JP4182415B2 - Scheduling processing apparatus in radio access system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a scheduling processing device, and in particular, in a high-speed packet radio access system, transmission of packet data shared by a plurality of user terminals (for example, mobile stations) from a radio base station to each user terminal (for example, mobile station). The present invention relates to a scheduling processing apparatus for assigning packet data addressed to each user to a downlink shared channel used for the network.
[0002]
With the rapid spread of the Internet in recent years, the diversification of information, and the increase in capacity, in the field of mobile communications, it is urgent to develop a radio access method with a high-speed information transmission bit rate exceeding 2 Mbps. In particular, in the downlink for transmitting packet data from the network side to the user terminal (mobile station) side, it is frequently performed to download information data such as images, a large amount of file data and video from a database or a website, High-speed and large-capacity traffic is increasing. Therefore, a high-speed packet transmission technique adapted to the increasing data traffic is indispensable.
[0003]
In a mobile communication system using a W-CDMA (Wide Band Code Division Multiple Access) method, information data is transmitted using an individual channel assigned to each communicator (user). In a high-speed packet radio access system, packet data is transmitted. A downlink shared channel (HS-DSCH) shared by a plurality of users is used as a transmission channel, and a plurality of communicators (users) are accessed through the shared channel.
[0004]
This shared channel is used by assigning packet data transmission timing to each user terminal (mobile station) by time division. For this reason, scheduling for assigning packet data transmission timing to each user terminal (mobile station) is indispensable. This scheduling process is executed for the purpose of improving the throughput of the entire cell, which is one radio zone, and maintaining the fairness of allocation among users.
[0005]
[Prior art]
A general scheduling process in the high-speed packet radio access system will be described. FIG. 22 shows an outline of scheduling of transmission timing assignment of high-speed packet data in the downlink channel. In FIG. 22, packet data addressed to each user terminal (mobile station) # 1, # 2, # 3 arrives from the network side (not shown), and is received for each user terminal (mobile station) # 1, # 2, # 3. And each queue buffer (Queue Buffer) for each transmission priority.
[0006]
The scheduler of the radio base station (BTS) selects one queue from the queue, extracts one packet data, assigns the extracted packet data to one shared channel in a time division manner, and transmits the same. On the other hand, the user terminal (mobile station) side is notified of the timing at which packet data addressed to itself is transmitted via another channel, receives only the packet data at that timing from the shared channel, and captures packet data addressed to itself. .
[0007]
FIG. 23 shows the relationship between the associated dedicated channel and the shared channel between the radio base station and the user terminal (mobile station). The associated dedicated channel is a channel that is always assigned to each user who performs high-speed packet radio access. FIG. 23 shows an example in which the associated dedicated channels are allocated to user # 1 and user # 2. Control information for transmitting packet data is notified through the accompanying dedicated channels (a) and (b).
[0008]
Packet data of information content to an actual user is transmitted by a shared channel shared by a plurality of users by time division. In the example of FIG. 23, user # 1 and user # 2 use the shared channel (c). Scheduling of transmission timing allocation to each user in the shared channel (c) is performed by the radio base station. The scheduling is performed based on priority information of transmission packet data designated from an upper layer of the network, information on air (wireless) environment reported from a user terminal (mobile station), and the like.
[0009]
Here, the compression mode will be described. In order to perform a so-called inter-frequency handover between the user terminal (mobile station) and the radio base station for switching to a radio signal of another frequency different from the frequency being communicated, other different frequency radio signals Quality measurement is required.
[0010]
For a single receiver user terminal (mobile station) that receives only a single frequency radio signal and does not receive a radio signal of a different frequency at the same time, the user equipment (mobile station) ) Measures the quality of radio signals of different frequencies during the transmission stop period. As described above, a mode for stopping transmission in a certain timing section is referred to as a compressed mode, and the transmission stop section is referred to as GAP. There are three types of compressed modes in which transmission stop sections are provided only on the downlink, only the uplink, and both the upper and lower lines.
[0011]
FIG. 24 shows the relationship between the accompanying dedicated channel and the shared channel in the compressed mode. The accompanying individual channel has a compressed mode like a normal individual channel. (A) of the figure shows the timing of the transmission stop period (GAP) of the accompanying dedicated channel for user # 1, and (b) of the figure shows the timing of the transmission stopping period (GAP) of the accompanying dedicated channel of user # 2. Is shown.
[0012]
The timing position of the transmission stop period (GAP) of the associated individual channel is a position determined in advance for each user. On the other hand, as shown in FIG. 24C, the transmission timing of the packet data addressed to each user terminal (mobile station) to the shared channel is assigned by the scheduler regardless of the transmission stop period (GAP) of the associated dedicated channel. .
[0013]
Therefore, as in the example shown in FIG. 24C, packet data addressed to the user # 1 is allocated in the transmission timing interval T2 of the shared channel, and the timing is just the transmission stop interval ( GAP). Similarly, the transmission timing period T4 to which the packet data addressed to the user # 2 is allocated may overlap with the transmission stop period (GAP) of the associated dedicated channel of the user # 2.
[0014]
As described above, the processing operation at the user terminal (mobile station) for the packet data in the transmission timing sections T2 and T4 that overlaps the transmission stop section (GAP) of the associated dedicated channel is the shared channel transmitted in the sections T2 and T4. Since the packet data is ignored and the data is discarded, a response indicating normal reception is not returned. As a result, the packet data is transmitted after being scheduled again from the radio base station.
