KR100862614B1 - Method of Uplink Signaling for Streaming Services in Packet Mobile Communication Systems, Base Station and Mobile Terminal - Google Patents

Abstract

The present invention provides an uplink signaling method capable of supporting fair scheduling according to channel conditions and time constraints and buffer status of a terminal in order to efficiently support a streaming service requiring real-time processing in a packet-based mobile communication system. A base station apparatus and a mobile terminal, comprising: a mobile terminal having an uplink buffer and a base station having an uplink scheduler, the uplink signaling method in a packet mobile communication system, comprising: a resource allocation request from the mobile terminal (A) allocating an uplink resource and setting a transmission allowance window using characteristic information of the transmitted packet service and uplink radio channel state information measured by the base station; And transmitting data to the mobile terminal at transmission time intervals using the set transmission permission window, channel state estimation information of each mobile terminal, buffer status information transmitted from each mobile terminal, and reception result information of data received from the mobile terminal. (B) transmitting scheduling permission information for granting the permission.

OFDMA, packet, scheduling, resource, allocation, buffer, mobile, communication, uplink, link

Description

TECHNICAL FIELD The uplink signaling method for a streaming service in a packet mobile communication system, and a base station apparatus and a mobile terminal for the same, and a method for Uplink Signaling for Streaming Services in Packet Mobile Communication Systems, Base Station and Mobile Terminal}

1 is a view showing a configuration example of a general packet mobile communication system,

2 is a view for explaining a transmission process of an uplink data channel in a general packet mobile communication system;

3 is an exemplary block diagram of a base station for uplink signaling according to the present invention;

4 is a flowchart illustrating an uplink signaling method for a streaming service according to the present invention;

5 is a flowchart illustrating an uplink packet scheduling process according to the present invention;

6 is a view for explaining a process of determining an uplink transmission allowance window according to the present invention;

7 is a diagram for explaining uplink packet scheduling according to the present invention.

* Explanation of symbols for the main parts of the drawings

31: receiving wireless processing unit 32: control information processing unit

33: channel state measurement unit 34: average data rate calculation unit

35: resource allocation unit 36: reception data processing unit

37: uplink scheduler 38: transmit radio processing unit

The present invention relates to an uplink signaling method for efficiently supporting a streaming service requiring a real-time service in a packet-based mobile communication system, and a base station apparatus and a mobile terminal therefor.

3GPP, an asynchronous mobile communication standardization organization, started LTE (Long Term Evolution) standardization activities to develop the next generation mobile communication system standard. As a next-generation mobile communication system standard, a wireless transmission scheme using frequency division duplex (FDD) has been proposed, and an orthogonal frequency division multiple access (OFDMA) scheme has been proposed for the downlink. Link-based single carrier frequency division multiple access (SC-FDMA) has been proposed.

In general, a mobile communication system includes a base station constituting a cell and a mobile station used by a user. The mobile terminal transmits and receives packet data to and from the base station through a wireless channel.

1 illustrates a configuration of a general packet mobile communication system, based on uplink signaling.

The mobile communication system includes a base station 11 and a plurality of mobile terminals 12 for receiving uplink data. The uplink buffer 13 is provided in the mobile terminal 12. The mobile terminal 12 transmits the data stored in the uplink buffer 13 to the base station 11 through the uplink data channel under the control of the base station 11. That is, the base station 11 informs the mobile terminal 12 of the data transmission permission information and the data channel information through the scheduling permission channel. Then, the mobile terminal 12 transmits the data stored in the uplink buffer 13 to the base station 11 through the data channel according to the data transmission permission information and the data channel information. The result of the data received at the base station 11 is transmitted to the mobile terminal 12 via the retransmission response channel.

2 schematically illustrates an uplink data transmission structure using an SC-FDMA scheme in a general packet mobile communication system.

Radio resource characteristics of the SC-FDMA scheme is similar to the OFDMA scheme. In FIG. 2, the frequency axis is composed of a plurality of subcarriers, and the time axis is composed of radio resources divided into a transmission time interval (TTI). In order to efficiently control radio resources, subcarriers included in contiguous bandwidths for uplink are grouped into groups, and each subcarrier group is assigned to a mobile terminal. That is, the uplink scheduler (14 in FIG. 1) located in the base station allocates resources to the mobile terminal in units of uplink subcarrier groups.

In such a packet-based mobile communication system, a plurality of mobile terminals share a radio resource managed by one base station to transmit and receive packet data. As such, since multiple mobile terminals use the same resource at the same time, a collision may occur.

