Statistics and Image Evaluation

1. Statistics and Image Evaluation Oleh Tretiak Medical Imaging Systems Fall, 2002

2. Which Image Is Better?

3. Which Image is Better?

4. Overview • Why measure image quality? • How to measure image quality • Statistical variation and probability theory • Some results in probability theory • Some results in statistics • Experimental design • Subjective quality measurement • ROC theory and estimation

5. Why Measure Image Quality • Market studies (sell films) • Market studies (sell equimpent) • Test if equipment is working up to specification • Measure effect of equipment on radiologists performance • Measure the ability to perform diagnosis

6. Types of ‘Quality’ • Viewer preference • Relevant for entertainment, home viewing • Technical quality • Process control (equipment maintenance) • Utility • Ability to perform diagnosis, drive a remote vehicle, locate enemy weapons

7. How to Measure Image Quality • Viewer preference • Viewer trials • Technical quality • Phantoms, resolution targets, expert viewers • Utility • Viewer trials with expert viewers

8. Variation and Probability Theory • Sources of variation • Input: Different patients are different • Equipment: Different equipment is different, same equipment is different at different times • Subjective: Different viewers report different opinions, same viewers report different findings at different times

9. Probability Theory • Probability theory used almost universally • Models • Independent trials • Dependency effects • Same films viewed by different viewers • Same patients imaged by different modalities • Same patients viewed by several radiologists, multiple reading

10. Example • Goal: evaluate quality of television set • Method: Ask viewers to report quality of image, standard viewing conditions • Viewers report a quality number 1-5 • 1-Terrible, 2-Bad, 3-So-so, 4-Good, 5-Excellent • Evaluation: Compute average response

11. Probabilistic Model • Reported values are iid random variables. • Set {1, 2, 3, 4, 5} • Probabilities p(1), p(2), p(3), p(4), p(5) • Probabilities are unknown! • Example: 100 observation, computed average value is ?

12. Breakout • Excel visq.xls • Blackboard

13. Conclusions • Results depend on who you ask • Average result measured from a sample varies from sample to sample • Prob. Theory tells us that with large samples, the average is equal to expected value • Why does this matter?

14. Some Results from Prob. Theory • Mean (Expected value) • Variance, Standard Deviation • Sample mean, sample variance • Law of large numbers • Central limit theorem

15. Some Results in Statistics • Statistical problems • Estimation • Hypothesis testing • Confidence level

16. Estimate of the Mean • For a Gaussian (Normal) random variable with known standard deviation, • ~ a is the confidence level

17. Practical Issues • Can use for non-normal distributions (CLT) • If n is large and st. dev. Is not known, use sample st. dev. • Small sample, unknown st. dev. — use the Student t statistic.

18. Experiment Quality 1 Quality 5

19. Case A

20. Case B

21. More Statistics • Estimate of variance • chi-squared (ki-squared) • Depends on number of observations (degrees of freedom) • Estimate ratio of independent normal variances • Fisher f distribution • Most important