[0015]
Next, the relationship between the uplink dedicated control channel and the shared channel will be described. FIG. 25 shows the relationship between the uplink dedicated control channel and the shared channel. The uplink dedicated control channels shown in (a) and (b) of the figure are uplink channels corresponding to the associated dedicated channels, and the packet data transmitted through the shared channel can be transmitted without error at the user terminal (mobile station). It is used for returning confirmation information (ACK / NACK) indicating whether or not the signal has been normally received.
[0016]
The timing for returning the confirmation information (ACK / NACK) is defined to be returned after a predetermined time t (s) with respect to the transmission timing position of the packet data of the shared channel. As shown in FIG. The confirmation information (ACK / NACK) for the packet data addressed to the user # 2 assigned to the shared channel timing section T1, as shown in FIG. 4B, is the user # after the elapse of time t (s) from the timing section T1. 2 uplink dedicated control channels.
[0017]
Also, the confirmation information (ACK / NACK) for the packet data addressed to the user # 1 assigned to the shared channel timing section T2 is shown after the elapse of time t (s) from the timing section T2, as shown in FIG. It is placed on the uplink dedicated control channel of user # 1.
[0018]
FIG. 26 shows the relationship between the uplink dedicated control channel and the shared channel in the compressed mode. In the compressed mode, each user terminal (mobile station) stops transmission of the uplink dedicated control channel in the same timing section (GAP) as the associated dedicated channel.
[0019]
Therefore, as shown in (a) and (b) of FIG. 26, the transmission stop period (GAP) of the uplink dedicated control channel in the compressed mode and confirmation information (ACK / NACK) for the packet data of the shared channel are transmitted. The user terminal (mobile station) does not transmit the confirmation information (ACK / NACK) when the timing to be overlapped.
[0020]
Therefore, the scheduler on the radio base station side determines that the packet data of the shared channel has not been normally received on the user terminal (mobile station) side by not receiving the ACK confirmation signal, and has already transmitted the packet. The data is retransmitted even though it is normally received on the user terminal (mobile station) side.
[0021]
The following documents are listed as prior art documents related to the present invention. The one described in Patent Document 1 described below is configured to control the synchronization of transmission order such as packet numbers between base stations while allowing the base stations to have a scheduling function. Patent Document 2 describes, in paragraph 0099 and the like, a technique that makes it possible to receive another carrier by adjusting the transfer time for symbols even in the compressed mode.
[0022]
Patent Document 3 describes a transmitter that can insert dummy bits in accordance with an interleaver to be used and a receiver thereof so that the positions of dummy bits in the compressed mode are optimized. Patent Document 4 describes a technique for determining the number of gap generation bits to be used in interleaving and distributing the effect of gap generation over an interleaving cycle.
[0023]
Non-Patent Documents 1 and 2 listed below return a technique for transmitting high-speed packet data on a shared channel (HDPA: High Speed Downlink Packet Access), and Non-Patent Document 3 returns confirmation information (ACK / NACK). Non-Patent Document 4 describes the standard of the compression mode regarding the retransmission when it is not performed.
[0024]
[Patent Document 1]
JP 2002-26919 A
[Patent Document 2]
JP 2002-300083 A
[Patent Document 3]
JP 2000-332618 A
[Patent Document 4]
JP 2002-135216 A
[Non-Patent Document 1]
3GPP TS25.308 Ver. 5.2.0 World Standard Specification for Third Generation Mobile Communications
[Non-Patent Document 2]
3GPP TS25.321 Ver. 5.1.0 World Standard Specification for Third Generation Mobile Communications
[Non-Patent Document 3]
3GPP TS25.214 Ver. 5.1.0 World Standard Specification for Third Generation Mobile Communications
[Non-Patent Document 4]
3GPP TS25.212 Ver. 5.2.0 World Standard Specification for Third Generation Mobile Communications
[0025]
[Problems to be solved by the invention]
As described above, the conventional scheduling process includes the transmission stop period (GAP) of the associated dedicated channel for each user terminal (mobile station), the transmission allocation timing of the shared channel for packet data addressed to the user terminal (mobile station), and Since the user terminal (mobile station) interrupts the reception of the currently received packet data and discards the packet data received so far, the total throughput is reduced. It will fall.
[0026]
In addition, when the timing for transmitting the confirmation information (ACK / NACK) in the uplink dedicated control channel and the timing of the transmission stop period (GAP) of the uplink dedicated control channel in the compressed mode overlap, the ACK confirmation information may be returned. Since this is not possible, retransmission processing of packet data that is not necessary originally occurs, and in this case as well, the overall throughput is reduced.
[0027]
The present invention improves throughput by reducing the number of occurrences of discarding of downlink packet data transmitted on a shared channel in the compressed mode, and further, the transmission stop period (GAP) of the uplink dedicated control channel and confirmation information ( It is an object of the present invention to avoid an increase in the number of retransmissions of packet data of a shared channel and increase the throughput by overlapping the transmission timing of (ACK / NACK) and making it impossible to return an ACK confirmation signal.
[0028]
[Means for Solving the Problems]
The scheduling processing apparatus in the radio access system of the present invention is (1) shared with a plurality of user terminals, and is used for a downlink shared channel used for transmission of packet data from a radio base station to each user terminal. In the scheduling processing apparatus for allocating the packet data, when transmission of the associated individual channel corresponding to each user terminal is stopped for each timing interval determined in advance for each user terminal, information on the transmission suspension period of the associated individual channel is obtained. Based on this, the packet data addressed to the user terminal in the downlink shared channel that overlaps the transmission stop period of the associated dedicated channel is excluded, and the packet data addressed to each user terminal is assigned to the downlink shared channel. is there.
