2. 程式人生 > >【 Notes 】MOBILE LOCALIZATON METHOD BASED ON MULTIDIMENSIONAL SIMILARITY ANALYSIS

【 Notes 】MOBILE LOCALIZATON METHOD BASED ON MULTIDIMENSIONAL SIMILARITY ANALYSIS

阿新 發佈:2018-11-22

目錄

ABSTRACT

INTRODUCTION

LINEAR TOA LOCALIZATION

MULTIDIMENSIONAL SIMILARITY ANALYSIS

SUBSPACE BASED LOCALIZATION

SIMULATION RESULTS

CONCLUSION

REFERENCES

ABSTRACT

A novel noise subspace based method is applied to the minimum localization system using time-of-arrival (TOA) measurements from three base stations (BS). Since the distance measurement between the mobile station (MS) and the BS bears analogy to the multidimensional similarity (MDS) between their coordinates, we express the MS coordinate as the linear combination of the BSs’ coordinates, where the weight vector lies in the noise subspace of the MDS matrix. It is proved that this weight vector is the area coordinate of the MS when the triangle formed by the three BSs serves as the reference frame.
Because the dimension knowledge of the localization problem is utilized to estimate the noise subspace and to mitigate the errors in TOA measurements, the proposed method is superior to the ordinary linear localization method in most of the enhanced quadrants of the area
coordinates system.

基於噪聲子空間的新方法應用於來自三個基站(BS)的到達時間(TOA)測量的最小定位系統。 由於移動臺(MS)和BS之間的距離測量類似於它們座標之間的多維相似性(MDS),我們將MS座標表示為BS座標的線性組合,其中權重向量位於噪聲中 MDS矩陣的子空間。 證明了當由三個BS形成的三角形作為參考框架時,該權重向量是MS的區域座標。

由於利用定位問題的維數知識來估計噪聲子空間並減輕TOA測量中的誤差,所提出的方法在區域座標系的大多數增強象限中優於普通線性定位方法。

INTRODUCTION

Recently, positioning of the mobile station (MS) in cellular systems attracted large interest and the number of applications based on the location information grew rapidly. Large-scale deployment of such applications usually requires methods for positioning that are accurate
and simple enough to be used in mobile phones.
Many linear methods have been proposed to estimate the MS position in closed-form.

The first and simplest of the existing methods is the Cell ID (CID) method where the position estimate is the coordinate of the serving BS.


The second of the existing methods is described in [1], the MS position is calculated as the average (centroid) of the positions of all N BSs whose beacons the MS can decode. It is called UnWeighted Centroid (UWC) method.

The CID method can be regarded as a special case of UWC with N=1. In [2], three approximated linear methods were proposed to estimate the position of the MS. The first, Path-Gain Weighted Centroid (PGWC) method, is based on signal strength, the second, Time Weighted Centroid (TWC) method, is based on time, and the third, PGWC+TA, is a hybrid between time and signal-strength methods.

Finally, the third benchmark method uses circular multilateration of propagation delays. This is sometimes known as Time-of-Arrival (TOA) [3]. In our implementation of TOA localization, the ordinary method calculates the MS positions from the MS-BSi propagation delays using a linear and closed-form solution [4].


In this paper, we propose a simple but quite accurate localization method and compare it with the ordinary method by means of simulation. Our results show that in the noisy measurement environment, the proposed algorithm is superior to ordinary linear localization methods in most of the enhanced quadrants of area coordinates system. Unlike the enhanced quadrant-aware localization method in [5] and [6], the linear weight vector in the proposed method is derived from multidimensional similarity analysis.
Our proposed methods are very simple and do not require complicated calculations as opposed to some iterative methods [7]-[9]. The performance measures are coordinate bias and cumulative distribution function of the root mean square location error, and the evaluation is done for seven quadrants in the area coordinate system.
Because the dimension knowledge of the localization problem is utilized to estimate the noise subspace and to mitigate the errors in range measurements, the proposed method is superior to the ordinary linear localization method in most of the enhanced quadrants.