If a collision occurs in the wireless communication using the OFDMA scheme and the SC-FDMA scheme, it becomes impossible to receive all the collided packet data, which makes communication difficult. In addition, resource allocation for retransmitting unsuccessful data causes resource inefficiency. Therefore, in the OFDMA and SC-FDMA mobile communication systems, a centralized scheme that manages and manages all radio resources belonging to its cell at the base station in order to minimize such collisions and efficiently allocate resources to each mobile terminal. Use a centralized approach. To this end, the base station is provided with a downlink packet scheduler (15 of FIG. 1) that is responsible for downlink resource allocation and an uplink packet scheduler (14 of FIG. 1) that is responsible for uplink resource allocation.

The uplink packet scheduler provided in the base station can determine the radio channel state of the mobile station belonging to its cell, the quality of service (QoS) used, and the uplink buffer state. Collect and use the collected information to select a mobile terminal to transmit data. Then, data transmission is allowed to the selected mobile terminal to transmit the packet.

In this case, the radio channel state is measured by receiving a radio channel state measurement control signal (reference signal) transmitted from the mobile terminal at the base station. The base station determines the type of adaptive modulation and channel coding (AMC) according to the measured radio channel state.

Packet-based systems generally use an adaptive modulation scheme and channel coding to improve the downlink and uplink data transmission throughput.

The QoS (QoS) of the packet service is performed according to the call setup procedure of the upper layer at the time of the connection setup of the service between the mobile terminal and the base station, and the set parameter is controlled by the medium access control (MAC). Transfer to layer to use in wireless transmission and reception. Packet services are largely divided into real-time and non-real-time services, and this information is used for the operation of the uplink packet scheduler.

The uplink buffer is for storing packet data to be transmitted from the mobile terminal to the base station through the uplink.

Since the uplink packet scheduler operating in the base station cannot directly know the state of the uplink buffer provided in the mobile terminal, there is a need for a method for transmitting the state information of the mobile terminal to the base station. In addition, signaling for this should be defined to minimize overhead.

In general, uplink using the SC-FDMA scheme combines subcarriers into a certain group, and this subcarrier group is assigned to a mobile terminal. A subcarrier channel having a distributed structure is allocated to a mobile terminal having a poor channel state, but a constant subcarrier group channel is allocated to a mobile terminal having a stable channel state. In this way, it is efficient to assign a subcarrier group to the mobile terminal. In order to move a group or allocate a distributed channel, an uplink packet scheduler must transmit a reference signal to a corresponding wireless channel for estimating a necessary channel state. However, this has a problem of difficulty in allocating radio resources and increasing power consumption of the terminal.

In addition, a constant delay occurs in order to transmit the state of the uplink buffer to the base station. This is caused by the transmission time interval (TTI), the transmission time to the radio channel, and the channel modulation and demodulation time. In addition, since a scheduling request channel for reporting status information of the uplink buffer operates at a long period to minimize the load and accommodate a large number of mobile terminals, the scheduling request channel has a high performance in a real time service having a large delay constraint. It will have a big impact.

Moreover, transmission periods are generally unknown in the nature of packet services. In general, in the case of streaming services, a method of transmitting cycle information is not used, and a variety of transmission cycles are used according to characteristics of an application program. For this reason, it is problematic to generalize the transmission period and use it in a mobile communication system. The Adaptive Multi-Rate (AMR) codec method used in 3GPP is designed based on the voice codec used as a standard specification in a conventional circuit-based system and can be used at a special period (20ms). However, since packet-based systems use VoIP (Voice over IP) and various streaming services, the period cannot be used as scheduling information.

In order to support a streaming service requiring a real-time service in a packet mobile communication system, an operation for transmitting and receiving data at a rapid cycle is performed. However, such an operation may act as a factor of consuming power of the mobile terminal, thereby limiting the usage time of the mobile terminal.

Accordingly, the present invention has been proposed to solve the above problems of the prior art, and in order to efficiently support a streaming service requiring a real-time service in a packet-based mobile communication system. It is an object of the present invention to provide an uplink signaling method capable of supporting fair scheduling according to channel state and time constraints and a buffer state of a terminal, and a base station apparatus and a mobile terminal therefor.

Another object of the present invention is to provide a mobile terminal for minimizing power consumption by controlling a transmission / reception operation of a terminal according to a buffer state.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. It will also be appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

According to an aspect of the present invention, there is provided a method for uplink signaling in a packet mobile communication system including a mobile terminal having an uplink buffer and a base station having an uplink scheduler. (A) allocating an uplink resource and setting a transmission allowance window by using characteristic information of a packet service delivered with an allocation request and uplink radio channel state information measured by the base station; And transmitting data to the mobile terminal at transmission time intervals using the set transmission permission window, channel state estimation information of each mobile terminal, buffer status information transmitted from each mobile terminal, and reception result information of data received from the mobile terminal. (B) transmitting scheduling permission information for granting the permission.

