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I have floor(sqrt(floor(x))). Which is true:

  1. The inner floor is redundant.
  2. The outer floor is redundant.
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Why call it a "Floor and Ceiling Question"? –  Renze de Waal May 17 '09 at 21:01
4  
Actually, the following very general result can be proved by extending Elazar Leibovich's idea below: If f(x) is any continuous, monotonically increasing function such that: f(x) is an integer ==> x is an integer, then floor(f(x)) = floor(f(floor(x))) and similarly, ceiling(f(x)) = ceiling(f(ceiling(x))). (Reference: Concrete Mathematics by Graham, Knuth, Patashnik; Pg 71, Eq. 3.10). –  Ashutosh Mehra May 18 '09 at 1:42
    
My next question was to develop a general framework. Thanks for the reference. I will definitely take a look at the findings. –  unj2 May 18 '09 at 2:13
    
@Ashutosh: Btw your blog looks cool. –  unj2 May 18 '09 at 2:16

8 Answers 8

up vote 35 down vote accepted

Obviously the outer floor is not redundant, since for example, sqrt(2) is not an integer, and thus floor(sqrt(2))≠sqrt(2).

It is also easy to see that sqrt(floor(x))≠sqrt(x) for non-integer x. Since sqrt is a monotone function.

We need to find out whether or not floor(sqrt(floor(x)))==floor(sqrt(x)) for all rationals (or reals).

Let us prove that if sqrt(n)<m then sqrt(n+1)<m+1, for integers m,n. It is easy to see that

n<m^2 ⇒ n+1 < m^2+1 < m^2+2m+1 = (m+1)^2

Therefor by the fact that sqrt is montone we have that

sqrt(n) < m -> sqrt(n+1) < m+1 -> sqrt(n+eps)<m+1 for 0<=eps<1

Therefor floor(sqrt(n))=floor(sqrt(n+eps)) for all 0<eps<1 and integer n. Assume otherwise that floor(sqrt(n))=m and floor(sqrt(n+eps))=m+1, and you've got a case where sqrt(n)<m+1 however sqrt(n+eps)>=m+1.

So, assuming the outer floor is needed, the inner floor is redundant.

To put it otherwise it is always true that

floor(sqrt(n)) == floor(sqrt(floor(n)))

What about inner ceil?

It is easy to see that floor(sqrt(n)) ≠ floor(sqrt(ceil(n))). For example

floor(sqrt(0.001))=0, while floor(sqrt(1))=1

However you can prove in similar way that

ceil(sqrt(n)) == ceil(sqrt(ceil(n)))
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Does your solution imply that an inner ceiling would also be redundant? –  unj2 May 17 '09 at 20:46
1  
See updated answer for the case of the ceiling. –  Elazar Leibovich May 17 '09 at 21:13
    
I cant see any problem here. Unless somebody proves otherwise, this is correct. –  unj2 May 17 '09 at 21:28
4  
+1 Nice to see a mathematical proof –  Tom Leys May 17 '09 at 22:53

The inner one is redundant, the outer one of course not.

The outer one is not redundant, because the square root of a number x only results in an integer if x is a square number.

The inner one is redundant, because the square root for any number in the interval [x,x+1[ (where x is an integer) always lies within the interval [floor(sqrt(x)),ceil(sqrt(x))[ and therefore you don't need to floor a number before taking the square root of it, if you are only interested the integer part of the result.

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1  
now that's a nice explanation. +1 –  Peter Perháč May 17 '09 at 20:48
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There were a lot of good proofs but this one is the sweetest. Thanks. –  unj2 May 17 '09 at 20:54
    
Who said there's no whole integer in [sqrt(x),sqrt(x+1)]? If for example sqrt(x)==0.9 and sqrt(x+1)=1.2, then the result of floor(sqrt(floor(x))) might be different than floor(sqrt(x)) –  Elazar Leibovich May 17 '09 at 21:05
    
I'm glad you like it. After reading all the different and well done actual proofs I thought my explanation might be too informal for some tastes. –  Simon Lehmann May 17 '09 at 21:05
    
Wow. Is there a hole in the solution? –  unj2 May 17 '09 at 21:14

Intuitively I believe the inner one is redundant, but I can't prove it.

