KR20020058616A - Method for controlling supplemental channel in is-95c 1x system - Google Patents

Abstract

PURPOSE: A method for controlling an SCH(Supplemental CHannel) in an IS-95C 1X system is provided to efficiently use radio resources by executing the allocation and release of an SCH according to control parameters designed in consideration of the characteristics of a TCP(Transmission Control Protocol) used as an end-to-end protocol. CONSTITUTION: In an idle state(QOS_STATE_IDLE), in case that data transmission through the presently allocated SCH does not exist and the residual data amount of a buffer is larger than a recovery start threshold(otax_start_thresh), the value of a counter is set as a recovery start wait threshold(otax_start_wait). Then the present state is transited to a recovery wait state(QOS_STATE_WAIT_OTAX)(S21). However, in case that the residual data amount of the buffer is smaller than the recovery start threshold(otax_start_thresh), a data transmission stop procedure is executed(S23). Also, in case that the residual data amount of the buffer is larger than an upper threshold(up_thresh) and the bit rate(SCH_RATE) of the presently allocated SCH is smaller than the maximum SCH rate, the value of the counter is set as an upper wait threshold value(up_wait). Then the present state is transitted to a bit rate up wait state(QOS_STATE_WAIT_UP)(S24). Also, in case that the residual data amount of the buffer is smaller than or equal to a lower threshold(down_thresh) and the bit rate of the presently allocated SCH is larger than the minimum SCH rate, the value of the counter is set as a lower wait threshold value(down_wait). Then the present state is transitted to a bit rate down wait state(QOS_STATE_WAIT_DOWN)(S22).

Description

Method for Controlling Supplemental Channel in IS-95C 1X System

The present invention relates to an IC-95C 1X system, and more particularly, to a control method of an auxiliary channel (SCH) for providing up to 144 Kbps forward packet data service. According to the characteristics of TCP used as an end-to-end protocol for efficient use of the wireless interval band according to the A secondary channel control method of a 95C 1X system.

In general, the IS-95C has evolved from the IS-95B. However, since the IS-95C is supported up to 144Kbps, a video transmission service can be implemented. Thus, speed is less than IMT-2000, but similarly provides most of the services discussed in IMT-2000 as a protocol between the terminal and the base station controller.

As such, the improvement in transmission speed up to 144 Kbps in IS-95C is possible because the modulation rate of the supplemental channel (hereinafter abbreviated as SCH) is implemented so that it depends on the amount of data transmitted from the upper layer. It became.

Accordingly, in the IS-95C 1X system using the SCH, methods for efficiently controlling the SCH to efficiently use radio resources are being sought, and a detailed method has not been proposed yet.

Accordingly, an object of the present invention has been made in view of the above-mentioned problems of the prior art, and to perform the transmission rate and channel allocation and release procedure of the SCH according to a control parameter considering the characteristics of TCP used as an end-to-end protocol. To provide an auxiliary channel control method of the IS-95C 1X system to efficiently use the resources of the radio section.

According to an aspect of the present invention for achieving the above object, when the amount of data in the buffer in the initial state increases above the first threshold, the channel allocation or in use of the channel after the first waiting threshold A first step of increasing the transfer rate and transitioning to an initial state and, if the amount of data in the buffer in the initial state of the first step is greater than the second threshold, then the transmission of data that has been interrupted after the second waiting threshold is stopped. A second step of initiating and transitioning to an initial state; and, if the amount of data in the buffer in the initial state of the second step decreases below a third threshold, release of the channel being used after the third waiting threshold, or The third step is to reduce the transmission speed and transition to the initial state.

Preferably, the method further includes the step of waiting for the first waiting threshold when the transmission rate of the channel being used in the first step is smaller than the preset maximum speed and larger than the first threshold. Also, in the first step, when the amount of data in the buffer is less than or equal to the first threshold within the first waiting threshold, the transition to the initial state. At this time, the data transmission through the channel is started, and after the transition to the initial state, if the amount of data in the buffer is smaller than the fourth threshold for interrupting transmission, the data being transmitted is stopped.

On the other hand, if there is a channel allocated in the second step, but the data transmission is not performed further comprises the step of waiting for a second waiting threshold when the data amount of the buffer is larger than the second threshold. Further, in the second step, when the amount of data in the buffer is less than or equal to the second threshold within the second waiting threshold, the transition to the initial state.

