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Statistical Analysis with R Essentials For Dummies (eBook)

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2024 | 1. Auflage
192 Seiten
For Dummies (Verlag)
978-1-394-26343-1 (ISBN)

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Statistical Analysis with R Essentials For Dummies -  Joseph Schmuller
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The easy way to get started coding and analyzing data in the R programming language

Statistical Analysis with R Essentials For Dummies is your reference to all the core concepts about R-the widely used, open-source programming language and data analysis tool. This no-nonsense book gets right to the point, eliminating review material, wordy explanations, and fluff. Understand all you need to know about the foundations of R, swiftly and clearly. Perfect for a brush-up on the basics or as an everyday desk reference on the job, this is the reliable little book you can always turn to for answers.

  • Get a quick and thorough intro to the basic concepts of coding for data analysis in R
  • Review what you've already learned or pick up essential new skills
  • Perform statistical analysis for school, business, and beyond with R programming
  • Keep this concise reference book handy for jogging your memory as you work

This book is to the point, focusing on the key topics readers need to know about this popular programming language. Great for supplementing classroom learning, reviewing for a certification, or staying knowledgeable on the job.

Joseph Schmuller, PhD, is a cognitive scientist and statistical analyst. He creates online learning tools and writes books on the technology of data science. His books include R All-in-One For Dummies and R Projects For Dummies.

Joseph Schmuller, PhD, is a cognitive scientist and statistical analyst. He creates online learning tools and writes books on the technology of data science. His books include R All-in-One For Dummies and R Projects For Dummies.

Chapter 1

Data, Statistics, and Decisions


IN THIS CHAPTER

Introducing statistical concepts

Generalizing from samples to populations

Testing hypotheses

Looking at two types of errors

Statistics, first and foremost, is about decision-making. Statisticians look at data and wonder what the numbers are saying.

R helps you crunch the data and compute the numbers. As a bonus, R can also help you comprehend statistical concepts.

Developed specifically for statistical analysis, R is a computer language that implements many of the analytical tools statisticians have developed for decision-making. I wrote this book to show how to use these tools in your work.

The Statistical (and Related) Notions You Just Have to Know


The analytical tools that R provides are based on statistical concepts in the remainder of this chapter. These concepts are based on common sense.

Samples and populations


If you watch TV on election night, you know that one of the main events is the prediction of the outcome immediately after the polls close (and before all the votes are counted).

The idea is to talk to a sample of voters right after they vote. If they’re truthful about how they marked their ballots, and if the sample is representative of the population of voters, analysts can use the sample data to draw conclusions about the population.

That, in a nutshell, is what statistics is all about — using the data from samples to draw conclusions about populations.

Here’s another example. Imagine that your job is to find the average height of 10-year-old children in the United States. Because you probably wouldn’t have the time or the resources to measure every child, you’d measure the heights of a representative sample. Then you’d average those heights and use that average as the estimate of the population average.

Estimating the population average is one kind of inference that statisticians make from sample data. I discuss inference in more detail in the upcoming section “Inferential Statistics: Testing Hypotheses.”

Here’s some important terminology: Properties of a population (like the population average) are called parameters, and properties of a sample (like the sample average) are called statistics. If your only concern is the sample properties (like the heights of the children in your sample), the statistics you calculate are descriptive. If you’re concerned about estimating the population properties, your statistics are inferential.

Now for an important convention about notation: Statisticians use Greek letters (μ, σ, ρ) to stand for parameters, and English letters (, s, r) to stand for statistics. Figure 1-1 summarizes the relationship between populations and samples, and between parameters and statistics.

FIGURE 1-1: The relationship between populations, samples, parameters, and statistics.

Variables: Dependent and independent


A variable is something that can take on more than one value — like your age, the value of the dollar against another currency, or the number of games your favorite sports team wins. Something that can have only one value is a constant. Scientists tell us that the speed of light is a constant, and we use the constant π to calculate the area of a circle.

Statisticians work with independent variables and dependent variables. In any study or experiment, you’ll find both kinds. Statisticians assess the relationship between them.

A dependent variable is what a researcher measures. In an experiment, an independent variable is what a researcher manipulates. In some contexts, a researcher can’t manipulate an independent variable. Instead, he notes naturally occurring values of the independent variable and how they affect a dependent variable.

In general, the objective is to find out whether changes in a dependent variable are associated with changes in an independent variable.

In examples that appear throughout this book, I show you how to use R to calculate characteristics of groups of scores, or to compare groups of scores. Whenever I show you a group of scores, I'm talking about the values of a dependent variable.

