An Introduction to the Central Limit Theorem In a world full of data that seldom follows nice theoretical distributions, the Central Limit Theorem is a beacon of light. Often referred to as the cornerstone of statistics, it is an important concept to understand when performing any type of data analysis.
Suppose that we are interested in estimating the average height among all people. Collecting data for every person in the world is impractical, bordering on impossible. While we can’t obtain a height measurement from everyone in the population, we can still sample some people. The question now becomes, what can we say about the average height of the entire population given a single sample.
The Central Limit Theorem addresses this question exactly. Formally, it states that if we sample from a population using a sufficiently large sample size, the mean of the samples (also known as the sample population) will be normally distributed (assuming true random sampling). What’s especially important is that this will be true regardless of the distribution of the original population.
When I first read this description I did not completely understand what it meant. However, after visualizing a few examples it become more clear. Let’s look at an example of the Central Limit Theorem in action.
Suppose we have the following population distribution.
I manually generated the above population by choosing numbers between 0 and 100, and plotted it as a histogram. The height of the histogram denotes the frequency of the number in the population. As we can see, the distribution is pretty ugly. It certainly isn’t normal, uniform, or any other commonly known distribution.
In order to sample from the above distribution, we need to define a sample size, referred to as N. This is the number of observations that we will sample at a time. Suppose that we choose N to be 3. This means that we will sample in groups of 3. So for the above population, we might sample groups such as [5, 20, 41], [60, 17, 82], [8, 13, 61], and so on.
Suppose that we gather 1,000 samples of 3 from the above population. For each sample, we can compute its average. If we do that, we will have 1,000 averages. This set of 1,000 averages is called a sampling distribution, and according to Central Limit Theorem, the sampling distribution will approach a normal distribution as the sample size N used to produce it increases. Here is what our sample distribution looks like for N = 3.
As we can see, it certainly looks uni-modal, though not necessarily normal. If we repeat the same process with a larger sample size, we should see the sampling distribution start to become more normal. Let’s repeat the same process again with N = 10. Here is the sampling distribution for that sample size.
This certainly looks more normal, and if we repeated this process one more time for N = 30 we observe this result.
The above plots demonstrate that as the sample size N is increased, the resultant sample mean distribution becomes more normal. Further, the distribution variance also decreases. Keep in mind that the original population that we are sampling from was that weird ugly distribution above.
Data sampling is a statistical analysis technique used to select, manipulate and analyze a representative subset of data points to identify patterns and trends in the larger data set being examined. It enables data scientists, predictive modelers and other data analysts to work with a small, manageable amount of data about a statistical population to build and run analytical models more quickly, while still producing accurate findings.
Sampling can be particularly useful with data sets that are too large to efficiently analyze in full – for example, in big data analytics applications or surveys. Identifying and analyzing a representative sample is more efficient and cost-effective than surveying the entirety of the data or population. An important consideration, though, is the size of the required data sample and the possibility of introducing a sampling error. In some cases, a small sample can reveal the most important information about a data set. In others, using a larger sample can increase the likelihood of accurately representing the data as a whole, even though the increased size of the sample may impede ease of manipulation and interpretation. There are many different methods for drawing samples from data; the ideal one depends on the data set and situation. Sampling can be based on probability, an approach that uses random numbers that correspond to points in the data set to ensure that there is no correlation between points chosen for the sample.
• Simple random sampling: Software is used to randomly select subjects from the whole population.
• Stratified sampling: Subsets of the data sets or population are created based on a common factor, and samples are randomly collected from each subgroup.
o EX: In the image below, let's say you need a sample size of 6. Two members from each
group (yellow, red, and blue) are selected randomly. Make sure to sample proportionally:
In this simple example, 1/3 of each group (2/6 yellow, 2/6 red and 2/6 blue) has been
sampled. If you have one group that's a different size, make sure to adjust your
proportions. For example, if you had 9 yellow, 3 red and 3 blue, a 5-item sample would
consist of 3/9 yellow (i.e. one third), 1/3 red and 1/3 blue.
• Cluster sampling: The larger data set is divided into subsets (clusters) based on a defined factor, then a random sampling of clusters is analyzed.
o EX: In the image below, the strata are natural groupings by head color (yellow, red, blue).
