1 / 16

Estimating – with confidence!

Estimating – with confidence!. Case study….

teva
Download Presentation

Estimating – with confidence!

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. Estimating – with confidence!

  2. Case study… • The amount of potassium in the blood varies slightly from day to day and this fact (along with routine measurement errors) means that successive readings of a patient’s potassium level will show a small variation with a standard deviation of s = 0.2 mmol/L with a range of 3.5 – 5.0 mmol/L being cosidered normal. A significantly different value could indicate possible renal failure. • A patient has 1 K-test performed and presents a reading of 3.4 mmol/L. How reliable is this 1 measure? Can we quantify our confidence in this reading?

  3. A confidence Interval • If we assume that the errors in measuring K are normally distributed then we can use z-scores to help quantify our confidence in this reading: • The reading of X=3.4 mmol/L is our estimate of the true value of the parameter “K blood-level concentration” • A 90% confidence interval would represent a range of readings that we would expect to get 90% of the time.

  4. Solution… • Use the correct z-value for 90% 95% of area left of this point 5% of area left of this point The correct z values are -1.645 and +1.645 and are usually denoted z* to indicate that these are special ones chosen with a particluar confidence level “C” in mind. In this example C = 90%

  5. Using the z-score formula we get: 90% of the readings will be expected to fall in the range (3.1,3.7) mmol/L Suppose 5 tests were performed over a number of days and eachtime gave a result of 3.4 mmol/L. How would that change the range of numbers in the confidence interval?

  6. Using Confidence Intervals when Determining the True value of a Population Mean • We rarely ever know the population mean – instead we can construct SRS’s and measure sample means. • A confidence interval gives us a measure of how precisely we know the underlying population mean • We assume 3 things: • We can construct “n” SRS’s • The underlying population of sample means is Normal • We know the standard deviation

  7. This gives … Confidence interval for a population mean: Number of samples or tests We infer this We measure this

  8. Example: Fish or Cut Bait? A biologist is trying to determine how many rainbow trout are in an interior BC lake. To do this he uses a large net that filters 6000 m3 of lake water in each trial. He drops the net in a specific area and records the mean number of fish caught in 10 trials. This represents one SRS. From this he is able to determine a mean and standard deviation for the number of fish in 100 SRS’s. Each SRS has the same s = 9.3 fish with a sample mean of 17.5 fish. How precisely does he know the true mean of fish/6000 m3? Use C = 90% If the volume of the lake is 60 million m3, how many trout are in the lake?

  9. Solution: • Since C = 0.90, z* = 1.645 There is a 90% chance that the true mean number of fish/6000 m3 lies in the range (16.0,19.0) Total number of fish: He is 90% confident that there are between 160 000 and 190 000 fish in the lake. Why should you be skeptical of this result?

  10. Margin of Error • When testing confidence limits you are saying that your statistical measure of the mean is: • ie: X = 3.2 cm +/- 1.1 cm with a 90% confidence estimate +/- the margin of error

  11. Math view… • Mathematically the margin of error is: • You can reduce the margin of error by • increasing the number of samples you test • making more precise measurements (makes s smaller)

  12. Matching Sample Size to Margin of Error • An IT department in a large company is testing the failure rate of a new high-end graphics card in 200 of its work stations. 5 cards were chosen at random with the following lifetime per failure (measured in 1000’s of hours) and s = 0.5: Provide a 90% confidence level for the mean lifetime of these boards.

  13. IT is 90% confident that the mean lifetime of these boards is between 1290 and 2030 hours. However – these are expensive boards and accounting wants to have the margin of error reduced to 0.10 with a 90% confidence level. What should IT do? IT needs to test 68 machines!

  14. Important Caveats… • Read page 426 carefully! • Data must be a SRS • Outliers can wreak havoc! • We “fudged” our knowledge of s, in general we don’t know this • Poorly collected data or bad experiment design cannot be overcome by fancy formulas!

  15. Examples… • 6.13 • 6.18 • 6.19 • 6.30

  16. In conclusion… • This whole discussion rests on your understanding of z-scores. If you are OK with this then just review the new terms and try the previous examples • If you are still “rusty” or un-sure about z-scores, come and see me!

More Related