1 / 15

Confidence Intervals vs. Prediction Intervals

Confidence Intervals vs. Prediction Intervals. Confidence Intervals – provide an interval estimate with a 100(1- ) measure of reliability about the mean (or some parameter) of a population

cora
Download Presentation

Confidence Intervals vs. Prediction Intervals

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Confidence Intervals vs. Prediction Intervals Confidence Intervals – provide an interval estimate with a 100(1-) measure of reliability about the mean (or some parameter) of a population Prediction Intervals – provide an interval estimate with a 100(1-) measure of reliability about future observations (or individual random variables) from a population

  2. Inference on the Mean Response Let x* be some specified value of the predictor variable x The mean response at x* is Hence, the point estimate of the mean at x* is

  3. Inference on the Mean Response Cont’d Aside: The estimated mean is on the least squares line Mean and Variance of

  4. C.I. for the Mean Response at x* A 100(1-)% confidence interval for is given by Recall:

  5. Remarks about C.I.’s at x* • The best estimation (i.e. tightest C.I.’s) of occurs at since the variance increases as x* moves away from • The estimation of the mean response should only be used for x values within the range of the data (i.e., x*’s within the range of the x’s of the data). Extrapolation in very dangerous and should be used with extreme caution.

  6. Multiple C.I.’s Consider a collection of k different 100(1-)% C.I.’s correspond the k different specifications of x*. The joint confidence level for this collection of confidence intervals is bounded below by Bonferroni’s inequality; as such the confidence level is guaranteed to no less than 100(1-k)%.

  7. Example – Multiple C.I.’s Consider the data of problem 12.4. Suppose we wish to construct 95% confidence intervals for the mean response when x* = 4, 10, 18. The joint confidence level for these 3 intervals is guaranteed to be at least 100(1-3(.05))% = 85%.

  8. Prediction Intervals • Frequently, we would like to use our L.S. regression model to predict the response y when x = x* • Our best guess would be the mean response at x*, i.e.

  9. Prediction Intervals Cont’d • Computing the variance of this guess (or prediction) yields

  10. Prediction Interval Cont’d Hence, the 100(1- )% Prediction Interval for Y when x = x* is

  11. Remarks about P.I.’s at x* • The P.I.’s are wider than C.I.’s. • As with C.I.’s the prediction interval is tightest at x = x* and as a rule, should not be used for extrapolated x* specifications • Additionally, as with C.I.’s, the joint confidence level of Multiple P.I.’s is bounded by Bonferroni’s inequality

  12. Example 12.4 Cont’d For the data of example 12.4, calculate the confidence interval and prediction interval corresponding to x* = 30

  13. Table of Confidence Intervals

  14. Table of Prediction Intervals

  15. Scatter Plot with Confidence Intervals and Prediction Intervals

More Related