Recent advances in sensor technology and information processing afford a new flexibility in the design of waveforms for agile sensing. Sensors are now developed with the ability to dynamically choose their transmit or receive waveforms in order to optimize an objective cost function. This has exposed a new paradigm of significant performance improvements in active sensing: dynamic waveform adaptation to environment conditions, target structures, or information features. The manuscript provides a review of recent advances in waveform-agile sensing for target tracking applications. A dynamic waveform selection and configuration scheme is developed for two active sensors that track one or multiple mobile targets. A detailed description of two sequential Monte Carlo algorithms for agile tracking are presented, together with relevant Matlab code and simulation studies, to demonstrate the benefits of dynamic waveform adaptation. The work will be of interest not only to practitioners of radar and sonar, but also other applications where waveforms can be dynamically designed, such as communications and biosensing. Table of Contents: Waveform-Agile Target Tracking Application Formulation / Dynamic Waveform Selection with Application to Narrowband and Wideband Environments / Dynamic Waveform Selection for Tracking in Clutter / Conclusions / CRLB Evaluation for Gaussian Envelope GFM Chirp from the Ambiguity Function / CRLB Evaluation from the Complex Envelope
Recent advances in sensor technology and information processing afford a new flexibility in the design of waveforms for agile sensing. Sensors are now developed with the ability to dynamically choose their transmit or receive waveforms in order to optimize an objective cost function. This has exposed a new paradigm of significant performance improvements in active sensing: dynamic waveform adaptation to environment conditions, target structures, or information features. The manuscript provides a review of recent advances in waveform-agile sensing for target tracking applications. A dynamic waveform selection and configuration scheme is developed for two active sensors that track one or multiple mobile targets. A detailed description of two sequential Monte Carlo algorithms for agile tracking are presented, together with relevant Matlab code and simulation studies, to demonstrate the benefits of dynamic waveform adaptation. The work will be of interest not only to practitioners of radar and sonar, but also other applications where waveforms can be dynamically designed, such as communications and biosensing. Table of Contents: Waveform-Agile Target Tracking Application Formulation / Dynamic Waveform Selection with Application to Narrowband and Wideband Environments / Dynamic Waveform Selection for Tracking in Clutter / Conclusions / CRLB Evaluation for Gaussian Envelope GFM Chirp from the Ambiguity Function / CRLB Evaluation from the Complex Envelope
Recent innovations in modern radar for designing transmitted waveforms, coupled with new algorithms for adaptively selecting the waveform parameters at each time step, have resulted in improvements in tracking performance. Of particular interest are waveforms that can be mathematically designed to have reduced ambiguity function sidelobes, as their use can lead to an increase in the target state estimation accuracy. Moreover, adaptively positioning the sidelobes can reveal weak target returns by reducing interference from stronger targets. The manuscript provides an overview of recent advances in the design of multicarrier phase-coded waveforms based on Bjorck constant-amplitude zero-autocorrelation (CAZAC) sequences for use in an adaptive waveform selection scheme for mutliple target tracking. The adaptive waveform design is formulated using sequential Monte Carlo techniques that need to be matched to the high resolution measurements. The work will be of interest to both practitioners and researchers in radar as well as to researchers in other applications where high resolution measurements can have significant benefits. Table of Contents: Introduction / Radar Waveform Design / Target Tracking with a Particle Filter / Single Target tracking with LFM and CAZAC Sequences / Multiple Target Tracking / Conclusions
Recent innovations in modern radar for designing transmitted waveforms, coupled with new algorithms for adaptively selecting the waveform parameters at each time step, have resulted in improvements in tracking performance. Of particular interest are waveforms that can be mathematically designed to have reduced ambiguity function sidelobes, as their use can lead to an increase in the target state estimation accuracy. Moreover, adaptively positioning the sidelobes can reveal weak target returns by reducing interference from stronger targets. The manuscript provides an overview of recent advances in the design of multicarrier phase-coded waveforms based on Bjorck constant-amplitude zero-autocorrelation (CAZAC) sequences for use in an adaptive waveform selection scheme for mutliple target tracking. The adaptive waveform design is formulated using sequential Monte Carlo techniques that need to be matched to the high resolution measurements. The work will be of interest to both practitioners and researchers in radar as well as to researchers in other applications where high resolution measurements can have significant benefits. Table of Contents: Introduction / Radar Waveform Design / Target Tracking with a Particle Filter / Single Target tracking with LFM and CAZAC Sequences / Multiple Target Tracking / Conclusions
Recent advances in sensor technology and information processing afford a new flexibility in the design of waveforms for agile sensing. Sensors are now developed with the ability to dynamically choose their transmit or receive waveforms in order to optimize an objective cost function. This has exposed a new paradigm of significant performance improvements in active sensing: dynamic waveform adaptation to environment conditions, target structures, or information features. The manuscript provides a review of recent advances in waveform-agile sensing for target tracking applications. A dynamic waveform selection and configuration scheme is developed for two active sensors that track one or multiple mobile targets. A detailed description of two sequential Monte Carlo algorithms for agile tracking are presented, together with relevant Matlab code and simulation studies, to demonstrate the benefits of dynamic waveform adaptation. The work will be of interest not only to practitioners of radar and sonar, but also other applications where waveforms can be dynamically designed, such as communications and biosensing. Table of Contents: Waveform-Agile Target Tracking Application Formulation / Dynamic Waveform Selection with Application to Narrowband and Wideband Environments / Dynamic Waveform Selection for Tracking in Clutter / Conclusions / CRLB Evaluation for Gaussian Envelope GFM Chirp from the Ambiguity Function / CRLB Evaluation from the Complex Envelope
Core Statistical Concepts with Excel® connects statistical concepts to applications with Excel® using practical research examples. The text jointly promotes an understanding of Excel® and a deeper knowledge of core concepts through practice. Authors Gregory J. Privitera and Darryl Mayeaux provide students step-by-step instruction for using Excel® software as a useful tool not only to manage but also analyze data—all through the use of key themes, features, and pedagogy: an emphasis on student learning, a focus on current research, and integration of Excel® to introduce statistical concepts.
