Part D: m OCK = .3 8m 35° 35° 10m Дх Theoretical: Released from rest, find Ax and impact speed.

The goal is to find the impact speed and delta X.

The only information I am given is the image. 

All my prof is telling us is to draw a free body diagram of m and find acceleration from that. 

Transcribed Image Text:

**Part D: Physics Problem Explanation** The diagram illustrates a physics scenario involving a block sliding down an inclined plane and then projecting off a horizontal surface. **Details of the Diagram:** - A block of mass \( m \) starts from rest at the top of an inclined plane. - The inclined plane makes an angle of \( 35^\circ \) with the horizontal. - The length of the inclined plane is given as \( 8 \, \text{m} \). - The coefficient of kinetic friction (\( \mu_k \)) between the block and the plane is \( 0.3 \). - After descending the inclined plane, the block moves horizontally across a \( 10 \, \text{m} \) platform before projecting off into free space. **Key Points to Analyze:** 1. **Theoretical Investigation:** - Determine the horizontal distance (\( \Delta x \)) traveled by the block after leaving the platform. - Calculate the impact speed at the moment it leaves the horizontal surface. 2. **Experimental Setup:** - Conduct the experiment using the initial parameters (mass, friction, angle, and distances). - Measure the actual values of \( \Delta x \) and impact speed. - Calculate the percentage error between theoretical predictions and experimental results. This setup provides an opportunity to explore dynamics involving friction, projectile motion, and energy transition from potential to kinetic forms.