What is the probability of making a cake?












2












$begingroup$


The question:



We are given 6 different ingredients. 2 types of flours, 2 types of sugars, and 2 identical eggs.



$$F_1,F_2,S_1,S_2,E,E$$



We choose 3 items at random, we mix them, and throw them into the oven.



A) What is the sample space of the question



B) What is the probability we make a cake (flour + sugar + egg)



My attempt:



A) This would just be all permutations of possible choices, the size of the sample space would be 6 choose 3 (although I don't think this is correct because the eggs are identical)





How would I solve question B?










share|cite|improve this question











$endgroup$












  • $begingroup$
    You should use the term "permutations" to only refer to things which are very specifically permutations, bijective functions from a set to itself or equivalently strings of $n$ distinct characters where each character occurs exactly once. The term has been misused and has come to mean any string of characters of whatever length in some cases, but even in that case the order of the letters as they appear still matter. In your case the order does not. Call these instead "combinations" or "outcomes."
    $endgroup$
    – JMoravitz
    1 hour ago


















2












$begingroup$


The question:



We are given 6 different ingredients. 2 types of flours, 2 types of sugars, and 2 identical eggs.



$$F_1,F_2,S_1,S_2,E,E$$



We choose 3 items at random, we mix them, and throw them into the oven.



A) What is the sample space of the question



B) What is the probability we make a cake (flour + sugar + egg)



My attempt:



A) This would just be all permutations of possible choices, the size of the sample space would be 6 choose 3 (although I don't think this is correct because the eggs are identical)





How would I solve question B?










share|cite|improve this question











$endgroup$












  • $begingroup$
    You should use the term "permutations" to only refer to things which are very specifically permutations, bijective functions from a set to itself or equivalently strings of $n$ distinct characters where each character occurs exactly once. The term has been misused and has come to mean any string of characters of whatever length in some cases, but even in that case the order of the letters as they appear still matter. In your case the order does not. Call these instead "combinations" or "outcomes."
    $endgroup$
    – JMoravitz
    1 hour ago
















2












2








2





$begingroup$


The question:



We are given 6 different ingredients. 2 types of flours, 2 types of sugars, and 2 identical eggs.



$$F_1,F_2,S_1,S_2,E,E$$



We choose 3 items at random, we mix them, and throw them into the oven.



A) What is the sample space of the question



B) What is the probability we make a cake (flour + sugar + egg)



My attempt:



A) This would just be all permutations of possible choices, the size of the sample space would be 6 choose 3 (although I don't think this is correct because the eggs are identical)





How would I solve question B?










share|cite|improve this question











$endgroup$




The question:



We are given 6 different ingredients. 2 types of flours, 2 types of sugars, and 2 identical eggs.



$$F_1,F_2,S_1,S_2,E,E$$



We choose 3 items at random, we mix them, and throw them into the oven.



A) What is the sample space of the question



B) What is the probability we make a cake (flour + sugar + egg)



My attempt:



A) This would just be all permutations of possible choices, the size of the sample space would be 6 choose 3 (although I don't think this is correct because the eggs are identical)





How would I solve question B?







probability combinatorics combinations






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited 1 hour ago







AlanSTACK

















asked 1 hour ago









AlanSTACKAlanSTACK

1,71121323




1,71121323












  • $begingroup$
    You should use the term "permutations" to only refer to things which are very specifically permutations, bijective functions from a set to itself or equivalently strings of $n$ distinct characters where each character occurs exactly once. The term has been misused and has come to mean any string of characters of whatever length in some cases, but even in that case the order of the letters as they appear still matter. In your case the order does not. Call these instead "combinations" or "outcomes."
    $endgroup$
    – JMoravitz
    1 hour ago




















  • $begingroup$
    You should use the term "permutations" to only refer to things which are very specifically permutations, bijective functions from a set to itself or equivalently strings of $n$ distinct characters where each character occurs exactly once. The term has been misused and has come to mean any string of characters of whatever length in some cases, but even in that case the order of the letters as they appear still matter. In your case the order does not. Call these instead "combinations" or "outcomes."
    $endgroup$
    – JMoravitz
    1 hour ago


















