KR100800730B1 - Transfer method of control signals for robust transmission time adjustment between utran and ue - Google Patents

Abstract

The present invention relates to an information transmission method that supports Adaptive Transmission Time Adjustment (hereinafter referred to as "ATTA"). The present invention provides a robust transmission time of a code division multiple communication system having a mobile terminal for measuring a time difference between the reception time of an initial discovery path of a forward dedicated physical channel and the transmission time of an uplink dedicated physical channel and transmitting the measured time difference to a wireless network controller. In the sorting method, the wireless network controller determines whether the forward dedicated physical channel is followed by the forward difference physical channel, and generates robust transmission time alignment information by using the time difference measurement according to the trailing decision. Transmitting, receiving, by the base station, the robust transmission time alignment information, and aligning a transmission time of a forward dedicated physical channel; and receiving, by the mobile terminal, the robust transmission time alignment information, a transmission time of a forward dedicated physical channel. Characterized in that the process of sorting do.

ATTA, NCF, UL DPCH, DL DPCH

Description

TRAINFER METHOD OF CONTROL SIGNALS FOR ROBUST TRANSMISSION TIME ADJUSTMENT BETWEEN UTRAN AND UE}             

1 is a view showing a visual relationship between a forward dedicated physical channel and a reverse dedicated physical channel in a handover region in a general code division multiple communication system.

2 is a diagram illustrating a method of determining control coefficients in a wireless network controller of a code division multiple access communication system according to an embodiment of the present invention.

3 is a diagram illustrating a process of generating a time difference between transmission times of a forward dedicated physical channel and a reverse dedicated physical channel in a mobile terminal of a code division multiple access communication system according to the present invention;

4 is a flowchart illustrating an adaptive transmission time adjusting method in a code division multiple access communication system according to a first embodiment of the present invention.

FIG. 5 is a diagram illustrating a process of a base station of a code division multiple access communication system according to a first embodiment of the present invention delaying a forward dedicated physical channel transmission frame according to a received NCF to align it with a reverse dedicated physical channel. FIG.

6 is a view showing a process of generating a time difference between a forward dedicated physical channel and a reverse dedicated physical channel in a mobile terminal of a code division multiple access communication system according to a second embodiment of the present invention;

7 is a flowchart illustrating an adaptive transmission time adjusting method in a code division multiple access communication system according to a second embodiment of the present invention.

8 is a view showing a time difference between a forward dedicated physical channel and a reverse dedicated physical channel after performing adaptive transmission time adjustment in a code division multiple access communication system according to a second embodiment of the present invention;

9 is a view showing a time difference between forward dedicated physical channel frames and a reverse dedicated physical channel frame on a CFN (SFN) axis in a mobile terminal of a code division multiple access communication system according to a third embodiment of the present invention;

FIG. 10 is a diagram illustrating a reverse dedicated physical channel frame and a reverse dedicated physical channel frame after performing delay alignment with a forward dedicated physical channel frame at a mobile terminal in a code division multiple access communication system according to a third embodiment of the present invention. A diagram showing the time difference between dedicated physical channel frames.

11 is a flowchart illustrating an adaptive transmission time adjusting method in a code division multiple access communication system according to a third embodiment of the present invention.

The present invention relates to a method for transmitting a dedicated physical channel frame between a base station controller and a mobile terminal in a code division multiple access communication system. In particular, an adaptive transmission time arrangement for adaptively aligning a transmission time between a base station controller and a mobile terminal ( Adaptive Transmission Time Adjustment: Hereinafter referred to as "ATTA" method.

In general, a radio network controller (hereinafter referred to as a "base station controller") of a code division multiple access communication system is referred to as a user equipment (hereinafter referred to as "UE") through a base station (hereinafter referred to as "Node B"). ) And arranges transmission time to send and receive data. In general, the transmission time alignment between the RNC and the UE refers to a downlink dedicated physical control channel (DPCCH) / dedicated physical data channel (DPDCH) (hereinafter, DPCCH and DPDCH). In this case, the uplink DPCH frame is transmitted after the T ₀ chip (1024 chips) at the time of receiving the "DPCH" frame, but in practice, the propagation time delay depends on the distance between the Node B and the UE. In this case, a serving radio network controller (hereinafter referred to as a "SRNC") is a time difference between the time at which a forward DPCH frame is received and the time at which a reverse DPCH frame is transmitted to the UE. Request to measure and report “UE Rx-Tx time difference.” The SRNC receives the UE Rx-Tx time difference from the UE in response to the request. Based on the time difference, the UE adjusts the DPCH frame offset information element (IE) of the Radio Resource Control (RRC) reconfiguration message to the UE. The SRNC can transmit the alignment of the transmission time to the UE but cannot adjust the transmission time of the UE according to the alignment of the transmission time.

