KR20100073695A - Method of effecting outer loop power control using supervision of base station controller in 1xev-do system - Google Patents

Abstract

PURPOSE: An outer loop power control using the management of a control station of 1xEV-DO system is provided to realize the control of quick PCT by performing each outer loop power control. CONSTITUTION: A part of or a whole base stations of the plurality of base stations receive a packet of the same time stamp from a mobile station(102). A mobile switching center(108) receives the packet from the mobile station. The control station obtains packet error mismatching number to each part of or each whole base station based on packets. The control station transmits a PCT(Power Control Threshold) control signal to one or more base stations of the part of or the whole base station based on the packet error mismatching number.

Description

METHOD OF EFFECTING OUTER LOOP POWER CONTROL USING SUPERVISION OF BASE STATION CONTROLLER IN 1xEV-DO SYSTEM}

The present invention relates to a power control (reverse power control) method of a signal transmitted from a mobile station to a base station in a 1xEV-DO system, and more specifically, in a soft-handoff situation, a control station ( A method of optimizing the transmission power of a mobile station using a supervision of a base station controller.

In general, according to the 1xEV-DO communication method, since multiple users share the same time and frequency, interference caused by multiple access occurs. In order to reduce the interference while maintaining the quality of the data channel above a certain level, it is necessary to adjust the transmission power between the base station and the mobile station. As a method of adjusting the transmission power, a forward power control method that largely controls the power transmitted from the base station to the mobile station and a reverse power control method that controls the power transmitted from the mobile station to the base station are exist. Among these, in relation to the reverse power control, the transmission power of the mobile station is generally determined based on the power received from the base station under the assumption that the forward and reverse radio environment path losses between the mobile station and the base station are the same. However, since the wireless environment changes rapidly at various moments due to various causes (for example, the movement of the mobile station, the change of the medium), the forward and reverse wireless environments are very unlikely to be the same. Therefore, determining the transmission power of the mobile station based on the power received from the base station may cause problems in maintaining the wireless communication quality.

As a method for resolving this problem, a closed loop power control (CLPC) scheme is used in which a base station measures power of a signal received from a mobile station to correct transmission power of the mobile station. According to the CLPC scheme, the base station measures the power of the pilot signal received from the mobile station and compares the measured value with a power control threshold (PCT). If it is determined that the power of the pilot signal is lower than the PCT, the base station determines that there is a problem in maintaining the reverse radio quality, and thus transmits an Up Power Control Bit (Up PCB) to increase the transmission power of the mobile station. On the other hand, if it is determined that the power of the pilot signal is higher than the PCT, the down power control bit is determined to reduce the transmission power of the mobile station by determining that the pilot signal may interfere with the pilot signal received from another mobile station. Down Power Control Bit: Down PCB) is transmitted to the mobile station. The mobile station increases or decreases its transmit power in accordance with the received power control bits.

As such, the CLPC focuses on adjusting the transmit power of the mobile station by comparing the power of the pilot signal received from the mobile station with the PCT, but the quality of service actually felt from the user's point of view is the Packet Error Rate (PER). This PER can be changed by the fading environment (e.g., mobile speed, channel status, etc.) of each mobile station, and simply control the transmit power of the mobile station using a fixed PCT value. There is a limit to maintaining service quality. Accordingly, an outer loop power control (OLPC) scheme is introduced that adjusts the PCT value in response to a PER that may change from time to time. Specifically, according to the OLPC method, when a base station receives a packet from a mobile station, if a cyclic redundancy check (CRC) error occurs in the packet, the PCT is increased by a predetermined value, and if the packet does not occur, the PCT is increased. A method of decreasing by a predetermined value is used.

This OLPC may be performed at the base station or control station. The base station performs the OLPC, the base station receives the packet from the mobile station to check whether the packet error is made in the form of adjusting the PCT value according to the packet error. This approach may be appropriate when one base station and one mobile station communicate with each other, but may not be suitable for soft handoff where two or more base stations communicate with one mobile station. For example, when base stations A and B each receive a packet from a mobile station, and an error occurs in a packet received by base station A and no error occurs in a packet received by base station B, only the PCT of base station A is increased and The PCT remains intact, resulting in an imbalance between the PCTs of base stations A and B.

