News0 min ago
a^b^c=z
3 Answers
This question refers to a Times brainteaser that was published a few years ago.
I never did fully understand the given answer, and something reminded me of it recently.
Original "Times Brainteaser" as set:
===
Unlike "A plus B plus C" and "A times B times C", "A to the B to the C" is ambiguous.
However, sometimes you get the same answer both ways, as I did with my A, B and C.
My A was a whole number greater than one, while B and C were different positive fractions.
My answer was a whole number less than a million, but even if you knew it you could not work out my A, B and C.
What was my answer?
====
The Given Answer was 262,144
I found one way this is derived from A^B^C but no other.
The combination I found is
A = 256 = 4^4
B = 27/8 = (3^3)/(2^3)
C = 2/3
Then (A^B)^C = A^(B^C) = Z = 262,144 = (2^18)
Note that for this B and C: B^C = B*C = 9/4
This B and C can also lead to other solutions where A and Z are integers of the form A = x^4 ; Z = y^9 and Z < 1,000,000 :
If A = 16 = 2^4 then Z = 512 = 2^9
If A = 81 = 3^4 then Z = 19,683 = 3^9
However, as 262,144 can be expressed in several ways
2^18 = 4^9 = 8^6 = 64^3
I was hoping to find another B and C combination that can lead to it - but never did - and still can't.
Can anyone spot another A,B,C where (A^B)^C = A^(B^C) = 262,144
I never did fully understand the given answer, and something reminded me of it recently.
Original "Times Brainteaser" as set:
===
Unlike "A plus B plus C" and "A times B times C", "A to the B to the C" is ambiguous.
However, sometimes you get the same answer both ways, as I did with my A, B and C.
My A was a whole number greater than one, while B and C were different positive fractions.
My answer was a whole number less than a million, but even if you knew it you could not work out my A, B and C.
What was my answer?
====
The Given Answer was 262,144
I found one way this is derived from A^B^C but no other.
The combination I found is
A = 256 = 4^4
B = 27/8 = (3^3)/(2^3)
C = 2/3
Then (A^B)^C = A^(B^C) = Z = 262,144 = (2^18)
Note that for this B and C: B^C = B*C = 9/4
This B and C can also lead to other solutions where A and Z are integers of the form A = x^4 ; Z = y^9 and Z < 1,000,000 :
If A = 16 = 2^4 then Z = 512 = 2^9
If A = 81 = 3^4 then Z = 19,683 = 3^9
However, as 262,144 can be expressed in several ways
2^18 = 4^9 = 8^6 = 64^3
I was hoping to find another B and C combination that can lead to it - but never did - and still can't.
Can anyone spot another A,B,C where (A^B)^C = A^(B^C) = 262,144
Answers
1 to 3 of 3
Best Answer
No best answer has yet been selected by beermagnet. Once a best answer has been selected, it will be shown here.
For more on marking an answer as the "Best Answer", please visit our FAQ.
Thanks for thinking about it D, but I don't think the teaser is looking for cases where B and C can be swapped in the expression. Surely it is the the expression itself that is ambiguous.
A^B^C can be read as (A^B)^C or A^(B^C) which give very different results in most cases.
For (A^B)^C to equal A^(B^C), as (A^B)^C is equivalent to A^(B*C), the cases we need to find are where B^C = B*C which is possible for a few positive fractions.
The most trivial case is B=4 ; C=1/2 B^C=B*C=2
But not many of these B,C pairs are both proper fractions.
Indeed, the only cases I can find are where for fraction C the difference between the denominator and the numerator is 1. These are:
B C Effective power
4 1/2 2
27/8 2/3 9/4
256/81 3/4 64/27
3125/1024 4/5 625/256
etc.
Of these the 27/8, 2/3 case with effective power 9/4 is the only one where both B and C are proper fractions and there is a possible "answer" Z value < 1,000,000
As I said, I never did find any other cases except those where C is of the form n/(n+1) and suspect there aren't any, but haven't proved that. I would be interested to hear of any.
Of course, I might be completely misinterpreting the original question.
A^B^C can be read as (A^B)^C or A^(B^C) which give very different results in most cases.
For (A^B)^C to equal A^(B^C), as (A^B)^C is equivalent to A^(B*C), the cases we need to find are where B^C = B*C which is possible for a few positive fractions.
The most trivial case is B=4 ; C=1/2 B^C=B*C=2
But not many of these B,C pairs are both proper fractions.
Indeed, the only cases I can find are where for fraction C the difference between the denominator and the numerator is 1. These are:
B C Effective power
4 1/2 2
27/8 2/3 9/4
256/81 3/4 64/27
3125/1024 4/5 625/256
etc.
Of these the 27/8, 2/3 case with effective power 9/4 is the only one where both B and C are proper fractions and there is a possible "answer" Z value < 1,000,000
As I said, I never did find any other cases except those where C is of the form n/(n+1) and suspect there aren't any, but haven't proved that. I would be interested to hear of any.
Of course, I might be completely misinterpreting the original question.
1 to 3 of 3
Latest Posts
Film, Media & TV0 min ago
ChatterBank1 min ago
ChatterBank6 mins ago
Quizzes & Puzzles11 mins ago
Related Questions
Sorry, we can't find any related questions. Try using the search bar at the top of the page to search for some keywords, or choose a topic and submit your own question.