$begingroup$
You should use the term "permutations" to only refer to things which are very specifically permutations, bijective functions from a set to itself or equivalently strings of $n$ distinct characters where each character occurs exactly once. The term has been misused and has come to mean any string of characters of whatever length in some cases, but even in that case the order of the letters as they appear still matter. In your case the order does not. Call these instead "combinations" or "outcomes."
$endgroup$
– JMoravitz
1 hour ago






$begingroup$
You should use the term "permutations" to only refer to things which are very specifically permutations, bijective functions from a set to itself or equivalently strings of $n$ distinct characters where each character occurs exactly once. The term has been misused and has come to mean any string of characters of whatever length in some cases, but even in that case the order of the letters as they appear still matter. In your case the order does not. Call these instead "combinations" or "outcomes."
$endgroup$
– JMoravitz
1 hour ago












2 Answers
2






active

oldest

votes


















2












$begingroup$

In an attempt to make the problem easier to calculate, we may choose to take one of the two identical eggs and mark it with a foodsafe marker of some sort. Now, the eggs are in fact distinguishable. In this way we would have $binom{6}{3}$ outcomes in our sample space. We generally choose to do this because we have that each of these $binom{6}{3}=20$ outcomes are equally likely to occur (given the most common interpretation of the problem).



If you insist that you want to look at the sample space as being where the eggs are treated as identical, you will have overcounted each outcome where exactly one egg appears twice each when we wanted to count them only once. There are $binom{4}{2}=6$ such outcomes being overcounted. This drops our sample space down to size $binom{6}{3}-binom{4}{2}=14$. This is not a useful sample space for performing calculations with however since the outcomes are not equally likely to occur. It is far more likely to have an outcome of $(F_1, S_1, E)$ than $(F_1, E, E)$ (specifically it is twice as likely to occur).



Remember that if we want to use $Pr(E) = dfrac{|E|}{|S|}$, we require that each outcome in the sample space be equally likely to occur. There are only two outcomes to playing the lottery, you either win or you lose. The probability of winning the lottery is nowhere close to $frac{1}{2}$ however despite this.





Making the proposed simplification to the problem where we mark one of the eggs ahead of time, we count how many outcomes will actually result in one of each type of ingredient being used. There are $2$ ways to select which flour is used, $2$ ways to select the sugar, and $2$ ways to select the egg. Multiplying the number of options for each gives the total number of arrangements of one of each type as per the rule of product. This yields $2times 2times 2=8$ ways to select one from each ingredient type.



Dividing by the size of the sample space (remembering that this sample space was chosen specifically because it is an equiprobable sample space that fully describes the event we are interested in), gives us the probability:



$$frac{8}{20}=0.4$$






share|cite|improve this answer









$endgroup$













  • $begingroup$
    I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
    $endgroup$
    – AlanSTACK
    1 hour ago










  • $begingroup$
    @AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
    $endgroup$
    – JMoravitz
    1 hour ago












  • $begingroup$
    You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
    $endgroup$
    – AlanSTACK
    1 hour ago












  • $begingroup$
    @AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
    $endgroup$
    – JMoravitz
    1 hour ago



















4












$begingroup$

The probability you make a cake is equal to the number of three-ingredient combinations in the space that form a cake (flour + sugar + egg), divided by the total number of three-ingredient combinations in the space. The total number of three-ingredient combinations is 20 (= 6 choose 3), and because you have two possibilities for each of flour, sugar, and egg, the number of three-ingredient-combinations that make a cake is 2*2*2 = 8. So the probability of making a cake is 8 / 20, or 2/5 = 40%.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
    $endgroup$
    – AlanSTACK
    1 hour ago











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2 Answers
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2 Answers
2






active

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active

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2












$begingroup$

In an attempt to make the problem easier to calculate, we may choose to take one of the two identical eggs and mark it with a foodsafe marker of some sort. Now, the eggs are in fact distinguishable. In this way we would have $binom{6}{3}$ outcomes in our sample space. We generally choose to do this because we have that each of these $binom{6}{3}=20$ outcomes are equally likely to occur (given the most common interpretation of the problem).



If you insist that you want to look at the sample space as being where the eggs are treated as identical, you will have overcounted each outcome where exactly one egg appears twice each when we wanted to count them only once. There are $binom{4}{2}=6$ such outcomes being overcounted. This drops our sample space down to size $binom{6}{3}-binom{4}{2}=14$. This is not a useful sample space for performing calculations with however since the outcomes are not equally likely to occur. It is far more likely to have an outcome of $(F_1, S_1, E)$ than $(F_1, E, E)$ (specifically it is twice as likely to occur).



