Comparison and combination of EAKF and SIR-PF in the Bayesian filter framework

Bayesian estimation theory provides a general approach for the state estimate of linear or nonlinear and Gaussian or non-Gaussian systems. In this study, we first explore two Bayesian-based methods： ensemble adjustment Kalman filter（EAKF） and sequential importance resampling particle filter（SIR-PF）, using a well-known nonlinear and non-Gaussian model（Lorenz ＇63 model）. The EAKF, which is a deterministic scheme of the ensemble Kalman filter（En KF）, performs better than the classical（stochastic） En KF in a general framework. Comparison between the SIR-PF and the EAKF reveals that the former outperforms the latter if ensemble size is so large that can avoid the filter degeneracy, and vice versa. The impact of the probability density functions and effective ensemble sizes on assimilation performances are also explored. On the basis of comparisons between the SIR-PF and the EAKF, a mixture filter, called ensemble adjustment Kalman particle filter（EAKPF）, is proposed to combine their both merits. Similar to the ensemble Kalman particle filter, which combines the stochastic En KF and SIR-PF analysis schemes with a tuning parameter, the new mixture filter essentially provides a continuous interpolation between the EAKF and SIR-PF. The same Lorenz ＇63 model is used as a testbed, showing that the EAKPF is able to overcome filter degeneracy while maintaining the non-Gaussian nature, and performs better than the EAKF given limited ensemble size.

A Bayesian Filter for Sound Environment System with Quantized Observation*

In the real sound environment, the observation data are usually contaminated by additional background noise of arbitrary distribution type. In order to estimate several evaluation quantities for specific signal based on the observed noisy data, it is fundamental to estimate the fluctuating wave form of the specific signal. On the other hand, the observation data are very often measured in a digital level form at discrete times. This is because some signal processing methods by utilizing a digital computer are indispensable for extracting exactly various kinds of statistical evaluation for the specific signal based on the quantized level data. In this study, a Bayesian filter matched to the complicated sound environment system is derived. First, in the real situation where the sound environment system is affected by background noise of arbitrary probability distribution, a stochastic system model with quantized observation is established. Next, two types of the recursive algorithm of Bayesian filter to estimate the unknown specific signal are theoretically proposed in the quantized level form. Finally, the effectiveness of the proposed theory is experimentally confirmed by applying it to the estimation problem of real sound environment.

Smoother and Bayesian filter based semi-codeless tracking of dual-frequency GPS signals

To precisely determine the integrated orbit of the Chinese manned spacecraft mission, a smoother and Bayesian filter based technique for optimum semi-codeless tracking of the P（Y） code on dual-frequency GPS signals has been advanced. This signal processing technique has been proven effective and robust for affording access to dual-frequency GPS signals. This paper introduces the signal dynamics and measurement models, describes the W o D bit estimation method, and corrects the mistakes of direct estimation of W bit in current semi-codeless tracking. Median filter is chosen as a smoother to find the best measurements at the current time among the history and current information. The Bayesian filter is used to track the L2 P（Y） code phase and L2 carrier phase recursively.

Nonlinear Bayesian Estimation： From Kalman Filtering to a Broader Horizon

This article presents an up-to-date tutorial review of nonlinear Bayesian estimation. State estimation for nonlinear systems has been a challenge encountered in a wide range of engineering fields, attracting decades of research effort. To date,one of the most promising and popular approaches is to view and address the problem from a Bayesian probabilistic perspective,which enables estimation of the unknown state variables by tracking their probabilistic distribution or statistics(e.g., mean and covariance) conditioned on a system's measurement data.This article offers a systematic introduction to the Bayesian state estimation framework and reviews various Kalman filtering(KF)techniques, progressively from the standard KF for linear systems to extended KF, unscented KF and ensemble KF for nonlinear systems. It also overviews other prominent or emerging Bayesian estimation methods including Gaussian filtering, Gaussian-sum filtering, particle filtering and moving horizon estimation and extends the discussion of state estimation to more complicated problems such as simultaneous state and parameter/input estimation.

Modified unscented particle filter for nonlinear Bayesian tracking

A modified unscented particle filtering scheme for nonlinear tracking is proposed, in view of the potential drawbacks （such as, particle impoverishment and numerical sensitivity in calculating the prior） of the conventional unscented particle filter （UPF） confronted in practice. Specifically, a different derivation of the importance weight is presented in detail. The proposed method can avoid the calculation of the prior and reduce the effects of the impoverishment problem caused by sampling from the proposal distribution, Simulations have been performed using two illustrative examples and results have been provided to demonstrate the validity of the modified UPF as well as its improved performance over the conventional one.

