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A vector quantity has both magnitude and direction. Acceleration, velocity, force and displacement are all examples of vector quantities. A scalar quantity is has only magnitude (so the direction is not important). Examples include speed, time and distance.
Vectors are usually represented as follows:
The arrow shows the direction and the number (v in this case) represents the magnitude.
Letters used to represent vectors should always be underlined or in bold type. For example, the velocity of an object may be represented by v. Since this is a vector quantity, it is in bold type. Small case letters are usually used to represent vectors.
A unit vector is a vector which has a magnitude of 1. There are three important unit vectors which are commonly used and these are the vectors in the direction of the x, y and z-axes. The unit vector in the direction of the x-axis is i, the unit vector in the direction of the y-axis is j and the unit vector in the direction of the z-axis is k.
Writing vectors in this form can make working with vectors easier.
For example, the vector 5i - 3j would look something like this on a diagram:
If two vectors are added together, the resultant is found by placing the vectors to be added end to end. If the vectors are given in unit vector form, you simply add together the i, j and k values.
p = 3i + j, q = -5i + j. Find p + q.
Since the vectors are given in i, j form, we can easily calculate the resultant. 3i + j - 5i + j = -2i + 2j
This could also have been worked out from a diagram:
The Magnitude of a Vector
The magnitude of a vector can be found using Pythagoras's theorem.
The magnitude of ai + bj = √(a2 + b2)
Resolving a Vector
Resolving a vector means finding its magnitude in a particular direction.
In the diagram above, the vector r has magnitude r and direction j to the x-axis. Using basic trigonometry, we can calculate that the component of r in the direction of the x-axis is rcosj. The component in the direction of the y-axis is rsinj. Therefore r = rcosji + rsinjj.