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In Spivak's Calculus 3rd Edition, there is an exercise to prove the following:

$x^n - y^n = (x-y)(x^{n-1} + x^{n-2} y + ... + x y^{n-2} + y^{n-1})$

I can't seem to get the answer. Either I've gone wrong somewhere, I'm overlooking something, or both. Here's my (non) proof:

$\begin{align*} x^n - y^n &= (x - y)(x^{n-1} + x^{n-2}y +\cdots+ xy^{n-2} + y^{n-1}) \\ &= x \cdot x^{n-1} + x \cdot x^{n-2} \cdot y + \cdots + x \cdot x \cdot y^{n-2} + x \cdot y^{n-1}\\ &\qquad + (-y) \cdot x^{n-1} + (-y) \cdot x^{n-2} \cdot y + \cdots + (-y) \cdot x \cdot y^{n-2} + (-y) \cdot y^{n-1}\\ &= x^n + x^{n-1} y + \cdots + x^2 y^{n-2} + x y^{n-1} - x^{n-1}y - y^2 x^{n-2} - \cdots- x y^{n-1} - y^n \\ &= x^n + x^2 y^{n-2} - x^{n-2} y^2 - y^n \\ &\neq x^n - y^n \end{align*}$

Is there something I can do with $x^n + x^2 y^{n-2} - x^{n-2} y^2 - y^n$ that I'm not seeing, or did I make a mistake early on?

EDIT:

I should have pointed out that this exercise is meant to be done using nine of the twelve basic properties of numbers that Spivak outlines in his book:

  • Associate law for addition
  • Existence of an additive identity
  • Existence of additive inverses
  • Commutative law for additions
  • Associative law for multiplication
  • Existence of a multiplicative identity
  • Existence of multiplicative inverses
  • Commutative law for multiplication
  • Distibutive law
  • 0
    Use synthetic divison2014-12-01

7 Answers 7

2

Since powers of x and y is always greater than or equal to zero, You can prove it by mathematical induction.

16

Here is the inductive step, presented more conceptually

$\rm\frac{x^{n+1}-y^{n+1}}{x-y}\: =\ x^n\: +\ y\ \frac{x^n-y^n}{x-y}$

So, intuitively, proceeding inductively yields

$\rm\:x^n + y\: (x^{n-1} + y\: (x^{n-2} +\:\cdots\:))\ =\ x^n + y\: x^{n-1} + y^2\: x^{n-2} + \:\cdots $

Use this intuition to compose a formal proof by induction.

  • 1
    It should be possible to prove this using the basic properties of numbers discussed in Spivak's book: Associative law for addition, Existence of an additive identify, Existence of additive inverses, Commutative law for addition, Associative law for multiplication, Existence of a multiplicative identity, Existence of multiplicative inverses, Commutative law for multiplication, and Distributive law.2012-03-07
14

You have everything right except the last line.

Maybe it is easier to do in this order:

$(x−y)\left(x^{n−1}+x^{n−2}y+\cdots+xy^{n−2}+y^{n−1}\right)=\\ =x\cdot x^{n-1}-y\cdot x^{n-1} +x\cdot x^{n−2}y- y\cdot x^{n−2}y+x\cdot x^{n−3}y^2-\cdots\\ \cdots -y\cdot x^2y^{n-3} +x\cdot xy^{n-2}-y \cdot y^{n-1}$

The second term $y\cdot x^{n-1}$ is the same as the third term $x\cdot x^{n−2}y$ except the sign, similarly the 4th and the 5th terms are canceled... So the only terms left are: $x\cdot x^{n-1}$ and $y\cdot y^{n-1}$.