注:紅色字型部分是論文所做的工作!

LINEAR TOA LOCALIZATION

Consider the problem of MS location using range measurements from three BSs. Assume that the BSs locate at  (x_i,y_i),i=1,2,3 and the MS locates at  (x_0,y_0)  in the system of rectangular coordinates.
The MS position can be expressed as

It is the linear combination of BSs’ position, where the weight vector (s_1,s_2,s_3) is not unique. Introducing the following constraint

Equation (1) becomes

From Cramer’s determinant formula, we have

It can be proved that the absolute value of s_1,s_2 ,s_3 is the normalized area (with respect to the area of triangle formed by BS1, BS2 and BS3) of triangle formed by (MS, BS2, BS3), (MS, BS1, BS3) and (MS, BS1, BS2), respectively.

可以證明 s_1,s_2 ,s_3 的絕對值是由(MS,BS2,BS3),(MS,BS1,BS3)和 (MS,BS1,BS2)形成的三角形的歸一化區域(相對於由BS1,BS2和BS3形成的三角形的區域)。

 

Therefore, we call  (s_1,s_2,s_3)  area coordinates of the MS. The signs of  (s_1,s_2,s_3)  are determined by the enhanced quadrant in which the MS lies [5]. As shown in Fig.1, we have seven quadrants in area coordinate system, whereas four in rectangular coordinate system.

因此,我們稱MS為 (s_1,s_2,s_3) 區域座標。 (s_1,s_2,s_3) 的符號由MS所在的增強象限決定[5]。 如圖1所示,我們在面積座標系中有七個象限,而在直角座標系中有四個象限。

From (3), we have the following orthogonal property,

which means that the vector  [s_1,s_2,s_3]  lies in the orthogonal  subspace  spanned  by vectors [x_1-x_0,x_2-x_0,x_3-x_0] and [y_1-y_0,y_2-y_0,y_3-y_0].

If the vector  [s_1,s_2,s_3]  is estimated from TOA measurements, the MS position can be calculated from (4).
In [5], the absolute value of area coordinate of MS is estimated by using Heron formula, but the sign is determined by the enhanced quadrant information. When this information is not known, it may be determined from an original estimation of MS position. However, when the MS locates close to the axes of the reference triangle, the ambiguity of the enhanced quadrant will degrade the location performance.
In the following two sections, we introduce the multidimensional similarity (MDS) matrix and establish the relationship between the vector [s_1,s_2,s_3]  and the null  space of the MDS matrix. Based on this relationship, we can calculate the vector[s_1,s_2,s_3] from the null subspace of the MDS matrix without additional quadrant information.

MULTIDIMENSIONAL SIMILARITY ANALYSIS

Assume that the distance between the i-th BS and the MS is r_i , between the i-th BS and the j-th BS is d_{i,j},i,j = 1,2,3 . Note that d_{i,i}=0 and d_{i,j}=d_{j,i} . Define a symmetric matrix as

Denote the element of matrix D by D_{i,j} , i, j=1,2,3.
From cosine formula, we have

where \theta_{i,j} is  the  angle  between  the  vectors [x_i - x_0,y_i - y_0] and [x_j - x_0,y_j - y_0]. Therefore, we have

It can be seen that the matrix D is semi-positive with the rank equaling to 2 if vectors [x_1 - x_0,x_2 - x_0,x_3 - x_0] and [y_1 - y_0,y_2 - y_0,y_3 - y_0] is not correlated, and D_{i,j}, the elements of Matrixis the correlation between the vectors 

[x_i - x_0,y_i - y_0] and [x_j - x_0,y_j - y_0]

BecauseD_{i,j} measures the similarity between two vectors, matrix D is also called multidimensional similarity matrix [10].

