Answer to Question #114836 in Real Analysis for Sheela John

Let "\\{a_n\\}" be the decreasing sequence of positive terms. Suppose "\\sum_{n=1}^{\\infty} a_n \\sin(nx)"  converges uniformly and let the first "n" partial sum of the given series be "S_{n}(x)=\\sum_{r=1}^{n} a_r \\sin(rx)" , By the hypothesis "S_{n}(x)" converges uniformly.Now by Cauchy's criteria of uniform convergence, for every "\\epsilon >0,\\exist N\\in \\mathbb{N}" such that "n\\geq N , m \\geq N" for sufficiently large "m,n \\implies"

"|S_{n}(x)-S_{m}(x)|<\\epsilon , \\forall x \\in \\mathbb{R}" "\\iff" "|\\sum_{r=m+1}^{n} a_r \\sin(rx)|<\\sum_{r=m+1}^{n}|a_r \\sin(rx)|" (since, from general triangle inequality),thus

"|\\sum_{r=m+1}^{n} a_r \\sin(rx)|<\\sum_{r=m+1}^{n}|a_r \\sin(rx)|=\\sum_{r=m+1}^{n}|a_r|| \\sin(rx)|" .We also know that, always "|\\sin(rx)|<1" "\\iff \\sum_{r=m+1}^{n} |a_r||\\sin(rx)|<\\sum_{r=m+1}^{n} |a_r|=\\sum_{r=m+1}^{n} a_r" (since, "a_r >0 ,\\forall r \\in \\mathbb{N}" .Hence choose "\\epsilon = \\sum_{r=m+1}^{n} a_r \\iff \\epsilon = \\sum_{r=m+1}^{n} a_r> a_n (n-m)" ("\\because \\{a_n\\}" is decreasing sequence),thus "a_n \\rightarrow 0 ," as "n \\rightarrow \\infty" (since, "\\epsilon" is finite positive real number).

Hence, we are done.