TRbuffer notified from the mobile station 102. In addition, the MAC-e unit 1220 performs radio resource control, that is, scheduling, on the uplink E-DCH. Also, the downlink E-DPCCH is output to the physical layer control unit 1204. Details of each E-DPCCH will be described later.

  FIG. 11 is a block diagram illustrating a configuration of the physical layer control unit 1204 on the base station side. As shown in the figure, the physical layer control unit 1204 includes a reception unit 1701, a demodulation unit 1702, a separation unit 1703, a multiplexing unit 1704, a modulation unit 1705, a transmission unit 1706, a PHY control unit 1707, and an antenna 1205.

Next, an input / output relationship of each unit of the physical layer control unit 1204 will be outlined.
Since the operations of the antenna 1205, the reception unit 1701, the demodulation unit 1702, the modulation unit 1705, and the transmission unit 1706 are the same as those of the mobile station 102, the description thereof is omitted.
The demultiplexer 1703 inputs demodulated data from the demodulator 1702 through the uplink physical channels DPDCH and DPCCH. Further, the received DCH data and the received E-DCH data are separated from the uplink DPDCH data using a known technique. Also, E-DCH data reception determination result ACK / NACK is output to Mac-e unit 1220 of MAC unit 1203. Also, the separated report information TRbuffer is output to the MAC-e unit 1220. Also, the separated uplink DPCCH data is output to the PHY control unit 1707.
The multiplexing unit 1704 uses downlink DCH data from the transmission buffer 1604, downlink E-DPCCH data from the MAC-e unit 1220, and downlink DPCCH data from the PHY control unit 1707 using a known technique. Are multiplexed and output to the modulation unit 1705.

Next, the operation during uplink will be described.
FIG. 12 is a diagram illustrating a packet transmission flow from the mobile station to the base station according to the first embodiment.
It should be noted that here, a description of the DPCCH 106, which is a conventional physical control channel, is unnecessary and is omitted. In addition, the flow related to DCH data transmission transmitted from the base station 103 is not a matter specific to the present invention, and thus the description thereof is omitted.

First, in step ST200, the mobile station 102 measures an untransmitted data amount (Measurement) as one of state information of the mobile station 102 (step ST200).
The data to be measured includes the data amount of each buffer of the radio link control unit 202, the data amount of each buffer of the media access control unit 203, the data amount by priority of untransmitted data, and the retransmission control function ARQ (Automatic Repeat reQuest). ), There is a data amount by priority regarding retransmission control. In Embodiment 1, the amount of data in the transmission buffers 502a and 502b of the radio link control unit 202 is used as report information (TRbuffer) notified from the mobile station 102 to the base station 103 for scheduling.
The status information of the mobile station 102 includes other transmission power (total power or specific channel power) from the mobile station 102 or its statistical value, transmission power margin or its statistical value, priority of untransmitted data or its statistical value. Value, transmission speed or its statistical value. These may be measured simultaneously with the above-described measurement of the amount of untransmitted data, or may be collected separately.

The operation of mobile station 102 in step ST200 will be described in detail.
First, when a communication service is generated in the upper layer block 201, the service data is stored in the transmission buffer 502a of the radio link control unit 202 as transmission data (TXdata). Thereafter, the data stored in the transmission buffer 502a is output to the transmission system MAC-d unit 603 of the media access control unit 203 as transmission data of the logical channel DTCH. Various known transmission control information (TXcontrol) related to the communication service is stored in the transmission buffer 502b. The transmission control information (TXcontrol) stored in the transmission buffer 502b is output from the transmission buffer 502b to the transmission MAC-d unit 603 of the media access control unit 203 as control logical channel DCCH data.

Further, in the transmission buffers 502a and 502b of the radio link control unit 202, a serial number TSN (Transmission Sequential Number) is added for each transmission unit amount of each logical channel data. As a result, it is possible to determine whether a part of the data has been lost due to a communication error, or whether the data has arrived at the base station 103 in order. Further, the base station 103 can reconstruct the data string based on this number. Note that the addition of TSN may be performed by the transmission system MAC-d unit 603 of the media access control unit 203. Which is installed is specified in the standard, but in the present invention, which is installed. Also good.
Further, data amount information (Data info) in the buffer is output from the transmission buffers 502 a and 502 b to the buffer monitoring unit 504. This report may be performed periodically, may be performed when the amount of data changes, or may be performed at other timings or conditions. The condition setting is set in the mobile station 102 by the radio resource control unit 206 in advance based on the exchange with the base station before starting communication.
In the buffer monitoring unit 504, the input data amount information (Data info) is classified into one for the transport channel DCH and one for the E-DCH. Each classified data amount information (Data info) is output as DCH data information (DCH LOGbuffer) and E-DCH data information (EDCH LOGbuffer) for each logical channel.

  Data information (DCH LOGbuffer and EDCH LOGbuffer) output from the buffer monitoring unit 504 is output to the communication amount measuring unit 608 in the media access control unit 203 and the data amount information unit 606 in the MAC-e unit 605, respectively. Note that the transmission / reception of information among the radio link control unit 202, the media access control unit 203, the physical layer control unit 204, and the like as described above may be referred to as primitive.

  Based on the DCH LOGbuffer and EDCH LOGbuffer, the traffic volume measuring unit 608 is assigned to the total value of the logical channel data amount assigned to the conventional channel DCH and to the E-DCH channel related to the present invention. The total value of the data amount of the logical channel is obtained. This is an extension of the traffic volume measurement report function (Traffic volume measurement) notified to the base station controller 104 defined in the conventional standard. A measurement cycle, a measurement method, a report condition, and the like related to E-DCH data information are defined in TS25.331, and are set by the base station control device 104 when communication is started. Note that the measurement period, measurement method, report condition, and the like may be set differently for each logical channel or each transport channel.

Next, each calculated total amount of data is output to the MAC control unit 607 in accordance with a report condition set for a traffic report to be notified to the base station controller 104 (Traffic Report).
The MAC control unit 607 transfers a traffic report (Traffic Report) to the radio resource control unit 206. The radio resource control unit 206 transmits the transferred traffic report (Traffic Report) via the radio link control unit 202, the media access control unit 203, the physical layer control unit 204, the antenna 205, and the base station 103 of the mobile station 102. To the base station controller 104.

  Also, the E-DCH data information (EDCH LOGbuffer) input to the data amount information unit 606 is converted into a data format of report information (TRbuffer) for notification to the base station 103 using a known technique, and control information multiplexing To the unit 610. As the report information (TRbuffer), similar to the traffic volume measurement report function for notifying the base station controller 104 (Traffic volume measurement), the total value of the data amount, the data amount by buffer, the data amount by channel, The amount of data by priority can be considered. The data format is determined by the standard document TS25.331. In Embodiment 1, the amount of data for each logical channel allocated to E-DCH is used.