On the other hand, the control station performs the OLPC, because the control station receives packets from all base stations involved in soft handoff, compares the packets for errors, and gives each base station the same PCT change command. It can solve the problem of PCT imbalance. However, since this method sends a PCT change command to each base station whenever the control station receives a packet from the base stations, the relay line load between the control station and the base station increases, and additional communication between the base station and the control station ( There is a problem that the OLPC is delayed by requiring continuous transmission of the PCT change command.

An object of the present invention is to solve the problems of the prior art described above, in order to solve the problem that PCT imbalance between base stations occurs when the OLPC is performed in the base station under a soft handoff environment, The present invention provides a method of predicting PCT imbalance between base stations by synthesizing the reception states and adjusting PCT for each base station only when it is determined that the degree of PCT imbalance is more than a specific value.

According to one aspect of the present invention, a method is provided for a control station to perform supervision on a plurality of base stations that perform outer loop power control (OLPC). The control station receives a packet with the same time stamp from some or all of the base stations among the plurality of base stations, each of which has received a packet with the same time stamp from the mobile station. Based on the received packets, the number of packet error mismatches is obtained for each of some or all of the base stations. Then, a Power Control Threshold (PCT) coordination signal is sent to one or more of the some or all of the base stations based on the number of packet error mismatches for each of some or all of the base stations, thereby causing a PCT imbalance between the base stations. Adjust it.

According to an embodiment of the present invention, the base station determines whether the difference between the maximum value and the minimum value of the packet error mismatches is greater than or equal to the predetermined threshold value, so that the difference between the maximum value and the minimum value is greater than the predetermined threshold value. If it is determined to be the same or the same, the power control reference adjustment signal is transmitted to one or more base stations of some or all base stations.

According to one embodiment of the invention, the control station sets parameters indicating the reception states of a packet each of which some or all of the base stations receive from the mobile station, and integrates the reception states of the packets received by some or all of the base stations. A parameter indicating the reception state is set, and the number of packet error inconsistencies is obtained for each of some or all of the base stations based on the parameters indicative of such reception states and the parameters incorporating the reception states.

According to one embodiment of the invention, when the control station first receives a packet with the same time stamp from one of some or all of the base stations, the control station enables a timer with a predetermined expiration period, Receive a packet with the same time stamp from another base station until it expires.

According to an embodiment of the present invention, each of the parameters indicating the reception states has a value indicating that an error has occurred in the received packet, or a value indicating that no error has occurred in the received packet.

According to an embodiment of the present invention, a parameter incorporating reception states may be a value indicating that all or all of the base stations that have received a packet from the mobile station have received a packet in error, or that the packet has been received from the mobile station, or At least one or more of the base stations has a value indicating that an error free packet has been received.

According to one embodiment of the invention, the control station transmits a PCT coordination signal to one or more base stations with a maximum number of packet error mismatches.

According to one embodiment of the present invention, after transmitting the PCT coordination signal to one or more base stations, the control station updates the packet error mismatch number for the base station to the minimum value.

According to one embodiment of the present invention, the plurality of base stations performs soft handoff with the mobile station.

According to one embodiment of the present invention, the plurality of base stations communicate with the mobile station according to the 1xEV-DO scheme.

According to an embodiment of the present invention, a packet received by a plurality of base stations includes a CRC value.

According to one aspect of the present invention, a method is provided in which a control station performs supervision of a plurality of base stations performing outer loop power control. The control station initializes the number of packet error mismatches for the plurality of base stations and receives the same time stamp packets from some or all of the base stations of the plurality of base stations, each of which received the same time stamp packet from the mobile station. Accumulate the number of packet error mismatches for each of some or all of the base stations from the received packets. The control station repeats the operation of receiving packets from the base stations and accumulating packet error mismatches for at least one time stamp that is different from the time stamp. The control station then sends a power control reference adjustment signal to one or more of the some or all of the base stations based on the number of packet error mismatches for each of some or all of the base stations to adjust the PCT imbalance.

