91Ó°ÊÓ

The given function is $\frac{2z+3}{z+2}$.

For the complex function $f\left(z\right)=f(x+iy)=u(x,y)+iv(x,y)$, where $u(x,y)$is the real part and $v(x,y)$is the imaginary part, to be analytic the conditions are $\frac{∂u}{∂x}=\frac{∂y}{∂y}$and $\frac{∂v}{∂x}=-\frac{∂u}{∂y}$.

Substitute $z=x+iy$in $\frac{2z+3}{z+2}$and simplify.

role="math" $$\begin{gathered} \frac{2z+3}{z+2}=\frac{2(x+iy)+3}{(x+iy)+2} \\ =\frac{(2x+3)+2iy}{(x+2)+iy} \end{gathered}$$

Multiply numerator and denominator by $(x+2)-iy$:

$$\begin{gathered} \frac{2z+3}{z+2}=\frac{\left[(2x+3)+2iy\right]\left[(x+2)-iy\right]}{\left[(x+2)+iy\right]\left[(x+2)-iy\right]} \\ =\frac{\left[(2x+3)(x+2)-iy(2x+3)+2iy(x+2)-2i^2{y}^2\right]}{\left[{(x+2)}^2-i^2{y}^2\right]} \\ =\frac{(2x^2+4x+3x+6)+i(-2xy-3y+2xy+4y)2y^2}{{(x+2)}^2+y^2} \\ =\frac{(2x^2+2y^2+7x+6)+iy}{{(x+2)}^2+y^2} \end{gathered}$$

Simplify the equation further gives:

$\frac{(2x^2+2y^2+7x+6)+iy}{{(x+2)}^2+y^2}=\frac{(2x^2+2y^2+7x+6)}{{(x+2)}^2+y^2}+i\frac{y}{{(x+2)}^2+y^2}$

Hence, the real part of the given function is $u(x,y)=\frac{(2x^2+2y^2+7x+6)}{{(x+2)}^2+y^2}$ and the imaginary part is$v(x,y)=\frac{y}{{(x+2)}^2+y^2}$.

Substitute the values of $u$and $v$in $\frac{∂u}{∂x}=\frac{∂v}{∂y}$and $\frac{∂v}{∂x}=-\frac{∂u}{∂y}$and simplify.

role="math" $$\begin{gathered} \frac{∂u}{∂x}=\frac{\left[{(x+2)}^2+y^2\right](4x+7)-2(x+2)(2x^2+2y^2+7x+6)}{{\left[{(x+2)}^2+y^2\right]}^2} \\ =\frac{x^{2-}{y}^2+4x+4}{{\left[{(x+2)}^2+y^2\right]}^2} \\ \frac{∂u}{∂y}=\frac{\left[{(x+2)}^2+y^2\right]\left(4y\right)-(2x^2+2y^2+7x+6)\left(2y\right)}{{\left[{(x+2)}^2+y^2\right]}^2} \\ =\frac{2xy+4y}{{\left[x+2{)}^2+y^2\right]}^2} \\ \frac{∂u}{∂y}=\frac{\left[x+2{)}^2+y^{2)}\right].0-2(x+2)y}{{\left[{(x+2)}^2+y^2\right]}^2} \\ =\frac{(2xy+4y)}{{\left[{(x+2)}^2+y^2\right]}^2} \\ \frac{∂v}{∂y}=\frac{\left[{(x+2)}^2+y^2\right].1-2y.y}{{\left[{(x+2)}^2+y^2\right]}^2} \\ =\frac{x^2-y^2+4x+4}{{\left[{(x+2)}^2+y^2\right]}^2} \end{gathered}$$

Here, $\frac{∂u}{∂x}=\frac{∂v}{∂y}$and $\frac{∂v}{∂x}=-\frac{∂u}{∂y}$, that is, this function satisfy the Cauchy-Riemann condition except $z=-2$.

Therefore, the given function is analytic everywhere except at$z=-2$