Real exponential function/Representation/Continuation/Remark

There is another way to introduce the exponential function ${\displaystyle {}x\mapsto a^{x}}$ to base ${\displaystyle {}a>0}$. For a natural number ${\displaystyle {}n\neq 0}$, one takes the ${\displaystyle {}n}$th product of ${\displaystyle {}a}$ with itself as definition for ${\displaystyle {}a^{n}}$. For a negative integer ${\displaystyle {}x}$, one sets ${\displaystyle {}a^{x}:=(a^{-x})^{-1}}$. For a positive rational number ${\displaystyle {}x=r/s}$, one sets

${\displaystyle {}a^{x}:={\sqrt[{s}]{a^{r}}}\,,}$

where one has to show that this is independent of the chosen representation as a fraction. For a negative rational number, one takes again the inverse. For an arbitrary real number ${\displaystyle {}x}$, one takes a sequence ${\displaystyle {}q_{n}}$ of rational numbers converging to ${\displaystyle {}x}$, and defines

${\displaystyle {}a^{x}:=\lim _{n\rightarrow \infty }a^{q_{n}}\,.}$

For this, one has to show that these limits exist and that they are independent of the chosen rational sequence. For the passage from ${\displaystyle {}\mathbb {Q} }$ to ${\displaystyle {}\mathbb {R} }$, the concept of uniform continuity is crucial.