可重构智能表面辅助通信系统时变级联信道估计

针对可重构智能表面(RIS)辅助通信系统时变级联信道的估计中需解决的级联信道稀疏表示、时变信道参数跟踪和信号重构等关键问题,提出了一种结合Khatri-Rao积的分层贝叶斯卡尔曼滤波(KR-HBKF)算法。该算法首先利用信道的稀疏特性,通过Khatri-Rao积和克罗内克积变换得到RIS级联信道的稀疏表示,将RIS级联信道估计问题转化为低维度的稀疏信号恢复问题。然后,根据RIS级联信道的状态演化模型,在HBKF算法的预测模型中引入了时间相关性参数,应用改进的HBKF解决时变信道参数跟踪和信号重构问题,完成时变级联信道的估计。KR-HBKF算法综合利用了信道的稀疏性和时间相关性,能以较小的导频开销获得更好的估计精度。仿真结果表明,与传统压缩感知算法相比,所提算法具有约5 dB的估计性能提升,且在不同的时变信道条件下具有更好的鲁棒性。

融合深度学习的贝叶斯滤波综述

当前动态系统呈现大型化、复杂化的趋势,基于贝叶斯滤波的动态系统状态估计遇到一系列新的挑战.随着深度学习在特征提取与模式识别等方面的优势与潜力不断显现,深度学习与传统贝叶斯滤波相结合的研究也随之兴起.为此,梳理了不同领域融合深度学习的贝叶斯滤波方法的应用案例,从中剖析不同类型动态系统下贝叶斯滤波存在的局限性和共性难题.在此基础上,总结了当前贝叶斯滤波存在的几类不确定性问题,以深度学习的视角将这些问题归纳为特征提取和参数辨识两大基本问题,进而介绍深度学习为贝叶斯滤波所提供的解决方案.其次,归纳整理了两类深度学习与贝叶斯滤波结合的具体方法,着重介绍了深度卡尔曼滤波和融合深度学习的自适应卡尔曼滤波.最后,综合考虑深度学习方法和贝叶斯滤波方法的优势,讨论了融合深度学习的贝叶斯滤波方法的开放问题和未来研究方向.

一种高斯-重尾切换分布鲁棒卡尔曼滤波器

为降低实际应用中由强未知干扰和仪器故障对观测造成的影响,减轻随机和未建模干扰对系统的侵蚀,从而提升系统在非高斯噪声环境下的状态估计精度,提高滤波器的鲁棒性能,提出了一种基于高斯-重尾切换分布的鲁棒卡尔曼滤波器(Gaussian-heavy-tailed switching distribution based robust Kalman filter,GHTSRKF)。首先,通过自适应学习高斯分布和一种重尾分布之间的切换概率将噪声建模为GHTS(Gaussian-heavy-tailed switching)分布,所设计的GHTS分布可以通过在线调整高斯分布和新的重尾分布之间的切换概率来对非平稳重尾噪声进行建模,具有虚拟协方差的高斯分布用于处理协方差矩阵不准确的高斯噪声。其次,引入两个分别服从Categorical分布与伯努利分布的辅助参数将GHTS分布表示为一个分层高斯形式,进一步利用变分贝叶斯方法推导了GHTSRKF。最后,利用一个仿真场景对几种不同的RKFs(robust Kalman filters)进行了对比验证。结果表明,所提出的GHTSRKF算法的估计精度对初始状态的选取不敏感,精度优于其他RKFs,它的RMSEs最接近噪声信息准确的KFTNC(KF with true noise covariances)的RMSEs(root mean square errors),且当系统与量测噪声是未知时变高斯噪声时,相比于现有的滤波器,GHTSRKF具有更好的估计性能,从而验证了GHTSRKF的有效性。

基于稀疏贝叶斯学习的GFDM系统联合迭代信道估计与符号检测

针对当前广义频分复用(Generalized Frequency Division Multiplexing,GFDM)系统时变信道估计精度低的问题,提出基于稀疏贝叶斯学习的GFDM系统联合信道估计与符号检测算法.具体地,采用无干扰导频插入的GFDM多重响应信号模型,在稀疏贝叶斯学习框架下,结合期望最大化算法(Expectation-Maximization,EM)和卡尔曼滤波与平滑算法实现块时变信道的最大似然估计;基于信道状态信息的估计值进行GFDM符号检测,并通过信道估计与符号检测的迭代处理逐步提高信道估计与符号检测的精度.仿真结果表明,所提算法能够获得接近完美信道状态信息条件下的误码率性能,且具有收敛速度快、对多普勒频移鲁棒性高等优点.

