JP2006081217A - Base station, terminal, and communications system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communications system for transmitting incoming and outgoing packet transmissions in a coexistence manner, as much as possible to the extent that does not exceed the limit of the transmission power of a terminal. <P>SOLUTION: In the communications system, in which outgoing packet transmission from a base station to a terminal and incoming packet transmission from the terminal to the base station can occur simultaneously, the base station determines the transmission timing and notifies the terminal so that the transmission timing of a outgoing packet response signal transmitted from the terminal to the base station in response to the outgoing packet transmission from the base station and the transmission timing of the incoming packet data transmitted from the terminal to the base station do not overlap each other, and the terminal carries out transmission in accordance with the notified transmission timing. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a base station, a terminal, a communication system, and a communication method in wireless packet communication.

In a W-CDMA (Wideband CDMA) system that is an example of a CDMA (Code Division Multiple Access) system, a shared channel is used in packet communication between a base station and a terminal.
There are two types of shared channels: those related to downlink packet communication when packet data is transmitted from the base station to the terminal, and those related to uplink packet communication when packet data is transmitted from the terminal to the base station. The former includes a channel used when transmitting packet data from the base station to the terminal, a channel used when transmitting ACK / NACK signals from the terminal to the base station in response thereto, and the like. The latter includes a channel used when transmitting packet data from the terminal to the base station, a channel used when transmitting ACK / NACK signals from the base station to the terminal in response thereto, and the like.

  The HSDPA (High Speed Downlink Packet Access) method is known as a method for realizing high speed downlink packet communication using a shared channel. This method employs an adaptive modulation method in which the base station selects the optimal modulation method and coding rate according to the current propagation state, thereby enabling efficient high-speed packet transmission. ing. In order to select an optimal modulation scheme and coding rate, quality information CQI (Channel Quality Indicator) indicating the current propagation state is periodically transmitted from the terminal to the base station, and the base station determines the optimum based on the quality information CQI (Channel Quality Indicator). Determine the modulation scheme and coding rate.

  Communication using the shared channel is realized by assigning slots to a plurality of terminals in a time division manner. In the HSDPA system, allocation of shared channel slots to terminals, that is, scheduling of downlink packet communication is performed on the base station side. In downlink packet communication, since the presence or absence of transmission data from the base station to each terminal is known on the base station side, scheduling can be performed on the base station side.

  Practical use of a method for realizing high-speed uplink packet communication using a shared channel is also in progress. In the case of uplink packet communication, the base station cannot know the presence / absence of transmission data from each terminal to the base station without receiving a notification from the terminal. Therefore, the allocation of the shared channel slot to each terminal, that is, the scheduling of uplink packet communication, can be performed by the base station that has received the notification from the terminal, but a method in which the terminal autonomously performs is also conceivable.

By the way, depending on the result of scheduling, transmission of a response signal using a shared channel related to downlink communication and transmission of packet data using a shared channel related to uplink communication occur simultaneously with respect to data transmission from a certain terminal to the base station. there is a possibility.
In this way, when transmissions using different channels from a certain terminal to the base station overlap, it is possible to either transmit both at the same time or select only one of them and transmit. It is done.

  As a related art related to channel assignment to a plurality of terminals, for example, there is a wireless communication system disclosed in Patent Document 1. This discloses a technique for efficiently assigning upper and lower channels in a TDMA communication system according to priority.

  Further, as a technique related to adjustment of the amount of data transmitted from a terminal, for example, there is a communication device disclosed in Patent Document 2. This discloses a technique for demodulating a Time Division Multiple Access (TDMA) signal having a variable time slot.

JP 2001-285230 A JP-A-10-093518

As described above, in the data transmission from a certain terminal to the base station, when the transmission of the ACK / NACK signal for the downlink packet data from the base station and the transmission of the uplink packet data to the base station occur at the same time, If it is transmitted, the limit of the transmission power of the terminal is temporarily exceeded, and a communication error may occur.
In order to avoid this, it is also conceivable to select only one of uplink communication and downlink communication. When uplink packet communication is selected, downlink packet communication cannot be used, and when downlink packet communication is used, uplink packet communication cannot be used. However, for example, in the case of streaming data transmitted and received when making a videophone or the like, it is not desirable that one of them be unavailable, and it is better to realize simultaneous transmission as much as possible.

  That is, it is necessary to avoid transmitting data in the same time slot for data that causes the transmission power of the terminal to exceed when transmitted at the same time by means of scheduling and frame structure.

In the above-mentioned Patent Document 1, a technique for allocating a time slot of one channel to a plurality of terminals based on priority in each of the upper and lower communications is described, but it is not a technique for solving the above-described problem.
Further, in the above-mentioned Patent Document 2, a data communication technique using a variable frame is disclosed. However, this technique uses a variable frame in response to a change in the amount of data, and a technique for solving the above-described problems. is not.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain a base station, a terminal, a communication system, and a communication method that enable communication considering the limit of transmission power of the terminal. .

  The communication system according to the present invention is a communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously, and the terminal responds to the downlink packet communication from the base station. The base station determines the transmission timing and notifies the terminal so that the transmission timing of the downlink packet response signal transmitted to the base station does not overlap with the transmission timing of the uplink packet data transmitted from the terminal to the base station. Transmission to the base station is performed according to the notified transmission timing.

  The communication system according to the present invention is a communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously, and the terminal responds to the downlink packet communication from the base station. When the transmission timing of the downlink packet response signal transmitted to the base station and the transmission timing of the uplink packet data transmitted from the terminal to the base station overlap, the duplication of the transmission timing of the uplink packet data and the downlink packet response signal is avoided. The terminal adjusts the transmission frame length of the uplink packet data, the terminal notifies the determined transmission frame length to the base station, and transmits the uplink packet data.

  According to the present invention, it is possible to realize simultaneous use of uplink packet communication and downlink packet communication even when uplink communication and downlink communication coexist and the terminal has a transmission power limit.

Hereinafter, various embodiments of the present invention will be described.
Embodiment 1 FIG.
1 is a diagram showing a configuration and a channel configuration of a packet communication system according to Embodiment 1 of the present invention. Here, a channel configuration between the base station 101 and the terminal 100 in the W-CDMA system will be described as an example. The channel name is a temporary name and may be changed in the future. In addition, as an actual channel usage, there is a possibility that a plurality of control channels are carried on one channel. In the W-CDMA system, the terminal 100 may be referred to as a UE (User Equipment) and the base station 101 may be referred to as a Node-B.
The base station 101 is controlled by a base station controller 10 (SRNC: Serving Radio Network Controller). Information on the terminal 100 is registered in the base station control device 10.

A downlink channel used when data is transmitted from the base station 101 to the terminal 100 will be described. CPICH 102 (Common Pilot Channel) is used for transmission of a pilot signal that is commonly transmitted to all terminals in the cell. This pilot signal becomes a reference for all timings in the intra-cell communication.
As downlink channels used during downlink packet communication, HS-SCCH 105 (HiSpeed Shared Control Channel) used for transmitting packet control information, HS-DSCH 106 (HiSpeed Downlink Shared Channel) used for transmitting downlink packet data There is. These are shared channels that are commonly used by terminals in a cell.
Further, as a downlink shared channel used in uplink packet communication, DL-SACCH 108 (Downlink Scheduling Assignment Control Channel) used for notification of an allocation position (transmission time) by a scheduler for transmission of control information, a base station There is a DL-ACK / NACK-CCH 111 (Downlink ACK / NACK Control Channel) for notifying the terminal 100 of success / failure of reception of uplink packet data at 101.

Next, an uplink channel from terminal 100 to base station 101 will be described. As an uplink shared channel used during downlink packet communication, there is an HS-DPCCH 104 (HiSpeed Dedicated Physical Control Channel) for control signal transmission. This transmits quality information CQI (Channel Quality Indicator) to be reported to the base station 101 based on the propagation situation of the downlink and ACK / NACK which is a response to whether or not the downlink packet has been correctly received.
Also, as an uplink shared channel used during uplink packet communication, UL-SICCH 107 (Uplink Scheduling Information Control Channel) used to notify the presence / absence of transmission data of terminal 100, the modulation scheme selected by terminal 100 UL-TFRI-CCH 109 (Uplink TFRI Control Channel) used for notifying the base station 101 of the encoding rate, etc., and EUTCHCH 110 (Enhanced Updated Transport Channel) used for transmitting the upstream packet data body. is there.

  Here, TFRI (Transport Format and Resource Indicator) is information for notifying a combination of a modulation scheme, a coding rate, and the like. In adaptive modulation, it is necessary to know at the time of reception the combination of the modulation method, coding rate, etc. determined at the time of transmission, but this information makes it possible.

  Further, DPCH 103 (Dedicated Physical Channel), which is a channel individually set for communication with a specific terminal, is set for each uplink and downlink in the HSDPA communication state, and for voice and data communication and higher layer signaling. Used for

  The configuration of the transmission frame of each channel in the first embodiment will be described. One frame is composed of 15 slots, and 3 slots are used in one transmission, and these 3 slots are called subframes. That is, 5 subframes are arranged in one frame.

FIG. 2 is a block diagram showing a configuration of base station 101 according to the first embodiment.
The CDMA modulation / demodulation process will be described with reference to FIG. This is a part that performs the same processing in other embodiments, and is a general operation of communication by the CDMA system.
A description will be given starting from the part related to the processing during downlink packet communication to the terminal. In the modulation unit 201, the channel signal is multiplied by the channelization code generated by the downlink channelization code generator 202, and then the signal of each channel is multiplexed. Further, the multiplexed signal is multiplied by the scrambling code generated by the downlink scrambling code generator 203 to perform spread spectrum processing. The frequency of the multiplexed baseband signal obtained in this way is raised to the carrier frequency in the frequency converter 204. Thereafter, the power amplification unit 205 amplifies the signal to a desired power by a power amplifier and transmits the amplified signal through the antenna 206.
When receiving uplink data from the terminal, a weak signal received via the antenna 206 is amplified by the low noise amplification unit 207 and lowered to the frequency of the baseband signal by the frequency conversion unit 208. After being lowered to the baseband signal, it is input to the demodulator 211, multiplied by the scrambling code generated by the uplink scrambling code generator 210, despreaded, and generated by the uplink channelization code generator 209. Use channelization codes to separate each channel. In this way, code-divided channels can be separated.

Next, processing during downlink packet communication will be described.
Transmission data buffer 215 for downlink packet communication holds transmission data for each terminal acquired from the network. Also, the quality information (CQI) transmitted from the terminal using the HS-DPCCH 104 is decoded by the decoding unit 212, and the quality information receiving unit 214 acquires the current propagation state of the terminal from there. These data and quality information are supplied to the downlink packet communication scheduler 216 (scheduling unit).

  The downlink packet communication scheduler 216 acquires the downlink communication channel scheduling from the timing management unit 226, that is, the slot allocation status to each terminal, and the presence / absence of transmission data to each terminal and the propagation information obtained from the quality information The packet transmission timing (second transmission schedule) is determined by comprehensively judging the state. When the packet transmission timing is determined, the downlink packet communication control information transmitter 217 transmits information necessary for each terminal to demodulate the downlink data through the modulator 201 using the HS-SCCH 105. Further, the downlink packet communication data transmission unit 218 transmits the downlink data body through the modulation unit 201 using the HS-DSCH 106.

  When the transmitted packet is correctly received by the terminal 100, an ACK / NACK is transmitted from the terminal 100 using the HS-DPCCH 104, and is input to the response signal determination unit 213 through the demodulation unit 211. The response signal determination unit 213 determines the signal, and the determination result is passed to the downlink packet communication scheduler 216. When it is determined as ACK, transmission of the next packet is scheduled, and when it is determined as NACK, retransmission processing is performed. In downstream packet communication, the above series of flows is repeated.

