KR20050011291A - Apparatus and method for requesting scheduling of reverse link in a mobile system - Google Patents

Abstract

PURPOSE: An apparatus and a method for requesting uplink scheduling in a mobile communication system are provided to enhance efficiency of uplink transmission and reception efficiency of uplink data. CONSTITUTION: When MSs(Mobile Stations) simultaneously transmit scheduling request messages(401,411) to a base station during a period starting from the same point T0 to a point T1, each timer thereof is set to have the same value. Accordingly, each timer of the MSs is terminated at the same point T2. Then, each controller of the MSs controls a random number generator to generate a random number, and a transmission time point of a scheduling request message is determined according to the generated random number. If a random number generated from the MS is 1, the MS transmits a scheduling request update message(403) immediately when the timer is terminated. If a random number generated by controlling the random number generator by the controller of the MS(B) is 3, the MS waits for double the time required for transmission of a scheduling request update message, and then, generates and transmits the scheduling request update message at a point(T4). By transmitting the scheduling request update message, the timers of the two MSs are terminated at a different point, so uplink interference can be reduced.

Description

Device and method for requesting reverse scheduling in mobile communication system {APPARATUS AND METHOD FOR REQUESTING SCHEDULING OF REVERSE LINK IN A MOBILE SYSTEM}

The present invention relates to an apparatus and a method for transmitting a signal in a mobile communication system, and more particularly, to an apparatus and a method for transmitting a scheduling request signal for a reverse link in a mobile communication system.

In general, a mobile communication system has been developed to provide a voice call regardless of the user's mobility. However, due to the development of technology and the demands of users, many researches and developments about data services are being conducted. Thanks to these developments, mobile communication systems are being developed that can provide multimedia services as well as voice services.

In a mobile communication system capable of providing such a multimedia service, data is transmitted in a different manner for packet data and voice service. For example, in the case of a voice service, since real-time is very important, it cannot be configured to transmit or stop a voice signal by performing scheduling. However, in the case of data service, whether or not data error occurs is more important than voice service.

Next, a scheduling method for data transmission in such a mobile communication system will be described. In general, a channel used in a mobile communication system has a characteristic of changing from time to time. As such, since the state of the channel changes over time, the base station always needs scheduling to control the data rate according to the state of the channel. That is, in a data communication that is less sensitive to time delay, such as a data service, throughput may be increased through a scheduling method, which is a dynamic resource allocation method that takes full advantage of channel change characteristics over time.

The scheduling method is a technique of allocating more resources to a user having a good state of a channel every predetermined time. This scheduling scheme can be largely divided into a forward link and a reverse link. In the following description, "forward" means the direction from the base station to the mobile station, and "reverse direction" means the direction from the mobile station to the base station.

Therefore, in the case of the forward link, which is the transmission from the base station to the mobile station, the resources that can be allocated by the base station are limited by the transmission power of the base station. On the other hand, in the reverse link, which is a transmission from a mobile station to a base station, resources are limited by the amount of interference. In this case, the interference of the reverse link is caused by transmission signals of mobile stations transmitting in the reverse direction. For example, when a particular mobile station transmits data or a signal at high power for reverse transmission to obtain a high data rate, the base station receiver receiving the signal of the mobile station receives a high power signal at the mobile station. However, in this case, the reverse transmission power acts as interference in other mobile stations except for the mobile station which transmits data or signals at the high power. Therefore, if the mobile station performing the reverse transmission performs data transmission at high power, other mobile stations have a large amount of interference.

If several mobile stations attempt to transmit at high power simultaneously to obtain high data rates, the total amount of interference on the reverse link will increase significantly, which will eventually prevent all mobile stations from achieving the desired call quality. Therefore, the base station should perform efficient resource allocation through a scheduling process for appropriately adjusting the amount of interference. In order to perform the scheduling process, the base station must request scheduling from each mobile station and receive information necessary for scheduling. Next, the scheduling process according to the scheduling request and the information required for the scheduling will be described.

1 is a signal flowchart when a mobile station transmits a scheduling request message to a base station when data to be transmitted is generated. Hereinafter, a scheduling method in a mobile communication system capable of providing a multimedia service will be described in detail with reference to FIG. 1.

