Summaries

9^th September 2009

Session 1.6

 

Rare Events

The Scale of Probability

Probabilities range from 0 to 1.

Pr{Event} = 0 The event is impossible.

 

Pr{Event} » 0 The event is rare, highly unlikely to be observed in modestly-sized samples.

 

Pr{Event} = ½ The event is observed in approximately half of observed trials. The event is as likely to occur as not.

 

Pr{Event} » 1 The event is almost certain, highly likely to be observed in nearly every observed trial.

 

Pr{Event} = 1 The event is certain.

 

Pr{Event} < ½ The event is more likely to not occur than to occur.

Pr{Event} > ½ The event is more likely to occur than not occur.

The Rare Event Approach

An event is rare if

Pr{Event} ≈ 0.

The implications for observing rare events in random samples are important. In particular, we can say that the smallest sample size in which we expect to reliably observe a rare event depends on its true probability. That is:

n ≥ 1/ Pr{Event}.

Rare Event Approach: Pairs of Dice and the Pair (1,1) Consider a sequence of pairs of fair dice, and the occurrence (relative to n=100) of the face-pair (1,1).

Pair of Fair Dice, each with face values {1,2,3} per die

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D3}*Pr{1 shows from 2^nd D3} = (1/3)*(1/3) = 1/9 @ .1111111

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/9) @ 11.11111.

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/9) = 9. 

Pair of Fair Dice, one with face values {1,2,3,4} per die and one with face values {1,2,3} per die

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D4}*Pr{1 shows from 2^nd D3} = (1/4)*(1/3) = 1/12 @ .0833

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/12) @ 8.33

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/12) = 12.

Pair of Fair Dice, each with face values {1,2,3,4}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D4}*Pr{1 shows from 2^nd D4} = (1/4)*(1/4) = 1/16 @ .0625

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/16) @ 6.25

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/16) = 16.

Pair of Fair Dice, one with face values {1,2,3,4,5} and one with face values {1,2,3,4}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D5}*Pr{1 shows from 2^nd D4} = (1/5)*(1/4) = 1/20 @ .05

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/20) @ 5

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/20) = 20.

Pair of Fair Dice, each with face values {1,2,3,4,5}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D5}*Pr{1 shows from 2^nd D5} = (1/5)*(1/5) = 1/25 @ .04

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/25) @ 4

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/25) = 25.

Pair of Fair Dice, one with face values {1,2,3,4,5,6} and one with face values {1,2,3,4,5}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D6}*Pr{1 shows from 2^nd D5} = (1/6)*(1/5) = 1/30 @ .0333

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/30) @ 3.33

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/30) = 30.

Pair of Fair Dice, each with face values {1,2,3,4,5,6}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D6}*Pr{1 shows from 2^nd D6} = (1/6)*(1/6) = 1/36 @ .0278

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/36) @ 2.78

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/36) = 36.

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8} and one with face values {1,2,3,4,5,6}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D8}*Pr{1 shows from 2^nd D6} = (1/8)*(1/6) = 1/48 @ .0208

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/48) @ 2.08

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/48) = 48.

Pair of Fair Dice, each with face values {1,2,3,4,5,6,7,8} 

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D8}*Pr{1 shows from 2^nd D8} = (1/8)*(1/8) = 1/64 @ 0.0156

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/64) @ 1.56.

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/64) = 64. 

Pair of Fair Dice, on e with face values {1,2,3,4,5,6,7,8,9,10} and one with face values {1,2,3,4,5,6,7,8} 

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D10}*Pr{1 shows from 2^nd D8} = (1/10)*(1/8) = 1/80 = 0.0125

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/80) = 1.25.

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/80) = 80. 

Pair of Fair Dice, each with face values {1,2,3,4,5,6,7,8,9,10}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D10}*Pr{1 shows from 2^nd D10} = (1/10)*(1/10) = 1/100 = 0.01

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/100) = 1.

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/100) = 100. 

 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,12} and one with face values {1,2,3,4,5,6,7,8}

 

Pr{(1,1) shows} = Pr{1 shows from D12}*Pr{1 shows from D8} = (1/12)*(1/8) = 1/96 @ 0.0104

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/96) @ 1.04.

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/96) = 96. 

 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,12} and one with face values {1,2,3,4,5,6,7,8,9,10}

 

Pr{(1,1) shows} = Pr{1 shows from D12}*Pr{1 shows from D10} = (1/12)*(1/10) = 1/120 @ 0.00833

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/120) @ 0.833.

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/120) = 120. 

 

Pair of Fair Dice, each with face values {1,2,3,4,5,6,7,8,9,10,11,12}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D12}*Pr{1 shows from 2^nd D12} = (1/12)*(1/12) = 1/144 @ 0.006944444

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/144) @ . 6944444

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/144) = 144. 

