To build the pyramids in Egypt, it is believed that giant causeways were constructed to transport the building materials to the site. One such causeway is said to have been 3000 ft long, with a slope of about 2.3°. How much force would be required to hold a 60-ton monolith on this causeway?


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Trigonometric functions, such as sine, cosine, and tangent, relate the angles of a triangle to the lengths of its sides. In this context, the slope of the causeway can be analyzed using these functions to determine the vertical height and the angle of inclination, which are essential for calculating the force required to hold the monolith.

Understanding forces, particularly weight, is crucial in this scenario. The weight of the monolith, given as 60 tons, can be converted into a force using the equation F = mg, where m is mass and g is the acceleration due to gravity. This force acts downwards and must be countered by the force exerted along the slope of the causeway.

An inclined plane is a flat surface tilted at an angle, which affects how forces are distributed. The force required to hold an object on an incline can be calculated using the formula F = W * sin(θ), where W is the weight of the object and θ is the angle of the incline. This concept is vital for determining how much force is needed to keep the monolith stationary on the slope.