Preferably, in the step (b), the buffer status information transmitted from the mobile terminal is included in the header of the packet transmitted from the mobile terminal, characterized in that delivered.

Advantageously, step (a) comprises: receiving a resource allocation request including characteristic information of a packet service from said mobile terminal; Calculating an average data rate per subcarrier group using an uplink channel state of the entire base station; Allocating an uplink resource using the average data rate and characteristic information of a packet service received from the mobile terminal; And setting a transmission allowance window by comparing the data transmission rate delivered from the mobile terminal with the calculated average data transmission rate.

Preferably, the step (b) may include: transmitting the scheduling permission information for allowing transmission to each mobile terminal at transmission time intervals based on the set transmission permission window; If data is received from each mobile terminal according to the scheduling permission information, performing an error check on the received data; If there is an error in the received data, giving a scheduling opportunity by weighting the mobile terminal in which the error occurred, and transmitting the scheduling permission information to each mobile terminal at each transmission time interval; If there is no error in the received data, checking buffer status information included in a header of a data packet received from the mobile terminal; And granting scheduling opportunities in order of high priority according to the buffer status information to transmit the scheduling grant information to each mobile terminal.

Preferably, the present invention deletes the retransmission request information if the received data has an error and transmits the retransmission request to the mobile terminal having the error, and if the data is not received even after a certain period from the mobile terminal.

In addition, the base station apparatus according to the present invention for achieving the above object, in a packet mobile communication system comprising a mobile terminal having an uplink buffer and a base station having an uplink scheduler, resource allocation request from the mobile terminal; First means for allocating an uplink resource and setting a transmission permission window by using the characteristic information of the packet service transmitted together with the uplink radio channel state information measured by the base station; And transmitting data to the mobile terminal at transmission time intervals using the set transmission permission window, channel state estimation information of each mobile terminal, buffer status information transmitted from each mobile terminal, and reception result information of data received from the mobile terminal. And uplink scheduling means for transmitting scheduling grant information for granting the grant.

Advantageously, the first means comprises: channel state measurement means for measuring an uplink channel state using a channel state measurement control signal periodically received from the mobile terminal; Average data rate calculating means for calculating an average data rate per subcarrier group by using the uplink channel state of the entire base station measured by the channel state measuring means; Control information processing means for processing the control information transmitted from the mobile terminal; And allocating an uplink resource using the calculated average data rate and the characteristic information of the packet service delivered from the mobile terminal through the control information processing means, and transmitting the data rate and the calculated average data transmitted from the mobile terminal. And resource allocation means for comparing transmission rates and setting transmission permission windows.

Preferably, the control information processing means extracts the buffer state information of the mobile terminal, which is included in the header of the packet transmitted from the mobile terminal, and transmits the buffer state information to the uplink scheduling means.

Preferably, the present invention provides a means for deleting the retransmission request information if there is an error in the received data so that the retransmission request is sent to the mobile terminal having the error, and the data is not received even after a certain period of time from the mobile terminal. Include.

delete

delete

delete

delete

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is an exemplary block diagram of a base station for uplink signaling according to the present invention, and FIG. 4 is a flowchart illustrating an uplink signaling method for a streaming service according to the present invention. 5 is a flowchart illustrating an uplink packet scheduling process according to the present invention.

The present invention can be largely divided into two components.

The first component is to determine the uplink transmission allowance window using the characteristics of the packet service (QoS) information and the average value of the uplink radio channel measured by the base station. This is a procedure that operates when a connection setup is made between a mobile terminal and a base station. This is performed by the channel state measuring unit 33, the control information processing unit 32, the average data rate calculating unit 34, and the resource allocating unit 35 in FIG.

The second component transmits scheduling grant information for allowing data transmission from the base station uplink scheduler to the mobile terminal using the transmission permission window information and the radio channel state estimation information determined by the first component, and the mobile terminal transmits the uplink. The data stored in the buffer and the buffer status information are transmitted to the base station. In addition, this includes re-scheduling the packet by using the data and the buffer status information received from the mobile terminal, and transmitting scheduling permission information for allowing data transmission to the mobile terminal. This process is performed at every transmission time interval (TTI). This is performed by the uplink scheduler 37 in FIG.

A detailed description of the uplink transmission allowance window determination process, which is the first component, is as follows.

In a mobile communication system, a procedure of establishing a connection between a mobile terminal and a base station may be classified into a random access operation and a link setting operation. The mobile terminal uses a random access scheme when attempting to access the base station. This is necessary because the base station does not recognize the mobile terminal. The mobile station makes a resource allocation request to the base station through a random access operation.