Next, in step ST201, the mobile station 102 transmits an uplink radio resource allocation request to the base station 103.
The operation of mobile station 102 in ST201 will be described.
First, the report information (TRbuffer) output from the data amount information unit 606 to the control information multiplexing unit 610 is multiplexed with uplink MAC-d flow data (MAC-d PDU) using a known technique, and MAC-e. And then output from the MAC-e unit 605 to the E-DCH buffer 604b as E-DCH data (MAC-e PDU). Multiplexing processing in the control information multiplexing unit 610 is performed by adding various information of the MAC-e unit 605 as a header. In practice, there may be no MAC-d flow data to be transmitted.
Next, the multiplexed E-DCH data is output from the E-DCH buffer 604 b to the multiplexing unit 704. The E-DCH data input to the multiplexing unit 704 is multiplexed using a known technique and output to the modulation unit 705 as DPDCH data.

Uplink DPCCH data and DPCCH (E-DCH) data are respectively output from the PHY control unit 707, multiplexed in the multiplexing unit 704 with DPDCH and DPCCH (E-DCH), and output to the modulation unit 705. .
Note that when there is no MAC-e SDU data, DPCCH (E-DCH) data is not output from the PHY control unit 707.
Next, the DPDCH data, DPCCH data, and DPCCH (E-DCH) data input to the modulation unit 705 are modulated by a known technique. Each modulated data is processed in the transmission unit 706 and then wirelessly transmitted to the base station 103 via the antenna 205.
In addition to the report information (TRbuffer), other movements such as transmission power margin information (Power margin) indicated in relation to the transmission request channel USICCH in Non-Patent Document 1 are included in the DPDCH (E-DCH) 110. Station information can also be included. What information is transmitted simultaneously with the report information (TRbuffer) differs depending on the configuration of the scheduler implemented in the MAC-e unit 1220 of the base station 103 and the radio resource management method. RRC signaling).
In the mobile station 102, as an expression format when multiplexing report information (TRbuffer) included in E-DCH data (MAC-e PDU) onto DPDCH (E-DCH) 110, 1. Data amount (number of bits) 2. an index indicating a combination of data amounts; 3. Buffer occupancy (%) 4. Index indicating a combination of buffer occupancy rates; 5. statistics of data volume or buffer occupancy; 6. index of statistical values; Increase / decrease in data volume, 8. 8. Index indicating increase / decrease in data amount, The threshold of the amount of data to be reported; 10. threshold index; Increase / decrease amount, 12. Increase / decrease index, 13. Requested transmission rate converted based on the amount of data; 14. 14. Required transmission rate index It is possible to convert the data into various representation formats such as the expected transmission speed converted based on the data amount. The multiplexing process is defined in the standard document TS25.212, and the correspondence between the data amount information and the index is defined in the standard document TS25.214.

Next, the reception operation of DPDCH (E-DCH) 110 in base station 103 will be described.
Uplink DPDCH (E-DCH) 110 data received via the antenna 1205 is processed by a receiving unit 1701, a demodulating unit 1702, and a demultiplexing unit 1703, respectively, using a known technique. From the separation unit 1703, the higher-order data (MAC-e SDU) separated from the DPDCH (E-DCH) is output as E-DCH data to the E-DCH buffer 1601b. Also, report information (TRbuffer) is separated from the separation unit 1703 and input to the MAC-e unit 1220.

Next, in step ST202, the MAC-e unit 1220 of the base station 103 performs uplink radio resource allocation (scheduling) for the mobile station 102.
The scheduling operation of base station 103 in step ST202 will be described.
The MAC-e unit 1220 measures and predicts an increase in power (Noise Rise) caused by packet transmission from the mobile station 102, and performs uplink scheduling so that the sum is within the reception power margin value of the base station 103. . Information used for scheduling includes: 1. Communication service type and QoS of the mobile station 102; 2. Communication speed setting, 3. communication environment; 4. Amount of data received by base station 5. Data amount information of the mobile station 102 There are uplink quality (path loss) and the like, and what is used depends on the implementation method of the scheduler.
As a scheduling method, 1. 1. Method for giving priority to mobile station 102 with a large amount of untransmitted packets 2. a method for giving priority to the mobile station 102 having a transmission power margin; 3. A method for assigning transmission requests in the order received. 4. A method of assigning the mobile stations 102 in a predetermined order (so-called Round Robin). 5. A method of preferentially allocating to the mobile station 102 having a good communication environment with less propagation loss or less interference (so-called Max C / I); 6. An intermediate method between Round Robin and Max C / I (so-called Proportional Fairness), 7. a method of giving priority to the mobile station 102 having high priority data; Various methods such as a method of assigning the delay from the mobile station 102 to the communication partner (for example, a computer connected to another communication network 105) to shorten the delay, a combination of various methods 9.1 to 8, and the like are applied. Is possible. In designing the base station apparatus and the communication system, for example, the design and selection are performed so that the throughput of the entire cell becomes the highest.
In addition, the scheduling target channels are: 1. Only the E-DCH is targeted, and the base station controller 104 is controlled as in the past for the DCH. 2. Control is performed including DCH under the restriction of control in the conventional base station controller 104; 3. Perform control including DCH in cooperation with the base station control device 104; Various methods such as targeting the logical channel allocated to E-DCH can be applied. In designing the base station apparatus and the communication system, for example, it is designed and selected so that the throughput of the entire cell becomes the highest. The
In addition, as an expression format of the scheduling result, 1. 1. Maximum transmission speed 2. Total power or channel power; Power offset, 4. 4. DPDCH signal amplitude coefficient (gain factor); Timing or duration, 6. 6. Power margin, Various types of indexes, 8. 8. Combination of various types, Various methods such as increase / decrease in various formats are applicable, and communication overhead due to the required number of bits is taken into consideration. Details thereof are defined in the standard document TS25.214 and the like. In the first embodiment, it is assumed that the maximum allowable transmission rate is used as a scheduling result format and is notified to mobile station 102.

Next, in step ST203, scheduling result information (Scheinfo) is notified from the base station 103 to the mobile station 102 via the downlink E-DPCCH 111.
The transmission operation of base station 103 in step ST203 will be described.
First, the maximum allowable transmission rate information as scheduling result information is output from the MAC-e unit 1220 to the multiplexing unit 1704 as E-DPCCH 111 data. In multiplexing section 1704, E-DPCCH, DCH, and DPCCH are multiplexed by a known technique, and further wirelessly transmitted via modulation section 1705, transmission section 1706, and antenna 1205.
At this time, the DCH (or DPDCH) may not actually have DCH data to be transmitted. For example, when there is no service data (TXdata) to be transmitted from the base station 103 when the communication service is started, only scheduling result notification is performed.
Next, the reception operation of mobile station 102 in step ST203 will be described.
The downlink E-DPCCH 111 data received by the antenna 205 is processed by the receiving unit 701, the demodulating unit 702, and the demultiplexing unit 703, and input to the MAC-e unit 605 as scheduling result information (E-DPCCH data).

Next, in step ST204, packet data is transmitted by DPDCH (E-DCH) / DPCCH (E-DCH) 110 based on the scheduling result information notified from base station 103 by mobile station 102.
The transmission operation of mobile station 102 in step ST204 will be described.
The MAC-e unit 605 determines the amount of transmission data (or transmission rate) that can be transmitted within the range of the maximum allowable transmission rate notified from the base station 103, and stores the untransmitted data in the E-DCH buffer 604b. Output as E-DCH data. At this time, the MAC-e unit 605 controls the output timing, that is, the transmission timing from the mobile station 102. Control of transmission timing is as follows. 1. When based on scheduling of the base station 103 (Time & Rate control), 2. 2. When based on autonomous transmission of the mobile station 102 (Autonomous control); There are various methods such as a case based on probability (persistence control), and the operation varies depending on the scheduling method in the MAC-e unit 605, but the operation is defined in the standard TS25.214.

