Kinematics
Cards (61)
- DistanceA measure of how far an object travels. It is a scalar quantity - the direction is not important.
- DisplacementA measure of how far something is from its starting position, along with its direction. It is a vector quantity - it describes both magnitude and direction.
- Distance is a scalar quantity because it describes how far an object has travelled overall, but not the direction it has travelled in.
- Displacement is a vector quantity because it describes how far an object is from where it started and in what direction.
- The difference between distance and displacement is that distance is a scalar while displacement is a vector.
- SpeedThe distance an object travels every second. It is a scalar quantity.
- VelocityThe rate of change of position. It is a vector quantity because it describes both magnitude and direction.
- The difference between speed and velocity is that speed is a scalar quantity while velocity is a vector quantity.
- Instantaneous speed/velocityThe speed/velocity of an object at any given point in time.
- Average speed/velocityThe total distance/displacement divided by the total time taken.
- Acceleration is the rate of change of velocity. It is a vector quantity.
- Negative acceleration is called deceleration.
- Kinematic equationsA set of four equations that can describe any object moving with constant or uniform acceleration, relating displacement, initial velocity, final velocity, acceleration, and time.
- Deriving kinematic equationsUsing calculus to derive the four kinematic equations from the definitions of velocity and acceleration.
- Key things to look out for when using kinematic equations are 'starts from rest', 'falling due to gravity', and 'constant acceleration in a straight line'.
- Starts from restThis means u = 0 and t = 0
- Falling due to gravityThis means a = g = 9.81 m/s^2
- It doesn't matter which way is positive or negative for the scenario, as long as it is consistent for all the vector quantities
- If downwards is considered positive, this is 9.81 m/s^2, otherwise, it is -9.81 m/s^2
- For example, if downwards is negative then for a ball travelling upwards, s must be positive and a must be negative
- Constant acceleration in a straight lineThis is a key indication for the kinematic equations are intended to be used
- For example, an object falling in a uniform gravitational field without air resistance
- How to use the kinematic formulae1. Step 1: Write out the variables that are given in the question, both known and unknown, and use the context of the question to deduce any quantities that aren't explicitly given2. Step 2: Choose the equation which contains the quantities you have listed3. Step 3: Convert any units to SI units and then insert the quantities into the equation and rearrange algebraically to determine the answer
- This is one of the most important sections of this topic - usually, there will be one, or more, questions in the exam about solving problems with the kinematic equations equations
- The best way to master this section is to practice as many questions as possible!
- Watch out for the direction of vectors: displacement, acceleration and velocity
- Don't worry, you won't have to memorise these, they are give in your data booklet in the exam
- You may sometimes see these equations referred to as 'SUVAT' equations
- Displacement-time graphs
- Slope equals velocity
- The y-intercept equals the initial displacement
- A straight (diagonal) line represents a constant velocity
- A curved line represents an acceleration
- A positive slope represents motion in the positive direction
- A negative slope represents motion in the negative direction
- A zero slope (horizontal line) represents a state of rest
- The area under the curve is meaningless
- Velocity-time graphs
- Slope equals acceleration
- The y-intercept equals the initial velocity
- A straight (diagonal) line represents uniform acceleration
- A curved line represents non-uniform acceleration
- A positive slope represents acceleration in the positive direction
- A negative slope represents acceleration in the negative direction
- A zero slope (horizontal line) represents motion with constant velocity
- The area under the curve equals the change in displacement
- Acceleration-time graphs
- Slope is meaningless
- The y-intercept equals the initial acceleration
- A zero slope (horizontal line) represents an object undergoing constant acceleration
- The area under the curve equals the change in velocity
- Acceleration can either be uniform (i.e. a constant value) or non-uniform (i.e. a changing value)
- Motion of a Bouncing Ball
- The acceleration due to gravity is always in the same direction (in a uniform gravitational field such as the Earth's surface)
- The ball changes its direction when it reaches its highest and lowest point, so the direction of the velocity will change at these points
- The vector nature of velocity means the ball will sometimes have a positive velocity if it is travelling in the positive direction, or a negative velocity if it is traveling in the negative direction
- Ignoring the effect of air resistance, the ball will reach the same height every time before bouncing from the ground again
- When the ball is traveling upwards, it has a positive velocity which slowly decreases (decelerates) until it reaches its highest point
- Section D of the graph
- Has the steepest slope
- Largest accelerationIs shown in section D
- Calculating the gradient of a velocity-time graphGives the acceleration for that time period
- Drawing a large gradient triangleAt the appropriate section of the graph
- The acceleration is given by the gradient, which can be calculated using: acceleration = gradient = 5/5 = 1 m s−2
- Therefore, Tora accelerated at 1 m s−2 between 5 and 10 seconds
- ProjectileA particle moving freely, under gravity, in a two-dimensional plane