In the present invention, the mobile terminal requests resource allocation from the base station using the following packet service characteristic (QoS) information.

1) Service class (QoS class): Conversational, streaming, interactive, background

2) data rate: kbps

3) delay constraint: msec

Here, the service type means a packet service characteristic defined in the existing 3GPP standard specification. The Bit Error Rate (BER) value defined in the 3GPP specification is reflected when setting an Adaptive Modulation and Condig (AMC) value determined according to channel conditions. This information is conveyed as simple information, which is transmitted by the mobile terminal to the base station through a random access channel (RAC), which is a transport channel used for random access. The base station receives the simplified packet service characteristic information and uses the data channel for resource allocation. If more detailed information than the simplified packet service characteristic information is needed, the detailed information may be transmitted through a general resource allocation negotiation procedure used in the link establishment operation between the base station and the mobile terminal after the data channel is allocated.

When the base station receives a packet service setting request, the base station calculates an average data rate by performing the following procedure in case of a conversational class and a streaming class service requiring real time processing. This average data rate calculation is performed by the average data rate calculator 34.

The channel state measuring unit 33 of the base station measures an uplink average channel state value of the entire base station by using a control signal (reference signal) for uplink channel measurement received from all mobile terminals located in its cell. In the uplink using the SC-FDMA scheme, a bandwidth is divided into a predetermined group and a subcarrier group is allocated to the mobile station. Therefore, the base station always manages the state of the subcarrier group at regular intervals. This is performed by the channel state measuring unit 33. The channel state measuring unit 33 uses the uplink channel measurement control signal received through the receiving radio processor 31 to uplink the average of all mobile terminals connected to the base station. Manage channel status. The average value of the channel state may be expressed as a data size that can be stored in the minimum data resource block. This can also be expressed as the data rate per subcarrier group.

For example, when the transmission time interval (TTI) is 0.5 msec and the number of symbols of the data channel is six, if the number of subcarriers in the subcarrier group is 24, the QPSK modulation scheme is used for the minimum data allocation block. 288 bits (36 bytes) of information can be allocated (6 symbols x 24 subcarriers x 2 bits (QPSK) = 288 bits (36 bytes)). Here, when QPSK and 1/2 coding are used in the AMC scheme, the amount of data that can be transmitted in the MAC layer is 18 bytes.

However, in order to briefly describe the gist of the present invention, the packet header required in the CRC and MAC layers will not be considered. In addition, if the calculation is expressed as a data rate, it is equal to 144 bits (0.5 ms) x 2000 TTI = 288 kbps, which represents an average data rate that can be transmitted by one group of subcarriers.

The control information processor 32 transmits the data transmission rate of the packet service received from the mobile terminal and the time constraint parameter of the packet service to the resource allocator 35 through the reception wireless processor 31.

The resource allocator 35 stores the average data rate of the wireless channel calculated by the average data rate calculator 34, the data rate of the packet service delivered from the mobile terminal through the control information processor 32, and the time of packet service. An uplink resource is allocated to a mobile station as follows for each subcarrier group using a delay constraint parameter.

1) Since the SC-FDMA scheme described in the present invention operates a plurality of subcarrier groups, an input packet service is allocated to one subcarrier group. At this time, the sum of the data rate of the input packet service and the data rate of the entire packet service for which data transmission and reception are currently performed in the subcarrier group should not exceed the average value of the uplink data rate that is acceptable.

For example, if the average transmission rate of one subcarrier group is 288 kbps, the sum of the transmission rate of the existing packet service being used and the newly input packet service should be 288 kbps or less. If this criterion is exceeded, the resource allocation unit 35 allocates the requested packet service to another subcarrier group or restricts the service.

2) The resource allocator 35 sets a time constraint parameter of the packet service as a period of transmission permission. That is, the resource allocator 35 determines resource allocation every 20ms when the service has a time constraint of 20ms as shown in FIG. 6.

The resource allocator 35 then sets a transmission allowance window by comparing the data rate of the packet service with the average rate of the wireless channel. That is, the resource allocator 35 determines how many windows are needed based on the size of data that can be transmitted per one transmission time interval (TTI) as shown in FIG. 6. A window means that when one transmission is made in one window, the packet data rate is satisfied within a transmission allowance period.

As shown in FIG. 6, a service requiring a data rate of 32 kbps should transmit 80 bytes (32,000 bits * (20/1000) ms) = 640 bits (80 bytes) per 20 ms period. This means that if the average data rate of the data allocation block is 20 bytes, 4 transmissions should be made per 20 ms period. Therefore, the present invention can support the data rate when one transmission per window is successfully made.

