Applications-of-GeoGebra/C3/Differentiation-using-GeoGebra/English
Visual Cue | Narration |
Slide Number 1
Title Slide |
Welcome to this tutorial on Differentiation using GeoGebra. |
Slide Number 2
Learning Objectives |
In this tutorial, we will learn how to use GeoGebra to:
Understand Differentiation Draw graphs of derivative of functions. |
Slide Number 3
System Requirement |
Here I am using:
Ubuntu Linux Operating System version 16.04 GeoGebra 5.0.481.0-d. |
Slide Number 4
Pre-requisites www.spoken-tutorial.org |
To follow this tutorial, you should be familiar with:
GeoGebra interface Differentiation For relevant tutorials, please visit our website. |
Slide Number 5
Differentiation: First Principles
f'(x) is derivative of f(x) A (x, f(x)), B (x+j, f(x+j)) |
Differentiation: First Principles
Let us understand differentiation using first principles for the function f of x. f of x is equal to x squared minus x
A is x comma f of x and B is x plus j comma f of x plus j |
Show the GeoGebra window. | I have opened the GeoGebra interface. |
Type f(x)=x^2-x in the input bar >> Enter | In the input bar, type the following line.
For the caret symbol, hold the Shift key down and press 6. Press Enter. |
Point to the equation in Algebra view.
Point to parabola in Graphics view. |
Observe the equation and the parabolic graph of function f. |
Click on Point on Object tool >> click on the parabola at (2,2).
Point to A at (2,2). Click on Point tool and click on (3,6). |
Clicking on the Point on Object tool, create point A at 2 comma 2 and B at 3 comma 6. |
Click on Line tool >> click on points B and A. | Click on Line tool and click on points B and A to draw line g. |
Click on the Move tool.
Double click on the resulting line g and click on Object Properties. Click on Color tab and select blue. Click on Style tab and select dashed style. |
As shown earlier in this series, make this line g blue and dashed. |
Click on Tangents tool under Perpendicular Line tool. | Under Perpendicular Line, click on Tangents. |
Click on A >> click on the parabola. | Click on A and then on the parabola. |
Point to tangent h at point A to the parabola. | This draws a tangent h at point A to the parabola. |
Double click on tangent h and click on Object Properties.
Under Color tab, select red. Close the Preferences box. |
Let us make tangent h a red line. |
Click on Point tool and click in Graphics view.
Point to point C. |
Click on the Point tool and click anywhere in Graphics view.
This creates point C. |
Double click on point C in Algebra view and change its coordinates to (x(B),y(A)).
Point to C. |
In Algebra view, double-click on C and change its coordinates to the following. |
Point to B and A. | Now C has the same x coordinate as point B and the same y coordinate as point A. |
Under Line, click on Segment and click on B and C, and then on A and C. | Let us use the Segment tool to draw segments BC and AC. |
Right-click on C >> Select Object Properties >> Color tab >> Purple
Click on Style tab >> select dashed line Under Basic tab >> choose Name and Value >> Show Label check box. Close the Preferences dialog box. |
We will make AC and BC purple and dashed segments. |
With Move highlighted, drag B towards A on the parabola. | With Move highlighted, drag B towards A on the parabola. |
Point to the value of j (length of AC) and lines g and h. | Observe lines g and h and the value of j (length of AC).
As j approaches 0, points B and A begin to overlap. Lines g and h also begin to overlap. |
Point to line g, BC and AC. | Slope of line g is the ratio of length of BC to length of AC. |
Point to all the points on the parabola. | Derivative of the parabola is the slope of the tangent at each point on the curve. |
Point to text-box that appears in GeoGebra window.
