WO2020133721A1 - 一种基于非参数贝叶斯框架的信号交叉口状态估计方法 - Google Patents
一种基于非参数贝叶斯框架的信号交叉口状态估计方法 Download PDFInfo
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- G—PHYSICS
- G08—SIGNALLING
- G08G—TRAFFIC CONTROL SYSTEMS
- G08G1/00—Traffic control systems for road vehicles
- G08G1/01—Detecting movement of traffic to be counted or controlled
- G08G1/0104—Measuring and analyzing of parameters relative to traffic conditions
- G08G1/0125—Traffic data processing
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- G—PHYSICS
- G08—SIGNALLING
- G08G—TRAFFIC CONTROL SYSTEMS
- G08G1/00—Traffic control systems for road vehicles
- G08G1/01—Detecting movement of traffic to be counted or controlled
- G08G1/0104—Measuring and analyzing of parameters relative to traffic conditions
- G08G1/0137—Measuring and analyzing of parameters relative to traffic conditions for specific applications
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- the invention belongs to the field of traffic control, and relates to a signal intersection state estimation method based on a non-parametric Bayesian framework.
- Traffic State Estimation refers to the process of inferring changes in traffic state using part of traffic observation data with noise. These data are obtained from various monitoring technologies. Signal-controlled intersections are an indispensable component of urban traffic networks. Accurate and practical TSE methods play an important role in the planning and operation of signal-controlled intersections, which can effectively alleviate traffic congestion. Especially for traditional signal control systems, estimating the traffic state is of great significance for measuring the performance of intersections and further optimizing signal control schemes. In addition, for most emerging adaptive traffic signal control systems, their basic idea is to understand the evolution of the traffic state. In general, the more precise and advanced the signal control system, the more accurate and frequent traffic status data is required.
- TSE methods can be divided into two categories based on different assumptions and input data that they rely on.
- One is model-driven methods, and the other is data-driven methods.
- the model-driven TSE method relies on the physical model of the transportation system, which is characterized by the need for empirical relationships and the need for careful model selection and calibration procedures. In specific cases, a large amount of data is required to test the rationality of the model or to calibrate the model.
- the data-driven TSE method must consider historical data under various traffic conditions, otherwise the method may fail if an emergency occurs. In addition, the cost of training and learning may be relatively high. However, with the continuous development of data and sensing technologies, data-driven models have attracted more and more attention.
- the present invention is to provide a signal intersection state estimation method based on a non-parametric Bayesian framework, does not require an accurate traffic model, is driven by data, has a wide range of applications, and has an estimated accuracy rate high.
- a state estimation method of signalized intersection based on non-parametric Bayesian framework the steps are as follows:
- Intersection state estimation the extended Kalman filter is used to linearize the transfer model and measurement model, and then the traffic state and signal control parameters at the previous moment are input to the transfer model to obtain the predicted state and its covariance, and then the The obtained predicted state, its covariance, and the measured value at the current time are input to the measurement model to predict the best estimated value of the state at the current time.
- step (4) verification of the state estimation method the introduction of connected car data, calculation of intersection state estimation accuracy at different estimation intervals and connected vehicle penetration rates.
- state data is traffic flow data
- state vector is expressed as:
- n k,t represents the number of vehicles on the kth lane at time t
- N lane represents the total number of lanes at the intersection
- the control data is the green signal ratio, and the control vector is expressed as:
- g k,t refers to the green signal ratio controlling the k-th lane at time t within the defined estimation interval of traffic lights.
- the transition model is expressed as:
- g( ⁇ ) represents a mapping between the state-control pair (x t-1 , u t-1 ) at time t-1 and the state x t at time t , and ⁇ follows the covariance matrix of ⁇ tran and the mean is zero White Gaussian distribution process;
- the state transition probability is as follows:
- the measurement model is expressed as:
- h ( ⁇ ) represents the state at time t and the measured values X t mapping between z t, ⁇ subject covariance matrix ⁇ meas, white Gaussian process with zero mean;
- the measurement probability is as follows:
- ⁇ meas represents the covariance matrix of the measurement model.
- the number of elements of the state, control, and measurement vectors are respectively represented by M x , Mu , and M z , and the data points of the three are the same size, then the training data sets of the transfer model and the measurement model are respectively for:
- X tran and Y tran are the data points of the input and output of the transfer model, X meas and Y meas are the input and output data points of the measurement model;
- z q,t refers to the q-th element of the measurement vector
- linearization of the transfer model and the measurement model specifically uses an extended Kalman filter, uses a first-order Taylor expansion to construct the function value, and slopes to approximate the function linearly.
