Forces & Kinematics: Videos & Practice Problems

In solving one-dimensional motion problems that involve forces, it's essential to integrate the concepts of motion and force. The five key motion variables to remember are initial velocity (\(v_{\text{initial}}\)), final velocity (\(v_{\text{final}}\)), displacement (\(\Delta x\)), time (\(\Delta t\)), and acceleration (\(a\)). When you know three of these variables, you can apply one of the four equations of uniformly accelerated motion (UAM) to find the unknown variable.

On the forces side, the primary variables are force (\(F\)), mass (\(m\)), and acceleration (\(a\)), governed by the equation \(F = ma\). To solve a forces problem, you need to know two of these three variables. In scenarios where both motion and forces are involved, the acceleration variable serves as the common link between the two sets of equations.

For example, consider a 20 kg block on a frictionless surface being pushed and accelerating from rest to a final velocity of 30 m/s over a time period of 6 seconds. To find the applied force, you first draw a free body diagram to identify the forces acting on the block, which include the weight force and the applied force, while noting that there is no friction due to the frictionless surface.

Next, you apply the equation \(F = ma\) to find the applied force. However, since the acceleration is unknown, you can use the motion equations to find it. Using the equation \(v_{\text{final}} = v_{\text{initial}} + at\), you can substitute the known values: \(30 = 0 + a \cdot 6\). Solving for \(a\) gives you \(a = \frac{30}{6} = 5 \, \text{m/s}^2\).

Now that you have the acceleration, you can substitute it back into the force equation: \(F_a = m \cdot a = 20 \cdot 5 = 100 \, \text{N}\). Thus, the magnitude of the applied force pushing the block is 100 newtons. This example illustrates how to effectively combine the principles of forces and motion to solve complex problems.

In this scenario, we analyze a 1,000-kilogram rocket that is accelerating upwards due to thrust. The forces acting on the rocket include the weight force (force of gravity), thrust, and air resistance. The weight force, denoted as \( w \), is calculated as \( w = mg \), where \( g \) is the acceleration due to gravity, typically approximated as \( 10 \, \text{m/s}^2 \). Thus, for our rocket, \( w = 1,000 \, \text{kg} \times 10 \, \text{m/s}^2 = 10,000 \, \text{N} \).

The thrust force, \( F_t \), is given as \( 25,000 \, \text{N} \), while the air resistance, \( F_{\text{air}} \), is \( 5,000 \, \text{N} \). To find the net force acting on the rocket, we consider the upward direction as positive. Therefore, the net force \( F_{\text{net}} \) can be expressed as:

\( F_{\text{net}} = F_t - F_{\text{air}} - w \)

Substituting the known values, we have:

\( F_{\text{net}} = 25,000 \, \text{N} - 5,000 \, \text{N} - 10,000 \, \text{N} = 10,000 \, \text{N} \)

Using Newton's second law, \( F = ma \), we can solve for acceleration \( a \):

\( 10,000 \, \text{N} = 1,000 \, \text{kg} \times a \)

From this, we find:

\( a = \frac{10,000 \, \text{N}}{1,000 \, \text{kg}} = 10 \, \text{m/s}^2 \)

Now that we have the acceleration, we can use kinematic equations to find the final velocity after 20 seconds. The initial velocity \( v_0 \) is \( 0 \, \text{m/s} \), and the time \( t \) is \( 20 \, \text{s} \). We can use the equation:

\( v_f = v_0 + at \)

Substituting the known values:

\( v_f = 0 + (10 \, \text{m/s}^2)(20 \, \text{s}) = 200 \, \text{m/s} \)

Thus, the final velocity of the rocket after 20 seconds is \( 200 \, \text{m/s} \).