According to embodiments of the present invention, since the OLPC is performed at each of the base stations, it is possible to adjust the PCT faster than the OLPC is performed at the control station, and at the same time, the control station predicts the occurrence of PCT imbalance between the base stations. Therefore, since the PCT adjustment signal is sent to one or more base stations only when it is determined that the degree of PCT imbalance is equal to or above a certain reference value, the PCT imbalance can be adjusted while reducing the relay line load between the control station and the base stations. As a result, it is possible to optimize the transmission power of mobile stations communicating with these base stations by balancing the PCT values of the respective base stations.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Hereinafter, if it is determined that there is a risk of unnecessarily obscure the subject matter of the present invention, a detailed description of the known functions and configurations will be omitted. In addition, it should be understood that the following description relates to one embodiment of the present invention, but the present invention is not limited thereto.

1 is a diagram schematically illustrating a 1xEV-DO system in which an OLPC is performed by base stations in a soft handoff situation and a control station supervisions these base stations according to an embodiment of the present invention. Although FIG. 1 shows that two base stations perform a soft handoff for convenience, according to another embodiment of the present invention, a larger number of base stations may be involved in the soft handoff. In addition, although not shown in the figure, a plurality of mobile stations may simultaneously perform soft handoff with two or more base stations.

Mobile station 102 performs soft handoff with base station A 104 and base station B 106. In a soft handoff situation, mobile station 102 exchanges data with base station A 104 and base station B 106 over a reverse and forward wireless link. Mobile station 102 receives signals from base station A 104 and base station B 106 and correspondingly transmits pilot signals including packets to base station A 104 and base station B 106. The packet contains a CRC value, so that the receiving side can know whether an error has occurred during the transmission of the packet.

When base station A 104 and base station B 106 receive a packet from mobile station 102, it determines whether a CRC error has occurred in the received packet, and adjusts a power control threshold (PCT) accordingly. do. Specifically, as shown in FIG. 1, base station A 104 determines that an error has occurred in a packet received from mobile station 102 and increases its PCT value by a predetermined value, while base station B 106 Determines that no error has occurred in the packet received from the mobile station 102 and decreases its PCT value by a predetermined value. In addition, each of the base stations A and B 104 and 106 transmits a packet received from the mobile station 102 to the control station 108.

The control station 108 is a device that performs control of the base stations A and B 104 and 106 and the mobile station 102, and is a packet error for each base station based on packets received from the base stations A and B 104 and 106. Measure the number of packet error mismatches. Packet error mismatch for a base station means that the same base station receives the same packet transmitted from the mobile station with a packet error, but at least one of the other base stations involved in the soft handoff is received without a packet error. do. For example, as shown in FIG. 1, when base stations A and B 104 and 106 receive the same packet from mobile station 102, the packet received by base station A 104 has failed and base station B has received an error. Since the packet received by 106 does not generate an error, a packet error mismatch occurs only for the base station A 104. If a packet error mismatch occurs, the PCT value is different for each base station, and the control station 108 determines the PCT for one or more base stations when the number of packet error mismatches exceeds a predetermined reference value in order to prevent such an unbalance of the PCT value. Carry out a supervision. In order to act as a supervisor, the control station 108 manages the parameters BTS_X_T_PacketState and T_PacketState described later.

The parameter BTS_X_T_PacketState is a value indicating a reception state of a packet whose time stamp T is received by an arbitrary base station (base station X) from the mobile station, and the control station receives a packet having a time stamp T from any base station X. Is updated every time. The time stamp is the system time at which the packet is sent from the mobile station to the base station, which is measured at the base station's modem. The value of BTS_X_T_PacketState may have a value specifically described in Table 1 below.

Value of BTS_X_T_PacketState Instruction content NO_RCV Base station X never received a packet with time stamp T CRC_PASS No error in packet with time stamp T received by base station X CRC_FAIL Error in packet with time stamp T received by base station X

The parameter T_PacketState is a value representing the reception state of each base station for a packet having a time stamp T. The default value of the T_PacketState is NO_RCV and is updated based on the aforementioned BTS_X_T_PacketState. The value of T_PacketState may specifically have a value described in Table 2 below.

