Introduction to Maple Maple is a computer algebra system designed to do mathematics. Symbolic, numerical and graphical computations can all be done with Maple. Maple's treatment of the topics of calculus is thorough. The user may compose Maple commands to carry out all of the fundamental operations that are studied in Calculus I - III, Differential Equations and Linear Algebra. 1. Starting Maple When using the Windows version of Maple, you may start the Maple program by positioning the mouse arrow " " over the Maple icon that appears on the terminal screen and then double-clicking the left hand mouse button. MAPLE ICON This icon should be present on the main window of any computer in an IIT calculus lab room. Maple will respond to your double-click by providing a blank worksheet . A prompt sign " >" appears on the first line of this worksheet and just to its right is a flashing cursor " | ". The prompt sign tells you that Maple is waiting for a command, i.e. an input. MAPLE WORKSHEET WINDOW 2. Saving a Maple Worksheet In order to name and save a Maple worksheet, begin by clicking the left hand mouse button on the word File which appears at the upper left corner of the menu bar of the Maple Worksheet Window (see figure above). From the File menu that results, click on the option Save As. . . . At this time, a submenu will appear in the middle of the window. Type in the name that you have chosen to describe your worksheet and then click the mouse button on the rectangle OK . This will save your worksheet under its given name on your computer's Drive C. Note: if you want to save your worksheet on a floppy disc instead, then insert your disc at this stage and follow the steps described above, but be sure to choose Drive A from the Drives Field of the Save As. . . submenu. If you make some changes after naming your worksheet and decide to save the revised copy instead of the original one, then click on the floppy disc icon located on the tool bar of the Maple Worksheet Window. This will immediately save the edited worksheet under the original name. * * * Always use the left hand mouse button to click on a selection.* * * 3. Ending a Maple Session When you want to end a Maple session, and have saved your work (if desired) then simply click on the square containing the X which is located at the extreme upper right corner of the Maple Worksheet Window. 4. Opening a Saved Maple Worksheet In order to open a named Maple worksheet, you must first Start Maple as described in Section 1. Next, click on the word File located on the menu bar. Then click on Open from the resulting File menu. In the Drives Field of the Open submenu, select Drive A in case the worksheet is stored on a floppy disc, otherwise select Drive C. Finally, double-click on the name of the desired worksheet appearing in the large box below the field File name . This sequence will open the appropriate worksheet. Note: there is a shortcut to opening a Maple worksheet. Just click on the icon displaying an open folder on the tool bar, , then the Open submenu will immediately appear. 5. Defining a Maple Command We will call any string of symbols contained between a prompt sign and a semicolon (or colon) a command. Commands in the Windows version of Maple always appear in red type. The semicolon " ; " or colon " : " signals the end of a command. (i) If " ; " is used to end a command and then the Enter key is pressed, Maple will execute your command, if possible, and display the related outcome in blue type (for non-graphical output). If the command cannot be executed, then Maple will often respond by reprinting your command using blue characters. (ii) If the end of your command is signaled with " : " and the Enter key is pressed, then Maple will execute the command but will not display the outcome. In either case (i) or case (ii), after Maple has finished its execution, it will produce a new prompt sign and a flashing cursor on the first blank line of the worksheet. Note: If Maple responds to your command with an error message, then you must go back to the command line and make the necessary corrections. The cursor can be moved to the appropriate position on the command line by using the arrow keys : (grouped on the right side of the keyboard ), or by simply positioning the mouse arrow at the desired location on the terminal screen and clicking the left hand button one time. The backspace key, , can also be used to move the cursor. However, each time that it is pressed, the first character to the left of the cursor will be erased and all the characters on that line located to the right of the cursor will move one space leftward. The space bar located at the bottom of the keyboard will move the cursor and all characters to its right one space rightward each time it is pressed. 6. Maple Symbols Some of the elementary symbols used frequently in Maple commands are described below. Integers: Use the keys on the top row of your computer's keyboard to enter the desired integer. Use the hyphen character " - " also located along this row to denote a negative number. Fractions: To enter the fraction NiMqJiUicEciIiIlInFHISIi in a command, insert the slash symbol " / " between the numbers p and q. Decimals: Decimals are entered in the natural way. Special Numbers: Handwritten notation Maple syntax NiMlI1BpRw== . . . . . . . . . . . . . . . . . . . . . . . . Pi e . . . . . . . . . . . . . . . . . . . . . . . . exp( 1 ) NiMlKWluZmluaXR5Rw== . . . . . . . . . . . . . . . . . . . . . . . . infinity NiMsJCUpaW5maW5pdHlHISIi . . . . . . . . . . . . . . . . . . . . . . . . - infinity i . . . . . . . . . . . . . . . . . . . . . . . . I Note: Maple is case sensitive so to indicate the number NiMlI1BpRw== , you must enter capital P and small i . Similiarly, Maple only recognizes I as the imaginary unit. All special numbers must be input exactly as described above. Variables: Almost any letter or string of letters and numbers can be used to name a variable. However, certain letters and strings have preassigned meanings and cannot be reassigned, e.g. D denotes the differential operator and cannot be used to name a variable quantity. Numerical Operations: Operation Maple syntax addition . . . . . . . . . . . . . . . . . . . . . . + subtraction . . . . . . . . . . . . . . . . . . . . - multiplication . . . . . . . . . . . . . . . . . . . * division . . . . . . . . . . . . . . . . . . . . . . . / exponentiation . . . . . . . . . . . . . . . . . . ^ factorial . . . . . . . . . . . . . . . . . . . . . . . ! Numerical Relations: Relation Maple syntax equality . . . . . . . . . . . . . . . . . . . . . . . . = inequality . . . . . . . . . . . . . . . . . . . . . . . . <> less than . . . . . . . . . . . . . . . . . . . . . . . . . . < greater than . . . . . . . . . . . . . . . . . . . . . . . > less than or equal to . . . . . . . . . . . . . . . . . < = greater than or equal to . . . . . . . . . . . . . . . > = Standard Functions: Function Maple syntax absolute value . . . . . . . . . . . . . . . . . . . . . . . abs square root . . . . . . . . . . . . . . . . . . . . . . . . . sqrt exponential . . . . . . . . . . . . . . . . . . . . . . . . . exp base e logarithm . . . . . . . . . . . . . . . . . . . . . ln or log sine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . sin cosine . . . . . . . . . . . . . . . . . . . . . . . . . . . . cos tangent . . . . . . . . . . . . . . . . . . . . . . . . . . . . tan cotangent . . . . . . . . . . . . . . . . . . . . . . . . . . cot secant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . sec cosecant . . . . . . . . . . . . . . . . . . . . . . . . . . . csc Note: The trigonometric functions assume radian measure. 7. Commands for Numerical Calculations We will write some basic commands for calculation using the symbols described above.3+4*9;

NiMiI1I=

(3+4)*9;

NiMiI2o=

3*exp(1)/4;

NiMsJC0lJGV4cEc2IyIiIiMiIiQiIiU=

(4/3)*Pi*r^3;

NiMsJComJSNQaUciIiIlInJHIiIkIyIiJUYo

12*ln(exp(2));

NiMiI0M=

sin(Pi/6);

NiMjIiIiIiIj

tan(Pi/4);

NiMiIiI=

abs(-17);

NiMiIzw=

sqrt(25)/(2^3);

NiMjIiImIiIp

4!-2*3*4;

NiMiIiE=

Note: Every Maple worksheet is organized into groups, ten of which are shown in the examples above. Each group can be identified by a tall left bracket " [ " appearing at the left edge of the window. 8. Commands for Decimal Representations of Real Numbers If you would like to obtain a decimal represenation for a particular real number, then use the command name called evalf. For example, considerevalf(5/8);

NiMkIisrKytdaSEjNQ==

evalf(3*exp(1)/4);

NiMkIityOHJRPyEiKg==

Normally, Maple will calculate the decimal number to ten significant digits. However, this can be changed using the command name called Digits. Digits:=25;

NiM+JSdEaWdpdHNHIiNE

evalf(3*exp(1)/4);

NiMkIjo6LV9FUkdXOFA2KFE/ISND

Notes: (i) Because Maple is case sensitive, "DIGITS": or "digits" would be viewed by this system as two different variables and would not effect the number of digits that Maple uses. (ii) The symbol " := " is the assignment sign. The value on the right is assigned to the variable on the left. If you were to leave out the " : ", then you would have an equation rather than an assignment. (iii) Once "Digits" has been assigned, it affects all subsequent decimal calculations until the next command "Digits:= . . . " or the end of the sesssion. Alternatively, you may specify a number of digits within an "evalf " command affecting only that calculation, by entering: > evalf ( number , digits ) ; For example, consider the following command which calculates NiMqKCIiJCIiIi0lJGV4cEc2I0YlRiUiIiUhIiI= to twenty significant digits: evalf(3*exp(1)/4,20);

NiMkIjVtI1JHVzhQNihRPyEjPg==

9. Commands involving Symbolic Calculations We will apply some commands to polynomial and rational expressions to simplify, expand or collect like terms. First, we construct a polynomial expression:8*x^2+16*x+6;

NiMsKCokSSJ4RzYiIiIjIiIpRiUiIzsiIiciIiI=

Observe that when Maple prints the polynomial it does so in ordinary math typeset without showing the " * " between the coefficients and the variable.%/(2*x+1);

NiMqJiwoKiRJInhHNiIiIiMiIilGJiIjOyIiJyIiIkYsLCZGJkYoRixGLCEiIg==

The symbol " % " stands for " the last output ", so the result of the above command is a rational expression.simplify(%);

NiMsJkkieEc2IiIiJSIiJyIiIg==

The command name simplify will often make a complicated expression simpler by finding cancellations. In the above command, Maple cancelled the common factor 2 x + 1 from numerator and denominator.expand((2*x+3)*(4*x+2));

NiMsKCokSSJ4RzYiIiIjIiIpRiUiIzsiIiciIiI=

The command name expand is used to write an expression as a sum of simple terms. In the above command, Maple expanded the product of the two linear expressions in x.collect(2*(x^2+x)+5*x+3+3*(2*x^2+3*x+1),x);

NiMsKCokSSJ4RzYiIiIjIiIpRiUiIzsiIiciIiI=

Observe that a command of the form > collect ( expression , variable ) ; will rewrite the given expression as a sum of coefficients times powers of the specified variable. 10. Commands to Assign Names or Values to Expressions It is often useful to assign names to mathematical expressions. This can always be accomplished with a command of the form > name : = expression ; which assigns to the variable called name the value expression . Here, expression may denote any mathematical expression. For example, consider the following calculations involving assigned variables: y:=8*x^2+16*x+6;

NiM+SSJ5RzYiLCgqJEkieEdGJSIiIyIiKUYoIiM7IiInIiIi

Y:=y/(2*x+1);

NiM+SSJZRzYiKiYsKCokSSJ4R0YlIiIjIiIpRikiIzsiIiciIiJGLiwmRilGKkYuRi4hIiI=

simplify(Y);

NiMsJkkieEc2IiIiJSIiJyIiIg==

Z:=y*Y;

NiM+SSJaRzYiKiYsKCokSSJ4R0YlIiIjIiIpRikiIzsiIiciIiJGKiwmRilGKkYuRi4hIiI=

Z1:=simplify(Z);

NiM+SSNaMUc2IiwkKiYsJkkieEdGJSIiIyIiJCIiIkYsLCgqJEYpRioiIiVGKSIiKUYrRixGLEYv

Z2:=expand(Z1);

NiM+SSNaMkc2IiwqKiRJInhHRiUiIiQiI0sqJEYoIiIjIiQ3IkYoIiQ/IiIjTyIiIg==

A command of the form > subs ( NiMmJSVleHByRzYjJSRvbGRH = NiMmJSVleHByRzYjJSRuZXdH , expr ) ; is used to substitute NiMmJSVleHByRzYjJSRuZXdH for NiMmJSVleHByRzYjJSRvbGRH in the expression called expr . For example, consider the following commands:subs(x=2, Z1);

NiMiJCEpKg==

subs(x=-3*v,Y);

NiMqJiwqKiQsJiokSSJ4RzYiIiIkISNJRigiJEgiIiIjIiIpRichJCFbRigiJWs/IiInIiIiRjIsKEYnISNnRigiJGUjRjJGMiEiIg==

11. Commands for Defining Functions The simplest way to define a function in Maple is with a mapping command of the form: > fcn : = var - > expr ; which assigns the name fcn to the mapping of the variable var into the expression expr (where, of course, expr involves var in the case that fcn is to be nonconstant). Consider the following examples:f:=x->x+abs(x);

