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Introduction to Linearization ( No units, no uncertainties, just the core idea ) The purpose of linearization is to get the equation that describes real.

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Presentation on theme: "Introduction to Linearization ( No units, no uncertainties, just the core idea ) The purpose of linearization is to get the equation that describes real."— Presentation transcript:

1 Introduction to Linearization ( No units, no uncertainties, just the core idea ) The purpose of linearization is to get the equation that describes real data. Mr. Klapholz Shaker Heights High School

2 A scientist varies the mass, and measures the acceleration. Force is kept constant. AccelerationMass 121 62 43 34

3 Acceleration Mass What shape will we see when we graph it?

4 Acceleration Mass The greater the Mass, the less the acceleration

5 Mass It is tough to know the equation of this function. a = ? Acceleration

6 Mass So we linearize it. Acceleration

7 We guess that Acceleration = k / Mass

8 We guess that acceleration = k / Mass Acceleration Mass1 ÷ M 1211.00 62 ? 4 ? 0.33 ? 40.25

9 We guess that acceleration = k / Mass Acceleration Mass1 ÷ M 1211.00 620.50 430.33 340.25

10 Acceleration 1 / Mass What shape will we see when we graph it?

11 Acceleration 1 / Mass

12 Acceleration 1 / Mass

13 Acceleration y = mx +b 1 / Mass

14 Acceleration a = (slope)×(1/Mass) + b 1 / Mass y = mx +b

15 Find the slope and the intercept.

16 Slope Slope = Rise / Run Slope =  a /  (1/M) Slope = ( 12 – 3 ) / (1 – 0.75) Slope = 9 / 0.75 Slope = 12

17 Intercept Since the graph goes through the origin, the intercept is 0.

18 So, what is the equation?

19 a = ?

20 a = 12 (1/M) Notice that we were able to write down the conclusion to the lab only because we had linearized the data. The function could be said to be “linear in 1/M”. But what we really wanted was the function, and we have it: a = 12 / M. FYI: Newton’s second law says, in part, that acceleration = Force / mass.

21 Our last example…

22 A researcher changes the distance that a spring is compressed, and measures the energy in the spring. EnergyDistance 21 82 183 324

23 Energy Distance What shape will we see when we graph it? Energy = ?

24 Energy Distance

25 The greater the Distance, the greater the acceleration. Energy Distance

26 Energy Distance It is tough to know the equation of this function. E = ?

27 Energy Distance Let’s linearize it.

28 We guess that E = k × D 2

29 EnergyDistanceD2D2 21 82 183 324

30 We guess that E = k × D 2 EnergyDistanceD2D2 211 824 1839 32416

31 What shape will we see when we graph it?

32 Energy Distance

33 Energy Distance

34 y = mx +b Energy Distance

35 a = (slope)×(1/Mass) + b Energy Distance y = mx +b

36 Find the slope and the intercept.

37 Slope Slope = Rise / Run Slope =  E /  D 2 ) Slope = ( 32 – 2 ) / ( 16 – 1 ) Slope = 30 / 15 Slope = 2

38 Intercept Since the graph goes through the origin, the intercept is 0.

39 So, what is the equation?

40 E = ?

41 E = 2 D 2 The data indicate that the energy stored in a spring is proportional to the square of the compression distance.

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