Learn about statistics essentials for developers, from basic concepts to advanced methods, practical applications, challenges, and considerations. Discover how statistics empower developers to make informed decisions and build data-driven s
Understanding statistics is crucial for developers to make informed decisions, optimize software, and innovate effectively. Here’s a quick guide covering the essentials:
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Basic Statistical Concepts: Learn about different types of data, distributions, and how to sample and estimate accurately.
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Statistical Programming: Why programming offers more flexibility than traditional formulas, including key concepts and popular libraries like Pandas, NumPy, and SciPy.
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Advanced Statistical Methods: Dive into regression analysis, hypothesis testing, Bayesian analysis, and time series analysis for deeper insights.
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Practical Applications: From code examples to case studies of big companies like Microsoft and Facebook, see statistics in action.
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Challenges and Considerations: Common pitfalls, debugging tips, and further learning resources to enhance your statistical skills.
Whether it’s making sense of data, optimizing user engagement, or predicting future trends, statistics empower developers to build better, data-driven software.
The Role of Statistics in Development
Improving Decision Making
Statistics help us make smarter choices when we're building software. Here's how they can help:
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Prioritizing features: By looking at what customers say, how they use the product, and what they buy, we can figure out what features are most wanted. Statistics help us tell the difference between a real trend and just a coincidence.
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Resource allocation: Information about how fast we're working, how many bugs we find, and how many people we need helps us decide on things like team size and budget. Predictive modeling can forecast what resources we'll need.
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Testing: Statistics about how much of our code is tested, how many tests pass, and bugs help us plan our testing better. By choosing samples smartly, we don't have to test everything.
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Release planning: Looking at how users behave, sales data, and market conditions helps us pick the best time to launch. Statistics help us know when we're ready.
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Process improvements: By using statistics, we can spot where we're wasting time or resources. Testing out our ideas with statistics helps make sure the changes we make are actually improvements.
Informing Project Outcomes
Using statistics also helps our projects succeed in many ways:
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Quality: By controlling quality with statistics, we reduce bugs and make our software more reliable. Statistics help us set and reach quality goals.
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User engagement: Analyzing clicks, grouping users, and testing different options give us clear data to make the user experience better and keep people coming back. Statistics guide us to the best choices.
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ROI: Optimizing how we turn visitors into customers, using sales models, and testing different strategies improve how much money we make. Statistics show us what's really working.
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Innovation: Using experiments and research methods based on statistics helps us come up with new ideas faster. Statistics are key to making new discoveries.
In short, statistics are super important for teams that make software. They help us make informed decisions, create better products, and achieve success with the help of data. Thinking with statistics is a must for top-notch software today.
Basic Statistical Concepts
Variables and Data Types
Variables are like containers for storing information in programming. There are a few main types:
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Numeric: These are numbers you can do math with, like 1, 2, 3 or 3.14.
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String: These are text, like names or any word. For example, "Hello World". You can put strings together too.
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Boolean: This type only has two options, True or False. It's great for making decisions in code.
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List: A list is a collection of items in order. For example, ["red", "blue", "green"] shows a list of colors.
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Array: Think of this like a spreadsheet with rows and columns, used to organize data neatly. For instance, [[1,2], [3,4]] is a simple array.
Knowing what type of data you're dealing with helps you figure out what you can do with it in your code.
Distributions
Distributions are about understanding the chances of different outcomes. Here's the rundown:
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Probability Mass Function (PMF): This tells you how likely each possible outcome is when the outcomes are clear-cut. It all adds up to 100%.
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Cumulative Distribution Function (CDF): This shows the chance of getting a result up to a certain point. It starts at 0% and goes up to 100%.
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Probability Density Function (PDF): For more fluid situations, this shows how likely different outcomes are. The total area under its curve equals 100%.
Knowing about these helps you predict how data might behave, which is super useful in fields like data analytics and machine learning.
Sampling and Estimation
Instead of looking at everything, we often use samples to make good guesses about larger groups:
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Sampling methods: These are ways to pick a part of the whole group so we can study it. Techniques like grabbing random items or picking by category help make sure our sample is fair.