Specifically, the Radio Network Subsystem Application Part (hereinafter referred to as "RNSAP") / Base Station Application Part (hereinafter referred to as "NBAP") message is associated with any IE related to forwarding time alignment. It also cannot support SRNC's DPCH forward time adjustment.

Typically, the UE transmits the uplink DPCH frame from the time point at a time, receiving the downlink DPCH frame T ₀ chips (1024 chips) obtained by adding the unit time. The initial alignment error at this time should be limited to within ± 1.5 chips. Thereafter, the UE can adjust the transmission time within a quarter chip unit for 200 ms unit time according to the time frame of the received forward DPCH.

On the other hand, when the UE enters the handover region, the UE receives a plurality of forward DPCH data, and each DPCH data has a different propagation delay value, thereby making arrangement for the reverse DPCH frame transmission time. It can't be done. In addition, the UE communicates with a source base station in a soft handover area and performs a tracking process to match a transmission time difference while performing a handover to a target base station. Even in this case, since the propagation delay time is different for the source base station and the target base station, alignment determination for transmission time cannot be performed.

In this state, when the UE leaves the handover region, the variation α for the difference between the forward DPCH data reception time and the forward DPCH data transmission time may exceed an allowable 128 chip unit size. Therefore, the UE causes a serious problem in that it cannot perform proper transmission time alignment.

1 illustrates a visual relationship between forward DPCH data and reverse DPCH data in a handover region. In FIG. 1, it is assumed that the UE moves away from cell 1 (hereinafter referred to as “cell”) 1 and moves toward cell 2. In the case of FIG. 1, the UE performs transmission time alignment as a method of adjusting the transmission time to the first cell 1, the second is a method of adjusting the transmission time to the cell 2 which is a new cell, and the third is a transmission time. This is how you fix it.

According to the first method, the UE transmits the reverse DPCH 102 after T0 after receiving the forward DPCH 100 in Cell1. However, in the second method, i.e., when the UE moves to a handover area, which is an overlapping area of cell 1 and cell 2, forward DPCHs 101, 105, 107, 110 having different propagation delay values from cell 1 and cell 2; , 111, 113). At this time, the UE does not perform reverse DPCH transmission time alignment as shown in FIG. 1 and continuously transmits reverse DPCHs 103, 109, and 112 transmitted to Cell 1 and Cell 2 at a constant time. In this state, the third method is performed when the UE leaves the handover area and enters the cell 2 area. The difference between the reception time of the forward DPCH 115 and the transmission time of the reverse DPCH 117 in the region of Cell 2 reaches T ₀ + α, and the actual α exceeds the allowable range of 128 chip units. Therefore, the UE performs transmission time adjustment within a quarter chip in units of 200ms and thus cannot perform forward DPCH alignment.

As described above, in the conventional code division multiple access communication system, since there is no path for transmitting a control signal for strong transmission time alignment of the forward DPCH and the reverse DPCH, the UE does not adjust the forward transmission time, and the UE does not adjust the handover region. If you enter, it will cause a problem that can not perform the forward DPCH alignment. In addition, since the tracking process is performed in units of one quarter chips, there is a problem that the conventional tracking process alone cannot follow the alignment of the dedicated physical channel data transmission time.

Accordingly, an object of the present invention is to provide a method for transmitting a control signal for adaptive transmission time alignment of a forward DPCH and a reverse DPCH between a wireless network controller and a mobile terminal.

Another object of the present invention is to provide a method for aligning transmission times of a forward DPCH and a reverse DPCH by transmitting a control signal for adaptive transmission time alignment between a base station controller and a mobile station when performing handover. .

A further object is keeping the difference between T ₀ of the transmission time of the transmission time and the reverse physical data channel data of the forward dedicated physical data channel data by changing the transmission time of the forward or reverse dedicated physical data channel data of the base station and the terminal according to the present invention To provide a way to do this.

It is still another object of the present invention to provide a method for performing adaptive transmission time alignment between a plurality of base stations and mobile terminals in a handover region.