If data to be transmitted is generated in step 100, the mobile station 10 proceeds to step 102 and generates a scheduling request message and transmits it to the base station 20. The scheduling request message is information transmitted by the mobile station 10 without permission of the base station 20 when data to be transmitted is generated. At this time, the mobile station 10 drives a timer provided therein. The value set for the timer is set to a time value required until the time required for scheduling again after data transmission, that is, the transmission of the scheduling request update message. Therefore, the time at which data can be transmitted by one scheduling is determined to be a predetermined time. In addition, when the mobile station 10 generates and transmits the scheduling request message, the mobile station 10 transmits a transmission rate applicable to the request data transmission, the state of the buffer in which the data is stored, and the quality of service (QoS) information of the data. do. Based on this information, the base station 20 can perform scheduling. After receiving the scheduling request message from each of the mobile stations included in the base station, the base station 20 performs backward scheduling for each mobile station for which scheduling is required in step 104. Thereafter, the base station 20 transmits the scheduling result in the grant message in each mobile station in step 106.

Accordingly, the mobile station 10 starts transmitting data in the reverse direction based on the grant information received from the base station 20 in step 108. At this time, transmission in the reverse direction is continued as long as there is data to be transmitted from the mobile station 10, and is continuously performed within the driving time of the timer. As such, if there is data to be transmitted continuously from the base station 20, the mobile station 10 generates and transmits a scheduling request update message to the base station 20 in step 110. In this case, the mobile station 10 also transmits the information transmitted in step 102 to the base station 20 together. When the scheduling request update message is transmitted in this way, the base station 20 performs scheduling again. In FIG. 1, although not shown, the scheduling is newly performed in the base station 20. In addition, the base station 20 generates and transmits an acknowledgment message in step 112 after the scheduling. The mobile station 10 then transmits data again in step 114.

However, when the mobile station transmits the scheduling request message to the base station by the above scheme, the scheduling request message may be continuously generated at the same time, which may adversely affect data transmission at a specific time point. This will be described with reference to FIG. 2.

2 is a timing diagram when a mobile station transmits a scheduling request message and a scheduling request update message.

Among two mobile stations included in a specific base station, two mobile stations (mobile station A and mobile station B) can simultaneously transmit from the time point T0 to the time point T1. This point of time may occur simultaneously in several mobile stations as well as in two mobile stations. The transmission time of the scheduling request message cannot be predicted by the base station 20. Therefore, the amount of interference caused by the scheduling request message is also unpredictable. Moreover, the scheduling request message has a small amount of information as described above. Therefore, the scheduling request message generated by one mobile station cannot ignore a portion of the reverse link capacity.

In addition, a base station employing a scheduling scheme typically allocates resources to each mobile station by filling up to a given criterion of backward capacity. Therefore, when several mobile stations transmit a scheduling request message at the same time, the base station suddenly increases the amount of interference in an unpredictable state, thereby increasing the probability of not accurately demodulating the data received at that moment.

In addition, when all of the mobile stations continuously have data to transmit, the scheduling request update message is simultaneously transmitted from the time point T2 to the time point T3. This is because all mobile stations transmit the scheduling request update message by applying the same timer. Therefore, when the scheduling request update message is simultaneously transmitted in this case, there is a problem in that the amount of interference continues to increase continuously in an unexpected state. That is, the base station has a problem in that the probability of not correctly demodulating the data received at the moment of transmitting the above-mentioned messages becomes very high.

Accordingly, an object of the present invention is to provide an apparatus and method for reducing interference caused by a reverse scheduling request message in a mobile communication system.

Another object of the present invention is to provide an apparatus and method for reducing backward interference in a mobile communication system.

Another object of the present invention is to provide an apparatus and method for improving the efficiency of reverse transmission in a mobile communication system.

Another object of the present invention is to provide an apparatus and method for increasing the reception efficiency of data transmitted in a reverse direction in a mobile communication system.

The method according to the first embodiment of the present invention for achieving the above object, the data transmission in the reverse direction, and performs the reverse transmission scheduling in response to the request of the mobile station and the mobile station requesting the reverse scheduling and the response signal thereto A reverse scheduling request method in a mobile station of a mobile communication system including a transmitting base station, when a data to be transmitted is generated, generating and transmitting a scheduling request message to a base station, and driving a timer having a predetermined value; Transmitting data in the reverse direction after receiving the acknowledgment message; determining whether to send a scheduling request update message by driving a random number generator when there is more data to be transmitted in the reverse direction when the timer ends; and at the determined time point, Scheduling Request Update It includes a process for generating and transmitting a message.

In accordance with a second embodiment of the present invention for achieving the above objects, a method for transmitting data in a reverse direction, and performing a reverse transmission scheduling at the request of the mobile station and the mobile station requesting reverse scheduling, and receiving a response signal thereto. As a reverse scheduling request method in a mobile station of a mobile communication system including a transmitting base station, when data to be transmitted is generated, a scheduling request message is generated and transmitted to a base station at a predetermined time of transmission of a scheduling request message, and a timer having a predetermined value is driven. And transmitting data in the reverse direction after receiving the grant message from the base station; and generating and transmitting the scheduling request update message at the predetermined scheduling request time when there is further data to be transmitted in the reverse direction when the timer ends. It includes the process.