  Next, data processing during uplink packet communication will be described. The transmission data amount transmitted from the terminal 100 to the base station 101 using the UL-SICCH 107 is supplied to the transmission buffer amount reception unit 219 through the demodulation unit 211, so that there is data to be transmitted in the terminal 100. Is notified to the scheduler (scheduling unit) 223 for uplink packet communication. Also, the uplink channel quality information receiving unit (not shown) notifies the uplink packet communication scheduler 223 of the current uplink channel propagation state.

  The uplink packet communication scheduler 223 acquires the uplink communication channel scheduling from the timing management unit 226, that is, the slot allocation status to each terminal, and the presence / absence of transmission data to each terminal and the propagation information obtained from the quality information A packet transmission timing (first transmission schedule) is determined by comprehensively judging the state. When the packet transmission timing is determined, subframe allocation information creation section 224 places the subframe allocation information on DL-SACCH 108 and transmits it to terminal 100 through modulation section 201.

  Thereafter, TFRI information transmitted from the terminal 100 using the UL-TFRI-CCH 109 at the designated subframe position (transmission time) is supplied to the TFRI receiver 220 through the demodulator 211. Parameters necessary for demodulation of uplink packet data notified to the TFRI receiving unit 220 are supplied to the demodulating unit 211 and the decoding unit 221. Following the TFRI, the data body transmitted from the terminal 100 using the EUDTCH 110 is supplied to the decoding unit 221 through the demodulation unit 211 and decoded. When the packet from the terminal 100 can be received correctly, the response signal generator 222 generates an ACK / NACK signal and notifies the terminal 100 using the DL-ACK / NACK-CCH 111. In upstream packet communication, the above series of flows is repeated.

FIG. 3 is a block diagram showing a configuration of terminal 100 according to the first embodiment.
First, CDMA modulation / demodulation processing will be described. This part is the same part in other embodiments, and is a general process of a terminal that performs communication by the CDMA system.
The processing related to uplink packet communication to the base station will be described. The modulation unit 301 multiplies the signal of each channel by applying the channelization code generated by the channelization code generator 302 later. The multiplexed signal is multiplied by the scrambling code generated by the scrambling code generator 303 to perform spread spectrum processing. The multiplexed baseband signal is raised to the carrier frequency in the frequency converter 304. Thereafter, the power amplifying unit 305 inputs a signal to the power amplifier, amplifies it to a desired power, and transmits it via the antenna 306.
At the time of receiving data and signals from the base station 101, a weak signal received via the antenna 306 is amplified by the low noise amplification unit 307 and lowered to the frequency of the baseband signal by the frequency conversion unit 308. The baseband signal is input to the demodulation unit 311. In the demodulator 311, the baseband signal is multiplied by the scrambling code generated by the scrambling code generator 310 to perform the despreading process, and the signal is further generated using the channelization code generated by the channelization code generator 309. Separate into each channel. Thus, the code-divided channels can be separated.

Next, a configuration related to data processing during downlink packet communication will be described. The reference timing notified from the base station 101 using the CPICH 102 is supplied to the timing management unit 318 through the demodulation unit 311. A timing management unit (transmission control unit) 318 supplies a timing signal serving as a reference for processing timing to each processing unit. In particular, the uplink packet data transmission timing signal is output to the EUDTCH transmission processing unit 322 based on the schedule information (DL-SACCH timing information) received from the base station, and the HS-DPCCH transmission is performed based on the HS-SCCH timing signal. The transmission timing signal for the downlink packet response signal is output to the processing unit 317. The transmission timing signal output from the HS-DPCCH transmission processing unit 317 is generated based on a criterion that a preset time has elapsed from the transmission timing of HS-SCCH or HS-DSCH.
Further, the reference timing is also notified to the propagation quality estimation unit 315 and used for estimating the propagation state of the downlink channel. A quality information signal generation unit 316 generates a CQI value based on the propagation state estimated by the propagation quality estimation unit 315, supplies the CQI value to the HS-DPCCH transmission processing unit 317, and transmits it to the base station 101 using the HS-DPCCH 104. Is done.

  When the packet data transmitted from the base station 101 is received by the terminal 100, the packet control signal transmitted using the HS-SCCH 105 is supplied to the decoder 312 through the demodulator 311 and subjected to decoding processing. . By decoding the control signal by the decoder 312, a demodulation parameter of packet data transmitted from the base station 101 using the HS-DSCH 106 is obtained. Demodulation parameters are supplied to the demodulator 311 and the decoder 313. Packet data transmitted from the base station 101 using the HS-SCCH 105 is supplied to the decoder 313 through the demodulator 311. If the packet is correctly received, the response signal generation unit 314 generates an ACK signal. If an error occurs, a NACK signal is generated. The generated ACK / NACK signal is placed in a predetermined slot in the HS-DPCCH transmission processing unit 317 and notified to the base station 101 using the HS-DPCCH 104. At the time of downlink packet communication, this series of processing is repeated.

Next, a configuration related to data processing during uplink packet communication will be described. In accordance with a user instruction, data to be transmitted via the upper layer is stored in the transmission data buffer 320 for uplink packet communication. The uplink packet communication buffer amount transmission processing unit 323 confirms the amount of transmission data stored in the uplink packet communication transmission data buffer 320, and when there is data to be transmitted, transmits to the base station 101 using the UL-SICCH 107. Notifies the amount of data in the data buffer.
When the base station 101 receives the transmission data amount and notifies the terminal 100 of transmission permission, the base station 101 notifies the allocation position on the transmission frame using the DL-SACCH 108. When the terminal 100 receives the transmission allocation position, the subframe position / transmission margin receiving unit 324 is notified of the subframe position and transmission margin allowing transmission through the demodulation unit 311. The TFRI transmission processing unit 321 determines the TFRI to be transmitted in consideration of the transmission margin and the amount of data stored in the uplink packet communication transmission data buffer 320 at the present time, and notifies the EUDTCH transmission processing unit 322 of the TFRI. The EUDTCH transmission processing unit 322 processes the data in the uplink packet communication transmission data buffer 320 according to the notified TFRI and transmits the processed data to the base station 101 using the EUDTCH 110.

  Base station 101 notifies terminal 100 of an ACK / NACK signal indicating whether or not packet data from terminal 100 has been correctly received using DL-ACK / NACK-CCH 111. When ACK / NACK is received by terminal 100, it is supplied to response signal receiving section 319 through demodulating section 311 and the result is notified to transmission data buffer 320 for uplink packet communication. When the response signal is NACK, the data is retransmitted. When the response signal is ACK, the transmitted data in the transmission data buffer 320 for uplink packet communication is deleted and the next packet is transmitted. This series of flows is repeated during upstream packet communication.

  Next, the flow of downlink packet communication will be described. The base station 101 transmits a pilot signal using the CPICH 102 to the terminal 100 existing in the cell. Further, the DPCH 103 is set in the communication state. When the base station 101 starts data transmission, information including a modulation scheme, a coding rate, and the like necessary for demodulating packet data transmitted to the terminal 100 through the HS-DSCH 106 is obtained using the HS-SCCH 105. Send. The terminal 100 receives this information and starts demodulating the packet data transmitted by the HS-DSCH 106 using the information if it is addressed to itself. Ignore it if it is not addressed to you. The terminal 100 collates the demodulated data, and transmits an ACK to the base station 101 using the HS-DPCCH 104 if there is no error, and transmits a NACK if there is an error.

  Here, FIG. 4 shows a frame configuration when data is transmitted using the HS-DPCCH 104. One frame is composed of 15 slots, and 3 slots used for one transmission are called subframes. That is, 5 subframes are arranged in one frame. Of the three slots constituting one subframe, one slot is used for ACK / NACK transmission, and two slots are used for the quality information CQI transmission described above. These two are used independently and do not necessarily transmit at the same time.

  Next, the flow of upstream packet communication will be described. In the case of downlink packet communication, in principle, scheduling is performed on the base station 101 side, and the terminal 100 transmits a packet to the base station 101 in accordance with a packet transmission period and timing designated by the base station 101. On the other hand, in the case of uplink packet communication, a plurality of scheduling methods can be considered. Here, a general method in which the base station 101 performs all scheduling is taken as an example. Note that DPCH 103 is set between base station 101 and terminal 100 even in the uplink packet communication state.

  When there is data to be transmitted, terminal 100 uses UL-SICCH 107 to notify base station 101 of the presence or absence of transmission data. The base station 101 performs scheduling based on a transmission request from each terminal and notifies each terminal of transmission permission information using the DL-SACCH 108. This information includes a subframe position for which transmission is permitted, a power margin for which transmission is permitted, and the like. The terminal 100 selects a modulation scheme, a coding rate, and the like based on the transmission permission information notified by the DL-SACCH 108 and the amount of data to be transmitted by the terminal 100, and uses the UL-TFRI-CCH 109 to the base station 101. Send. Further, immediately after that, the upstream packet data body is transmitted to the base station 101 using the EUDTCH 110. The base station 101 receives packet data transmitted using the EUDTCH 110 in accordance with the control information notified by the UL-TFRI-CCH 109. The base station 101 notifies the terminal 100 of ACK using the DL-ACK / NACK-CCH 111 when the data transmitted by the EUDTCH 110 is normally received, and notifies NACK when there is an error. .

  As described above, downlink packet communication and uplink packet communication operate independently between the base station 101 and the terminal 100. Therefore, when continuous transmission is performed from the terminal 100 to the base station 101, it is possible that each control signal related to uplink packet communication and packet data and each control signal related to downlink packet communication are transmitted overlapping each other.

  Here, the transmission power of the terminal 100 will be described with reference to FIG. In the figure, the horizontal axis indicates time, and the vertical axis indicates transmission power. In general, a portable terminal has an upper limit on the output of a power amplifier due to constraints such as battery capacity and heat generation limit. As described above, when a plurality of data and signals are simultaneously sent from the terminal, if the upper limit value of the power amplifier output is exceeded, the desired power cannot be satisfied and a communication error occurs. As shown in the figure, in general, transmission power used when transmitting an ACK / NACK signal by the HS-DPCCH 104 in response to a downlink packet communication from the base station 101, and when transmitting packet data to the base station 101 by the EUDTCH 110 The transmission power used for is large. On the other hand, the transmission power required for transmission of quality information CQI to the base station 101 and data transmission using the DPCH 103 which is a dedicated channel is not so large.

  Therefore, when data transmission by EUDTCH 110 and transmission of an ACK / NACK signal by HS-DPCCH 104 occur simultaneously, the limit value of transmission power of terminal 100 is exceeded. As a result, the power exceeding the limit value is insufficient and a communication error occurs.

  A case where the transmission power limit value of terminal 100 is exceeded will be described with reference to the time chart of FIG. In the figure, the horizontal axis represents the passage of time, and the frame structure of each channel is represented in each band. The thickness of each band represents the magnitude of the transmission power of the data signal transmitted using each channel. As described above, the uplink packet communication and the downlink packet communication are performed independently using the channel for transmitting each data body and the control channel. The timing of data transmission between channels in downlink packet communication or uplink packet communication is determined, but there is actually a slight time lag. However, since this is a shift that does not have a significant effect, it is not considered on the time chart.