NiM+SSJmRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLCY5JCIiIi1JJGFic0dJKnByb3RlY3RlZEdGMTYjRi1GLkYlRiVGJQ==

The function f can now be evaluated at any value of x by writing this value in parentheses. For instance,f(5);

NiMiIzU=

f(-4);

NiMiIiE=

f(a+b);

NiMsKEkiYUc2IiIiIkkiYkdGJUYmLUkkYWJzR0kqcHJvdGVjdGVkR0YqNiMsJkYkRiZGJ0YmRiY=

Note the difference between the function f defined above and the expression y defined in Maple by:y:=x+abs(x);

NiM+SSJ5RzYiLCZJInhHRiUiIiItSSRhYnNHSSpwcm90ZWN0ZWRHRis2I0YnRig=

To evaluate this expression y when x = 5, we must use the more complicated command :subs(x=5,y);

NiMsJiIiJiIiIi1JJGFic0dJKnByb3RlY3RlZEdGKDYjRiRGJQ==

simplify(%);

NiMiIzU=

However, we can convert an expression into a function with a command of the form: > fcn : = unapply ( expr , var ) ; which assigns the name fcn to the mapping of the variable var into the expression expr. For example, consider r:=unapply(y,x);

NiM+SSJyRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLCY5JCIiIi1JJGFic0dJKnByb3RlY3RlZEdGMTYjRi1GLkYlRiVGJQ==

r(5);

NiMiIzU=

Sometimes, we may need to represent a piecewise defined function in Maple. To illustrate one way of doing this, consider the following example. Suppose that NiMvLSUiZkc2IyUieEctJSpQSUVDRVdJU0VHNiU3JCokRiciIiMyRichIiI3JCwmRiciIiIhIiNGMjMxLCZGL0YyRidGLyIiITIsJkYnRjJGL0YyRjc3JCokRiciIiQlKm90aGVyd2lzZUc= In order to define this function f , we enter the following:f:=x->piecewise(-1>x, x^2,-1<=x and 1>x, x-2 , x^3);

NiM+SSJmRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLUkqcGllY2V3aXNlR0kqcHJvdGVjdGVkR0YuNicyOSQhIiIqJEYxIiIjMzFGMkYxMkYxIiIiLCZGMUY4ISIjRjgqJEYxIiIkRiVGJUYl

Observe that the first input within the piecewise command is the condition on the first piece of of the function, and the second input is the formula for that piece. You may input as many pieces as required. Note that the last input is the formula to be used when none of the specified conditions hold. Therefore, it is not necessary to specify conditions on the last part of the formula for f . To check our definition, we evaluate f at x .'f(x)'=f(x);

NiMvLUkiZkc2IjYjSSJ4R0YmLUkqUElFQ0VXSVNFR0YmNiU3JCokRigiIiMyRighIiI3JCwmRigiIiIhIiNGMzMxLCZGMEYzRihGMCIiITJGKEYzNyQqJEYoIiIkSSpvdGhlcndpc2VHRiY=

12. Commands for Solving Equations A command of the form > solve ( equa , var ) ; asks Maple to solve the equation equa in terms of the variable var. For example, considers:=solve(x^5+12*x^3-4*x=0,x);

NiM+SSJzRzYiNiciIiEsJCokLCYhIiciIiIqJCIjNSNGLCIiI0YwRi8hIiJGKSwkKiQsJkYrRixGLSEiI0YvRjFGMw==

Each of the four solutions listed above has a unique name. The first is denoted by s [ 1 ], the second by s [ 2 ] , . . . , and the fourth by s [ 4 ]. To verify this, enter one such name at a prompt sign.s[3];

NiMqJCwmISInIiIiKiQiIzUjRiYiIiNGKkYp

Observe that we get the eappropriate value : NiMsJC0lJXNxcnRHNiMsJiIiJyEiIiomIiIjIiIiLUYlNiMiIzVGLEYsRik= for s [ 3 ] . Maple can often solve equations which have an infinite number of solutions. Recall how the function r was defined above and consider the command:solve(r(x)=0,x);

NiMtSSpSZWFsUmFuZ2VHNiRJKnByb3RlY3RlZEdGJkkoX3N5c2xpYkc2IjYkLCRJKWluZmluaXR5R0YmISIiIiIh

However, sometimes it is too complicated for Maple to express all of the solution to an equation in terms of the usual operations of algebra.Solutions:=solve(x^6+12*x^3-4*x=0,x);

NiM+SSpTb2x1dGlvbnNHNiI2KCIiIS1JJ1Jvb3RPZkc2JEkqcHJvdGVjdGVkR0YrSShfc3lzbGliR0YlNiQsKCokSSNfWkdGJSIiJiIiIiokRjAiIiMiIzchIiVGMi9JJmluZGV4R0YqRjItRik2JEYuL0Y4RjQtRik2JEYuL0Y4IiIkLUYpNiRGLi9GOCIiJS1GKTYkRi4vRjhGMQ==

To find all possible values of an expression involving RootOf , we may use the command > allvalues ( expr ) ;### WARNING: allvalues now returns a list of symbolic values instead of a sequence of lists of numeric values evalf(allvalues(Solutions[2]));

NiMkIiteIil6R2QhIzU=

Observe that one pair of solutions to the fifth degree polynomial equation are complex conjugates of one another. Note also that Maple has given decimal approximation to the real and imaginary parts of all solutions to ten significant digits. Alternatively, we could have used the command > fsolve ( equ , var ) ; to find decimal representations for the real solutions.fsolve(x^6+12*x^3-4*x=0,x);

NiYkISthTFdQQSEiKiQhK2UhZTojZSEjNSQiIiFGKiQiK14iKXpHZEYo

For a nonpolynomial equation the solve and fsolve commands will not always yield all real solutions. In case we are interested in the particular solution to an equation which lies in the interval [ a , b ] , then we may try the following command : > fsolve ( equ , var , a . . b ) ; .solve(cot(Pi*x)=0,x);

NiMjIiIiIiIj

fsolve(cot(Pi*x)=0,x,1..2);

NiMkIisrKysrOiEiKg==

fsolve(cot(Pi*x)=0,x,10..11);

NiMkIisrKytdNSEiKQ==

13. Commands for Plotting I . Plotting Expressions In order to plot an expression involving a single variable over the interval [ a , b ] , we use a command of the form: > plot ( exp , var = a . . b ) ; For example, suppose y:=3*x^4-4*x^3;

NiM+SSJ5RzYiLCYqJEkieEdGJSIiJSIiJCokRihGKiEiJQ==

plot(y,x=-2..2);

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

Note that the general shape of this graph is not easily recognized due to the large values that y attains when x lies in the interval [ -2 , -1 ]. We can restrict the range of the plotted curve to the interval [ c , d ] by entering : > plot ( exp , var = a . . b , c . . d ) ; .plot(y,x=-2..2, -1..4);

LSUlUExPVEc2Ji0lJ0NVUlZFU0c2JDdYNyQkISIjIiIhJCIjISlGLDckJCEzeW1tbSJwMGsmPiEjPCQiMzNLeiFwXmItUighIzs3JCQhM01MTEwkUTZHIj5GMiQiM0AzNm9PS2k6b0Y1NyQkITMxKyt2My0pWyg9RjIkIjM0TnhWeTs6VmpGNTckJCEzYm1tO00hXHAkPUYyJCIzMXRPVillaWAqZUY1NyQkITMjKSoqKlw3WSJIJXoiRjIkIjMuYjFZRVg+P2FGNTckJCEzTUxMTCkpUWpePEYyJCIzV2p2OCNwYVIoXEY1NyQkITM8TExMYE5wMzxGMiQiM2VRXiJlKj15X1hGNTckJCEzQUxMTD1Ldmw7RjIkIjM1SD4iWydIYmVURjU3JCQhMysrK0RycCxCO0YyJCIzKUglRzNQeiE9eiRGNTckJCEzd21tO0MyRyFlIkYyJCIzWzFXem4pKVxcTUY1NyQkITNPTEwkM3lPNV0iRjIkIjM5VXBLaFh2dkdGNTckJCEzJioqKioqXG5VKSo9OUYyJCIzeTJdQVJPOGZCRjU3JCQhM1NMTCQzV0RUTCJGMiQiMy07aDNXQUMrPkY1NyQkITM1KytdZChRJlw3RjIkIjNEdXpaRHBzNjpGNTckJCEzZ21tbWM0YGk2RjIkIjNhLCoqZUZAU3c2RjU3JCQhM0tMTExRVyplMyJGMiQiMyE9MmI1I1w1JEgqRjI3JCQhM3crKysrKCk+JyoqKiEjPSQiMyV6ciYzOTcpMypwRjI3JCQhM0UrKysrMCIqSCIqRl5xJCIzLCNIVjljTSZHXkYyNyQkITM1KysrKzgzJkgpRl5xJCIzSWFAcTM+WS5QRjI3JCQhM1xMTEwzayhwYChGXnEkIjM/bixoeCNmMW8jRjI3JCQhM0FubW1tal5ObUZecSQiM292IXlWXlYtdiJGMjckJCEzKXptbW1ZaD0oZUZecSQiM2MpW2x2TWBrOyJGMjckJCEzKywrK3YjXE4pXEZecSQiM2FFLz5dYUQsb0ZecTckJCEzY29tbW1DQyg+JUZecSQiMzckUT5vSFkoKSlRRl5xNyQkITM5KioqKipcRlJYTCRGXnEkIjNnUWMnM2knKlImPUZecTckJCEzdCoqKioqXCM9LzhERl5xJCIzSlk7KTRHWFthKCEjPjckJCEzPW1tbTthKmVsIkZecSQiMylwKD4wUld0VD9GXnQ3JCQhM2tvbW07V24obylGXnQkIjMpcGRJNDpJUHojISM/NyQkITNJcUxMTCRlVig+Rml0JCIzJzMtIjR5KFxJMyQhI0Q3JCQiMylRam1tImZgQCcpRl50JCEzJXl4OT0xTHdSI0ZpdDckJCIzJXoqKioqXG5aKUg7Rl5xJCEzTWs0J0giKT0sXyJGXnQ3JCQiM2NrbW07JHkqZUNGXnEkITNZZDUmSERFMCZbRl50NyQkIjNmKSoqKioqKlJeYkokRl5xJCEzKz4peXM9b2A0IkZecTckJCIzJ2UqKioqKlw1YWBURl5xJCEzSXAyZk9dUHQ+Rl5xNyQkIjMnbyoqKipcN1JWJ1xGXnEkITM/JltZVk0rPDIkRl5xNyQkIjNZJyoqKioqXEBma2VGXnEkITN5KHlrXCJRVD5YRl5xNyQkIjNfSUxMTCY0Tm4nRl5xJCEzI3AqKilSNDU0UWZGXnE3JCQiM0EqKioqKioqXCxzYChGXnEkITNNLV1wYzxWWHVGXnE3JCQiMyVbbW07ek0pPiQpRl5xJCEzKXp6T2U8aTxtKUZecTckJCIzTSoqKioqKipwZmE8KkZecSQhMy5UKUgpPiZSYmoqRl5xNyQkIjM5SExMZWdgISkqKkZecSQhM1UyKGZDR3QoKioqKkZecTckJCIzdyoqKipcI0cyQTMiRjIkITMlKT5RcVJHcVsmKkZecTckJCIzO0xMTCQpR1trNkYyJCEzcU44QmJEdykqekZecTckJCIzIykqKioqXDd5aF03RjIkITNFVmgrO0MhUSZbRl5xNyQkIjN4bW1tJylmZEw4RjIkIjM3JD0/bDJ4a3MiRml0NyQkIjNibW1tLEZUPTlGMiQiMzsvZkFaPHMkRyhGXnE3JCQiM0ZMTCRlI3BhLTpGMiQiM1NRKnlRb0g/cyJGMjckJCIzISoqKioqKipSdiYpejpGMiQiM21OdGZzaEo7SEYyNyQkIjNJTExMR1VZbztGMiQiM1tNdUN1Q25wWUYyNyQkIjNfbW1tMV5yWjxGMiQiM3QiUmdDTD5raidGMjckJCIzNCsrXXNJQEs9RjIkIjNiLCMzZWpdYT8qRjI3JCQiMzQrK10yJSkzOD5GMiQiM1FPbmd4ZXk8N0Y1NyQkIiIjRiwkIiM7RiwtJSZDT0xPUkc2JiUkUkdCRyQiIzUhIiIkRixGXl1sRl9dbC0lK0FYRVNMQUJFTFNHNiRRIng2IlEhRmRdbC0lJUZPTlRHNiQlKkhFTFZFVElDQUdGXV1sLSUlVklFV0c2JDskRml0Rl5dbCQiIz9GXl1sOyQhIzVGXl1sJCIjU0ZeXWw=

