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 #1
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Let S be the number of students who studied and NS be the number of students who did not study

 

We can represent the total number of students (T) with the following equation

 

T = S + N

 

We are given the average scores for each group and the overall class average:

 

Average score for those who studied (AS): AS = 78

 

Average score for those who did not study (ANS): ANS = 54

 

Overall class average (Avg): Avg = 70

 

We can express the total score for all students using the average scores and the number of students in each group:

 

Total score for those who studied (TS): TS = AS * S

 

Total score for those who did not study (TNS): TNS = ANS * NS

 

Total score for the entire class (Total): Total = Avg * T (since Avg represents the average score per student)

 

Since the total score for the entire class is the sum of the scores from each group:

 

Total = TS + TNS

 

We can substitute the expressions for each score:

 

Avg * T = AS * S + ANS * NS

 

Now we can substitute the values we are given:

 

70 * (S + NS) = 78 * S + 54 * NS

We can rearrange the equation to isolate NS (the number of students who did not study):

 

20 * (S + NS) = 24 * S

 

20S + 20NS = 24S

 

-4S = 20NS

 

NS = (-4/20) * S (we can divide both sides by -4 as long as S is not 0, which we can safely assume since there must be at least one student who studied)

 

NS = -(1/5) * S

 

Since NS represents a number of students, it cannot be negative. Therefore, we can flip the signs to get a positive value for the fraction representing the portion of the class that did not study:

 

NS/T = (1/5) * S/T

 

We are interested in the portion of the class that did not study, so we can express this as:

 

Fraction of class who did not study = NS/T = 1/5.

Jul 4, 2024
 #1
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Let's analyze the scenario step-by-step:

 

Initial Flips: We are given that after 2 flips, Erica has more heads than Alan. This can happen in 3 ways:

 

Erica gets HH and Alan gets TT (2 heads for Erica, 0 for Alan).

 

Erica gets HT and Alan gets TT (1 head for Erica, 0 for Alan).

 

Erica gets TH and Alan gets TT (1 head for Erica, 0 for Alan).

 

Remaining Flips: There are 3 remaining flips for each person. Since the coin is fair (each flip has a 50% chance of heads or tails), there are 23=8 possible outcomes for each person's remaining flips.

 

Favorable Outcomes: We only care about the outcomes where Erica maintains more heads than Alan after 5 flips. Consider the 3 initial scenarios:

 

HH vs TT: In this case, Erica needs any combination of heads and tails in her remaining 3 flips. There are 8 possibilities for her flips. For Alan, he cannot have any heads, so he needs all tails. There is only 1 possibility for his flips. So, there are 8⋅1=8 favorable outcomes.

 

HT vs TT: Here, Erica needs at least 2 heads in her remaining flips. There are (23​)+(33​)=3+1=4 ways for her to achieve this (2 heads and 1 tail, or 3 heads). Again, Alan needs all tails, so there is only 1 possibility for his flips. This gives us 4⋅1=4 favorable outcomes.

 

TH vs TT: Similar to HT vs TT, Erica needs at least 2 heads. There are 4 favorable outcomes. Alan still needs all tails, resulting in 1 possibility. So, there are 4⋅1=4 favorable outcomes.

 

Total Favorable Outcomes: Summing up the favorable outcomes from each initial scenario, we get a total of 8+4+4=16 successful outcomes for Erica.

 

Total Outcomes: There are 23=8 possibilities for Erica's remaining flips and 23=8 possibilities for Alan's remaining flips, leading to a total of 8⋅8=64 total outcomes.

 

Probability: The probability that Erica has more heads than Alan after 5 flips is the number of favorable outcomes divided by the total number of outcomes: $ \frac{16}{64} = \frac{1}{4}$.

 

Converting the fraction to relatively prime integers, we have m=1 and n=4. Therefore, m+n=5​.

Jul 1, 2024
 #1
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Jun 22, 2024
 #1
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Jun 22, 2024