[0029]
In addition, (2) a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal; When the uplink individual control channel corresponding to each user terminal that transmits the reception confirmation information of the packet data of the downlink shared channel from the user terminal to the radio base station is stopped at every predetermined timing interval for each user terminal Based on the information on the transmission stop period of the uplink dedicated control channel, the transmission timing of the confirmation information for the packet data addressed to the user terminal on the downlink shared channel overlaps with the transmission stop period of the uplink dedicated control channel Exclude packet data addressed to each user terminal Those having means for assigning packet data to the downlink shared channel.
[0030]
(3) The means for allocating packet data addressed to the user terminal to the downlink shared channel obtains information on the transmission stop period of the associated individual channel from each user terminal, and obtains the associated dedicated channel obtained from the user terminal. Based on the information of the transmission stop period, the packet data addressed to the user terminal in the downlink shared channel overlapping the transmission stop period of the associated dedicated channel is excluded, and the packet data addressed to each user terminal is assigned to the downlink shared channel Is.
[0031]
Further, (4) in a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal. A host device that controls the flow rate of packet data to the downlink shared channel, the host device obtains information on transmission stop of the downlink associated dedicated channel corresponding to each user terminal from the radio base station, and the associated dedicated channel Means for limiting the flow rate of packet data addressed to a user terminal whose transmission is stopped for each predetermined timing section is provided.
[0032]
Further, (5) in a scheduling processing device that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal. A host device that controls the flow rate of packet data to the downlink shared channel, the host device obtains information on transmission stop of the downlink associated dedicated channel corresponding to each user terminal from the radio base station, and the associated dedicated channel The packet data addressed to the user terminal whose transmission is stopped periodically at predetermined timing intervals is the same as or an integer multiple of the cycle of the transmission stop interval of the associated individual channel, and the associated individual channel Means for transmitting to the radio base station at a timing position different from the transmission stop section is provided.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block diagram of a scheduling processing apparatus according to the first embodiment of this invention. In the first embodiment of the present invention, the transmission stop information of each associated individual channel is transmitted from the individual channel call setting control block 1-3 that performs call setting control of the associated individual channel for each user terminal (mobile station) to the scheduler 1-. Pass to 2.
[0034]
The scheduler 1-2 originally uses the shared channel based on the air (wireless) state reported from the user terminal (mobile station) and the priority of the packet data designated by the higher-level device. Mobile station) and scheduling of the transmission timing of packet data stored in the queue buffer 1-1. The information for stopping transmission of the associated dedicated channel in the compressed mode is added to the original scheduling information, and the scheduler 1-2 performs scheduling by adding the transmission stop information of the associated dedicated channel.
[0035]
By adding the transmission stop information of the associated dedicated channel to the original scheduling information, the scheduler 1-2 can recognize the timing of the transmission stop period (GAP) of the associated dedicated channel in advance. Scheduling is performed so that the transmission stop timing (GAP) of the associated dedicated channel for each user terminal (mobile station) does not overlap with the transmission timing of the shared channel assigned to the user terminal (mobile station).
[0036]
Since the transmission stop period (GAP) of the associated individual channel of each user terminal (mobile station) and the transmission timing of the shared channel assigned to the user terminal (mobile station) do not overlap, the packet data transmitted on the shared channel is the user terminal The number of discards at the (mobile station) can be reduced, and the throughput can be improved.
[0037]
FIG. 2 is a block diagram of a scheduling processing apparatus according to the second embodiment of this invention. In the second embodiment of the present invention, transmission stop information of each uplink dedicated control channel is passed to the scheduler 2-2 from the dedicated channel call setting control unit 2-3 that performs call setting of the uplink dedicated control channel.
[0038]
The scheduler 2-2 originally uses the shared channel based on the air (wireless) state reported from the user terminal (mobile station) and the priority information of the packet data designated by the host device. The transmission timing of the packet data allocated to the terminal (mobile station) and stored in the queue buffer 2-1 is scheduled. In addition to the original scheduling information, transmission stop information of the uplink dedicated control channel in the compressed mode is added, and the scheduler 2-2 performs scheduling in consideration of the transmission stop information of the uplink dedicated control channel.
[0039]
By adding the transmission stop information of the uplink dedicated control channel to the original scheduling information, the scheduler 2-2 may recognize the timing of the uplink dedicated control channel transmission stop section (GAP) in advance. The transmission stop period (GAP) of the uplink individual control channel for each user terminal (mobile station), and the transmission timing of the confirmation information (ACK / NACK) for the packet data of the shared channel from the user terminal (mobile station) Scheduling of the transmission timing of packet data addressed to each user terminal (mobile station) is performed so that there is no overlap.
[0040]
By performing scheduling in this way, the number of times that confirmation information (ACK / NACK) cannot be returned from the user terminal (mobile station) for the packet data transmitted on the shared channel is reduced, and the number of retransmission processing of packet data on the shared channel is reduced. Can be reduced and the throughput can be improved.
[0041]
【Example】
FIG. 3 shows a block and flowchart of the first embodiment of the present invention. This example is an example of the first embodiment of the present invention described above. (A) of the figure shows the functional block, and (b) of the figure shows the processing flow. The scheduler 3-2 is a block that sequentially selects one packet data from the packet data stored in the queue buffer 3-1, and allocates it to the shared channel.
[0042]
The scheduler 3-2 includes transmission information (GAP) timing information of the associated dedicated channel, priority information for each queue designated by the host device, air (wireless) environment information for each user terminal (mobile station), and the like. The packet data to be allocated to the shared channel is determined and selected based on the scheduling determination factor information including
[0043]
FIG. 3B shows a processing flow of a procedure for selecting packet data to be allocated to the shared channel. First, user information and queue information of packet data stored in the queue buffer 3-1 are obtained (step S31). A specific example of user information and queue information is shown in the information table of Table 1 in FIG. The user information and queue information in the information table of Table 1 are updated every time after the scheduler 3-2 selects packet data.