The present invention to achieve the above object; In a method of changing a data transmission time of a code division multiple communication system comprising a mobile terminal for measuring a time difference between a reception time of forward dedicated physical channel data and a transmission time of reverse dedicated physical channel data and transmitting the same to a base station controller, the base station controller Transmitting transmission time alignment information for adjusting the transmission time of the reverse dedicated physical channel data and the forward dedicated physical channel data to a base station and a mobile terminal when the time difference is out of a predetermined allowable range; Adjusting the transmission time of the forward dedicated physical channel data based on the information; and changing a search time of the forward dedicated physical channel data according to the transmission time alignment information in the mobile terminal to transmit the forward dedicated physical channel data. Including the process of receiving And a gong.
The present invention for achieving the above object; In a method of changing a data transmission time of a code division multiple communication system comprising a mobile terminal for measuring a time difference between a reception time of forward dedicated physical channel data and a transmission time of reverse dedicated physical channel data and transmitting the same to a base station controller, the base station controller Transmitting transmission time alignment information for adjusting the transmission time of the reverse dedicated physical channel data to the base station and the mobile terminal so that the time difference is within a predetermined allowable range, and transmitting the reverse dedicated physical signal by the transmission time alignment information at the mobile terminal. Changing the transmission time of channel data and transmitting the data; and receiving the reverse dedicated physical channel data by changing the search time of the reverse dedicated physical channel data according to the transmission time alignment information at the base station. It is done.
The present invention for achieving the above object; Measuring time differences between a reception time of forward dedicated physical channel data received from a plurality of base stations forming a wireless link with the base stations and a transmission time of reverse dedicated physical channel data transmitted to the base stations. In an adaptive transmission time alignment method in a code division multiple access communication system having a mobile terminal for transmitting to a base station controller, a time difference with respect to any one of the base stations in the base station controller satisfies a first condition. The first transmission time alignment information is set to be transmitted to the first base station and the mobile terminal, and the second transmission time alignment information is received so that time differences with respect to the second base stations other than the first base station satisfy the second condition. Transmitting to the second base stations and the mobile station, and when the mobile station transmits the first Change the transmission time of reverse dedicated physical channel data for the first base station according to the alignment information, and change the search time of forward dedicated physical channel data for the second base stations according to the second transmission time alignment information. And receiving, by the first base station, the reverse dedicated physical channel data by changing a search time of the reverse dedicated physical channel data according to the first transmission time alignment information, and receiving the second dedicated physical channel data by the second base station. And changing the transmission time of the forward dedicated physical channel data according to the transmission time alignment information.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.
The present invention transmits a control signal for transmission time alignment between a forward DPCH and a reverse DPCH between a UTRAN (UMTS Terrestrial Radio Access Network) and a UE. In particular, the present invention performs transmission time alignment even in an unaligned situation shown in the handover region as shown in FIG. 1.

In the present invention, the RNC of the UTRAN requests the UE to measure and report the "UE Rx-Tx time difference". Thereafter, the UE transmits a UE RX-Tx time difference, which is a time difference between the time of receiving the forward DPCH and the time of transmitting the reverse DPCH, to the RNC. Receiving the UE Rx-Tx time difference transmitted from the UE, the RNC can determine the trailing of the forward DPCH or the trailing of the reverse DPCH based on the T ₀ + α.

2 is a diagram illustrating a method of determining control coefficients in an RNC of a code division multiple access communication system according to an exemplary embodiment of the present invention. That is, the RNC receives the UE Rx-Tx time difference from the UE by the method of FIG. 2 to determine whether it is a trailing of the forward DPCH or the backward DPCH, and then determines an associated control coefficient.
Referring to FIG. 2, the UE measures the UE Rx-Tx time difference, which is the difference between the time of receiving the forward DPCH and the transmission time of the reverse DPCH in response to the request of the RNC in step 201, and transmits the difference to the RNC. In response to the UE Rx-Tx time difference measurement, the RNC checks whether the UE meets a condition smaller than the time interval T + Δ between the forward DPCH and the reverse DPCH that the UE Rx-Tx time difference α allows. If the UE Rx-Tx time difference does not satisfy the condition smaller than (T + Δ) in step 202, the RNC determines the time interval between the forward DPCH and the reverse DPCH in which the UE Rx-Tx time difference α is allowed in step 203. Check whether the condition less than T ₀ -Δ) is satisfied. When the condition of step 202 is satisfied, the case of the forward DPCH frame is followed, and when the condition of step 203 is satisfied, the case of the backward DPCH frame is followed. If the condition is satisfied in step 202, the RNC proceeds to step 204, whereby the base station control element (hereinafter referred to as " NCF ") is set so that? Set it. If the condition of step 203 is satisfied, the RNC proceeds to step 205 and the reverse DPCH frame transmission time control coefficient of the UE is set so that the UE Rx-Tx time difference after compensation is within the set (UE Control Factor: "UCF"). Set).
In more detail about the method for determining the NCF and the UCF, the RNC determines the degree of delay time when the Rx-Tx time difference is transmitted from the UE. That is, it is searched whether the visual difference is greater than or less than or equal to T ₀ + Δ. Here, Δ is a time for adjusting the time for transmitting the dedicated physical data channel data between the Node B and the UE, which is usually 128 chips, and can be set to 147 chips by applying an experimentally obtained stable value. The stable value is variable.
The RNC determines to change the transmission time point of the dedicated physical data channel data of the base station when it is determined that the time difference received from the UE is greater than T ₀ + Δ. Once it is determined to change the transmission time of the base station dedicated physical data channel data, the transmission time of the base station is followed by a multiple of 256 chips to make the difference between the transmission time between the base station and the terminal T ₀ . That is, it will be followed by one, two, or three times 256 chips. The change value of the data transmission time of the dedicated physical data channel of the base station is NCF. On the contrary, when it is determined that the time difference measurement received from the terminal is less than T ₀ + Δ, the base station controller determines a change in transmission time point of the dedicated physical data channel data of the terminal. The data transmission time change of the terminal may occur in one chip unit differently from the base station, or may be determined in multiples of 256 chips like the base station. This is merely an implementation method, and the data transmission time change value of the terminal determined by the base station controller is UCF (UCF). However, if the time difference is equal to the T ₀ + Δ, the transmission time of both the base station and the mobile station may be maintained.

