In a triangle $\Delta ABC$, the value of $\cos \left(\frac{B+C}{2}\right)$ in terms of angle $A$.
Show Hint
Whenever you see a sum of two angles divided by two in a triangle problem, immediately think of $90^\circ$ minus the half-angle of the third vertex. This substitution simplifies almost all triangle-based trig identities.
1. Angle Relationship: Starting with the sum of angles:
$$A + B + C = 180^\circ \implies B + C = 180^\circ - A$$
Dividing by 2 gives:
$$\frac{B+C}{2} = 90^\circ - \frac{A}{2}$$
2. Applying the Cosine Function: Apply the cosine ratio to both sides of the equation:
$$\cos\left(\frac{B+C}{2}\right) = \cos\left(90^\circ - \frac{A}{2}\right)$$
3. Using Trigonometric Identities: Using the complementary angle identity $\cos(90^\circ - \theta) = \sin \theta$:
$$\cos\left(90^\circ - \frac{A}{2}\right) = \sin \frac{A}{2}$$
Thus, the value of $\cos \left(\frac{B+C}{2}\right)$ is exactly $\sin \frac{A}{2}$.