KR100456400B1 - Method and Apparatus for estimating location of Mobile Terminal in service area of single Base Station - Google Patents

Abstract

The present invention relates to a method and an apparatus for locating a terminal in a single base station service area for dividing a service area of a single base station into a plurality of detailed areas so that the location of a terminal can be divided by the detailed areas. Distributed antennas distributed in sub-regions are installed (S601), and the delay distribution values of the signals received for each antenna overlap each other by varying the delay of the path between the base station and each antenna through a hardware artificial method. If the communication signal is received through the multipath corresponding to the distributed antenna (S603), after calculating the delay value of the received signal (S604), the calculated delay value, The reception signal is based on the delay distribution value preset in step S602 and the strength of the received signal. Determining in which area of the detailed area of the terminal is located (S605), it is possible to divide the service area of a single base station into a plurality of detailed areas and to determine the location of the corresponding terminal in the communication area By providing a detailed location-based service within the service area of a single base station.

Description

Method and Apparatus for Identifying Terminal Location in Single Base Station Service Area {Method and Apparatus for estimating location of Mobile Terminal in service area of single Base Station}

The present invention relates to a method and device for locating a terminal in a single base station service area, and more particularly, to divide a service area of a single base station into a plurality of detailed areas so that the location of the terminal can be divided into the detailed areas. A terminal location method and apparatus in a base station service area.

In general, a code division multiple access (CDMA) mobile communication system uses a PN code orthogonality to multipath fading signals due to differences in arrival times of respective reception paths. After receiving the received signal separated by the path, and using the multipath diversity receiver that can combine the received signal to improve the reception performance. Herein, the time difference and the signal magnitude that arrive on the time axis of each signal are called a delay profile. Typically, the delay profile that can be received is within a few uSec.

In addition, there is a round-trip-delay (RTD) between the base station and the terminal depending on the distance between the terminal and the base station or a processing delay caused by hardware, and a cell as a service area of the base station. As the larger the position distribution of the terminal is, the distribution of the round trip delay is also widely distributed on the time axis. Conversely, the smaller the cell size, the narrower the position distribution of the terminal on the time axis.

As described above, in wireless communication, there are a myriad of paths between a base station and a terminal. Therefore, the signals transmitted through this path are canceled or merged with each other at the receiving end so that the magnitude of the input signal varies greatly. This phenomenon is called multipath fading. However, in a communication system using CDMA, a delay diversity receiver using orthogonality of multipath signals is used to increase reception performance for multipath fading.

FIG. 1 is a diagram illustrating a reception method using delay diversity in a CDMA communication scheme, and FIG. 1A illustrates a multipath path-1 existing between a base station (BTS) 110 and a terminal 120. , path-2, ..., path-N), and (b) of FIG. 1 is a block diagram showing the receiving end of the base station 110. Reference numerals 111-1, 111-2, ..., 111 -N is the fingers (Finger-1, finger-) as a multipath receiver 111 to restore the signals received through the N multipath (path-1, path-2, ..., path-N), respectively 2, ... Finger-N, and reference numeral 112 denotes a combiner 112 for coupling the output signals of the fingers 111-1, 111-2, ..., 111-N. Indicates.

In FIG. 1, first, the receiving end of the base station 110, the CDMA system time (hereinafter referred to as reference time) of the signal coming through the N paths (path-1, path-2, ..., path-N) After determining the reception delay of each path through the device for searching for the delay of each path, the receiving device for each path of the multi-path receiver 111, that is, each finger (111-1, 111-2, 111-N), the delayed signal obtained from the input signal is restored by a delay time corresponding to the delayed information. At this time, the delayed signal is restored to a large signal, but the other delayed signal acts as noise according to the code orthogonality of CDMA. In other words, each finger stage (111-1, 111-2, ... 111-N) with respect to the input signal increases the signal to noise ratio by increasing the input signal for the corresponding delay. Since there are several such fingers 111-1, 111-2, ... 111-N, each of the fingers 111-1, 111-2, ... 111-N receives a signal of a different path, and then the signal These signals may be combined through the combiner 112 to recover a degraded signal due to multipath fading.

Therefore, it is possible to know how much the arrival delay time of the signal transmitted from the specific terminal is compared with the reference time of the base station by using the receiver as shown in FIG.

