Go on. Explore!

lvl 0 • 0 xp

lvl 1

Home Market Decks Interests

AP Physics Mechanics Equations

memorize.ai (lvl 286)

(0)

31 cards

()

Section 1

Preview this deck

Force (Hooke's Law)

Front

1 / 31

Physics

0.0

0 reviews

5			0
4			0
3			0
2			0
1			0

Active users

All-time users

Favorites

Last updated

4 years ago

Date created

Mar 1, 2020

Cards (31)

Section 1

(31 cards)

Force (Hooke's Law)

Front

F(s) = -k∆x

Back

Angular Acceleration

Front

α = ∑𝜏 / I = 𝜏(net) / I

Back

Kinetic Energy

Front

K = ½mv²

Back

Period of Pendulum

Front

T(p) = 2π √𝑙/g

Back

Angular Speed

Front

Ѡ = Ѡ₀ + αt

Back

Force of Friction

Front

F(fric) ≤ µN

Back

Period of a Wave

Front

T = 2π/Ѡ = 1/f

Back

Force

Front

F = dp/dt

Back

Torque

Front

𝜏 = r × F

Back

Position

Front

x = x(max)cos(Ѡt + ϕ)

Back

Period of Spring

Front

T(s) = 2π √m/k

Back

Momentum

Front

p = mv

Back

Gravitational Potential Energy

Front

U(g) = - Gm₁m₂ / r

Back

Work Done on a System

Front

∆E = W = ∫F dr

Back

Rotational Inertia

Front

I = ∫r² dm = ∑mr²

Back

Position

Front

x = x₀ + v₀t + ½at²

Back

Velocity

Front

v = v₀ + at

Back

Elastic Potential Energy

Front

U(s) = ½k(∆x)²

Back

Velocity²

Front

v² = v₀² + 2a(x-x₀)

Back

Gravitational Force

Front

| F(g) | = Gm₁m₂ / r²

Back

Potential Energy

Front

∆U(g) = mg∆h

Back

Rotational Kinetic Energy

Front

K = ½I²Ѡ

Back

Centripetal Acceleration

Front

a(c) = v²/r = Ѡ²r

Back

Power

Front

P = dE / dt

Back

Impulse

Front

J = ∫F dt = ∆p

Back

Power-Velocity Relationship

Front

P = Fv

Back

Angle

Front

θ = θ₀ + Ѡ₀t + ½αt²

Back

Angular Momentum

Front

L = r × p = IѠ

Back

Center of Mass

Front

x(cm) = ∑mx / ∑m

Back

Instantaneous Linear Velocity/Speed

Front

v = rѠ

Back

Acceleration

Front

a = ΣF / m = F(net) / m

Back