If \[ \sin x=\frac{\sqrt5}{3} \] and \(x\) lies in the IInd quadrant, find the values of \[ \cos\frac{x}{2},\quad \sin\frac{x}{2},\quad \tan\frac{x}{2} \]

Solution: Given, \[ \sin x=\frac{\sqrt5}{3} \] Using \[ \sin^2x+\cos^2x=1 \] we get \[ \cos^2x = 1-\left(\frac{\sqrt5}{3}\right)^2 \] \[ = 1-\frac59 \] \[ = \frac49 \] \[ \cos x=\pm\frac23 \] Since \(x\) lies in the IInd quadrant, \[ \cos x<0 \] Therefore, \[ \cos x=-\frac23 \] Now, \[ \cos\frac{x}{2} = \pm\sqrt{\frac{1+\cos x}{2}} \] Substituting the value of \(\cos x\): \[ = \pm\sqrt{ \frac{1-\frac23}{2} } \] \[ = \pm\sqrt{ \frac{\frac13}{2} } \] \[ = \pm\sqrt{\frac16} \] Since \(x\) lies in the IInd quadrant, \[ \frac{x}{2} \] lies in the Ist quadrant, where cosine is positive. Hence, \[ \boxed{ \cos\frac{x}{2} = \frac{1}{\sqrt6} } \] Now, \[ \sin\frac{x}{2} = \pm\sqrt{\frac{1-\cos x}{2}} \] Substituting: \[ = \pm\sqrt{ \frac{1+\frac23}{2} } \] \[ = \pm\sqrt{ \frac{\frac53}{2} } \] \[ = \pm\sqrt{\frac56} \] Since \(\frac{x}{2}\) lies in the Ist quadrant, sine is positive. Therefore, \[ \boxed{ \sin\frac{x}{2} = \sqrt{\frac56} } \] Now, \[ \tan\frac{x}{2} = \frac{\sin\frac{x}{2}}{\cos\frac{x}{2}} \] Substituting values: \[ = \frac{\sqrt{\frac56}}{\sqrt{\frac16}} \] \[ = \sqrt5 \] Hence, \[ \boxed{ \tan\frac{x}{2}=\sqrt5 } \]