Understanding the Context

1. Equations of Motion (Constant Acceleration)

These are your most essential tools:

• v = u + at
  Instant update: Velocity at any time t, given initial velocity u and constant acceleration a.
  
• s = ut + (1/2)at²
  Quick distance recall: Displacement (s) using initial velocity (u), time (t), and acceleration (a).
  
• v² = u² + 2as
  Acceleration-proof: Find final velocity using displacement (s) and acceleration (a), with no time involved—ideal for timed exams where time data is missing.

Why powerful: Core building block used in nearly every motion problem.

2. Relative Velocity

Understanding motion in different reference frames is critical.

• v_rel = v₁ – v₂
  Relative speed difference: Velocity of object 1 as observed from object 2’s frame, assuming constant velocities.

Key Insights

Why powerful: Helps simplify complex problems involving multiple moving objects—frequent on exam word problems.

3. Distance-Time Graph Analysis

Graphs are exam-friendly visual tools.

• Slope = velocity
  Key insight: A straight line’s steepness directly gives constant velocity; steep lines mean rapid motion.
  
• Area under slope = displacement
  Integral thinking: The area under a velocity-time graph gives total displacement.

Why powerful: Visual formulas speed up calculations and minimize errors.

Final Thoughts

4. Projectile Motion Parameters

Projectile problems often appear in exams; mastering these ratios is key:

• Time of Flight: T = 2u⨯sinθ / g
  
• Horizontal Range: R = (u²sin2θ) / g
  
• Maximum Height: H = (u²sin²θ) / 2g
  
• Time to Peak: t_peak = u⨯sinθ / g

Why powerful: Solving projectile motion problems instantly requires memorizing and combining these equations efficiently.

5. Acceleration from Velocity-Time Graphs

• a = (v – u) / t
  
• Area under graph = ∫v dt = displacement
  
• Slope = acceleration

Why powerful: Interpreting graphs directly from diagrams saves time and avoids guesswork.