The E-DCH data stored in the E-DCH buffer 604b is output to the multiplexing unit 704 and multiplexed with other channels. The multiplexing unit 704 determines a modulation method and the like based on the data amount of the input E-DCH data, and outputs it to the modulation unit 705 as DPCCH (E-DCH) data. Note that the determination of the modulation method may be performed by the MAC-e unit 605 and differs depending on the mounting method of the mobile station 102. When the MAC-e unit 605 performs the scheduling information, the scheduling information is transmitted from the media access control unit 203 to the physical layer control unit 204 as a primitive (not shown).
Each channel data multiplexed by the multiplexing unit 704 is processed by a modulation unit 705 and a transmission unit 706 according to a known technique, and is transmitted as radio transmission data (Data) by the DPDCH (E-DCH) 110 via the antenna 205. Wirelessly transmitted to the base station 103. The radio transmission data (Data) to be transmitted includes report information (TRbuffer).
In Embodiment 1, the report information (TRbuffer) is transmitted to the base station in step ST201. However, when packet data is transmitted in step ST204, the report information (TRbuffer) may be transmitted at the same time.

The reception operation of base station 103 in step ST204 will be described.
Radio transmission data (Data) received via the antenna 1205 is processed by a receiving unit 1701, a demodulating unit 1702, and a separating unit 1703 according to a known technique, and data of each channel is demodulated and separated and output. In addition, the separation unit 1703 performs reception determination of E-DCH data. When the reception determination result is OK, an ACK signal is sent to the MAC-e unit 1220, and the received higher layer data is output to the E-DCH buffer 1601b as E-DCH data. The E-DCH data input to the E-DCH buffer 1601b is sent to the upper layer block 1201 through the processing of each unit of the radio link control unit 1202. On the other hand, if the reception determination result is NG, a NACK signal is sent to the MAC-e unit 1220 and the received data is discarded. If the reception determination result is NG, it is also possible to combine data after waiting for retransmission from the mobile station 102. In this case, the received data is temporarily held.

Next, in step ST205, the reception determination result (ACK / NACK) is notified from the base station 103 to the mobile station 102 to the mobile station 102 via the downlink E-DPCCH 111.
The transmission operation of base station 103 in step ST205 will be described.
The reception determination result (ACK / NACK) is output from the MAC-e unit 1220 to the multiplexing unit 1704 as E-DPCCH data. Thereafter, the data is processed by a multiplexing unit 1704, a modulation unit 1705, and a transmission unit 1706 according to a known technique, and wirelessly transmitted as downlink E-DPCCH 111 data. The processing after multiplexing is performed in the same manner as in step ST203.

Next, the reception operation of mobile station 102 in step ST205 will be described.
The E-DPCCH 111 received by the antenna 205 is processed by the reception unit 701, the demodulation unit 702, and the separation unit 703 by a known technique, and is input to the MAC-e unit 605 as E-DPCCH data.
The MAC-e unit 605 analyzes the reception determination result (ACK / NACK) in the E-DPCCH data, and determines whether to retransmit packet data or transmit new data (retransmission control). The MAC-e unit 605 outputs the E-DCH data to the E-DCH buffer 604b.
The E-DCH buffer 604b transmits the E-DCH data as radio transmission data (Data) to the base station 103 via the multiplexing unit 704, the modulation unit 705, the transmission unit 706, and the antenna 205. That is, the process proceeds to step ST204. The operation of the MAC-e unit 605 at the time of retransmission control will be described later.

As described above, the base station 103 performs scheduling for uplink packet data transmission based on the report information (TRbuffer) directly transmitted from the mobile station 102 to the base station 103.
In the first embodiment, among a series of steps (steps ST200 to ST205) necessary for transmitting packet data from mobile station 102, a scheduling cycle including step ST201 and step ST203, and step ST204 And the cycle for packet data transmission consisting of step ST205 is performed continuously, but the two cycles may be performed separately.
Also, the data amount measurement step ST200 in the mobile station 102 may be performed in a cycle different from a series of cycles. In this case, report information (TRbuffer) at the time before the start of step ST201 may be used during scheduling.

Next, retransmission control processing in the MAC-e unit 605 of the mobile station 102 will be described.
FIG. 13 is a diagram illustrating a configuration related to retransmission control of the MAC-e unit 605. As shown in the figure, the MAC-e unit 605 includes a retransmission control unit 650, and the retransmission control unit 650 includes a selector 651 and retransmission buffers 652 _{1 to} 652 _M.
Various known techniques can be applied as a retransmission control method in the mobile station 102. In the first embodiment, the channel parallel type Stop & Wait method (hereinafter referred to as M-channel Stop & Wait) disclosed in Release 5 of the standard document. It is assumed that retransmission control is performed. In this method, M independent retransmission cycles are performed in a time multiplexed manner.
The MAC-d flow data (MAC-e SDU) input to the MAC-e unit 605 is sent by the selector 651 of the retransmission control unit 650 based on the quality request (QoS) for the data service, the priority of the logical channel, and the like. Retransmission buffers 652 ₁ , 652 ₂ ,. . . , 652 are stored in one of _M. The selector 651 adds an index (Queue ID: 1 to M) to the head of the input MAC-d flow data (MAC-e SDU) in order to distinguish each retransmission buffer.
According to the transmission timing control in the MAC-e unit 605, retransmission buffers 652 ₁ , 652 ₂ ,. . . , 652 _M is selected from the _M and the stored data is output to the control information multiplexer 610.
The data input to the control information multiplexing unit 610 is multiplexed with report information (TRbuffer) in the control information multiplexing unit 610 and output to the E-DCH buffer 604b as E-DCH data (MAC-e PDU). Subsequent processing is the same as step ST204 of FIG.

FIG. 14 is a diagram illustrating a format of a MAC-e PDU output from the MAC-e unit 605 according to the first embodiment. In the figure, (a) shows the format of the MAC-e PDU, and (b), (c), and (d) show examples of VF values and their definitions when using this format.
Queue ID is an index of retransmission buffers 652 _{1 to} 652 _M. D _{1 to DN} are report information (TRbuffer) areas. N is the number of logical channels, the D ₁ to D _N can place logical channel-specific report information. As the value of N, the number M of retransmission buffers may be used, or a part of the M pieces of information may be assigned. When some information is used, when data is actually transmitted from the transmission buffer for each logical channel, the data amount information of the buffer may be included. A transmission sequence number (TSN) is a serial number that is assigned in order to correctly sort and output data from the lower layer to the upper layer when receiving at the base station 103. SID (Size ID) _{1 to} SID _k are indexes indicating the length of the MAC-e SDU when a plurality of MAC-e SDUs having the same number of bits are transmitted at a time. N _{1 to} N _k are numbers indicating how many MAC-e SDUs of the same SID are consecutive. F _{1 to} F _k−1 are flags indicating that a MAC-e header (MAC-e header) follows. Padding is a bit added to adjust the length of the MAC-e PDU to a multiple of 8 bits, for example. opt indicates an optional specification. In MAC-e, the entire MAC-e SDU is called MAC-e payload.
As shown in the figure, the report information areas D _{1 to DN} are multiplexed in the header area (MAC-e header) of the MCA-e PDU. Note that the definition of the MAC-e PDU format and parameters are defined in the standard TS25.321, but the order of the areas in the MAC-e header is not limited to that shown in the figure.