 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20} and one with face values {1,2,3,4,5,6,7,8,9,10}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D20}*Pr{1 shows from 2^nd D10} = (1/20)*(1/10) = 1/200 @ 0.005

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/200) @ .50

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/200) = 200. 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24} and one with face values {1,2,3,4,5,6,7,8,9,10}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D24}*Pr{1 shows from 2^nd D10} = (1/24)*(1/10) = 1/240 @ 0.0042

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/240) @ .42

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/240) = 240. 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,27,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30} and one with face values {1,2,3,4,5,6,7,8,9,10}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D30}*Pr{1 shows from 2^nd D10} = (1/30)*(1/10) = 1/300 @ 0.003333

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/300) @ 0.03333

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/300) = 300. 

Pair of Fair Dice, each with face values {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20}

 

Pr{(1,1) shows} = Pr{1 shows from 1^st D20}*Pr{1 shows from 2^nd D20} = (1/20)*(1/20) = 1/400 @ 0.0025

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/400) @ 0.25

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/400) = 400. 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24} and one with face values {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20}

Pr{(1,1) shows} = Pr{1 shows from 1^st D24}*Pr{1 shows from 2^nd D20} = (1/24)*(1/20) = 1/480 @ 0.0021

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/480) @ 0.21

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/480) = 480. 

Pair of Fair Dice, each with face values {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24}

Pr{(1,1) shows} = Pr{1 shows from 1^st D24}*Pr{1 shows from 2^nd D24} = (1/24)*(1/24) = 1/576 @ 0.0017

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/576) @ 0.17

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/576) = 576. 

Pair of Fair Dice, one with face values {1,2,3,4,5,6,7,8,9,10,11,27,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30} and one with face values {1,2,3,4,5,6,7,8,9,10,11,27,13,14,15,16,17,18,19,24}

Pr{(1,1) shows} = Pr{1 shows from 1^st D30}*Pr{1 shows from 2^nd D24} = (1/30)*(1/24) = 1/720 @ 0.0014

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/720) @ 0.14

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/720) = 720. 

Pair of Fair Dice, each with face values {1,2,3,4,5,6,7,8,9,10,11,27,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30}

Pr{(1,1) shows} = Pr{1 shows from 1^st D30}*Pr{1 shows from 2^nd D30} = (1/30)*(1/30) = 1/900 @ 0.001111111

In random samples of 100 tosses of the pair of dice, we expect approximately 100*Pr{(1,1)} = 100*(1/900) @ 0. 1111111

The smallest sample size for which we expect to observe one or more tosses showing the pair (1,1) is 1/(1/900) = 900. 

Tracking The Pair (1,1) in Random Samples of n=100

Samples

6.30 Samples for n=100
Pair	#{(1,1)}	Pr{(1,1)}	Min Sample for Pr{(1,1))	E100	Rare?	Unusual Result?
2d4	2	0.0625	16	6.25	No	No
2d5	3	0.04	25	4	No	No
2d8	1	0.015625	64	1.5625	Borderline	No
2d10	0	0.01	100	1	Borderline	No
2d20	0	0.0025	400	0.25	Yes	No
2d30	1	0.001111111	900	0.111111111	Yes	Yes
2d30	0	0.001111111	900	0.111111111	Yes	No
8.00 Samples for n=100
Pair	#{(1,1)}	Pr{(1,1)}	Min Sample for Pr{(1,1))	E100	Rare?	Unusual Result?
d4d6	9	0.041666667	24	4.166666667	No	No
d6d6	2	0.027777778	36	2.777777778	No	No
d8d10	1	0.0125	80	1.25	Borderline	No
d12d12	0	0.006944444	144	0.694444444	Yes	No
d24d24	0	0.001736111	576	0.173611111	Yes	No
d30d20	0	0.001666667	600	0.166666667	Yes	No

When an event is rare relative to a sample size, the occurrence of that event in samples of that size will be irregular.

At this point, work through all Part One (Fall and Spring) Case Types except Conditional Probability, unless you’re working ahead. Work one case type at a time. The only new cases left involve conditional probability.

A Partial List of Part One Probability Case Types

 

ÖLong Run Argument/Perfect Samples – should be finished

ÖProbability Rules – should be finished, except for the conditional probability bits

ÖColor Slot Machine – should be finished, except for the conditional probability bits

 

ÖPairs of Dice – should be nearly finished, except for the conditional probability bits

ÖRandom Variables – should be nearly finished, except for the conditional probability bits

 

Next  Case Types:

 

Conditional Probability

Clinical Trial Sketch

Design Fault Spot