Replace the loading by an equivalent resultant force and couple moment acting at point O. Part A : Determine the equivalent resultant force (express your answer in terms of the variables w0, L, and constant pi.) Part B : Determine the couple moment (express your answer in terms of the variables w0, L, and constant pi.)

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### Diagram Explanation for Educational Use #### Description: The diagram depicts a beam subjected to a variable distributed load. The beam is positioned horizontally, with one end at point \( O \) and the other extending to a length \( L \). #### Details: - **Beam**: The horizontal structure is shown as a thick line extending from \( O \) to \( L \). - **Distributed Load**: Illustrated by vertical arrows pointing downward along the top of the beam. The load varies along the length of the beam. - **Load Equation**: The load intensity \( w \) is defined by the equation \( w = w_0 \cos\left(\frac{\pi}{2L} x\right) \). This indicates that the load is a cosine function of the position \( x \), starting from maximum intensity \( w_0 \) at \( x = 0 \) and varying sinusoidally along the beam. - **Axes**: - The vertical line represents the load intensity, marked as \( w \). - The horizontal axis runs along the beam and is labeled with \( x \), representing the position along the beam. - **Origin**: Marked as \( O \), this is the starting point of the beam where \( x = 0 \). This diagram is typically used in structural engineering to analyze the effects of variable loads on beam deflection and stress.