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I came across this question: say given two weights 1 and 3, u can weigh 1,2 (by 3-1),3,4 (by 3+1) (using both sides of balance). Now find the minimum number of weights so that you can measure 1 to 1000.

So the answer was 1,3,9,27...

I want to know how do you arrive at such a solution means powers of 3. What is the thought process?

Source: http://classic-puzzles.blogspot.com/search/label/Google%20Interview%20Puzzles

Solution: http://classic-puzzles.blogspot.com/2006/12/solution-to-shopkeeper-problem.html

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Can you give a link to the original question? –  astander Apr 7 '10 at 4:27
You'll need to give a bit more information: how do you measure 2 when you have a 1 and a 3? (I assume you're using scales, in which case I know how it works, but you should spell it out in the question.) –  David Johnstone Apr 7 '10 at 4:30
Let me reform the question: Given a set of integers as input. Take a subset of integers, and apply addition or subtraction randomly. An example is to take 1, 2 and 3, and apply -, +, which then becomes 1 - 2 + 3. Each application produces an integer. The output is a set of all possible applications. Find the minimal input that produce an output set of [1..1000]. –  SiLent SoNG Apr 8 '10 at 8:40

3 Answers 3

up vote 2 down vote accepted

Theorem: You'll need weights 3^0 through 3^N to cover values 1 through S(N) = sum(3^i) for i = 0 to N.


  1. You've given the base case where N = 1.
  2. Now assume this holds for N < M. For the case N = M we'll have weights 3^0=1 through 3^M which we already know covers values up to S(M-1). Consider that by trading sides for each weight on the scale we can express all negative values down to -S(M-1) with these same weights as well. This it will be sufficient to prove that we can express values S(M-1) + 1 through S(M) as 3^M + X where -S(M-1) <= X <= S(M-1). But S(M) = S(M-1) + 3^M so this is clear provided that S(M-1) + 1 >= 3^M - S(M-1). That is, if 3^M <= 1 + 2 * S(M-1) = 1 + sum(2 * 3^i) for i = 0 to M-1. This seems clear to me at the moment, but I've had a few cocktails and a proof wasn't really what you were asking for anyway, so I'll leave this final step as an exercise to the reader.
  3. By induction, QED.
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This u r doing by knowing the answer. But how do u arrive at the solution at the first place. Although a good proof. –  avd Apr 7 '10 at 5:08
There's lots of interesting books on problem solving techniques; entertaining and valuable. In problems like this one, solving a simpler problem first is a good technique. See why it works for N=1, then N=2, and hope that a pattern emerges that you can codify. –  Grumdrig Apr 7 '10 at 19:08

Here is how I had solved the problem. Say you have weights a_1, a_2, ..., a_r.

Now you can weight a weight x is you have

a_i1 + a_i2 + ... + a_ik = x + a_j1 + a_j2 + ... + a_jl

i.e x = Sum e_i * a_i

where e_i is either -1, 0 or 1.

i.e. we need to write each number as a linear combination of the a_i with coefficients 1,0 or -1.

Now we know that we can write any number in base 3 as a combination of powers of 3 with the coefficients(digits) 0,1,2.

A similar fact is that we can also use digits 1, 0 and -1 when we write a number in base 3!

The fact that we need to get all possible numbers leads to the fact that you might possibly be able to use powers of 3.

The puzzle is so constructed that it actually works out well and you can prove it easily.

The same idea can be applied to the similar problem where you have a spring balance (i.e just one pan). Here the coefficients are 0 and 1, and powers of 2 immediately spring to mind.

And another problem:

Suppose I said you had two copies of each weight and a common balance and had to weigh all weights from 1 to 61. Which weights would you choose?

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Assume you have a set of weights using which you can weigh any number up to n. Now you want to expand your set of weights to weight more numbers which means you want to weigh n+1, n+2 and so on. Adding weights n+1, n+2,....,2n would be redundant. The next weight in the series should be the ((sum of all the previous weights) * 2) + 1)

I think you just start at the base case 1, and work your way up. In order to hit the number 2 your choices are {2, 3, 4...} . 4 - 1 can't reach, 2 is redundant. After one more number the pattern emerges.

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