1. Impulse from Force-Time Graph
Key Idea:
The impulse is the area under the Force vs. Time curve.
$$ I = \int F \,dt = \text{Area} $$
Strategy:
- Calculate the geometric area of the graph (rectangle, triangle, etc.).
- Set the calculated area equal to Impulse (I).
- Use \( I = \Delta p \) to find the change in velocity: \( v_f = v_i + \frac{I}{m} \).
2. Impulse-Momentum Theorem
Key Idea:
Directly relates force, time, and change in momentum.
$$ F_{avg}\Delta t = \Delta p = m(v_f - v_i) $$
Strategy:
- Identify all known variables (mass, velocities, time, force).
- Plug the knowns into the theorem's equation.
- Solve algebraically for the single unknown variable.
3. Conservation of Momentum
Key Idea:
In an isolated system, total momentum before an event equals total momentum after.
$$ \sum p_i = \sum p_f $$
Strategy:
- Draw "before" and "after" diagrams.
- Sum all momentum vectors before the event.
- Sum all momentum vectors after the event.
- Set them equal and solve for the unknown(s).
4. Perfectly Inelastic Collision
Key Idea:
Objects collide and stick together, moving as one mass.
$$ m_1v_{1i} + m_2v_{2i} = (m_1 + m_2)v_f $$
Strategy:
- Plug in known masses and initial velocities.
- Solve for the common final velocity, \(v_f\).
- If asked, calculate \( \Delta KE = KE_f - KE_i \) to find energy loss.
5. Elastic Collision (1D)
Key Idea:
Objects bounce off each other. Both momentum and kinetic energy are conserved.
$$ v_{1i} - v_{2i} = -(v_{1f} - v_{2f}) $$
Strategy:
- Set up two equations: momentum conservation and the relative velocity equation above.
- Solve the system of two equations for the two unknowns, \(v_{1f}\) and \(v_{2f}\).
6. 2D Collisions
Key Idea:
Momentum is conserved independently in both the x and y directions.
$$ \sum p_{x,i} = \sum p_{x,f} \quad \text{and} \quad \sum p_{y,i} = \sum p_{y,f} $$
Strategy:
- Break all initial velocity vectors into x and y components.
- Set up a momentum conservation equation for each axis.
- Solve the resulting system of two equations for the unknowns.
7. Explosions (Recoil)
Key Idea:
An object breaks apart. Initial momentum is often zero.
$$ 0 = m_1v_{1f} + m_2v_{2f} + ... $$
Strategy:
- The total momentum before the explosion is the same as after (often zero).
- Sum the momenta of all pieces after the explosion.
- Set the sum equal to the initial momentum and solve.
8. Kinetic Energy Loss
Key Idea:
Finding the energy converted to heat, sound, or deformation in a collision.
$$ \Delta KE = KE_f - KE_i $$
Strategy:
- Calculate total system kinetic energy before the collision (\(KE_i\)).
- Calculate total system kinetic energy after the collision (\(KE_f\)).
- Find the difference. A negative result means energy was lost.