[0044]
The information table of Table 1 in FIG. 4 includes item numbers given in the order of packet data input, destination user terminal (mobile station) information of the packet data, queue information of the queue storing the packet data, Holding. Each packet data is stored in each queue corresponding to the priority according to the priority.
[0045]
Next, as shown in the flowchart of FIG. 3B, the transmission stop section (GAP) information of the downlink associated dedicated channel for each user is obtained from the block that controls call setting (step S32). Table 2 in FIG. 4 shows a specific example of the information table of the transmission stop period (GAP) of the downlink associated dedicated channel. The scheduler 3-2 first excludes the users in the transmission suspension section (GAP) of the downlink associated dedicated channel overlapping with the timing for assigning transmission from the scheduling selection targets (step S33).
[0046]
From the remaining packet data addressed to the user terminal (mobile station), the air (wireless) environment reported from the user terminal (mobile station), the priority specified by the host device, etc. are used as an index to the shared channel. The packet data to be allocated is selected and determined (step S34). Table 3 in FIG. 5 shows a specific example of an air (wireless) environment information table, and Table 4 shows a specific example of a priority information table.
[0047]
FIG. 6 shows a scheduling timing chart of the first embodiment of the present invention. The scheduling process for the transmission timing T1 of the shared channel is performed in order as described above. First, the user information and queue information of the packet data stored in the queue buffer are ascertained from the information table of Table 1 in FIG. 4, and the user terminal ( The mobile station) obtains transmission stop section (GAP) information of the downlink associated dedicated channel for each user, and excludes user # 3 whose transmission timing T1 is in the transmission stop section (GAP) from the scheduling selection targets.
[0048]
Next, since the user # 2 is in the best state from the air (wireless) environment information table of Table 3 in FIG. 5, the user # 2 is selected, and the user # 2 is selected from the priority information table of Table 4. Since the queue of queue number # 0 in the packet data has the highest priority, the packet data of queue # 0 of user # 2 is selected. By such a scheduling procedure, the transmission timing of the packet data assigned to the shared channel does not overlap with the transmission stop period (GAP) of the downlink associated dedicated channel of the destination user terminal (mobile station).
[0049]
Similarly, the transmission timings T2, T3, and T4 are also scheduled according to the above-described processing procedure, so that the packet data addressed to each user terminal (mobile station) assigned to the shared channel is transmitted to the transmission timing and each user terminal (mobile The transmission stop section (GAP) of the downlink associated dedicated channel of the station does not overlap.
[0050]
FIG. 6 shows an example in which the packet data of queue # 0 of user # 3 is selected at transmission timing T2 in FIG. 6, and this transmission timing T2 is not the transmission stop section (GAP) of the downlink associated dedicated channel of user # 3. It is shown that. The same applies to transmission timings T3 and T4. Note that at the transmission timings T2, T3, and T4, the information contents in Tables 1 to 4 shown in FIGS. 4 and 5 respectively change from time to time and are different from those at the transmission timing T1. Scheduling is performed according to the contents of the new table information.
[0051]
FIG. 7 shows a block diagram and a flowchart of the second embodiment of the present invention. This example is an example of the above-described second embodiment of the present invention. (A) of the figure shows the functional block, and (b) of the figure shows the processing flow. The scheduler 7-2 is a block that sequentially selects one packet data from the packet data stored in the queue buffer 7-1 and allocates it to the shared channel.
[0052]
The scheduler 7-2 includes the timing information of the transmission stop period (GAP) of the uplink dedicated channel, priority information for each queue designated by the host device, and air (wireless) environment information for each user terminal (mobile station), etc. The packet data to be allocated to the shared channel is determined and selected based on the scheduling determination factor information including
[0053]
FIG. 7B shows a processing flow of a procedure for selecting packet data to be allocated to the shared channel. First, user information and queue information of packet data stored in the queue buffer 7-1 are obtained (step S71). A specific example of user information and queue information is shown in the information table of Table 5 in FIG. The user information and queue information in Table 5 are updated every time after the scheduler 7-2 selects packet data.
[0054]
The information table of Table 5 in FIG. 8 holds the item numbers given in the input order of packet data, destination user terminal (mobile station) information of the packet data, and queue information in which the packet data is stored. is doing. Each packet data is stored in each queue corresponding to the priority according to the priority.
[0055]
Next, as shown in the flowchart of FIG. 7B, transmission stop section (GAP) information of the uplink dedicated control channel for each user is obtained from the block that controls call setting (step S72). Table 6 in FIG. 8 shows a specific example of the transmission stop period (GAP) information of the uplink dedicated control channel. The scheduler 7-2 first excludes a user whose time after the elapse of a predetermined time t (s) from the timing at which transmission is assigned is a transmission stop section (GAP) of the uplink dedicated channel from the scheduling selection targets (step S73).
[0056]
Here, the predetermined time t (s) is confirmation information (ACK / NACK) whether or not the packet data is received without error at the user terminal (mobile station) after transmission of the packet data assigned to the shared channel. Is the elapsed time until is returned.
[0057]
From the remaining packet data addressed to the user terminal (mobile station), the air (wireless) environment reported from the user terminal (mobile station), the priority specified by the host device, etc. are used as an index to the shared channel. The packet data to be allocated is selected and determined (step S74). Table 7 in FIG. 9 shows a specific example of an air (wireless) environment information table in this embodiment, and Table 8 shows a specific example of a priority information table in this embodiment.