II . Plotting Continuous Functions of One Variable We use a command of the form > plot ( fcn , a . . b ) ; to plot the function called fcn over the interval [ a , b ] . Consider the following example.h:=t->abs(t)^(1/3)*signum(t);

NiM+SSJoRzYiZio2I0kidEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlKiYtSSRhYnNHSSpwcm90ZWN0ZWRHRi82IzkkIyIiIiIiJC1JJ3NpZ251bUc2JEYvSShfc3lzbGliR0YlRjBGM0YlRiVGJQ==

Recall that the signum function , denoted by sgn , is defined byNiMvLSUkc2duRzYjJSJ0Ry0lKlBJRUNFV0lTRUc2JTckIiIiMiIiIUYnNyRGLi9GJ0YuNyQhIiIyRidGLg== Therefore, we can express the function h more simply as: h ( t ) = NiMpJSJ0RyomIiIiRiYiIiQhIiI= .plot(h,-10..10);

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

Analogous to the case of expressions, we may restrict the plot of the range of a function to the interval [ c , d ] , by entering > plot ( fcn , a . . b , c . . d ) ; .plot(h,-10..10,-1.5 .. 1.5);

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

III . Plotting Functions of One Variable Possessing Jump Discontinuities Recall the piecewise defined function f from the example in Section 11 :f:=x->piecewise(-1>x, x^2,-1<=x and 1>x, x-2 , x^3);

NiM+SSJmRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLUkqcGllY2V3aXNlR0kqcHJvdGVjdGVkR0YuNicyOSQhIiIqJEYxIiIjMzFGMkYxMkYxIiIiLCZGMUY4ISIjRjgqJEYxIiIkRiVGJUYl

plot(f,-3..2);

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

Because the plot command joins each ordered pair ( x , y ) that it computes to the next one, the graph appears to have vertical segments at the points of discontinuity x = -1 and x = +1 . To correct this problem, we may use the option " discont = true " in the plot command for an expression .plot(f(x),x=-3..2,discont=true);

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

IV . Plotting Several Functions or Expressions Together The forms of the commands for plotting several functions or expressions together are analogous to those described above in III. However, the set of functions/expressions to be plotted must be enclosed by curly braces " { } " within the plot command. Consider the following examples: ( i ) Plotting two or more expressions togetherw:=3*x^4-4*x^3-12*x^2+5;

NiM+SSJ3RzYiLCoqJEkieEdGJSIiJSIiJCokRihGKiEiJSokRigiIiMhIzciIiYiIiI=

v:=10*x^3-43*x;

NiM+SSJ2RzYiLCYqJEkieEdGJSIiJCIjNUYoISNW

plot({w,v},x=-2..2);

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

( ii ) Plotting two or more functions togetherg:=x->x^2;

NiM+SSJnRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlKiQ5JCIiI0YlRiVGJQ==

h:=x->x^3;

NiM+SSJoRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlKiQ5JCIiJEYlRiVGJQ==

plot({g,h},-2..2);

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

( iii ) Plotting functions and expressions togetherplot({g(x),h(x),w,v},x=-2..2);

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

V. Plotting Equations in Two Variables The command name implicitplot is located in Maple's "plots" package and is used to graph equations for which one variable is not readily expressible as a function of the other. To read in the "plots" package, we enter the command > with(plots) : . This package only needs to be read in once during a Maple session, after which, you can use all the functions from this package. Now the general form of the equation plotting command is given by: > implicitplot( equ , NiMmJSR2YXJHNiMiIiI= = a . . b , = c . .var[1] d ) ; where equ denotes the equation to be plotted over the ranges [ a , b ] and [ c , d ] for the variables NiMmJSR2YXJHNiMiIiI= and NiMmJSR2YXJHNiMiIiM= respectively. Consider the following example. equ:=x^4+y^4-4*(y^3+x^2+x^2*y)+2*x^2*y^2=0;

NiM+SSRlcXVHNiIvLC4qJEkieEdGJSIiJSIiIiokSSJ5R0YlRipGKyokRi0iIiQhIiUqJEYpIiIjRjAqJkYpRjJGLUYrRjAqJkYpRjJGLUYyRjIiIiE=

with(plots):y:='y':implicitplot(equ,x=-3..3,y=-1..4);

-%%PLOTG6%-%'CURVESG6gt7$7$$!3d************>D!#<$"3i/<1pD:r"*!#=7$$!3RH#*[SpTQDF,$"""""!7$F07$$!3`W9gx#p4a#F,$"3)R?,!)Ruu,"F,7$7$$!3S8BSy9apDF,$"3%**************>"F,F77$F=7$$!35J()zdI#>d#F,$"3:wA$[@pKC"F,7$7$$!3')4hu4hu&e#F,$"3!**************R"F,FC7$FI7$$!3k[v&)p'>Oe#F,$"3Edza"R;IX"F,7$7$$!3ah&RpN;he#F,$"33+++++++;F,FO7$FU7$$!3Sp_m'G)HzDF,$"3cCx))Q_T\;F,7$7$$!35h$p0h@2d#F,$"3#)*************z"F,Fen7$F[o7$$!3Ie!*HrXNiDF,$"31\D3waHN=F,7$7$$!3$*RM#fe1/a#F,$"3y**************>F,Fao7$Fgo7$$!3>/@3nB%f`#F,$"3Z`<!fI&G8?F,7$7$F*$"3Y,(>:V!p)3#F,F]p7$7$$!3O************zAF,$"3UG#45a">zNF/7$$!3R7BL6Uv,BF,$"3m**************RF/7$7$$!3&>JK8@a<I#F,F_q7$$!3*f8bif1wJ#F,$"3xQh7-$)Q8VF/7$7$$!3)>LNG?U\R#F,$"3m)*************fF/Feq7$7$F\r$"3w**************fF/7$$!3S1nN[iNfCF,$"3EfD(HSNY\(F/7$7$$!3k%f>exy%zCF,$"3U+++++++!)F/Fdr7$7$F[s$"3a,++++++!)F/F)7$Fcp7$$!3w>c_\J!4\#F,$"3A$o/Yi_d<#F,7$7$$!3c0%)HrLo'[#F,$"3s*************>#F,Fds7$Fjs7$$!3"\>^pZ*=ICF,$"3WH$fu*y:DBF,7$7$$!3Z@uc>>)*4CF,$"3!**************R#F,F`t7$Fft7$$!3K9"3Cp"RoBF,$"37HMnV(fOZ#F,7$7$$!3x5`WtF8ABF,$"33+++++++EF,F\u7$Fbu7$$!3*fCRS,$)pI#F,$"3x0F.Xe[AEF,7$7$Fhp$"3u,K'3m.4o#F,Fhu7$7$$!3:************R?F,$"3^s*>F_.QW%!#>7$$!3'=v<ny[u:#F,$"3a**************>F/7$FhvFgp7$F^v7$$!3imH&H>OgA#F,$"3WRTzg,.bFF,7$7$$!3i"["["["G0AF,$"3E+++++++GF,F_w7$7$$!3="["["["G0AF,Fhw7$$!3<'=A;C`m8#F,$"3Y*[=!oVa!)GF,7$7$$!3Yu!oN[pw1#F,$"3W+++++++IF,F^x7$Fdx7$$!3UoUi,BIb?F,$"3"\A?!=>v7IF,7$7$Fcv$"3rr**3^,#\.$F,Fjx7$7$$!3;*************z"F,$!3v7l4UZ:2<F/7$$!3%oI)fGU^))>F,$!3s#yDJ7:6b&!#M7$7$$!3i1$)fGU^))>F,F\zFbv7$F`y7$$!3/_`rZ")HY>F,$"3SGh4B^">7$F,7$7$$!3!*y*)[!G\"*)=F,$"3g+++++++KF,Fdz7$7$$!3oy*)[!G\"*)=F,$"3;+++++++KF,7$$!3C*Q_!G#3W%=F,$"3%eK5n&o+PKF,7$7$Fey$"3;raAf*)G)G$F,Fe[l7$7$$!3;************f:F,$!3)[!)=(4!=!yJF/7$$!3[\of"yp2v"F,$!3m+++++++?F/7$Fd\l7$$!3#*)************z"F,$!3Z7l4UZ:2<F/7$7$$!3Q*************z"F,F\\l7$$!3@P.ef$3'G<F,$"35\pJmp]SLF,7$7$$!3=M8i^gPs;F,$"3C,++++++MF,Fc]l7$7$Fj]l$"3y+++++++MF,7$$!3+S-z)>f'4;F,$"3!\`ecm#QTMF,7$7$F`\l$"3I'Q&=)Hoj[$F,Fb^l7$7$$!3S************>8F,$!3nD\K1%*z=UF/7$$!3-Vsuhozq8F,$!3y+++++++SF/7$7$Fb_l$!3M,++++++SF/F_\l7$7$F`\l$"3'eQ&=)Hoj[$F,7$$!3G+qCzP1z9F,$"3)>]s$\JbKNF,7$7$$!3!>;^Yg=\R"F,$"3'4++++++g$F,F^`l7$7$Fe`l$"3_+++++++OF,7$$!3_Ktf2:!)[8F,$"3976Lc7+COF,7$7$$!3<************>8F,$"3tj&)[^T2WOF,F]al7$7$FdalF__l7$$!3U+H2[*p\F"F,$!3[BesK/DvVF/7$7$$!3=************z5F,$!3!eA![p&eDu%F/Fjal7$7$Fdal$"3Hj&)[^T2WOF,7$$!3_Xv0f%os>"F,$"35!H")erBxp$F,7$7$Fabl$"3_,,,zY9nPF,Fibl7$7$Fabl$!3DD-[p&eDu%F/7$$!3eFC%p?]Fm*F/$!3]/8)3;3x%\F/7$7$$!3#>************R)F/$!3Y!>j#eA+$)[F/Ffcl7$7$Fabl$"33,,,zY9nPF,7$$!3!p?lUr7B0"F,$"3Ouw)=EFpx$F,7$7$$!3h@dgozR/5F,$"3;,++++++QF,Fedl7$7$F\el$"3q+++++++QF,7$$!3-#QP\Q+0'))F/$"3q;"y?.v$QQF,7$7$F]dl$"3%=T4N#e#y&QF,Fdel7$F\dl7$$!3q!GO])=#\H(F/$!3hEk8H%)*3#\F/7$7$$!3+#*************fF/$!3!))y4-z4-f%F/F^fl7$7$F]dl$"3Q6%4N#e#y&QF,7$$!3w#*yy4n,#3(F/$"3W#**["f!o,*QF,7$7$Fefl$"3;!=LrNWY#RF,F]gl7$7$Fefl$!3C)y4-z4-f%F/7$$!3:qg/")fPV`F/$!3_-;Y#o'=ZXF/7$7$$!3GRwrIi"))y$F/Fd_lFjgl7$7$$!3%)RwrIi"))y$F/$!3A+++++++SF/7$$!3#Ge$[p#p*pOF/$!3%=MIaF#pTRF/7$7$$!33#************f$F/$!39y%o%ejP\QF/Fihl7$7$Fefl$"3szJ8dVkCRF,7$$!3y2gv<-WX_F/$"3FNj9=+7PRF,7$7$F`il$"3)*>\^Xb6sRF,Fhil7$7$$!3_"************f$F/$!3ex%o%ejP\QF/7$$!3ev#**G#yv(>#F/$!3GJReZ^`oJF/7$7$$!3=#************>"F/$!37#)GYA`d%3#F/Fgjl7$F^jl7$$!3%))3='f$4fH$F/$"3-4:I8"fY(RF,7$7$$!3/#************>"F/$"3!=U[Gkco*RF,Fc[m7$7$F^[m$!3o#)GYA`d%3#F/7$$!3wLX/8'4&)4"F/F`\m7$7$$"3s2++++++7F/$!3+"*GYA`d%3#F/Fb\m7$7$F^[mF\\m7$$!3cV5=9(zA;"F/F\\m7$7$$"3'y++++++?"F/F\\mF]]m7$7$Fg\m$!3s!*GYA`d%3#F/7$$"3CJlvfN4o=F/$!3?P/8LYucDF/7$7$$"3i2++++++OF/$!39)[o%ejP\QF/Fh]m7$7$Fg\mF\\m7$$"3R))HmYF/U7F/$"3#e3yxV'\'*RF,7$7$F_^mF_jlFe^m7$7$$"3a2++++++gF/$!3e"z4-z4-f%F/7$$"31UwrIi"))y$F/Fd_l7$7$Fc_mFh_lF^^m7$7$F_^m$"3_>\^Xb6sRF,7$$"3'=)z\^0RASF/$"3%)p^P(y+['RF,7$7$F^_mFfilF[`m7$F]_m7$$"3//9B())[1n'F/$!3=JGpsS()eXF/7$7$$"3Y2++++++%)F/F_dlFc`m7$Fa`m7$$"3yBxN8V1>tF/$"3/eo)Q(z2!*QF,7$7$Fj`m$"3%4T4N#e#y&QF,F]am7$Fi`m7$$"3S)=J;`D$>#*F/$!3y=$fjFrFo%F/7$7$$"3u++++++!3"F,$!3.B-[p&eDu%F/Fgam7$7$F^bm$"3k+,,zY9nPF,7$$"3%=s0'ozR/5F,F^el7$Ffbm7$$"3c3++++++%)F/F[gl7$F]bm7$$"35@wbQGOP6F,$!3sPokaO-yWF/7$7$$"3t++++++?8F,$!3B@\K1%*z=UF/F^cm7$Fcbm7$$"33eOtb&4e<"F,$"3b'GbNqe,s$F,7$7$Fecm$"3%Gc)[^T2WOF,Fjcm7$Fdcm7$$"3(GT/:f$[M8F,$!3&>5qef'p?TF/7$7$$"3YVsuhozq8F,Fd_lFddm7$7$$"3CVsuhozq8F,Fh_l7$$"3]Cu?"p!)=["F,$!37m=1gd+\LF/7$7$$"3s++++++g:F,$!3+'z=(4!=!yJF/Faem7$7$Fhem$"3_%Q&=)Hoj[$F,7$$"37i6l/'=\R"F,Fg`l7$7$Fafm$"3U,++++++OF,F`dm7$Fgem7$$"3b3QDU-?H;F,$!3++%[aoomd#F/7$7$$"3/\of"yp2v"F,Fg\lFhfm7$F^gm7$$"3')4!=^*)egx"F,$!36x+l#z!\+=F/7$7$$"3q+++++++=F,$!3)**\'4UZ:2<F/Fbgm7$7$Figm$"3EqaAf*)G)G$F,7$$"3=M8i^gPs;F,F`^l7$7$Fbhm$"3M+++++++MF,7$$"3]++++++g:F,F^fm7$Fhgm7$$"3[!p!)yM<l)=F,$!3*)*\d+**y(4sFgv7$7$$"3S1$)fGU^))>F,F\zF\im7$Fbim7$$"3@3igYQk5?F,$"3iq$\h6YjW#Fgv7$7$$"3#4++++++/#F,$"3@x,sAN!QW%FgvFfim7$7$F]jm$"3$*p**3^,#\.$F,7$$"3Yy*)[!G\"*)=F,Fc[l7$7$FfjmF][lF^hm7$7$F]jm$"3^w,sAN!QW%Fgv7$$"3<okA4@#e5#F,$"3ksF6BC[^9F/7$7$$"3'=v<ny[u:#F,F[wF^[n7$Fd[n7$$"3'fVXEl"p*>#F,$"3#)3Z&zAO#pEF/7$7$$"39,+++++!G#F,$"3Gd#45a">zNF/Fh[n7$7$F_\n$"3?)>j3m.4o#F,7$$"3="["["["G0AF,Fhw7$Fg\n7$$"3.)eqU@w=6#F,$"376XxaJ5SHF,7$7$$"3Yu!oN[pw1#F,FgxF[]n7$Fa]n7$F]jm$"3\p**3^,#\.$F,7$7$F_\n$"3uc#45a">zNF/7$$"33eu!ps5VH#F,$"3/iyVURu!)QF/7$7$$"3R7BL6Uv,BF,F_qF\^n7$Fb^n7$$"3Ys\$=9c#fBF,$"32Q_P^@`R`F/7$7$$"3UK`$G?U\R#F,FbrFf^n7$7$$"3)>LNG?U\R#F,F^r7$$"3O@_*y=L^U#F,$"3gK)Rvwc0z'F/7$7$$"3?%f>exy%zCF,FasFc_n7$7$Fj_nF]s7$$"3o!**)o)f'>)[#F,$"3Q>%eUMG]E)F/7$7$$"3N,+++++?DF,$"37q<1pD:r"*F/F^`n7$7$Fe`n$"3O%p>:V!p)3#F,7$$"370%)HrLo'[#F,F]t7$F]an7$$"3aH(HD\8aZ#F,$"32$*=*GUbrB#F,7$7$$"3e?uc>>)*4CF,$"3Y*************R#F,Faan7$7$$"3Z@uc>>)*4CF,Fit7$$"3q&Q]%3KM_BF,$"3.8!eH*RrRDF,7$7$$"3x5`WtF8ABF,FeuF`bn7$FfbnFd\n7$7$Fe`n$"3-p<1pD:r"*F/7$$"3+x490!4a`#F,$"3S/_#Qi"fr)*F/7$7$$"3$)H#*[SpTQDF,F3F^cn7$7$$"3RH#*[SpTQDF,F37$$"35:dU3M@kDF,$"3!>dyH\bJ;"F,7$7$$"3S8BSy9apDF,F@F[dn7$Fadn7$$"3KC$f()oUHe#F,$"3#4Bn$fxaZ8F,7$7$$"3')4hu4hu&e#F,FLFedn7$7$$"3I5hu4hu&e#F,FL7$$"3]Ah<NRH)e#F,$"3<KKN(Q)3V:F,7$7$$"35h&RpN;he#F,FXFben7$7$Fien$"3')*************f"F,7$$"3#[a'GjQ'od#F,$"3g87EZMh_<F,7$7$$"3ah$p0h@2d#F,F^oF_fn7$Fefn7$$"3**3E&e(f)\a#F,$"3yfhX`$y"z>F,7$7$$"3$*RM#fe1/a#F,FjoFifn7$7$F`gn$"3c**************>F,Fj`n-%&COLORG6&%$RGBG$"#5!""$F5F\hnF]hn-%+AXESLABELSG6$Q"x6"Q"yFbhn-%%FONTG6$%*HELVETICAGF[hn