You're not allowed to vote me down unless you can provide a value of x that proves me wrong. 8-)

Edit: See v3's comment on this answer for proof - thanks, v3!

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I too tried out examples and feel it in my gut that the inner one is redundant but its damn hard to prove that i am correct. –  unj2 May 17 '09 at 20:15
    
Indeed. There was an answer saying the inner one is redundant, but before I could upvote it it got downvoted and deleted. Still, I believe that's the case. –  GSerg May 17 '09 at 20:17
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Can't you just say that floor(sqrt(x)) only changes value on integer values of x? If x is not an integer, then flooring it won't change the integer part of the square root. –  v3. May 17 '09 at 20:22

The inner floor is redundant

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2  
there, i'll give ya the ten points lost :) I was surprised Richie got that many upvotes for an answer like that... –  Peter Perháč May 17 '09 at 20:22
    
Anybody who downvotes me, needs to downvote Richie. I give my answer before him. –  ichiban May 17 '09 at 20:26
1  
Man, people. Leave a comment if you don't like an answer, Also, this answer is short and to the point, and correct. If you down voted this, you probably need a reality check. –  GManNickG May 17 '09 at 22:17

The inner floor is redundant. A proof by contradiction:

Assume the inner floor is not redundant. That would mean that:

floor(sqrt(x)) != floor(sqrt(x+d))

for some x and d where floor(x) = floor(x+d). Then we have three numbers to consider: a = sqrt(x), b = floor(sqrt(x+d)), c = sqrt(x+d). b is an integer, and a < b < c. That means that a^2 < b^2 < c^2, or x < b^2 < x+d. But if b is an integer, then b^2 is an integer. Therefore floor(x) < b^2, and b^2 <= floor(x+d), and then floor(x) < floor(x+d). But we started by assuming floor(x) = floor(x+d). We've reached a contradiction, so our assumption is false, and the inner floor is redundant.

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If x is an integer then the inner floor is redundant.

If x is not an integer then neither are redundant.

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the question really is why for the second part. –  unj2 May 17 '09 at 20:18
1  
So much bla-bla around, while Macker only got it right and concise. –  majkinetor May 17 '09 at 20:41
    
the bla bla was trying to convince ourselves that it is true. –  unj2 May 17 '09 at 20:43
    
Macker is wrong. –  unj2 May 17 '09 at 20:48
    
Your answer was the first to be right and to the point. +1 –  Jose Basilio May 17 '09 at 21:02

The outer floor is not redundant. Counterexample: x = 2.

floor(sqrt(floor(2))) = floor(sqrt(2)) = floor(1.41...)

Without the outer floor the result would be 1.41...

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If the inner floor were not redundant, then we would expect that floor(sqrt(n)) != floor(sqrt(m)), where m = floor(n)

note that n - 1 < m <= n. m is always less than or equal to n

floor(sqrt(n)) != floor(sqrt(m)) requires that the values of sqrt(n) and sqrt(m) differ by at least 1.0

however, there are no values n for which the sqrt(n) differs by at least 1.0 from sqrt(n + 1), since for all values between 0 and 1 the sqrt of that value is < 1 by definition.

thus, for all values n, the floor(sqrt(n)) == floor(sqrt(n + 1)). This is in contradiction to the original assumption.

Thus the inner floor is redundant.

share|improve this answer
    
"floor(sqrt(n)) != floor(sqrt(m)) requires that the values of sqrt(n) and sqrt(m) differ by at least 1.0" doesn't seem to be true, if sqrt(n) = 0.999 and sqrt(m) = 1, their different by far less than 1, however floor(sqrt(n))!=floor(sqrt(m)) –  Elazar Leibovich May 17 '09 at 21:07
    
"note that n <= m < n + 1" That doesn't seem to be true, since floor(n) can be < n –  melfar May 17 '09 at 22:37
    
good points, noted. –  Demi May 17 '09 at 23:40
    
edited in response. –  Demi May 17 '09 at 23:45

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