Know and understand the meaning of Newton’s three laws.

Includes applying the laws to problems.

Newton's first law Newton's second law for motion in a straight line Newton's third law

Understand the term equation of motion.

Newton's second law for motion in a straight line

Be able to formulate the equation of motion for a particle moving in a straight line when the forces acting are parallel or in two perpendicular directions or in simple cases of forces given as 2-D vectors in component form.

Including motion under gravity.

Notation:
\(F = ma\) where \(F\) is the resultant force.
\(\bold{F} = m\bold{a}\) where \(\bold{F}\) is the resultant force.

[Excludes: Variable mass]

Newton's second law for motion in a straight line Weight and motion in a straight line under gravity

Be able to model a system as a set of connected particles.

e.g. simple smooth pulley systems, trains. Internal and external forces for the system.

Smooth pulleys Connected particles

Be able to formulate the equations of motion for the individual particles within the system.

Connected particles

Know that a system in which none of its components have any relative motion may be modelled as a single particle with the mass of the system.

e.g. Train.

Connected particles

Be able to formulate the equation of motion for a particle moving in a straight line or in a plane.

Including motion under gravity.

Notation:
\(F = ma\) where \(F\) is the resultant force.
\(\bold{F} = m\bold{a}\) where \(\bold{F}\) is the resultant force.

[Excludes: Variable mass]

Newton's second law for motion in a straight line Weight and motion in a straight line under gravity