SUBSPACE BASED LOCALIZATION

Let the eigenvalue decomposition of   D be 

where \Sigma = diag(\lambda _1,\lambda_2,\lambda_3)\bold{U = [u_1,u_2,u_3]} and \lambda_1 \geq \lambda_2 \geq \lambda_3

Because the rank of matrix D equals to 2, we have

\lambda_3 = 0

and 

\bold{u_3^TDu_3} = 0

From (6), we have

Comparing (4) with (7) yields

where

is sum of the elements of vector \bold{u_3} . From (7), a novel subspace based position estimation can be given by

SIMULATION RESULTS

In this section, we compare the proposed location method with the ordinary method, which gives the position estimation as [4]

As shown in Fig.1, three base stations locate at (0, 0), (2500, 4330) and (5000, 0), and the range measurement error is Gaussian distributed with zero mean and standard deviation of 30, all the units are meter. To compare the performance of the above two methods, seven mobile stations are fixed in different quadrant of area coordinate system.
Table 1 gives the comparison results of the root mean square location error. They are obtained from 300 runs at each MS position. It can be seen that the improvement of the proposed method is significant in quadrant 2, 4, 5 and 7. Because the root mean square location error is not enough to reflect the distribution of location error, we also plot in Figs.2-5 the estimation bias of x and y coordinates obtained in each run.

如圖1所示,三個基站位於(0,0),(2500,4330)和(5000,0),距離測量誤差為高斯分佈,零均值和標準差為30,所有單位 是米。 為了比較上述兩種方法的效能,將7個移動臺固定在不同的區域座標系的象限中。

表1給出了均方根位置誤差的比較結果。 它們來自每個MS位置的300次執行。 可以看出,所提方法的改進在象限2,4,5和7中是顯著的。由於均方根位置誤差不足以反映位置誤差的分佈,我們也在圖2-5中繪製。 每次執行中獲得的x和y座標的估計偏差。

Comparison of location error in different quadrant of area coordinate system is illustrated in Figs.2-5. The left two columns of these figures are the location bias of x and y coordinates obtained from the proposed method and the ordinary method, respectively, and the right column is the cumulative distribution function (CDF) of the root mean square location error (solid line: the proposed method, dotted line: the ordinary method). Though the location error distributes differently in each quadrant, it can be seen that the improvement of the proposed method is significant in most of quadrants, except quadrant 3.

區域座標系不同象限的位置誤差比較如圖2-5所示。 這些圖的左兩列分別是從所提出的方法和普通方法獲得的x和y座標的位置偏差,右列是均方根位置誤差的累積分佈函式(CDF)(實線) :提出的方法,虛線:普通方法)。 儘管位置誤差在每個象限中的分佈不同,但可以看出,除了象限3之外,所提方法的改進在大多數象限中都很重要。

CONCLUSION

This paper establishes the relationship between the weight vectors of the enhanced quadrant-aware method and the proposed dimension-aware method, which estimate the rectangular coordinates of the mobile station by linear combination of that of the base stations. Unlike the former method, the linear weight vector is estimated from multidimensional similarity analysis and the additional enhanced quadrant information is not required in the proposed method. Simulation results shown that the proposed method performs better than the ordinary method in most of quadrants in area coordinate system.

本文建立了增強象限感知方法的權向量與所提出的維數感知方法之間的關係,該方法通過基站的線性組合來估計移動臺的直角座標。 與前一種方法不同,線性權重向量是從多維相似性分析估計的,並且在所提出的方法中不需要附加的增強象限資訊。 模擬結果表明,該方法在區域座標系中的大多數象限中均優於普通方法。

注:至於模擬我會試一下,將這片論文拿出來做筆記的原因在於覺得這是一種不錯的方法。我們可以觸類旁通,用到其他方面,不僅僅是在通訊中。例如,電子對抗定位中。

模擬地址:https://blog.csdn.net/Reborn_Lee/article/details/84206489

REFERENCES

[1] N. Bulusu, J. Heidemann, D. Estrin, “GPS-less Low-Cost Outdoor Localization for Very Small Devices”, IEEE Personal Communications Mag., Vol. 7, No. 5, pp. 28-34, Oct 2000.

https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=878533&tag=1
[2] M. Berg, “Performance of mobile station location Methods in a Manhattan Microcellular Environment”, Technical Reports from Signal Processing, Royal Institute of Technology, Sweden, Oct 2002.