As B approaches A, slope AB approaches slope of tangent at A. |
As B approaches A on f of x, slope of AB approaches the slope of tangent at A. |
Now let us look at the Algebra behind these concepts. | |
Slide Number 6
Differentiation: First Principles, the Algebra
= lim_j→0 [(f(x+j) – f(x)]/[(x+j) – x] Remember f(x) = x2-x, (x+j)2 = x2+2xj+j2 f'(x) = lim_j→0 [(x+j)2-(x+j)-(x2-x)]/(x+j-x) |
Differentiation: First Principles, the Algebra
Slope of line AB equals the ratio of the lengths of BC to AC. Line AB becomes the tangent at point A as distance j between A and B approaches 0.
Let us rewrite f of x plus j and f of x in terms of x squared minus x. We will expand the terms in the numerator. |
Slide Number 7
The Algebra-Cont’d
= lim_j→0 [2xj+j2-j]/j = lim_j→0 [j(2x+j-1)]/j
f'(x2-x) = 2x -1 |
After expanding the terms in the numerator, we will cancel out similar terms with opposite signs.
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Let us look at derivative graphs for some functions. | |
Slide Number 8
Differentiation of a Polynomial Function
Differentiation rules: d(u±v)/dx = d(u)/dx ± d(v)/dx
d(5+12x-x3)/dx = d(5)/dx + d(12x)/dx - d(x3)/dx = 0 + 12 - 3x2 = -3x2 +12
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Differentiation of a Polynomial Function
Consider g of x. Derivative g prime x is the sum and difference of derivatives of the individual components.
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Let us differentiate g of x in GeoGebra. | |
Open a new GeoGebra window. | Open a new GeoGebra window. |
Type g(x)=5+12x-x^3 in input bar >> Enter | In the input bar, type the following line and press Enter. |
Under Move Graphics View, click on Zoom Out.
Click in Graphics view until you see function g. |
As shown earlier in the series, zoom out to see function g properly. |
Right-click in Graphics view and select xAxis : yAxis option.
Select 1:5. |
Right-click in Graphics view and select xAxis is to yAxis option.
Select 1 is to 5. |
Under Move Graphics View, click on Zoom Out again.
Click in Graphics view to zoom out. |
I will zoom out again. |
Click on Point on Object tool and click on the curve to create point A.
Click on Tangent under Perpendicular Line. Click on point A and the curve. |
As shown earlier, draw point A on curve g and a tangent f at this point. |
Click on Slope tool under Angle tool and on tangent line f. | Under Angle, click on Slope and on tangent line f. |
Point to slope of line f at A appearing as m value in Graphics view. | Slope of tangent line f appears as m value in Graphics view. |
Click on Point tool and in Graphics view to create point B.
Double click on point B in Algebra view and change coordinates to (x(A), m). Point to points A and B and slope m of tangent line g. |
Draw point B and change its coordinates to x A in parentheses comma m. |
Right-click on point B >> select Trace On option. | Right-click on B and select Trace On option |
Click on Move tool and move point A on curve.
Observe the curve traced by point B. |
With Move tool highlighted, move point A on curve.
Observe the curve traced by point B. |
Let us check whether we have the correct derivative graph. | |
Type Deri in input bar >> select Derivative( <Function> ) >> Type g instead of highlighted <Function> >> press Enter | In the input bar, type d e r i.
Type g to replace the highlighted word <Function>.
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Point to the equation in Algebra view.
Drag the boundary. |
Note the equation of g prime x in Algebra view.
Drag the boundary to see it properly |
Compare slides' calculations with equation of g'(x) in Algebra view. | Compare the calculations in the previous slide with the equation of g prime x |
Let us find the maxima and minima of the function g of x. | |
Point to derivative curve g'(x) above the x-axis and to g(x). | Derivative curve g prime x remains above the x-axis (is positive) as long as g of x is increasing. |
Point to derivative curve g'(x) below the x-axis and to g(x). | g prime x remains below the x-axis (is negative) as long as g of x is decreasing. |
Point to derivative curve g'(x) intersecting x-axis at x = -2 and x = 2. | 2 and -2 are the values of x when g prime x equals 0. |
Point to slope. | Slope of the tangent at the corresponding point on g of x is 0.