A sample size of 6 is needed, so two of the complete strata are selected randomly (in this
example, groups 2 and 4 are chosen).
Cluster sampling is a probability sampling technique where researchers divide the population into multiple groups (clusters) for research. Researchers then select random groups with a simple random or systematic random sampling technique for data collection and data analysis.
Example: A researcher wants to conduct a study to judge the performance of sophomore’s in business education across the U.S.
It is impossible to conduct a research study that involves a student in every university. Instead, by using cluster sampling,
the researcher can club the universities from each city into one cluster. These clusters then define all the sophomore
student population in the U.S. Next, either using simple random sampling or systematic random sampling and randomly pick clusters
for the research study. Subsequently, by using simple or systematic sampling, the sophomore’s from each of these selected
clusters can be chosen on whom to conduct the research study.
In this sampling technique, researchers analyze a sample that consists of multiple sample parameters such as demographics, habits, background – or any other population attribute, which may be the focus of conducted research. This method is usually conducted when groups that are similar yet internally diverse form a statistical population. Instead of selecting the entire population, cluster sampling allows the researchers to collect data by bifurcating the data into small, more productive groups.
Cluster sampling is defined as a sampling method where the researcher creates multiple clusters of people from a population where they are indicative of homogeneous characteristics and have an equal chance of being a part of the sample.
Example: Consider a scenario where an organization is looking to survey the performance of smartphones across Germany. They can divide the entire country’s population into cities (clusters) and select further towns with the highest population and also filter those using mobile devices.
There are two ways to classify this sampling technique. The first way is based on the number of stages followed to obtain the cluster sample, and the second way is the representation of the groups in the entire cluster analysis. In most cases, sampling by clusters happens over multiple stages. A stage is considered to be the step taken to get to the desired sample. We can divide this technique into single-stage, two-stage, and multiple stages.
As the name suggests, sampling is done just once. An example of single-stage cluster sampling – An NGO wants to create a sample of girls across five neighboring towns to provide education. Using single-stage sampling, the NGO randomly selects towns (clusters) to form a sample and extend help to the girls deprived of education in those towns.
Here, instead of selecting all the elements of a cluster, only a handful of members are chosen from each group by implementing systematic or simple random sampling. An example of two-stage cluster sampling – A business owner wants to explore the performance of his/her plants that are spread across various parts of the U.S. The owner creates clusters of the plants. He/she then selects random samples from these clusters to conduct research.
Multiple-stage cluster sampling takes a step or a few steps further than two-stage sampling.
For conducting effective research across multiple geographies, one needs to form complicated clusters that can be achieved only using the multiple-stage sampling technique. An example of Multiple stage sampling by clusters – An organization intends to survey to analyze the performance of smartphones across Germany. They can divide the entire country’s population into cities (clusters) and select cities with the highest population and also filter those using mobile devices.
• Multistage sampling: A more complicated form of cluster sampling, this method also involves dividing the larger population into a number of clusters. Second-stage clusters are then broken out based on a secondary factor, and those clusters are then sampled and analyzed. This staging could continue as multiple subsets are identified, clustered and analyzed.
• Systematic sampling: A sample is created by setting an interval at which to extract data from the larger population -- for example, selecting every 10th row in a spreadsheet of 200 items to create a sample size of 20 rows to analyze.
Sampling can also be based on non-probability, an approach in which a data sample is determined and extracted based on the judgment of the analyst. As inclusion is determined by the analyst, it can be more difficult to extrapolate whether the sample accurately represents the larger population than when probability sampling is used.
• Convenience sampling: Data is collected from an easily accessible and available group.
• Consecutive sampling: Data is collected from every subject that meets the criteria until the predetermined sample size is met.
• Purposive or judgmental sampling: The researcher selects the data to sample based on predefined criteria.
• Quota sampling: The researcher ensures equal representation within the sample for all subgroups in the data set or population (random sampling is not used).
Once generated, a sample can be used for predictive analytics. For example, a retail business might use data sampling to uncover patterns about customer behavior and predictive modeling to create more effective sales strategies.
Is Ha(Alternate Hypothesis) true? No, H0(Null Hypothesis) is True (Ha is Negative: TN); Yes, H0 is False (Ha is Positive: TP).