[0058]
FIG. 10 shows a scheduling timing chart of the second embodiment of the present invention. The scheduling process for the transmission timing T1 of the shared channel is performed as described above. First, the user information and queue information of the packet data stored in the queue buffer are ascertained from the information table of Table 5 in FIG. 8, and the user terminal is determined from the transmission stop section (GAP) information of the uplink dedicated control channel in Table 6. (Mobile station) The transmission stop section (GAP) information of the uplink dedicated control channel is acquired and the timing after the elapse of a predetermined time t (s) from the timing of assigning transmission is the transmission stop section (GAP) of the uplink dedicated channel. Are excluded from the scheduling targets. Here, the user # 1 is excluded from the scheduling at the timing T1.
[0059]
From the remaining users, the packet data of the user number and queue number to be assigned to the shared channel is determined using the air (wireless) environment reported by the user, the priority information of the packet data specified from the top, etc. as indices. Specifically, the user # 2 is selected based on the air (wireless) environment information in Table 7, and the queue # 0 is selected based on the priority information in Table 8.
[0060]
Due to such scheduling, the return timing of the confirmation information (ACK / NACK) of the packet data allocated to the shared channel is the same as the transmission stop period (GAP) of the uplink dedicated control channel of the destination user terminal (mobile station). There is no overlap.
[0061]
FIG. 11 shows a block diagram and a flowchart of the third embodiment of the present invention. This example is an example in which the above-described first embodiment of the present invention is applied to scheduling at the time of retransmission data transmission. (A) of the figure shows the functional block, and (b) of the figure shows the processing flow. The scheduler 11-2 is a block that sequentially selects one packet data from the packet data stored in the queue buffer 11-1 and allocates it to the shared channel.
[0062]
The scheduler 11-2 includes timing information of the transmission stop period (GAP) of the associated dedicated channel, priority information for each queue designated by the host device, air (wireless) environment information for each user terminal (mobile station), etc. The scheduler 11-2 determines and selects packet data to be allocated to the shared channel based on the information.
[0063]
FIG. 11B shows a processing flow of a procedure for selecting packet data to be allocated to the shared channel. First, user information and queue information of packet data stored in the queue buffer 11-1 are obtained (step S111). A specific example of user information and queue information is shown in the information table of Table 9 in FIG. The user information and queue information in Table 9 are updated every time after the scheduler 11-2 selects packet data.
[0064]
The radio base station receives confirmation information (ACK / NACK) for transmission packet data as retransmission control information from the user terminal (mobile station) side. A specific example of the information table storing the confirmation information (ACK / NACK) for each user is shown in the information table of Table 10 in FIG. The scheduler 11-2 selects new packet data or retransmission packet data as the packet data to be transmitted next (step S112).
[0065]
Next, transmission stop section (GAP) information of the downlink associated dedicated channel is obtained for each user from the block that controls call setting (step S113). A specific example of the transmission stop section (GAP) information of the downlink associated dedicated channel is shown in the information table of Table 11 in FIG. The scheduler 11-2 first excludes the users in the transmission suspension section (GAP) of the downlink associated dedicated channel overlapping with the timing for assigning transmission from the scheduling selection targets (step S114).
[0066]
From the remaining packet data addressed to the user terminal (mobile station), the air (wireless) environment reported from the user terminal (mobile station), the priority specified by the host device, etc., are used as an index for the shared channel. The packet data to be allocated is selected and determined (step S115). Table 12 in FIG. 13 shows a specific example of an air (wireless) environment information table, and Table 13 shows a specific example of a priority information table.
[0067]
FIG. 14 shows a scheduling timing chart of the third embodiment of the present invention. The scheduling process for the transmission timing T1 of the shared channel is performed as described above. First, the user information and queue information of the packet data stored in the queue buffer are grasped from the information table of Table 9 in FIG. Also, retransmission information as shown in the information table of Table 10 is obtained based on confirmation information (ACK / NACK) from the user terminal (mobile station) side, and retransmission packet data is transmitted or new packet data is transmitted. Select whether or not.
[0068]
Next, the transmission stop period (GAP) information of the downlink associated dedicated channel for each user, such as the information table of Table 11, is obtained from the block that controls the call setting, and the transmission timing T1 and the downlink associated dedicated channel to be allocated are allocated. The user # 3 that overlaps with the transmission stop section (GAP) is excluded from the scheduling selection targets.
[0069]
In the first embodiment, only the scheduling process for assigning newly transmitted packet data has been described. However, in the third embodiment, similarly, the retransmission scheduling for packet data that failed to be transmitted for the first time is also transmitted. The retransmission packet data of the user # 3 whose timing T1 is in the transmission stop period (GAP) can be excluded from the scheduling selection targets.
[0070]
Then, among the remaining users, the air (wireless) environment reported from the users as shown in Table 12, priority information specified from the top as shown in Table 13 and the like, are assigned to the shared channel as an index. The number and the queue number are determined, and packet data to be assigned to the transmission timing T1 is determined. By such scheduling, packet data allocated to the shared channel does not overlap the transmission stop period (GAP) of the associated dedicated channel at the same time, whether it is new data or retransmission data.
[0071]
FIG. 15 shows a block diagram and a flowchart of the fourth embodiment of the present invention. In this example, the transmission stop period (GAP) information of the associated dedicated channel in the first embodiment of the present invention described above is obtained from the user terminal (mobile station). (A) of the figure shows the functional block, and (b) of the figure shows the processing flow. The scheduler 15-2 is a block that sequentially selects one packet data from the packet data stored in the queue buffer 15-1 and allocates it to the shared channel.
[0072]
The scheduler 15-2 includes timing information of the transmission stop period (GAP) of the associated dedicated channel, priority information for each queue designated by the host device, air (wireless) environment information for each user terminal (mobile station), and the like. The scheduler 15-2 determines and selects packet data to be allocated to the shared channel based on the information.