As shown in the figure, regarding downlink packet communication, when control information is transmitted from the base station 101 to the terminal 100 using the HS-SCCH 105, packet data is transmitted using the HS-DSCH 106 two slots later. Is done. On the terminal 100 side, when there is no error in the packet data transmitted by the HS-DSCH 106, an ACK signal is transmitted using the HS-DPCCH 104 with a delay of about 7.5 slots from the end of the HS-DSCH 106. If there is an error, a NACK signal is similarly transmitted.
On the other hand, when looking at the uplink packet communication, the base station 101 performs scheduling based on the transmission data amount that the terminal 100 transmits from the terminal 100 using the UL-SICCH 107 in the transmission buffer, and sets the DL-SACCH 108 to The allocation position that can be transmitted is notified to the terminal 100 by using it. The terminal 100 notifies the base station 101 of the modulation scheme determined according to the notified allocation position using the UL-TFRI-CCH 109, and immediately after that, transmits the data body of the uplink packet communication using the EUDTCH 110. At this time, depending on the allocation position determined by the scheduler of the base station 101, the transmission timing of the ACK / NACK signal transmitted on the HS-DPCCH 104 and the uplink packet data transmitted on the EUDTCH 110 is as shown in FIG. There is a possibility of overlapping. When both timings overlap, the limit of the transmission power of the terminal 100 occurs as shown in FIG.

As a method for avoiding the collision of response signals for uplink packet data and downlink packet data as shown in FIG. 6, mutual adjustment of the transmission timings of both by the scheduler of the base station 101 will be described with reference to the time chart of FIG. As in FIG. 6, for downlink packet communication, control information is transmitted from the base station 101 using the HS-SCCH 105, and after 2 slots, downlink packet data is transmitted on the HS-DSCH 106, and from the end of the HS-DSCH 106. ACK or NACK is transmitted from terminal 100 to base station 101 using HS-DPCCH 104 with a delay of about 7.5 slots.
For uplink packet communication, the base station 101 determines the transmission subframe position based on the transmission data presence / absence notification using the UL-SICCH 107 from the terminal 100. At this time, the uplink packet communication scheduler 223 of the base station 101 uses a scheduling process to be described later so that the transmission timing of the ACK / NACK signal transmitted on the HS-DPCCH 104 and the uplink packet data transmitted on the EUDTCH 110 does not overlap. The transmission timing to be assigned to 100 is determined and notified to the terminal 100 using the DL-SACCH 108.
In accordance with the notified transmission timing, the terminal 100 notifies the selected TFRI to the base station 101 using the UL-TFRI-CCH 109, and immediately thereafter transmits the data body using the EUDTCH 110.
As a result, as shown in FIG. 7B, a collision between the transmission timing of the signal transmitted on the HS-DPCCH 104 and the packet data transmitted on the EUDTCH 110 is avoided.

  Next, the scheduling process in the base station 101 will be described. As shown in FIG. 2, the base station 101 includes an inter-scheduler communication circuit 225 that exchanges data between the uplink packet communication scheduler 223 and the downlink packet communication scheduler 216. By exchanging ACK / NACK signal transmission during downlink packet communication and transmission timing information of the data body during uplink packet communication via the inter-scheduler communication circuit 225, scheduling that does not cause a collision is realized.

FIG. 8 is a flowchart of the scheduling process by the scheduler of the base station 101 according to the first embodiment.
First, the operation of the downlink packet communication scheduler 216 will be described. The downlink packet communication scheduler 216 notifies the uplink packet communication scheduler of the transmission position information of the ACK / NACK signal using the HS-DPCCH 104.
First, the downlink packet communication scheduler 216 acquires the current quality information of the terminal 100 from the quality information receiving unit 214 (step ST100).
Next, the reception subframe position of the uplink data by EUDTCH 110 determined in scheduler for uplink packet communication 223 is acquired via inter-scheduler communication circuit 225 (step ST101).
Next, the downlink packet communication scheduler 216 determines control information by HS-SCCH 105 addressed to terminal 100 and a transmission subframe position of packet data by HS-DSCH 106 (step ST102).
Next, based on the downlink scheduling determined in step ST102, the reception subframe position of the ACK / NACK response signal transmitted from the terminal 100 using the HS-DPCCH 104 for the downlink communication is calculated ( Step ST103).
Next, the scheduled reception position (time) of the signal by HS-DPCCH 104 calculated in step ST103 and the number for identifying terminal 100 are notified to scheduler 223 for uplink packet communication via inter-scheduler communication circuit 225 (step ST104). ).
Next, the reception position of the signal by HS-DPCCH 104 calculated in step ST103 is notified to timing management section 226 (step ST105). According to the scheduling result notified to the timing management unit 226, the timing of the transmission / reception operation in each processing unit is controlled.
In order to realize this, it is necessary to predict the transmission timing of the terminal in each of the upper and lower schedulers existing in the base station. An example of prediction is shown.

As shown in FIG. 6, the prediction of the ACK / NACK position of downlink packet communication is as follows:
(1) Control information is transmitted from the base station 101 to the terminal 100 using the HS-SCCH 105.
(2) The time difference (τHS-PDSCH) at each head of the HS-SCCH 105 and the HS-DSCH 106 is 2 slots with respect to the HS-SCCH 105 as disclosed in FIG. 35 of the 3GPP specification TS25.211 (Ver 5.3.0). Packet data is transmitted using HS-DSCH 106 at a position delayed by minutes (5120 chips).
(3) Further, as the processing time required by the terminal 100, the time difference (τUEP) between the last part of the HS-DSCH 106 and the beginning of the HS-DPCCH 104 is disclosed in FIG. 34 of the 3GPP specification TS25.211 (Ver 5.3.0). Thus, 19200 chips are prepared. By performing this calculation using the scheduler in the base station, it is possible to predict the position at which the terminal 100 transmits ACK / NACK when the HS-SCCH 105 of the downlink packet is transmitted.

Also, prediction of packet transmission timing of the terminal 100 in uplink packet communication will be described using FIG.
(1) The base station 101 notifies the terminal 100 of allocation location information (MAP) permitted to the terminal using the DL-SACCH 108.
The DL-SACCH 108 includes information on the transmission subframe position (variable k) and the number of consecutive subframes (variable n) (hereinafter, k = 1 and n = 3 will be described as an example). ).
(2) From the time difference between DL-SACCH108 and UL-TFRI-CCH109 (tentative name τSACCH-TFRI) and subframe position (k), the position at which the terminal sends TFRI can be predicted by calculating τk × Tsubframe + τSACCH-TFRI. .
(3) Thereafter, the position at which the EUDTCH 110 is transmitted from the terminal 100 can be predicted from the time difference between the UL-TFRI-CCH 109 and the EUDTCH 110 (tentative name τTFRI-EUDTCH).
As actual calculation, EUDTCH transmission start point = k × Tsubframe + τSACCH
-TFRI + τTFRI-EUDTCH
EUDTCH transmission end point = k × Tsubframe + τSACCH
-TFRI + τTFRI-EUDTCH + n × Tsubframe
It becomes.
Here, Tsubframe indicates the time length of one subframe.

The avoidance of overlap by scheduling based on these predictions will be described. Considering the case where uplink packet communication is used in advance of downlink packet communication as an example, the transmission timing of EUDTCH can be predicted by the above method at the timing when the scheduler determines uplink packet transmission to a certain terminal. A reserved subframe is reserved in advance for a subframe at an EUDTCH transmission scheduled location at a timing when the scheduler determines uplink packet transmission. The downlink packet scheduler uses an empty subframe by predicting the timing at which ACK / NACK is not transmitted in the subframe in which the reservation is made by the above method.
Considering the case where downlink packet communication is used in advance of uplink packet communication as an example, when continuous packet transmission is performed in downlink packet communication, a subframe to be used in the future is reserved in advance. The uplink packet communication scheduler performs scheduling in such a way as to avoid future reservations. In this way, scheduling for guaranteeing transmission of downlink packet communication is performed.

In order to realize this, it is necessary to communicate the transmission timing between the uplink packet scheduler and the downlink packet scheduler.
As a method for realizing communication, when the hardware of the scheduler is different between the upstream packet scheduler and the downstream packet scheduler, a method such as providing a shared memory etc. and communicating via the data bus between the boards and the control bus is considered. It is done.
When both schedulers are operated in the same CPU, communication between the tasks of both schedulers (unit of program processing in the real-time OS) is performed in software. As a means for communicating between tasks in the real-time OS, methods such as an event flag, a semaphore, and a mailbox can be considered. These mounting means depend on the functions of the circuit and the OS, and since each method is known, detailed description thereof will be omitted.

Next, the operation of the uplink packet communication scheduler 223 will be described.
First, the quality state regarding the propagation state of the current uplink channel is acquired (step ST106).
Next, the transmittable power (PowerClass) of terminal 100 is acquired (step ST107).
The transmittable power of terminal 100 is the upper limit value of the transmit power of the terminal shown in FIG. The base station control apparatus 10 has the transmittable power of the terminal 100 and is supplied to the uplink packet communication scheduler 223 via the upper layer of the base station 101.
Next, the uplink packet communication scheduler 223 calculates the reception subframe position of the ACK / NACK response signal transmitted from the terminal 100 using the HS-DPCCH 104, calculated by the downlink packet communication scheduler 216, between the scheduler communication circuits. Obtained via H.225 (step ST108).
Next, the uplink packet communication scheduler 223 calculates the transmission position of the packet data by the EUDTCH 110 so as to avoid the ACK / NACK response signal acquired in step ST108 (step ST109).
Next, the reception subframe position of the packet data by EUDTCH 110 in base station 101 is calculated based on the transmission position of the packet data by EUDTCH 110 calculated at step ST109 (step ST110).
Next, the reception position of packet data received by EUDTCH 110 calculated in step ST110 is communicated to scheduler for downlink packet communication 216 via inter-scheduler communication circuit 225 (step ST111).
Next, the reception subframe position of the packet data by EUDTCH 110 determined in step ST110 is notified to timing management section 226 (step ST112).
According to the scheduling result notified to the timing management unit 226, the timing of the transmission / reception operation in each processing unit is controlled.

The scheduling process in step ST109 of the uplink packet communication scheduler 223 will be described with reference to FIG.
The uplink packet communication scheduler 223 determines the transmission subframe allocation position for transmission packet data for which each terminal has requested transmission permission using the UL-SICCH 107 in consideration of the propagation state and the like.
In the example of FIG. 10, transmission requests for three terminals are output to one transmission queue, but actually, transmission requests from a large number of terminals are scheduled and a plurality of outputs are prepared. . Although the case of the uplink packet communication scheduler 223 has been described here, the downlink packet communication scheduler 216 performs almost the same process. In the case of downlink, the difference is that the transmittable power of the terminal is not considered in scheduling.
In addition to the packet data transmitted from each terminal, the uplink packet communication scheduler 223 is also supplied with quality information and transmittable power of each terminal as shown in step ST106 and step ST107 in FIG. Furthermore, as shown in step ST108, the scheduled reception position of the ACK / NACK signal transmitted from the terminal using the HS-DPCCH 104 is also supplied.

  In the example of FIG. 10, the transmittable power indicates that the smaller the value is, the more power is available, and a larger power can be used for the transmission process. The uplink packet communication scheduler 223 generates a transmission queue according to a certain algorithm, and sends each packet to the transmission buffer. As this algorithm, for example, an algorithm such as a round robin that is allocated evenly, or an algorithm that is allocated preferentially to a terminal having good propagation quality can be considered. When performing scheduling using the algorithm, the uplink packet communication scheduler 223 is transmitted from the terminal using the EUDTCH 110 using the scheduled reception position of the ACK / NACK signal transmitted using the HS-DPCCH 104. The subframe positions are assigned so that the packet data transmission positions do not overlap. At this time, as with the terminal 1 in FIG. 10, for a terminal having a sufficient transmittable power, a problem exceeding the limit value of the transmission power does not occur, and thus avoiding duplication (see (C) in the figure). .

  In the above description, an example in which the transmission timing of the ACK / NACK signal and the uplink packet data for the downlink packet data is predicted and scheduling is performed so that both do not overlap is shown, but the scheduling is not limited to the above example, Any scheduling method may be used as long as the transmission of the ACK / NACK signal and the uplink packet data does not overlap.