On the other hand, in the third step, when the amount of data in the buffer is greater than the third threshold within the third waiting threshold, the initial state transitions, and in the third step, the amount of data in the buffer is the third threshold value. If less than or equal to, further comprising waiting by a third waiting threshold. At this time, if the amount of data in the buffer is less than the fourth threshold for interrupting the transmission in the standby state, the data being transmitted is stopped.

1 is a diagram illustrating a control state transition diagram of an auxiliary channel according to the present invention.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

In the present invention, a method of controlling a supplemental channel (hereinafter, referred to as SCH) is a sliding window protocol of a transmission control protocol (hereinafter, referred to as TCP) that operates as an end-to-end protocol in packet data service. It consists of a process of state transition under four states based on QoS control parameter values designed considering Window Protocol, and the SDU function (Select Distributed Unit Function) of the base station in charge of the Medium Access Control layer. Implemented in

Among the QoS control parameters implemented here, four parameters of the upper threshold value (up_thresh), the upper wait threshold value (up_wait), the lower threshold value (down_thresh), and the lower wait threshold value (down_wait) are determined according to the QoS of the SCH. The essential parameters of the control method are three parameters: recovery start threshold (otax_start_thresh), recovery start wait threshold (otax_start_wait) and recovery stop threshold (otax_stop_thresh). This is an additional parameter that can make it more efficient.

The upper threshold (up_thresh) and the upper wait threshold (up_wait) are thresholds used for allocating an SCH or increasing a transmission rate of an already allocated SCH. When the amount is greater than the upper threshold up_thresh for a time equal to the upper wait threshold up_wait, the SCH is allocated or the transmission speed is increased. In the sliding window protocol of TCP, flow control is performed by transmitting a buffer size (window size) that can receive data to a counterpart TCP in an acknowledgment signal (ACK). That is, the amount of data to be transmitted that is sent by the SDU and stored in the SDU's current internal buffer is larger than the upper threshold value (up_thresh) indicates that the SDU is larger because the current receivable window size of the receiving TCP is larger than the upper threshold value (up_thresh). This means that the amount of data transmission is increased, or the received data of the SDU is accumulated in the buffer and is momentarily larger than the threshold. In the former case, the SDU must allocate the SCH or increase the transmission rate of the allocated SCH for the transmission of the increased data. However, the latter case may be a temporary phenomenon. In addition to the threshold (up_thresh), the backup delay value is set as much as the upper wait threshold (up_wait), and the amount of data remaining in the buffer is periodically checked during the delay time. If large, i.e., only when the SDU is determined to increase the amount of data transmission, the SCH allocation or transmission rate increase procedure is performed, thereby preventing frequent occurrence of SCH allocation or transmission rate increase. Here, even if the transmission rate of the SCH increases, the amount of data measured during the time equal to the upper wait threshold (up_wait) is greater than the upper threshold value (up_thresh), rather than the amount of data transmitted at the transmission rate of the current SCH. This means that more data comes from the Packet Data Servicing node, so we can determine the increase in transmission rate. Two parameters, the upper threshold (up_thresh) and the upper wait threshold (up_wait), are used to determine Regardless of the transmission rate, the reference value is used to determine allocation of the SCH or increase of the transmission rate of the SCH.

The lower threshold (down_thresh) and the lower wait threshold (down_wait) are two parameters that are used as a reference for reducing the transmission speed of the SCH or releasing the SCH when the transmission speed is already at the lowest speed. When the amount of data to be transmitted in the forward direction remaining at is less than or equal to the lower threshold (down_thresh) for a time equal to the lower wait threshold (down_wait), the transmission rate of the SCH is reduced or released. As described in the case of the upper threshold value up_thresh, when it is determined that the amount of transmission from the actual SDU is reduced by using two parameters, the lower threshold value down_thresh and the lower delay value down_wait, which is a backup delay value. Only reduce or cancel the transmission rate of the SCH.

The recovery start threshold (otax_start_thresh) and the recovery start wait threshold (otax_start_wait) are two thresholds that are used as a reference for restoring data transmission when data transmission through the SCH is interrupted. The transmission is restored only when the amount of data to be transmitted in the forward direction is greater than the recovery start threshold (otax_start_thresh) for a time equal to the recovery start wait threshold (otax_start_wait). That is, the transmission recovery is determined by using the recovery start wait threshold (otax_start_wait) as a backup delay value as the two parameters, the upper threshold value up_thresh and the lower threshold value down_thresh described above.

