Resultant Forces (Cambridge (CIE) IGCSE Physics)
Revision Note
Written by: Ashika
Reviewed by: Caroline Carroll
Effects of forces
A force is defined as:
A push or a pull that acts on an object due to the interaction with another object
Forces can have a variety of effects on an object
Forces can change an object's
speed
direction
shape
size
Effects of forces on different objects
A thrust force can cause a car to speed up, a gravitational force can cause a comet to change direction, compression forces can cause a spring to change shape
The effects of forces on an object often depend on the type of force acting
The push force (thrust) of an engine can cause a car to speed up, whilst the force exerted by the brakes (friction) can cause it to slow down
The gravitational pull of the Sun on a comet causes the comet to change direction
When two opposing forces push on each end of a spring, the spring changes shape (it compresses)
Resultant forces on a straight line
What is a resultant force?
A resultant force is a single force that describes all of the forces operating on a body
When multiple forces act on one object, the forces can be combined to produce one net force that describes the combined action of all of the forces
This single resultant force determines:
The direction in which the object will move as a result of all of the forces
The magnitude of the net force experienced by the object
Balanced and unbalanced forces
The forces acting on an object can be described as balanced or unbalanced
Forces are balanced if multiple forces act in opposing directions with an equal magnitude in each direction
The effects of the forces then cancel out
There is no resultant force in that plane of direction
Forces are unbalanced if the effects of the forces acting in each plane do not cancel out
There is a resultant force in one or more planes of direction
A book is a rest on a table
The gravitational pull of the Earth on the book (weight) acts in a downward direction
The push force of the table on the book (normal contact force) acts in the upward direction
The forces are equal in magnitude and opposite in direction
The forces are therefore balanced
There is no resultant force acting on the book
Zero resultant force on a book resting on a table
A book resting on a table is an example of balanced forces
Calculating resultant force
Force is a vector quantity, it has both magnitude and direction
When adding forces together, it is important to assign positive and negative values to show the direction in which the forces are acting
If a 5 N force acts to the right and a 5 N force acts to the left on an object, then we assign one of the values as positive and one as negative
So the resultant force acting on the object is
The forces acting on the object are equal in magnitude and opposite in direction; therefore they cancel one another out
This is like two people pushing a box with equal force from opposite sides, the box doesn't move
If two people push the box from the same side in the same direction, one with a 3 N force and one with a 7 N force, then the forces will add together and the box will move in the direction of the resultant force
If two people push the box in opposite directions, one with a 7 N force to the left (negative) and one with a 3 N force to the right (positive), then the forces will add together and the box will move in the direction of the resultant force
Zero and non-zero resultant forces
Zero and non-zero resultant forces acting on three objects
Worked Example
Calculate the magnitude and direction of the resultant force in the diagram below.
Answer:
Step 1: Assign a direction to the forces
Forces acting to the right are positive
Forces acting to the left are negative
Step 2: Add together all the forces acting on the object
Step 3: State the magnitude and direction of the resultant force
The resultant force is 2 N to the left
Examiner Tips and Tricks
Mathematically, it doesn't matter which direction you assign to be positive or negative, as long as you are consistent throughout your calculation.
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