Difference between revisions of "September 4, 2007 - Cosmic Telescope"
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Instrumental Uncertainty =<math>\sigma = \sqrt{\frac{\sum (x_i - \bar{x})^2}{N-1}} = 12.12</math> counts per hour | Instrumental Uncertainty =<math>\sigma = \sqrt{\frac{\sum (x_i - \bar{x})^2}{N-1}} = 12.12</math> counts per hour | ||
+ | |||
+ | Your instrumental uncertainty is approximately equal to the Poisson sigma (<math>\sqrt{N}</math>) |
Revision as of 15:57, 5 September 2007
Plateau Zeroing | |||||||
---|---|---|---|---|---|---|---|
Time Start | Time Stop | Time elapsed (min.) | Thresholds on both Scintillators | Singles Count (on top) | Coinc. Counts | Coinc. per minute | Angle measure |
1:35 pm on 8/31 | 1:10 pm on 9/04 | 5725 min | 225 | 626816 | 1654 | .2889 | 75 degrees |
- Binomial distribtuion
- best example is a coin toss, its either heads or tails
- Poisson Distribution
- standard deviation ( ) = root of the mean ( )
- use in counting experiments
- the distribtuion approximates the Binomial Distribution for the special case when the mean ( ) is a lot less than the number of attempts to measure ( ) because the probability of the event occurrring is small.
- In the cosmic ray telescope experiment the mean number of detected cosmic rays is much smaller than the number of cosmic rays passing by.
Time Start | Time Stop | Time elapsed (hour) | Singles Count (on top) | Coinc. Counts | Coinc. per hour | ||
1:20 pm | 2:20 pm | 1 | 5694 | 127 | 127 | 11.3 | 121 |
2:20 pm | 3:20 pm | 1 | 4896 | 136 | 136 | 11.6 | 4 |
3:20 pm | 4:20 pm | 1 | 4655 | 151 | 151 | 12.2 | 169 |
Instrumental Uncertainty =
counts per hourYour instrumental uncertainty is approximately equal to the Poisson sigma (
)