As a method of using the VF value, for example, the following can be considered.
In the example shown in (b) in the figure, the case where VF is used as the identifier of the release version of the standard is shown. According to this example, since it is possible to cope with future format changes, a base station 103 corresponding only to a release in which E-DCH is newly added and a base station 103 corresponding to a later release are included in the communication system. Even in the case of coexistence, backward compatibility (Backward compatibility) can be secured, and it is also possible to cope with the case where the standard is expanded in the future.
In the example shown in (c), the case where VF is used as an identifier for the presence / absence of multiplexing of report information (TRbuffer) is shown. According to this example, when there is no large change in the data amount of the transmission buffer and new report information (TRbuffer) is not transmitted to the base station 103, the length of the MAC-e PDU is made variable and the number of transmission bits is shortened. can do. As a result, it is possible to reduce communication overhead occurring in the communication cycle for scheduling, and to reduce communication interference in the uplink.
In the example shown in (d), the VF value is represented by a plurality of bits and used as an identifier of the content of the report information (TRbuffer). For example, in Embodiment 1, VF = 00 is used because data amount information for each logical channel assigned to E-DCH is transmitted to base station 103. According to this example, a plurality of types of contents of the report information (TRbuffer) can be set, so that the most effective report information can be used for a communication system used by a communication company or a base station manufacturer.
It should be noted that an identifier combining (b), (c), and (d) can be obtained by dividing and using the bit representing VF.

FIG. 15 is a diagram illustrating another example of the format of the MAC-e PDU.
The difference from the format shown in FIG. 14 is that a parameter P is added after the report information (TRbuffer). In the first embodiment, the parameter P represents the mobile station total transmission power value (absolute value). Note that the DPCCH 106 power value (absolute value) may be used instead of the total transmission power value (absolute value). By using this format, the base station 103 can measure the uplink communication environment (for example, propagation loss: Path Loss), and more efficient scheduling is possible by using the information for scheduling. It becomes.
Note that the value of the parameter P may represent another state measurement item of the mobile station 102 as described in relation to step ST200 of FIG. When there is a plurality of pieces of mobile station information in the scheduling operation of the base station 103, more effective scheduling can be performed. It should be noted that depending on the report timing, the format with the parameter P and the format without the parameter P may be set to be used properly. Further, when there is a case where the power information is notified to the base station 103 that can use only the format without the parameter P, the report information area D may be used instead of the data amount information. The state information regarding power is measured by the physical layer control unit 204, notified to the MAC-e unit 605 by control information (PHYcont, MACcont) or primitive, and transmitted to the base station 103 through the processing of the physical layer control unit 204. .

Further, in FIGS. 14 and 15, the order and position of the report information regions D ₁ to D _N and power information region P is not limited to the example of FIG. However, since the MAC-e unit 605 can perform processing collectively by keeping them adjacent, the configuration of the processing device is simplified.
14 and 15, if error correction processing is performed on all or part of the MAC-e header (for example, the report information areas D _{1 to DN} and the power information area P), transmission errors are reduced. be able to.
Further, the mobile station identification information (UE ID) column is provided in the MAC-e header, or the mobile station identification information (UE ID) is incorporated into the whole or a part of the MAC-e header, so that the base station 103 Since the mobile station 102 can be identified, transmission from the mobile station 102 can be performed on a common link, and radio resources can be used more efficiently.
If the length of the MAC-e PDU is made variable, it is not necessary to add an additional bit (Padding) at the end. In the implementation of the media access control unit 203, a DSP, a gate array, or the like is used in order to prioritize speeding up of processing. Therefore, the processing amount of the mobile station 102 can be reduced by shortening the length of the MAC-e PDU.
Further, the length of the MAC-e PDU may be made variable, and the length of the report information D _{1 to DN} may be shortened when the number of logical channels to be reported as report information is small. In that case, an identification number of the logical channel (denoted as C / T in the standard) may be added to each of the report information areas D _{1 to DN} .

As described above, according to Embodiment 1, untransmitted data information of mobile station 102 is multiplexed as report information (TRbuffer) on the MAC-e header of the MAC-e PDU and transmitted to base station 103. Therefore, high-speed notification of untransmitted data amount information from the mobile station 102 to the base station 103 is possible. As a result, uplink radio resource control (scheduling) in the base station 103 becomes possible, and high-speed control is possible compared to radio resource control by the base station control device 104, so that the communication system becomes more efficient, There is an effect that the throughput of the entire cell is improved.
Further, since the untransmitted data information as the status information of the mobile station 102 is transmitted directly to the base station 103 without going through the base station control device 104, high-speed and high-frequency transmission is possible. There is an effect that the link radio resource control is made more efficient and the throughput of the entire cell is improved.
In addition, there is no need to transfer data amount information from the base station control device 104 to the base station 103, and there is an effect that traffic from the base station control device 104 to the base station 103 can be reduced.
In addition, since report information is multiplexed with higher-order data (MAC-e SDU) and transmitted via DPDCH, a dedicated channel (channel separation code) is used to notify mobile station 102 status information to base station 103. There is no need to secure. When a plurality of channels are transmitted in parallel using many spreading codes, it is possible to reduce peak / average (PAR: Peak to Average Ratio) in a radio frequency signal. For this reason, it is possible to relax the linearity in the transmitter characteristics of the mobile station 102 and to transmit for a long time.
Since the base station 103 is notified of the data amount information for each logical channel, the base station 103 that holds the logical channel information of all the mobile stations performs control in consideration of the priority of transmission between the mobile stations. It becomes possible. Thereby, there is an effect that uplink scheduling becomes more efficient.

In the first embodiment, the data amount report (Traffic Report) generation to the base station control apparatus 104 and the report information (TRbuffer) generation to the base station 103 are performed in separate processing blocks. You may go on. For example, an extension of the standard specification of a conventional Traffic volume measurement block can be considered.
Further, DCH related information such as DCH data amount information (DCH LOGbuffer), DCH transmission rate information, logical channel priority information of DCH data, and the like from the radio link control unit 202 is also transmitted as report information (TRbuffer). It may be. In this case, since the base station 103 can also grasp the amount of DCH transmission data, the base station controller 104 can take into account the amount of interference due to the DCH when scheduling the E-DCH in the base station 103. When combined with the control of both low-speed channels (DCH and E-DCH), more efficient communication system control is possible. This is particularly effective when transmission control is performed independently for DCH transmission and E-DCH transmission, and transmission priorities are different.

Embodiment 2. FIG.
The configuration of the mobile station and base station according to the second embodiment is the same as that of the first embodiment.
FIG. 16 is a diagram illustrating a MAC-e PDU format according to the second embodiment. In the figure, (a) shows the format of the MAC-e PDU, and (b) and (c) show examples of parameter D / C definitions. Also in Embodiment 2, the report information (TRbuffer) is multiplexed on the MAC-e header. D / C is a flag indicating whether only data is transmitted or whether control information is also transmitted. Other parameters are the same as those in the first embodiment. In addition, MAC-e payload may not be transmitted. In that case, zero is set as the values of SID ₁ and N ₁ , and only various control information for base station scheduling including report information (TRbuffer) is transmitted as the MAC-e PDU.