FIG. 2 shows a factor on the time axis as a factor of delay of a signal arriving at a base station.

First, a delay element of a forward link sent from a base station to a terminal includes a base station processing delay, a free air traveling delay, and a terminal processing delay.

The base station processing delay represents a delay from the inside of the base station to the final antenna stage. Since the base station processing delay is a fixed value in the system design, the base station processing delay may be ignored according to the provision of compensating and transmitting the delay value to the final antenna stage in advance. The terminal processing delay may be precompensated and ignored like the base station processing delay. In addition, the pre-air traveling delay is 3.33 uSec / Km, which is a variable value depending on the position between the base station and the terminal. The above three delay factors determine the time T1 to reach the terminal.

The following is a base station delay offset (Delay Offset), which means the time when the signal transmitted from the terminal arrives on the fastest path when the terminal reaches the base station through the multi-path, that is, the time from T1 to T2. The delay offset of the base station receiving side signal is a delay factor such as Access Probe PN randomization, Free Space Traveling Delay, Hardware Delay, and Processing Delay. Determined by

The access probe PN randomization is a value that can be known to both the base station and the terminal by a predetermined standard by randomly delaying a transmission time within a given range when the access probe is transmitted from the terminal to the base station. The free space traveling delay is a value proportional to the distance between the terminal and the base station and varies with the position of the terminal. The hardware delay and the processing delay represent the time to reach the internal receiver from the antenna stage and the processing time, respectively, and are fixed values in the system design.

The following is a delay factor for each path due to a difference in arrival time for each path, that is, a mutual time difference between the reverse link delay time T2 of path 1 and the reverse link delay time T3 of path 2 and the reverse link delay time T4 of path 3 to the base station receiver. (relative delay spread), the difference between the earliest arriving signal and the latest arriving signal, that is, the difference between T2 and T4, is usually known in a few uSec units.

Therefore, in view of the above, acting as a variable of the arrival delay factor of the signal received at the base station antenna is the free air space element and the relative delay spread between the base station and the terminal. It can be called an element.

The present invention has been created to use the technical background of the above-described delay in the location of the terminal, the object of which is to divide the service area of a single base station into a plurality of detailed areas and to determine in which area the terminal is communicating. It is an object of the present invention to provide a method and apparatus for locating a terminal in a single base station service area, which can identify a location.

1 is a diagram illustrating a reception method using delay diversity in a code division multiple access communication scheme.

FIG. 2 is a diagram showing factors causing delay elements of a signal arriving at a base station on a time axis;

3 is a diagram illustrating an apparatus for locating a terminal in a single base station service area according to an embodiment of the present invention.

4 is a view for explaining a delay distribution in the present invention,

FIG. 5 illustrates an example of arrangement of sub-regions when the sub-division is divided into 6 and the delay size is set to 20 PN chips according to the present invention.

6 is a flowchart of a method for locating a terminal in a single base station service area according to an embodiment of the present invention implemented based on the above description;

FIG. 7 is a flowchart for explaining an example of detailed processes of steps S603 to S605 of FIG. 6;

8 is a flowchart for explaining another example of detailed processes of steps S603 to S605 of FIG. 6.

※ Explanation of code for main part of drawing

310: base station 321,322,323: antenna

321a, 322a, 323a: Multipath 331,332,333: Delay

In order to achieve the above object, a method for determining a location of a terminal in a single base station service area according to the present invention comprises the steps of: dividing a service area of a single base station into detailed areas and determining a location of a terminal for each detailed area. A first step of installing a distributed antenna that is extended from and distributed in each of the sub-areas; A second step of differently setting a delay distribution value for each antenna; Calculating a delay value of a signal received by the base station through each antenna; And a fourth step of determining in which area of the detailed area the corresponding terminal of the received signal is located based on the calculated delay value, the predetermined delay distribution value, and the strength of the received signal. .

In order to achieve the above object, an apparatus for determining a location of a terminal in a single base station service area according to the present invention comprises: a device for dividing a service area of a single base station into detailed areas and identifying a location of a terminal for each specific area. A region dividing unit having a plurality of antenna apparatuses extending from the base station to divide the service region of the base station into a plurality of sub-regions, the delay distributions of which are different from each other; And calculating a delay value of a signal received through the plurality of antenna devices, and receiving the received signal through any one of the plurality of antenna devices based on the calculated delay value and the set delay value information. And position estimation means for grasping whether or not the received signal is applied.