- predicting the optimal estimate of the state at the current moment also includes: calculating the Kalman gain using the predicted state and the covariance matrix, adding the predicted state to the new state estimate based on the correctness of the measured value, and calculating the optimal State, the degree of accuracy is proportional to the Kalman gain, and proportional to the deviation between the current measured value and the predicted measured value.
- non-parametric Bayesian framework adds estimated interval and vehicle permeability parameters, specifically:
- measuring elements can be calculated by the following formula:
- r k,t refers to the penetration rate of the connected vehicle at time t
- ⁇ t refers to the estimated interval duration
- ⁇ represents the length of time to update the permeability
- the verification parameters for estimating the accuracy of the intersection state estimation include: mean absolute error (MAE) and weighted mean absolute error (WAPE), the calculation formula is as follows:
- T is the total time period of the sequence
- MAE refers to the average absolute error that can be expected in the estimation method. WAPE allows the comparison of estimates under different conditions.
- the design of the frame is compatible with the traditional signal control system and the adaptive signal control system.
- the generated lane-based state can be used for the signal controller based on the group or lane; the frame is not limited by the data type, that is, the fixed position detection data and Mobile data can be used; the included model is non-parametric and does not require prior knowledge of setting parameters.
- Figure 1 is the offline training process of Bayesian filter based on Gaussian process.
- Figure 2 is the online estimation process of Bayesian filter based on Gaussian process.
- Figure 3 is the pseudocode for one-step state estimation using the BFGP modeling framework.
- Fig. 4 is the pseudo code of the detailed steps of the extended Kalman filter based on the Gaussian process.
- Figure 5 is a typical independent intersection layout.
- Fig. 6 is a semaphore phase sequence.
- This embodiment provides a method for estimating the state of a signalized intersection based on a non-parametric Bayesian framework. The steps are as follows:
- the problem of recursive state estimation is to determine the most likely state in a certain period of time given all the past measurement and control inputs. Therefore, the probability rules describing the evolution of the state are determined by the probability distribution conditioned on the measurement and control signals.
- the posterior probability of the state variable of the probability distribution is referred to as belief distribution for short. Assuming that the system starts from the initial state x 0 and performs the initial control u 0 , the first measurement vector is defined as z 1 . Then the belief distribution bel(x t ) of the state variable x t at time t is expressed as follows:.
- the initial belief distribution which refers to the prediction of the state at time t based on the previous state posterior distribution bel(x t-1 ) before combining the measured values.
- the estimated bel(x t ) is usually called measurement correction or measurement update. Therefore, the realization of the Bayesian filter requires three probability distributions: state transition probability P(x t
- the state transition model is usually expressed as:
- h( ⁇ ) refers to the mapping between the state x t and the measured value z t at time t .
- X is an N ⁇ M matrix
- the rows of the matrix are a 1 ⁇ M vector, representing the input data.
- y represents the training output, which is an N ⁇ 1 matrix, and the training data is represented as (12)(13):
- x i and y i are the column vector and scalar value of the i-th training data set.
- K represents the covariance matrix determined by the kernel function of the input data, and its elements are expressed as follows:
- K( ⁇ ) is a kernel function, indicating the degree of similarity between data points. Specifically, if two data points (x i , x j ) are more similar, then their instance values (f i , f j ) are more related. The degree of similarity depends on the differences between the applied variables.
- the joint distribution of output variables is a multivariate Gaussian distribution, including new variables conditioned on input data points and hyperparameters. which is:
- c N+1 is an N ⁇ 1 matrix, defined as follows:
- c N+1 [C(x 1 ,x N+1 , ⁇ , ⁇ 1 ),C(x 2 ,x N+1 , ⁇ , ⁇ 2 ),...,C(x N ,x N+ 1 , ⁇ , ⁇ N+1 )) T (26)
- ⁇ (x N+1 ,D) and ⁇ (x N+1 ,D) refer to the mean and variance functions, respectively, as shown in (28)(29) below:
- X tran and Y tran are the input and output data points of the transfer model
- X meas and Y meas are the input and output data points of the measurement model.
- Each input data point of the transfer model contains a state and control vector, which is a (M x +M u ) ⁇ 1 column vector, defined as follows:
- z q,t refers to the q-th element of the measurement vector
- the extended Kalman filter is used to linearize the transfer model and measurement model, and then the traffic state and signal control parameters at the previous moment are input to the transfer model to obtain the predicted state and its covariance, and then the obtained The predicted state and its covariance, and the measured value at the current time are input to the measurement model to predict the best estimated value of the state at the current time, see Figure 2.
- Figure 3 shows the one-step estimation process of new observations.