[0073]
FIG. 15B shows a processing flow of a procedure for selecting packet data to be allocated to the shared channel. First, user information and queue information of packet data stored in the queue buffer 15-1 are obtained (step S151). A specific example of user information and queue information is shown in the information table of Table 14 in FIG. The user information and queue information in Table 14 are updated every time after the scheduler 15-2 selects packet data.
[0074]
Next, transmission stop section (GAP) information of the downlink associated dedicated channel for each user is obtained from the user terminal (mobile station) side (step S152). A feature of the fourth embodiment resides in that transmission stop section (GAP) information of this downlink associated dedicated channel for each user is obtained from the user terminal (mobile station). A specific example of the transmission stop section (GAP) information of the downlink associated dedicated channel is shown in the information table of Table 15 in FIG. The scheduler 15-2 first excludes the users in the transmission suspension period (GAP) of the downlink associated dedicated channel overlapping with the timing for assigning transmission from the scheduling selection targets (step S153).
[0075]
From the remaining packet data addressed to the user terminal (mobile station), the air (wireless) environment reported from the user terminal (mobile station), the priority specified by the host device, etc. are used as an index to the shared channel. The packet data to be allocated is selected and determined (step S154). Table 16 in FIG. 17 shows a specific example of an air (wireless) environment information table, and Table 17 shows a specific example of a priority information table.
[0076]
FIG. 18 shows a timing chart of scheduling according to the fourth embodiment of the present invention. First, the user information and queue information of the packet data stored in the queue buffer are grasped from the information table of Table 14 in FIG. Next, transmission stop section (GAP) information as shown in Table 15 is obtained from the user terminal (mobile station) side.
[0077]
If the first timing position of the transmission stop section (GAP) of the downlink associated dedicated channel and the period of the transmission stop section (GAP) can be known from the user terminal (mobile station) side, the next transmission stop section (GAP) It is possible to predict the timing position.
[0078]
The packet data addressed to the user where the predicted transmission stop section (GAP) timing position overlaps with the timing position to which transmission packet data is allocated is excluded from the allocation target. When scheduling at the timing T1, the packet data addressed to the user # 3 is excluded. Among the remaining users, using the air environment reported by the user as shown in Table 16 of FIG. 17 and the priority information specified from the top as shown in Table 17 as an index, the user number assigned to the shared channel and Determine the packet data of the queue number. With this scheduling, the packet data assigned to the shared channel does not overlap the transmission stop period (GAP) of the downlink associated dedicated channel with the assigned transmission timing.
[0079]
FIG. 19 shows a block diagram of the fifth embodiment of the present invention. In the figure, a radio network controller (RNC: Radio Network Controller) 19-1 controls the flow rate of packet data sent to a radio base station (BTS) 19-2. First, a request command including the data amount of a packet to be transmitted as shown in the table of Table 18 in FIG. 20 is transmitted from the radio network controller (RNC) 19-1 to the radio base station (BTS) 19-2. .
[0080]
In response to the request command, the radio base station (BTS) 19-2 determines the flow rate of packet data based on the air (radio) transmission status, the queue buffer availability, etc. ) Allocation information including information on the transmission data amount and transmission interval for one time is returned to the block 19-1 as shown in the table of Table 19 in FIG.
[0081]
Further, the flow control block of the radio network controller (RNC) 19-1 is changed from the radio base station (BTS) 19-2 to the transmission stop section (downlink dedicated channel as shown in the table of Table 20 in FIG. By giving (GAP) information, the radio network controller (RNC) 19-1 performs control to reduce the flow rate of packet data transmission addressed to the user in which the transmission stop section (GAP) exists. In the case of the example shown in the table of Table 20, the flow rate of the transmission of packet data for the user # 4 is suppressed.
[0082]
By controlling the scheduling in this way, in the queue buffer on the radio base station (BTS) 19-2 side, the transmission amount of packet data addressed to a user who does not have a transmission stop section (GAP) of the downlink associated dedicated channel increases, The transmission amount of packet data addressed to a user having a stop section (GAP) decreases. In this state, by assigning the packet data accumulated in the queue buffer to the shared channel, the probability that the transmission stop period (GAP) of the associated dedicated channel overlaps the transmission timing of the packet data assigned to the shared channel may be reduced. it can.
[0083]
FIG. 21 shows a block diagram of the sixth embodiment of the present invention. In FIG. 6A, the host device 21-1 controls the transmission interval Tp of downlink packet data. First, from the radio base station (BTS) 21-2 side to the host device 21-1 side, as shown in the information table of Table 21 in FIG. Mode transmission stop interval (GAP) period T _GAP To be notified.
[0084]
The host device 21-1 side sets the transmission interval Tp of the packet data addressed to each user to the period T of the transmission stop period (GAP) of each user. _GAP And the offset T between the packet data transmission timing and the compressed mode transmission stop period (GAP) timing. _OFF To prevent the timing of the transmission stop period (GAP) in the compressed mode from overlapping with the transmission allocation timing of the shared channel (see the timing chart of FIG. 21B).
[0085]
By performing such scheduling, the transmission timing of the transmission packet data allocated to the shared channel does not overlap the transmission stop section (GAP) in the compressed mode. As shown in FIG. 21B, the transmission interval Tp of the packet data addressed to each user corresponding to the associated dedicated channel is set to the period TAP of the transmission stop period (GAP). _GAP The packet data transmission interval Tp is set to the period T of the transmission stop period (GAP). _GAP A similar effect can be obtained even with a configuration that is an integral multiple of. However, the packet data transmission interval Tp is equal to or longer than the time RTD (Round Trip Delay time) required until one packet data reaches from the transmission source to the destination and a response is returned from the transmission destination to the transmission source. .
