Skip to main content

Start with a question

You’re in a car going down the highway. The speedometer says 100 km/h. Simple, right? Now answer this: are you moving?
  • Compared to the road? Yes, 100 km/h.
  • Compared to the person in the passenger seat? No. Not at all. You’re sitting still next to them.
That’s the first secret of motion: motion is always relative to something else. There’s no such thing as “just moving.” You’re always moving compared to something. Keep that in your pocket. It explains a lot.

Speed vs. velocity (the real difference)

School tells you these are different and then never explains why. Here’s why.

Speed

How fast. Just a number.“I’m going 60 km/h.”

Velocity

How fast and which way. A number plus a direction.“I’m going 60 km/h north.”

Why direction matters

Imagine two cars, both doing 60 km/h, heading straight at each other. Same speed. But they’re about to crash — because their velocities are opposite. Now imagine two cars doing 60 km/h side by side on the highway. Same speed, same velocity. They’ll never crash. Direction isn’t a fussy detail. Direction is the difference between a peaceful drive and a head-on collision. That’s why engineers always track it.
Anything with a direction baked in is called a vector. Anything that’s just a number is a scalar. Velocity = vector. Speed = scalar. You’ll see those words a lot.

Acceleration: the most misunderstood word in physics

In everyday English, “accelerate” means “speed up.” In physics, it means something bigger:
Acceleration = any change in velocity.
That includes:
  • Speeding up (pressing the gas)
  • Slowing down (pressing the brake)
  • Turning (changing direction even at the same speed)
Yes, turning a corner at constant speed is acceleration. That feels weird, but it’s true — because your velocity (which includes direction) is changing.

The feeling test

Here’s a trick: if your body feels pushed into the seat, you’re accelerating.
  • Floor it from a stoplight → pushed back → acceleration.
  • Slam the brakes → pushed forward → acceleration (just negative).
  • Sharp left turn → pushed right → acceleration.
  • Cruising on the highway → no push → no acceleration, even at 120 km/h.
If nothing is pushing you, your velocity isn’t changing. Simple as that.

The three equations that run everything

For an object speeding up at a steady rate, three equations cover almost every problem. Don’t memorize them yet — just read what they mean.
1

Final velocity

v=v0+atv = v_0 + at“My new speed = my old speed + (how hard I’m accelerating × how long I’ve been doing it).”Floor a car at 3 m/s² for 5 seconds and you gained 15 m/s. Obvious when you read it slowly.
2

Distance traveled

d=v0t+12at2d = v_0 t + \tfrac{1}{2} a t^2“How far I went = how far I’d have gone at my old speed + the extra distance from speeding up.”The 12at2\tfrac{1}{2} a t^2 part is the bonus distance you get because you’re getting faster as you go.
3

Velocity from distance

v2=v02+2adv^2 = v_0^2 + 2ad“If I don’t care about time, just distance, here’s how fast I’ll be going.”This one is gold for stopping-distance problems.

A worked example you can actually feel

Problem: You’re stopped at a red light. It turns green. You accelerate at 2 m/s². How fast are you going after 4 seconds, and how far did you travel? Step 1 — picture it. A car going from 0 to something. Pretty boring scene. Good. Step 2 — list what you know.
  • Starting speed v0=0v_0 = 0 m/s (you were stopped)
  • Acceleration a=2a = 2 m/s²
  • Time t=4t = 4 s
Step 3 — pick the recipe. We want final speed → use equation 1. v=0+(2)(4)=8 m/sv = 0 + (2)(4) = 8 \text{ m/s} That’s about 29 km/h. Reasonable for 4 seconds of gentle acceleration. We want distance → use equation 2. d=(0)(4)+12(2)(4)2=16 md = (0)(4) + \tfrac{1}{2}(2)(4)^2 = 16 \text{ m} You covered 16 meters. About 4 car-lengths. Also reasonable.
Notice we never “did physics.” We pictured a car, listed what we knew, and picked the recipe that used those ingredients. That’s the whole skill.

The biggest misconception

“If something is moving, a force must be pushing it.”
False. This is what Aristotle thought for 2,000 years and what your brain still secretly believes. The truth (Newton figured it out): things in motion stay in motion until something stops them. A hockey puck on perfect ice would slide forever. We’ll unpack that on the next page, because it’s the gateway to understanding every force in the universe.

Next: Forces and Newton's Laws

Why things start moving, stop moving, and push back when you push them.