In the example shown in (b), the parameter D / C is used to indicate the presence / absence of information for radio resource control in the base station 103 such as the report information areas D _{1 to DN} . D / C = 0 indicates that there is control information, and D / C = 1 indicates that there is no control information. By defining the D / C flag at the beginning of the MAC-e header, the base station 103 can recognize the presence or absence of control information such as report information (TRbuffer) at the start of reception. Since packet data is generated in bursts and the amount of data received by the base station 103 can be grasped, the transmission frequency can be reduced by transmitting report information only when a burst occurs. Thereby, it is possible to suppress the occurrence of uplink interference, and resources can be passed to other mobile stations 102.

In the example shown in (c), D / C = 0 represents a case where upper layer data (MAC-e SDU) is present, and represents a case where D / C = 1 is absent. In this case, control information such as report information (TRbuffer) is transmitted by default when transmitting all MAC-e PDUs. Therefore, when the communication overhead by the report information area (D _{1 to} D _N ) is small, the status information of the mobile station 102 can be notified to the base station 103 at a high frequency, and scheduling at the base station 103 is more effective. Can be.

As described above, according to Embodiment 2, untransmitted data information of mobile station 102 is multiplexed as report information (TRbuffer) in the MAC-e header of MAC-e PDU and transmitted to base station 103. Therefore, high-speed notification of untransmitted data amount information from the mobile station 102 to the base station 103 is possible. As a result, uplink radio resource control (scheduling) in the base station 103 becomes possible, and high-speed control is possible compared to radio resource control by the base station control device 104, so that the communication system becomes more efficient, There is an effect that the throughput of the entire cell is improved.
In addition, since untransmitted data information is transmitted directly to the base station 103 without going through the base station controller 104, high-speed and high-frequency transmission is possible, and uplink radio resource control in the base station 103 is more efficient. As a result, the throughput of the entire cell is improved.
In addition, by setting the D / C parameter in the MAC-e header of the MAC-e PDU, when there is no upper data, the MAc-e PDU format length can be shortened, and the communication overhead can be shortened. .

In the second embodiment, report information areas (D _{1 to} D _N ) are on the MAC-e header. Since the base station 103 can recognize the presence of control information such as report information (TRbuffer) at the start of reception based on the D / C parameter, the report information area (D _{1 to} D _N ) is defined in the format of the MAC-e SDU. It is also possible to arrange them later. In this case, it is not necessary to set the padding.

  Similarly to the first embodiment, DCH related information such as data amount information (DCH LOGbuffer) from the radio link control unit 202 may also be transmitted as report information (TRbuffer). In this case, since the base station 103 can also grasp the transmission status such as the amount of DCH transmission data, the amount of interference due to DCH can be taken into account when scheduling E-DCH in the base station 103. When combined with the control of both low-speed channels (DCH and E-DCH) in the station controller 104, more efficient communication system control is possible.

Embodiment 3 FIG.
The configuration on the mobile station and base station side according to the third embodiment is the same as that of the first embodiment.
FIG. 17 is a diagram illustrating a MAC-e PDU format according to the third embodiment. Also in Embodiment 3, the report information (TRbuffer) is multiplexed on the MAC-e header.
In the figure, EF is a flag indicating that a set of parameters from Queue ID to N before EF is repeated after EF. Other parameters are the same as in the first and second embodiments.
In the second embodiment, the base station 103 is notified of the data amount for each retransmission buffer indicated by QueueID _{1 to} QueueID _M together with the data amount for each logical channel.
As shown in the figure, for each retransmission buffer, the data amount information and the MAC-e SDU are multiplexed by multiplexing the data amount information and the transmitted MAC-e SDU data information (SID, N, F) in the header. There is no need to provide a separate buffer ID for the data.
Also, by placing a plurality of buffer IDs, it is possible to multiplex retransmission buffers with different priorities to the same MAC-e PDU and transmit them at the same time, so that transmission is efficiently performed when the data amount of each buffer is small. It becomes possible.

As described above, according to Embodiment 3, untransmitted data information of mobile station 102 is multiplexed as report information (TRbuffer) in the MAC-e header of the MAC-e PDU and transmitted to base station 103. Therefore, high-speed notification of untransmitted data amount information from the mobile station 102 to the base station 103 is possible. As a result, uplink radio resource control (scheduling) in the base station 103 becomes possible, and high-speed control is possible compared to radio resource control by the base station control device 104, so that the communication system becomes more efficient, There is an effect that the throughput of the entire cell is improved.
In addition, since untransmitted data information is transmitted directly to the base station 103 without going through the base station controller 104, high-speed and high-frequency transmission is possible, and uplink radio resource control in the base station 103 is more efficient. As a result, the throughput of the entire cell is improved.

  In addition, since report information for each retransmission buffer is transmitted from the mobile station 102, scheduling in consideration of the priority of untransmitted data of each mobile station 102 is possible in the base station 103, and more efficient radio resources are available. Management becomes possible. Also, since the report information for logical channels with the same priority is stored in the same retransmission buffer, the number of bits required for the report information can be reduced by setting the data amount information for each retransmission buffer, and the amount of uplink interference can be reduced. Can be reduced.

  In the third embodiment, report information for each retransmission buffer for E-DCH is transmitted. However, data amount information (DCH LOGbuffer) from the radio link control unit 202 may also be transmitted as report information. In this case, the format as in Embodiment 1 or 2 may be set as a part of the MAC-e PDU. Thereby, since the base station 103 can also grasp the amount of DCH transmission data, the base station controller 104 can take into account the amount of interference due to the DCH when scheduling the E-DCH in the base station 103. When combined with the control of both low-speed channels (DCH and E-DCH), more efficient communication system control is possible.

Embodiment 4 FIG.
The configuration on the mobile station and base station side according to the fourth embodiment is the same as that of the first embodiment.
FIG. 18 is a diagram illustrating a MAC-e PDU format according to the fourth embodiment. In the figure, (a) shows the format of the MAC-e PDU, and (b) shows an example of the definition of the parameter PDU type. The format of the MAC-e PDU according to the fourth embodiment is a dedicated format for MAC-e communication for transmitting control information such as report information (TRbuffer). This format can also be used for notification of control information from the base station 103 to the mobile station 102, and can be used not only for data amount information reporting but also for general purposes.
The PDU type is a parameter for distinguishing the format (type) of the MAC-e PDU. Other parameters are the same as those in the first embodiment. As shown in FIG. 16 of the second embodiment, the D / C parameter is set to a value indicating control information.
Note that the MAC-e PDU format according to Embodiment 4 is similar to the STATUS PDU, which is one of the RLC PDU formats in the conventional standard.