[0086]
(Supplementary Note 1) In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal. When transmission of the associated dedicated channel corresponding to the user terminal is stopped at each predetermined timing interval for each user terminal, the transmission stop period of the associated dedicated channel is determined based on the information of the transmission stopped period of the associated dedicated channel. A scheduling processing apparatus in a radio access system, comprising means for excluding packet data addressed to a user terminal in a downlink shared channel overlapping with and assigning packet data addressed to each user terminal to the downlink shared channel.
(Supplementary Note 2) In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal. When the uplink individual control channel corresponding to each user terminal that transmits the reception confirmation information of the packet data of the channel shared channel from the user terminal to the radio base station is stopped for each predetermined timing interval for each user terminal, Based on the information on the transmission stop period of the uplink dedicated control channel, the transmission timing of the confirmation information for the packet data addressed to the user terminal on the downlink shared channel is addressed to the user terminal that overlaps with the transmission stop period of the uplink dedicated control channel Packet data is excluded and addressed to each user device. A scheduling processing apparatus in a radio access system, comprising means for allocating packet data to a downlink shared channel.
(Supplementary Note 3) The means for assigning packet data addressed to the user terminal to a downlink shared channel obtains information on the transmission stop period of the associated dedicated channel from each user terminal, and the associated dedicated channel obtained from the user terminal. Based on the information of the transmission stop period, the packet data addressed to the user terminal in the downlink shared channel that overlaps the transmission stop period of the associated dedicated channel is excluded, and the packet data addressed to each user terminal is assigned to the downlink shared channel The scheduling processing apparatus in the wireless access system according to Supplementary Note 1, wherein
(Supplementary Note 4) In a scheduling processing apparatus that assigns packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal. A host device that controls the flow rate of packet data to the channel shared channel, the host device obtains information on the transmission stop of the downlink associated dedicated channel corresponding to each user terminal from the radio base station, and the associated dedicated channel A scheduling processing apparatus in a radio access system, comprising means for limiting a flow rate of packet data addressed to a user terminal whose transmission is stopped for each predetermined timing section.
(Supplementary Note 5) In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal. A host device that controls the flow rate of packet data to the channel shared channel, the host device obtains information on the transmission stop of the downlink associated dedicated channel corresponding to each user terminal from the radio base station, and the associated dedicated channel is periodically The packet data addressed to the user terminal whose transmission is stopped at every predetermined timing interval is transmitted at the same or an integral multiple of the cycle of the transmission stop interval of the associated individual channel, and transmission of the associated individual channel. Radio access characterized by having means for transmitting to the radio base station at a timing position different from the stop period. Scheduling processing device in the access system.
(Supplementary Note 6) In a scheduling processing device that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal, When transmission of the associated dedicated channel corresponding to the user terminal is stopped at each predetermined timing interval for each user terminal, the transmission stop period of the associated dedicated channel is determined based on the information of the transmission stopped period of the associated dedicated channel. A scheduling processing apparatus in a radio access system comprising means for allocating packet data addressed to each user terminal to a downlink shared channel by excluding retransmission packet data addressed to the user terminal in a downlink shared channel overlapping with .
[0087]
【The invention's effect】
As described above, according to the present invention, the transmission timing of the downlink shared channel that is shared by a plurality of user terminals and is used for transmission of packet data from the radio base station to each user terminal can be transmitted to each user. In scheduling control assigned to packet data, scheduling is performed so that the transmission timing of packet data addressed to each user assigned to the downlink shared channel does not overlap the transmission stop section (GAP) of the downlink dedicated channel of the user. As a result, the number of times the packet data transmitted on the shared channel is discarded by the user terminal is reduced, and the throughput can be improved.
[0088]
Further, information on the transmission stop period (GAP) of the uplink dedicated control channel used for transmission of control information from each user terminal to the radio base station is given to the scheduler, and the transmission stop period (GAP) of the uplink dedicated control channel, Transmission is performed on the downlink shared channel by performing scheduling control of the transmission timing of the packet data to be allocated to the downlink shared channel so that the return timing of the confirmation information (ACK / NACK) for the packet data transmitted on the downlink shared channel does not overlap. The number of occurrences of the case where confirmation information (ACK / NACK) for the received packet data is not returned is reduced, the number of packet data retransmissions is reduced, and the throughput can be improved.
[0089]
In addition, the host device that controls the flow rate of packet data to the downlink shared channel transmits the associated dedicated channel for each predetermined timing interval based on the transmission stop information of the downlink associated dedicated channel corresponding to each user terminal. By limiting the flow rate of the packet data addressed to the user terminal that is stopped, the probability of overlapping the timing of assigning the packet data addressed to the user terminal and the transmission stop period of the associated dedicated channel of the user terminal is reduced. The number of times data is discarded at the user terminal is reduced, and the throughput can be improved.
[0090]
In addition, the host apparatus that controls the flow rate of packet data to the downlink shared channel uses a timing interval in which the associated dedicated channel is periodically determined based on information on transmission stoppage of the downlink associated dedicated channel corresponding to each user terminal. The packet data addressed to the user terminal whose transmission is stopped every time is the same as the period of the transmission stop period of the associated individual channel or a cycle that is an integral multiple of the same, and at a timing position different from the transmission stop period of the associated individual channel. By transmitting to the radio base station, the number of times the packet data is discarded at the user terminal (mobile station) is reduced, and the throughput can be improved.
[Brief description of the drawings]
FIG. 1 is a block diagram of a scheduling processing apparatus according to a first embodiment of this invention.