Value of T_PacketState Instruction content NO_RCV No base station has ever received a packet with time stamp T CRC_PASS A base station receives a packet with time stamp T, at least one of which receives an error free packet CRC_FAIL There is a base station that has received a packet with timestamp T, and all of these base stations receive the failed packet

On the other hand, the control station 108 receives a packet having the same time stamp from the base stations involved in the soft handoff, wherein the time at which the packet is received from the base stations is different and in some cases among the base stations involved in the handoff. Since packets may not be received from some base stations, the control station 108 needs to limit the time for receiving packets from the base stations. For this purpose, the control station 108 uses Packet_Timer_T, a timer for waiting for the reception of a packet with time stamp T. That is, when the control station 108 first receives a packet with time stamp T from one of the base stations, it enables Packet_Timer_T and waits for packet reception from other base stations until Packet_Timer_T expires.

2 is a block diagram illustrating a process of setting parameter values required for a control station to adjust PCTs of base stations.

First, the control station 108 waits for a new event (S202). Next, in step 204, it is determined whether an event in which Packet_Timer_T expires has occurred. If it is determined that an event has expired, Packet_Timer_T proceeds to step 222 described later to disable Packet_Timer_T and terminate parameter setting. If an event in which Packet_Timer_T expires has not occurred, it is determined whether a reception event of a packet having a time stamp T has occurred from an arbitrary base station (base station X) (S206). If no receive event of a packet with time stamp T has occurred, the process returns to step 202 to wait for the event. On the other hand, if a reception event of a packet with time stamp T from any base station (base station X) occurs, the process proceeds to step 208. In FIG. 2, after determining whether an event in which Packet_Timer_T expires occurs, it is determined whether a reception event of a packet having a time stamp T has occurred from the base station. However, according to another embodiment of the present invention, these two determination steps The order may be reversed or may be determined at the same time.

In step 208, the control station 108 updates the parameter BTS_X_T_PacketState using the reception status of the packet with the time stamp T received from the base station X. For example, as shown in FIG. 1, when the control station 108 receives a packet (an error packet) received from the mobile station 102 by the base station A 104, the control station is received. 108 updates the BTS_A_T_PacketState to CRC_FAIL. On the other hand, when the control station 108 receives a packet (a packet in which no error occurs) from the base station B 106, it updates the BTS_B_T_PacketState to CRC_PASS.

The control station 108 then determines whether the T_PacketState value is NO_RCV (step 210). If it is determined that the T_PacketState value is not NO_RCV, the process proceeds to step 214. If it is determined that the T_PacketState value is NO_RCV, the control station 108 enables Packet_Timer_T described above (S212), and the process proceeds to step 214. This Packet_Timer_T expires after proceeding for Packet_Wait_Time, which is the maximum time waiting for packet reception. Specifically, referring to FIG. 1, when the control station 108 first receives a packet having a time stamp T from the base station A 104, the control station because T_PacketState is set to NO_RCV (default). 108 first enables Packet_Timer_T to prepare to receive packets with time stamp T from base station B 106 only for a predetermined period (Packet_Wait_Time).

In step 214, the control station 108 determines whether the T_PacketState value is CRC_PASS. If it is determined that the T_PacketState value is CRC_PASS, the process proceeds to step 218. If it is determined that the T_PacketState value is not CRC_PASS (when the T_PacketState value is NO_RCV or CRC_FAIL), the control station 108 uses the reception state of the packet having the time stamp T received from the base station X, that is, the T_PacketState value using the BTS_X_T_PacketState value. Update (S216). In detail, when the BTS_X_T_PacketState value is CRC_PASS (when there is no error in the packet), the T_PacketState value is updated to CRC_PASS, while when the BTS_X_T_PacketState value is CRC_FAIL (when there is an error in the packet), the T_PacketState value is updated to CRC_FAIL. For example, as described in step 208, if the control station 108 receives from the base station A 104 a packet (an error occurred) received by the base station A 104 from the mobile station 102, the control station 108 Update the BTS_A_T_PacketState value to CRC_FAIL, and update the T_PacketState value from NO_RCV (default) to CRC_FAIL based on this BTS_A_T_PacketState value. On the other hand, when the control station 108 receives an error free packet from the base station B 106, the control station 108 updates the BTS_B_T_PacketState value to CRC_PASS, and based on this BTS_B_T_PacketState value, sets the T_PacketState value to NO_RCV (default). Value) to CRC_PASS.

