Let \(D\) be \(T_ n=\{z=(z_ 1,\ldots,z_ n)\in\mathbb{C}^ n:| z_ j|<1\) for \(j=1,\ldots,n\}\) or \(B_ \alpha=\{z\in\mathbb{C}^ n:\sum^ n_{j=1}| z_ j|^ \alpha<1\}\), where \(\alpha=(\alpha_ 1,\dots,\alpha_ n)\in\mathbb{R}^ n_ +\). The paper is primarily concerned with certain conditions under which some power series (about 0) which represent a holomorphic map \(f\) of \(D\) reduce themselves to monomials. The motivation comes from the classical case in which \(f=P_ k\), when \(D=T_ 1\), \(f(D)\subseteq D\) and \(P_ k\) is one of the terms of \(f\) (so that for some \(a_ k\in\mathbb{C}\), \(P_ k(z)=a_ kz^ k\) for all \(x\in D)\) and the term maps \(D\) onto \(D\) (so that \(| a_ k|=1\), \(k>0)\). The paper has five theorems. Theorem 1 extends (easily) the classical result to the case when \(D=T^ n\). Here (to typically illustrate) \(f=(f_ 1,\dots,f_ n)\), \(f_ s=\sum^{+\infty}_{m=0}P_ m^{[s]}\) on \(D\) where \(P_ m^{[s]}\) is a homogeneous polynomial of degree \(m(m=0,1,\dots,s=1,\dots,n)\) and \(P_ k=(P^{[1]}_{k_ 1},\dots,P^{[n]}_{k_ n})\). It is shown that \(f=P_ k\), under the (frequent) assumptions that \(k\in\mathbb{R}^ n_ +\) and \(P_ k(z)=(z^{k_ 1}_ 1,\dots,z_ n^{k_ n})\) for all \(x\in D\). Theorem 2 extends Schwarz’s lemma to the case when \(f\) maps \(RT_ 1\) into \((1/M)B_ \alpha\) where \(R,M\in\mathbb{R}_ +\). Theorem 3 and 4 consider the case when \(f\) maps \(B_ \alpha\) into \(B_ \gamma\) where \(\gamma=(\alpha_ 1/k_ 1,\dots,\alpha_ n/k_ n)\). The assumption of \(f\) “starting” with \(P_ k\) in Theorem 3 is replaced by the holomorphy of \(f\) on \(\overline B_ \alpha\) in Theorem 4. Theorem 5 is an easy consequence of Theorem 3 and 4 through applying a non-singular linear transformation. [Some apparent misprints may have to be negociated].