https://www.researchgate.net/publication/2362632_Performance_Of_Mobile_Station_Location_Methods_In_A_Manhattan_Microcellular_Environment
[3] J.J. Caffery, G.L. Stüber, “Overview of Radiolocation in CDMA Cellular Systems”, IEEE Communications Mag., Vol. 36, No. 4, pp. 38 45, Apr 1998.

https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=667411&tag=1
[4] J. J. Caffery, Wireless Location in CDMA Cellular Radio System, Kluwer Academic Publishers, Boston Dordrecht London, 2000.

http://gpreview.kingborn.net/268000/7c9a7a245ef74bf4b743fed11886cf73.pdf
[5] Q. Wan, S. J. Liu, F. X. Ge, J. Yuan, Y. N. Peng, W.L. Yang, “A Quadrant-Based Range Location Method”, IEEE Conference on VTC, pp. 210-212, Apr 2003

https://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1207532
[6] Q. Wan, Y. N. Peng, “An Improved 3-Dimensional Mobile Location Method Using Volume Measurements of Tetrahedron”, IEICE Transactions on Communications, Vol. E85-B, No.9, pp. 1817-1823, Sept. 2002

https://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1021473
[7] Y. T. Chan, K. C. Ho, “A Simple and Efficient Estimator for Hyperbolic Location”, IEEE Transaction on Signal Processing, Vol.42, No.8, pp. 1905-1915, 1994.

https://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=301830
[8] J. O. Smith, J. S. Abel, “The Spherical Interpolation Method of Source Localization”, IEEE Journal of Oceanic Engineering, Vol. 12, No. 1, pp. 246-252, 1987.

https://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1145217
[9] Q. Wan, Y. N. Peng, “Enhanced Linear Estimator for Mobile Location using Range Difference Measurements”, IEICE Transactions on Communications, 2002, E85-B(5): 946-950.


[10] I. Borg, J. Lingoes, Multidimensional Similarity Structure Analysis, Springer-Verlag, New York, 1987.

https://link.springer.com/book/10.1007%2F978-1-4612-4768-5

 

原論文地址:https://download.csdn.net/download/reborn_lee/10792598

相關推薦

Notes MOBILE LOCALIZATON METHOD BASED ON MULTIDIMENSIONAL SIMILARITY ANALYSIS

目錄 ABSTRACT INTRODUCTION LINEAR TOA LOCALIZATION MULTIDIMENSIONAL SIMILARITY ANALYSIS SUBSPACE BASED LOCALIZATION SIMULATION RESULTS C

Notes ALGORITHMS FOR TDOA-based SOURCE LOCALIZATION

Measurement Model in my blog:Measurement Model and Principles for TDOA-based Location Nonlinear Method: NLS Similarly, with the use of Equat

Notes Measurement Model and Principles for TDOA-based Location

TDOA is the difference in arrival times of the emitted signal received at a pair of sensors, implying that clock synchronization across all receiver

Notes Best linear unbiased estimator(BLUE) approach for time-of-arrival based localisation

目錄   Abstract Introduction BLUE-based positioning  BLUE-LSC algorithm  BLUE-LLS algorithm Abstract  A common

Notes WLLS Algorithm of TOA - Based Positioning (include the two - step WLS estimator)

目錄   LLS review WLLS the two - step WLS estimator LLS review 前面有博文:LLS,提到了線性最小二乘演算法,使用LLS去求解TOA-Based Positioning問題,從推導過程看起來很簡單。具

Codeforces Round #517 (Div. 2, based on Technocup 2019 Elimination Round 2) C. Cram Time 貪心

C. Cram Time 題意 給你兩個數a,b,用a,b分別構造兩個序列A,B, 要求A序列的和小於a,B序列的和小於b 而且A序列中和B序列中每個數最多在兩個序列中出現一次 要是最終的兩個序列的長度和最大,輸出兩個序列 做法

Codeforces Round #517 (Div. 2, based on Technocup 2019 Elimination Round 2) D. Minimum pathdp+滾動陣列

