AQA GCSE Speed

AQA GCSE Speed

Speed

Speed is the distance (metres) an object travels in one second. 

Speed has units of metres per second, or m/s

Speed is a scalar quantity, so it has a magnitude, but no direction. 

Uniform and non uniform speed

Uniform speed means that the speed is constant and it does not change. An example is a car travelling along a road at a constant speed of 10m/s. 

In real life uniform speed is unrealistic. This is because most of the time when an object is moving it will increase or decrease its speed. 

Non-uniform speed means that the speed will change, so it can increase or decrease. An example could be a person going for  walk at 1.5m/s, then run at 3m/s, then return to walking at 1.5m/s for the remainder of their journey. 

In real life non-uniform speed is more realistic as it represents real life examples better. 

Typical speeds

The following table will give you examples of different typical speeds. 

It is important to understand that there are different factors that could affect the values in the table below. 

If a person is walking up a hill, there speed is likely to be less than 1.5m/s, or if the person is elderly, then value may be less than 1.5m/s

MotionSpeed (m/s)
Walking1.5
Running3
Cycling6
Car12
Bus10
Train25
Aeroplane250
Wind speed3

Speed of Sound in air

Speed of sound in air has a typical value of 330m/s

However, this value varies:

1. Temperature decreases, speed of sound in air will decrease as the particles have less kinetic energy, so sound wave is transferred more slowly.

2. At higher altitudes, temperature decreases, so speed of sound of air will decrease. 

Practice Questions

1. Define the term Speed

2.Explain the difference between uniform and non uniform speed. 

3. Draw a bar chart to compared the different speeds that allows a comparison for walking, running, cycling, running, car, train and bus

Answers to questions
physics worksheet

Energy stores and systems notes and questions

Real life energy transfers

Kinetic energy

Gravitational potential energy

Elastic Potential energy

Changes in energy, Specific heat capacity

Power

Conservation of Energy

Work done

Conduction

Wasted energy transfers

Efficiency

Energy Resources

Wind and Solar

Coal, Oil and Natural Gas

Nuclear Power

Biofuels

Hydroelectric, Wave and Tidal

Circuit Symbols

Electric Current and Charge

Potential difference, Current and Resistance

Resistors

Thermistors and Light Dependent Resistors

Series Circuit

Parallel Circuits

Series Circuit Calculations

Parallel Circuit Calculations

Alternating and Direct Electrical Circuits

Mains Electricity

Earth wire

Fuses

Electrical Power

Energy Transfer in Circuits

Power of Appliances

National Grid

Static Charge

Static Electricity

Static Electricity and Forces

Static Electricity and Sparking

Electric Fields

Electric Fields and Objects

Density

Measuring Density

States of Matter

Changes of state

Internal Energy

Specific Heat Capacity

Latent Heat

Specific Latent Heat

Heating and Cooling Curves

Specific heat capacity compared to Specific latent heat

Motion of gas particles 

Gas Pressure and Volume

Doing work on gases

Structure of the Atom

Absorption and Emission of EM Radiation

Mass Number and Atomic Number

Isotopes

Ionisation

JJ Thomson and Plum pudding model

Ernest Rutherford and the Nuclear Model

Niels Bohr changing the Nuclear Model

Discovering the Proton and Neutron

Radioactive Decay

Measuring radiation from radioactivity

Radiation types and properties

Random nature of radioactive decay

Half life

Half life calculations

Radioactive contamination or irradiation

Hazards of contamination and irradiation

Studies on the effects of radiation on humans

Background Radiation

Different half lives of radioactive isotopes

Uses of nuclear radiation

Nuclear Fission

Nuclear Fission Chain Reaction

Writing nuclear fission equations

Drawing and interpreting nuclear fission diagrams

Nuclear Fusion

Scalar and Vector Quantities

Contact and Non Contact Forces

Describing interactions of forces and objects

Gravity

Measuring Weight

Calculating Weight

Resultant Forces

Free body diagrams

Free body diagrams part 2

Resolving Forces

Forces and Equilibrium

Finding the resultant force, using the parallelogram rule

Finding the resultant force, using the parallelogram rule part 2

Work done and Forces

Forces and Elasticity

Hooke’s Law

Calculating Spring Constant

Using Force-extension graphs

Linear and Non linear force extension graphs

Work done and elastic potential energy

 

Introduction to moments

Levers

Balancing Moments

Balancing Moments made more complex

Gears

Gears and Moments

Pressure acting on a surface

Pressure at the surface of a fluid

Pressure due to a column of liquid

Explaining pressure in a column of liquid

Upthrust

Atmospheric Pressure

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Accordion Content
Accordion Content