  • 0
    ohhhh I see why you started with $-y*x^2y^n-3$ after the ellipsis and not the $x*x^2y^n-3$... it's because $-y*x^2y^n-3$ cancels with the 2nd to last term because they are =2018-01-17
9

I think it would be easier for you to recall

$\left(1+x+x^2+\cdots+x^{n-1}\right)(x-1) = x^n-1$

and put $x=\dfrac{b}{a}$

$\eqalign{ & \left( {1 + \frac{b}{a} + \frac{{{b^2}}}{{{a^2}}} + \cdots + \frac{{{b^{n - 1}}}}{{{a^{n - 1}}}}} \right)\left( {\frac{b}{a} - 1} \right) = \frac{{{b^n}}}{{{a^n}}} - 1 \cr & \left( {1 + \frac{b}{a} + \frac{{{b^2}}}{{{a^2}}} + \cdots + \frac{{{b^{n - 1}}}}{{{a^{n - 1}}}}} \right)\left( {\frac{{b - a}}{a}} \right) = \frac{{{b^n} - {a^n}}}{{{a^n}}} \cr & {a^{n - 1}}\left( {1 + \frac{b}{a} + \frac{{{b^2}}}{{{a^2}}} + \cdots + \frac{{{b^{n - 1}}}}{{{a^{n - 1}}}}} \right)\left( {b - a} \right) = {b^n} - {a^n} \cr & \left( {{a^{n - 1}} + b{a^{n - 2}} + {b^2}{a^{n - 3}} + \cdots + {b^{n - 1}}} \right)\left( {b - a} \right) = {b^n} - {a^n} \cr} $

A little bit "tidier", so that we know what happens in between the dots...

$\eqalign{ & {x^n} - 1 = \left( {x - 1} \right)\sum\limits_{k = 0}^{n - 1} {{x^k}} \cr & \frac{{{b^n}}}{{{a^n}}} - 1 = \left( {\frac{b}{a} - 1} \right)\sum\limits_{k = 0}^{n - 1} {\frac{{{b^k}}}{{{a^k}}}} \cr & \frac{{{b^n} - {a^n}}}{{{a^n}}} = \left( {\frac{{b - a}}{a}} \right)\sum\limits_{k = 0}^{n - 1} {\frac{{{b^k}}}{{{a^k}}}} \cr & {b^n} - {a^n} = \left( {b - a} \right)\sum\limits_{k = 0}^{n - 1} {{b^k}{a^{n - k - 1}}} \cr} $

6

Your method is sound, you just made a sort of arithmetic mistake. When cancelling or otherwise combining two sequences, try explicitly lining things up to make sure you do it right:

$ \begin{align} x^n &+& x^{n-1} y &+& x^{n-2} y^2 &+& \cdots + x y^{n-1} & \\ &-& x^{n-1} y &-& x^{n-2} y^2 &+& \cdots - x y^{n-1} &+& y^n \end{align} $

I've found that, when shorthand starts becoming awkward and/or error prone, that it really is helpful to switch to summation notation. So, you are trying to prove

$ x^n - y^n = (x-y) \sum_{k=0}^{n-1} x^k y^{n-1-k} $

and the first stem of your work would be

$ \cdots = \left( \sum_{k=0}^{n-1} x^{k+1} y^{n-1-k} \right) - \left( \sum_{k=0}^{n-1} x^{k} y^{n-k} \right)$

and now, we can change the index to line things up: I'm substituting k = j-1:

$ \cdots = \left( \sum_{(j-1)=0}^{n-1} x^{(j-1)+1} y^{n-1-(j-1)} \right) - \left( \sum_{k=0}^{n-1} x^{k} y^{n-k} \right)$ and simplifying

$ \cdots = \left( \sum_{j=1}^{n} x^{j} y^{n-j} \right) - \left( \sum_{k=0}^{n-1} x^{k} y^{n-k} \right)$

and now replacing $j$ with $k$.

$ \cdots = \left( \sum_{k=1}^{n} x^{k} y^{n-k} \right) - \left( \sum_{k=0}^{n-1} x^{k} y^{n-k} \right)$

(can you take it from here?)

5

The $x^2 y^{n-2}$ term from $x \cdot x y^{n-2}$ is cancelled by the term from $(-y) \cdot x^2 y^{n-3}$. Similarly, the $(-y) \cdot x^{n-2} y$ is cancelled by the $x \cdot x^{n-3} y^2$.