FIG. 2 is a block diagram of a scheduling processing apparatus according to a second embodiment of this invention.
FIG. 3 is a block diagram and a flowchart of the first embodiment of the present invention.
FIG. 4 is a diagram illustrating a specific example of an information table of (Table 1) user information and queue information of packet data, and (Table 2) a transmission stop section (GAP) of a downlink associated dedicated channel.
FIG. 5 is a diagram showing a specific example of (Table 3) air (wireless) environment information and (Table 4) priority information table.
FIG. 6 is a diagram illustrating a timing chart of scheduling according to the first embodiment of this invention.
FIG. 7 is a block diagram and a flowchart of a second embodiment of the present invention.
8 is a diagram showing a specific example of an information table of (Table 5) packet data user information and queue information, and (Table 6) an uplink dedicated control channel transmission stop period (GAP). FIG.
FIG. 9 is a diagram showing a specific example of (Table 7) air (wireless) environment information and (Table 8) priority information table.
FIG. 10 is a diagram illustrating a timing chart of scheduling according to the second embodiment of this invention.
FIG. 11 is a block diagram and a flowchart of a third embodiment of the present invention.
[Table 9] (Table 9) User information and queue information of packet data, (Table 10) Information of confirmation information (ACK / NACK), (Table 11) Information table of transmission stop section (GAP) of downlink associated dedicated channel It is a figure which shows a specific example.
FIG. 13 is a table showing a specific example of (Table 12) air (wireless) environment information and (Table 13) priority information table.
FIG. 14 is a timing chart of scheduling according to the third embodiment of the present invention.
FIG. 15 shows a block diagram and a flowchart of a fourth embodiment of the present invention.
16 is a diagram illustrating a specific example of an information table of (Table 14) packet data user information and queue information, and (Table 15) a transmission stop section (GAP) of a downlink associated dedicated channel.
FIG. 17 is a diagram illustrating a specific example of (Table 16) Air (wireless) environment information and (Table 17) priority information table.
FIG. 18 is a diagram showing a timing chart of scheduling according to the fourth embodiment of the present invention.
FIG. 19 is a diagram showing a block diagram of a fifth embodiment of the present invention.
FIG. 20 is a diagram illustrating a specific example of an information table of (Table 18) request command, (Table 19) allocation information, and (Table 20) a transmission stop section (GAP) of a downlink associated dedicated channel.
FIG. 21 is a block diagram showing a sixth embodiment of the present invention.
FIG. 22 is a diagram showing an outline of scheduling of transmission timing assignment of high-speed packet data in a downlink channel.
FIG. 23 is a diagram illustrating a relationship between an associated dedicated channel and a shared channel between a radio base station and a user terminal (mobile station).
FIG. 24 is a diagram illustrating a relationship between an accompanying dedicated channel and a shared channel in a compressed mode.
FIG. 25 is a diagram illustrating a relationship between an uplink dedicated control channel and a shared channel.
FIG. 26 is a diagram illustrating a relationship between an uplink dedicated control channel and a shared channel in the compressed mode.
[Explanation of symbols]
1-1 Queue buffer
1-2 Scheduler
1-3 Individual channel call setting control block

Claims (5)

In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal,
When transmission of the associated dedicated channel corresponding to each user terminal is stopped at each predetermined timing interval for each user terminal, transmission of the associated dedicated channel is stopped based on the information of the transmission suspended section of the associated dedicated channel. A scheduling processing apparatus in a radio access system comprising means for excluding packet data addressed to a user terminal in a downlink shared channel overlapping with a section and allocating packet data addressed to each user terminal to the downlink shared channel . In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal,
When the uplink individual control channel corresponding to each user terminal that transmits the reception confirmation information of the packet data of the downlink shared channel from the user terminal to the radio base station is stopped at every predetermined timing interval for each user terminal Based on the information on the transmission stop period of the uplink dedicated control channel, the transmission timing of the confirmation information for the packet data addressed to the user terminal on the downlink shared channel overlaps with the transmission stop period of the uplink dedicated control channel A scheduling processing apparatus in a radio access system, comprising means for excluding addressed packet data and allocating packet data addressed to each user terminal to a downlink shared channel. The means for allocating packet data addressed to the user terminal to a downlink shared channel obtains information on the transmission stop period of the associated dedicated channel from each user terminal, and transmits the information on the transmission stop period of the associated dedicated channel obtained from the user terminal. Based on the information, the packet data addressed to the user terminal in the downlink shared channel overlapping the transmission stop period of the associated dedicated channel is excluded, and the packet data addressed to each user terminal is assigned to the downlink shared channel The scheduling processing apparatus in the radio access system according to claim 1. In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal,
A host device that controls the flow rate of packet data to the downlink shared channel, the host device obtains information on transmission stop of the downlink associated dedicated channel corresponding to each user terminal from the radio base station, and the associated dedicated channel A scheduling processing apparatus in a radio access system, comprising means for restricting a flow rate of packet data addressed to a user terminal whose transmission is stopped for each predetermined timing section. In a scheduling processing apparatus that allocates packet data addressed to each user terminal to a downlink shared channel that is shared by a plurality of user terminals and used for transmission of packet data from a radio base station to each user terminal,
A host device that controls the flow rate of packet data to the downlink shared channel, the host device obtains information on transmission stop of the downlink associated dedicated channel corresponding to each user terminal from the radio base station, and the associated dedicated channel The packet data addressed to the user terminal whose transmission is stopped periodically at predetermined timing intervals is the same as or an integer multiple of the cycle of the transmission stop interval of the associated individual channel, and the associated individual channel A scheduling processing apparatus in a radio access system, comprising means for transmitting to a radio base station at a timing position different from a transmission stop period.

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