When the process of connection setup of the packet service by the resource allocator 35 is completed with the transmission permission window setting as described above, the mobile terminal periodically transmits a control signal for measuring channel state through the assigned subcarrier group. Send by The channel state measuring unit 33 of the base station measures the uplink channel state using a control signal for measuring channel state transmitted from the mobile terminal through the receiving wireless processor 31. In addition, the resource allocator 35 transmits the set resource allocation information to the uplink scheduler 37.

The uplink scheduler 37 controls scheduling so that at least one transmission permission is performed in the corresponding window. In this case, the reason for allowing one or more times is that the mobile terminal that has received the transmission permission cannot immediately confirm whether or not the mobile terminal, which has received the transmission permission, actually transmits data, and the uplink scheduler 37 of the base station indicates as many transmission permission as possible. .

The receiving radio processor 31 processes a radio frequency (RF) signal received through an antenna and transmits a channel state measurement control signal to the channel state measurement unit 33, and transmits a service type, a data rate, The time constraint parameter is transmitted to the control information processor 32.

The received data processor 36 is a processor that demodulates the data transmitted from the mobile terminal and performs an error check. The receive data processor 36 outputs an error check result for the data received from each terminal. To pass).

In addition, the transmitting radio processor 38 transmits downlink data at a radio frequency or transmits scheduling grant information input from the uplink scheduler 37 as a radio frequency signal.

Next, a process of performing scheduling in the uplink scheduler 37 will be described.

The uplink scheduler 37 transmits the data size calculated by the AMC and the mobile terminal to allow uplink data transmission at every transmission time interval (TTI) by using the following parameter value as a weight.

1) Transmission allowance window information determined by the resource allocator 35

2) Channel state information of each mobile terminal calculated by the channel state measuring unit 33

3) Buffer status information of each mobile terminal transmitted through the control information processing unit 32

4) Receive result information of a previously transmitted data block input from the receive data processor 36

The transmission permission window information is for the mobile terminal to guarantee resource allocation one or more times in the window. Accordingly, the uplink scheduler 37 processes the scheduling to be performed one or more times in consideration of transmission permission information of all mobile terminals to be scheduled.

The channel state information of the mobile terminal is used to determine the adaptive modulation and coding (AMC) value. In general, the AMC step takes into account the channel state value, the bit error rate (BER) value of the service, and the data allocation block. Can be obtained using a defined table. If the channel state of the mobile terminal is a bad channel state below the reference value, the channel assignment is not made, and the channel assignment is processed at the next transmission time interval (TTI).

Although the buffer status information of the mobile terminal may be periodically transmitted from the mobile terminal to the base station, channel transmission cycles and transmission / reception delays occur, which is not suitable for informing buffer information of data requiring real time processing. Therefore, in the present invention, the mobile terminal displays the buffer status information in the uplink packet header and transmits it to the base station, and adds the buffer status display field to the packet header for real time processing. This can be implemented by adding a buffer status information transmitter (not shown) to the mobile terminal. The buffer status information transmitter of the mobile terminal designates an average allowable delay value and a maximum allowable delay value based on a delay constraint among the QoS parameters of the packet service, and considers the delay value of the data stored in the buffer. Display the buffer status in the header.

For example, in the case of a packet service with a 20 ms delay constraint, the average allowable delay value may be set to 10 ms and the maximum allowable delay value may be set to 18 ms. In this case, the buffer status is indicated by 2 bits as follows.

00: Indicates that data exists in the buffer and that the data does not exceed the average allowable delay value (low priority)

01: Indicates that data exists in the buffer and the data exceeds the average allowable delay value (high priority).

11: Indicates that data exists in the buffer and that the data exceeds the maximum allowable delay value (highest priority)

10: Indicates no data or small data in buffer (lowest priority)

The reception result information of the previously transmitted data block refers to information obtained when the uplink packet data is received by the base station, and the reception data processing unit 36 performs a CRC check and results. Since the reception result information is delayed by 4 cycles (TTI) at the scheduling time in the uplink, the base station recognizes the response as a response of a scheduling grant channel transmitted before 4 cycles. The physical layer configures this information as response (ACK / NACK) information of Automatic Repeat Request (ARQ) and transmits it to the mobile terminal. The mobile terminal retransmits the failed data using the response information of the retransmission. However, the present invention also uses this information as information for confirming the result of the scheduling.

4 is a flowchart illustrating a signaling method for uplink in a base station according to the present invention.

As described above, when receiving a resource allocation request including a service type, a data rate, and time constraint information from the mobile terminal (101), the UL average channel state value of the entire base station is determined, and the determined average channel state value is determined. Calculate the average data rate per subcarrier group using (102).

