# Correlation

**Correlation** measures the relationship of the process inputs (x) on the output (y). It is the degree or extent of the relationship between two variables. These studies are used to examine if there is a predictive relationship of the input on the process.

Correlation and Regression studies are normally done together as part of the ANALYZE phase of a DMAIC project.

** Assumption : ** Continuous data with interval or ratio measurement level

Predicting **within the range** of the data is called "interpolating"

Correlation studies and dependencies tend to be stronger with more more data and the maximum range being applied (be aware this can hide areas of correlation or unique relationships with subsets of the data too).

However, visualization of the data set can also show that there may exist varying relationships within the range being samples. Within a certain range there could be a relationship, and then another range could show and different relationship or none at all.

The picture to the left shows that there is very little, if any, correlation of the variables.

They are independent variables at least within the range of inputs studied and the "r" value is approximately zero.

A correlation value may be close to zero but closer review will indicate enlightening information. Be cautious because sometimes too much data can hide relationships within.

The point is to run the correlation visually and mathematically.

**"X" is considered the independent variable or predictor variable.**

**"Y" is the dependent variable or predicted variable.**

Regression and correlation involve testing a relationship rather than testing of means or variances. They are used to find out the variables and to the degree the impact the response so that the team can control the key inputs. Controlling these key inputs is done to shift a mean and reduce variation of an overall Project "Y".

### Linear Correlation

There are several correlation coefficients in use but the most frequently used is the **Pearson Product Moment Correlation**. also referred to as the **Coefficient of Correlation (COC)** that measures only a linear relationship between two variables and is denoted by an "r" value. The formula is shown below.

The "r" value is used to measure the linear correlation and it will always range from -1.0 (anticorrelation) to +1.0. As the value approaches 0 there is less linear correlation, or dependence, of the variables.

If the value:

- of one variable increases when the value of the other increases, they are said to be positively linearly correlated.
- of the output (y) decreases when the value of the input (x) increases, they are said to be negatively linearly correlated.
- of the output increases when as the input value increase then they are said to be positively correlated.

The degree of linear association between two variables is quantified by the Coefficient of Correlation.

Pearson's Correlation does NOT assume that the data is normally distributed but is strongly influenced by outliers anywhere in the data set. As expected, an outlier is likely to take away from the linear association of the other non-outlying variables whether the association is negative or positive.

The "r" value represents a unitless translation of Covariance. meaning the closer the value is to +1, the closer the linear relationship is between the x and y random variables.

As the value of "r" approaches zero from either side, the correlation is weaker. That is the input, x, has a lower correlation on the output, y.

This is normally shown by a x-y plot referred to as a Scatter Graph. This graph shows all the data points where the input, x, is varied systematically and the output, or the effect, of y is measured.

A "r" value of +1.0 indicates a perfect and strong POSITIVE correlation.

A "r" value of -1.0 indicates a perfect and strong NEGATIVE correlation or anticorrelation.

A data set that does not have a slope (slope = 0) will have a correlation coefficient that is undefined because the variance of Y is zero. In other words, the output is not affected by any of the input values.

Shown below in the video is an example starting with a set of data and the progessive steps to manually calculate the LINEAR correlation coefficient, "r".

This is a study between the number of caterpillars in a cabbage patch and the quantity of cabbages destroyed.

### Non Linear Correlation

The picture below indicates a strong relationship that would not be evident by simply analyzing the "r" value. The "r" value is going to be close to zero which means the variables are independent. Recall, the "r" value is measure of __linear association only__ .

There is another measurement that explains association. Visit Spearman's Rho Correlation Coefficient for an explanation of the monotonic association strength between two variables.

However, when it comes to data similar to the picture below there is strong indication that an association exist but it is non-linear.

This module doesn't investigate non-linear mathematical relationships but it is important to understand they exist as the picture below shows (which is non-linear and non-monotonic).

### More about Correlation

This __"r" value squared__ (r^2) represents the Coefficient of Determination.

**What is the difference between the Coefficient of Correlation (COC) and Coefficient of Determination (COD)?**

The COD ranges from 0-1 (0%-100%).

The COD is the proportion of variability of the dependent variable (Y) accounted for or explained by the independent variable (x) equal to the COC value squared.