Note that this graph is not very accurate. Clearly, ( 0 , 0 ) is a point which satisfies the equation and yet the graph does not pass through the origin. We can use the option grid = [ NiMmJSRpbnRHNiMiIiI= , NiMmJSRpbnRHNiMiIiM= ] to increase the grid size of the plot. The default size is [25, 25] .implicitplot(equ,x=-3..3,y=-1..4,grid=[85,85]);

-%%PLOTG6%-%'CURVESG6b\m7$7$$!3Gq&G9dG9d#!#<$"3ekVe5sd_6F,7$$!3;))z6*o]#yDF,$"3b_4Q_4Q-7F,7$F/7$$!3M?7ZFD"*yDF,$"3U%\;Ce<'37F,7$7$$!3%G\6I*R)\e#F,$"33iZ!>w/>E"F,F57$F;7$$!3]qnfv,'fe#F,$"3[G\/KW,u7F,7$7$$!39?h$=ja-f#F,$"3ir&G9dG9K"F,FA7$FG7$$!3?p#onqa6f#F,$"3;()\a<q'yL"F,7$7$$!3[;`#>$p.%f#F,$"39"Q_4Q_4Q"F,FM7$FS7$$!3#\(fh0%)e%f#F,$"3V=_xUAD+9F,7$7$$!3'*eUW<[J'f#F,$"3p!>w/>w/W"F,FY7$Fin7$$!3y2G[A%ejf#F,$"3-AZNm5Dh9F,7$7$$!3W2#)='f"3(f#F,$"3A+++++++:F,F_o7$Feo7$$!3]qkwIac'f#F,$"3"Qe"y#QZ4_"F,7$7$$!3kE!pp^Rjf#F,$"3w4Q_4Q_f:F,F[p7$Fap7$$!31Q(RGA7`f#F,$"3k\kO_oUz:F,7$7$$!3OAd.L"*4%f#F,$"3H>w/>w/>;F,Fgp7$F]q7$$!3_M,Y:Bq#f#F,$"3gAR2RdxO;F,7$7$$!3c6$=;^y.f#F,$"3#)G9dG9dy;F,Fcq7$Fiq7$$!3=*yaWiQ))e#F,$"3!zF$41)zIp"F,7$7$$!3eR&=BL-_e#F,$"3OQ_4Q_4Q<F,F_r7$Fer7$$!3M@wWbA#Qe#F,$"3Y9663LU[<F,7$7$$!3aU."p"4gyDF,$"37[!>w/>wz"F,F[s7$7$Fbs$"3)y/>w/>wz"F,7$$!3S%e!zV9vxDF,$"3SE2#z5))G!=F,7$7$F*$"3Y/__d)=4&=F,Fjs7$7$$!3m)************\#F,$"3.a'p6Q!*4T)!#=7$$!31>!Q2CJ7]#F,$"3aa4Q_4Q_%)Fit7$Fjt7$$!3u7@Ckgg,DF,$"3?R_1@[wl%)Fit7$7$$!3[;hR7(pw^#F,$"3!*\!>w/>w/*FitF`u7$Ffu7$$!3\)p"*f`rC_#F,$"3i!))\v%=)[B*Fit7$7$$!3/**oF%[XG`#F,$"3NYr&G9dGk*FitF\v7$Fbv7$$!3M![$RY&G2a#F,$"3ach8'phA)**Fit7$7$$!316d2jamYDF,$"3&R_4Q_4Q-"F,Fhv7$F^w7$$!3;i:-ngUcDF,$"3g$\FjCJ32"F,7$7$$!3y!))\<AW!fDF,$"3[LLLLLL$3"F,Fdw7$7$$!3A"))\<AW!fDF,F]x7$$!3?(R')*=eipDF,$"3DK`:\[NT6F,7$7$$!3WU*[7w0*pDF,$"3-Vr&G9dG9"F,Fcx7$FixF)7$F`t7$$!39PFs9XfqDF,$"3i'*z))4yWc=F,7$7$$!3;v-#['=^qDF,$"3UdG9dG9d=F,F`y7$Ffy7$$!3;kleL:JhDF,$"3vG$)z,eB3>F,7$7$$!3M=#)e"*43gDF,$"3'pmmmmmm">F,F\z7$Fbz7$$!3yeyz1p:^DF,$"3-]:LAuHf>F,7$7$$!3!)RSwqCB[DF,$"3]w/>w/>w>F,Fhz7$7$$!3ORSwqCB[DF,$"3Gw/>w/>w>F,7$$!3q#=(>xCBSDF,$"3Mj9_Svr4?F,7$7$$!3%)4#pwvB]`#F,$"3.'G9dG9d.#F,Fi[l7$F_\l7$$!3=a:ef@jGDF,$"37:*)p=Wdf?F,7$7$$!32ou39E^?DF,$"3M&4Q_4Q_4#F,Fe\l7$F[]l7$$!35`V;X=W;DF,$"3fd](GjR*3@F,7$7$$!3cBio5iv/DF,$"3m/>w/>wa@F,Fa]l7$Fg]l7$$!3\XGJ'[RP]#F,$"3uVfNV"yy:#F,7$7$Fet$"3E%HcSF?6<#F,F]^l7$7$$!30F9dG9dGCF,$"3:%4%\s_$=W'Fit7$$!3xXEr.DXPCF,$"3ipmmmmmmmFit7$7$F]_l$"3_ommmmmmmFit7$$!3ZLJfeNjTCF,$"3I))3=]x^vnFit7$7$$!3c^FCB1')fCF,$"3'Qw/>w/>E(FitFe_l7$F[`l7$$!3i%*\&o!)oLZ#F,$"3!)f6gZi@NwFit7$7$$!3e>.^]fA"[#F,$"3?fG9dG9dyFitFa`l7$Fg`lFdt7$Fc^l7$$!3E2@B1K+*[#F,$"3rP"z%><70AF,7$7$$!3'o/a8>sk[#F,$"3(Rr&G9dG9AF,F^al7$Fdal7$$!3Yz1Z?!yKZ#F,$"3!44Nv?T:D#F,7$7$$!3'*p(*>\H[mCF,$"3GB&4Q_4QF#F,Fjal7$F`bl7$$!33)\tsxysX#F,$"3C#e%R9Bt(H#F,7$7$$!3%oHg_0'QXCF,$"3fKLLLLLLBF,Ffbl7$F\cl7$$!3G*Qd(yQ1TCF,$"3F,$)[3PuVBF,7$7$Fh^l$"371l:dq;yBF,Fbcl7$7$$!3UbG9dG9dBF,$"3qs@W#4T)3\Fit7$$!3MZY2?]>%Q#F,$"3#yZ!>w/>waFit7$Fadl7$$!3`NTLgCk,CF,$"3#oZ%y-0-ZeFit7$7$$!3/LH(Q%\">T#F,$"3;t&G9dG92'FitFgdl7$F]el7$Fh^l$"3E&4%\s_$=W'Fit7$Fhcl7$$!3C`,R;O.CCF,$"3[!31Fjv!*Q#F,7$7$$!3Nx')zMInACF,$"3!>9dG9dGR#F,Fgel7$F]fl7$$!3B#*e*=.f[S#F,$"3)f+==i?EV#F,7$7$$!3_T#*yfn9(R#F,$"3A^4Q_4Q_CF,Fcfl7$Fifl7$$!3Q=NK:4s&Q#F,$"3%p$['3+'>wCF,7$7$$!3-cT7k+qqBF,$"3`gZ!>w/>^#F,F_gl7$7$Ffgl$"3(4w/>w/>^#F,7$$!3oL'\sU\mO#F,$"3H4/m.p#)>DF,7$7$F]dl$"3IfAD4@"4a#F,F^hl7$7$$!3#QG9dG9dG#F,$"3;!H,Ke#*4k$Fit7$$!3Cb*>4o(e)G#F,$"3!H>w/>w/p$Fit7$7$F^il$"3M#>w/>w/p$Fit7$$!3))z$=')*eF"H#F,$"3:&*pnkH#ot$Fit7$7$$!3h@T<vj@ABF,$"3q(G9dG9dG%FitFfil7$F\jl7$$!3E!))z#G7OaBF,$"3m)eF/9sx&[Fit7$7$$!3U>Yc.yibBF,$"3/$Q_4Q_4)[FitFbjl7$7$$!3)*=Yc.yibBF,$"3[#Q_4Q_4)[FitF\dl7$Fdhl7$$!3+OO(\qChM#F,$"3=?U&zxYAc#F,7$7$$!32B!y>-y>M#F,$"3%)p&G9dG9d#F,Fd[m7$Fj[m7$$!3=F)o:l0VK#F,$"3">-uH/)e.EF,7$7$$!3;P$RTGv5J#F,$"3;zB&4Q_4j#F,F`\m7$Ff\m7$$!3LD!Qin*y-BF,$"3C(\bI(==XEF,7$7$Fihl$"3S=kk_)G$yEF,F\]m7$7$$!3>7dG9dG9AF,$"3Gnl`gHt_DFit7$$!3mK6$QUF)\AF,$"3c(4Q_4Q_4$Fit7$7$$!3AK6$QUF)\AF,$"3+(4Q_4Q_4$FitFhhl7$7$Fihl$"3'zTYE&)G$yEF,7$$!3SwC1Bq!4G#F,$"3%*[jEQ,Z'o#F,7$7$$!3cQ>Ss'H)yAF,$"3Y)=w/>w/p#F,Fj^m7$F`_m7$$!3O8(f1**HnD#F,$"3)e&yy?k%es#F,7$7$$!3]"[-JP*RVAF,$"3A)***********\FF,Ff_m7$7$$!31"[-JP*RVAF,$"3y(***********\FF,7$$!3$R!GOG83LAF,$"3M24t6ImlFF,7$7$Fg]m$"31zPY^Nz(z#F,Fg`m7$7$$!3dSr&G9dG9#F,$"3)*Hn"zATIg"Fit7$$!3Wc'f*yv\l@F,$"3K1>w/>w/>Fit7$Ffam7$$!3()4sjXN3/AF,$"3zY"Hz#>)\T#Fit7$7$$!3#oz$oE:O5AF,$"3m,++++++DFitF\bm7$FbbmFf]m7$F]am7$$!3%oj"R4*R#4AF,$"3qx?6s*=`!GF,7$7$$!3Ia\v*R_n?#F,$"342Q_4Q_4GF,Fibm7$F_cm7$$!3G:X:mX3$=#F,$"3]>;Fim/VGF,7$7$$!3Uf2"*>zzm@F,$"3S;w/>w/pGF,Fecm7$F[dm7$$!3ASoc_vld@F,$"3_*p0QH"Q")GF,7$7$Fbam$"3;"Ha&e!yP!HF,Fadm7$7$$!3'*o&G9dG92#F,$"3%z!3,EU/cv!#>7$$!3%\NX\$z%z6#F,$"3)4"Q_4Q_48Fit7$7$$!3\a`%\$z%z6#F,FdemFaam7$Fgdm7$$!3<<V*>R\88#F,$"3pRd=O;)*=HF,7$7$$!3+xfnwF"\7#F,$"3sD9dG9dGHF,F[fm7$Fafm7$$!3Q%*>()3Gi.@F,$"3Q!Gu(f**RbHF,7$7$$!3'f#zYsW\!3#F,$"3/N_4Q_4))HF,Fgfm7$F]gm7$$!3u9In1&)yw?F,$"3+S*)z]=c#*HF,7$7$F\em$"3'yFx$zTx**HF,Fcgm7$7$$!3c(*************>F,$"37"ySw66Q$G!#@7$$!3<fx$*)ef4,#F,$"37/iZ!>w/>"F`em7$7$Fdhm$"3G/iZ!>w/>"F`em7$$!3)pFu^?LL0#F,$"3Yn%**\&*4\j&F`em7$7$$!3'GZ?yz)\n?F,$"3Mcr&G9dG9(F`emF\im7$7$$!3Us/#yz)\n?F,FeimF[em7$Figm7$$!3G/k/n0iZ?F,$"3HSs'R/zx-$F,7$7$$!3Z$o2(=UeK?F,$"3yW!>w/>w/$F,F\jm7$7$Fcjm$"3MW!>w/>w/$F,7$$!3f>l-Hys=?F,$"3u7y!=dDK1$F,7$7$$!3M(*************>F,$"3%4fdtIqn3$F,F[[n7$7$$!3QE9dG9dG>F,$!3%R#["=#)\ft'F`em7$$!31[8e2oC\>F,$!3wZZ!