The recovery stop threshold (otax_stop_thresh) stops the transmission of the SCH if data transmission through the SCH is in progress and the amount of data remaining in the buffer is less than the recovery stop threshold (otax_stop_thresh), so that the payload field of the SCH cannot be filled. To efficiently use the radio section resources.

The state transition diagram using such a parameter is shown in FIG.

1 is a diagram illustrating a control state transition diagram of an auxiliary channel according to the present invention.

Referring to Figure 1, there is an initial state (QOS_STATE_IDLE), so that transitions to the other three states always begin from this initial state. In this initial state, transitions to the other three states are determined by conditions based on the above-described QoS control parameter values (up_thresh, up_wait, down_thresh, down_wait, otax_start_thresh, otax_start_wait, and otax_stop_thresh).

The recovery wait state (QOS_STATE_WAIT_OTAX) temporarily stops data transmission through the SCH when the data to be forwarded decreases sharply.In order to recover the data transmission through the SCH when the amount of data increases above the reference value Transition to this state.

The transmission rate increase wait state (QOS_STATE_WAIT_UP), when the amount of data to be transmitted in the forward direction increases, allocates the SCH if the SCH is not allocated, and transitions to this state to increase the transmission rate if it is already allocated.

When the amount of data to be transmitted in the forward direction decreases, the QOS_STATE_WAIT_DOWN waits to release the SCH when the transmission rate of the SCH is the lowest rate, and to reduce the transmission rate when the transmission rate is not the minimum rate. .

Therefore, there is no data transmission through the currently allocated SCH (SCH_ALLOC == YES) in the initial state (QOS_STATE_IDLE) (SCH_TX == NO), and the amount of data remaining in the buffer (BUFF) is the recovery start threshold (otax_start_thresh). If greater, the value of the counter (COUNTER) is set to the recovery start wait threshold (otax_start_wait) and transitions to the recovery wait state (QOS_STATE_WAIT_OTAX). (S21) However, data is currently being transmitted through the SCH (SCH_TX). == YES), if the amount of data remaining in the buffer BUFF is smaller than the recovery stop threshold taox_stop_thresh, the data transmission stop procedure is performed (SCH_TX = NO) (S23). Also, in the initial state (QOS_STATE_IDLE), if the amount of data remaining in the buffer (BUFF) is larger than the upper threshold value (up_thresh), and the transmission rate (SCH_RATE) of the allocated SCH is smaller than the maximum speed (MAX_SCH_RATE) The (COUNTER) value is set to an upper wait threshold (up_wait), and the state transitions to a transmission rate increase wait state (QOS_STATE_WAIT_UP) (S24). Also, in the initial state (QOS_STATE_IDLE), if the amount of data remaining in the buffer (BUFF) is less than or equal to the lower threshold (down_thresh), and the transmission rate (SCH_RATE) of the allocated SCH is greater than the minimum rate (MIN_SCH_RATE). In step S22, the counter COUNTER value is set to a lower wait threshold value (down_wait), and the transfer speed decrease wait state (QOS_STATE_WAIT_DOWN).

On the other hand, if the amount (BUFF) of data remaining in the buffer in the recovery wait state (QOS_STATE_WAIT_OTAX) is less than or equal to the recovery start threshold (otax_start_thresh), the transition to the initial state (QOS_STATE_IDLE) (S13). If the COUNTER value set to the recovery start wait threshold (otax_start_wait) becomes 0 immediately before the transition to this recovery wait state (QOS_STATE_WAIT_OTAX), the data transfer recovery procedure through the suspended SCH is performed, and the initial state (QOS_STATE_IDLE) is performed. Transition to (S14). However, in the recovery wait state (QOS_STATE_WAIT_OTAX), if the two conditions S13 and S14 are not satisfied, the value of the counter COUNTER is decreased by 1 (S15).