Next, an uplink resource is allocated using the calculated average data rate per subcarrier group, data rate and time constraint parameters delivered from the mobile terminal (103). In this case, the sum of the data rate transmitted from the mobile terminal and the data rate of the entire packet service that is currently transmitting and receiving data in the subcarrier group does not exceed the average value of the allowable uplink data rate. Set the transmission allowance period. Also, the number of windows required is determined based on the size of data that can be transmitted per one transmission time interval.

When the resource allocation is completed, periodically receiving a control signal for measuring the channel state through the assigned subcarrier group, and measures and manages the uplink channel state (104).

Further, by using the determined transmission allowance window information, channel state information of each mobile terminal, buffer state information of each terminal, and reception result information of a previously transmitted data block, generating scheduling permission information for allowing transmission of the mobile terminal is generated. Uplink packet scheduling for transmission to the mobile terminal is performed (105).

A detailed process of the uplink packet scheduling method will be described with reference to FIG. 5.

5 is a flowchart illustrating an uplink packet scheduling process according to the present invention, and FIG. 7 is a diagram illustrating uplink packet scheduling according to the present invention.

When the uplink scheduler receives the transmission permission window information and the channel state information of each terminal (201), the uplink scheduler transmits the scheduling permission information in the order of allowing the transmission of the terminal having the small transmission permission window (202). Referring to FIG. 7, when there is a mobile terminal 1 having a 16 kbps service and a mobile terminal 2 having a 32 kbps service, scheduling is performed in order of allowing a small terminal to transmit in consideration of a transmission permission window. grant) information is transmitted to the mobile terminal. That is, scheduling permission information is transmitted in the order of 1, 2, 3, and 4 in FIG. The remaining time gives priority to the mobile station having a good channel state in consideration of the channel state and allows scheduling (203). In FIG. 7, it is assumed that mobile terminals 1 and 2 are in the same channel state. In this state, scheduling grants are alternately performed. The base station then waits 204 for some time to receive data from the mobile terminal.

The mobile terminal transmits data stored in the uplink buffer according to the scheduling grant information of the base station. The mobile terminal transmits data, and the base station receives the data after a predetermined transmission time interval (4 transmission time intervals (TTI) in the example of FIG. 7).

If data is received after a predetermined transmission time interval (205), the base station performs an error check on the received data (206). If the error check results in an error (207), that is, when data reception fails (NACK), the scheduling opportunity is allocated by increasing the weight at the next scheduling (208). The retransmission request is transmitted while transmitting the scheduling grant information or the NACK information to the corresponding mobile terminal (209). The base station then waits 204 for a period of time for data to be received again. Referring to FIG. 7, when there is an error in data transmitted from the mobile terminal by the scheduling grant channel 2, the order of the scheduling grant channel is transmitted in the order of 5, 6, 7, and 8. In other words, the base station transmits the scheduling grant channel 6 to the mobile terminal 1 and then assigns the scheduling grant channel 7 to the mobile terminal 1 rather than the mobile terminal 2.

On the other hand, if the error check results in that the received data is successfully received without an error (in the case of ACK), the previous transmission allowance window value is initialized so that the scheduling grant is no longer allocated in the window.

As such, when one transmission is successfully performed in one transmission allowance window, the data transmission rate required by the packet service is satisfied, and thus the present invention can support the streaming service.

Meanwhile, the mobile terminal transmits data stored in the uplink buffer while displaying the state information of the buffer in the header. In other words, the mobile terminal generally includes a wireless processing unit and a data transmission processing unit. In the present invention, the mobile terminal includes a buffer state information transmitting unit, and transmits the data stored in the buffer by the data transmission processing unit to transmit the state information of the current buffer. Mark the header so that it can be sent.

The control information processor 32 (FIG. 3) of the base station extracts buffer status information from the header of the data received through the reception wireless processor 31 and transmits the buffer status information to the uplink scheduler 37.

The uplink scheduler 37 checks the buffer state information (211), allocates the scheduling grant channel in high priority order (212), and transmits the scheduling grant information to the mobile terminal (213). Referring to FIG. 7, when the packet header received by the scheduling grant channels 11 and 12 has a buffer status indication of low priority "00" and high priority "11", the order of the scheduling grant channels is 15, 16, 17 and 18 are sent. That is, since the priority of the buffer state information of the mobile terminal 2 is high, the scheduling grant channel 15 is allocated to the mobile terminal 2, and then the scheduling grant channel 16 is allocated to the mobile terminal 2 again.