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Estimators: These are tools that help us use our sample to guess things about the whole group, like the average or range.
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There's always some error in our guesses because we're not looking at everything. But understanding this error helps us make better guesses.
Picking the right samples and making smart guesses is key to getting useful insights without having to check every single thing.
Statistical Programming for Developers
Why Program Instead of Use Formulas?
Programming lets us do stats in a way that's more flexible and easier to change than just using set formulas. Here's why it's great:
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Customization: You can make your stats work exactly how you need for your specific data and questions.
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Automation: Writing code for your stats saves you from doing the same steps by hand every time you get new data. It's a big time-saver.
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Reproducibility: When you program, it's easier for others (or you in the future) to see how you got your results and check them.
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Advanced techniques: The latest tools for stats are often in programming libraries, giving you access to cutting-edge methods.
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Visualizations: It's easier to make graphs and charts with programming, which helps you see what your data is telling you.
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Big data: Programming can handle really large sets of data without getting bogged down, unlike basic formulas.
So, while formulas are good for the basics, programming opens up a lot more possibilities.
Key Programming Concepts
Here are the basics you need for doing stats with programming:
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Functions are like shortcuts for doing the same thing with different data.
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Loops let you go through your data step by step automatically.
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Conditionals are if-then decisions in your code.
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Data structures (like lists or tables) help you keep your data organized.
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Algorithms are step-by-step instructions for analyzing your data.
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Plotting is making graphs to understand your data better.
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Object-oriented programming is a way to write your code that mimics real-world things.
Understanding these parts helps you use programming for stats effectively.
Popular Statistical Libraries
For programming with stats, languages like Python and R have some go-to tools:
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Pandas is great for working with tables of data.
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NumPy helps with calculations and working with numbers in arrays.
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SciPy has tools for more math-heavy tasks.
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Statsmodels lets you do more complex stats like predicting trends.
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Matplotlib and Seaborn are for making all kinds of charts and graphs.
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Scikit-learn is all about machine learning, helping you make predictions based on your data.
These tools make it a lot easier to do serious stats work with programming.
Advanced Statistical Methods
Regression Analysis
Regression analysis helps us understand how different things are connected by using math to model their relationship.
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Linear regression looks at the straight-line connection between one thing influencing another. It's like finding the best straight path through a set of points.
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Multiple linear regression lets us look at how several things at once affect something else. It's a bit more complex but gives us a clearer picture.
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To see if our model is doing a good job, we check its goodness of fit. This means looking at things like R-squared values to make sure our line is as close as possible to the actual data points.
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Making sure our model is valid means checking it against certain rules to ensure it's reliable and not thrown off by unusual data.
In short, regression helps us predict future trends based on past data, guiding decisions in business and software development.
Hypothesis Testing
Hypothesis testing is a way to test our assumptions with data:
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A null hypothesis is our starting point, where we assume no effect or difference. The alternative hypothesis is what we're trying to prove.
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The p-value helps us understand if what we're seeing in the data could happen by chance or if it's likely something real. A small p-value means it's probably not just random.
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Confidence intervals give us a range where we think the true answer lies, based on our data. The smaller this range, the more confident we are.
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Significance testing helps us decide if our findings are strong enough to be considered real or if they might just be due to chance.
This process helps us make sure we're not making claims without solid evidence.
Bayesian Analysis
Bayesian analysis is a different way of looking at statistics that combines what we already believe with new data:
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It starts with prior beliefs and updates these as new data comes in. This way, our conclusions get better over time.
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This approach lets us make more detailed conclusions than just yes or no. It's especially useful in fields like machine learning and predictive modeling.
Bayesian analysis is a powerful tool for making decisions with a clear picture of uncertainty.
Time Series Analysis
Time series analysis is all about data that's collected over time:
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It helps us spot trends and seasonal patterns, showing us how things change.
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Forecasting uses these patterns to predict what might happen next. This can be really useful for things like planning how much stock a store needs or predicting sales.