>w/>w%F`em7$7$$!3#yM"e2oC\>F,F_\nF]hm7$7$F^hm$"3S"fdtIqn3$F,7$$!3Ic[?))yW*)>F,$"3#G!pkI%\$)4$F,7$7$$!3qsaxS2I#)>F,$"35aG9dG92JF,Fi\n7$7$$!3#HZv2u+B)>F,Fb]n7$$!3%>Rw%Q0be>F,$"3<D.t[a7KJF,7$7$$!31^%ocv:"H>F,$"3'Hmmmmmm;$F,Fh]n7$F^^n7$$!3!H?!fn(p)G>F,$"3oVc^#G:p;$F,7$7$$!3;E9dG9dG>F,$"3A"*)4C7]s;$F,Fd^n7$7$$!3aaG9dG9d=F,$!3u#)QG$>VPG"Fit7$$!39(*R?%p8=)=F,$!37q&G9dG92"Fit7$Fe_n7$F[_nFj[n7$7$$!3%fUr&G9dG>F,$"3y!*)4C7]s;$F,7$$!3!G4TTY(4'*=F,$"31&>l"R)G"*>$F,7$7$$!3MkFi4VOr=F,$"3Gs/>w/>EKF,Fb`n7$Fh`n7$$!3#*)fN/:(pk=F,$"3j#4,1s&[KKF,7$7$Fa_n$"31@&R`/*RSKF,F^an7$7$$!3O$G9dG9dy"F,$!3j?J?%*z_M=Fit7$$!3g*35(*QDt!=F,$!3=lmmmmmm;Fit7$F]bnF`_n7$Fdan7$$!35Cgj")*G7$=F,$"3#)*ee%*Q>TE$F,7$7$$!3\#Rx]cN+"=F,$"39"G9dG9dG$F,Fdbn7$7$F[cn$"3/#G9dG9dG$F,7$$!3%*eO]ob@)z"F,$"3#[4s8-KhH$F,7$7$Fian$"3y,bDt,M3LF,Fccn7$7$$!3(>r&G9dG9<F,$!3NS@")4UWKBFit7$$!34y)fFbHVs"F,$!3!3w/>w/>E#Fit7$7$Fcdn$!3_gZ!>w/>E#FitFhan7$Ficn7$$!3!)Gk!\`HQw"F,$"3K7#)*G!3+FLF,7$7$$!3S&**))*H^eW<F,$"3M"4Q_4Q_M$F,F\en7$7$Fcen$"3!44Q_4Q_M$F,7$$!3U"yg5nI$H<F,$"3I:t@fbxdLF,7$7$F^dn$"3-Q5qvZXrLF,F[fn7$7$F^dn$!32S@")4UWKBFit7$$!3a4Bc.`8z;F,$!3?YkE^[#[b#Fit7$7$$!3dSr&G9dGk"F,$!39"4C"pnDyFFitFhfn7$7$$!3v6dG9dG9<F,$"3eP5qvZXrLF,7$$!3?'oO(\4"Qp"F,$"3QX5(4g*p(Q$F,7$7$$!3ah^M+ZUu;F,$"3A+>w/>w/MF,Fign7$F_hn7$$!3SPv`z>(zl"F,$"3\kb*>gdtT$F,7$7$F_gn$"3mV5%e1N,V$F,Fehn7$7$$!3=p&G9dG9d"F,$!3s#yE4:'\uJFit7$$!3L<VUP$e&G;F,$!3)e&G9dG9dGFit7$FdinF^gn7$7$F_gn$"3AV5%e1N,V$F,7$$!3:6uT&H96i"F,$"3=,Evum;YMF,7$7$$!3C)*R`gL"*)f"F,$"3)*4dG9dGkMF,F^jn7$Fdjn7$$!3I3Y@uR4%e"F,$"3%)3ug;-%[Z$F,7$7$$!3'*o&G9dG9d"F,$"3'\1Xg&*zZ[$F,Fjjn7$7$$!3c(************\"F,$!3E&3[JrlI`$Fit7$$!3%**)4V()z.;:F,$!3A^4Q_4Q_MFit7$F[\o7$F`in$!3;#yE4:'\uJFit7$F`[o7$$!3sO<B!>5da"F,$"3![#)y%RvP-NF,7$7$$!3j&\q(fRM<:F,$"3G>&4Q_4Q_$F,Fe\o7$F[]o7$$!3h^c*)Gfn2:F,$"3mjDAJh?INF,7$7$$!3y(************\"F,$"3JibT*Q*yNNF,Fa]o7$7$Fh]o$!3#e3[JrlI`$Fit7$$!3IXQ(fq\%y9F,$!3>AA$ftm>j$Fit7$7$$!3QE9dG9dG9F,$!3S311&\2X%QFitF`^o7$Fg]o7$$!3K%4&f%f(fn9F,$"3=U#H)G8LcNF,7$7$$!3G4QD$4B*G9F,$"3;GLLLLL$e$F,F\_o7$Fb_o7$$!3)>6U]c?(G9F,$"3/mbs8wX$e$F,7$7$Fg^o$"3)zt8Q(zb$e$F,Fh_o7$7$$!3)\&G9dG9d8F,$!39_`+:Ac@TFit7$$!3q1'ycz[iP"F,$!3cY!>w/>w/%Fit7$Fg`oFf^o7$7$$!3;E9dG9dG9F,F_`o7$$!3%3!3wq7!oQ"F,$"3m\\,y'[!3OF,7$7$Fc`o$"3YhN#4&e9FOF,Faao7$Fb`o7$$!3J`Q$e<!fT8F,$!3'31%>DZAxTFit7$7$$!3g$G9dG9dG"F,$!3)zVa^4!R`VFitF[bo7$7$Fc`o$"3,hN#4&e9FOF,7$$!3]5`+It&eM"F,$"3Y$=4p`_Mj$F,7$7$$!3@jHx%*RbI8F,$"3"z8dG9dGk$F,Fjbo7$F`co7$$!32Y)4;>oLI"F,$"3]RM5J(ovl$F,7$7$Fbbo$"378$*zg%H!oOF,Ffco7$7$$!3O$G9dG9dG"F,Fdbo7$$!3g$4krEN"H7F,$!3^I1()o36>XFit7$7$$!3>7dG9dG97F,$!3_DMU#Hq^b%FitFcdo7$F\do7$$!3%GiIy")=-E"F,$"3iiX9HZ8"o$F,7$7$$!3eWU:(**4DA"F,$"3yY4Q_4Q-PF,F_eo7$Feeo7$$!3g2b&>Cjt@"F,$"3#HWs(eb%\q$F,7$7$Fjdo$"3#*))>@&f>mq$F,F[fo7$7$$!3!39dG9dG9"F,$!3LuBo_M!or%Fit7$$!3!4JKV7%zv6F,$!3YUr&G9dGk%Fit7$7$F[go$!3!>9dG9dGk%FitFido7$Fafo7$$!3/1G;E#=><"F,$"3JMB!=_)fEPF,7$7$$!3dSr&G9dG9"F,$"3ft#R'o&p:u$F,Fdgo7$Fefo7$$!3%z")[B$f'38"F,$!3GmJ4(*QyUZFit7$7$$!3Sp&G9dG92"F,$!36<o6Q6&y$[FitF`ho7$7$Fffo$"3/u#R'o&p:u$F,7$$!3F&)yCi_%p7"F,$"37VqRh[k[PF,7$7$$!37xfuX]m*4"F,$"3acZ!>w/>w$F,F_io7$Feio7$$!3Kai$RZe53"F,$"3kg6m!oH*pPF,7$7$Fgho$"37r$Q4f^Wx$F,F[jo7$7$Fgho$!3b;o6Q6&y$[Fit7$$!32dFWB_[U5F,$!3)zd0%4<0%)[Fit7$7$$!2+)**************F,$!3v#zF*oK#\#\FitFhjo7$Fajo7$$!3\>h[Hs[L5F,$"3/ClZ'y5)*y$F,7$7$F_[p$"3%>)f+>]d/QF,Fd[p7$7$F_[p$!3J$zF*oK#\#\Fit7$$!33;+,-bG8'*Fit$!3kWa^C#>^'\Fit7$7$$!3/mUr&G9dG*Fit$!3g$oPSu9i(\FitFa\p7$Fj[p7$$!3UZuorh)3')*Fit$"3E@DS_d$)4QF,7$7$$!3Qdc-I!o%z&*Fit$"3Sl&G9dG9#QF,F]]p7$Fc]p7$$!3A/g)y*f`v$*Fit$"3^V&4Tr8*GQF,7$7$Fh\p$"3)yo$[e7\KQF,Fi]p7$Fg\p7$$!3+Je0o-/g))Fit$!3qQe!4\&e(*\Fit7$7$$!33_&G9dG9d)Fit$!3s;E?gv+!*\FitFc^p7$7$$!3%\E9dG9dG*FitF`^p7$$!33EJ)>L#*H())Fit$"3O8"3[))el%QF,7$7$Fj^p$"3clW$=R7x&QF,Fb_p7$Fi^p7$$!3!Qpgq2l_:)Fit$!37d.$[0g'*)\Fit7$7$$!37QG9dG9dyFit$!3'R3_xpo['\FitF\`p7$Fh_p7$$!3Wq@Yi&f*o$)Fit$"3o4&QN'*zS'QF,7$7$$!3gC#p=ZTW(yFit$"3suB&4Q_4)QF,Fh`p7$F^ap7$$!3'zfHR2$yhyFit$"3_/Yol!R8)QF,7$7$Fc`p$"3eX:r*G#\")QF,Fdap7$Fb`p7$$!3?dd!HTn=\(Fit$!3%>/)QYLDZ\Fit7$7$$!39Cr&G9dG9(Fit$!3G@H;lK&***[FitF^bp7$Fjap7$$!3Z[!)*yklrK(Fit$"3E="RIU6j*QF,7$7$Febp$"3+Z=f(**z=!RF,Fjbp7$7$Febp$!3%=#H;lK&***[Fit7$$!3wci"4]^Y'oFit$!3+ky!y<&pu[Fit7$7$$!3=59dG9dGkFit$!3UV]smBW&z%FitFgcp7$7$Febp$"3cY=f(**z=!RF,7$$!3Uj,Uu#pxy'Fit$"3(R5tZ`&)3"RF,7$7$F^dp$"3mMT+ZKs?RF,Ffdp7$F]dp7$$!3[tuUZHqpiFit$!3/B/"QaZ_x%Fit7$7$$!3@'p&G9dG9dFit$!3m"*yHPW8`YFitF`ep7$7$F^dp$"3@MT+ZKs?RF,7$$!37+TEhIOUiFit$"3:3R`E)e\#RF,7$7$Fgep$"38$=4[1@z$RF,F_fp7$Ffep7$$!3\/x7*=$*Qq&Fit$!3g-))[!e<:l%Fit7$7$$!31r["QBF*ocFitFagoFifp7$7$$!3'*p["QBF*ocFit$!3NTr&G9dGk%Fit7$$!3Wv(3Rw"ek^Fit$!3GYJ$Hn0d]%Fit7$7$$!3C#)************\Fit$!3k)eXcbW6W%FitFhgp7$7$Fgep$"3e$=4[1@z$RF,7$$!3uKHBime*o&Fit$"3q`%Qh$zTQRF,7$7$$!33'[%=O')o%f&Fit$"3-%=w/>w/%RF,Fghp7$F]ip7$$!3^'QF_x")H6&Fit$"3G,=TQ8*)\RF,7$7$F_hp$"3%4/QmMkA&RF,Fcip7$F^hp7$$!3K8XsHT*4l%Fit$!3F/'[GFd%QVFit7$7$$!3EoUr&G9dG%Fit$!3in?I]&p!)=%FitF]jp7$Fiip7$$!3=d8N>'*4CXFit$"3ETf%\jT.'RF,7$7$Fdjp$"3)*4=IA]okRF,Fijp7$Fcjp7$$!3M"Rh:mA>;%Fit$!3'368Wty2:%Fit7$7$$!3\l]HVP)3"RFitFj`oFc[q7$7$$!3%\1&HVP)3"RFitFj`o7$$!31#*p!GB2Qp$Fit$!3-#o.)HojXRFit7$7$$!3Ia&G9dG9d$Fit$!3=C_.scCpQFitF`\q7$7$Fdjp$"3U5=IA]okRF,7$$!3*\uMNjIV#RFit$"3M*p^cp%))pRF,7$7$Fg\q$"3'Q#H1w!H`(RF,F_]q7$Ff\q7$$!3_%)>vty)yC$Fit$!3QfZW+#)*>s$Fit7$7$$!3yRG9dG9dGFit$!3Y?