As described above, in the first embodiment, the base station receives the reception response signal of the downlink packet data transmitted to the terminal via the control channel, and transmits the uplink packet transmitted by a plurality of subframes via the time division multiplexing channel. Receive packet data. A first transmission schedule in which a scheduling unit of a base station causes a terminal to transmit a plurality of subframes on a time division multiplexing channel at an intermittent transmission timing with at least one non-transmission period interposed therebetween; and a non-transmission period; A transmission timing overlapping with the transmission period of the reception response signal from the terminal is set, and a second transmission schedule for downlink packet data transmission based on this transmission timing is generated. Then, the transmission unit transmits the downlink packet data according to the second transmission schedule created by the scheduling unit and transmits the schedule information of the first schedule to the terminal, so that time division multiplexing caused by the transmission energy limit of the terminal Communication failures in the channel and control channel can be suppressed.
Further, the terminal transmits uplink packet data transmitted to the base station using a time division multiplexing channel shared with other terminals, and receives a downlink packet data from the base station and a base station. A transmission unit that transmits a plurality of subframes for transmitting uplink data using a time division multiplexing channel and transmits a reception response signal for downlink packet data using a control channel. The transmission control unit controls the transmission timing of the transmission unit, instructs transmission of a plurality of subframes at an intermittent timing with at least one non-transmission period interposed therebetween, and transmits the downlink packet response signal to the downlink packet Since the response signal is transmitted at a timing that occurs during the non-transmission period, it is possible to solve the problem that the transmission power of the time division multiplexing channel and the transmission power of the control channel exceed the transmission limit of the transmission unit.
Here, the non-transmission period may be provided between the subframes, or a plurality of subframes may be provided as one group, and the non-transmission period may be provided between the groups. Further, the transmission unit may be a frame unit instead of a subframe unit.
The above non-transmission period is an example in which data is not transmitted in a specific subframe of a time division multiplex channel assigned to one terminal, but the non-transmission period is reduced in power compared to normal transmission power. The low power transmission period may be used.

  As described above, according to the first embodiment, the HS-DPCCH 104 from the terminal is used between the downlink packet communication scheduler 216 and the uplink packet communication scheduler 223 of the base station 101 via the inter-scheduler communication circuit 225. By exchanging the transmission timing of the ACK / NACK signal and the information on the transmission position of the uplink packet data using the EUDTCH 110, scheduling is performed so that the transmission timings of both do not overlap. On the terminal side, transmission using each channel is performed in accordance with the transmission timing determined by the base station, so that the upper and lower packets are controlled so as not to exceed the limit of transmittable power of the terminal by the control of the base station 101. There is an effect that scheduling can be performed without sacrificing communication.

Furthermore, since the uplink packet communication scheduler 223 performs scheduling based on the value of the transmittable power of each terminal, if there is a margin in the transmittable power of the terminal, it avoids unnecessary duplication of transmission timing. The transmission allocation position can be determined without doing so.
When the processing is simplified, scheduling may be performed so that the transmission timings of the uplink packet data and the downlink packet response signal do not overlap regardless of the value of the transmittable power of the terminal.

Embodiment 2. FIG.
In Embodiment 1, the upper and lower packet communication schedulers are provided in the base station, and the base station performs scheduling for both uplink and downlink communication. On the other hand, in Embodiment 2, the packet transmission timing from the terminal is not determined on the base station side, and the terminal has the right to determine the transmission timing and performs mutual adjustment of the upper and lower communications. The configuration of the packet communication system and the channel configuration in the second embodiment are the same as those in the first embodiment shown in FIG.

FIG. 11 is a block diagram showing a configuration of base station 400 according to the second embodiment. In the figure, the same reference numerals as those in FIG. 2 represent the same components.
In base station 400, the configuration related to CDMA modulation / demodulation and the configuration related to downlink packet communication are the same as those in the first embodiment, and a description thereof will be omitted.

  A configuration related to uplink packet communication of the base station 400 will be described. The configuration related to uplink packet communication is different from that of the first embodiment.

  In response to a transmission permission request transmitted from the terminal using the UL-SICCH 107, the base station 400 needs to notify the terminal of the allowable transmission power to the terminal. The interference amount measurement unit 419 measures the current interference amount including interference in other cells. The total interference amount at the time when the EUDTCH 110 is transmitted from the terminal is predicted by the base station total interference amount prediction unit 423 in consideration of the value and power used for other voice channels, etc., and the terminal transmission power margin transmission unit At 424, the data is transmitted to each terminal using the DL-SACCH 108.

In reception of packet data transmitted from the terminal using the EUDTCH 110, first, demodulation parameters necessary for reception of packet data from the terminal transmitted from the terminal using the UL-TFRI-CCH 109 are transmitted through the demodulation unit 411 to the TFRI. The signal is supplied to the receiving unit 420. The obtained demodulation parameters are supplied to the demodulation unit 411 and the decoding unit 421.
Packet data transmitted from the terminal using the EUDTCH 110 is supplied to the decoding unit 421 through the demodulation unit 411, and after error correction check is performed, is supplied to the response signal transmission unit 422. If there is no reception error, ACK When an error occurs, a NACK response signal is generated. The ACK / NACK response signal is transmitted to the terminal using DL-ACK / NACK-CCH 111.

  The timing management unit 425 generates a timing such as a subframe based on a reference clock signal supplied from an original vibration (not shown) and supplies it to each processing unit. In upstream packet communication, this series of flows is repeated.

FIG. 12 is a block diagram showing a configuration of terminal 500 according to the second embodiment. In the figure, the same reference numerals as those in FIG. 3 represent the same components.
In terminal 500, the configuration related to CDMA modulation / demodulation and the configuration related to downlink packet communication are the same as those in the first embodiment, and a description thereof will be omitted.

A configuration related to uplink packet communication of terminal 500 will be described. The configuration related to uplink packet communication is different from that of the first embodiment.
In response to the transmission permission transmitted to the base station 400 by the terminal 500 using the UL-SICCH 107, the allowable transmission power margin transmitted from the base station 400 using the DL-SACCH 108 is transmitted through the demodulation unit 511 to the transmission margin receiving unit. 519. The transmission margin receiving unit 519 notifies the transmission determining unit 520 of the maximum power allowed for the terminal. In accordance with a user instruction, data to be transmitted via the upper layer is stored in the uplink packet communication transmission data buffer 522. The uplink packet communication transmission data buffer 522 notifies the transmission determination unit 520 that there is data to be transmitted in the buffer. The transmission determining unit 520 determines a TFRI when transmitting a packet and notifies the TFRI transmission processing unit 523 of the TFRI.
Furthermore, the transmission determination unit 520 acquires the transmission timing of the ACK / NACK signal using the HS-DPCCH 104 from the timing management unit 518, and determines a transmission subframe so as not to overlap with the ACK / NACK signal. The determined transmission subframe is actually notified to the timing management unit 518. The TFRI transmission processing unit 523 transmits TFRI using the UL-TFRI-CCH 109 according to the subframe position specified by the timing management unit 518. The transmission data stored in the uplink packet communication transmission data buffer 522 is supplied to the EUDTCH transmission processing unit 524, and the EUDTCH transmission processing unit 524 uses the EUDTCH 110 according to the subframe position specified by the timing management unit 518. Send data.

  Base station 400 transmits an ACK / NACK response signal for packet data transmitted from terminal 500 using EUDTCH 110 to terminal 500 using DL-ACK / NACK-CCH 111. The ACK / NACK signal transmitted by the DL-ACK / NACK-CCH 111 is supplied to the response signal reception unit 521 through the demodulation unit 511. The reception result is notified to the upstream packet communication transmission data buffer 522. The uplink packet communication transmission data buffer 522 performs retransmission when the reception result is NACK, and deletes the transmitted data and transmits the next packet when the reception result is ACK. In upstream packet communication, this series of flows is repeated.

  FIG. 13 is a time chart for explaining avoidance of transmission timing collision by scheduling of terminal 500 according to the second embodiment. As shown in the figure, in downlink packet communication, control information is transmitted from the base station 400 using the HS-SCCH 105, and packet data is transmitted using the HS-DSCH 106 at a position shifted by 2 slots from the head thereof. . If the reception result of the packet data transmitted by the HS-DSCH 106 is not an error, the terminal 500 sets the HS-DPCCH 104 at a position delayed about 7.5 slots by the terminal processing time from the end of the data transmission timing by the HS-DSCH 106. ACK is transmitted using it, and if there is an error, NACK is transmitted.

  On the other hand, in uplink packet communication, base station 400 uses DL-SACCH 108 to notify terminal 500 of a transmission power allowable margin in advance. Based on the notified transmission power margin, terminal 500 selects a TFRI such as a modulation scheme and a coding rate within the range. The selected TFRI is notified to the base station 500 using the UL-TFRI-CCH 109, and immediately after that, the data body is transmitted using the EUDTCH 110.

  When terminal 500 determines the subframe position for data transmission by UL-TFRI-CCH 109 and EUDTCH 110, the transmission subframe position of the ACK / NACK signal by HS-DPCCH 104 overlaps the transmission subframe position of the packet data by EUDTCH 110. Schedule to avoid. Since the control information notified from the base station 400 using the HS-SCCH 105 is received in advance by the terminal 500, the terminal 500 can predict the transmission subframe position of the ACK / NACK signal by the HS-DPCCH 104. .

  Next, the scheduling process in terminal 500 transmission determining section 520 will be described. The transmission determination unit 520 determines subframe allocation so that transmission of an ACK / NACK signal in downlink packet communication and transmission of a data body in uplink packet communication do not collide.

FIG. 14 is a flowchart of the scheduling process of transmission determining section 520 of terminal 500 according to the second embodiment.
First, transmission determination section 520 acquires the reception subframe position of control information from base station 400 by HS-SCCH 105 from timing management section 518 (step ST200).
Next, a transmission margin is acquired from the transmission margin receiving unit 519 (step ST201).
Next, the data buffer state is acquired from the uplink packet communication transmission data buffer 522 (step ST202).
Next, based on the reception timing of the control signal by HS-SCCH 105 acquired at step ST200, an ACK / NACK transmission scheduled position for downlink packet data by HS-DPCCH 104 is calculated (step ST203).
Next, TFRI is determined based on the data buffer state of uplink packet communication transmission data buffer 522 and the transmission margin notified from base station 400 (step ST204).
Next, the determined TFRI is notified to the TFRI transmission processing unit 523 (step ST205).
Next, the position of the EUDTCH 110 transmission subframe is determined at a position with a certain offset from the reception timing of the control signal by HS-SCCH 105 (step ST206).
Next, the TFRI transmission subframe position by UL-TFRI-CCH 109 is determined one subframe before the data transmission subframe by EUDTCH 110 (step ST207).
Next, the ACK / NACK scheduled reception position from base station 400 for the uplink packet data by DL-ACK / NACK-CCH 111 is calculated at a position with a certain offset from the data transmission subframe by EUDTCH 110 (step ST208).
Next, the determined subframe position is notified to timing management section 518 (step ST209).

As described above, according to the second embodiment, in transmission determination section 520 of terminal 500, the transmission timing of the ACK / NACK signal using HS-DPCCH 104 and the transmission position of the uplink packet data using EUDTCH 110 do not overlap. The terminal 500 determines the transmission subframe position as described above, and the terminal 500 performs transmission processing according to the determined transmission subframe position, so that the terminal 500 does not exceed the transmittable power limit of the terminal 500 and There is an effect that scheduling can be performed without sacrificing either packet communication.
Note that when the transmission determining unit 520 performs scheduling, the transmittable power of the terminal 500 is taken into consideration, and it is determined that the transmittable power is exceeded when the transmission timings of the uplink packet data and the downlink packet data response signal overlap. Only overlapping transmission timings may be avoided.

