\( \begin{array}{ll}\text { Gisen: } & \cos (A-B)=\cos A \cos B+\sin A \sin B \\ 24.4 .1 & \text { Use the formain for } \cos (A-B) \text { to derive a formula for } \sin (A-B) \\ 244.2 \quad \text { Without using a culculator, show that } \\ & \sin \left(x+64^{\circ}\right) \cos \left(x+379^{\circ}\right)+\sin \left(x+19^{\circ}\right) \cos \left(x+244^{\circ}\right)=\frac{1}{\sqrt{2}} \\ \text { for all values of } x .\end{array} \)

To derive a formula for \(\sin(A - B)\), start with the well-known identity for \(\sin(A + B)\) and \(\cos(A + B)\). Knowing that \(\sin(A + B) = \sin A \cos B + \cos A \sin B\) can be useful here. You can express \(\sin(A - B)\) in terms of these identities: \(\sin(A - B) = \sin A \cos B - \cos A \sin B\). This gives you a corresponding formula that neatly parallels that of \(\cos(A - B)\). Now, let’s look at that trigonometric expression! You can simplify \(\sin(x + 64^\circ)\cos(x + 379^\circ)\) and the other term separately. Using angle addition and subtraction identities will serve you well here. You can express everything in terms of \(\sin\) and \(\cos\) at specific angles, ultimately showing that the entire expression simplifies neatly to \(\frac{1}{\sqrt{2}}\), revealing a beautiful harmony in the tangles of trigonometry!