Types of data


When you do statistical work, you can run into four kinds of data. And when you work with a variable, the way you work with it depends on what kind of data it is:

The first kind is nominal data. If a set of numbers happens to be nominal data, the numbers are labels — their values don’t signify anything.

The next kind is ordinal data. In this data-type, the numbers are more than just labels. The order of the numbers is important. If I ask you to rank ten foods from the one you like best (one), to the one you like least (ten), we’d have a set of ordinal data.

But the difference between your third-favorite food and your fourth-favorite food might not be the same as the difference between your ninth-favorite and your tenth-favorite. This type of data lacks equal intervals and equal differences.

The third kind of data, interval, gives us equal differences. The Fahrenheit scale of temperature is a good example. The difference between 30° and 40° is the same as the difference between 90° and 100°. Each degree is an interval.

On the Fahrenheit scale, a temperature of 80° is not twice as hot as 40°. For ratio statements (“twice as much as,” “half as much as”) to make sense, “zero” has to mean the complete absence of the thing you’re measuring. A temperature of 0°F doesn’t mean the complete absence of heat — it’s just an arbitrary point on the Fahrenheit scale. (The same holds true for Celsius.)

The fourth kind of data, ratio, provides a meaningful zero point. On the Kelvin Scale of temperature, zero means “absolute zero,” where all molecular motion (the basis of heat) stops. So 200° Kelvin is twice as hot as 100° Kelvin. Another example is length. Eight inches is twice as long as four inches. “Zero inches” means “a complete absence of length.”

An independent variable or a dependent variable can be either nominal, ordinal, interval, or ratio. The analytical tools you use depend on the type of data you work with.

A little probability


When statisticians make decisions, they use probability to express their confidence about those decisions. They can never be absolutely certain about what they decide. They can only tell you how probable their conclusions are.

What do we mean by probability? In my experience, the best way to understand probability is with examples.

If you toss a coin, what’s the probability that it turns up heads? If the coin is fair, you might figure that you have a 50-50 chance of heads and a 50-50 chance of tails. And you’d be right. In terms of the kinds of numbers associated with probability, that’s ½.

Think about rolling a fair die (one member of a pair of dice). What’s the probability that you roll a 4? Well, a die has six faces and one of them is 4, so that’s ⅙.

Still another example: Select one card at random from a standard deck of 52 cards. What’s the probability that it’s a diamond? A deck of cards has four suits, so that’s ¼.

In general, the formula for the probability that a particular event occurs is

At the beginning of this section, I say that statisticians express their confidence about their conclusions in terms of probability, which is why I brought all this up in the first place. This line of thinking leads to conditional probability — the probability that an event occurs given that some other event occurs. Suppose that I roll a die, look at it (so that you don’t see it), and tell you that I rolled an odd number. What’s the probability that I’ve rolled a 5? Ordinarily, the probability of a 5 is ⅙, but “I rolled an odd number” narrows it down. That piece of information eliminates the three even numbers (2, 4, 6) as possibilities. Only the three odd numbers (1,3, 5) are possible, so the probability is ⅓.

What’s the big deal about conditional probability? What role does it play in statistical analysis? Read on.

Inferential Statistics: Testing Hypotheses


Before a statistician does a study, he draws up a tentative explanation — a hypothesis that tells why the data might come out a certain way. After gathering all the data, the statistician has to decide whether or not to reject the hypothesis.

That decision is the answer to a conditional probability question — what’s the probability of obtaining the data, given that this hypothesis is correct? Statisticians have tools that calculate the probability. If the probability turns out to be low, the statistician rejects the hypothesis.

Back to coin-tossing for an example: Imagine that you’re interested in whether a particular coin is fair — whether it has an equal chance of heads or tails on any toss. Let’s start with “The coin is fair” as the hypothesis.

To test...

Erscheint lt. Verlag 25.3.2024
Sprache englisch
Themenwelt Mathematik / Informatik Informatik Programmiersprachen / -werkzeuge
Schlagworte basic r programming • Computer Science • Informatik • Programmierung • Programmierung u. Software-Entwicklung • Programming & Software Development • R • r books • R coding • R language • r manual • R (Programm) • R Programming • R programming beginners • r programming reference • r quick • r reference • r statistical analysis • R statistics • statistical analysis with r • statistics with R
ISBN-10 1-394-26343-0 / 1394263430
ISBN-13 978-1-394-26343-1 / 9781394263431
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