Answer to Question #260598 in Algebra for saduni

"1.\\\\\nlim_{\u00a0z->\\infin}\u00a0\\frac{(\ud835\udc4e\ud835\udc67+\ud835\udc4f)^3}{(\ud835\udc67+\ud835\udc51)^3\u00a0}\\\\\n\\text{apply l'hospital rule}\\\\\n=lim_{\u00a0z->\\infin}\u00a0\\frac{3a(\ud835\udc4e\ud835\udc67+\ud835\udc4f)^2}{3(\ud835\udc67+\ud835\udc51)^2}\\\\\n=lim_{\u00a0z->\\infin}\u00a0\\frac{a(\ud835\udc4e\ud835\udc67+\ud835\udc4f)^2}{(\ud835\udc67+\ud835\udc51)^2}\\\\\n\\text{apply l'hospital rule}\\\\\n=lim_{\u00a0z->\\infin}\u00a0\\frac{2a^2(\ud835\udc4e\ud835\udc67+\ud835\udc4f)}{2(\ud835\udc67+\ud835\udc51)}\\\\\n=lim_{\u00a0z->\\infin}\u00a0\\frac{a^2(\ud835\udc4e\ud835\udc67+\ud835\udc4f)}{(\ud835\udc67+\ud835\udc51)}\\\\\n\\text{apply l'hospital rule}\\\\\n=lim_{\u00a0z->\\infin}\u00a0\\frac{a^3}{1}\\\\\n=a^3\\\\\n2.\\\\\nlim_{\u00a0z->1}\u00a0\\frac{1-\\bar z}{1-z}\\\\\n=lim_{\u00a0(x,y)->(1,0)}\u00a0\\frac{1-x+iy}{1-x-iy}\\\\\n\\text{We choose a path such that it satisfy the point (1,0). Let x=my+1 be that path where m is a real number,}\\\\\n=lim_{\u00a0y->0}\u00a0\\frac{1-my-1+iy}{1-my-1-iy}\\\\\n=lim_{\u00a0y->0}\u00a0\\frac{(-m+i)y}{(-m-i)y}\\\\\n=lim_{\u00a0y->0}\u00a0\\frac{(-m+i)}{(-m-i)}\\\\\n=\\text{doesn't exist}\\\\\n\\text{Since, for different value of m, we get different limits.}"