As shown in FIG. 4B, in the fourth embodiment, 3 bits are used in the PDU type area.
PDU type = 000 represents a case where the MAC-e PDU includes status information (STATUS) of the mobile station 102 that is directly notified from the mobile station 102 to the base station 103 in addition to the report information (TRbuffer). For example, when data is transmitted to an external network from an external device (TE: Terminal Equipment) connected to the mobile station 102, the external device (TE) is used to perform transmission control (so-called flow control) from the mobile station 102. For example, the mobile station 102 collects the state information and notifies the base station 103 of the state information.
PDU type = 001 is used when the state information of the transmission source is set to the initial state at the reception destination. In this case, the format can be used for notification from the base station 103 to the mobile station 102 as well as from the mobile station 102 to the base station 103. The notification method from the base station 103 to the mobile station 102 replaces the operations of the base station 103 and the mobile station 102, and a description thereof will be omitted.
PDU type = 010 is used when notifying that the reset has been completed (RESET ACK) in response to the reset request notification. Also in this case, the format can be used for notification from the base station 103 to the mobile station 102 in addition to the mobile station 102 to the base station 103.
PDU type = 011 is used when transmitting state information (MAC-e STATUS) of the mobile station 102. In this case, the mobile station 102 notifies the base station 103. The other PDU type value indicates that it is not used (Reserve), for example, in a release in which E-DCH is introduced.
Note that the MAC-e PDU according to the fourth embodiment is transmitted with priority over the MAC-e PDU according to the first to third embodiments.

As described above, according to Embodiment 4, untransmitted data information of mobile station 102 is multiplexed as report information (TRbuffer) in the MAC-e header of MAC-e PDU and transmitted to base station 103. Therefore, high-speed notification of untransmitted data amount information from the mobile station 102 to the base station 103 is possible. As a result, uplink radio resource control (scheduling) in the base station 103 becomes possible, and high-speed control is possible compared to radio resource control by the base station control device 104, so that the communication system becomes more efficient, There is an effect that the throughput of the entire cell is improved.
In addition, since untransmitted data information is transmitted directly to the base station 103 without going through the base station controller 104, high-speed and high-frequency transmission is possible, and uplink radio resource control in the base station 103 is more efficient. As a result, the throughput of the entire cell is improved.
Also, by using the PDU type parameter, it is possible to notify not only the report information (TRbuffer) of the mobile station 102 but also various state information and control information of the mobile station 102, so that more efficient uplink There is an effect that control becomes possible.

Further, the MAC-e PDU format according to the fourth embodiment is the same format as the STATUS PDU which is one of the RLC PDU formats in the conventional standard. Need not be specified separately. For this reason, since the PDU generation processing circuit and the like can be shared, there is an effect that the configuration of the mobile station apparatus is simplified.
Further, according to the fourth embodiment, information (STATUS, RESET, RESET ACK) used in radio link control section 202 can be notified to base station 103 in addition to base station control apparatus 104. As a result, the information used by the base station control device 104 can be used for radio resource control at the base station 103, so that more effective scheduling can be achieved.

In the fourth embodiment, a dedicated format for control information is defined. However, by defining a value indicating data information in the D / C parameter, it is also possible to transmit data (MAC-e SDU) instead of report information (D _{1 to} D _N ) in the same format. is there.
In Embodiment 4, the report information (D _{1 to} D _N ) and other mobile station state information are distinguished by PDU type, but other distinctions may be set.

Embodiment 5 FIG.
The configuration on the mobile station and base station side according to the fifth embodiment is the same as that of the first embodiment.
FIG. 19 is a diagram illustrating a MAC-e PDU format according to the fifth embodiment. In the figure, (a) shows the format of the MAC-e PDU, and (b) shows the format of the piggyback PDU. In the fifth embodiment, a piggyback PDU is added to the last part of the MAC-e PDU in addition to the padding (opt).
In FIG. 5B, R2 is a substitute for the D / C parameter in the MAC-e PDU, and is not used in the fifth embodiment. Other parameters are the same as those in the fourth embodiment.

When the report information column is added to the data (MAC-eSDU) for transmission, the D / C parameter of the MAC-e PDU is set to “with control information” as shown in FIG. 16 of the second embodiment. To do. At the same time, 011 is used for the PDU type parameter as shown in FIG. 18 of the fourth embodiment, and the base station 103 determines that the piggyback PDU is invalid when receiving another value of the MAC-e PDU. And dismiss it.
Note that the MAC-e PDU added with the piggyback PDU according to the fifth embodiment is transmitted with priority over the MAC-e PDU that transmits only data. At this time, transmission may be performed without MAC-e SDU.

As described above, according to Embodiment 5, untransmitted data information of mobile station 102 is multiplexed as report information (TRbuffer) on the MAC-e header of MAC-e PDU and transmitted to base station 103. Therefore, high-speed notification of untransmitted data amount information from the mobile station 102 to the base station 103 is possible. As a result, uplink radio resource control (scheduling) in the base station 103 becomes possible, and high-speed control is possible compared to radio resource control by the base station control device 104, so that the communication system becomes more efficient, There is an effect that the throughput of the entire cell is improved.
In addition, since untransmitted data information is transmitted directly to the base station 103 without going through the base station controller 104, high-speed and high-frequency transmission is possible, and uplink radio resource control in the base station 103 is more efficient. As a result, the throughput of the entire cell is improved.

In addition, since report information can be transmitted in a dedicated format as required, there is an effect that transmission setting different from upper layer data transmission can be performed. In addition, since a format dedicated to mobile station state information is defined, there is no need to define a plurality of formats as MAC-e PDU, and there is an effect that processing of the mobile station 102 and the base station 103 is simplified.
Further, according to the fifth embodiment, information (STATUS, RESET, RESET ACK) used in radio link control section 202 can be diverted to notify base station 103 in addition to base station control apparatus 104. . As a result, these pieces of information can also be used for radio resource control in the base station 103, so that more effective scheduling is possible.

  Further, the MAC-e PDU format according to the fifth embodiment is similar to the piggyback PDU, which is one of the RLC PDU formats in the conventional standard, and therefore the formats of the radio link control unit 202 and the media access control unit 203 Need not be specified separately. For this reason, since the processing circuit can be shared in mounting the mobile station 102, there is an effect that the structure of the mobile station apparatus is simplified.

In the fifth embodiment, PDU type = 011 is set. However, the selection of the setting is arbitrary, and the specification of the standard is not limited to this embodiment.
In Embodiment 5, data information for each logical channel is used as report information. However, data information for each logical channel priority, data information for each retransmission buffer, status information of other mobile stations, and the like are reported information. It may be used as

  Each format of the STATUS PDU according to the fourth embodiment and the piggyback PDU according to the fifth embodiment is not only a report from the mobile station 102 to the base station 103 but also a notification of a scheduling result from the base station 103 to the mobile station 102. Can also be used. In this case, instead of the report information notification column, a column for describing the designated transmission time, the maximum transmittable speed, and the like is provided, and various mobile station transmission controls as described in Non-Patent Documents 1 and 2, etc. You can put information.

  In Embodiments 4 and 5, it is assumed that data information corresponding to E-DCH is measured by the MAC-e unit 605 and multiplexed as a part of the MAC-e header. Similarly to the standard traffic volume measurement function, when measurement is performed in the MAC-d unit, it can be multiplexed as a part of the header of the MAC-d PDU. In that case, as shown in FIG. 20, the control information multiplexing unit 610 is mounted on the MAC-d unit 603.