In the implementation of the method and apparatus of the present invention, the delay distribution may be achieved by adjusting, for example, a length of a wired path extending between the base station and each of the antennas, or as another example on a path corresponding to each antenna. This is accomplished by providing delay elements with different delay values.

As an example of applying the present invention, it is suitable for providing a variety of additional services using location information of a subscriber by identifying which floor a terminal user is located in a densely populated building. First, to solve the problem of service shadow area by installing a distributed antenna system for smooth communication regardless of the user's location in the building, the delay of each antenna is artificially placed with different delay distribution for each antenna. By varying the round-trip delay (RTD), it is possible to know at which layer the terminal communicates. In general, path losses are known to be very large when propagation is moved from one layer to another. Therefore, the distributed antenna in the building is easy to determine the location of the terminal because the service area is well separated by each antenna.

Hereinafter, a method and apparatus for locating a terminal in a single base station service area according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The present invention divides an area serviced by a single base station into a plurality of sub-areas by using a delay distribution so as to determine the area in which the terminal is communicating. As illustrated in FIG. 3, a single base station (BTS) ( A plurality of antennas 321, 322, and 323 are distributed and expanded from 310 to be located in a desired detailed area, and artificial hardware delays are performed for each antenna path 321a, 322a, and 323a. Delay 2, Delay 3) (331, 332, 333) to give different arrival delay time for each antenna (321-323), as shown in Figure 4, by the path through each antenna (321-323) 321a-323a) By delaying the distribution of the distribution is not overlapped with each other, it is characterized in that it is possible to determine which antenna communicates through which antenna to know the detailed location where the antenna is installed and serviced. This will be described in detail below.

As described in the technical background of the present invention described above, the range of the relative delay spread element is usually several uSec, and the delay value due to the distance between the terminal and the base station is variable. The distribution of delay for each antenna can be reduced.

In addition, since the service area for each antenna is not overlapped and separated, it is ideal for the base station and the terminal to communicate through one antenna, but in some cases, it is possible to communicate through several antennas. It can be seen whether the signal received through the received signal size measured at the finger end. That is, assuming that the signal measured by the finger 111-1 of FIG. 1B is the largest, the delay value of the signal received by the finger 111-1 is dependent on the delay distribution of a certain antenna. The corresponding terminal is determined by comparing the corresponding reference delay distribution value for each antenna to determine where the terminal is located.

In the description of FIG. 3 of the present invention, a method of giving delays 331 to 333 for each antenna 321 to 323 provides a delay by adjusting a path length of a wire and providing a delay by installing a delay element. In the case of the delay method by the wire, the optical cable as the wire has a delay characteristic of 5usec / km, the signal loss according to the distance is very small, and the price is low. The delay method is divided into a digital signal and an analog signal. In the case of a digital signal, there is a method of delaying through a memory and an analog signal using a delay filter such as a SAW filter. There is a way. However, until now, a method of giving a delay according to the length of the optical path is preferable in terms of economical efficiency.

According to the description of FIG. 3, when the area serviced by the single base station 310 is divided into detailed areas, this can be implemented by inducing an artificial delay 331-333 to each antenna 321-323. According to the relationship between the installed environment and the neighboring base station, there are various delay methods such as a method for delaying both transmission and reception paths as follows, a method for delaying only a reception path, and a method for delaying only a diversity path among reception paths.

First, a method of delaying both the transmission and reception paths will be described.

The method of delaying both the transmission and reception paths is a case in which the transmission and reception paths have a delay by the same wired path (for example, an optical cable), which is limited by the maximum value of the transmission path. To distinguish base stations, each base station is separated by at least 64 PN chips. Therefore, an artificial delay value is determined at the transmitting side. In addition, when determining each delay value of the detailed area of the base station, the delay value should be determined so that there is no problem when the terminal receives the base station transmission signal in any detailed area. For example, when the terminal belongs to an area where two sub-areas overlap, each delay value of each sub-area is too large, so that the diversity effect cannot be obtained when the terminal leaves the multi-path search window area upon reception.

Next, a method of delaying only the reception path will be described.

