Combining & Resolving Vectors
- Vectors can be changed in a variety of ways, such as
- Combining through vector addition or subtraction
- Combining through vector multiplication
- Resolving into components through trigonometry
Combining Vectors
- Vectors can be combined by adding or subtracting them to produce the resultant vector
- The resultant vector is sometimes known as the ‘net’ vector (e.g. the net force)
- There are two methods that can be used to combine vectors: the triangle method and the parallelogram method
Triangle method
- To combine vectors using the triangle method:
- Step 1: link the vectors head-to-tail
- Step 2: the resultant vector is formed by connecting the tail of the first vector to the head of the second vector
Parallelogram method
- To combine vectors using the parallelogram method:
- Step 1: link the vectors tail-to-tail
- Step 2: complete the resulting parallelogram
- Step 3: the resultant vector is the diagonal of the parallelogram
Worked example
Draw the vector c = a + b.
Answer:
Worked example
Draw the vector c = a – b.
Answer:
Vector Multiplication
- The product of a scalar and a vector is always a vector
- For example, consider the scalar quantity mass and the vector quantity acceleration
- The product of mass and acceleration gives rise to a vector quantity force
- For another example, consider the scalar quantity mass and the vector quantity velocity
- The product of mass and velocity gives rise to a vector quantity momentum
Resolving Vectors
- Two vectors can be represented by a single resultant vector
- Resolving a vector is the opposite of adding vectors
- A single resultant vector can be resolved
- This means it can be represented by two vectors, which in combination have the same effect as the original one
The magnitude of the resultant vector is found by using Pythagoras’ Theorem
- When a single resultant vector is broken down into its parts, those parts are called components
- For example, a force vector of magnitude FR and an angle of θ to the horizontal is shown below
Resolving two force vectors F1 and F2 into a resultant force vector FR
- It is possible to resolve this vector into its horizontal and vertical components using trigonometry
The resultant force FR can be split into its horizontal and vertical components
- The direction of the resultant vector is found from the angle it makes with the horizontal or vertical
- The question should imply which angle it is referring to (i.e. calculate the angle from the x-axis)
- Calculating the angle of this resultant vector from the horizontal or vertical can be done using trigonometry
- Either the sine, cosine or tangent formula can be used depending on which vector magnitudes are calculated
- For the horizontal component, Fx = F cos θ
- For the vertical component, Fy = F sin θ
Worked example
A hiker walks a distance of 6 km due east and 10 km due north.
Calculate the magnitude of their displacement and its direction from the horizontal.
Answer:
Step 1: Draw a vector diagram
Step 2: Calculate the magnitude of the resultant vector using Pythagoras' Theorem
Resultant vector = 11.66
Step 3: Calculate the direction of the resultant vector using trigonometry
Step 4: State the final answer complete with direction
- Vector magnitude: 12 km
- Direction: 59° east and upwards from the horizontal
Exam Tip
Make sure you are confident using trigonometry as it is used a lot in vector calculations!
If you're unsure as to which component of the force is cos θ or sin θ, just remember that the cos θ is always the adjacent side of the right-angled triangle AKA, making a 'cos sandwich'