Remember that if we want to use $Pr(E) = dfrac{|E|}{|S|}$, we require that each outcome in the sample space be equally likely to occur. There are only two outcomes to playing the lottery, you either win or you lose. The probability of winning the lottery is nowhere close to $frac{1}{2}$ however despite this.





Making the proposed simplification to the problem where we mark one of the eggs ahead of time, we count how many outcomes will actually result in one of each type of ingredient being used. There are $2$ ways to select which flour is used, $2$ ways to select the sugar, and $2$ ways to select the egg. Multiplying the number of options for each gives the total number of arrangements of one of each type as per the rule of product. This yields $2times 2times 2=8$ ways to select one from each ingredient type.



Dividing by the size of the sample space (remembering that this sample space was chosen specifically because it is an equiprobable sample space that fully describes the event we are interested in), gives us the probability:



$$frac{8}{20}=0.4$$






share|cite|improve this answer









$endgroup$













  • $begingroup$
    I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
    $endgroup$
    – AlanSTACK
    1 hour ago










  • $begingroup$
    @AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
    $endgroup$
    – JMoravitz
    1 hour ago












  • $begingroup$
    You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
    $endgroup$
    – AlanSTACK
    1 hour ago












  • $begingroup$
    @AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
    $endgroup$
    – JMoravitz
    1 hour ago
















2












$begingroup$

In an attempt to make the problem easier to calculate, we may choose to take one of the two identical eggs and mark it with a foodsafe marker of some sort. Now, the eggs are in fact distinguishable. In this way we would have $binom{6}{3}$ outcomes in our sample space. We generally choose to do this because we have that each of these $binom{6}{3}=20$ outcomes are equally likely to occur (given the most common interpretation of the problem).



If you insist that you want to look at the sample space as being where the eggs are treated as identical, you will have overcounted each outcome where exactly one egg appears twice each when we wanted to count them only once. There are $binom{4}{2}=6$ such outcomes being overcounted. This drops our sample space down to size $binom{6}{3}-binom{4}{2}=14$. This is not a useful sample space for performing calculations with however since the outcomes are not equally likely to occur. It is far more likely to have an outcome of $(F_1, S_1, E)$ than $(F_1, E, E)$ (specifically it is twice as likely to occur).



Remember that if we want to use $Pr(E) = dfrac{|E|}{|S|}$, we require that each outcome in the sample space be equally likely to occur. There are only two outcomes to playing the lottery, you either win or you lose. The probability of winning the lottery is nowhere close to $frac{1}{2}$ however despite this.





Making the proposed simplification to the problem where we mark one of the eggs ahead of time, we count how many outcomes will actually result in one of each type of ingredient being used. There are $2$ ways to select which flour is used, $2$ ways to select the sugar, and $2$ ways to select the egg. Multiplying the number of options for each gives the total number of arrangements of one of each type as per the rule of product. This yields $2times 2times 2=8$ ways to select one from each ingredient type.



Dividing by the size of the sample space (remembering that this sample space was chosen specifically because it is an equiprobable sample space that fully describes the event we are interested in), gives us the probability:



$$frac{8}{20}=0.4$$






share|cite|improve this answer









$endgroup$













  • $begingroup$
    I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
    $endgroup$
    – AlanSTACK
    1 hour ago










  • $begingroup$
    @AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
    $endgroup$
    – JMoravitz
    1 hour ago












  • $begingroup$
    You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
    $endgroup$
    – AlanSTACK
    1 hour ago












  • $begingroup$
    @AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
    $endgroup$
    – JMoravitz
    1 hour ago














2












2








2





$begingroup$

In an attempt to make the problem easier to calculate, we may choose to take one of the two identical eggs and mark it with a foodsafe marker of some sort. Now, the eggs are in fact distinguishable. In this way we would have $binom{6}{3}$ outcomes in our sample space. We generally choose to do this because we have that each of these $binom{6}{3}=20$ outcomes are equally likely to occur (given the most common interpretation of the problem).