D. Minimum path 題意 給你一個字元矩陣,起點在左上角,每次可以向右或者向下走,可以改變這個字元矩陣中的k個字元,是這個路徑構成的字串字典序最小。 做法 由於可以改變k個字元,那麼肯定是找到一條路徑,前面至少有k項為a, 後面按照字典序選擇路徑就可以。 所

Codeforces Round #517 (Div. 2, based on Technocup 2019 Elimination Round 2) A.B.C.D

前言 在晚上的div2之前開啟的這場,但是自己頭腦貌似不太清醒,全程在寫bug,而且B題不知道自己在寫啥,寫了一百多行?,C也寫了好多bug導致最後的D一眼思路但是沒寫完。希望晚上狀態不要這麼差!QWQ A. Golden Plate 題意 給你一個h*w的長方形邊框,

poj1195Mobile phones(二維樹狀數組)

單點 開始 str type algo while blog target hone 題目鏈接:http://poj.org/problem?id=1195 【題意】 給出一個全0的矩陣,然後一些操作 0 S:初始化矩陣,維數是S*S,值全為0,這個操作只有最開始出現

Rno applicable method for 'xml_find_all' applied to an object of class "xml_document"

原始碼: # 安裝依賴包 if (!require(rvest)) { install.packages("rvest") } if (!require(xml2)) { install.packages("xml2") } # 引入 library(rvest)

15、Short-term CHP Heat Load Forecast Method based on Concatenated LSTMs

亮點:提出了一種級聯LSTM模型,很有創新性 基於短期熱電聯產熱負荷預測方法級聯LSTM CHP (combined heat and power):熱電聯供 首先對輸入資料進行歸一化處理; 並將其分為歷史氣候和熱負荷資料。然後 將分離的資料饋送到兩個LST

PytorchRuntimeError: arguments are located on different GPUs

0x00 前言 Pytorch裡使用optimizer的時候,由於其會記錄step等資訊, 有時會希望將optimizer的內容記錄下來,以備之後繼續使用, 那麼自然而然的會想到使用API中自帶的torch.save(object, path)torch.load(pa

Easily Build Android APKs on Device in Termux

您是否曾想在Android上構建自己的Android應用程式? 你自己的應用程式,APK! 您可以通過網際網路分發的東西,可以在全球的Android智慧手機上使用。 您是否敢於嘗試花一些時間學習新的東西? 此原始碼儲存庫僅用於此目的。 原始碼是用可理解的人類語言編寫軟體的方

Notes TOA Estimation Preliminary introduction

TOA estimation allows the measurement of distance, thus enabling localization. Here, multiple base nodes collaborate to localize a target

Notes Time

As the name suggests, TDOA estimation requires the measurement of the difference in time between the signals arriving at two base nodes. S

Notes COMPARISON OF BASIC METHODS AND POSITIONING SYSTEMS

目錄 COMPARISON OF BASIC METHODS AND POSITIONING SYSTEMS 各種基本方法以及定位系統的對比: This section compares basic localization methods and positi

Notes SOURCE LOCALIZATION PREVIEW

FINDING THE  position of a passive source based on measurements from an array of spatially separated sensors has been an important problem

Notes ML ALGORITHMS of TOA

ML方法是NLS方法的一個推廣版本,具體接著看: Assuming that the error distribution is known, the ML approach maximizes the PDFs of TOA measurements to obtai

New method based on artificial intelligence may help predict epilepsy outcomes

Medical University of South Carolina (MUSC) neurologists have developed a new method based on artificial intelligence that may eventually help both patient

BZOJ2588 Spoj 10628. Count on a tree LCA+主席樹

題目傳送門 如果是強制線上的話,那就只能用主席樹了。 這題的主席樹建立方法也是挺好的,每個節點向它的父親節點建立主席樹。 對於每個詢問(x,y),抓住x,y,lca(x,y),father[lca(x,y)]這四個點,初始化這四個點在各自主席樹的根部,然後