- A type I error occurs when the null hypothesis is true but it gets rejected.
- A type II error occurs when the null it is actually false but we failed to reject it.
Q4. What is linear regression? What do the terms p-value, coefficient, and rsquared value mean? What is the significance of each of these components?
Imagine you want to predict the price of a house. That will depend on some factors, called independent variables, such as location, size, year of construction… if we assume there is a linear relationship between these variables and the price (our dependent variable), then our price is predicted by the following function:
The p-value in the table is the minimum
The p-value is used as an alternative to rejection points to provide the smallest level of significance at which the null hypothesis would be rejected. A smaller p-value means that there is stronger evidence in favor of the alternative hypothesis.
The coefficient value signifies how much the mean of the dependent variable changes given a one-unit shift in the independent variable while holding other variables in the model constant. This property of holding the other variables constant is crucial because it allows you to assess the effect of each variable in isolation from the others.
R squared (
There should be linear relationship betweent the independent and dependent variables, either there can be a positive correlation or negative correlation.
The Errors or residuals of the data to be Normally distributed ND~(0,1) and the variance of it should have homoscedasticity for any value of Independent Variable. There should be no autocorrelation among the errors nor postive or negative. There should be no relation between the Errors or any Independent Variable (also covers in Homoscedasticity of Error)
No Hetroscedasticity but Homoscedasticity. This means the variance around the regression line is the same for all values of the predictor variable.
Basically, an interaction is when the effect of one factor (input variable) on the dependent variable (output variable) differs among levels of another factor. For example, in a pain relief drug trial, one factor is “dose” and another factor is “gender”. The dependent variable is “headache pain” (measured on a scale of 0 to 50). We can look at the findings by showing the means for each group in a table like this:
If compare the “marginal means”, we can see that the average pain score for women was 20 and the average pain score for men was 20. There is no difference in headache pain between men and women. Likewise, the drug appears to have no effect on headache pain.
However, if we had stopped there, we would be missing some important findings. There is an interaction between gender and dose on headache pain. If we graph the means of each group, we can see it clearly: men have more headache pain than women unless they take the drug. There are simple effects of dose for both men and women, but the effects “wash out” one another. The result is no main effect of dose or gender. If you did not examine gender, it would appear that your drug did not work; if you did not study drug dose, you would see no difference between men and women. Examining the interaction allows us to see that the drug works – for men – AND that it causes pain in women.
This is called a “pure interaction” because there are no main effects, but there is an interaction.
More commonly seen, however, when effects occur in both (or all) conditions, but they are stronger in one condition than another. Also fairly common is an effect in one condition (or for one group), but no effect at all in another. For example, what if our same pain study resulted in the following means:
For men, there is no effect of the drug on headache pain. The drug causes pain in women, who would otherwise have the same amount of pain as men.
To recap, When two or more independent variables are involved in a research design, there is more to consider than simply the "main effect" of each of the independent variables (also termed "factors"). That is, the effect of one independent variable on the dependentvariable of interest may not be the same at all levels of the other independent variable. Another way to put this is that the effect of one independent variable may depend on the level of the other independent variable. In order to find an interaction, you must have a factorial design, in which the two (or more) independent variables are "crossed" with one another so that there are observations at every combination of levels of the two independent variables.
EX: stress level and practice to memorize words: together they may have a lower performance.
Selection (or ‘sampling’) bias occurs when the sample data that is gathered and prepared for modeling has characteristics that are not representative of the true population
There are several aspects of sampling bias, all of which ultimately mean that the population being studied does not provide the data that we require to make conclusions.
A common example of this happening in practice is through self-selection. Specific groups of people may be drawn to taking part in a particular study because of self-selecting characteristics. It is known that individuals who are inclined to sensation-seeking, or thrill-seeking are more likely to take part in certain studies, which could skew data from a study if it is examining those personality traits (and possibly within other studies too).
The best way around this bias is to draw from a sample that is not self-selecting. This may not always be possible of course, due to experimental constraints (particularly for studies requiring volunteers), but particular effort should be made to avoid the potential for this bias when examining different personality types. The effects of this bias are unlikely to be so detrimental if the experiment is concerned with something more constant, such as psychophysiological measurements.
