2: Part One- Least Squares

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Welcome to the foundation of it all.

This first part of the book is dedicated to the Classical Linear Model, the workhorse of statistical analysis and the cornerstone from which countless other techniques are derived. You may know it simply as linear regression. Our journey begins here because understanding this model — truly understanding its mechanics, its logic, and its soul — is essential for everything that follows.

We will first build the model from the ground up, deriving the Ordinary Least Squares (OLS) solution with the familiar tools of scalar algebra. This approach provides an intuitive, tangible feel for how the model finds the "best-fitting" line by minimizing error. Then, we will ascend to a more powerful perspective: the matrix derivation. This framework is not merely a mathematical formality; it is the key that unlocks the analysis of complex, multi-dimensional data and paves the way for modern statistical computing. Once the mathematics are out of the way, we introduce probability distributions so we can explore confidence intervals and hypothesis testing.

Crucially, we will also put the model's famous assumptions under the microscope. We will explore the core requirements — linearity, independence, constant variance, and normality — asking not just what they are, but how crucial each one truly is to a valid analysis. You will learn which assumptions are deal-breakers, which are flexible, and how to diagnose and address problems when they arise.

By the end of this part, you will possess a deep and operational knowledge of OLS regression. You will be able to derive it, fit it using R, interpret its results, and critically assess its validity. The examples from Ruritania will guide our way, transforming abstract equations into meaningful stories about relationships in the world. Let us begin.

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