Sensor systems that acquire large sets of data have been deployed to document sporting events at unprecedented levels of detail. Machine learning techniques have been applied to these sensor measurements to discover new skills, quantify known skills with greater accuracy, and understand biomechanical principles to improve performance and prevent injury. The use of learning methods to support the generation of predictive models has revolutionized decision making as teams search for an advantage in a highly competitive industry. Machine learning methods are particularly well suited for baseball due to the discrete structure of the sport.

We develop and apply learning methods to large sets of sensor data to address several of the most important and challenging problems in baseball analytics. We introduce a method for learning a function over distributions that generalizes nonparametric kernel regression by using the Wasserstein metric for distribution space. The technique is applied to the problem of learning the dependence of pitcher performance on multidimensional pitch distributions that are derived from sensor measurements which capture physical properties of each pitch. We also develop a method for estimation and prediction called measurement space partitioning. The method is applied to the problem of estimating batted-ball talent by using large sets of trajectory measurements acquired by in-game sensors to show that the predictive value of a batted ball depends on its physical properties. This knowledge is exploited to estimate batted-ball distributions defined over a multidimensional measurement space by using regression parameters that adapt to batted ball properties. This process is central to a new method for quantifying batted-ball skill. We present examples illustrating facets of the approach and use a set of experiments to show that the new methods generate predictions that are significantly more accurate than those generated using current methods.

Among all cardiac arrhythmia diseases, atrial fibrillation (AF) is the most prevalent and is associated with a chaotic and fast heartbeat, which often increases the risk of cardioembolic stroke and other heart-related problems, including myocardial infarction and progressive heart failure. Thus, it is important to diagnose AF in patients in the early stages and to have them receive proper treatment before the condition worsens. Surface electrocardiogram (ECG), implantable cardiac monitor (ICM), and Holter monitor analyses by doctors are the standard methods to diagnose AF in clinics. However, such analyses/diagnoses are time-consuming and sometimes difficult to interpret due to noise or data contamination. In this thesis, a new AF detection algorithm is proposed and evaluated using four available databases. Before discussing the new algorithms developed in this thesis, a basic introduction of the heart and its arrhythmia are reviewed in Chapter 1. An overview of existing AF detection methods and algorithms used in clinical and academic research is provided in Chapters 2 and 3. Chapter 4 is dedicated to exploring the real-life factors that impact AF detection. The new QRS template-based AF detection method is introduced and discussed in Chapter 5 through 7. It is shown that the new AF detection algorithm improves detection accuracy over standard methods in Chapter 8.

We evaluate a model for pitch sequencing in baseball that is defined by pitch-to-pitch correlation in location, velocity, and movement. The correlations quantify the average similarity of consecutive pitches and provide a measure of the batter's ability to predict the properties of the upcoming pitch. We examine the characteristics of the model for a set of major league pitchers using PITCHf/x data for nearly three million pitches thrown over seven major league seasons. After partitioning the data according to batter handedness, we show that a pitcher's correlations for velocity and movement are persistent from year-to-year. We also show that pitch-to-pitch correlations are significant in a model for pitcher strikeout rate and that a higher correlation, other factors being equal, is predictive of fewer strikeouts. This finding is consistent with experiments showing that swing errors by experienced batters tend to increase as the differences between the properties of consecutive pitches increase. We provide examples that demonstrate the role of pitch-to-pitch correlation in the strikeout rate model.