If you insist that you want to look at the sample space as being where the eggs are treated as identical, you will have overcounted each outcome where exactly one egg appears twice each when we wanted to count them only once. There are $binom{4}{2}=6$ such outcomes being overcounted. This drops our sample space down to size $binom{6}{3}-binom{4}{2}=14$. This is not a useful sample space for performing calculations with however since the outcomes are not equally likely to occur. It is far more likely to have an outcome of $(F_1, S_1, E)$ than $(F_1, E, E)$ (specifically it is twice as likely to occur).



Remember that if we want to use $Pr(E) = dfrac{|E|}{|S|}$, we require that each outcome in the sample space be equally likely to occur. There are only two outcomes to playing the lottery, you either win or you lose. The probability of winning the lottery is nowhere close to $frac{1}{2}$ however despite this.





Making the proposed simplification to the problem where we mark one of the eggs ahead of time, we count how many outcomes will actually result in one of each type of ingredient being used. There are $2$ ways to select which flour is used, $2$ ways to select the sugar, and $2$ ways to select the egg. Multiplying the number of options for each gives the total number of arrangements of one of each type as per the rule of product. This yields $2times 2times 2=8$ ways to select one from each ingredient type.



Dividing by the size of the sample space (remembering that this sample space was chosen specifically because it is an equiprobable sample space that fully describes the event we are interested in), gives us the probability:



$$frac{8}{20}=0.4$$






share|cite|improve this answer









$endgroup$



In an attempt to make the problem easier to calculate, we may choose to take one of the two identical eggs and mark it with a foodsafe marker of some sort. Now, the eggs are in fact distinguishable. In this way we would have $binom{6}{3}$ outcomes in our sample space. We generally choose to do this because we have that each of these $binom{6}{3}=20$ outcomes are equally likely to occur (given the most common interpretation of the problem).



If you insist that you want to look at the sample space as being where the eggs are treated as identical, you will have overcounted each outcome where exactly one egg appears twice each when we wanted to count them only once. There are $binom{4}{2}=6$ such outcomes being overcounted. This drops our sample space down to size $binom{6}{3}-binom{4}{2}=14$. This is not a useful sample space for performing calculations with however since the outcomes are not equally likely to occur. It is far more likely to have an outcome of $(F_1, S_1, E)$ than $(F_1, E, E)$ (specifically it is twice as likely to occur).



Remember that if we want to use $Pr(E) = dfrac{|E|}{|S|}$, we require that each outcome in the sample space be equally likely to occur. There are only two outcomes to playing the lottery, you either win or you lose. The probability of winning the lottery is nowhere close to $frac{1}{2}$ however despite this.





Making the proposed simplification to the problem where we mark one of the eggs ahead of time, we count how many outcomes will actually result in one of each type of ingredient being used. There are $2$ ways to select which flour is used, $2$ ways to select the sugar, and $2$ ways to select the egg. Multiplying the number of options for each gives the total number of arrangements of one of each type as per the rule of product. This yields $2times 2times 2=8$ ways to select one from each ingredient type.



Dividing by the size of the sample space (remembering that this sample space was chosen specifically because it is an equiprobable sample space that fully describes the event we are interested in), gives us the probability:



$$frac{8}{20}=0.4$$







share|cite|improve this answer












share|cite|improve this answer



share|cite|improve this answer










answered 1 hour ago









JMoravitzJMoravitz

46.7k33886




46.7k33886












  • $begingroup$
    I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
    $endgroup$
    – AlanSTACK
    1 hour ago










  • $begingroup$
    @AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
    $endgroup$
    – JMoravitz
    1 hour ago












  • $begingroup$
    You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
    $endgroup$
    – AlanSTACK
    1 hour ago












  • $begingroup$
    @AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
    $endgroup$
    – JMoravitz
    1 hour ago


















  • $begingroup$
    I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
    $endgroup$
    – AlanSTACK
    1 hour ago










  • $begingroup$
    @AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
    $endgroup$
    – JMoravitz
    1 hour ago












  • $begingroup$
    You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
    $endgroup$
    – AlanSTACK
    1 hour ago












  • $begingroup$
    @AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
    $endgroup$
    – JMoravitz
    1 hour ago
















$begingroup$
I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
$endgroup$
– AlanSTACK
1 hour ago




$begingroup$
I understand everything in your post except There are (4 choose 2) such outcomes being over counted. How did you get that number?
$endgroup$
– AlanSTACK
1 hour ago