First, the case where the trailing of the forward DPCH is determined from the transmitted UE Rx-Tx time difference will be described in detail.

delete

In the case of the trailing of the forward DPCH, the base station controller determines whether the condition of Equation 1 below is satisfied. After making the determination according to Equation 1, the base station controller generates the forward DPCH frame transmission time control coefficient NCF of the base station.

α <256 * NCF + Δ

When the condition of Equation 1 is satisfied, the base station controller sets the NCF and transmits the radio signal to the base station using a Radio Link Reconfiguration Prepare message and moves using a Physical Channel Reconfiguration message. It can transmit to the terminal. The NCF value may be 0, 1, 2, or the like. The Δ value may be set in units of 147 chips when 128 chips are common and a stable value is added. The NCF value may be transmitted in a Radio Link Reconfiguration Prepare message. At this time, the base station controller allocates 2 bits for the NCF to the reserved area of the Radio Link Reconfiguration Prepare message and sets the values of 1,2 and 3 among the multiples of 256 chips. Alternatively, it may indicate whether a UCF or NCF is added to one bit in which a bit for a flag is added for the UCF value, and the remaining values may be transmitted by carrying a value of UCF or NCF. Likewise, a method of using a physical channel reconfiguration message transmitted by the base station controller to the terminal may also be the same as a method of transmitting a message including a value of the NCF or UCF to the base station. However, if the UCF is moved by one chip unit, the transfer time of the dedicated physical data channel data of the terminal is changed by indicating the number of chips to be moved instead of the above method.

FIG. 3 is a diagram illustrating forward and reverse DPCHs on a connection frame number (hereinafter referred to as "CFN") / system frame number (hereinafter referred to as "SFN") axis of a mobile terminal. FIG. 11 is a diagram illustrating a process of generating a mobile station Rx-Tx time difference measurement value at the request of a base station controller.
Referring to FIG. 3, the time difference between the start time point 301 of the forward DPCH on the time axis of the forward DPCH and the start time point 302 of the transmission on the CFN time axis of the reverse DPCH is represented by T ₀ + α. Where T ₀ is a statically set 1024 chip, and α corresponds to a predetermined time accumulation value of propagation delay due to mobile terminal motion and represents an allowable threshold value.

4 is a flowchart illustrating a robust transmission time adjusting method in a code division multiple access communication system according to a first embodiment of the present invention. Hereinafter, referring to FIG. 4, a process of generating a base station forward DPCH transmission time adjustment coefficient NCF using UE Rx-Tx time difference measurement and transmitting the same to a base station and a mobile station using Radio Link Reconfiguration Prepare and Physical Channel Reconfiguration messages, respectively. Explain.

In step 401 of FIG. 4, the mobile station generates UE Rx-Tx time difference measurements by using the time of receiving the forward DPCH and the transmission time of the reverse DPCH at the request of the base station controller, and transmits the measurement to the base station controller through the base station. The base station controller receiving the UE Rx-Tx time difference measurement value from the mobile station determines whether the condition of Equation 1 is satisfied with respect to the UE Rx-Tx time difference measurement value in step 402 of FIG. 4, and in step 403, the UE Rx-Tx time difference measurement value. The NCF of Equation 1 above is set to be within the set threshold value Δ of the UE Rx-Tx time difference measured value after compensation according to the condition search result for the measured value. If the NCF is configured in step 403, the base station controller transmits the NCF to the base station using a Radio Link Reconfiguration Prepare message in step 404. In addition, the base station controller transmits a radio link reconfiguration prepare message to the base station and simultaneously transmits the set NCF to the mobile station using a physical channel reconfiguration prepare message in step 406. In step 405, the base station receiving the Radio Link Reconfiguration message transmitted from the base station controller detects an NCF included in the Radio Link Reconfiguration message and delays a forward DPCH frame transmission time according to the NCF. For example, when the NCF has a value of 0, 1, or 2, the base station transmits a forward DPCH frame by delaying 256 chips when NCF is 0 and 256 * 2 chips when 1. In addition, when the NCF has a value of 3, the base station transmits a forward DPCH frame by delaying a 256 * 3 chip.

The mobile station also receives the physical channel reconfiguration message transmitted in step 406 by the base station controller in step 307 and detects an NCF from the physical channel reconfiguration message. The mobile terminal delays the search time for the forward DPCH frame according to the detected NCF.