The mobile terminal is a function in which power saving is essential. In general, for power management, when there is no data transmitted and received in the mobile terminal, the transmission and reception function of the mobile terminal is managed in a sleep state. In addition, the mobile terminal is divided into a downlink channel reception function and an uplink channel transmission function, and power management is effectively performed accordingly.

In the present invention, in order to reduce downlink power consumption, the mobile terminal receives a scheduling grant channel only when there is data in its uplink buffer. Although the base station permits data transmission using resource allocation and scheduling parameters, the mobile terminal does not need to receive this scheduling grant channel when there is no data to transmit, thereby reducing power consumption due to use of the reception function.

In addition, in the present invention, in order to reduce uplink power consumption, the mobile terminal transmits data through the data channel only when there is data in its uplink buffer. Since the base station transmits the scheduling grant channel, when uplink data is not received or when data reception fails (NACK), a problem occurs in normal operation. Thus, the following procedure is solved.

After the base station transmits the scheduling grant channel to the mobile terminal, if a CRC error occurs in the received data after a certain period (4 transmission time intervals) (206 and 207), the base station transmits retransmission response information (NACK) to the mobile terminal. (209).

If there is no data in the buffer, the mobile terminal does not receive retransmission response information and thus does not retransmit the data.

If the base station does not receive data after a certain period (205), it recognizes that previously received NACK information is an error, and deletes this information (214).

This operation is to stop the transmission / reception function in order to minimize the power consumption of the mobile terminal. When the base station receives the uplink data, it may be omitted when the base station recognizes that the data is not received instead of the NACK.

Meanwhile, in the description of the present invention, only some components necessary for the description of the present invention have been described without describing all of the components of the base station. In addition, the components of the mobile terminal have not been described in detail, but only some of the components necessary for the description of the present invention have been described. However, it will be apparent to one skilled in the art to implement this using the present invention as described above.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

According to the present invention as described above, it is possible to transmit the uplink data to satisfy the time constraints of the streaming service that requires a real-time service, it is possible to give a fair scheduling opportunity to the mobile terminals connected to the base station. In addition, the mobile terminal can control the transmission and reception operation according to the buffer state to minimize the power consumption.

Claims (29)