In step 218, the control station 108 increments the T_PacketRcvCnt value, which represents the number of packets with time stamp T received from the base station, by one. That is, the control station 108 increments the T_PacketRcvCnt value by 1 each time a reception event of a packet having a time stamp T occurs once. The control station 108 then determines whether the T_PacketRcvCnt value matches the number of base stations involved in soft handoff (S220). If it is determined that the T_PacketRcvCnt value does not match the number of base stations involved in soft handoff, the process returns to step 202 to further receive packets of time stamp T from other base stations. If the T_PacketRcvCnt value matches the number of base stations involved in soft handoff, Packet_Timer_T is disabled (S222), whereby the parameter setting operation is terminated (S224).

3 is a block diagram illustrating a process in which a control station performs supervision of base stations according to a set parameter.

The control station 108 receives the packets having the time stamp T from the base stations and terminates the parameter setting (S302), and then determines whether the T_PacketState value is CRC_FAIL (S304). If the T_PacketState value is CRC_FAIL, the process proceeds to step 314 where the control station 108 terminates supervision of the base stations that have received the packet with time stamp T. Since the T_PacketState value is CRC_FAIL, it means that all the base stations have received a packet having the same time stamp T as the error. Therefore, the control station 108 terminates the supervision of the base station without the procedure of adjusting the PCT for each base station.

On the other hand, when the T_PacketState is not CRC_FAIL, the control station 108 increases the BTS_X_Imbalance of the base station X by which the BTS_X_T_PacketState value of the base stations involved in the soft handoff is not CRC_PASS by 1 (S306). BTS_X_Imbalance means the number of occurrences of a packet error mismatch for an X base station (when the same base station receives a packet error while at least one of the other base stations receives a packet error). For example, referring to FIG. 1, the control station 108 receives a packet with time stamp T from the base stations A and B 104 and 106 and sets the parameter setting as BTS_A_T_PacketState = CRC_FAIL, BTS_B_T_PacketState = CRC_PASS, T_PacketState = CRC_PASS. Upon completion, control station 108 increments BTS_A_Imbalance for base station A 104 that received the packet in error by 1, while BTS_B_Imbalance for base station B 106 that received the packet in error did not increase. Keep that value. More specifically, packets with different time stamp values (eg, time stamps T-4, T-3, T before the control station 108 receives packets with time stamp T from base stations A and B 104 and 106). -2, T-1 packets) and the value of BTS_A_Imbalance is set to 4 and the value of BTS_B_Imbalance is set to 1, the control station 108 receives the packet of time stamp T so that the value of BTS_A_Imbalance is equal to 1 Increase it to 5 and keep the BTS_B_Imbalance value at 1.

Next, the control station 108 obtains a maximum value (Max), minimum value (Min), and a delta value that is a difference between the maximum value and the minimum value among the BTS_X_Imbalacne for the base stations involved in the soft handoff (S308). For example, if the value of BTS_A_Imbalance is set to 5 and the value of BTS_B_Imbalance is set to 1 for the base stations A and B 104 and 106 involved in soft handoff as shown in FIG. 1, the maximum value is 5 and the minimum value is 1. , Delta value is 4.

After obtaining the maximum value, the minimum value, and the delta value, the control station 108 determines whether the delta value is greater than or equal to the predetermined threshold value Imbalance_Threshold (S310). According to one embodiment of the invention, the predetermined threshold may be appropriately set according to the characteristics of the wireless communication system. If it is determined that the delta value is less than the predetermined threshold, the process proceeds to step 314 where supervision of the control station 108 ends. If it is determined that the delta value is greater than or equal to the predetermined threshold value, the BTS_X_Imbalance signal is transmitted to the base station X having the maximum value indicating that the PCT of the base station needs to be adjusted, and the BTS_X_Imbalance value for the base station is updated to the minimum value (S312). ). For example, as described above, when the parameters are set to BTS_A_Imbalance = 5 (maximum value), BTS_B_Imbalance = 1 (minimum value), and delta = 4, and the threshold value is set to 4, the delta value and the threshold value match. The control station 108 determines that it is necessary to adjust the PCT of the base station A, which has a relatively large packet error mismatch, transmits a PCT adjustment signal to the base station A, and updates the BTS_A_Imbalance to a minimum value of 1. That is, the control station 108 determines that the base station A 104 is in a state where the PCT value of the base station A 104 is increased more than necessary because the packet error inconsistency occurs in comparison with the base station B 106. A signal for adjusting the PCT value of A is transmitted to the base station A. In this way, supervision of the base stations receiving the packet having the time stamp T is terminated (S314). 2 and 3 illustrate a process when the base stations receive a packet having a time stamp T, but each time the base stations receive a packet having a different time stamp (e.g., a packet having a time stamp T + 1). The process of is performed repeatedly.