[2(R7,\$FitFi]q7$7$Fg\q$"3ICH1w!H`(RF,7$$!3&>hH.))y?J$Fit$"3/[<uDvQyRF,7$7$$!3MSG9dG9dGFit$"3mu`>GB8%)RF,Fh^q7$7$F__qFb^q7$$!3f`v%>bzn#GFit$!3kc.r1PoxMFit7$7$$!3#[k44Ze$yFFitF^\oFe_q7$7$F\`q$!3m]4Q_4Q_MFit7$$!3X5^BT'e%>CFit$!3LJEt.(z=A$Fit7$7$$!33Er&G9dG9#Fit$!3aFI@(\g_*HFitFb`q7$F^_q7$$!3Apc+P"Qco#Fit$"3mi&))*Rzq&)RF,7$7$Fi`q$"3)=a>)['R5*RF,F^aq7$7$$!3OEr&G9dG9#FitF[aq7$$!3d#e/I."QT?Fit$!3vv*>?G1<%HFit7$7$$!3I)*GrmRM7>FitFginF[bq7$7$$!3-)*GrmRM7>FitFgin7$$!3o^6.#*3eu;Fit$!3Q1k#4(\8_EFit7$7$$!3%=Tr&G9dG9Fit$!35u6S&)>M%Q#FitFhbq7$Fdaq7$$!3()oyp_E>V?Fit$"3=b+#ei%p"*RF,7$7$F_cq$"3'>x?yW1g*RF,Fdcq7$F^cq7$$!31S[Pk6)GM"Fit$!3&R!>S:LJLBFit7$7$$!3%>_22F(oV7FitFidnF^dq7$Fddq7$$!3U7V'["**o65Fit$!3<[#*3Gz19?Fit7$7$$!3aeOs.o*[^(F`emF`bnFhdq7$F^eq7$$!32(=\f:p"4uF`em$!3*4)*3*)*RZW;Fit7$7$$!3$f(p&G9dG9(F`em$!3Q)osCBfyc"FitFbeq7$Fjcq7$$!3%\V%3]m"GQ"Fit$"3GXFz,r='*RF,7$7$Fieq$"3CeEgA****)*RF,F^fq7$Fheq7$$!3#oWVy:0OE%F`em$!36kj%oBm8J"Fit7$7$$!3#f*3jb<"f*>F`em$!3)*p&G9dG92"FitFhfq7$7$$!3A&*3jb<"f*>F`emFagq7$$!3NkAgGjM.:F`em$!3g2q62r\h%*F`em7$7$$!3c]bhQ;F5;!#?$!33ZZ!>w/>w%F`emFggq7$7$$!3f`bhQ;F5;F`hqF_\n7$$!3[SfFiG%=["F`hq$!39Z\rcyTQYF`em7$7$$"3![tPp`M`m"!#K$"3q1)RJPF-5"F`emFghq7$Fdfq7$$!3R%=dQ&erCqF`em$"3]G$e#*[:!**RF,7$7$F^iq$"3M$*************RF,Fdiq7$7$$"3+4t&G9dG9(F`em$!31[FZK#fyc"Fit7$$"3sV5jb<"f*>F`emFagq7$Fcjq7$$"3*REr8w(p=BF`hq$!3E9ANv&H^&\F`em7$7$$"3cL(='Q;F5;F`hqF_\nFgjq7$7$$"3<J(='Q;F5;F`hqF_\n7$F^iq$"3=1)RJPF-5"F`em7$7$F_jq$"3!yl-E#****)*RF,Fjiq7$7$$"3:X9dG9dG9Fit$!3o-7S&)>M%Q#Fit7$$"3"o^22F(oV7FitFidn7$7$$"3&p^22F(oV7FitFidn7$$"3zIWvTC`L%)F`em$!3YeZdTHAu<Fit7$7$$"3YePs.o*[^(F`emF`bnFh\r7$F^]rF^jq7$Fh[r7$$"3#QN/:%Q&)osF`em$"3sn7^F+&*)*RF,7$7$F]\rF[dqFc]r7$7$$"3nfr&G9dG9#Fit$!3'308s\g_*HFit7$$"3!e*GrmRM7>FitFgin7$F`^rF\\r7$Fi]r7$$"3!*H"fD')=1["Fit$"3y_V$Qric*RF,7$7$$"36fr&G9dG9#Fit$"3UT&>)['R5*RF,Fe^r7$7$$"3?uG9dG9dGFit$!3yQ[2(R7,\$Fit7$$"3]T'44Ze$yFFitF^\o7$Ff_r7$$"3Rfr&G9dG9#FitF^^r7$7$F[`rF^_r7$$"3uD"*H))p!QE#Fit$"3CjJ@Y3#**)RF,7$7$$"3ktG9dG9dGFit$"3Au`>GB8%)RF,F_`r7$7$Ff`r$!3AQ[2(R7,\$Fit7$$"3/W\N_MqrHFit$!3Gww0:"[ya$Fit7$7$$"3g(eG9dG9d$Fit$!3%>CN?nX#pQFitF^ar7$7$Ff`rFa_q7$$"3+u:SjQEzIFit$"3%=5Xh"**[")RF,7$7$FearFf]qF[br7$7$$"3e,Vr&G9dG%Fit$!3S!3-.bp!)=%Fit7$$"3%\1&HVP)3"RFitFj`o7$7$$"3\l]HVP)3"RFitFj`o7$Fear$!3QT_.scCpQFit7$7$Fear$"3UBH1w!H`(RF,7$$"30`*)\O)e+$RFit$"3giudWT6qRF,7$7$Fdbr$"3a4=IA]okRF,Ffcr7$Fcbr7$$"3I+?H]m%>c%Fit$!3%)Grw%o7yF%Fit7$7$$"3a:++++++]Fit$!3u*fXcbW6W%FitF`dr7$F\dr7$$"3\`f#yWz&>[Fit$"3q*o!\O7^bRF,7$7$Fgdr$"3]S!QmMkA&RF,F\er7$7$$"3^HdG9dG9dFit$!3++zHPW8`YFit7$$"3'*p["QBF*ocFitFago7$F[frFfdr7$7$$"3iIdG9dG9dFitFffp7$$"3)\[%=O')o%f&Fit$"3e$=w/>w/%RF,7$7$FdfrF`ipFber7$Ffer7$$"3***\B#Gd4HdFit$!3]<'Q6#))>bYFit7$7$$"3[V9dG9dGkFit$!3)*[]smBW&z%FitF[gr7$7$Fger$"3p#=4[1@z$RF,7$$"3A1<ql*Gnv&Fit$"38'=eGDRp$RF,7$7$Fbgr$"3LLT+ZKs?RF,Fjgr7$Fagr7$$"3'*pghcScOmFit$!3!*HV*GL%=;[Fit7$7$$"3Xdr&G9dG9(Fit$!3sDH;lK&***[FitFdhr7$F`hr7$$"3m$\&4yl5snFit$"3iz"\8E[="RF,7$7$F[irFddpF`ir7$7$F[ir$!3=DH;lK&***[Fit7$$"3elc^2qKsuFit$!3p)*eSj`T<\Fit7$7$$"3UrG9dG9dyFit$!3G(3_xpo['\FitF[jr7$Ffir7$$"3/Jz?kA4ZyFit$"3')>OOI**y")QF,7$7$Fbjr$"3qW:r*G#\")QF,Fgjr7$Fajr7$$"3A*3@0g#)RC)Fit$!3UBBn&fB_'\Fit7$7$$"3Q&eG9dG9d)Fit$!3E<E?gv+!*\FitFa[s7$7$$"3]'eG9dG9d)FitFi_p7$$"3/H#p=ZTW(yFitFaap7$F`\sF][s7$Fg[s7$$"3!GXZGJq@'*)Fit$!3#))>12Ev%o\Fit7$7$$"3O*H9dG9dG*Fit$!3]#oPSu9i(\FitFe\s7$7$Fh[s$"37lW$=R7x&QF,7$$"33d3hb2`^!*Fit$"3#>&QglQ%4%QF,7$7$F\]s$"3*po$[e7\KQF,Fd]s7$F[]s7$$"38izH#pJwj*Fit$!3uFNM[;7O\Fit7$7$$"3M,++++++5F,$!3)**yF*oK#\#\FitF^^s7$7$Fe^s$"3h!)f+>]d/QF,7$$"3#=mD+.o%z&*FitFf]p7$F]_sFj]s7$Fd^s7$$"3@QzV&=$)z-"F,$!3w\*R[N]g([Fit7$7$$"3ss&G9dG92"F,$!367o6Q6&y$[FitFb_s7$Fj^s7$$"3wISo**HWS5F,$"3Ou=prgs(y$F,7$7$Fi_s$"3Op$Q4f^Wx$F,F^`s7$Fh_s7$$"33OTWBOl*3"F,$!3Oq,KwDt%z%Fit7$7$$"38Wr&G9dG9"F,$!3AoBo_M!or%FitFh`s7$7$F_as$"3qs#R'o&p:u$F,7$$"37xfuX]m*4"F,$"35cZ!>w/>w$F,7$FgasFd`s7$F^as7$$"35@v!*yiQ\6F,$!3y<O%*4mE(p%Fit7$7$$"3!4JKV7%zv6F,FagoF^bs7$Fdbs7$$"3M"*R**QOT07F,$!3#Rx#4#=B*oXFit7$7$$"3_:dG9dG97F,$!3k;MU#Hq^b%FitFhbs7$Fdas7$$"38j)3;iE;?"F,$"3KC$yi>IHr$F,7$7$F_cs$"3.))>@&f>mq$F,Fdcs7$F^cs7$$"3yJ/)Qf"He7F,$!3s\$34rMVT%Fit7$7$$"3#pG9dG9dG"F,$!3)zUa^4!R`VFitF^ds7$7$Feds$"3!4J*zg%H!oOF,7$$"3pXU:(**4DA"F,Fheo7$F]esFjcs7$Fdds7$$"3P$G]kl42J"F,$!3G]Bv.Q"fD%Fit7$7$$"3KeG9dG9d8F,$!3/T`+:Ac@TFitFbes7$7$Fies$"3zeN#4&e9FOF,7$$"3xiHx%*RbI8F,$"3ZPr&G9dGk$F,7$FafsFjds7$Fhes7$$"3C^p;>L'GO"F,$!3S)['[k&*G&4%Fit7$7$$"3#pgycz[iP"F,Fj`oFhfs7$F^gs7$$"3N\nCT5%4T"F,$!3d5nC`"*p+RFit7$7$$"3rH9dG9dG9F,$!3_%fg]\2X%QFitFbgs7$F^fs7$$"3'*eV1&HCvU"F,$"3[?#*eWf?%e$F,7$7$Figs$"3wNP"Q(zb$e$F,F^hs7$7$Figs$!3(Rfg]\2X%QFit7$$"3Y%3s\k**zX"F,$!3euI0*3;wp$Fit7$7$$"3)3++++++]"F,$!3$32[JrlI`$FitF[is7$7$$"35,++++++:F,$"3lfbT*Q*yNNF,7$$"3i3QD$4B*G9F,Fe_o7$7$F]js$"3qFLLLLL$e$F,Fdhs7$7$FhisFdis7$$"3p'yX$o^t0:F,$!3$Q;H>-u,]$Fit7$7$$"3;!*4V()z.;:F,F^\oFejs7$7$$"3%**)4V()z.;:F,F^\o7$$"3'Rr2uS5&\:F,$!3+k/a&eH(pKFit7$7$$"3]s&G9dG9d"F,$!3_ln#4:'\uJFitFb[t7$7$Fi[t$"3'=1Xg&*zZ[$F,7$$"3T&\q(fRM<:F,$"3%)=&4Q_4Q_$F,7$Fa\tFgis7$Fh[t7$$"39Y/"*)*y<$f"F,$!3+O^#GD(QQIFit7$7$$"3)oJCuLe&G;F,FginFh\t7$F^]t7$$"3U'*3r&[toj"F,$!3<#z!fZ!zs!GFit7$7$$"3!R9dG9dGk"F,$!3;rS7pnDyFFitFb]t7$7$Fi]t$"3+T5%e1N,V$F,7$$"3C)*R`gL"*)f"F,Fgjn7$Fa^t7$Fi[t$"3Ii]/c*zZ[$F,7$Fh]t7$$"3W3vd<L&on"F,$!3M)z2z@1_a#Fit7$7$$"3I:dG9dG9<F,$!3(*=@")4UWKBFitFi^t7$7$F`_t$"3ON5qvZXrLF,7$$"3+i^M+ZUu;F,Fbhn7$Fh_tF^^t7$F__t7$$"3!\<Q_9(o=<F,$!3qc_<`Le)H#Fit7$7$$"3Jy)fFbHVs"F,FidnF]`t7$7$$"3ay)fFbHVs"F,Fedn7$$"3w!e]JYnlv"F,$!3RxQ(Qd9!