Embodiment 3 FIG.
In Embodiment 1 and Embodiment 2, for example, as shown in FIG. 7 and FIG. 13, it is assumed that HS-DPCCH 104 includes an empty subframe that is not used for transmission of an ACK / NACK signal. ing. If there is no empty subframe in HS-DPCCH 104, the transmission position of the ACK / NACK signal is avoided and the transmission subframe of the packet data by EUDTCH 110 cannot be assigned.

  Depending on the capabilities of the terminal, there are those that can continuously process packets in parallel. The interval at which the terminal can process packets continuously is represented by a parameter called Minimum Inter-TTI interval. For example, if the value of Minimum Inter-TTI interval is 2, it indicates that transmission is performed every other subframe. In a high-performance terminal, the Minimum Inter-TTI interval may be 1, and in this case, packet transmission is performed continuously without any interval. In this case, ACK / NACK is also continuously transmitted correspondingly, and it becomes difficult to find an empty subframe.

  FIG. 17 is a time chart for explaining a method of avoiding transmission timing collision when there is no empty subframe that is not used for transmission of the ACK / NACK signal on HS-DPCCH 104. In the example of FIG. 17, the value of Minimum Inter-TTI interval is 2, and packets are transmitted every other subframe.

As shown in the figure, in downlink packet communication, control information is transmitted using HS-SCCH 105, and downlink packet data is transmitted using HS-DSCH 106 at a position shifted by 2 slots from the head thereof.
When there is no error in the reception result of the HS-DSCH 106, an ACK is transmitted using the HS-DPCCH 104 at a position delayed about 7.5 slots by the terminal processing time from the end of the HS-DSCH 106. NACK is transmitted.

  The uplink packet communication will be described. The base station 600 notifies the terminal of the transmission power allowable margin when transmitting data using the EUDTCH 110 using the DL-SACCH 108 in advance. The terminal notifies the base station 600 of the combination of modulation scheme, coding rate, etc. selected within the range using the UL-TFRI-CCH 109, and immediately after that, transmits the data portion using the EUDTCH 110.

  Since terminal 700 has received control information by HS-SCCH 105 in advance, when ACK / NACK signal transmission position by HS-DPCCH 104 can be predicted when terminal 700 determines transmission of the uplink data body using EUDTCH 110 It is. However, when the ACK / NACK transmission position by HS-DPCCH 104 is continuous, there is no empty subframe, and therefore, a subframe position that does not overlap with the ACK / NACK transmission position cannot be assigned to transmission by EUDTCH 110.

In Embodiment 3, when there is no empty subframe of the ACK / NACK signal during downlink packet communication on HS-DPCCH 104, collision is avoided by reducing the frame length of the data body transmitted by EUDTCH 110. . Note that the collision avoidance method using the variable frame length according to the third embodiment is used both when the base station performs scheduling as in the first embodiment and when the terminal performs scheduling as in the second embodiment. Applicable.
The configuration of the packet communication system and the channel configuration in the third embodiment are the same as those shown in FIG.

FIG. 15 is a block diagram showing a configuration of base station 600 according to the third embodiment. In the figure, the same reference numerals as those in FIG. 2 represent the same components.
As described above, the third embodiment can be applied both when scheduling is performed on the base station side and when scheduling is performed on the terminal side. Here, as in the first embodiment, the uplink is performed on the base station side. A case where scheduling of packet communication is performed will be described as an example.

First, the configuration related to CDMA modulation / demodulation and the configuration related to downlink packet communication in base station 600 are the same as those in Embodiment 1, and thus description thereof is omitted.
A configuration related to uplink packet communication of the base station 600 will be described. The configuration related to uplink packet communication is different from that of the first embodiment. A transmission permission request transmitted from the terminal using the UL-SICCH 107 is supplied to the transmission buffer amount receiving unit 619 through the demodulation unit 611. The transmission buffer amount receiving unit 619 notifies the uplink packet communication scheduler 623 that transmission data exists in the terminal. Further, the quality information receiving unit (not shown) acquires the current propagation state of the uplink channel and notifies the uplink packet communication scheduler 623 of the propagation state.

  The uplink packet communication scheduler 623 acquires the transmission timing from the timing management unit 625, comprehensively determines the presence / absence of transmission data and the propagation state of each terminal, and determines the transmission timing of the uplink packet data. When the packet transmission assignment is determined, the subframe allocation information creating unit 624 notifies the terminal of the transmission subframe position using the DL-SACCH 108.

  Base station 600 must receive packet data from the terminal based on the subframe length when packet data is received by EUDTCH 110 selected by the subframe length determination method described later. As a subframe length acquisition method of the base station 600, a method of acquiring the subframe length determined on the terminal side by notification from the terminal, and the base station 600 also calculates the subframe length by a process similar to that on the terminal side. Although a method is conceivable, here, the former case will be described as an example.

  The terminal transmits the subframe length of the EUDTCH 110 determined together with the modulation scheme and the coding rate to the base station 600 using the UL-TFRI-CCH 109 according to the transmission timing notified from the base station 600 using the DL-SACCH 108. To do. Information transmitted on the UL-TFRI-CCH 109 is referred to as TFRI. The TFRI received by the base station 600 is supplied to the TFRI receiving unit 620. The TFRI reception unit 620 supplies the acquired demodulation parameters to the demodulation unit 611 and the decoding unit 621. The variable frame information received by the TFRI receiving unit 620 is set in the variable frame control unit 626. The variable frame control unit 626 sets variable frame information in the decoding unit 621. The packet data transmitted from the terminal by the EUDTCH 110 is supplied to the decoding unit 621 through the demodulation unit 611. The decoding unit 621 decodes the packet data based on the variable frame information using the designated demodulation parameter.

  When the packet data transmitted from the terminal can be received correctly, the response signal generator 622 generates an ACK signal. When the packet data cannot be received correctly, the NACK signal is generated. The generated ACK / NACK signal is notified to the terminal using DL-ACK / NACK-CCH 111. In upstream packet communication, this series of flows is repeated.

FIG. 16 is a block diagram showing a configuration of terminal 700 according to the third embodiment. In the figure, the same reference numerals as those in FIG. 3 represent the same components.
In terminal 700, the configuration related to CDMA modulation / demodulation and the configuration related to downlink packet communication are the same as those in the first embodiment, and a description thereof will be omitted.

A configuration related to uplink packet communication of terminal 700 will be described. The configuration related to uplink packet communication is different from that of the first embodiment.
Control information transmitted from the base station 600 using the DL-SACCH 108 is supplied to the subframe position / transmission margin reception unit 719 through the demodulation unit 711. The maximum power allowed for the terminal included in the control information is notified to the transmission determination unit 720. In accordance with a user instruction, data to be transmitted via the upper layer is stored in the upstream packet communication transmission data buffer 722. The uplink packet communication transmission data buffer 722 notifies the transmission determination unit 720 that there is data to be transmitted.

  The variable frame control unit 726 obtains the transmission timing of the ACK / NACK signal transmitted by the HS-DPCCH 104 from the timing management unit 718. The variable frame control unit 726 selects a short subframe length as the subframe length of the EUDTCH 110 when the packet data transmission subframe position by the EUDTCH 110 overlaps with the ACK / NACK signal of the downlink packet communication, and there is no ACK / NACK. In this case, the normal subframe length is selected. The determined subframe length is notified to transmission determining section 720. The configuration of the variable subframe and the method for determining the subframe length will be described later.

  The transmission determining unit 720 determines a modulation scheme, a coding rate, and the like when transmitting a packet. The determined modulation scheme, encoding rate, and subframe length notified from variable frame control section 726 are notified to TFRI transmission processing section 723. In addition, the timing management unit 718 is notified of the subframe position to be transmitted. The TFRI transmission processing unit 723 and the EUDTCH transmission processing unit 725 perform transmission according to the subframe position specified by the timing management unit 718.

  The response signal reception unit 721 acquires an ACK / NACK signal as an uplink packet data reception result transmitted from the base station 600 and notifies the transmission determination unit 720 of the result. The reception result is notified to the uplink packet communication transmission data buffer 722, and if it is NACK, retransmission is performed, and if it is ACK, the transmitted data is deleted and the next packet is transmitted. In upstream packet communication, this series of flows is repeated.

  FIG. 18 shows a variable frame structure of packet data transmitted on EUDTCH 110 according to the third embodiment. Here, three states are selected according to the scheduling situation. As shown in the figure, a normal subframe with a subframe length of 3 slots, the first one slot used when avoiding an ACK / NACK signal is short, a short subframe with a subframe length of 2 slots, and transmission is not allowed A subframe in the DTX state in which transmission is turned off for all three slots used in the above is used.

Here, a frame length control method according to the third embodiment will be described.
As a feature of the configuration of terminal 700 and base station 600 of Embodiment 3, variable frame control section 726 that selects normal frames and short frames within terminal 700, and reception within base station 600 according to the frame length determined by terminal 700 There is a variable frame control unit 626 that performs the following. In order to use the variable frame, the base station 600 must select the same frame length as the frame length selected by the terminal 700 and receive data transmitted by the EUDTCH 110. Alternatively, the base station 600 may perform the subframe length selection process to acquire the same subframe length as that of the terminal 700.

  First, the first method will be described. The first method is to select a subframe length based on whether ACK / NACK and CQI are set in the subframe of HS-DPCCH 104.

  FIG. 20 is a flowchart of a first example of a subframe length selection method according to the third embodiment. The process shown in the figure is executed by the variable frame control unit 726 of the terminal 700. The obtained subframe length is reported to base station 600. Alternatively, the variable frame control unit 626 of the base station 600 may perform similar processing so that the terminal 700 does not notify the base station 600.

  First, the variable frame control unit 726 acquires the scheduled transmission subframe position and the CQI transmission scheduled subframe position of the ACK / NACK signal transmitted by the HS-DPCCH 104 from the timing management unit 718 (step ST300).

  Next, it is checked whether there is transmission of either ACK / NACK or CQI by HS-DPCCH 104 at a subframe position where packet data is to be transmitted by EUDTCH 110 (step ST301).

  When there is no transmission, it progresses to step ST302 and selects the sub-frame length of 3 slots, ie, a normal sub-frame.

If it is determined in step ST301 that ACK / NACK or CQI is transmitted by the HS-DPCCH 104, the process proceeds to step ST303, and it is confirmed whether there is CQI transmission.
When CQI is transmitted, transmission is turned off (DTX state), and subframe length = 0 is selected. (Step ST304).
If it is determined in step ST303 that CQI is not transmitted, ACK / NACK transmission exists, and a subframe length of 2 slots, that is, a short subframe is selected.

  Using this first method has the advantage that the frame length can be selected with a simple process. However, since the frame length is automatically determined based on whether or not ACK / NACK or CQI is transmitted by the HS-DPCCH 104, there is a possibility that a short subframe may be selected even when there is still a margin in actual transmission power. There are disadvantages.

Also in the base station 600, the variable frame control unit 626 selects a subframe length based on the same flow, so that transmission using a variable frame is possible even when there is no explicit signaling between the base station and the terminal. Can be realized.
Further, when notifying base station 600 of the frame length selected by terminal 700, there is an advantage that the subframe length can be freely determined according to the situation of terminal 700.

  Also, when selecting the subframe length, considering the transmittable power of terminal 700, transmission is performed even if the transmission timing of the uplink packet data transmitted on EUDTCH 110 and the transmission timing of the downlink packet data response signal transmitted on HS-DPCCH 104 overlap. If the possible power is not exceeded, a normal frame length may be selected.

Next, the second frame length selection method will be described.
In the second frame length selection method, the frame length selected by terminal 700 is signaled at high speed and explicitly to base station 600. When explicit signaling is used as a means for synchronization with the base station 600, there is an advantage that the subframe length can be freely determined according to the situation of the terminal 700.

