| 1.1 Scalars and Vectors |
|---|
Every physical quantity is either a scalar or a vector.
Scalars
- Include quantities such as distance, speed, mass, and energy
- Are fully described by a magnitude alone and carry no directional information
Vectors
- Include quantities such as position, displacement, velocity, acceleration, and force
- Require both a magnitude and a direction to be fully described
This distinction determines how quantities combine: scalars add arithmetically, while vectors add component by component along each axis direction.
Vector Representation
- Vectors can be represented visually as arrows, where the arrow's length is proportional to the magnitude and the arrow's direction matches the vector's direction
- In calculations, vectors are expressed in unit vector notation using î, ĵ, and k̂ for the x-, y-, and z-directions
- The position vector r⃗ points from the origin to a point in space, while the unit position vector r̂ has a magnitude of one and carries only directional information
Resultant Vector
- A resultant vector is found by summing the components of the individual vectors along each axis
- These summed components are then combined using the Pythagorean theorem to find the magnitude and the inverse tangent to find the direction
In one-dimensional problems, opposite directions are represented by opposite algebraic signs, and the positive direction must be defined before any calculation begins.
At a Glance
| Quantity Type | Examples | Described By | How They Combine |
|---|---|---|---|
| Scalars | distance, speed, mass, and energy | a magnitude | add arithmetically |
| Vectors | position, displacement, velocity, acceleration, and force | both a magnitude and a direction | add component by component along each axis direction |