This title presents a flexible valuation and decision-making tool for financial planners, airlines, lease companies, bankers, insurance companies, and aircraft manufacturers.
Science is allegedly in the midst of a reproducibility crisis, but questions of reproducibility and related principles date back nearly 80 years. Numerous controversies have arisen, especially since 2010, in a wide array of disciplines that stem from the failure to reproduce studies or their findings:biology, biomedical and preclinical research, business and organizational studies, computational sciences, drug discovery, economics, education, epidemiology and statistics, genetics, immunology, policy research, political science, psychology, and sociology. This monograph defines terms and constructs related to reproducible research, weighs key considerations and challenges in reproducing or replicating studies, and discusses transparency in publications that can support reproducible research goals. It attempts to clarify reproducible research, with its attendant (and confusing or even conflicting) lexicon and aims to provide useful background, definitions, and practical guidance for all readers. Among its conclusions: First, researchers must become better educated about these issues, particularly the differences between the concepts and terms. The main benefit is being able to communicate clearly within their own fields and, more importantly, across multiple disciplines. In addition, scientists need to embrace these concepts as part of their responsibilities as good stewards of research funding and as providers of credible information for policy decision making across many areas of public concern. Finally, although focusing on transparency and documentation is essential, ultimately the goal is achieving the most rigorous, high-quality science possible given limitations on time, funding, or other resources. “The authors have written a nuanced and thoughtful primer on scientific reproducibility. By highlighting the social, political, and technical importance of reproducibility, together with a precise description of the related concepts of reproducibility, replicability, and repeatability, this primer provides a significant resource that all practicing researchers should read.” Daniel Reed, Vice President for Research and Economic Development, University of Iowa and former Corporate Vice President, Microsoft “This is a well-written, clearly articulated, and timely primer on the developing and evolving rich terminology of reproducible research. The primer, put together by authors with deep experience and expertise in the topic area, focuses primarily on human-centric research in biomedicine, medicine, and the social sciences as well as reproducibility issues in analytics and computational science. The growing focus on reproducibility will open new vistas in research methodologies, meta analysis, comparative studies of research results, and reuse and adaptation of results from prior research. This primer provides an excellent overview of the subject area, and I would recommend it to anyone interested in coming up to speed on current issues in reproducible research.” Chaitan Baru, Distinguished Scientist and Associate Director for Data Initiatives, San Diego Supercomputing Center; current appointment as Senior Advisor for Data Science, Computer and Information Science and Engineering Directorate, National Science Foundation “Pellizzari et al. have taken on the Herculean task of collecting, synthesizing, and relating the various interpretations of reproducibility used in the research community today, and turned the result into an accessible must-read guide. This important work provides a Rosetta Stone for various stakeholders to discuss and implement solutions that make real progress toward a research enterprise that routinely produces reproducible findings.” Victoria Stodden, Associate Professor at the School of Information Sciences, University of Illinois at Urbana Champaign and co-editor of the books Implementing Reproducible Research and Privacy, Big Data, and the Public Good: Frameworks for Engagement
A full-color case-based guide to the principles and clinical aspects of geriatric care Case-Based Geriatrics utilizes a case-and-evidence-based approach to help you understand the key principles and clinical points of geriatric medicine and healthcare. Written to reflect the field’s growing trend toward interdisciplinary collaboration, the book is of value not only to physicians, but to the entire health team involved in the care of the elderly. This unique text is constructed around case presentations, which are used as the primary teaching tool. These cases reflect issues and principles of geriatrics that are encountered and practiced worldwide. You will learn how cultural characteristics of both patients and providers have added new layers of complications to this already challenging field – and how they can be recognized and overcome. Each case is directly linked to the learning objectives found in each chapter. Review questions appear at the beginning and end of each chapter to test your understanding. Case-Based Geriatrics is divided into three sections: Issues in Aging -- features foundational chapters covering essential topics such as biology of aging, worldwide demographics, the geriatric physical exam, sensory changes in aging, and approaches to laboratory testing and imaging in aging Inter-professional Geriatrics -- provides an overview of multi-professional team care and covers important topics such as pre -and-post operative care, discharge planning and transitional care, end-of-life care, home care, and long-term care Geriatric Syndromes and Important Issues -- covers common disorders such as delirium, dementia, depression, stroke, hypertension, osteoporosis, and more
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