- the BF one-step estimation process also requires the state, covariance, and control data that were estimated at the previous moment. If the historical data sets D tran and D meas exist, then the historical data set can be used to update the transfer and measurement models.
- the Kalman filter When performing state estimation and prediction in a state space model, the Kalman filter is a widely used framework. However, equations (34) and (35) show that the transfer and measurement models are nonlinear functions. In order to deal with this nonlinearity, many algorithms are proposed under the BF modeling framework, such as extended Kalman filter, unscented Kalman filter, and particle filter. The present invention chooses to apply an extended Kalman filter and uses the first-stage Taylor expansion to linearize the nonlinear function based on GP.
- An extended Kalman filter based on a Gaussian process uses the last estimated state x t-1 , covariance ⁇ t-1 , control u t-1 , and current measured value z t-1 to predict the current state x t and its covariance matrix ⁇ t .
- Figure 4 shows the steps of DPEKF in detail using pseudocode, and then describes the mathematical rules of each step.
- Lines 1 and 2 represent prediction steps, and lines 3, 4, and 5 represent update steps.
- the predicted state s t can be composed of the following matrix:
- a first-order Taylor expansion can be used to construct the function value and the slope to linearly approximate the function.
- the covariance matrix of the predicted state is calculated by (38) below:
- the third line in the pseudocode indicates that the predicted state and the covariance matrix are used to calculate the Kalman gain.
- the specific expression is shown in (39):
- H t represents the Jacobian determinant of the GP mean function in the measurement model:
- the current estimated state is (41):
- the invention utilizes information gain Adjust the covariance matrix of the predicted state to update the covariance matrix of the estimated state, such as (42):
- the TSE method described in the present invention is verified using connected vehicle traffic data, and the traffic state data comes from a micro simulator.
- the experiment applies the estimation method to a typical, independent intersection, see Figure 5.
- the signal controller at this intersection uses phase-based phases, in which the traffic lights operate in a fixed phase sequence, see Figure 6 for the phase sequence.
- the induction detector includes a short induction detector and a long induction detector, which are placed at 80 meters and 10 meters away from the parking line, respectively.
- the present invention adopts a "vehicle drive" signal timing method, that is, the green light distribution time varies according to the number of vehicles detected by the loop detector.
- the elements of the state vector represent the number of vehicles, including queued vehicles, approaching vehicles, and vehicles in the lanes associated with intersections. The manner in which this state is defined has been applied to multiple adaptive signal control systems.
- the state vector is shown in equation (43):
- N lane 12
- Control data is obtained by collecting general information (green light, yellow light, red light) indicated by traffic lights, and any type of signal controller can access these data. In the process of state transition, green and non-green light indicators will have an important impact on the number of vehicles in the lane.
- the control vector is as follows (44):
- g k,t refers to the green signal ratio controlling the k-th lane at time t within the defined estimation interval of traffic lights.
- the framework uses Internet of Vehicles data sources.
- V2I vehicle-to-vehicle interface
- the signal controller can access the vehicle location.
- the number of connected vehicles in each lane can be extracted in real time.
- each connected vehicle enters an intersection and an ID is given.
- the signal controller is “responsible” to record the vehicle ID, and the flow of connected vehicles within a certain time interval is equal to the number of unique vehicle IDs.
- ⁇ t refers to the estimated interval duration
- r k,t refers to a rough estimate of the penetration rate of the connected vehicle at time t
- the recursive update equation is as follows:
- ⁇ represents the length of time to update the permeability. Represents the number of connected vehicles on lane k at time l, the corresponding measurement vector is defined as follows (47):
- T is the total time period of the sequence
- I the observed state vector.
- MAE refers to the average absolute error that can be expected in the estimation method. WAPE allows the comparison of estimates under different conditions.
- the traffic model is built on the open source micro simulator SUMO0.19.0. Then connect the developed and designed signal controller software program with the SUMO simulator, and set the traffic light signal changes in the simulation based on "vehicle drive" control.
- SUMO records the detection information and the number of vehicles on each lane through the programming interface TraCI provided by the application.
- a commonly used car tracking model-Intelligent Driver Model (IDM) is used. The parameters of the car following model and signal control parameters are shown in Table 1.
- the training data set refers to a set of data samples used to discover the potential relationship between state, control, and measurement; according to the performance standards described, the verification set is used to compare model performance or estimated accuracy, and the test set is used to evaluate The effectiveness of the proposed estimation method and provide detailed content of the estimation results.
- L, T, R represent the left turn rate, straight rate, and right turn rate, respectively.
- the "uniform" scheme in Table 2 assumes that the traffic flow is the same in all directions at the intersection.