In the transmission rate increase wait state (QOS_STATE_WAIT_UP), when the amount (BUFF) of data remaining in the buffer is less than or equal to the upper threshold value (up_thresh), the state transitions to the initial state (QOS_STATE_IDLE) (S10). If the value of the counter (COUNTER) set to the upper wait threshold (up_wait) is 0 just before the transition to the speed increase wait state (QOS_STATE_WAIT_UP), the transmission speed (SCH_RATE) of the currently allocated SCH is the highest speed (MAX_SCH_RATE. If not), and performs a rate increase procedure, if the current SCH is not assigned, performs the SCH allocation procedure, and transitions to the initial state (QOS_STATE_IDLE) (S11). However, in the transmission rate increase wait state (QOS_STATE_WAIT_UP), if the conditions of S10 and S11 are not satisfied, the value of the counter is decreased by 1 (S12).

In the transmission rate reduction waiting state QOS_STATE_WAIT_DOWN, when the amount BUFF of data remaining in the buffer is greater than the lower threshold value down_thresh, the state transitions to the initial state QOS_STATE_IDLE (S16). If data is currently transmitted through the SCH (SCH_TX == YES), and the amount of data remaining in the buffer (BUFF) is smaller than the recovery stop threshold value (otax_stop_thresh), the data transmission stop procedure is performed (S17). . If the counter value set to the low wait threshold (down_wait) becomes 0 immediately before the transition to the rate reduction wait state (QOS_STATE_WAIT_DOWN), the release procedure is performed if the transmission rate (SCH_RATE) of the currently allocated SCH is the minimum rate (MIN_SCH_RATE). If it is not the minimum speed, a transmission rate reduction procedure is performed, and the state transitions to the initial state (QOS_STATE_IDLE) (S18). However, in the transmission rate reduction wait state (QOS_STATE_WAIT_DOWN), when the conditions of S16, S17, and S18 are not satisfied, the value of the counter COTNTER is decreased by one.

As described above, the present invention measures the amount of fluid data flowing from the PDSN by TCP flow control in the packet data service of the IS-95C 1X system using a parameter value designed in consideration of the sliding window protocol of TCP. The SCH allocation, release and transmission rate increase / decrease procedures are performed according to the measured result value, so that resource management of a radio section closely related to end-to-end flow control can be performed.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (9)

If the amount of data in the buffer in the initial state increases above the first threshold, after the first waiting threshold, a first step of increasing the channel allocation or using the transmission rate of the channel being used and transitioning to the initial state, In the initial state of the first step, when the amount of data in the buffer is greater than the second threshold, a second step of initiating the transfer of the interrupted data after the second waiting threshold and transitioning to the initial state; When the amount of data in the buffer decreases below the third threshold in the initial state of the second step, the third channel transitions to an initial state by decreasing the release or transmission rate of the channel being used after the third waiting threshold; The secondary channel control method of the IS-95C 1X system, characterized in that consisting of steps. The method of claim 1, further comprising: waiting for a first waiting threshold when the transmission rate of the channel being used in the first step is smaller than a preset maximum speed and is larger than a first threshold. How to control the secondary channel of the IS-95C 1X system. 3. The assistance of an IS-95C 1X system according to claim 2, wherein in the first step, an initial state transitions to an initial state when the amount of data in the buffer is less than or equal to a first threshold value. Channel control method. The method of claim 1, further comprising: waiting for a second waiting threshold when there is a channel allocated in the second step, but the data amount of the buffer is larger than the second threshold when no data transmission is performed. A secondary channel control method of an IS-95C 1X system, characterized in that made. 2. The assistance of an IS-95C 1X system in accordance with claim 1, wherein in said second step, a transition to an initial state occurs when the amount of data in said buffer is less than or equal to a second threshold within a second waiting threshold. Channel control method. 2. The secondary channel control of an IS-95C 1X system according to claim 1, wherein in the third step, an initial state transitions to an initial state when the amount of data in the buffer is larger than a third threshold within a third waiting threshold. Way. The method according to claim 1, wherein if the transmission rate of the channel being used in the third step is smaller than a preset minimum transmission rate, and the amount of data in the buffer is less than or equal to the third threshold, The auxiliary channel control method of the IS-95C 1X system characterized in that it further comprises a step. 8. The method of claim 7, wherein in the standby state, the data being transmitted is interrupted when the amount of data in the buffer is less than a fourth threshold for interrupting transmission. The method of claim 1, wherein after the data transmission through the channel is started and transitioned to an initial state, the data being transmitted is stopped when the amount of data in the buffer is smaller than a fourth threshold for interrupting the transmission. Auxiliary channel control method for IS-95C 1X systems.