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1 Physics 11 S. Coghlan 2 This concept map is designed to help you; Understand how the various different parts of movement link together. Study the whole.

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Presentation on theme: "1 Physics 11 S. Coghlan 2 This concept map is designed to help you; Understand how the various different parts of movement link together. Study the whole."— Presentation transcript:

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2 1 Physics 11 S. Coghlan

3 2 This concept map is designed to help you; Understand how the various different parts of movement link together. Study the whole section of work. Main Concepts Linking words Printer friendly version available from my web site

4 3 Movement described by measured by shown by performs produceslaws related to Quantities Distance/Displacement Speed/VelocityAcceleration Graphs Work Energy Pressure Newton 1 Newton 2 Newton 3

5 4 Movement Quantities described by Distance/ Displacement Speed/Velocity Acceleration measured by Graphs shown by Work performs Energy produces Pressure related to Newton 1 Newton 2 Newton 3 laws

6 5 Movement Quantities described by Distance/ Displacement Speed/Velocity Acceleration measured by Graphs shown by Work performs Energy produces Pressure related to Newton 1 Newton 2 Newton 3 laws if constant rate of change types graph equation rate of doing magnitude magnitude + direction P = W/t a = v – u Scalar Vector t v = s s vs t t v vs t a vs t F vs s Power

7 6 Movement Quantities described by Distance/ Displacement Speed/Velocity Acceleration measured by Graphs shown by Work performs Energy produces Pressure related to Newton 1 Newton 2 Newton 3 laws Scalar Vector magnitude magnitude + direction v = s t if constant rate of change a = v – u t equation s vs t v vs t a vs t types F vs s graph Power P = W t rate of doing

8 7 Movement Quantities described by Distance/ Displacement Speed/Velocity Acceleration measured by Graphs shown by Work performs Energy produces Pressure related to Newton 1 Newton 2 Newton 3 laws Scalar Vector magnitude magnitude + direction v = s t if constant rate of change a = v – u t equation s vs t v vs t a vs t types F vs s graph Power P = W t rate of doing typessolidsfluids F = ma property of mass property of mass and velocity Kinetic ½mv 2 Potential mgh LightSoundHeat P =  gh P = F Impulsive force A Ft = m(v-u) Momentum p = mv Inertia

9 8 Movement Quantities described by Distance/ Displacement Speed/Velocity Acceleration measured by Graphs shown by Work performs Energy produces Pressure related to Newton 1 Newton 2 Newton 3 laws Scalar Vector magnitude magnitude + direction v = s t if constant rate of change a = v – u t equation s vs t v vs t a vs t types F vs s graph Power P = W t rate of doing Kinetic ½mv 2 Potential mgh Light Sound Heat typestypes degradesdegrades P =  gh fluids P = F A solids Impulsive force Ft = m(v-u) F = ma Inertia property of mass Momentum p = mv property of mass and velocity

10 9 Physics 11 S. Coghlan Your own concept map Single page concept map

11 10 Quantities Distance/Displacement Speed/VelocityAcceleration Graphs Work Energy Pressure Newton 1 Newton 2 Newton 3 a = v – u Scalar Vector t v = s s vs t v vs t t a vs t F vs s Power Kinetic ½mv 2 Potential mgh LightSoundHeat P =  gh P = F Impulsive force Inertia A Ft = m(v-u) Momentum p = mv described by measured by shown by performs produceslaws related to if constant rate of change types graph equation rate of doing magnitude magnitude + direction P = W/t property of mass and velocity typessolidsfluids F = ma property of mass You can use these Main Concepts and Linking Words to complete your own concept map. You can print out the next page and use it as a framework. Main Concepts Linking Words Printer friendly version available from my web site

12 11 Movement Printer friendly version available from my web site

13 12 Movement Quantities described by Distance/ Displacement Speed/Velocity Acceleration measured by Graphs shown by Work performs Energy produces Pressure related to Newton 1 Newton 2 Newton 3 laws Scalar Vector magnitude magnitude + direction v = s t if constant rate of change a = v – u t equation s vs t v vs t a vs t types F vs s graph Power P = W t rate of doing Kinetic ½mv 2 Potential mgh Light Sound Heat typestypes degradesdegrades P =  gh fluids P = F A solids Impulsive force Ft = m(v-u) F = ma Inertia property of mass Momentum p = mv property of mass and velocity

14 Newton 3 Weight Reaction force of ground on bike += 0

15 s t Displacement vs Time graph The gradient gives the velocity at this point. rise run

16 v t Velocity vs Time graph Gradient is the acceleration Area is v x t = s. rise run

17 a t Acceleration vs Time graph Constant acceleration Change in velocity,  v

18 F s Force vs Displacement graph Area is F x s = W

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