(3) \( \frac{\cos ^{2}\left(180^{\circ}+\theta\right)+\sin \left(\theta-180^{\circ}\right) \sin \left(360^{\circ}+\theta\right)}{\sin \left(90^{\circ}-2 \theta\right)} \) (4) \( \frac{2 \tan \left(x+180^{\circ}\right) \cos \left(720^{\circ}-x\right)}{\cos \left(450^{\circ}+x\right)}+1 \) (5) \( \frac{\cos \left(90^{\circ}-2 x\right)}{2-2 \sin (-x) \cos \left(90^{\circ}+x\right)} \)

Historical Background: The study of trigonometric functions dates back to ancient civilizations, including the Egyptians and Greeks, who utilized geometry to solve astronomical problems. The sine, cosine, and tangent functions were later formalized in the trigonometric tables of the Indian mathematicians around the 5th century. Fast forward to the Renaissance, when mathematicians in Europe further developed these concepts leading to the foundation of modern trigonometry as we know it today! Real-World Application: Trigonometry isn't just for classrooms! It's widely used in fields like engineering, physics, and architecture. For example, when designing buildings or bridges, engineers use trigonometric functions to calculate angles and forces. Additionally, trigonometric principles are essential in navigation and satellite technology, where finding angles helps determine precise locations on Earth. So next time you see a bridge or a satellite orbiting, think of the trigonometric magic at play!