FIG. 5 is a diagram illustrating a result of a base station of a code division multiple access communication system according to a first embodiment of the present invention delaying a forward DPCH transmission frame and aligning the reverse DPCH according to a received NCF.

Referring to FIG. 5 below, the base station performs a forward DPCH frame transmission delay according to the NCF ( K) received from the base station controller to perform alignment with the reverse DPCH (adjust the time difference within 128 chips). Specifically, reference numeral 501 of FIG. 5 denotes a reception start point of the forward DPCH frame before the alignment process. Reference numeral 502 of FIG. 5 denotes a reception point of a forward DPCH frame indicating a case in which the base station performs alignment through a forward DPCH frame transmission delay. 5 shows a transmission delay degree of the base station. The base station controller determines the NCF value according to the size of the base station, and the unit of the NCF corresponds to 256 chips.

In the case of the backward DPCH, the base station controller determines whether the condition of Equation 2 below is satisfied. After the determination is made according to the condition of Equation 1, the control terminal UCF of the reverse DPCH frame transmission time of the mobile station is generated according to the determination.

α + SU * UCF <Δ

If the above conditions are met, the base station controller transmits the UCF to the base station and the mobile station using Radio Link Reconfiguration Prepare and Physical Channel Reconfiguration messages, respectively. The shifting unit (SU) is a change unit, and is set to a single chip, 4 chips, 8 chips, 16 chips, 64 chips, 128 chips, and 256 chips. It is set in units.

Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 6 to 8.
First, FIG. 6 is a diagram illustrating a process of generating a UE Rx-Tx time difference measurement value at a request of a base station controller in a mobile terminal of a code division multiple access communication system according to a second embodiment of the present invention. 6 illustrates a case in which the time difference between the forward DPCH and the reverse DPCH is smaller than (T ₀ −), unlike in the first embodiment, the method of changing the forward DPCH frame transmission time point (following the forward DPCH frame) overlaps the data frame. It is not appropriate to cause information loss through the network. Therefore, when the reverse DPCH transmission frame is followed, the alignment may be performed by delaying the transmission time of the reverse DPCH frame of the mobile station. Reference numeral 601 of FIG. 6 denotes a reception point of a forward DPCH frame, and reference numeral 602 denotes a transmission start point of a reverse DPCH frame.

7 is a diagram illustrating a robust transmission time adjustment method in a code division multiple access communication system according to a second embodiment of the present invention, in which a mobile station reverse DPCH transmission time adjustment coefficient UCF is generated using a UE Rx-Tx time difference measurement value. After that, a process of transmitting to a base station and a mobile terminal by using a Radio Link Reconfiguration Prepare and a Physical Channel Reconfiguration message will be described.

Referring to FIG. 7, in step 701, the mobile station generates UE Rx-Tx time difference measurements using the time when the forward DPCH is received and the transmission time of the reverse DPCH at the request of the base station controller, and transmits them to the base station controller. In step 702, the base station controller receiving the UE Rx-Tx time difference measurement transmitted by the mobile station through the base station determines whether the UE Rx-Tx time difference measurement satisfies the condition of Equation 2. The base station controller sets the UCF so that the UE Rx-Tx time difference measurement after the compensation in Equation 2 is within a set threshold value according to whether the UE Rx-Tx time difference measurement satisfies Equation 2 above. . If the UCF is configured in step 703, the base station controller transmits the UCF to the base station using a Radio Link Reconfiguration Prepare message in step 704. The base station controller also transmits the set UCF to the mobile station in step 706 using the physical channel reconfiguration message at the same time as step 704. The base station receiving the Radio Link Reconfiguration Prepare message transmitted in step 704 detects the UCF from the Radio Link Reconfiguration Prepare message in step 705 and delays the search time for the reverse DPCH frame transmitted from the mobile station according to the UCF. . If SU is 256, UCF has a value of 1, 2, or 3, and the base station delays SU chip if UCF is 1, SU * 2 chip if 2, and SU * 3 chip if 3 Transmit reverse DPCH frames. The mobile station receiving the physical channel reconfiguration message transmitted by the base station controller in step 706 detects the UCF from the physical channel reconfiguration message in step 707 and delays the transmission time for the reverse DPCH frame according to the UCF. If SU is 256, UCF has a value of 1, 2, or 3, and the base station delays SU chip if UCF is 1, SU * 2 chip for 2, and SU * 3 chip for 3 Transmit reverse DPCH frames.