In the second method, the subframe length is determined using parameters specific to the terminal.
Here, terminal-specific parameters regarding the use of the HS-DPCCH 104 will be described. These parameters are specified to the terminal through higher layers.

In a soft handover state in which the terminal communicates with a plurality of base stations, such as when the terminal is at the edge of a cell, ACK / NACK transmission may be repeated continuously. In downlink high-speed packet communication called HSDPA in W-CDMA, the number of ACK / NACK repetitions is read as N_acknack_transmit. If N_acknack_transmit is greater than 1, ACK / NACK is repeated for that number of times. For example, FIG. 17 shows a case where N_acknack_transmit is 2.
Similarly, there is a case where CQI is repeatedly transmitted, and there is N_CQI_transmit as a parameter, and CQI transmission is repeated by that number of times.

When transmitting the HS-DPCCH 104, a power offset is prepared depending on the type of signal. There are ΔACK and ΔNACK indicating transmission power offset when transmitting an ACK / NACK signal. In general, ACK and NACK are given as independent parameters because ACK and NACK signals are more likely to require more power than NACK.
Similarly, ΔCQI is an example of the CQI transmission power offset.

  FIG. 21 is a flowchart of subframe length selection processing by the second frame length selection method. The process shown in the figure is executed by the variable frame control unit 726 of the terminal 700.

  First, variable frame control section 726 obtains a parameter related to transmission of ACK / NACK signal and CQI signal and a threshold value permitted for transmission at the time of data transmission using EUDTCH 110 from the upper layer (step ST400).

  Next, the ACK / NACK signal transmission scheduled subframe position and CQI transmission position by HS-DPCCH 104 are acquired from timing management section 718 (step ST401).

  Next, it is checked whether transmission of either ACK / NACK or CQI by HS-DPCCH 104 exists at the same position as the subframe in which packet data is to be transmitted by EUDTCH 110 (step ST402).

  If it is determined in step ST402 that there is no transmission using the HS-DPCCH 104, the process proceeds to step ST403, and a subframe length of 3 slots, that is, a normal subframe length is selected.

If it is determined in step ST402 that ACK / NACK or CQI is transmitted by the HS-DPCCH 104, the process proceeds to step ST404 and it is confirmed whether there is CQI transmission.
If it is determined in step ST404 that CQI is not transmitted, the process proceeds to step ST409. On the other hand, if it is determined that CQI is to be transmitted, the process proceeds to step 405, where the value of the N_CQI_transmit parameter is checked, and if 1, the process proceeds to step ST407. If it is other than 1, the process proceeds to step ST406, transmission is turned off (DTX state), and subframe length = 0 is selected.

In step ST407, the value of ΔCQI is compared with the threshold value acquired in step ST400. If ΔCQI is larger, the process proceeds to step ST408, transmission is turned off (DTX state), and subframe length = 0 is selected.
On the other hand, if the value of ΔCQI is smaller than the threshold value, the process proceeds to step ST409.

  In step ST409, the value of the N_acknack_transmit parameter is checked, and in the case of 1, the process proceeds to step ST411. In the case other than 1, the process proceeds to step ST410, and a transmission subframe length of 2 slots, that is, a short subframe is selected.

In step ST411, the value of ΔACK is compared with the threshold acquired in step ST400. If HS-DPCCH104ΔACK is larger, the process proceeds to step ST412 to select a transmission subframe length of 2 slots, that is, a short subframe.
When the value of ΔACK is smaller than the threshold value, the process proceeds to step ST413.

In step ST413, the value of ΔNACK is compared with the threshold acquired in step ST400. If ΔNACK is larger, the process proceeds to step ST414, and a transmission subframe length of 2 slots, that is, a short subframe is selected.
When the value of ΔNACK is smaller than the threshold value, the process proceeds to step ST415, and a transmission subframe length of 3 slots, that is, a normal subframe is selected.

  When this subframe length selection method is used, the existing N_CQI_transmit, N_acknack_transmit, or ΔCQI, ΔACK, and ΔNACK are used, and the subframe length that considers the actual transmission power margin more than Method 1 is used. Selection can be made.

  Also, when selecting the subframe length, considering the transmittable power of terminal 700, transmission is performed even if the transmission timing of the uplink packet data transmitted on EUDTCH 110 and the transmission timing of the downlink packet data response signal transmitted on HS-DPCCH 104 overlap. If the possible power is not exceeded, a normal frame length may be selected.

Next, a process of notifying base station 600 of the selected subframe after subframe selection at terminal 700 will be described using the flowchart of FIG.
In step ST500, transmission determining section 720 acquires the subframe length determined from variable frame control section 726.
Next, in step S501, the transmission determination unit 720 determines a modulation scheme, a coding rate, and the like when transmitting a packet.
Next, in step ST502, transmission determining section 720 selects a TFRI to be transmitted to base station 600 based on the value determined in step ST501 and the subframe length acquired in step ST500, and notifies TFRI transmission processing section 723 of the TFRI.

  Next, in step ST503, the TFRI transmission processing unit 723 transmits the TFRI including the subframe length information to the base station 600 using the UL-TFRI-CCH 109.

  Here, an example of the TFRI format will be described with reference to FIG. It is the TFRI number that is actually transmitted as signaling to the base station 600 using the UL-TFRI-CCH 109. The base station 600 has the same information as the terminal 700 as shown in FIG. 23. When receiving the notification of the TFRI number, the base station 600 can derive the modulation scheme, coding rate, and subframe length corresponding to the number. it can. In the example of the figure, for example, modulation method 1 corresponds to BPSK and 2 corresponds to QPSK.

  When this method is used, subframe length notification between the base station and the terminal can be performed using the existing UL-TFRI-CCH 109.

Next, reception processing based on the subframe length notified from terminal 700 in base station 600 will be described using the flowchart of FIG.
First, in step ST600, the TFRI transmitted from the terminal 700 using the UL-TFRI-CCH 109 is supplied to the TFRI receiver 620 through the demodulator 711. The TRFI includes information on the subframe length, a modulation scheme, a coding rate, and the like.

  Next, the received subframe length is notified to variable frame control section 626 in step ST601. In step ST602, information such as a subframe length, a modulation scheme, and a coding rate that are also included in TFRI is supplied to decoding section 621.

  Next, in step ST603, decoding section 621 performs decoding processing according to the designated subframe length, modulation scheme, and the like.

  The second subframe length selection method has an advantage that the terminal 700 can freely select a subframe length at high speed. However, it is necessary to notify the subframe length by signaling for each subframe.

  Note that in the second method, it is not necessary to use all parameters of _CQI_transmit, N_acknack_transmit, or ΔCQI, ΔACK, and ΔNACK.

  For example, in FIG. 21, the subframe length may be determined using only N_acknack_transmit. In this case, for example, if it is determined in step ST404 that CQI transmission is present, all 0 is selected as the subframe length, and if it is determined that CQI transmission is not performed, the process proceeds to step ST409. If N_acknack_transmit is determined to be other than 1 in step ST409, the process proceeds to step ST410, and a short subframe is selected. On the other hand, if N_acknack_transmit is determined to be 1, the process proceeds to step ST415 to select a normal subframe.

  In FIG. 21, the subframe length may be determined using only ΔACK and ΔNACK. In this case, for example, if it is determined in step ST404 that CQI transmission is present, all 0 is selected as the subframe length, and if it is determined that CQI transmission is not performed, the process proceeds to step ST411. From step ST411 to step ST415, the same processing as in FIG. 21 is performed.

  Further, the subframe length may be determined using N_acknack_transmit, ΔACK, and ΔNACK. If the number of parameter types to be used is small, the process can be simplified. If the number of parameter types is increased, the probability that the subframe length is unnecessarily shortened is reduced.

Next, a third subframe length selection method will be described.
In the third method, base station 600 and terminal 700 use the same algorithm to select a subframe length.

  The processing of the variable frame control unit 726 in the third subframe length selection method is the same as that in the second subframe length selection method. However, in the second method, the base station 600 is notified of the subframe length selected by the terminal 700, whereas in the third method, the base station 600 also performs the same processing by the same process as the second subframe length selection method. The same subframe length in time is acquired in the base station.

  According to this third subframe length selection method, terminal 700 can freely select a subframe length at high speed, and notification to base station 600 is unnecessary.

  Also, when selecting the subframe length, considering the transmittable power of terminal 700, transmission is performed even if the transmission timing of the uplink packet data transmitted on EUDTCH 110 and the transmission timing of the downlink packet data response signal transmitted on HS-DPCCH 104 overlap. If the possible power is not exceeded, a normal frame length may be selected.

  As described above, according to the third embodiment, even when a high-performance terminal having a Minimum Inter-TTI interval value of 1 is used, a variable frame is used for uplink packet data transmission by the EUDTCH 110. Since it avoids overlapping with the transmission timing of the ACK / NACK signal by HS-DPCCH 104, it is possible to avoid exceeding the limit of the transmission power of the terminal.

  Also, by using the first subframe length selection method, subframe length selection can be performed with simple processing.

  Also, by using the second subframe length selection method, it is possible to reduce the probability that a short subframe will be selected even if there is still a margin in actual transmission power.

  Further, the second subframe length selection method has an advantage that an existing variable can be used as a parameter.

  Furthermore, when the subframe length is determined on the terminal side and notified to the base station, the subframe length information is included in the TFRI transmitted using the UL-TFRI-CCH 109. Notification processing can be performed using a channel.

  In the third embodiment, scheduling is performed on the base station side as in the first embodiment, but the same subframe is used even when transmission timing is determined on the terminal side as in the second embodiment. A length determination method can be used.

In the third embodiment, packet transmission is performed in units of subframes. However, even when transmission is performed in units of frames of 15 slots, it is possible to avoid duplication of upper and lower communications by using variable frames. be able to. A method for selecting a variable frame when transmission is performed in units of frames will be described with reference to FIG. In this case, ACK / NACK by the HS-DPCCH 104 is transmitted five times during transmission of one frame. In order to avoid duplication with the ACK / NACK signal transmission position, data transmission by the EUDTCH 110 uses a variable frame provided with a transmission OFF section (first transmission section) as shown in the figure. Here, the transmission OFF section means that data transmission using the EUDTCH 110 is not performed in the section. Even in this section, transmission using other channels is possible.
In the example shown in the figure, five transmission OFF sections are provided on the frame, but it is not always necessary to provide five transmission OFF sections.

  The method of providing a transmission OFF section in a frame when transmitting in units of frames conforms to the subframe length selection method, but it is necessary to pay attention to the timing for determining whether or not to provide a transmission OFF section.

  As one method for providing a transmission OFF section, a method of performing coding processing so that data is not placed from the beginning at a position to be a transmission OFF section on a frame can be considered. In this case, if the position where the ACK / NACK signal is transmitted before the beginning of the frame is known, a coding process in which a transmission OFF section is provided at the corresponding position can be performed. However, if it is necessary to create a transmission OFF section of the ACK / NACK signal at the rear of the frame, the HS-SCCH 105 is transmitted immediately before, so when the transmission position of the ACK / NACK is known, the coding process has already been completed. Sending is in progress and not in time. Therefore, as a solution, for example, when the value of N_acknack_transmit is larger than 1, it is assumed that five transmission OFF sections are always provided. However, in this case, even when there is no ACK / NACK signal transmission, there is a possibility that a transmission OFF section is set, and the efficiency of data transmission is poor.

  As a second method for providing a transmission OFF section, in the first method, the position of the transmission OFF section is grasped in advance from the stage of coding processing, and a transmission OFF section is prepared for a place where an overlap is expected. Allocation is performed so that no data comes to the position, but in the second method, it is regarded as continuous in the coding process stage, and at the time of transmitting the ACK / NACK signal, the power of the channel of that part is sacrificed. To do. Since an error occurs if it is left as it is, a small value is applied to the coding rate so that the format has a high redundancy. A method for adjusting power between channels will be described below.