Binomial: multiple toss of a coin Bin(n,p): the binomial distribution consists of the probabilities of each of the possible numbers of successes on n trials for independent events that each have a probability of p of occurring.
- The binomial distribution is a probability distribution in statistics that summarizes the likelihood that a value will take one of two independent values under a given set of parameters or assumptions.
- The underlying assumptions of the binomial distribution are that there is only one outcome for each trial, that each trial has the same probability of success, and that each trial is mutually exclusive or independent of one another.
- The binomial distribution is a common discrete distribution used in statistics, as opposed to a continuous distribution, such as the normal distribution.
To start, the “binomial” in binomial distribution means two terms. We’re interested not just in the number of successes, nor just the number of attempts, but in both. Each is useless to us without the other.
The binomial distribution is a common discrete distribution used in statistics, as opposed to a continuous distribution, such as the normal distribution. This is because the binomial distribution only counts two states, typically represented as 1 (for a success) or 0 (for a failure) given a number of trials in the data. The binomial distribution thus represents the probability for x successes in n trials, given a success probability p for each trial.
Binomial distribution summarizes the number of trials, or observations when each trial has the same probability of attaining one particular value. The binomial distribution determines the probability of observing a specified number of successful outcomes in a specified number of trials.
The expected value, or mean, of a binomial distribution is calculated by multiplying the number of trials (n) by the probability of successes (p), or n x p. For example, the expected value of the number of heads in 100 trials of heads or tales is 50, or (100 * 0.5). Another common example of the binomial distribution is by estimating the chances of success for a free-throw shooter in basketball where 1 = a basket is made and 0 = a miss.
The binomial distribution formula is calculated as:
where:
- n is the number of trials (occurrences)
- X is the number of successful trials
- p is probability of success in a single trial
- nCx is the combination of n and x. A combination is the number of ways to choose a sample of x elements from a set of n distinct objects where order does not matter and replacements are not allowed. Note that nCx=n!/(r!(n−r)!), where ! is factorial (so, 4! = 4 x 3 x 2 x 1)
The mean of the binomial distribution is np, and the variance of the binomial distribution is np (1 − p). When p = 0.5, the distribution is symmetric around the mean. When p > 0.5, the distribution is skewed to the left. When p < 0.5, the distribution is skewed to the right.
The binomial distribution is the sum of a series of multiple independent and identically distributed Bernoulli trials. In a Bernoulli trial, the experiment is said to be random and can only have two possible outcomes: success or failure.
For instance, flipping a coin is considered to be a Bernoulli trial; each trial can only take one of two values (heads or tails), each success has the same probability (the probability of flipping a head is 0.5), and the results of one trial do not influence the results of another. The Bernoulli distribution is a special case of the binomial distribution where the number of trials n = 1
In statistics, a Poisson distribution is a probability distribution that is used to show how many times an event is likely to occur over a specified period. In other words, it is a count distribution. Poisson distributions are often used to understand independent events that occur at a constant rate within a given interval of time.
Poisson distributions are used when the variable of interest is a discrete count variable. Many economic and financial data appear as count variables, such as how many times a person becomes unemployed in a given year, thus lending themselves to analysis with a Poisson distribution.
Understanding Poisson Distributions A Poisson distribution can be used to estimate how likely it is that something will happen "X" number of times. For example, if the average number of people who buy cheeseburgers from a fast-food chain on a Friday night at a single restaurant location is 200, a Poisson distribution can answer questions such as, "What is the probability that more than 300 people will buy burgers?" The application of the Poisson distribution thereby enables managers to introduce optimal scheduling systems that would not work with, say, a normal distribution.
One of the most famous historical, practical uses of the Poisson distribution was estimating the annual number of Prussian cavalry soldiers killed due to horse-kicks. Modern examples include estimating the number of car crashes in a city of a given size; in physiology, this distribution is often used to calculate the probabilistic frequencies of different types of neurotransmitter secretions. Or, if a video store averaged 400 customers every Friday night, what would have been the probability that 600 customers would come in on any given Friday night?
In the example depicted in the graph above, assume that some operational process has an error rate of 3%. If we further assume 100 random trials, the Poisson distribution describes the likelihood of getting a certain number of errors over some period of time, such as a single day.
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