In the method of delaying only the reception path, an artificial delay is not given to the transmitter so that the terminal can be received into the multipath search window when receiving a base station signal regardless of which subcell belongs to. However, this method needs to correct a round trip delay value for handoff when several subregions of the subregions of the base station when the handoff is performed with the neighbor base station are areas where handoff may occur with the neighbor base station.

Next, a method of delaying only the diversity path among the reception paths will be described.

This method can be used for a system using antenna diversity at the time of reception, without artificially delaying one of the reception paths and the transmission path, and artificially zooming only the path for diversity of the reception paths. The problem of both methods can be overcome.

That is, the method of delaying only the diversity path among the reception paths solves the shortcoming in the method of delaying both the transmission path and the transmission path. To solve the shortcomings in the method, the subregions can be seen as the same cell for the neighboring base station when handoff with the neighboring base station. In the cell, the detail region is determined using the delay information of the signal received through the diversity path. Can be distinguished. When using this method, it is necessary to determine the detailed area where the terminal is located by using an artificially delayed path.

Next, a method of determining the delay value applied for each subregion will be described.

In general, since there is a limit to the size of the terminal that can receive a terminal signal in a radio access network (RAN) of a synchronous CDMA mobile communication system, the smaller the amount of delay applied to divide the detail area into more advantageous. .

On the other hand, when the applied delay size is small, a problem may occur in which the position of the terminal is incorrectly determined by the system. In other words, in order to secure the accuracy of the position determination, the larger the difference in the amount of delay applied to the adjacent subregions, the better.

In order to solve such a trade off problem, the delay for each sub-area is determined as follows.

The total number of subregions is called M, and when the subregions are arranged in adjacent order, they are called Z ₁ , Z ₂ , .., Z _n-1 , Z _n , Z _{n + 1} , .., Z _M , respectively. When the delay magnitude applied to each subregion is D ₁ , D ₂ , .., D _n-1 , D _n , D _{n + 1} , .., D _M , the delay magnitude in the present invention is represented by the following equation 1 Decide accordingly.

In Equation 1, the constant C represents a reference delay size for distinguishing each subregion.

The method for obtaining the dn in Equation 1 is divided into a case where M is an even number and an odd case. The even case is obtained based on Equation 2 below, and the odd case is obtained based on Equation 3 below. Do it.

The C and M defined as constants should be defined in consideration of the maximum delay size that can be accommodated in the RAN and the minimum delay size that can distinguish each subregion.

In addition, when the number of subregions is smaller than M, the value of dn defined in the above formula may be continuously applied or may be selectively applied in consideration of the delay size. In both cases, the search channel size of the call channel must be set so that the RAN can accommodate the multipath of both cells in the overlapping region of adjacent cells.

FIG. 5 illustrates an example of arrangement of detailed areas when the detailed areas are divided into six (Z1 to Z6) and the reference delay size is set to 20 PN chips.

Each adjacent sub-zone (Zone 1 to Zone 6) is continuously arranged without assigning a guard range.

6 is a flowchart of a method for locating a terminal in a single base station service area according to an embodiment of the present invention implemented based on the above description.

First, as shown in FIG. 3, distributed antennas 321-323 extending from a single base station 310 and distributed in subregions are installed (S601). The base station 310 and the base station are installed through a hardware artificial method. By varying the delays 331-333 for the paths 321a-323a between the antennas 321-323, the delay distribution values of the signals received by the respective antennas 321-323 are mutually different as shown in FIG. 4, for example. It is set to not overlap (S602).

Subsequently, when a communication signal is received through the multipaths 321a-323a corresponding to the distributed antennas 321-323 (S603), after calculating a delay value of the received signal (S604), the calculated delay is calculated. Based on the value, the delay distribution value preset by the step S602 and the strength of the received signal, it is determined in which area of the detailed area the corresponding terminal of the received signal is located (S605).

The delays 331-333 for the respective paths 321a-323a in step S602 impose artificial delays on both the transmit and receive paths, artificial delays only on the receive paths, and / or diversity in the receive paths as described above. Only the path is made with an artificial delay, which is selectively made based on the environment in which the base station 310 is installed and the relationship with neighboring base stations.

FIG. 7 is an example of a detailed process of steps S603 to S605 of FIG. 6, and illustrates a detailed process of a terminal location method used when the signal received in step S603 is a signal through an access channel. .