>?Fit7$7$$"3q'G9dG9dy"F,$!3['4.U*z_M=FitFj`t7$7$$"3#pG9dG9dy"F,$"3n)\bK<S$3LF,7$$"3S&**))*H^eW<F,Fien7$7$F\btFeenFe_t7$F`at7$$"3S7G,S.t&z"F,$!3=W5#eyL,v"Fit7$7$$"3#)*35(*QDt!=F,F`bnFabt7$7$$"30!45(*QDt!=F,F`bn7$$"3dY7!4oyA$=F,$!39pl)z>l%f9Fit7$7$$"3)y&G9dG9d=F,$!35cQG$>VPG"FitF^ct7$7$$"35eG9dG9d=F,$"3&z^R`/*RSKF,7$$"3F#Rx]cN+"=F,Facn7$F_dt7$Faat$"37*\bK<S$3LF,7$7$F[dtFgct7$$"3Oi;x6!=#p=F,$!3)*Q>+g[0s6Fit7$7$$"39(*R?%p8=)=F,Fh_nFhdt7$7$F_etFagq7$$"3\(Q*ztC2/>F,$!3ai)[*\hqs')F`em7$7$$"3rH9dG9dG>F,$!3&p_9=#)\ft'F`emFcet7$7$$"3\H9dG9dG>F,$"3o())4C7]s;$F,7$$"37kFi4VOr=F,$"3ss/>w/>EKF,7$7$FeftF[an7$F[dt$"3^<&R`/*RSKF,7$Fiet7$$"3Ts]Y0!Q#R>F,$!39T$3(phy]cF`em7$7$$"31[8e2oC\>F,F_\nF_gt7$Fegt7$$"35$G4D<H@(>F,$!3GG\M/eLRCF`em7$7$$"3)3+++++++#F,$"3m![tw66Q$GFbhmFigt7$7$F`ht$"3%pedtIqn3$F,7$$"3qsaxS2I#)>F,$"3l`G9dG92JF,7$Fhht7$$"38zlO@<!3$>F,$"3crtL*33[;$F,7$7$$"31^%ocv:"H>F,Fa^nF^it7$FditF_ft7$F_ht7$$"3<5/ERm%f+#F,$"3?UUv(=H#\pF`hq7$7$$"3<fx$*)ef4,#F,FjhmFiit7$7$F`jtFfhm7$$"3q(RE!))4pO?F,$"3k&4Ct![F&3%F`em7$7$$"3Us/#yz)\n?F,$"3tdr&G9dG9(F`emFdjt7$7$F[[uFeim7$$"3#eFe=9p"p?F,$"3j!*=QSH9JtF`em7$7$$"3]s&G9dG92#F,$"3;Q7,EU/cvF`emFa[u7$7$Fh[u$"3UtsPzTx**HF,7$$"3-$o2(=UeK?F,Fijm7$7$Fa\uFejmFeht7$Fg[u7$$"3#eU-%*)G.)4#F,$"3g,<uf6#y3"Fit7$7$$"3%\NX\$z%z6#F,FdemFf\u7$F\]u7$$"3T7Kn.r'y7#F,$"34TKs-3WM9Fit7$7$$"38Wr&G9dG9#F,$"3irn"zATIg"FitF`]u7$7$Fg]u$"3R&Ga&e!yP!HF,7$$"3+xfnwF"\7#F,$"3;E9dG9dGHF,7$7$F`^uFdfm7$$"3kNFx0@6'4#F,$"3ul<9Ec_nHF,7$7$$"3'f#zYsW\!3#F,F`gmFf^u7$7$F]_u$"3eM_4Q_4))HF,F]\u7$Ff]u7$$"3K/^%G_Rk:#F,$"3UQA'[Sv:z"Fit7$7$$"3)olf*yv\l@F,FiamFd_u7$Fj_u7$$"3kx[+()=j$=#F,$"3i`bVl/@g@Fit7$7$$"3#oz$oE:O5AF,FebmF^`u7$Fd`u7$$"3CC@p$y1=@#F,$"3Q'fY\vd1_#Fit7$7$$"3u:dG9dG9AF,$"3-?m`gHt_DFitFh`u7$7$F_au$"3%Gxj9b$z(z#F,7$$"3Ia\v*R_n?#F,Fbcm7$Fgau7$$"3Qx-ZC"Qx>#F,$"3"*QLqnMJBGF,7$7$$"3Uf2"*>zzm@F,F^dmF[bu7$7$$"3')f2"*>zzm@F,F^dmF\^u7$7$$"3I:dG9dG9AF,$"3Y>m`gHt_DFit7$$"3Zvo&\t%yOAF,$"34l<Jciu2HFit7$7$$"3AK6$QUF)\AF,Fd^mF^cu7$Fdcu7$$"3SG7$o'z0iAF,$"3[d-$f3uBH$Fit7$7$$"3O(G9dG9dG#F,$"3X[8?$e#*4k$FitFhcu7$7$F_du$"3u6kk_)G$yEF,7$$"3cQ>Ss'H)yAF,Fc_m7$Fgdu7$$"3#)R()QS%)\sAF,$"3`WT"\R*[,FF,7$7$$"31"[-JP*RVAF,Fe`mF[eu7$Faeu7$F_au$"3GtPY^Nz(z#F,7$F^du7$$"3/D4:ZXh(G#F,$"314U]y1kuOFit7$7$$"3ob*>4o(e)G#F,FdilFieu7$F_fu7$$"3HX#Rzo7,J#F,$"3#=(H<nUR#3%Fit7$7$$"3h@T<vj@ABF,$"39(G9dG9dG%FitFcfu7$7$$"30AT<vj@ABF,F_jl7$$"33)Gu3RkHL#F,$"35Y!>Y],s[%Fit7$7$$"3)*=Yc.yibBF,F[[mFbgu7$Fhgu7$$"3k.`gpT3cBF,$"39x')4xZx*)[Fit7$7$$"3)*eG9dG9dBF,$"3VSAW#4T)3\FitF\hu7$7$Fchu$"3>_AD4@"4a#F,7$$"3iA!y>-y>M#F,F]\m7$F[iu7$$"3a=1rTX0JBF,$"3)*p()GM)oJf#F,7$7$$"3;P$RTGv5J#F,Fi\mF_iu7$FeiuFddu7$Fbhu7$$"37gp76]BwBF,$"3cL'*)H>*3<`Fit7$7$$"3MZY2?]>%Q#F,FddlFjiu7$7$$"3yZY2?]>%Q#F,$"3%*y/>w/>waFit7$$"3w"GUfy&H'R#F,$"3/<nwkT:XdFit7$7$$"3fKH(Q%\">T#F,F`elFiju7$F_[v7$$"3jizC.;K;CF,$"3#)QT7\/^thFit7$7$$"3gI9dG9dGCF,$"3(H=%\s_$=W'FitFc[v7$7$Fj[v$"3!f\cr0n"yBF,7$$"3!pn)zMInACF,F`fl7$Fb\v7$$"3i1Qn3Vn>CF,$"3:&\Q%49F+CF,7$7$$"3_T#*yfn9(R#F,$"3m^4Q_4Q_CF,Ff\v7$7$F]]vF\gl7$$"35&o,)>O@zBF,$"35s!*ofC^$\#F,7$7$$"3YcT7k+qqBF,FhglFc]v7$7$Fj]v$"34gZ!>w/>^#F,Fhhu7$Fi[v7$$"3aW"[&Rb=NCF,$"3@aS>v!\:h'Fit7$7$$"3xXEr.DXPCF,Fc_lFa^v7$Fg^v7$$"3KnX&\(z?_CF,$"3+$HX?aL\1(Fit7$7$$"3c^FCB1')fCF,F^`lF[_v7$Fa_v7$$"3/u***=!*R*oCF,$"3^H$QF"*Q2_(Fit7$7$$"39>.^]fA"[#F,$"35eG9dG9dyFitFe_v7$7$F\`vFj`l7$$"37q4q9.G&[#F,$"3_g9I,p!)zzFit7$7$$"3A-++++++DF,$"30l(p6Q!*4T)FitFb`v7$7$Fi`v$"3E#GcSF?6<#F,7$$"3'o/a8>sk[#F,Fgal7$Faav7$$"3E"Rn+`b;[#F,$"3x*)GcsFdHAF,7$7$$"3_p(*>\H[mCF,FcblFeav7$7$$"3'*p(*>\H[mCF,Fcbl7$$"3q'=")oO`HX#F,$"39O&390:IJ#F,7$7$$"3%oHg_0'QXCF,F_clFbbv7$FhbvF_\v7$Fh`v7$$"3'ys+gl")4]#F,$"3yR#3d[+UW)Fit7$7$$"31>!Q2CJ7]#F,F]uF]cv7$Fccv7$$"31ZQuLXJ9DF,$"3.W.Um7LG*)Fit7$7$$"3#p6'R7(pw^#F,FiuFgcv7$7$$"3[;hR7(pw^#F,$"3y[!>w/>w/*Fit7$$"3^#*="3!=0FDF,$"3OGZUpaU<%*Fit7$7$$"3/**oF%[XG`#F,$"38Wr&G9dGk*FitFfdv7$7$F]ev$"3CXr&G9dGk*Fit7$$"3Y%**zoo'4RDF,$"3,1`49&*G7**Fit7$7$$"316d2jamYDF,FawFeev7$F[fv7$$"3/2u]%p].b#F,$"3SHQC@WPT5F,7$7$$"3y!))\<AW!fDF,F]xF_fv7$Fefv7$$"3kQ!4][92c#F,$"3%e%HoQ<E#4"F,7$7$$"3)>%*[7w0*pDF,F\yFifv7$F_gv7$$"3KMAIq')3qDF,$"3%G4HrstR9"F,7$7$$"3%QdG9dG9d#F,$"3W*Q%e5sd_6F,Fcgv7$7$$"3St&G9dG9d#F,$"3/y^_d)=4&=F,7$$"3;v-#['=^qDF,Fiy7$Fdhv7$$"3MYKu\7QqDF,$"3YjR@Dc,e=F,7$7$$"3!z@)e"*43gDF,FezFhhv7$F^iv7$$"315pMf(3"eDF,$"3W`!o+^mx#>F,7$7$$"3ORSwqCB[DF,Fa[lFbiv7$Fhiv7$$"3NHJS>*HMa#F,$"3g!o6ioA&**>F,7$7$$"3%)4#pwvB]`#F,Fb\lF\jv7$7$Fcjv$"3f&G9dG9d.#F,7$$"3T7adp8?EDF,$"3S?>f?OSt?F,7$7$$"3_ou39E^?DF,F^]lFijv7$F_[w7$$"3#[2%)[Lji]#F,$"3Ex^-fCa\@F,7$7$$"3cBio5iv/DF,Fj]lFc[w7$Fi[wF^av7$7$Fjgv$"3A*Q%e5sd_6F,7$$"3+9;!yG"exDF,$"3S_nt)o`s>"F,7$7$$"3;))z6*o]#yDF,F2Fa\w7$Fg\w7$$"3WC+-j)*)Qe#F,$"3')>_C_._^7F,7$7$$"3%G\6I*R)\e#F,F>F[]w7$Fa]w7$$"3ay-_e%z!*e#F,$"36^@&))\>nI"F,7$7$$"3-@h$=ja-f#F,FJFe]w7$F[^w7$$"3Wb4[o.1$f#F,$"3))H(3M)e#HO"F,7$7$$"3[;`#>$p.%f#F,FVF_^w7$7$Ff^w$"3Q"Q_4Q_4Q"F,7$$"3oNYqUHu&f#F,$"3#e!GT9U@?9F,7$7$$"3'*eUW<[J'f#F,F\oF\_w7$Fb_w7$$"3ez,)GUPqf#F,$"3u&*pX!Hf'y9F,7$7$$"3W2#)='f"3(f#F,FhoFf_w7$F\`w7$$"3s'**38f`of#F,$"3(4zcHHO$Q:F,7$7$$"3kE!pp^Rjf#F,FdpF``w7$Ff`w7$$"312>cF-5&f#F,$"3M3l$*Q7K*f"F,7$7$$"3!GsNI8*4%f#F,$"32>w/>w/>;F,Fj`w7$F`aw7$$"3'ovx9P%o"f#F,$"3')4r>&f"ph;F,7$7$$"3c6$=;^y.f#F,F\rFfaw7$F\bw7$$"3SDB[#R5le#F,$"3eyP)Q0Fbs"F,7$7$$"3eR&=BL-_e#F,$"3eQ_4Q_4Q<F,F`bw7$7$FgbwFhr7$$"3mx,@l)y%zDF,$"3g6xYp/"4z"F,7$7$$"3aU."p"4gyDF,FhsF]cw7$Fccw7$Fjgv$"3Ey^_d)=4&=F,-%&COLORG6&%$RGBG$"#5!""$""!F`dwFadw-%+AXESLABELSG6$Q"x6"Q"yFgdw-%%FONTG6$%*HELVETICAGF_dw