First, a method for adjusting the power between the first channels will be described.
FIG. 25 shows a case where the power ratio of each channel is kept constant and the total power matches the transmission power of the terminal. The original power ratio relationship is A: B: C, and A + B + C exceeds the transmission limit D of the terminal. Therefore, the power of the EUDTCH channel is a = D × A / (A + B + C), and similarly b = D × B / (A + B + C) and c = D × C / (A + B + C) are obtained. As a result, transmission can be performed while maintaining the power ratio of each channel. However, this method can be used only when the power is slightly reduced because the power of all channels is reduced. If the power drop is large, an error is caused in all channels.

A specific control method will be described. In W-CDMA, the power ratio of each channel is controlled at a fixed ratio called a gain factor. This is adjusted in the modulation unit 301 (control unit) by a parameter called gain factor β as disclosed in Chapter 5.1 uplink power control of 3GPP specification TS25.214 (Ver 5.3.0). The modulation unit 301 has a function as a control unit that controls transmission power and coding rate.
The actual processing method of the modulation unit in the case of the method for adjusting the power between the first channels is shown in FIG. 26 using a flowchart.
In step ST700, modulation section 301 acquires transmittable power of terminal 100.
In step ST701, the total desired power of each channel in the next subframe to be transmitted is obtained.
In step ST702, modulation section 301 determines whether the total desired power of each channel exceeds the limit of the transmission power of the terminal.
If the transmission power limit is not exceeded, the process ends.
On the other hand, when the limit of the transmission power is exceeded, the ratio between the gain factors is kept constant as shown in FIG. 25, and the total power is set to be reduced within the transmission limit range.
Then, since the power amplifying unit 305 amplifies the transmission signal according to the transmission power set by the modulation unit 301, as shown in FIG. 25, the entire transmission power is controlled within a range not exceeding the transmittable power of the terminal. And transmission signal errors can be suppressed. The transmission limit range can be set to any value as long as it is within the transmission limit range and practically does not interfere with transmission / reception, and the modulation unit 301 can reduce the transmission power based on a predetermined value. Can be determined. Further, the reduction method is not limited to that based on the transmission limit range. For example, the reduction may be performed at a constant ratio (% or dB).

Next, a method for adjusting the power between the second channels will be described.
This method aims to avoid errors in channels that maintain power by keeping other channels at the same power at the expense of certain channels. As shown in FIG. 27, EUDTCH power A is reduced to a value obtained by subtracting the transmission power of other channels from the transmittable power of the terminal. That is, a = D− (B + C). For B and C, the power is maintained as it is. In this case, since B and C originally maintain necessary power, no error occurs and only EUDTCH may cause a shortage of desired power and cause an error. That is, even if necessary power is transmitted by radio, an error may occur due to the influence of a propagation path, but here, it is considered that no error occurs when there is desired power.

A specific control method of power adjustment in this case will be described.
FIG. 28 shows a flowchart of processing of the modulation unit 301. First, in step ST800, the transmittable power of the terminal is obtained. Next, in step ST801, the total desired power of each channel in the next subframe to be transmitted is obtained. Next, in step ST802, it is determined whether the total desired power of each channel exceeds the limit of the transmission power of the terminal. If the transmission power limit is not exceeded, the process ends. On the other hand, when the transmission power limit is exceeded, in step ST803, as shown in FIG. 27, the gain factor of a specific channel is set so that the total transmission power of all channels does not exceed the upper limit of the transmission power of the terminal. Decrease the value of β.
In general, the gain factor is not an amount that can be set to an infinitely small value, but is set in a stepwise manner. For this reason, if there is not enough power that can be used for transmission to the extent that an error will always occur even if measures such as reducing the coding rate are taken, the gain factor of the channel is completely reduced to 0 for the sake of simplicity. It is also possible.
It is also possible to change the power reduction rate for each channel such that the power reduction rate of EUDTCH is large and the power reduction rate of ACK / NACK on HS-DPCCH is small.

  In the method of adjusting the power between the second channels, it is arbitrary which power of the channel is lowered. However, considering the influence of each channel, the DPCCH includes a pilot signal, and if this is lowered, the synchronization is lost. . In addition, DCH is under the control of conventional power control and may adversely affect it. Although it is possible to reduce the power of ACK / NACK on HS-DPCCH, it is a response signal and causes retransmission if it cannot be received by the base station. Therefore, it is desirable to reduce the power of EUDTCH in the method for adjusting the power between the second channels.

  This method for adjusting the power between the second channels can be used even if the transmission position of the ACK / NACK is not known in advance during the coding process of the uplink packet communication data. For example, when the unit of transmission time interval (TTI: Transmit Time Interval) of uplink packet data is as long as 10 ms, 20 ms, 40 ms, etc., transmission of ACK / NACK cannot be predicted in advance by receiving HS-SCCH. . Even in such a case, this method can be applied simultaneously with the transmission of ACK / NACK by the control of the modulation unit in the terminal. This can be used even when the transmission of ACK / NACK can be predicted, but is particularly effective when the TTI in which the transmission of ACK / NACK cannot be predicted is long.

However, in the method of adjusting the power between the second channels, there is a possibility that a part where the power is reduced at the time of transmission has insufficient power on the base station side at the time of data decoding, and an error may occur in part. high. Even for a partial error, a CRC error occurs because decoding is performed in units of TTI.
As a solution to this problem, in the EUDTCH coding process for uplink packet communication at the terminal, a value with a low coding rate is applied when uplink packet communication is performed, and sufficient data redundancy is provided. A method is conceivable in which error correction is possible at the time of decoding on the base station side even if a reception error has occurred in some data. Specifically, when the TRRI transmission processing unit 723 detects that the terminal receives a downlink data packet, or transmits an ACK / NACK signal, the total transmission power exceeds the transmittable power. If there is a possibility, the TFRI having a low coding rate is selected and transmitted to the EUDTCH transmission processing unit 725. Since the EUDTCH transmission processing unit 725 encodes the uplink packet in accordance with the TFRI, even when a process for reducing the transmission power is performed, it is possible to suppress a substantial decrease in signal transmission capability. That is, the error correction capability can be improved.
Note that the power control and the coding rate reduction may be performed on a subframe in which transmission power is reduced, or may be performed on a specific slot unit or frame unit. Further, the selection of the low power and the low coding rate is not limited to the case where the total transmission power is used as a reference, but when there is a combination of specific channels (for example, EUDTCH and HS-DPCCH) in a specific frame, or 1 It can also be performed based on a criterion such as when the power of one channel or a combination of specific channels exceeds a preset threshold.
Further, even when the transmission power other than EUDTCH is reduced, the control unit that similarly controls the coding rate of each channel can control the transmission capability by lowering the coding rate of the signal that lowers the transmission power. Needless to say.
In this case, the effect of error correction can be improved by distributing the missing data using interleaving to the entire frame. Other than the coding rate, it may be possible to compensate for the desired power by decreasing the modulation multi-level number (for example, from QPSK to BPSK) or increasing the spreading factor (for example from SF = 4 to SF = 16). It is desirable to realize this by selecting a transport format such as TFRI.

In this case as well, when providing a transmission OFF section in the frame, transmission of uplink packet data transmitted on EUDTCH 110 and downlink packet data response signal transmitted on HS-DPCCH 104 in consideration of the transmittable power of terminal 700 If the transmittable power does not exceed the transmission timing, the transmission OFF section may not be provided.
The operations described in the above embodiments can be realized not only by a dedicated circuit, but also by a combination of a computer constituted by a microprocessor and software executed by the computer. For example, a terminal or base station that performs the above-described operation can be realized by preparing software that allows a computer to execute the processing shown in the above-described flowchart and recording the software on a computer-readable recording medium.

It is a figure which shows the structure and channel structure of a packet communication system by Embodiment 1 of this invention. It is a block diagram which shows the structure of the base station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the terminal by Embodiment 1 of this invention. It is a figure which shows the frame structure at the time of transmitting data using HS-DPCCH. It is a figure explaining the transmission power of a terminal. It is a time chart for demonstrating generation | occurrence | production of the transmission power limit value excess of a terminal. It is a time chart for demonstrating the avoidance of the collision of the transmission timing by the scheduling of the base station by Embodiment 1 of this invention. It is a flowchart of the scheduling process by the scheduler of the base station by Embodiment 1 of this invention. It is a figure explaining the prediction process of the packet transmission timing of the terminal in uplink packet communication by Embodiment 1 of this invention. It is a figure for demonstrating the outline | summary of operation | movement of the scheduler for uplink packet communications of the base station by Embodiment 1 of this invention. It is a block diagram which shows the structure of the base station by Embodiment 2 of this invention. It is a block diagram which shows the structure of the terminal by Embodiment 2 of this invention. It is a time chart for demonstrating the avoidance of the collision of the transmission timing by the scheduling of the terminal by Embodiment 2 of this invention. It is a flowchart of the scheduling process by the transmission determination part of the terminal by Embodiment 2 of this invention. It is a block diagram which shows the structure of the base station by Embodiment 3 of this invention. It is a block diagram which shows the structure of the terminal by Embodiment 3 of this invention. It is a time chart for demonstrating the avoidance of the collision of the transmission timing when the sub-frame which is not used for transmission of an ACK / NACK signal does not exist in HS-DPCCH by Embodiment 3 of this invention. It is a figure which shows the variable frame structure of the packet data transmitted by EUDTCH by Embodiment 3 of this invention. It is a figure which shows the structure of the variable frame at the time of transmitting by the frame unit by Embodiment 3 of this invention. It is a flowchart of the selection method of the sub-frame length by Embodiment 3 of this invention. It is a flowchart of another example of the selection method of the sub-frame length by Embodiment 3 of this invention. It is a flowchart of the process which notifies the selected sub-frame length to the base station by Embodiment 3 of this invention. It is a figure which shows the example of the format of TFRI by Embodiment 3 of this invention. It is a flowchart of the data reception process in the base station based on the sub-frame length notified from the terminal by Embodiment 3 of this invention. It is a figure explaining the power adjustment method between the channels in the terminal according to Embodiment 3 of the present invention. It is a flowchart of the power adjustment process between the channels in the terminal by Embodiment 3 of this invention. It is a figure explaining another example of the power adjustment method between the channels in the terminal by Embodiment 3 of this invention. It is a flowchart of another example of the power adjustment process between the channels in the terminal according to Embodiment 3 of the present invention.