8 is a diagram illustrating a time difference between a forward DPCH and a reverse DPCH after performing robust transmission time adjustment in a code division multiple access communication system according to a second embodiment of the present invention. The mobile station performs alignment with the received forward DPCH frame by performing a reverse DPCH frame transmission delay according to the UCF ( v ) received from the base station controller. Reference numeral 801 of FIG. 8 denotes a time of transmission of the reverse DPCH frame before alignment. Reference numeral 802 denotes a time of transmission of a reverse DPCH frame when the mobile station performs alignment through a reverse DPCH frame transmission delay. 803 of FIG. 8 is a value representing the transmission delay degree of the mobile terminal and is set to a single chip, 4 chips, 8 chips, 16 chips, 128 chips, 256 chips, or the like. Alignment of the forward frame and the reverse DPCH frame is performed through the transmission delay of the set UCF size.

In addition, when the number of base stations is two, an embodiment showing the transmission time alignment scheme in the handover region is as follows. Of course, at this time, even in the case of three or more base stations can be extended in the same way.

First, in the actual handover area, the mobile station receives each forward DPCH frame from two base stations. The mobile station generates different UE Rx-Tx time differences between the received DPCH frames and the reverse DPCH frame of the mobile station at different time periods. The mobile station measures the generated UE Rx-Tx time difference for each base station and then transmits the corresponding measurement value for each base station to a base station controller. The base station controller determines the NCF or UCF by substituting two UE Rx-Tx time difference measurements received from the mobile station into the conditional expressions of Equations 1 and 2, respectively.

As a result of the determination according to the conditional expressions of Equations 1 and 2, when both are determined to be NCF, the base station controller delays the forward DPCH transmission frame of each base station according to the NCF value. In this case, when the NCF of the base stations (base station of cell 1 and base station of cell 2) is 1, 256, 2 is 256 * 2, and 3 is 256 * 3 chip transmission is performed in units of 256 * 3 chips. Delay.

9 shows the forward DPCH frames 905 and 906 and the reverse DPCH frame 907 on the CFN (SFN) axis of the mobile terminal at the time when the UCF for the base station 1 and the NCF for the base station 2 are determined from the above condition equation. ). In FIG. 9, reference numerals 901 and 902 indicate a reception time point of the mobile terminal for the forward DPCH frame 905 of the cell 1 and the forward DPCH frame 906 of the cell 2 in the handoff region, and 903 of FIG. 9 shows a reverse DPCH frame. 907 indicates the transmission start time. That is, in the handoff region, a transmission start time of the reverse DPCH frame 907 is different from a reception time of each forward DPCH frame of each of Cell 1 and Cell 2.

를 수신한 후 역방향 DPCH 프레임 전송 지연을 수행함으로써 셀1의 순방향 DPCH 프레임과의 정렬을 수행한 경우를 나타낸 도면이다. 상기 도 10의 1001은 정렬 이전, 즉 도9의 역방향 DPCH 프레임(907)의 전송시점을 나타낸다. 상기 도 10의 1002는 이동단말이 역방향 DPCH 프레임(1007) 전송 지연을 통한 정렬을 수행한 후의 역방향 DPCH 프레임의 전송시점이다. 상기 도 10의 1003은 셀2에서 이동단말로 전송된 순방향 DPCH 프레임(1009)의 수신 시점이다. 셀2에서 전송된 순방향 DPCH 프레임(1009)과 셀1과의 정렬을 수행하는 이동단말의 역방향 DPCH 프레임(1007)과의 정렬을 위해서는 하기의 수학식 3의 조건을 만족하도록 NCF가 결정되어야 하는 것으로, 이러한 정렬 과정 및 결과를 설명하면 다음과 같다.10 is observed from the mobile terminal side

FIG. 4 illustrates a case in which alignment with a forward DPCH frame of cell 1 is performed by performing a reverse DPCH frame transmission delay after receiving Rx. 10 shows the time of transmission of the reverse DPCH frame 907 of FIG. 9 before alignment. 10 is a time point of transmitting a reverse DPCH frame after the mobile station performs alignment through a reverse DPCH frame 1007 transmission delay. In FIG. 10, reference numeral 1003 denotes a reception time of the forward DPCH frame 1009 transmitted from the cell 2 to the mobile station. In order to align the forward DPCH frame 1009 transmitted from the cell 2 with the reverse DPCH frame 1007 of the mobile station performing alignment with the cell 1, the NCF should be determined to satisfy the condition of Equation 3 below. This sorting process and result are described as follows.

< 256*NCF + SU*UCF +

<256 * NCF + SU * UCF +

The UCF under the condition of Equation 3 corresponds to a time delay value that has already been calculated through Equation 2 and then aligned. 104 of FIG. 10 is a forward DPCH reception time that reflects the transmission time delay degree calculated through Equation 3 above. The control signal transmission method for such transmission time alignment uses the RL Reconfiguration Prepare and Physical channel prepare messages as in the first embodiment or the second embodiment, and separately adds a CFN-related term to perform transmission time alignment for cell 1 and cell 2. At the same time.

