Particularly general
Consider these three algebraic identities
$$(1-x)(1+x+x^2+x^3)\equiv (1-x^4)$$
and
$$(1-x)\big((1+x)(1+x^2)(1+x^4) \big)\equiv (1-x^8)$$
and
$$\cos\left(\frac{x}{2}\right)\cos\left(\frac{x}{4}\right)\cos\left(\frac{x}{8}\right)\cos\left(\frac{x}{16}\right)\equiv\frac{\sin(x)}{16\sin\left(\frac{x}{16}\right)}$$
Prove that they are true for any real number $x$ in the first two cases and any real numbers except multiples of $16\pi$ in the third case.
Use the ideas in your proofs to write down general forms
$$(1-x)(1+x+x^2+x^3+\dots+x^n)\equiv \quad ???$$
and
$$(1-x)\big((1+x)(1+x^2)(1+x^4)\dots(1+x^{2^n}) \big)\equiv \quad ???$$
and
$$\cos\left(\frac{x}{2}\right)\cos\left(\frac{x}{4}\right)\cos\left(\frac{x}{8}\right)\cos\left(\frac{x}{16}\right)\dots \cos\left(\frac{x}{2^n}\right)=\quad ???$$
In each case it is possible to write down 'infinite $n$' limiting identities. What are these, and for which values of $x$ are they valid?
Expand out the brackets in a systematic, organised manner.
You will need to use a double angle trig formula and difference of two squares. Considering $n=1$ might be useful.
There is perhaps no need to provide a proof for your identities if you are very clear in your mind how such a proof would be constructed, although you might wish to produce a proof if interested.
We had three very nice solutions to this challenge from Josh, from CGSB in the UK, Chuyi Yang from KECHG in the UK and Cyrille from France. They were all nice, so we include all three in full . It is well worth looking at all three to see which you prefer mathematically.
Read Cyrille's writeup, which includes proof by induction Cyrille - particularly_general.pdf
Read Chuyi's writeup, which used a proof by generic example idea to justify the full cases Chuyi-Particularly general.pdf
Rather nicely, Josh included his thinking steps in the solution, paying attention to which aspects were 'informal' and which aspects were 'formal', which is precisely how such mathematics should be approached. Josh writes:
To prove identity number one, I started with the LHS of the equation and
attempted manipulations to make it appear identical to the RHS, as
follows:
$$\begin{eqnarray}\mbox{LHS} &=& (1 - x)(1 + x + x^2 + x^3)\\
&=& 1 - x + x - x^2 + x^2 - x^3 + x^3 - x^4\\
&=& 1 - x^4 = \mbox{RHS, as required}\end{eqnarray}$$
I could also see (informally) in my head why this would hold for the nth case. When we multiply by one in the first bracket, we keep all of the powers of $x$ from zero to $n$. When we multiply by $-x$, we add one to all of the powers of $x$ in the bracket and then subtract them. Where there is overlap (from $x$ and $-x$ to $x^n$ and $-x^n$) they cancel immediately, leaving only $+1$ and $- x^{n+1}$ therefore
$$(1 - x)(1 + x + x^2 ... + x^n) =1- x^{n+1}$$
I proved identity number two in a similar manner:
$$\begin{eqnarray}\mbox{LHS} &=& (1 - x)\Big((1 + x)(1 + x^2)(1 + x^4)\Big)\\
&=& (1 - x)\Big((1 + x + x^2 + x^3)(1 + x^4)\Big)\\
&=& (1 - x)(1 + x + x^2 + x^3 + x^4 + x^5 + x^6 + x^7)
&=& 1 - x^8, \mbox{ as required}\end{eqnarray}$$
Again I could see informally why this would hold for the nth case. It is easier to see when we consider line two. When we take $(1 + x + x^2... + x^{2^n - 1})$ and multiply by $(1 + x^{2^n})$, the $1$ preserves all the powers of $x$ from $1$ to $2^n - 1$ and the $x^{2^n}$ adds $2^n$ to the powers so we continue from where we left off at (1)$(x^{2^n}) = x^{2^n}$and continue in increments of $1$ all the way up to $x^{2^n - 1 + 2^n}$, but $2^n + 2^n = 2^{n+1}$ so we finish up going from $x^0 = 1$ up to $x^{2^{n+1} - 1}$, and this is the same form as what we started with and so will continue for all values of $n$. Therefore, we are left with: $$(1 - x)(1 + x + x^2 ... + x^{2^{n+1} - 1})$$ which by the first identity simplifies into $$1 - x^{2^{n+1} - 1 + 1} = 1 - x^{2^{n+1}}$$
So $$(1 - x)(1 + x)(1 + x^2)...(1 + x^{2^n}) = 1 - x^{2^{n+1}}$$
Identity 3 I proved using a reverse method. Here I began with the RHS and
manipulated it repeatedly using the sin double angle formula. Here is what
I did:
Consider sin2A = 2sinAcosA
Therefore sinA = 2sin(A/2)cos(A/2) [1]
Let the RHS denominator = y
Then y = 16sin(x/16)
ycos(x/16) = 8{2sin(x/16)cos(x/16)}
By [1], 2sin(x/16)cos(x/16) = sin(x/8)
So ycos(x/16) = 8sin(x/8)
ycos(x/16)cos(x/8) = 8sin(x/8)cos(x/8) which similarly simplifies:
ycos(x/16)cos(x/8) = 4sin(x/4)
Similarly:
ycos(x/16)cos(x/8)cos(x/4) = 2sin(x/2)
ycos(x/16)cos(x/8)cos(x/4)cos(x/2) = sin(x)
But sin(x) = RHS numerator
Therefore the RHS can be rewritten as:
RHS = {ycos(x/16)cos(x/8)cos(x/4)cos(x/2)} / y
The y's cancel leaving:
RHS = cos(x/16)cos(x/8)cos(x/4)cos(x/2) = LHS as required
Here I reasoned that if we start with any RHS with any binary power outside
and inside the sin function on the denominator we could just repeat the
steps above.
Since we would always end on a multiplication of cos(x/2) in order to
obtain 2cos(x/2)sin(x/2) = sin(x), and begin on a multiplication of
cos(x/[2^n]) where 2^n was the binary power we used in the denominator, we
would have a multiplication in cosines ranging from cos(x/2) down to
cos(x/[2^n]).
Therefore:
cos(x/2)cos(x/4)...cos(x/[2^n]) = sin(x) / [2^n]sin(x/[2^n])
The first general identity holds true for x E R
The second holds true for x E R
The third holds true for x E R, x =/= [2^n]pi (else we would have
sin(n*pi) on the denominator which is always zero so we would have an
undefined fraction).
Why do this problem?
This problem gives practice and insight into manipulating and constructing algebraic identities. It is based upon the idea of 'proof by generic example': the proof method of a particular example encapsulates in a clear way all of the key points of a proof of a more general case. Manipulation of algebraic identities is always good fun and will give very solid general preparation for the more challenging end of school mathematics examinations, such as Further Mathematics and STEP. It can also be used to help students to understand the differences in the uses of direct proof and proof by induction.
Possible approach
Key questions
What is the difference between an identity and an equation?
What method of proof can you use for the specific examples given?
How can you expand the brackets or reduce the terms in a step by step way? Can you see how this procedure might generalise?
Possible extension
Using the ideas gained from solving this problem, can students construct some new identities of their own?
Possible support
Suggest the use of difference of two squares and a trigonometric double angle formula.