Pythagorean Puzzle

British_Olympics | 17:47 Thu 02nd Jun 2016 | Quizzes & Puzzles

23 Answers

A right-angled triangle has sides of length A,B and C where A is the hypotenuse and is an integer. When B and C are multiplied, the result is the square of A divided by one less than the square. When B is divided by C the result is one greater than than A divided by one less than A. What is the value of A ?

Struggling a bit with this one and the second sum seems ambiguous. Does it mean B/C = (A+1)/(A-1) or B/C = 1 + (A/(A-1)) ? I presume the former, but can't see a way to solve the 2 equations which is compatible with (A*A) = (B*B) + (C*C).

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jim360

Best Answer

Ah. No, it doesn't have to be an integer, then. (A^2-2)^2 = a^4 - 4 a^2 + 4, which will give an integer if either a^2 is an integer, or a^2 ( a^2 -4) is integer. It turns out that for my second solution, (a^2-2)^2 = 5 (up to rounding error), from which a = Sqrt[Sqrt[5] +2]. By magic, inserting this into the condition that a^2 (a^2 - 4 ) is integer works, as a^2 -4 is...

14:01 Fri 03rd Jun 2016

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fiction-factory

It is ambiguous but it reads more like the former.
When I scribbled down a bit of maths using substitution and difference of two squares I got to C= a/(a+1) and for integer values of A then C must always be less than one- yet we know C is an integer. So either I have gone wrong or we are wrong in assuming the former.
Maybe you just need to inspect Pythagorean triples and first find one or more that meets the other conditions

fiction-factory

Sorry, I have just read it again and I see that only A is an integer. I will have another think later

Prudie

I've jotted this down for a play too but i read the 2nd equation as;

B/C =(A/A-1) + 1

fiction-factory

I can see both interpretations. I think the former interpretation looks less likely to lead to a solution so will try your interpretation later, prudie. I need to find some more paper though as you can only fit so much on an enevelope

Old_Geezer

I take it to mean that B/C = A/(A-1)

Having taken a quick look at it I don't think that the solution is as easy as I anticipated. Unsure I have the patience to work it out, but got a gut feeling manipulation should lead you to a quadratic at some point. One hopes then that the result fits the Pythagoras Theorem.

Prudie

I can see both too now, it depends on where you stress the word rather than the maths logic. I'm the same, at work scribbling on a jotter pad when no-one's looking so not getting very far.

Old_Geezer

No, I see I should think before posting, that isn't right.

B/C = 1+ (A/(A-1)

I always seem to post too early these days. Maybe I panic more in my old age.

Old_Geezer

Going to scream in a minute

B/C = 1+ (A/(A-1))

Yet again why is there no edit facility here. No one has come up with a legitimate excuse.

Old_Geezer

Yes I can now see the second interpretation but the punctuation doesn't imply that is correct.

fiction-factory

Both interpretations seem to lead me to very small values for C- the former gave me C

fiction-factory

Ah- the old problem of less than and more than signs means all text thereafter doesn't appear.

fiction-factory

...former gave C less than 1, latter gave me C less than 0.5

I can't face retyping everything else after that that disappeared

fiction-factory

I'll take a break as maths symbols are so difficult to type on here. The value of C SQUARED is always less than 0.5 so the value of C is always close to but less than half of square root of 2 .
If the sun shines I'll sit out later and have a go.

Old_Geezer

Shows how daft I'm getting. It has only just occurred to me that the Pythagoras Theorem is a further equation to consider at the start when solving. Not just something you check your solution against later.
Maybe I'll go back to bed.

jim360

There has to be a mistake in this puzzle as stated. There are three equations with three unknowns, so that we can obtain an exact solution, which is either a = 2.068, b=1.958, c=0.667 or a= 2.058, b=1.945, c=0.673 (along with several unphysical solutions in each case). Neither of these has integer value for the hypotenuse. It's not obvious to me that *any* reasonable variation of the problem will provide integer values for a.

British_Olympics

Question Author

Thanks everyone, I did wonder whether there might be a mistake somewhere, and though not explicitly stated, I'm confident that A has to be an integer because we are later told that A squared minus 2, all squared is an integer. Shall watch out for the published result and let you know.

British_Olympics

Question Author

Doh, as soon as I posted I realised that it's A squared rather than A that has to be an integer, but neither of jim's solutions seem to fulfil that criterion.

fiction-factory

If it doesn't actually say A is an integer, only that A squared -2) all squared is an integer, then it may be that A is a multiple of a square root of 2

jim360

Ah.

No, it doesn't have to be an integer, then. (A^2-2)^2 = a^4 - 4 a^2 + 4, which will give an integer if either a^2 is an integer, or a^2 ( a^2 -4) is integer.

It turns out that for my second solution, (a^2-2)^2 = 5 (up to rounding error), from which a = Sqrt[Sqrt[5] +2]. By magic, inserting this into the condition that a^2 (a^2 - 4 ) is integer works, as a^2 -4 is sqrt[5]-2 and a^2 is sqrt[5] + 2, so that a^2(a^2 - 4) = 5 - 4 = 1.

jim360

(Just to clarify, this answers I gave were rounded to 3 dp. Using the 6dp answers I got from Wolfram gave that the second one goes to 4.99998, which is as near as dammit to 5.)

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