- Show how to multiply two linear polynomials $ax+b$ and $cx+d$ using only three multiplications.
Give a divide-and-conquer algorithms for multiplying two polynomials of degree-bound n that runs in time Θ(n^(lg3). The algorithm should divide the input polynomial coefficients into a high half and a low half.

(ax+b)(cx+d)=ac x^2+((a+b)(c+d)-ac-bd)x+bd

We let p and q be the vectors of coefficients of the first and second polynomial P and Q, respectively.

We assume that both of these vectors are of length n=max{ length(P), length(Q)} and we let m=ceil(n/2).

Then P=A x^m+B, where A=p_m+p_(m+1) x+ .... + p_(n-1) x^(n-1-m), B=p_0+p_1 x+ ...s+p_(m-1)x^(m-1) and Q=Cx^m+D, where C=q_m+q_(m+1) x+ ...+ q_(n-1) x^(n-1-m) and D=q_0+q_1 x+ ... + q_(n-1) x^(n-1)=q_0+q_1 x+ ... + q_(m-1) x^(m-1).

Using the previous result, it holds that (Ax^m+B)(Cx^m+D)=AC x^(2m)+((A+B)(C+D)-AC-BD) x^m+BD (1)$.

I found the following algorithm (link)

```
Algorithm(p,q){
n=size(p)
m=ceil(n/2)
if n==1 return p*q
else{
a=p[m,n-1]
b=p[0,m-1]
c=q[m,n-1]
d=q[0,m-1]
tmp1=Algorithm(a+b,c+d)
tmp2=Algorithm(a,c)
tmp3=Algorithm(b,d)
return tmp2<<n+(tmp1-tmp2-tmp3)<<m+tmp3
```

So we suppose that a,b,c,d are vectors, right?

Could you explain me why we make these recursive calls:

```
tmp1=Algorithm(a+b,c+d)
tmp2=Algorithm(a,c)
tmp3=Algorithm(b,d)
```

I haven't really understood it... Also, how could we elsewhise shift a number to the left by a specific number of digits?

Karatsuba multiplication. – Dr. Lutz Lehmann Aug 24 '15 at 11:05