Such points on g of x are maxima or minima. |
Point to (-2,-11) and (2,21). | Hence, for g of x, -2 comma -11 is the minimum and 2 comma 21 is the maximum. |
Point to minimum of g(x) and x=-3 and x = -1. | In GeoGebra, we can see that the minimum value of g of x lies between x equals -3 and x equals -1. |
In the input bar, type Min.
From the menu that appears, select Min Function Start x-Value, End x-Value option. Type g for Function. Press Tab to go to the next argument. Type -4 and -1 as Start and End x-Values. Press Enter. |
In the input bar, type Min.
From the menu that appears, select Min Function Start x-Value, End x-Value option. Type g for Function. Press Tab to go to the next argument. Type -4 and -1 as Start and End x-Values. Press Enter. |
Point to minimum C in Graphics view and its co-ordinates in Algebra view. | In Graphics view, we see the minimum on g of x.
Its co-ordinates are -2 comma -11 in Algebra view. |
In the input bar, type Max.
From the menu that appears, select Max Function Start x-Value, End x-Value option. Type g, 1 and 4 as the arguments. Press Enter. |
In the input bar, type Max.
From the menu that appears, select Max Function Start x-Value, End x-Value option.
Press Enter. |
Point to maximum C in Graphics view and its co-ordinates in Algebra view. | We see the maximum on g of x, 2 comma 21. |
Finally, let us take a look at a practical application of differentiation. | |
Slide Number 9
A Practical Application of Differentiation
We have to convert it into a box Squares have to be cut out from the four corners What size squares should we cut out to get the maximum volume of the box? |
We have a 24 inches by 15 inches piece of cardboard.
We have to convert it into a box. Squares have to be cut from the four corners. What size squares should we cut out to get the maximum volume of the box? |
Slide Number 10
A Sketch of the Cardboard Let’s draw the cardboard: The volume function here is (24-2x)*(15-2x)*x cubic inches. |
A Sketch of the Cardboard
Let us draw the cardboard: This is the volume function here. You could expand it into a cubic polynomial; but we will leave it as it is. |
Open a new GeoGebra window. | Open a new GeoGebra window. |
Type (24-2 x) (15-2 x) x in the input bar >> Enter. | In the input bar, type the following line and press Enter. |
Drag the boundary to see the equation properly in Algebra view. | Drag the boundary to see the equation properly in Algebra view. |
Right-click in Graphics view and set xAxis : yAxis to 1:50.
Under Move Graphics View, click on Zoom Out. Click in Graphics view to see the function properly. |
Right-click in Graphics view and set xAxis is to yAxis to 1 is to 50.
Now, zoom out to see the function properly. |
Point to the graph for this volume function in Graphics view.
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Observe the graph that is plotted for the volume function in Graphics view.
Drag the background to see the maximum. |
Point to the maximum on top of the broad peak and to x = 0 and x = 7. | Note that the maximum is on the top of this broad peak. |
Point to both axes. | The length of the square side is plotted along the x-axis.
Volume of the box is plotted along the y-axis. |
In the input bar, type Max with capital M.
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As before, let us find the maximum of this function. |
Point to the maximum, A, in Graphics view and its coordinates in Algebra view. | This maps the maximum, point A, on the curve.
Its coordinates 3 comma 486 appear in Algebra view.
This will give the maximum possible volume of 486 cubic inches for the cardboard box. |
Let us summarize. | |
Slide Number 11
Summary |
In this tutorial, we have learnt how to use GeoGebra to:
Understand differentiation Draw graphs of derivatives of functions |
Slide Number 12
Assignment Draw graphs of derivatives of the following functions in GeoGebra: h(x)=ex i(x)=ln(x) j(x)=(5x3+3x-1)/(x-1) Find the derivatives of these functions independently and compare with GeoGebra graphs. |
As an assignment:
Draw graphs of derivatives of the following functions in GeoGebra.
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Slide Number 13
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Slide Number 14
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Slide Number 15
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Slide Number 16
Acknowledgement |
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This is Vidhya Iyer from IIT Bombay, signing off.
Thank you for joining. |