  FIG. 21 is a diagram illustrating a flow of setting conditions for measuring or reporting report information (TRbuffer) exchanged between the mobile station 102, the base station 103, and the base station controller 104 according to the first to fifth embodiments. It is. These exchanges are performed separately from the actual data transmission prior to the actual data transmission of the communication service or when the communication service setting is changed during the transmission.

First, a condition setting request command (EDCH Parameter Setup Request) is transmitted from base station 103 to base station control apparatus 104 (step ST901).
The parameters notified at this time include, for example, a measurement timing cycle and a report timing condition (a distinction between Periodic and Event trigger, a report threshold, etc.). At this time, when a restriction is provided on the DCH in accordance with the E-DCH setting, various setting conditions related to the DCH may be transmitted together.
In the base station 103, a condition setting request is generated by the MAC-e unit 1220 and is output as control information (MACcont) from the media access control unit 1203 of the base station 103 to the radio resource control unit 1206 of the base station control apparatus 104. The exchange of various information between the base station 103 and the base station control device 104 is called NBAP signaling (NBAP signaling) and is defined in the standard TS25.433. The NBAP signaling information is transmitted by wired communication such as a coaxial cable.

Next, base station controller 104 notifies mobile station 102 of a report condition setting request (EDCH Parameter Setup Request) (step ST902).
The exchange of various setting information between the base station 103 and the mobile station 102 is called RRC signaling (RRC signaling) and is defined in the standard TS25.331.
The operation on the base station side in step ST902 will be described.
First, the setting request is output from the radio resource control unit 1206 to the radio link control unit 1202 as control information (RLCcont). Next, the radio link control unit 1202 outputs the DCCH data to the MAC-d unit 1221.
Next, it becomes DCH data in the MAC-d unit 1221 and is output to the physical layer control unit 1204. Next, the physical layer control unit 1204 generates DPDCH (DCH) data, which is wirelessly transmitted from the antenna 1205 to the mobile station 102.
The operation of mobile station 102 in step ST902 will be described.
The mobile station 102 receives a radio signal via the antenna 205, undergoes demodulation / separation processing in the physical layer control unit 204, becomes DCCH data in the reception system MAC-d unit 602, and receives the reception buffer of the radio link control unit 202. It is output to 501b. Next, the data is output from the reception buffer 501 b to the radio resource control unit 206 via the RLC control unit 503.

Next, the mobile station 102 performs an operation setting (Configuration or Reconfiguration) based on the setting information, and notifies the base station controller 104 of the setting completion after the setting is completed (Step ST903).
The operation of mobile station 102 in step ST903 will be described.
The radio resource control unit 206 stores the requested setting information in the MAC control unit 607 as control information (MACcont). At the same time, an instruction is issued to the MAC-e unit 605 in the media access control unit 203 to perform operation setting.
When the MAC control unit 607 recognizes that the operation setting has been completed, the MAC control unit 607 notifies the radio resource control unit 206 of the fact as control information (MACcont).
Next, the radio resource control unit 206 of the mobile station 102 transmits completion information (Setup Complete) indicating that the setting information is reflected in the mobile station 102 to the base station control device via the base station 103 by RRC signaling. 104 is notified.
The other detailed operations are the reverse operations of step ST902, and will not be described here.

Next, base station control apparatus 104 notifies completion information (Setup Complete) indicating that the setting information is reflected in mobile station 102 to base station 103 by NBAP signaling (step ST904). The detailed operation is the reverse of step ST901 and will not be described.
Completion information indicating that it has been reflected in the mobile station 102 is notified from the radio resource control unit 1206 of the base station control apparatus 104 to the radio link control unit 1202 and the media access control unit 1203.
Next, the media access control unit 1203 of the base station 103 notifies the base station control apparatus 104 of information (ACK) indicating that the base station 103 has confirmed the completion of setting in the mobile station 102 by NBAP signaling ( Step ST905).
The detailed operation is the same as step ST901, and thus the description thereof is omitted.

In the prior art, RRC signaling is transmitted / received using DCCH and DCH. However, when communication using E-DCH is already performed, it may be performed using E-DCH.
Further, when a condition setting request is notified from the base station controller 104 to the mobile station 102, for example, a CMAC-Measure-REQ command, which is a parameter setting command defined in the conventional standard, is extended and used, and an E-DCH reporting condition is set. You may make it add the parameter only for a setting separately.
In that case, by adding a standard version display parameter (or flag) to the CMAC-Measure-REQ command, the backward compatibility and expandability of the command are ensured.
In addition, there is an effect that the configuration of the apparatus can be simplified by using the same command as that of the conventional standard.
In the flow shown in FIG. 21, the exchange between the mobile station 102 and the base station controller 104 and the exchange between the base station 103 and the base station controller 104 can be performed independently.

Embodiment 6 FIG.
FIG. 22 is a diagram showing a STATUS PDU transmission flow exchanged between the base station control apparatus 104 and the radio link control unit of the mobile station 102 according to the sixth embodiment.
A STATUS PDU used between radio link controllers (RLCs) of the conventional standard is transmitted from the side (Receiver) that receives data (RLC PDU), that is, the base station side in the uplink. In the sixth embodiment, the state of the mobile station (Sender) is notified to the base station (Receiver) by transmitting the data (Sender), that is, the mobile station.

Report information (TRbuffer) from the MAC-e unit 605 is notified from the media access control unit 203 to the radio link control unit 202 by control information (MACcont, RLCcont), and the base station as communication information data between the radio link control units 202 Notification is made to the base station 103 via the control device 104.
The detailed transmission / reception operation is the same as that of the flow shown in FIG. 21 except that the process via the radio resource control unit (RRC) is omitted, and thus the description thereof is omitted.

FIG. 23 is a block diagram showing a configuration of media access control section 203 of the mobile station according to the sixth embodiment. The difference from the media access control unit 203 of the mobile station 102 of Embodiment 1 is that report information (TRbuffer) is also output from the MAC-e unit 605 to the MAC control unit 607.
The report information (TRbuffer) input to the MAC control unit 607 is output from the MAC control unit 607 to the radio resource control unit 206 as control information (MACcont) and further transferred to the radio link control unit 202. Next, the radio link control unit 202 becomes DCCH data, and is notified from the mobile station 102 to the base station controller 104 via the base station 103. The radio link control unit 1202 of the base station control device 104 decodes the STATUS PDU and notifies the base station 103 by NBAP signaling. The method of NBAP signaling is not particularly limited. The details of the transmission method from the mobile station 102 to the base station 103 are the same as those in the flow shown in FIG.

  In the sixth embodiment, report information (TRbuffer) can be divided into two types. For example, one can be transmitted and received via a radio link control unit at a long time interval, and one can be performed in a short cycle by MAC-e PDU. Alternatively, one can also perform the absolute value of the report information (TRbuffer) via the radio link control unit, and one can increase / decrease (Up / Down) information by MAC-e PDU in a short cycle. Note that what kind of information the report information (TRbuffer) is divided into is not limited to this embodiment. In addition, when reporting information (TRbuffer) is communicated to the base station 103 by communication between radio link control units, STATUS PDU or piggyback PDU may be used.

