Pendulum and Simple Harmonic Motion

T = π√(g/L)

T = π√(L/g)

T = 2π√(g/L)

T = 2π√(L/g)

When the angle is more than 15 degrees

When the pendulum is in a vacuum

When the angle is less than 15 degrees

When the pendulum has a large mass

Amplitude of motion

Spring constant and mass

Gravitational field strength

Length of the pendulum

The string has negligible mass

The pendulum bob is a point mass

There is significant friction

The string is inextensible

The centripetal force

The tension in the string

The force of air resistance

The component of gravitational force acting tangentially

Sine of theta is approximately equal to theta for small angles

Cosine of theta is approximately equal to theta for small angles

Tangent of theta is approximately equal to theta for small angles

Theta is approximately zero for small angles

√(g/L)

L/g

√(L/g)

g/L

Period is equal to angular frequency

Period is independent of angular frequency

Period is directly proportional to angular frequency

Period is inversely proportional to angular frequency

Neither angular velocity nor angular frequency

Both angular velocity and angular frequency

Only angular velocity

Only angular frequency

Maximum position times angular frequency

Maximum position divided by angular frequency

Maximum position plus angular frequency

Maximum position minus angular frequency