A method according to a third embodiment of the present invention for achieving the above object, the data transmission in the reverse direction, and performs the reverse transmission scheduling in response to the request of the mobile station and the mobile station requesting the reverse scheduling, and the response signal thereto A reverse scheduling request method in a mobile station of a mobile communication system including a transmitting base station, when data to be transmitted is generated, a transmission time of a scheduling request message is determined by a value generated by driving a random number generator, and the scheduling request is determined at the determined time point. Generating a message and transmitting the message to a base station, and then driving a timer having a predetermined value, transmitting data in a reverse direction after receiving an acknowledgment message from the base station, and further transmitting data in a reverse direction at the end of the timer. If the above random number generator To include a process for generating and transmitting an update message in the scheduling request procedure, and the determined point in time to determine when to send the update scheduling request message.

An apparatus of the present invention for achieving the above objects includes a mobile station for transmitting data in a reverse direction, a base station for performing reverse transmission scheduling at the request of the mobile station and transmitting a response signal thereto. A reverse scheduling request apparatus in a mobile station of a mobile communication system, comprising: a random number generator for generating a random number for determining a transmission time of a scheduling request message or a scheduling request update message, and driving with a value of a valid period of the response signal received from the base station; And a radio unit for generating and transmitting the scheduling request message and the scheduling request update message in a reverse direction, and receiving the response signal received in the forward direction, and the scheduling request message or the value according to a value generated from the random number generator. schedule Determining a transmission time of the update request message, and then transmits a scheduling request message, and driving the timer, and a controller for controlling a reverse data transmission according to the received response signal during the timer operation time.

1 is a signal flowchart when a mobile station transmits a scheduling request message to a base station when data to be transmitted is generated.

2 is a timing diagram when a mobile station transmits a scheduling request message and a scheduling request update message;

3 is a block diagram of a mobile station apparatus according to an embodiment of the present invention;

4 is a timing diagram when a scheduling request update message is transmitted at different time points after two different mobile stations transmit the scheduling request message at the same time point according to the first embodiment of the present invention.

5 is a timing diagram when a scheduling request update message is transmitted again at different times after transmitting scheduling request messages from two different mobile stations at different times according to the second embodiment of the present invention;

6 is a timing diagram when a scheduling request message and a scheduling request update message are transmitted at different time points through random number generation in two different mobile stations according to the third embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings.

In addition, in the following description, there are many specific details such as specific messages or signals, which are provided to aid the overall understanding of the present invention, and it is understood that the present invention may be practiced without these specific details. It will be self-evident to those of ordinary knowledge. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In the present invention, the mobile station does not transmit the 'scheduling request message' or the 'scheduling request update message' as soon as the occurrence condition is satisfied, and groups the group according to a predetermined rule to determine the transmission time. Through this, the scheduling request message is distributed and transmitted. Therefore, the group used in the present invention is determined by the absolute time. For example, if the occupancy time required to transmit a 'scheduling request message' or a 'scheduling request update message' is 10ms, each group is classified into a certain number with an occupancy time of 10ms. In general, the expiration time of the timer can be set in a reasonable range, so the group can be set within that range. If the expiration time of the timer is valid within the range of 50 to 80 ms, the group can be classified into four groups. However, it is natural that the number can be set smaller or larger than this.

Using the salping method in the prior art, in the above example, a specific value (e.g., 60 ms) within a reasonable category is set to the expiration time of the timer, which applies equally to all mobile stations. However, when using the method of the present invention, 50ms is regarded as the expiration time of the timer, and after 50ms, the mobile station transmits a 'scheduling request update message' at a time corresponding to a group set by a certain law.

3 is a block diagram of a mobile station apparatus according to a preferred embodiment of the present invention. Hereinafter, an internal block configuration and its operation of the mobile station apparatus according to the present invention will be described in detail with reference to FIG. In addition, FIG. 3 illustrates only the necessary configuration according to the present invention, and it should be noted that parts unnecessary for the description of the present invention are not shown.

The control unit 311 performs general control of the mobile station, and in particular, controls the transmission of the scheduling request message and the transmission of the scheduling request update message according to the present invention. In addition, for this control, the random number generator 312 is controlled to generate a random number, and the transmission time of the scheduling request message or the scheduling request update message is determined by the generated random number. That is, groups for transmitting the scheduling request message or the scheduling request update message are determined. The controller 311 controls the timer 313 to set a timer value at a predetermined time, and then detects the validity period of the scheduling request message based on a signal received from the timer 313.