- the "mainline” scheme considers the north-south direction or the east-west direction to be the main road.
- the corresponding traffic flow is defined as “medium” or “high” level.
- the “medium” level indicates that the traffic flow at the intersection is normal, and the “high” level indicates that there is a significant increase in traffic flow (about 20%) compared to the “medium” level.
- the traffic flow is randomly generated, and the selected values are shown in Table 2.
- Each verification data set contains 600 simulated data points.
- the traffic flow starts from the "East-West Main Line (Middle)" scheme, and the pattern of the traffic flow scheme is arranged from "East-West Main Line East (Middle)” ⁇ "East-West Main Line (High)” ⁇ "Uniform (High)” ⁇ "North-South Main Line (High)” ⁇ "Uniform (Middle)” ⁇ "North-South Main Line (Middle)”.
- Simulate each traffic flow scenario scenario for a duration of 600 seconds, for a total of 3600 seconds. Due to the randomness of traffic simulation, the time of vehicle generation is different.
- Table 3 and Table 4 summarize the estimation results of the four sets of permeability for the validation set under two typical estimation intervals (ie, 1s and 20s).
- the TSE framework proposed by the present invention can provide a feasible solution for the location information of networked vehicles when the estimation interval is small (such as 1 s) and the penetration rate is low.
- the estimation interval will increase, which will lead to a decrease in the effectiveness of the estimation model.
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- 一种基于非参数贝叶斯框架的信号交叉口状态估计方法,其步骤如下:(1)数据采集:获取交叉口历史交通数据和对应信号控制参数,向量化处理,分别建立状态数据集和控制数据集;(2)建立非参数贝叶斯框架:结合递归状态估计和高斯过程回归模型,利用所述状态数据集和控制数据集训练并优化转移模型和测量模型;(3)交叉口状态估计:采用扩展的卡尔曼滤波器来线性化所述转移模型和所述测量模型,再将上一时刻的交通状态、信号控制参数输入至转移模型得到预测状态及其协方差,然后将得到的预测状态及其协方差、当前时刻的测量值输入到测量模型,预测当前时刻状态的最优估计值。
- 根据权利要求1所述的一种基于非参数贝叶斯框架的信号交叉口状态估计方法,其特征在于:还包括步骤(4)状态估计方法验证:引入车联网数据,计算不同估计间隔和联网车辆渗透率下交叉口状态估计精度。
- 根据权利要求3所述的一种基于非参数贝叶斯框架的信号交叉口状态估计方法,其特征在于:基于递归状态估计,所述转移模型表示为:x t=g(x t-1,u t-1)+ε其中g(·)表示t-1时刻状态-控制对(x t-1,u t-1)与t时刻状态x t之间的一个映射,ε服从协方差矩阵为Σ tran、均值为零的白高斯分布过程;状态转移概率如下式所示:P(x t|x t-1,u t-1)=N(g(x t-1,u t-1),Σ tran)所述测量模型表示为:z t=h(x t)+ζ其中h(·)表示t时刻状态x t与测量值z t之间的映射,ζ服从协方差矩阵为Σ meas、均值为零的白高斯分布过程;测量概率如下式所示:P(z t|x t)=N(h(x t),Σ meas)其中,Σ meas代表测量模型的协方差矩阵。
- 根据权利要求4所述的一种基于非参数贝叶斯框架的信号交叉口状态估计方法,其特征在于:结合高斯过程回归模型,状态、控制、测量向量的元素个数分别由M x,M u,M z表示,且三者数据点规模相同,则转移模型和测量模型的训练数据集分别表示为:D tran=<X tran,Y tran>D meas=<X meas,Y meas>其中X tran,Y tran是转移模型输入输出的数据点,X meas,Y meas是测量模型的输入输出数据点;对于t时刻状态向量中的任一个元素x p,t(p=1,2,…,M x),状态向量x t的分布如下:测量变量z t的分布如下:
- 根据权利要求5所述的一种基于非参数贝叶斯框架的信号交叉口状态估计方法,其特征在于:所述转移模型和测量模型的线性化,具体为采用扩展的卡尔曼滤波器,使用一级泰勒展开式构建函数值,斜率来对函数进行线性近似。
- 根据权利要求6所述的一种基于非参数贝叶斯框架的信号交叉口状态估计方法,其特征在于:所述预测当前时刻状态的最优估计值还包括:使用被预测状态和协方差矩阵计算卡尔曼增益,根据测量值的正确性程度将被预测的状态加入到新的状态估计中,计算最优的状态,所述正确性程度与卡尔曼增益成正比,与当前测量值和预测测量值之间的偏差成正比。
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