Time warped continuous speech signal matching using Kalman filter

Khan, Wasiq, Holton, Robert

January 2015

No / Dynamic speech properties, such as time warping, silence removal and background noise reduction are the most challenging issues in continuous speech signal matching. Among all of them, the time warped speech signal matching is of great interest and has been a tough challenge for the researchers. The literature contains a variety of techniques to measure the similarity between speech utterances, however there are some limitations associated with these techniques. This paper introduces an adaptive framing based continuous speech tracking and similarity measurement approach that uses a Kalman filter (KF) as a robust tracker. The use of KF is novel for time warped speech signal matching and dynamic time warping. A dynamic state model is presented based on equations of linear motion. In this model, fixed length frame of input (test) speech signal is considered as a unidirectional moving object by sliding it along the template speech signal. The best matched position estimate in template speech (sample number) for corresponding test frame at current time is calculated. Simultaneously, another position observation is produced by a feature based distance metric. The position estimated by the state model is fused with the observation using KF along with the noise variances. The best estimated frame position in the template speech for the current state is calculated. Finally, forecasting of the noise variances and template frame size for next state are made according to the KF output. The experimental results demonstrate the robustness of the proposed technique in terms of time warped speech signal matching as well as in computation cost.

Nonlinear State Estimation in Polymer Electrolyte Membrane Fuel Cells

Tumuluri, Uma

January 2008

No description available.

FUEL CELLS

sequential Monte Carlo

unscented Kalman filter

Sensing and Control of MEMS Accelerometers Using Kalman Filter

Zhang, Kai

January 2010

No description available.

ACCELEROMETERS

KALMAN FILTER

KALMAN

MEMS ACCELEROMETERS

EKF

closed-loop

noise

Kalman Filter Aided Tracking Loop In GPS Signal Spoofing Detection

Chen, Hao

January 2014

No description available.

Electrical Engineering

GPS Spoofing

Kalman Filter

Test Function

ENHANCEMENT AND BIAS COMPENSATION IN THE EXTENDED KALMAN OBSERVER AS A PARAMETER ESTIMATOR

MEHROTRA, SUMIT

11 October 2001

No description available.

Engineering, Aerospace

extended Kalman filter

parameter estimation

bias compensation

A Low-Cost Acoustic Array for Detecting and Tracking Multiple Acoustic Targets

Case, Ellen E.

January 2008

No description available.

Electrical Engineering

acoustic array

CA-CFAR detection

Kalman filter

tracking

Traffic Surveillance Using Low Cost Continuous Wave (CW) Doppler Radars

Yang, Wu

12 September 2012

No description available.

Electrical Engineering

CW Doppler Radar

Traffic Surveillance

Kalman Filter

Spectrogram

Improving Tissue Elasticity Imaging Using A KALMAN Filter-Based Non-Rigid Motion Tracking Algorithm

Vadde, Susheel Reddy

26 July 2011

No description available.

Computer Science

Information Systems

Kalman Filter

Elastography

Multi Frame Motion

Assessing Kalman filter in the identification of synchronous machine stability parameters

Borrero, Antonio J.

January 1983

No description available.

Kalman Filter

Synchronous Machine Stability Parameters

Synchronous Machine Equations

ADVANCING SEQUENTIAL DATA ASSIMILATION METHODS FOR ENHANCED HYDROLOGIC FORECASTING IN SEMI-URBAN WATERSHEDS

Leach, James

January 2019

Accurate hydrologic forecasting is vital for proper water resource management. Practices that are impacted by these forecasts include power generation, reservoir management, agricultural water use, and flood early warning systems. Despite these needs, the models largely used are simplifications of the real world and are therefore imperfect. The forecasters face other challenges in addition to the model uncertainty, which includes imperfect observations used for model calibration and validation, imperfect meteorological forecasts, and the ability to effectively communicate forecast results to decision-makers. Bayesian methods are commonly used to address some of these issues, and this thesis will be focused on improving methods related to recursive Bayesian estimation, more commonly known as data assimilation. Data assimilation is a means to optimally account for the uncertainties in observations, models, and forcing data. In the literature, data assimilation for urban hydrologic and flood forecasting is rare; therefore the main areas of study in this thesis are urban and semi-urban watersheds. By providing improvements to data assimilation methods, both hydrologic and flood forecasting can be enhanced in these areas. This work explored the use of alternative data products as a type of observation that can be assimilated to improve hydrologic forecasting in an urban watershed. The impact of impervious surfaces in urban and semi-urban watersheds was also evaluated in regards to its impact on remotely sensed soil moisture assimilation. Lack of observations is another issue when it comes to data assimilation, particularly in semi- or fully-distributed models; because of this, an improved method for updating locations which do not have observations was developed which utilizes information theory’s mutual information. Finally, we explored extending data assimilation into the short-term forecast by using prior knowledge of how a model will respond to forecasted forcing data. Results from this work found that using alternative data products such as those from the Snow Data Assimilation System or the Soil Moisture and Ocean Salinity mission, can be effective at improving hydrologic forecasting in urban watersheds. They also were effective at identifying a limiting imperviousness threshold for soil moisture assimilation into urban and semi-urban watersheds. Additionally, the inclusion of mutual information between gauged and ungauged locations in a semi-distributed hydrologic model was able to provide better state updates in models. Finally, by extending data assimilation into the short-term forecast, the reliability of the forecasts could be improved substantially. / Dissertation / Doctor of Philosophy (PhD) / The ability to accurately model hydrological systems is essential, as that allows for better planning and decision making in water resources management. The better we can forecast the hydrologic response to rain and snowmelt events, the better we can plan and manage our water resources. This includes better planning and usage of water for agricultural purposes, better planning and management of reservoirs for power generation, and better preparing for flood events. Unfortunately, hydrologic models primarily used are simplifications of the real world and are therefore imperfect. Additionally, our measurements of the physical system responses to atmospheric forcing can be prone to both systematic and random errors that need to be accounted for. To address these limitations, data assimilation can be used to improve hydrologic forecasts by optimally accounting for both model and observation uncertainties. The work in this thesis helps to further advance and improve data assimilation, with a focus on enhancing hydrologic forecasting in urban and semi-urban watersheds. The research presented herein can be used to provide better forecasts, which allow for better planning and decision making.

Data Assimilation

Ensemble Forecasting

Ensemble Kalman FIlter

Particle Filter

Streamflow