11 is a UE Rx-Tx time difference measurement in the handover region after generating the UE reverse DPCH transmission time adjustment coefficient UCF and Node B forward DPCH transmission time adjustment coefficient NCF, the generated UCF and NCF are respectively Radio Link Reconfiguration Prepare and Physical Channel Reconfiguration Deliver message to Node B and UE. The overall transmission time alignment is performed through the message.

11 is a flowchart illustrating an adaptive transmission time alignment method in a code division multiple access communication system according to a third embodiment of the present invention. A description with reference to FIG. 11 is as follows.

The mobile station generates UE Rx-Tx time difference measurements for the radio link of Cell 1 and Cell 2 at the request of the base station controller in step 1001. The mobile station transmits the generated UE Rx-Tx time difference measurements to the base station controller when the UE Rx-Tx time difference measurements of each of Cell 1 and Cell 2 are generated. In step 1102, the base station controller receiving the UE Rx-Tx time difference measurements determines whether the UE Rx-Tx time difference measurements for Cell 1 satisfy the condition for Equation 2. If the condition is not satisfied, the base station controller waits for the UE Rx-Tx time difference measurement of the next step (not shown). However, if the condition is satisfied, the base station controller proceeds to step 1103 and after the alignment, sets the UCF so that the UE Rx-Tx time difference measurement value for the Radio Link of Cell 1 falls within the set threshold value. If the UCF is configured, the base station controller transmits the UCF to the base station using the Radio Link Reconfiguration Prepare message in step 11031, and transmits the UCF to the mobile station using the Physical Channel Reconfiguration message in step 11033. Then, the base station detects the UCF from the Radio Reconfiguration Prepare message transmitted by the base station controller in step 11032 and delays the search time of the reverse DPCH frame according to the detected UCF. The mobile station receiving the physical channel reconfiguration message in step 11033 detects a UCF from the physical channel reconfiguration message in step 11034 and transmits a delay time of transmitting a reverse DPCH frame according to the detected UCF. In this case, when SU is 256, UCF has a value of 1, 2, or 3, and the mobile terminal has SU chip when UCF is 1, SU * 2 chip when 2, and SU * 3 chip when 3 Delay to transmit the reverse DPCH frame.

The base station controller substitutes the condition of Equation 3 for UE Rx-Tx time difference measurement value of Radio Link of cell 2 reflecting the influence of the transmission time delay adjustment of the mobile station for cell 1 in step 1104. NCF is set to satisfy the condition of Equation 3. That is, the NCF is set such that the UE Rx-Tx time difference measurement value of the radio link of Cell 2 can be placed within the set threshold value after the alignment. When the NCF is set, the base station controller transmits the NCF to the base station using a Radio Link Reconfiguration Prepare message in step 11051. In step 11052, the base station of cell 2 detects the NCF included in the Radio Link Reconfiguration Prepare message and delays forward DPCH frame transmission according to the NCF. The NCF has a value of 1 or 2 or 3. The base station controller also transmits the NCF to the mobile station using a physical channel reconfiguration message in step 11053. The mobile station detects the NCF from the physical channel reconfiguration message transmitted by the base station controller in step 11054, and delays the search time for the forward DPCH frame according to the detected NCF.

The sequence of transmission time alignment is set to delay the forward DPCH with respect to the base station of cell 1, but when the loss of the transmission data frame is taken at a certain level, the transmission time of the forward DPCH frame is preceded by the transmission time of the DPCH frame. Sorting is possible. Even in this case, signaling is performed for each Radio Link using the same reconfiguration message (Radio Link Reconfiguration Prepare, Physical Channel Reconfiguration) as in the third embodiment.

As described above, the present invention has the advantage that the base station controller transmits the transmission time alignment control information to the base station and the mobile terminal, thereby providing an adaptive and stable alignment between the forward and reverse dedicated physical channel frames during handover.

Claims (17)

