proof of addition formula of exp

The addition formula

$$e^{z_1+z_2}=e^{z_1}{e}^{z_2}$$

of the complex exponential function may be proven by applying Cauchy multiplication rule to the Taylor series expansions (http://planetmath.org/TaylorSeries) of the right side factors (http://planetmath.org/Product).  We present a proof which is based on the derivative of the exponential function.

Let $a$ be a complex constant.  Denote  $e^z=w(z)$.  Then  $w^{\prime }(z)\equiv w(z)$.  Using the product rule and the chain rule we calculate:

$$\frac{d}{d{z}_1}[w(z_1)w(a-z_1)]=w^{\prime }(z_1)w(a-z_1)+w(z_1)w^{\prime }(a-z_1)(-1)=e^{z_1}{e}^{a-z_1}-e^{z_1}{e}^{a-z_1}\equiv 0$$

Thus we see that the product  $w(z_1)w(a-z_1)=e^{z_1}{e}^{a-z_1}$  must be a constant $A$.  If we choose specially  $z_1=0$,  we obtain:

$$A=w(0)w(a-0)=e^0{e}^a=e^a$$

Therefore

$$e^{z_1}{e}^{a-z_1}\equiv e^a.$$

If we denote  $a-z_1:=z_2$, the preceding equation reads  $e^{z_1}{e}^{z_2}=e^{z_1+z_2}$. Q.E.D.