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We also look at how accurate our predictions are, using different measures to see if we're on the right track.
Understanding data over time is key for making informed decisions in business and technology.
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Practical Applications
Code Examples and Tutorials
Here are some ways to use statistics when you're coding:
Sampling Data
Imagine you have a huge list of data with 1 million items. To make things faster, you want to look at just a small part of it. Here's a simple way to pick a random small part using Python:
import random
full_dataset = [/* 1 million rows */]
# Take random sample of 10,000 rows
sample = random.sample(full_dataset, 10000)
This lets you focus on a smaller chunk to try out your ideas more quickly.
Estimating Averages
If you want to find out the average age of people visiting a website, you can do it like this:
ages = [23, 45, 29, 56, 33, 28, 37] # collected ages
# Estimate average age
mean_age = sum(ages) / len(ages)
print(mean_age) # 36
This gives you a quick average, even with just a few numbers.
Hypothesis Testing
To see if two groups are really different, you can use this Python example:
import scipy.stats
group_a = [1, 3, 4, 5, 8]
group_b = [2, 4, 6, 7, 10]
# Is difference between groups significant?
tstat, pval = scipy.stats.ttest_ind(group_a, group_b)
if pval < 0.05:
print("Significant difference between groups")
else:
print("No significant difference")
This checks if the difference isn't just by chance, using a p-value.
Case Studies
Here's how some big companies use statistics in their work:
Microsoft
Microsoft used smart ways to find and fix errors in Windows Vista. By looking at a small part of the crash data, they managed to fix most errors quickly.
Facebook tests new features by showing them to some users and seeing how they react. This helps them figure out which changes make the app better.
Grammarly
Grammarly improves its writing suggestions by seeing how users respond to them. This feedback helps make the tool more helpful and accurate.
Challenges and Considerations
Common Pitfalls
When you're starting to use statistics in programming, it's easy to slip up. Here are a few mistakes to watch out for:
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Overfitting models: This is when you make a model that's too perfect for your current data but doesn't work well with new data. It's like making a key that only fits one lock.
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Sampling bias: This happens when your sample doesn't really represent the whole group you're interested in. Imagine only asking morning people about their sleep habits and missing out on night owls.
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Ignoring assumptions: Every statistical method assumes certain things about your data. If you don't check these, your results might not be reliable. It's like ignoring the weather forecast and then getting caught in the rain.
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Misinterpreting results: It's easy to mix up what your results are telling you. For example, just because two things happen together doesn't mean one caused the other.
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Using inappropriate tests: Not every statistical method is right for every situation. Picking the wrong one can lead to incorrect conclusions.
Avoiding these mistakes means paying attention to the details and always questioning if your approach makes sense.
Debugging Statistical Code
Fixing errors in statistical code can be tough. Here's how to make it easier:
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Unit test components: Test small parts of your code separately to find where errors are hiding.
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Check inputs and outputs: Make sure the data going into and coming out of your functions looks right. Sometimes just printing it out can help you spot mistakes.
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Visualize data: Looking at your data in charts can help you see if it's being processed correctly.
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Verify assumptions: Make sure your data meets the requirements for the statistical methods you're using.
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Use regression diagnostics: Tools like plots that show the difference between your model's predictions and the actual data can help you see if your model is working.
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Perform sanity checks: Sometimes, just asking if your results make sense can help you find errors.
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Try alternative approaches: If something isn't working, trying a different method might give you better results.
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Replicate simpler cases: Test your code with data where you already know the outcome to make sure it's working right.
By breaking down the problem and checking your work step by step, you can root out and fix errors in your statistical code.
Further Learning Resources
If you're a developer looking to get even better at understanding and using statistics, here are some helpful resources to check out:
Books
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"Think Stats" by Allen B. Downey - This book is great for beginners and teaches you about statistics with Python. You can read it online for free.
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"Statistical Inference via Data Science" by Chester Ismay and Albert Y. Kim - This book goes deeper into how to use statistics to make sense of data, using R.