误差状态卡尔曼滤波的视觉惯性自适应融合定位方法研究

头盔瞄准具(HMS)是近年来新一代战斗机飞行员的辅助瞄准设备,能够帮助飞行员增强战场态势感知能力,对敌方目标进行快速、精准打击。其能正常工作的关键是获取飞行员头部相对于运动飞机的姿态参数。本文结合头盔瞄准具这一应用场景研究了视觉组合姿态测量关键技术。视觉惯性组合定位能够实现目标位姿测量方法的优势互补,而由于标称噪声矩阵无法绝对准确预测,融合算法的鲁棒性、精度有待进一步提升。针对这一问题,本文提出一种误差状态卡尔曼滤波框架下基于变分贝叶斯推断的视觉惯性自适应融合方法。首先,对于过程噪声使用逆威沙特(Wishart)分布进行建模,之后通过引入隐变量分解一步预测协方差,并结合变分贝叶斯推断实现了对过程噪声协方差矩阵的在线估计。试验证明,在复杂运动及标称噪声协方差矩阵偏移较大的测量条件下,所提位姿测量算法具有较高的精度与鲁棒性,能够完成对靶标的快速、高精度跟踪。

基于Naive Bayesian算法的客户端邮件过滤器的实现

“垃圾”邮件是Internet上面临急待解决的问题。Naive Bayesian过滤器由于其简单高效性在文本分类中应用较广,重点研究了Naive Bayesian算法,给出了一个“垃圾”邮件过滤器,依据邮件的内容而不是通过设置规则来过滤邮件,并通过实验论证了它在客户端过滤邮件的可行性和有效性。

基于贝叶斯滤波理论的目标命中概率估计与判决方法研究

为了降低兵器试验中目标命中概率指标的判决错误率,提出了基于贝叶斯滤波理论的目标命中概率估计和判决方法。该方法构建了目标命中概率与试验观测数据的统计数学模型,依据贝叶斯滤波理论推导了目标命中概率后验概率密度函数、后验均值估计以及均方误差的解析表达式,并给出了基于目标命中概率后验均值估计的判决方法。依据不同的真实目标命中概率生成观测数据,分别利用传统方法和所提方法进行了估计和判决试验。结果表明:所提方法判决错误率仅为传统方法的1/3,证明所提方法具有可行性。

免微分非线性Bayesian滤波方法评述

以非线性递推Bayesian滤波问题的求解及其历史渊源为起点,分两类对各种免微分非线性Bayesian滤波方法或免微分方法的原理和算法进行了评述:一类是以线性最小均方误差最优估计子为特点的免微分高斯滤波,包括无味卡尔曼滤波、均差滤波器、中心差分滤波器和Gauss-Hermite滤波器或积分卡尔曼滤波器;另一类是后验密度数值逼近免微分方法,包括栅格法(GBMs)与近似栅格法、矩近似法和以粒子滤波为代表的Monte Carlo方法。其中还包括了作者的一些最新研究成果,如迭代UKF算法、裂变自举PF算法和关于粒子滤波算法有限收敛界的概念等。之后从加权统计线性回归的角度对两类免微分方法进行了统一认识,统一为以数值方法为特点的广义PF。为了建立一个关于各种免微分算法性能的整体印象,论文还通过一个复杂的递推非线性滤波估计例子,用MonteCarlo仿真实验的方法对7种典型的免微分方法和和传统的EKF算法进行了比较研究。最后对两类免微分方法进行了简单的比较,并指出了进一步研究的方向。

基于有监督Bayesian网络的垃圾邮件过滤

对影响邮件特性的邮件报文格式作了仔细的分析并对垃圾邮件的特征进行了分类归纳,在此基础上构建了一个有监督的Bayesian邮件分类网络。通过对该网络作Bayesian参数估计,实现了判定邮件类别的不确定推理。对不同邮件测试集的在线学习试验结果表明,有监督Bayesian邮件分类网络能够有效地实现垃圾邮件的相对完备特征学习,改善邮件过滤的准确率。

基于循环维纳滤波器的声学成像优化方法

针对混响环境中背景噪声干扰导致循环平稳源重建精度不高的问题,基于循环维纳滤波器,结合贝叶斯近场声全息技术,提出了一种声学成像优化方法。通过麦克风阵列在声源的近场测量由声源辐射信号的声压,利用循环维纳滤波器对测量值进行去噪,从而实现对循环平稳信号的盲提取,再应用贝叶斯近场声全息技术在空间上重建循环平稳源。首先,通过仿真分析,系统地评估了盲信号提取算法的有效性。然后,通过开展声源重建实验,进一步验证了该声学成像优化方法的可行性。