Explanation of symbols

  10 base station controller, 100 terminal, 101 base station, 102 CPICH, 103 DPCH, 104 HS-DPCCH, 105 HS-SCCH, 106 HS-DSCH, 107 UL-SICCH, 108 DL-SACCH, 109 UL-TFRI-CCH , 110 EUDTCH, 111 DL-ACK / NACK-CCH, 201 modulation unit, 202 downlink channelization code generator, 203 downlink scrambling code generator, 204 frequency conversion unit, 205 power amplification unit, 206 antenna, 207 low noise amplification , 208 Frequency conversion unit, 209 Uplink channelization code generator, 210 Uplink scrambling code generator, 211 Demodulation unit, 212 Decoding unit, 213 Response signal determination unit, 214 Quality information reception 215 Downlink packet communication transmission data buffer, 216 Downlink packet communication scheduler, 217 Downstream packet communication control information transmission unit, 218 Downstream packet communication data transmission unit, 219 Transmission buffer amount reception unit, 220 TFRI reception unit, 221 Decoding unit 222 Response signal generator, 223 Uplink packet communication scheduler, 224 Subframe allocation information generator, 225 Inter-scheduler communication circuit, 226 Timing manager, 301 Modulator, 302 Channelization code generator, 303 Scrambling code generator , 304 Frequency converter, 305 Power amplifier, 306 Antenna, 307 Low noise amplifier, 308 Frequency converter, 309 Channelization code generator, 310 Scrambling code generator, 31 1 demodulator, 312 decoder, 313 decoder, 314 response signal generator, 315 propagation quality estimator, 316 quality information signal generator, 317 HS-DPCCH transmission processor, 318 timing manager, 319 response signal receiver, 320 Uplink packet transmission data buffer, 321 TFRI transmission processing unit, 322 EUDTCH transmission processing unit, 323 Uplink packet transmission buffer amount transmission processing unit, 324 Subframe position / transmission margin receiving unit, 400 base station, 411 demodulating unit, 419 Interference amount measurement unit, 420 TFRI reception unit, 421 decoding unit, 422 response signal transmission unit, 423 base station total interference amount prediction unit, 424 terminal transmission power margin transmission unit, 425 timing management unit, 500 terminal, 511 demodulation unit 518 Timing management unit, 519 Margin receiving unit, 520 transmission determining unit, 521 response signal receiving unit, 522 transmission data buffer for uplink packet communication, 523 TFRI transmission processing unit, 524 EUDTCH transmission processing unit, 600 base station, 611 demodulating unit, 619 transmission buffer amount receiving unit 620 TFRI reception unit, 621 decoding unit, 622 response signal generation unit, 623 scheduler for uplink packet communication, 624 subframe allocation information creation unit, 625 timing management unit, 626 variable frame control unit, 700 terminal, 711 demodulation unit, 718 Timing management unit, 719 subframe position / transmission margin receiving unit, 720 transmission determining unit, 721 response signal receiving unit, 722 transmission data buffer for uplink packet communication, 723 TFRI transmission processing unit, 724 buffer amount for uplink packet communication Signal processing unit, 725 EUDTCH transmission processing unit.

Claims (37)

A base station that receives a downlink packet response signal for downlink packet data from a terminal via a control channel and receives uplink packet data transmitted by a plurality of subframes via a time division multiplexing channel,
A first transmission schedule for causing the terminal to transmit the plurality of subframes on the time division multiplexing channel at an intermittent transmission timing across at least one non-transmission period; and the non-transmission period and the terminal Setting a transmission timing overlapping with a transmission period of the downlink packet response signal from the scheduling unit, and generating a second transmission schedule for the downlink packet data transmission based on the transmission timing;
A base station comprising: a transmission unit that transmits the downlink packet data according to the second transmission schedule created by the scheduling unit, and transmits schedule information of the first transmission schedule to the terminal. The scheduling unit includes a downlink packet communication scheduling unit that schedules downlink packet communication,
An uplink packet communication scheduling unit for scheduling uplink packet communication;
A schedule communication unit for connecting the downlink packet communication scheduling unit and the uplink packet communication scheduling unit;
The downlink packet communication scheduling unit determines the transmission timing of the downlink packet response signal so as not to coincide with the transmission timing of the uplink packet data notified from the uplink packet communication scheduling unit via the schedule communication unit,
The uplink packet communication scheduling unit determines the transmission timing of the uplink packet data so as not to coincide with the transmission timing of the downlink packet response signal notified from the downlink packet communication scheduling unit via the schedule communication unit. The base station according to claim 1.   When it is determined that the transmission timing of the uplink packet data and the downlink packet response signal overlap each other, the scheduling unit transmits the uplink packet data so that the transmission timings of both do not overlap. 3. The base station according to claim 1, wherein timing is determined. A base station used in a communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
When the transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station overlap, A variable frame control unit for determining a transmission frame length of the uplink packet data so as to avoid duplication of transmission timing of the uplink packet data and the downlink packet response signal;
A base station that receives uplink packet data from the terminal based on the determined frame length.   5. The base station according to claim 4, wherein the variable frame control unit determines a transmission frame length of the uplink packet data using a terminal-specific variable relating to use of the downlink packet response signal transmission channel.   6. The base station according to claim 5, wherein the variable frame control unit uses the number of repetitions of downlink packet response signal transmission from the terminal as a variable unique to the terminal.   6. The base station according to claim 5, wherein the variable frame control unit uses an offset value of transmission power of the downlink packet response signal of the terminal as a variable unique to the terminal.   If the variable frame control unit determines that the transmission timing of the uplink packet data and the downlink packet response signal overlap and thus exceeds the transmittable power of the terminal, the variable packet control unit prevents the uplink packet data from overlapping with each other. The base station according to any one of claims 4 to 7, wherein a transmission frame length is determined.   The uplink packet data from the terminal is received based on the transmission frame length determined by the terminal, and the uplink packet data from the terminal is received based on the transmission frame length. The base station according to any one of the above. A terminal that transmits uplink packet data transmitted to a base station using a time division multiplexing channel shared with other terminals,
A receiving unit for receiving downlink packet data from the base station;
Transmitting a plurality of subframes for transmitting uplink data to the base station using the time division multiplexing channel, and transmitting a downlink packet response signal for the downlink packet data using a control channel;
The transmission unit controls transmission timing, instructs transmission of the plurality of subframes at an intermittent timing with at least one non-transmission period interposed therebetween, and transmits the downlink packet response signal of the downlink packet response signal. A terminal including a transmission control unit that instructs transmission at a timing at which transmission occurs during the non-transmission period.   The transmission control unit calculates the transmission timing of the downlink packet response signal to be transmitted to the base station from the transmission timing of the downlink packet control signal received from the base station, and the transmission timing of the downlink packet response signal and the uplink packet data overlap. The terminal according to claim 10, wherein a transmission timing of the uplink packet data is determined so as not to become.   When it is determined that the transmission timing of the uplink packet data and the downlink packet response signal overlap each other, the transmission control unit exceeds the transmittable power of the terminal, so that the transmission timing of both packets does not overlap. 12. The terminal according to claim 10, wherein transmission timing is determined. A terminal used in a communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
When the transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station overlap, A variable frame control unit for determining a transmission frame length of the uplink packet data so as to avoid duplication of transmission timing of the uplink packet data and the downlink packet response signal;
A terminal characterized by transmitting the uplink packet data to a base station using the determined frame length.   The terminal according to claim 13, wherein the terminal transmits the uplink packet data by notifying a base station of a transmission frame length of the uplink packet data determined by the variable frame control unit.   The terminal according to claim 13 or 14, wherein the variable frame control unit determines a transmission frame length of uplink packet data using a terminal-specific variable related to use of a downlink packet response signal transmission channel.   The terminal according to claim 15, wherein the variable frame control unit uses the number of repetitions of downlink packet response signal transmission from the terminal as a variable unique to the terminal.   The terminal according to claim 15, wherein the variable frame control unit uses an offset value of transmission power of the downlink packet response signal of the terminal as a variable unique to the terminal.   If the variable frame control unit determines that the transmission timing of the uplink packet data and the downlink packet response signal overlap and thus exceeds the transmittable power of the terminal, the variable packet control unit prevents the uplink packet data from overlapping with each other. The terminal according to any one of claims 13 to 17, wherein a transmission frame length is determined. A terminal used in a communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
When the transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station overlap, In order to avoid duplication of the transmission timing of the upstream packet data and the downstream packet response signal, the variable frame control unit that provides a transmission off section in the transmission frame of the upstream packet data,
A terminal that transmits the uplink packet data to a base station using the adjusted frame.   If the variable frame control unit determines that the transmission timing of the uplink packet data and the downlink packet response signal overlap and thus exceeds the transmittable power of the terminal, the variable packet control unit prevents the uplink packet data from overlapping with each other. 20. The terminal according to claim 19, wherein a transmission off section is provided in the transmission frame. A terminal that transmits uplink packet data transmitted to a base station using a time division multiplexing channel shared with other terminals,
A receiving unit for receiving downlink packet data from the base station;
Transmitting a plurality of subframes for transmitting uplink packet data to the base station using the time division multiplexing channel, and transmitting a downlink packet response signal for the downlink packet data using a control channel;
In the first transmission section in which the uplink packet data and the downlink packet response signal are transmitted at different timings, the transmission power of the uplink packet data is controlled by the transmission unit, and the uplink packet data and the downlink packet response signal are simultaneously transmitted. And a control unit that reduces the transmission power of the uplink packet data from the first transmission interval in a second transmission interval in which the transmission occurs.   The terminal according to claim 21, wherein the control unit reduces the coding rate of uplink data when simultaneous transmission occurs.   The control unit further controls the transmission power of the downlink packet response signal in the first transmission interval, and decreases the transmission power of the downlink packet response signal in the second transmission interval from the first transmission interval. The terminal according to claim 21. A communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
The transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station do not overlap. A communication system in which the base station determines a transmission timing and notifies the terminal, and the terminal performs transmission to the base station according to the notified transmission timing. A communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
The transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station do not overlap. A communication system in which the terminal determines a transmission timing of the uplink packet data and notifies the base station, and the terminal performs transmission to the base station according to the determined transmission timing.   When it is determined that the transmission power of the terminal exceeds the transmission timing of the uplink packet data and the downlink packet response signal, the transmission timing is determined so that the transmission timing of both does not overlap The communication system according to claim 24 or 25. A communication system in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
When the transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station overlap, The terminal determines the transmission frame length of the uplink packet data so as to avoid the duplication of the transmission timing of the uplink packet data and the downlink packet response signal, and the terminal notifies the determined transmission frame length to the base station. A communication system that transmits the uplink packet data.   The base station acquires the transmission frame length of the uplink packet data by performing the same processing as the terminal instead of receiving a notification of the transmission frame length of the uplink packet data from the terminal. Communication system.   29. The communication system according to claim 27 or claim 28, wherein a transmission frame length of the uplink packet data is determined using a terminal-specific variable relating to use of a downlink packet response signal transmission channel.   If it is determined that the transmission timing of the uplink packet data and the downlink packet response signal overlaps and exceeds the transmittable power of the terminal, the transmission frame length of the uplink packet data is determined so that the transmission timing of both does not overlap 30. The communication system according to any one of claims 27 to 29, wherein: A communication method in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
The transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station do not overlap. A communication method in which the base station determines a transmission timing and notifies the terminal, and the terminal performs transmission to the base station according to the notified transmission timing. A communication method in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
The transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station do not overlap. A communication method in which the terminal determines a transmission timing of the uplink packet data and notifies the base station, and the terminal performs transmission to the base station according to the determined transmission timing.   When it is determined that the transmission power of the terminal exceeds the transmission power of the uplink packet data and the downlink packet response signal, the transmission timing is determined so that the transmission timing of both does not overlap The communication method according to claim 31 or claim 32. A communication method in which downlink packet communication from a base station to a terminal and uplink packet communication from the terminal to the base station can occur simultaneously,
When the transmission timing of the downlink packet response signal that the terminal transmits to the base station in response to the downlink packet communication from the base station and the transmission timing of the uplink packet data that the terminal transmits to the base station overlap, The terminal determines the transmission frame length of the uplink packet data so as to avoid the duplication of the transmission timing of the uplink packet data and the downlink packet response signal, and the terminal notifies the determined transmission frame length to the base station. A communication method characterized by transmitting the uplink packet data.   The base station acquires the transmission frame length of the uplink packet data by performing the same processing as the terminal instead of receiving a notification of the transmission frame length of the uplink packet data from the terminal. Communication method.   36. The communication method according to claim 34 or claim 35, wherein the transmission frame length of the uplink packet data is determined using a terminal-specific variable related to use of the downlink packet response signal transmission channel.   If it is determined that the transmission timing of the uplink packet data and the downlink packet response signal overlaps and exceeds the transmittable power of the terminal, the transmission frame length of the uplink packet data is determined so that the transmission timing of both does not overlap 37. The communication method according to any one of claims 34 to 36, wherein the communication method is performed.

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