A method of changing a data transmission time of a code division multiple communication system having a mobile terminal for measuring a time difference between a reception time of forward dedicated physical channel data and a transmission time of reverse dedicated physical channel data and transmitting the measured time difference to a base station controller, Transmitting, by the base station controller, transmission time alignment information for adjusting transmission times of the reverse dedicated physical channel data and the forward dedicated physical channel data when the time difference is out of a predetermined allowable range to a base station and a mobile terminal; Adjusting and transmitting a transmission time of the forward dedicated physical channel data by the base station according to the transmission time alignment information; Receiving the forward dedicated physical channel data by using the transmission time alignment information in the mobile terminal. The method of claim 1, wherein the transmission time alignment information is a transmission time control coefficient (NCF) satisfying Equation 4 below. α <256 * NCF + Δ Is the delay time and? Is the allowable range of the delay time. The method of claim 1, wherein the transmission time alignment information is transmitted to the base station through a radio link reconfiguration preparation message. The method of claim 1, wherein the transmission time alignment information is transmitted to the mobile station through a physical channel reconfiguration message. A method of changing a data transmission time of a code division multiple communication system having a mobile terminal for measuring a time difference between a reception time of forward dedicated physical channel data and a transmission time of reverse dedicated physical channel data and transmitting the measured time difference to a base station controller, Transmitting, by the base station controller, transmission time alignment information for adjusting the transmission time of the reverse dedicated physical channel data so that the time difference is within a predetermined allowable range to a base station and a mobile terminal; Changing and transmitting the transmission time of the reverse dedicated physical channel data according to the transmission time alignment information in the mobile terminal; And receiving, by the base station, the reverse dedicated physical channel data based on the transmission time alignment information. The method of claim 5, wherein the transmission time alignment information is a transmission time control coefficient (UCF) satisfying Equation 5 below. α + SU * UCF <Δ Is the delay time,? Is the allowable range of the delay time, and SU is the change unit. 6. The method of claim 5, wherein the transmission time alignment information is transmitted to the base station through a radio link reconfiguration preparation message. The method of claim 5, wherein the transmission time alignment information is transmitted to the mobile station through a physical channel reconfiguration message. Measuring time differences between a reception time of forward dedicated physical channel data received from a plurality of base stations forming a wireless link with the base stations and a transmission time of reverse dedicated physical channel data transmitted to the base stations. An adaptive transmission time alignment method in a code division multiple access communication system having a mobile terminal for transmitting to a base station controller, The base station controller sets first transmission time alignment information so that the time difference with respect to any one of the base stations satisfies a first condition, and transmits the first transmission time alignment information to the first base station and the mobile terminal, and the first base station. Transmitting second transmission time alignment information to the second base stations and the mobile terminal so that time differences with respect to the remaining second base stations satisfy the second condition except for; The mobile station changes the transmission time of reverse dedicated physical channel data for the first base station according to the first transmission time alignment information, and transmits it, and forwards the second base stations according to the second transmission time alignment information. Changing the search time of the dedicated physical channel data; Receiving, by the first base station, the reverse dedicated physical channel data by changing a search time of the reverse dedicated physical channel data according to the first transmission time alignment information; And transmitting, by the second base station, by changing the transmission time of the forward dedicated physical channel data according to the second transmission time alignment information. 10. The transmission time alignment method of claim 9, wherein the first transmission time alignment information is a transmission time control coefficient (UCF) satisfying the first condition according to Equation (6). α + SU * UCF <Δ Is the delay time,? Is the allowable range of the delay time, and SU is the change unit. 10. The transmission time alignment method of claim 9, wherein the second transmission time alignment information is a transmission time control coefficient (NCF) that satisfies the second condition according to Equation (7).

Is the delay time,? Is the allowable range of the delay time, and SU is the change unit. 10. The method of claim 9, wherein the first transmission time alignment information is transmitted to the base stations through a radio link reconfiguration ready message. 10. The method of claim 9, wherein the second transmission time alignment information is transmitted to the mobile station through a physical channel reconfiguration message. In a mobile communication system comprising a mobile terminal, a first base station, a second base station adjacent to the first base station, and a base station controller connected to the first and second base stations, forward only from the first base station to the mobile terminal. Transmitting a data frame through a physical channel, measuring a reception time of receiving the data frame by the mobile terminal, and a transmission time of processing the received data frame by the mobile terminal and transmitting a response frame, A first time difference between a time and the reception time is transmitted to the base station controller, wherein the first time difference between the first base station and the mobile terminal is within a given allowable range time and the mobile terminal is the first base station and the second; The forward dedicated physical from the second base station when entering the second base station area beyond the handover area of the base station. A second time difference between the time received by the mobile terminal from the data frame transmitted through the channel and the time transmitted from the mobile terminal in response to the received data frame is transmitted to the base station controller and 1. A method of aligning a time when a data frame is transmitted from a second base station to a mobile terminal through a forward dedicated physical channel by a time that is transmitted by the mobile terminal to the second base station in response to the data frame. Setting transmission time alignment information in the base station controller so that the time difference with respect to the first base station is within a predetermined allowable range, and transmitting the time alignment information to the second base station and the mobile terminal; Transmitting, by the second base station, by changing the transmission time of the data frame transmitted through the forward dedicated physical channel according to the transmission time alignment information; And transmitting, by the mobile terminal, a data frame transmitted through the forward dedicated physical channel according to the transmission time alignment information. 15. The method of claim 14, wherein the transmission time alignment information is a transmission time control coefficient (NCF) satisfying Equation (8). α <256 * NCF + Δ Is the delay time and? Is the allowable range of the delay time. 15. The method of claim 14, wherein the transmission time alignment information is transmitted to the second base station through a radio link reconfiguration preparation message. 15. The method of claim 14, wherein the transmission time alignment information is transmitted to the mobile station through a physical channel reconfiguration message.

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