In other words, it is the percentage of variation in Y explained by the linear relationship with X.

The COC is a value from -1 to +1 that describes the linear correlation of the dependent and independent variable. A value near zero indicates no linear relationship.

The sign is necessary to see if relationship is positive or negative so solving for COR by taking the square root of COD may not give the correct correlation since the sign can be positive or negative.

**CAUTION:**

Correlation interpretations from data or graphs can be wrong if it is purely coincidental.

Regardless of how strong (positive or negative) it may appear, Correlation never implies causation. There could be other variables behind the one charted that could be a factor.

For example, a chart or correlation value may indicate a strong relationship (linear or non-linear) but in reality there may be no relationship or dependency at all.

Just like most statistical results they must be reviewed subjectively with consideration of common sense. This is done with the Six Sigma team. The GB/BB is responsible for sharing the results in any way to help the team make the right decisions.

It is possible to have the same "r" value and have several different graphical representations, another reason to review the scatter plot and "r" value together.

## Correlation of Two Y's

Below is an example of monthly results of cereal sales related to marketing dollars. The intention is to determine the degree of linear correlation between marketing dollars spent to cereal sales. The data was compiled and is shown below.

Visually depicting the data is recommended whether is it time-series charts, scatter plots, or box plots. This helps in seeing trends and overall behavioral relationships between data. A couple graphs of the data are shown below. The scatter plot shows quickly that there appears to be a strong linear correlation.

## Assessing the Correlation

__Establish the Practical Problem__

Is there a relationship between the amount of money dedicated to marketing to the sales of cereal and what is the strength of the relations

Ho: Sales and Marketing dollars spent are not correlated

If the calculated p-value is <0.05, then the reject the Ho (null) and infer the Ha.

## Using Minitab

Find Correlation from the pull-down menu and enter both continuous sets of data and use Pearson Correlation, then the results are shown.

**RESULT:**

P value = 0.000

r = 0.9851 or 98.51%

With those results, reject the null and infer that there is a statistically significant correlation (which is the alternative hypothesis).

The linear correlation between the marketing dollars spent and resulting cereal sales is strong within a given month. The correlation coefficient (r) = 0.9851 within the inference range of $2,548 to $8,023 marketing dollars analyzed. This is a strong positive correlation. The more marketing, the higher the cereal sales.

Likely, at some point, that cereal sales would level off regardless of how high the amount of marketing dollars. That is why it is very important to keep your conclusion with the inference range.

Another method to perform the statistical evaluation is by comparing the r- calculated value of 0.9851 to the r-critical value.

The __r-critical value for a sample size of 12 at alpha risk of 0.05 is 0.4973__ .

If the value of r-calculated is >0.4973, then there is a statistical significant correlation and in this example that is clearly the case.

Regression takes it a step further and develops a formula to describe the nature of the relationship. Visit the Regression module for more information.

CAUTION:

As indicated earlier, the scatter plot should be visually examined. Even if the correlation coefficient was very low (linear relationship) there may be a non-linear relationship such as cubic or quadratic that could be very strong.

## Correlation Coefficient in Excel

Finding the Pearson Correlation Coefficient of two sets of data is done in Excel as shown below. The data does not have to be normally distributed but do have to be equal sample sizes.

The Pearson Correlation Coefficient between these two sets of data is -0.2636, a weak negative correlation.

### How does Correlation relate to Regression?

Recall that __Correlation indicates the amount of linear association__ that exists between two variables in the form of a value between -1.0 to 1.0.

Such as the linear correlation from earlier example where the value of -0.2636 was found and indicates a negative correlation but it is not very strong.

Regression provides an equation describing the nature of relationship such as y=mx+b.

There are various types of Regression:

*Simple Linear Regression*

Single regressor (x) variable such as x1 and model linear with respect to coefficients.

*Multiple Linear Regression*

Multiple regressor (x) variables such as x1, x2. xn and model linear with respect to coefficients.

*Simple Non-Linear Regression*

Single regressor (x) variable such as x and model non-linear with respect to coefficients.

*Multiple Non-Linear Regression*

Multiple regressor (x) variables such as x1, x2, x3 and model nonlinear with respect to coefficients.

Return to the ANALYZE Phase

Source: www.six-sigma-material.comCategory: Forex

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