As described above, one embodiment of the present invention for understanding the present invention has been described, but as will be appreciated by those skilled in the art, the present invention is not limited to the examples described herein but is not limited to the scope of the present invention. It can be variously modified, reconfigured and replaced. Accordingly, all modifications and changes that fall within the true spirit and scope of the present invention are intended to be covered by the claims.

1 is a diagram schematically illustrating a 1xEV-DO system in which OLPC is performed by base stations in a soft handoff situation and a control station supervisions the base stations according to an embodiment of the present invention.

2 is a block diagram illustrating a process of setting parameter values required for a control station to adjust PCTs of base stations.

3 is a block diagram illustrating a process in which a control station performs supervision of base stations according to a set parameter.

<Description of Symbols for Main Parts of Drawings>

102: mobile station

104, 106: base station

108: control station

Claims (12)

A method of supervision of a control station with respect to a plurality of base stations that perform outer loop power control (OLPC), Receiving packets having the same time stamp from some or all of the base stations of the plurality of base stations, each having received the same time stamp from the mobile station; Obtaining a packet error mismatch count for each of the some or all base stations based on the received packets; And Transmitting a Power Control Threshold (PCT) coordination signal to one or more of the some or all base stations based on the number of packet error mismatches for each of the some or all base stations How to include. The method of claim 1, The adjustment signal transmission step Determining whether a difference between a maximum value and a minimum value of the packet error mismatch numbers is greater than or equal to a predetermined threshold value; And If it is determined that the difference between the maximum value and the minimum value is greater than or equal to a predetermined threshold, transmitting a power control threshold adjustment signal to one or more of the some or all of the base stations. / RTI &gt; The method of claim 1, The step of obtaining the number of packet error mismatches Updating parameters indicative of reception states of a packet received from the mobile station by each of the some or all base stations based on the reception states of the packet received from the some or all base stations; Based on the parameters, updating a parameter representing the reception states of packets received by the some or all base stations; And Obtaining a packet error inconsistency count for each of the some or all base stations based on the parameters indicative of the reception states and the parameters integrating the reception states; / RTI &gt; The method of claim 1, Receiving the packets from some or all of the base stations of the plurality of base stations, each of which has received the same time stamp from the mobile station, respectively Enabling a timer with a predetermined expiration period upon first receiving the packet with the same time stamp from one of the some or all base stations; And Receiving a packet with the same time stamp from another base station until the timer expires / RTI &gt; The method of claim 3, Wherein each of the parameters representing the reception states has a value indicating that an error has occurred in a received packet or a value indicating that no error has occurred in a received packet. The method of claim 3, The parameter incorporating the reception states is a value indicating that all of the some or all base stations receiving the packet from the mobile station have received an errored packet, or at least some or all of the base stations receiving the packet from the mobile station. At least one base station has a value indicating that an error free packet has been received. The method of claim 2, The number of packet error mismatches for the one or more base stations is the maximum value. The method of claim 7, wherein Updating the number of packet error mismatches for the one or more base stations from the maximum value to the minimum value How to include more. The method of claim 1, And wherein the plurality of base stations perform soft handoff with the mobile station. The method of claim 1, And wherein the plurality of base stations communicates with the mobile station in a 1xEV-DO scheme. The method of claim 1, And wherein said packet contains a CRC value. A method in which a control station performs supervision of a plurality of base stations that perform outer loop power control, A) initializing a packet error mismatch number for a plurality of base stations; B) receiving packets having the same time stamp from some or all of the base stations of the plurality of base stations, each receiving a packet having the same time stamp from the mobile station; C) accumulating the number of packet error mismatches for each of the some or all base stations from the received packets; D) repeating steps b) and c) for at least one time stamp different from the time stamp; And E) transmitting a power control reference adjustment signal to one or more of the some or all base stations based on the number of packet error mismatches for each of the some or all base stations; How to include.

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