List of equations in classical mechanics
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This page gives a summary of important equations in classical mechanics.
Contents |
[edit] Nomenclature
- a = acceleration (m/s²)
- g = gravitational constant (m/s²)
- F = force (N = kg m/s²)
- Ek = kinetic energy (J = kg m²/s²)
- Ep = potential energy (J = kg m²/s²)
- m = mass (kg)
- p = momentum (kg m/s)
- s = position (m)
- R = radius (m)
- t = time (s)
- v = velocity (m/s)
- v0 = velocity at time t=0
- W = work (J = kg m²/s²)
- τ = torque (m N, not J) (torque is the rotational form of force)
- s(t) = position at time t
- s0 = position at time t=0
- runit = unit vector pointing from the origin in polar coordinates
- θunit = unit vector pointing in the direction of increasing values of theta in polar coordinates
Note: All quantities in bold represent vectors.
[edit] Defining Equations
[edit] Center of mass
In the discrete case:
where n is the number of mass particles.
Or in the continuous case:
where ρ(s) is the scalar mass density as a function of the position vector
[edit] Velocity
Insertformulahere
[edit] Acceleration
- Centripetal Acceleration
(R = radius of the circle, ω = v/R angular velocity)
[edit] Momentum
[edit] Force
- (Constant Mass)
[edit] Impulse
- if F is constant
[edit] Moment of inertia
For a single axis of rotation: The moment of inertia for an object is the sum of the products of the mass element and the square of their distances from the axis of rotation:
[edit] Angular momentum
- if v is perpendicular to r
Vector form:
(Note: I can be treated like a vector if it is diagonalized first, but it is actually a 3×3 matrix - a tensor of rank-2)
r is the radius vector.
[edit] Torque
if |r| and the sine of the angle between r and p remains constant.
This one is very limited, more added later. α = dω/dt
[edit] Precession
[edit] Energy
m is here constant.
- in field of gravity
[edit] Central Force Motion
[edit] Useful derived equations
[edit] Position of an accelerating body
- if a is constant.