The random number generator 312 randomly generates one of the numbers predetermined by the control of the controller 311 and outputs the number to the controller 311. In an embodiment of the present invention, an integer of 1 to 4 may be generated and output to the controller 311. The timer 313 sets a preset time value under the control of the controller 311, generates a signal according to the timeout after being driven for the set time, and outputs the signal to the controller 311.

The wireless transmitter 315 converts the data to be transmitted in the reverse direction into a state capable of transmitting air by the control of the controller 311 and then transmits the data to the antenna through the duplexer 316. The wireless transmitter 315 also transmits a scheduling request message or a scheduling request update message according to the present invention. The wireless receiver 314 converts a signal received through the duplexer 316 into a signal that can be processed by the controller 311 and then outputs the signal to the controller 311. In this case, the received signals may be various data or messages received in the forward direction, and include the acknowledgment message mentioned in the present invention.

4 is a timing diagram when a scheduling request update message is transmitted at different time points after two different mobile stations transmit the scheduling request message at the same time point according to the first embodiment of the present invention.

When two different mobile stations (mobile station A and mobile station B) simultaneously transmit scheduling request messages 401 and 411 to the base station from the time T0 to the time T1, respectively, as described above in the related art. Is set to the same value. Therefore, the mobile station A and the mobile station B both have a timer at the same time T2. The controller 311 of each mobile station then generates a random number by controlling the random number generator 312. The transmission time of the scheduling request update message is determined according to the random number generated as described above. That is, when the random number generated by the mobile station A is 1, the scheduling request update message 403 is transmitted immediately after the timer expires. If the random number generated by the control unit 311 of the mobile station B, which is another mobile station, controls the random number generator 312, the mobile station B waits twice as long as necessary for the transmission of the scheduling request update message, and then at the time T4. Generate and send a scheduling request update message. That is, the transmission group of the scheduling request update message to be transmitted by each mobile station is determined. By transmitting the scheduling request update message as described above, since two timers are terminated at different time points, the interference in the reverse direction can be reduced.

In addition, although the embodiment of the present invention is configured to determine the time point of the scheduling request update message transmitted in the reverse direction by the random number generator, it may be configured to set each group determined by the base station, the mobile station by itself according to different criteria May be determined. In this case, the set group is not changed unless special changes exist. However, the method of the random number generator described in the present invention is that the time point for continuously sending the scheduling request update message is changed. That is, in the first embodiment of the present invention, the two mobile stations transmit the scheduling update request message at different time points, thereby reducing backward interference.

FIG. 5 is a timing diagram when two different mobile stations transmit scheduling request update messages at different time points after transmitting scheduling request messages at different time points according to the second embodiment of the present invention. Hereinafter, a second embodiment of the present invention will be described in detail with reference to FIG. 5.

In the second embodiment of FIG. 5, a group to which a scheduling request message is to be transmitted is determined in advance. In this case, the control unit 311 of each mobile station does not transmit the scheduling request message until the time of the group to which it belongs, even if data to be transmitted is generated. In the embodiment of FIG. 5 described below, it is assumed that mobile station A is included in group 2, and it is assumed that mobile station B is included in group 3. FIG. That is, each mobile station will individually drive its internal timer. At this time, it should be noted that the set value of each timer has the same value.

The mobile station A and the mobile station B do not immediately generate and transmit a scheduling request message even if data to be transmitted are generated, and check whether the transmission time of the group in which the mobile station A is included arrives. This check is carried out, and the mobile station A becomes the transmission time of the scheduling request message 501 at the time point T0. Therefore, at this time, mobile station A generates and transmits a scheduling request message. When the transmission of the scheduling request message is completed, a timer provided therein is set. In addition, the mobile station B generates the scheduling request message and transmits the scheduling request message 511 from the time point T1 to the time point T2, which is a transmission point of the third group group3 to which the mobile station B belongs. Mobile station B then drives a timer provided therein. As described above, when the timer is completed by driving the timer provided therein, if there is data to be transmitted further when the transmission time of the user arrives again, the scheduling request update message is generated and transmitted. That is, the mobile station A generates and transmits a scheduling request update message 503 at the time T4, and the mobile station B generates and transmits a scheduling request update message 513 at the time T5.

In this way, the scheduling request update message may be transmitted at a predetermined time point according to a predetermined group so that the reverse load may be uniformly distributed. Therefore, the efficiency of reverse data transmission can be increased, and the error rate of data received from the base station at a specific time can be lowered.