In addition, FIG. 8 illustrates another detailed process of steps S603 to S605 of FIG. 6, which is a detailed process of a terminal location method used when the signal received in step S603 is a signal through a traffic channel. Indicates.

7 will be described.

In the access channel, the detailed area of the terminal is determined by using a round trip delay value at the time of receiving capsule data. The method used is as follows.

First, after receiving an access message, a randomization delay (RD) is calculated. The delay magnitude calculated thereafter is used as a result of compensating this RN value (S701).

In step S702, the RTD of each multipath whose RN value is compensated corresponds to a specific area.

The received energy of each of the multipaths grouped by the subregions is accumulated (S703).

If the accumulated energy is greater than the predetermined threshold (S704), it is determined as a candidate candidate zone. If there is one candidate subregion, it is determined as the call subregion, that is, the subregion to which the terminal belongs.If two subregions are geographically adjacent to each other, it is determined as the boundary of the two subregions. If it is not adjacent to each other and is adjacent due to the delay size, it is determined as the detail region having the smaller delay size. If there is no candidate detail region, it is determined that the detail region determination is impossible. (S705).

For reference, since the RF coverage of each subregion is separated, or the threshold for the received signal strength for the determination of the candidate subregion is increased, the accuracy of the subregion determination is increased. When the distributed antenna is installed, the threshold value and the delay value are determined through field tests. This value is determined so that there are two or more candidate subregions for the accuracy of judgment.

8 will be described.

In this example, the same procedure can be used except for step S701 in the process of FIG. 7 used in the access channel. In addition, in the case of a call channel (TCH), since the time for collecting RTD information is very long compared to the access channel, the following method may be applied. It demonstrates with reference to FIG.

First, each energy of each received multipath is sampled in frame units 20mSec (S801).

Energy of each of the multipaths obtained in step S801 is accumulated for each subregion (S802).

By applying a sliding window for a predetermined period (for example, 2 seconds), the results of steps S801 and S802 in the window are accumulated for each subregion. The window always calculates for a period of time in the past based on the current time.

The accumulated value is compared with a predetermined threshold (S803) to determine whether a candidate candidate zone is present. If there is one candidate subregion, it is determined as the call subregion, that is, the subregion to which the terminal belongs.If two subregions are geographically adjacent to each other, it is determined as the boundary of the two subregions. In the case of not adjacent to each other and adjacent in terms of the delay size, it is determined as the subregion having the smaller delay size. If there is no candidate detail region, it is determined that the detail region determination is impossible. (S804).

For reference, since the RF coverage of each subregion is separated or the subfield determination threshold is increased by the candidate subregion determination threshold, the threshold value and the delay value are set through field tests when the base station and the distributed antenna are installed. do. This value is determined so that there are two or more candidate subregions for the accuracy of judgment.

As described in detail above, according to the method and apparatus for determining a location of a terminal in a single base station service area according to the present invention, the service area of a single base station can be divided into a plurality of detailed areas so as to determine the location of the corresponding area in which the terminal is communicating. Thus, the effect of providing a detailed location-based service in the service area of a single base station is created.

Claims (10)

A method of dividing a service area of a single base station into detailed areas and determining a location of a terminal for each detailed area, A first step of installing a distributed antenna that is extended from the base station and distributedly located in each of the sub-regions; A second step of differently setting a delay distribution value deviation between adjacent areas for each antenna to be different in a maximum range; Calculating a delay value of a signal received by the base station through each antenna; And And a fourth step of determining candidate detail region and final terminal position information based on the calculated delay value, the predetermined delay distribution value, and the cumulative energy amount of each detail region of the received signal. Method of locating terminal in single base station service area. The method of claim 1, Wherein the second step is performed by artificially delaying both transmission and reception paths. The method of claim 1, The second step is a terminal location within a single base station service area, characterized in that the artificial delay is given only to the receiving path. The method of claim 1, Wherein the second step is performed by artificially delaying only a diversity path of a reception path. The method of claim 1, The second step is a method for locating a terminal within a single base station service area, characterized in that the antenna is artificially delayed for each transmit / receive path, only the receive path, and / or only the diversity path of the receive path for each antenna. The method of claim 1, The delay distribution is a terminal location within the service area of a single base station, characterized in that by adjusting the length of the wired path for extending the connection between the base station and each antenna. delete delete delete delete