An uplink signaling method in a packet mobile communication system comprising a mobile terminal having an uplink buffer and a base station having an uplink scheduler. (A) allocating an uplink resource and setting a transmission permission window by using the characteristic information of the packet service delivered with the resource allocation request from the mobile terminal and the uplink radio channel state information measured by the base station; And By using the set transmission allowance window, channel state estimation information of each mobile terminal, buffer status information transmitted from each mobile terminal, and reception result information of data received from the mobile terminal, data transmission is performed to the mobile terminal at each transmission time interval. Uplink signaling method for a streaming service in a packet mobile communication system comprising the step of transmitting scheduling grant information to permit. The method of claim 1, In the step (b), the buffer status information transmitted from the mobile terminal is included in the header of the packet transmitted from the mobile terminal, characterized in that the uplink signaling method for streaming services in a packet mobile communication system. The method according to claim 1 or 2, In step (a), Receiving a resource allocation request including characteristic information of a packet service from the mobile terminal; Calculating an average data rate per subcarrier group using an uplink channel state of the entire base station; Allocating an uplink resource using the average data rate and characteristic information of a packet service received from the mobile terminal; And And setting a transmission allowance window by comparing the data transmission rate delivered from the mobile terminal with the calculated average data transmission rate. The method of claim 3, wherein And measuring an uplink channel state by using a channel state measurement control signal periodically received from the mobile terminal according to the uplink resource allocation. Signaling method. The method of claim 4, wherein The characteristic information of the packet service is An uplink signaling method for a streaming service in a packet mobile communication system, comprising a service type, a data rate, and a time constraint. The method of claim 4, wherein In the step (b), the scheduling permission information is scheduled to be transmitted at least once in the set transmission permission window and transmitted to each mobile terminal. The uplink for the streaming service in the packet mobile communication system Signaling method. The method of claim 3, wherein In step (b), Transmitting the scheduling permission information for allowing transmission to each mobile terminal at transmission time intervals based on the set transmission permission window; If data is received from each mobile terminal according to the scheduling permission information, performing an error check on the received data; If there is an error in the received data, giving a scheduling opportunity by weighting the mobile terminal in which the error occurred, and transmitting the scheduling permission information to each mobile terminal at each transmission time interval; If there is no error in the received data, checking buffer status information included in a header of a data packet received from the mobile terminal; And And transmitting the scheduling grant information to each mobile terminal by providing a scheduling opportunity in the order of high priority according to the buffer status information. The method of claim 5, wherein The uplink signaling method for the streaming service in the packet mobile communication system, characterized in that the characteristic information of the packet service is delivered to the base station in a simplified form through a transport channel for random access. The method of claim 4, wherein The average data rate calculation step, Determining an uplink average channel state value of the entire base station using an uplink channel measurement control signal received from each mobile terminal located in a cell of the base station; And And calculating a data rate per subcarrier group using the determined uplink average channel state value. The method of claim 5, wherein In the uplink resource allocation step, The uplink signaling method for the streaming service in the packet mobile communication system, characterized in that the time constraints transmitted from the mobile terminal are set to a transmission allowance period. The method of claim 7, wherein The method according to the channel state of each mobile terminal further comprising the step of transmitting scheduling permission information further uplink signaling method for a streaming service in a packet mobile communication system. The method of claim 7, wherein In the transmitting of the grant permission information based on the grant permission window, uplink signaling for a streaming service in a packet mobile communication system, wherein the scheduling grant information is transmitted in the order of the mobile terminals having the smaller transmit permission window. Way. The method of claim 7, wherein And transmitting the retransmission request to the mobile terminal having the error due to an error in the received data, and deleting the retransmission request information if the data is not received even after a certain period of time from the mobile terminal. An uplink signaling method for a streaming service in a packet mobile communication system. A packet mobile communication system comprising a mobile terminal having an uplink buffer and a base station having an uplink scheduler, First means for allocating an uplink resource and setting a transmission permission window by using characteristic information of a packet service delivered with a resource allocation request from the mobile terminal and uplink radio channel state information measured by the base station; And By using the set transmission permission window, channel state estimation information of each mobile terminal, buffer state information transmitted from each mobile terminal, and reception result information of data received from the mobile terminal, data transmission is performed to the mobile terminal at transmission time intervals. A base station apparatus for a streaming service in a packet mobile communication system including uplink scheduling means for transmitting scheduling permission information to be permitted. The method of claim 14, The first means, Channel state measurement means for measuring an uplink channel state using a channel state measurement control signal periodically received from the mobile terminal; Average data rate calculating means for calculating an average data rate per subcarrier group by using the uplink channel state of the entire base station measured by the channel state measuring means; Control information processing means for processing the control information transmitted from the mobile terminal; And Allocating an uplink resource using the calculated average data rate and the characteristic information of the packet service delivered from the mobile terminal through the control information processing means, the data rate transmitted from the mobile terminal and the calculated average data rate The base station apparatus for a streaming service in a packet mobile communication system comprising a resource allocation means for setting a transmission allowance window by comparing the two. The method of claim 15, The control information processing means, The base station apparatus for a streaming service in a packet mobile communication system, characterized in that for extracting the buffer status information of the mobile terminal included in the header of the packet transmitted from the mobile terminal to pass to the uplink scheduling means. The method of claim 15, The uplink scheduling means, On the basis of the transmission permission window set by the resource allocating means, the scheduling permission information for allowing transmission is transmitted to each mobile terminal at transmission time intervals. A streaming service is provided in a packet mobile communication system by increasing a weight to give a scheduling opportunity, and granting a scheduling opportunity in an order of high priority according to the buffer state information of the mobile terminal transmitted from the control information processing means. Base station device for. The method of claim 17, The characteristic information of the packet service is A base station apparatus for a streaming service in a packet mobile communication system comprising a service type, a data rate and a time constraint. The method of claim 17, And the uplink scheduling means schedules the transmission permission to be performed at least one time in the set transmission allowance window. The method of claim 18, The base station apparatus for streaming service in a packet mobile communication system, characterized in that the characteristic information of the packet service is delivered to the base station in a simplified form through a transport channel for random access. The method of claim 17, The average data rate calculating means, The uplink average channel state value of the entire base station measured by the channel state measuring means is determined, and the data rate per subcarrier group is calculated using the determined uplink average channel state value. Base station device for. The method of claim 17, The resource allocation means, The base station apparatus for the streaming service in the packet mobile communication system, characterized in that for setting the time constraints transmitted from the mobile terminal through the control information processing means as a transmission allowance period. The method of claim 17, The uplink scheduling means, A base station apparatus for a streaming service in a packet mobile communication system, wherein the priority is given according to the channel state of each mobile terminal to permit scheduling. The method of claim 17, The uplink scheduling means, The base station apparatus for a streaming service in a packet mobile communication system, characterized in that to allow scheduling in the order of the mobile terminal is small the transmission permission window. The method of claim 17, Means for deleting the retransmission request information if the received data has an error and transmits the retransmission request to the mobile terminal having the error, and if the data is not received even after a certain period of time from the mobile terminal. Base station apparatus for streaming service in packet mobile communication system. delete delete delete delete

Images