FIG. 6 is a timing diagram when two different mobile stations transmit a scheduling request message and a scheduling request update message at different time points through random number generation according to the third embodiment of the present invention. Hereinafter, a method according to a third exemplary embodiment of the present invention will be described in detail with reference to FIG. 6.

In the third embodiment of the present invention, both the scheduling request message and the scheduling request update message are transmitted at a time determined by the random number generator. Therefore, when the mobile station A and the mobile station B, which are different from each other, generate random numbers by driving a random number generator included therein. A group is determined according to a value generated by the random number generator, or a time point for transmitting a scheduling request message from a current time point. Mobile station A generates and sends a scheduling request message at the time T0 determined by the value generated by the random number generator. The mobile station B generates and transmits a scheduling request message at the time T1 determined by the random number generator. The mobile station A and the mobile station B respectively drive the timer at the time when the transmission of the scheduling request message is completed. When the timer is driven in this way, the time point at which the time set for the timer of the mobile station A ends is a point of time T3, and the time point at which the time set for the timer of the mobile station B ends is a point of time T4. When the time set for the timer is completed in this manner, the mobile station A and the mobile station B both determine when to send the scheduling request update message by the random number generator. Assuming that the time determined according to the values generated by the random number generators provided in the mobile stations A and B is the time of T5 and the time of T4, the mobile station A generates a scheduling request update message 603 at the time of T5. To transmit. The mobile station B generates and transmits a scheduling request update message 613 at the time T4. Through this method, a scheduling request message or a scheduling request update message can be generated and transmitted in different groups according to transmission timings of respective mobile stations.

As described above, if the reverse scheduling method according to the present invention is applied, the interference caused by the reverse scheduling request message can be reduced and the efficiency of reverse transmission can be improved. In addition, there is an advantage that can increase the reception efficiency of the data transmitted in the reverse direction in the mobile communication system.

Claims (4)

A reverse scheduling request method in a mobile station of a mobile communication system including a mobile station for transmitting data in a reverse direction, and a base station for performing reverse transmission scheduling at the request of the mobile station and transmitting a response signal thereto according to the request of the mobile station, Generating data to be transmitted to the base station by generating a scheduling request message and driving a timer having a predetermined value; Transmitting data in a reverse direction after receiving an acknowledgment message from the base station; Determining when to send a scheduling request update message by driving a random number generator when there is more data to be transmitted in the reverse direction at the end of the timer; And generating and transmitting the scheduling request update message at the determined time point. A reverse scheduling request method in a mobile station of a mobile communication system including a mobile station for transmitting data in a reverse direction, and a base station for performing reverse transmission scheduling at the request of the mobile station and transmitting a response signal thereto according to the request of the mobile station, Generating data to be transmitted to the base station by generating a scheduling request message at a predetermined time of transmission of the scheduling request message, and driving a timer having a predetermined value; Transmitting data in a reverse direction after receiving an acknowledgment message from the base station; And generating and transmitting the scheduling request update message at the predetermined scheduling request time point when there is further data to be transmitted in the reverse direction when the timer ends. A reverse scheduling request method in a mobile station of a mobile communication system including a mobile station for transmitting data in a reverse direction, and a base station for performing reverse transmission scheduling at the request of the mobile station and transmitting a response signal thereto according to the request of the mobile station, When data to be generated is generated, the transmission time of the scheduling request message is determined based on a value generated by driving a random number generator, and a scheduling request message is generated and transmitted to the base station at the determined time, and then a timer having a predetermined value is driven. Process, Transmitting data in a reverse direction after receiving an acknowledgment message from the base station; Determining when to send a scheduling request update message by driving the random number generator when there is more data to be transmitted in the reverse direction at the end of the timer; And generating and transmitting the scheduling request update message at the determined time point. A reverse scheduling request apparatus in a mobile station of a mobile communication system including a mobile station for transmitting data in a reverse direction and performing a reverse transmission scheduling at the request of the mobile station and transmitting a response signal thereto; A random number generator for generating a random number for determining a transmission time of a scheduling request message or a scheduling request update message; A timer driven by a value of a valid period of the response signal received from the base station; A wireless unit for generating and transmitting the scheduling request message and the scheduling request update message in a reverse direction, and receiving the response signal received in a forward direction; The transmission time of the scheduling request message or the scheduling request update message is determined according to the value generated from the random number generator, the timer is driven after the transmission of the scheduling request message, and is reversed according to the received response signal during the timer driving time. And a control unit for controlling data transmission.