Moreover, when transferring to the base station control apparatus 104 via the base station 103, the content may be decoded uniquely in the base station 103.
As described above, the mobile station 102 temporarily transfers the data to the radio link control unit and notifies the base station 103 of the absolute value of the report information (TRbuffer) by communication between the radio link control units. Since the values of the report information of the base station 103 can be synchronized, a packet transmission error due to a setting difference can be avoided. Moreover, since only the increase / decrease is transmitted by the MAC-e PDU, the length of the MAC-e PDU can be shortened, so that the overhead can be reduced.

Further, since packet data is generated in bursts and the amount of data received by the base station 103 can be grasped, the transmission frequency can be reduced by transmitting report information only when bursts occur. Thereby, it is possible to suppress the occurrence of uplink interference, and resources can be passed to other mobile stations 102.
In addition, since it is not necessary to frequently notify the absolute value having a large number of bits by the MAC-e PDU, the overhead of the MAC-e PDU is reduced, and the occurrence of uplink interference can be reduced.

  As described above, the mobile station according to the present invention is suitable for directly and rapidly notifying the base station of transmission data information of the mobile station necessary for uplink radio resource control in the base station.

  DESCRIPTION OF SYMBOLS 101 Communication system, 102 Mobile station, 103 Base station 103, 104 Base station control apparatus, 105 Communication network, 201, 1201 Upper layer block, 202, 1202 Radio link control part, 203, 1203 Media access control part, 204, 1204 Physical Layer control unit, 205, 1205 Antenna, 206, 1206 Radio resource control unit, 501a reception buffer, 501b reception buffer, 502a transmission buffer, 502b transmission buffer, 503 RLC control unit, 504 buffer monitoring unit, 601, 1601a reception buffer, 602 Reception system MAC-d unit, 603, 1221 Transmission system MAC-d unit, 604a, 1604 Transmission buffer, 604b, 1601b E-DCH buffer, 605, 1220 MAC-e unit, 606 Amount information section, 607, 1607 MAC control section, 608 communication amount measurement section, 610 control information multiplexing section, 650 retransmission control section, 651 selector, 652 retransmission buffer, 701, 1701 reception section, 702, 1702 demodulation section, 703 , 1703 Demultiplexer, 704, 1704 Multiplexer, 705, 1705 Modulator, 706, 1706 Transmitter, 707, 1707 PHY control unit.

Claims (15)

A radio link control unit that inputs and outputs data to and from the base station via a radio channel with an upper protocol layer;
A media access control unit that inputs and outputs the data via a logical channel with the radio link control unit;
A physical layer control unit that performs input / output of the data via a transport channel with the media access control unit, and controls wireless communication with the base station;
In a mobile station including a radio resource control unit that inputs and outputs control data between the radio link control unit, the media access control unit, and the physical layer control unit,
The mobile station characterized in that the media access control unit multiplexes report information used by the base station for scheduling of uplink transmission onto a packet data transmission channel and transmits the multiplexed information to the base station. The mobile station according to claim 1, wherein report information used by the base station for scheduling of uplink transmission is arranged in a header portion of a data format transmitted by a packet data transmission channel. 2. The mobile station according to claim 1, wherein report information used by the base station for scheduling of uplink transmission is arranged at the last part of a data format transmitted by a packet data transmission channel. The mobile station according to claim 1, wherein the data format transmitted by the packet data transmission channel has an information area indicating presence / absence of report information used by the base station for scheduling of uplink transmission . The mobile station according to claim 1, wherein the data format transmitted by the packet data transmission channel has an information area indicating a type of report information used by the base station for scheduling of uplink transmission .   The mobile station according to claim 1, wherein the data format transmitted by the packet data transmission channel has an information area indicating presence / absence of packet data. The mobile station according to claim 1, wherein the data format transmitted by the packet data transmission channel is a dedicated format for transmitting report information used by the base station for scheduling of uplink transmission .   8. The mobile station according to claim 7, wherein the dedicated format is transmitted to the base station in addition to a data format transmitted by the packet data transmission channel. A retransmission control unit for the packet data transmission channel,
The mobile station according to claim 1, wherein report information used by the base station for scheduling of uplink transmission is multiplexed in a data format transmitted by a packet data transmission channel for each retransmission control cycle. The mobile station according to claim 1, wherein a part of report information used for scheduling of uplink transmission by the base station is separated and notified to the base station controller. A radio link control unit that outputs service data input from an upper protocol layer using a first logical channel and outputs control data using a second logical channel;
Based on the data output using the first logical channel and the second logical channel output from the radio link controller, the transport channel data for the service data is created, and the base station A media access control unit that multiplexes the transport channel data with report information to be referred to for scheduling uplink transmission ;
A physical layer control unit that converts the transport channel data multiplexed with an index indicating a combination of the data amount information into physical channel data for the service data, converts the data into a radio frequency signal, and transmits the radio frequency signal to the base station; Mobile station equipped. A radio link control unit for inputting / outputting data to / from a mobile station via a radio channel with an upper protocol layer;
A media access control unit that inputs and outputs the data via a logical channel with the radio link control unit;
A physical layer control unit that inputs and outputs the data via a transport channel with the media access control unit and controls wireless communication with the mobile station;
In a base station having a radio resource control unit that inputs and outputs control data between the radio link control unit, the media access control unit, and the physical layer control unit,
The media access control unit performs radio resource allocation using report information that is multiplexed on data transmitted from the mobile station through a packet data transmission channel and used by the base station for scheduling of uplink transmission. Base station characterized by A radio link control unit that inputs / outputs data to / from a higher protocol layer via a radio channel, and a medium that inputs / outputs the data via a logical channel between the radio link control unit and the radio link control unit Between the access control unit and the media access control unit, the physical layer control unit that inputs and outputs the data via the transport channel and controls the radio communication, the radio link control unit, and the media access control In a communication system including a mobile station and a base station having a radio resource control unit that inputs and outputs control data between the unit and the physical layer control unit,
The mobile station multiplexes the report information used by the base station for scheduling of uplink transmission to the packet data transmission channel and transmits the packet information to the base station,
The base station communication system which has received from the upper Symbol mobile station, the base station that perform radio resource allocation using the report information used for scheduling uplink transmission characterized. A radio link control unit that inputs / outputs data to / from the base station via a radio channel with a higher protocol layer, and a data channel input / output between the radio link control unit and the radio link control unit. A media access control unit for performing
A physical layer control unit that performs input / output of the data to / from the media access control unit via a transport channel and controls radio communication with the base station, the radio link control unit, and the media access control unit And a mobile station equipped with a radio resource control unit for inputting / outputting control data to / from the physical layer control unit multiplexes report information used by the base station for uplink transmission scheduling on a packet data transmission channel. To the base station,
Base station has received from the upper Symbol mobile station, a communication method in which a base station and performs radio resource allocation using the report information used for scheduling uplink transmission. A radio link control unit that inputs and outputs data to and from the base station via a radio channel with an upper protocol layer;
A media access control unit that inputs and outputs the data via a logical channel with the radio link control unit;
A physical layer control unit that performs input / output of the data via a transport channel with the media access control unit, and controls wireless communication with the base station;
In a mobile station including a radio resource control unit that inputs and outputs control data between the radio link control unit, the media access control unit, and the physical layer control unit,
The media access control unit multiplexes data amount information for a base station into a packet data transmission channel and transmits the packet data transmission channel to the base station.

Images