$begingroup$
@AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
$endgroup$
– JMoravitz
1 hour ago






$begingroup$
@AlanSTACK Suppose you have exactly one egg in your selection. You still need $2$ more ingredients chosen to bring your total number of ingredients chosen up to $3$. There are $4$ non-egg ingredients left available to choose from of which you want to choose $2$ of them. There are $binom{4}{2}$ (read aloud as "4 choose 2") number of ways to do so. Now, note that for each selection with exactly one egg where the eggs were considered identical corresponds to two different outcomes if the eggs were marked, once where $E$ was replaced by $E_1$ and again where $E$ was replaced by $E_2$.
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– JMoravitz
1 hour ago














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You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
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– AlanSTACK
1 hour ago






$begingroup$
You have already answered my question, but out of curiosity. If the selection was $F_1, F_2, S, S, E, E$ (the different sugars were identical too). Would the sample space then be (6 choose 3) - (3 choose 2) - (3 choose 2)?
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– AlanSTACK
1 hour ago














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@AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
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– JMoravitz
1 hour ago




$begingroup$
@AlanSTACK Hmm... For this, I'd probably brute force the count honestly. Some outcomes will have been overcounted four times: $(F_1, S, E)$ corresponds to each of $(F_1, S_1, E_1), (F_1, S_1, E_2),dots (F_1, S_2, E_2)$, so I don't think it would be as easy as the expression you write. By my count I see $2+3+3+2=10$ outcomes there, not equal to the expression you wrote.
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– JMoravitz
1 hour ago











4












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The probability you make a cake is equal to the number of three-ingredient combinations in the space that form a cake (flour + sugar + egg), divided by the total number of three-ingredient combinations in the space. The total number of three-ingredient combinations is 20 (= 6 choose 3), and because you have two possibilities for each of flour, sugar, and egg, the number of three-ingredient-combinations that make a cake is 2*2*2 = 8. So the probability of making a cake is 8 / 20, or 2/5 = 40%.






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  • $begingroup$
    I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
    $endgroup$
    – AlanSTACK
    1 hour ago
















4












$begingroup$

The probability you make a cake is equal to the number of three-ingredient combinations in the space that form a cake (flour + sugar + egg), divided by the total number of three-ingredient combinations in the space. The total number of three-ingredient combinations is 20 (= 6 choose 3), and because you have two possibilities for each of flour, sugar, and egg, the number of three-ingredient-combinations that make a cake is 2*2*2 = 8. So the probability of making a cake is 8 / 20, or 2/5 = 40%.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
    $endgroup$
    – AlanSTACK
    1 hour ago














4












4








4





$begingroup$

The probability you make a cake is equal to the number of three-ingredient combinations in the space that form a cake (flour + sugar + egg), divided by the total number of three-ingredient combinations in the space. The total number of three-ingredient combinations is 20 (= 6 choose 3), and because you have two possibilities for each of flour, sugar, and egg, the number of three-ingredient-combinations that make a cake is 2*2*2 = 8. So the probability of making a cake is 8 / 20, or 2/5 = 40%.






share|cite|improve this answer









$endgroup$



The probability you make a cake is equal to the number of three-ingredient combinations in the space that form a cake (flour + sugar + egg), divided by the total number of three-ingredient combinations in the space. The total number of three-ingredient combinations is 20 (= 6 choose 3), and because you have two possibilities for each of flour, sugar, and egg, the number of three-ingredient-combinations that make a cake is 2*2*2 = 8. So the probability of making a cake is 8 / 20, or 2/5 = 40%.







share|cite|improve this answer












share|cite|improve this answer



share|cite|improve this answer










answered 1 hour ago









user326210user326210

9,102726




9,102726












  • $begingroup$
    I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
    $endgroup$
    – AlanSTACK
    1 hour ago


















  • $begingroup$
    I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
    $endgroup$
    – AlanSTACK
    1 hour ago
















$begingroup$
I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
$endgroup$
– AlanSTACK
1 hour ago




$begingroup$
I don't think my attempt is even correct. Since the eggs are identical. In addition, I don't really understand what you mean by the number of three-ingredient-combinations that make a cake is 2*2*2 = 8 Could you elaborate on that?
$endgroup$
– AlanSTACK
1 hour ago


















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