复杂多径下IR-UWB自适应频偏估计算法研究

在脉冲超宽带定位系统中,时钟频率偏移是影响测距和测角精度的重要因素;针对复杂多径下频偏估计精度低的问题,设计了一种适应复杂多径环境的脉冲超宽带自适应频偏估计算法;首先,借助脉冲超宽带信号的抗多径优势,将实时估计的信道脉冲响应作为自适应匹配滤波模板,以保证复杂多径下相关峰的准确提取;利用相关峰辐角信息得到前导符号的相位序列;再使用贝叶斯估计算法提高频偏估计精度;在IEEE 802.15.4a标准CM1、CM2多径信道下进行仿真,仿真结果表明,低信噪比情况下,频偏估计精度保证在0.2 ppm以内;在巷道环境实验结果表明,50 m范围内频偏估计标准差在0.06 ppm以内;实现了复杂多径环境下高精度频偏估计,具有较强的实用性。

GNSS/SINS组合导航系统的改进变分贝叶斯自适应滤波算法

针对系统噪声及测量噪声统计量不准确的组合导航系统线性高斯状态模型,提出一种组合导航系统的改进变分贝叶斯自适应滤波算法(modified variational Bayesian adaptive filter,MVBAKF)。首先,选择Wishart分布作为已知均值的高斯分布协方差矩阵的共轭先验,并给出测量噪声方差、状态向量及其预测误差协方差矩阵的联合概率分布函数;然后,利用变分贝叶斯方法给出测量噪声方差及状态向量预测误差协方差矩阵的计算公式,进而提出具有迭代性质的MVBAKF算法;最后,进行基于MVBAKF算法的GNSS/SINS组合导航系统仿真实验。结果表明,相对于传统VBAKF算法,MVBAKF算法可较准确地估计测量噪声方差,有效克服系统噪声统计量不准确对滤波精度的影响,进而提高组合导航系统的滤波精度。

交通弱势出行者轨迹预测及安全管控策略

针对骑车人在交通事故中易受伤害的问题,提出一种基于骑车人意图识别的轨迹预测方法.首先,从骑车人角度及车辆角度提取骑车人的多元特征,如运动方向、回头概率、与车辆相对位置等,在十字路口场景下构建动态贝叶斯模型网络,分析了骑车人意图的影响因素,最终得到骑车人意图后验概率.其次,根据意图识别结果,构建了相关交通场景并给出了骑车人运动方程,通过基于粒子滤波方法的骑车人轨迹预测算法,结合运动方程及观测方程,以粒子模拟骑车人未来轨迹集.最后,搭建激光雷达和单目相机为主的数据采集硬件平台,获取与骑车人运动及姿态有关的信息,根据收集的7 358帧数据,计算出骑车人进入十字路口区域的时长,用以对算法进行评价.结果表明:本算法在骑车人过街前0.24~0.54 s可基本识别骑车人的意图,能够预测骑车人未来5.0 s内的轨迹集;算法具有较好的实用性,可以降低骑车人与车辆碰撞事故的发生概率.

基于贝叶斯方法的发电机生命周期预测方法

为了对关键元件进行生命周期预测,提出了一种两阶段数据驱动的生命周期预测方法。在离线阶段,使用无监督变量选择方法寻找包含退化行为信息的变量,在此基础上,从所选变量中构建不同的健康指标,这些变量将退化状态表示为时间的函数,并作为参考模型保存在离线数据库中。在在线阶段,该方法将k近邻(k-NN)分类器作为剩余使用寿命预测器,找到与在线健康指标最相似的离线健康指标,使用离散贝叶斯滤波器来估计退化状态。利用发电厂发电机退化仿真数据对该方法进行了验证,结果表明,该方法能有效地预测发电机的剩余使用寿命,进而得到其生命周期。

基于粒子流滤波的视觉定位算法

针对基于粒子滤波的视觉定位算法存在的粒子需求量大以及重采样中粒子贫化而导致的计算量大、定位精度差等问题,提出了一种采用粒子流滤波进行优化的视觉定位算法。该算法通过一个微分方程进行粒子的移动,利用粒子流完成随机样本集从先验分布到后验分布的更新,进而避免了“粒子退化”现象,最后利用参量近似法来求解粒子流滤波,实验结果证明,该算法减少了算法计算量和运行时间,提高了系统的精度。