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"An Introduction to Statistical Learning" by Gareth James, Daniela Witten, Trevor Hastie, and Robert Tibshirani - Perfect for learning about machine learning and statistics. It also includes practical exercises in R.
Online Courses
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"Statistics for Data Science and Business Analysis" on Coursera - This course teaches you the basics of statistics, including how to analyze data in R, which is super useful for data analytics and predictive modeling.
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"Statistical Thinking for Data Science and Analytics" on edX - Offered by Columbia University, this course helps you understand how to use statistics to analyze real-world data.
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"Data Analysis: Statistical Modeling and Computation in Applications" on edX - A more advanced course from Harvard on computational statistics methods, including how to model and simulate data.
Tutorials and Practice
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Kaggle Learn - Offers hands-on coding challenges and short courses on statistics and data science. You get to work with real data.
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DataCamp - Has courses for all levels on using Python, R, and SQL for statistical programming. It includes lots of interactive exercises.
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Brilliant - Offers courses on math and statistics that help you solve problems step-by-step. It covers topics like probability and hypothesis testing.
Diving into these resources will really boost your skills in using statistics for programming. The key is to practice with actual data. Stick with it, and you'll pick up some awesome skills that will make your work stand out.
Conclusion
Statistics are super important in making software and understanding data today. By getting the hang of basic stats stuff and how to use it, developers can make smarter choices, create better programs, and come up with new ideas.
Here are some key points about why statistics matter in making software:
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They help us make choices based on data for things like what features to add, how to use our resources, testing, when to launch something, and how to make our work better.
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They give us insights into how to improve the quality of our software, make users happier, earn more money, and find new ideas.
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They support advanced stuff like making predictions, understanding trends, improving things, and teaching computers to learn from data.
But, using statistics the right way means avoiding common mistakes like making your model too perfect, choosing the wrong sample, not checking your basics, or picking the wrong test. Fixing errors in stats code can be tricky but doing things like testing in parts, double-checking your work, using pictures to understand your data, and trying different methods can help.
As data becomes more central to making software, knowing about statistics is becoming more and more important. There are lots of resources to learn more, like the book "Think Stats", online courses on Coursera and edX, and practicing with real data on sites like Kaggle.
By using statistics, developers can make better decisions, build better products, and push forward innovation. Mixing stats into the process of making software is a big chance to stand out and move ahead in the world of tech.
Related Questions
What are the 5 basic concepts of statistics?
The five basic concepts of statistics are:
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Population: This is everyone or everything you're interested in learning about. For example, all the people who visited a website last month.
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Sample: This is a smaller group picked from the population to study. For example, choosing 1,000 visitors from last month to look into.
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Parameter: A detail about the entire population. For example, the average time all visitors spent on the site last month.
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Statistic: A detail found from studying the sample. For example, the average time the 1,000 chosen visitors spent on the site.
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Variable: Something you're measuring. For example, how long people spend on a site.
Do programmers need statistics?
Yes, programmers need statistics for things like:
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Checking how well code works and how fast it runs
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Looking at data to find trends
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Making predictions with machine learning
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Understanding how certain we can be about results
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Making sure products work well and are reliable
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Using data to make business choices
Statistics help programmers make smarter decisions and better products.
How is statistics used in software development?
In software development, statistics are used for:
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Comparing different versions of a feature to see which one users like more
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Figuring out how much of the code has been tested
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Measuring how fast software runs
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Studying how users interact with software
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Making algorithms better
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Understanding risks
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Creating models to predict future trends
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Showing data in easy-to-understand charts
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Making sure products are of high quality
What are the essential topics in statistics?
The must-know topics in statistics are:
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Different ways to talk about chance and probability
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How to draw conclusions from data
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Understanding relationships between things with regression analysis
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Planning experiments
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Learning about how samples can represent larger groups
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Testing theories with data
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Guessing values within a range
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Knowing the difference between things happening together and one causing the other
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Figuring out if results are meaningful
These topics help you work with and make sense of data.