Answer to Question #118430 in Complex Analysis for Nii Laryea

After substitution of "w = 3i,\\, z=-3i" we receive:

"3i=\\frac{-3ai+b}{c-3i}\\Longrightarrow 3c\\,i+9=b-3ai" .

Since "a,\\,b,\\,c" are real, we get "b=9,\\,a+c=0" .

Setting "w=10-4i,\\,z=1+4i" we get:

"10-4i=\\frac{(1+4i)a+9}{1+4i-a}\\Longrightarrow 26+36i-a(10-4i)=a(1+4i)+9"

The latter implies that "36\\,i=0" .

Thus, there are no coefficients "a,b,c" satisfying the problem.

(a) We set "w=z" and receive:

"z=\\frac{az+b}{z+c}\\Longrightarrow z^2+(c-a)z-b=0,\\,\\,z\\neq-c"

Setting "z=x+i\\,\\,y" we get

"x^2+2xy\\,i-y^2+(c-a)(x+i\\,\\,y)-b=0" .

The latter leads to

"\\left\\{\\begin{array}{l}\n x^2-y^2+(c-a)x-b=0 \\\\\n2xy+(c-a)y=0\n\\end{array}\\right."

Solving the latter, we get

1. If "D=(a-c)^2+4b>0" then "x=\\frac{a-c\\pm\\sqrt{(a-c)^2+4b}}{2},\\quad y=0" ;
2. If "D=(a-c)^2+4b\\leq 0" then "x=\\frac12(a-c),\\quad y=\\pm\\frac12\\sqrt{-(a-c)^2-4b}."

Now we shall construct a circle for each case.

We set "(x-x_0)^2+(y-y_0)^2=R^2" ,

1. "D=(a-c)^2+4b>0" . Substitution of points yields the following system

"\\left\\{\\begin{array}{l}\n (x_1-x_0)^2+y_0^2=R^2 \\\\\n(x_2-x_0)^2+y_0^2=R^2\n\\end{array}\\right." with "x_1=\\frac{a-c-\\sqrt{(a-c)^2+4b}}{2},\\,\\, x_2=\\frac{a-c+\\sqrt{(a-c)^2+4b}}{2}"

We subtract the first equation from the second and then solve the obtained equation with respect to "x_0" . We receive "x_0=\\frac{x_1+x_2}{2}=a-c." We can then choose an arbitrary "y_0" and "R=\\sqrt{\\frac14(x_1-x_2)^2+y_0^2}" .

2. "D=(a-c)^2+4b\\leq 0" . Substitution of points yields the system:

"\\left\\{\\begin{array}{l}\n (x_1-x_0)^2+(y_1-y_0)^2=R^2 \\\\\n(x_1-x_0)^2+(-y_1-y_0)^2=R^2\n\\end{array}\\right." with "y_1=\\frac12\\sqrt{-(a-c)^2-4b}."

After substracting of the first equation from the second we receive that "y_1y_0=0" .

If "(a-c)^2+4b=0" we can choose arbitrary "x_0,y_0" and set "R=\\sqrt{(x_1-x_0)^2+(y_1-y_0)^2}" . Otherwise, we get "y_0=0" . We choose an arbitrary "x_0" and set "R=\\sqrt{(x_1-x_0)^2+y_1^2}" .

(b) All points on the line can be presented as "z=4+y\\,i" , "y\\in\\mathbb{R}". After acting with the transformation we receive

"w=\\frac{a(4+y\\,i)+b}{4+y\\,i+c}" .

We substitute "y=0,\\,\\,y=1" and receive "w=\\frac{4a+b}{4+c}" , "w=\\frac{(4a+b)(c+4)+1}{(c+4)^2+1}+\\frac{c+4-(4a+b)}{(c+4)^2+1}\\,i"

In general case (arbitrary "a,b,c" ), these two points are not of the form "w=4+\\tilde{y}\\,i" , "{\\tilde{y}}\\in{\\mathbb{R}}" .