14. Instructions for Labeling Graphs Consider the function f defined below:f:=x->piecewise(x<=0,x^2,x*sin(1/x));

NiM+SSJmRzYiZio2I0kieEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLUkqcGllY2V3aXNlR0kqcHJvdGVjdGVkR0YuNiUxOSQiIiEqJEYxIiIjKiZGMSIiIi1JJHNpbkc2JEYuSShfc3lzbGliR0YlNiMqJEYxISIiRjZGJUYlRiU=

To check our definition of f , we examine the value of f (x).`f(x)`=f(x);

NiMvSSVmKHgpRzYiLUkqUElFQ0VXSVNFR0YlNiQ3JCokSSJ4R0YlIiIjMUYrIiIhNyQqJkYrIiIiLUkkc2luRzYkSSpwcm90ZWN0ZWRHRjVJKF9zeXNsaWJHRiU2IyokRishIiJGMUkqb3RoZXJ3aXNlR0Yl

In order to label the graph of f , we use the following procedure:with(plots):P:=plot(f,-0.5..0.5,color=blue):Q:=textplot([0.35,0.26,`y = f(x)`]);

NiM+SSJRRzYiLUkvSU5URVJGQUNFX1BMT1RHRiU2Iy1JJVRFWFRHNiRJKnByb3RlY3RlZEdGLEkoX3N5c2xpYkdGJTYkNyQkIiNOISIjJCIjRUYyUSl5fj1+Zih4KUYl

display(P,Q);

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

The command P := . . . assigns the name, P, to the graph of f . The option color = was used within this plotting command to specify a color for the curve y = f ( x ) .The colon, :, at the end of this line tells Maple not to display any output at this time. The command Q := . . . centers the string of characters " y = f (x) " at the point ( 0.35 , 0.26 ) in the coordinate plane. Finally, the "plots" package was read with in: > with ( plots ) : because this package contains the display command. The statement [ > display ( P,Q ) ; then merges the graph of f with the string " y = f(x) " on a single coordinate plane. It is not hard to show that when the value of the function f is minimized, then x = NiMtJSRjb3RHNiMqJiIiIkYnJSJ4RyEiIg== . Specifically, this occurs when x = m , where to 10 significant digits:m:=fsolve(x=cot(1/x),x,0.2..0.3);

NiM+SSJtRzYiJCIrJWUiW0RBISM1

Thus, the minimum function value n is equal to f ( m ). n:=f(m);

NiM+SSJuRzYiJCErI0dPQjwjISM1

Suppose we wish to label the minimum point on the graph by the letter M . We may do this with the following command:R:=textplot([m,n-.005,`M`],align = BELOW);

NiM+SSJSRzYiLUkvSU5URVJGQUNFX1BMT1RHRiU2Iy1JJVRFWFRHNiRJKnByb3RlY3RlZEdGLEkoX3N5c2xpYkdGJTYlNyQkIislZSJbREEhIzUkISsjR09CQSNGMlEiTUYlSStBTElHTkJFTE9XR0Yr

Note that the align assignment tells Maple to write the letter M directly below the point with coordinates ( m , NiMsJiUibkciIiIkIiImISIkISIi ) in the plane. We may type LEFT, RIGHT, ABOVE, or BELOW after align = . Now we redraw the graph of f indicating the point M. display(P,Q,R);

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

15. Commands for Differentiation and Integration Enter the command > D ( fcn ) ; where fcn is the name of a function. Maple responds by calculating the derivative function.S:=t->t^4-t^3+t^2;

NiM+SSJTRzYiZio2I0kidEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLCgqJDkkIiIlIiIiKiRGLiIiJCEiIiokRi4iIiNGMEYlRiVGJQ==

s:=D(S);

NiM+SSJzRzYiZio2I0kidEdGJUYlNiRJKW9wZXJhdG9yR0YlSSZhcnJvd0dGJUYlLCgqJDkkIiIkIiIlKiRGLiIiIyEiJEYuRjJGJUYlRiU=

Enter the command > diff ( expr , var ) ; where expr is an expression to be differentiated with respect to the variable called var , and Maple returns the derivative as an expression.Y:=x^4-x^3+x^2;

NiM+SSJZRzYiLCgqJEkieEdGJSIiJSIiIiokRigiIiQhIiIqJEYoIiIjRio=

y:=diff(Y,x);

NiM+SSJ5RzYiLCgqJEkieEdGJSIiJCIiJSokRigiIiMhIiRGKEYs

Enter the command > int ( expr , var ) ; to obtain an antiderivative, (no constant of integration appears), of the given expression expr with respect to the variable var . Note that Maple returns an expression, not a function.int(Y,x);

NiMsKCokSSJ4RzYiIiImIyIiIkYnKiRGJSIiJSMhIiJGKyokRiUiIiQjRilGLw==

The use of the command name Int will write the integral in text form.Int(Y,x);

NiMtSSRJbnRHNiRJKnByb3RlY3RlZEdGJkkoX3N5c2xpYkc2IjYkLCgqJEkieEdGKCIiJSIiIiokRiwiIiQhIiIqJEYsIiIjRi5GLA==

Thus, we may enter :Int(Y,x)=int(Y,x);

NiMvLUkkSW50RzYkSSpwcm90ZWN0ZWRHRidJKF9zeXNsaWJHNiI2JCwoKiRJInhHRikiIiUiIiIqJEYtIiIkISIiKiRGLSIiI0YvRi0sKCokRi0iIiYjRi9GN0YsI0YyRi5GMCNGL0Yx

To obtain the definite integral of an expression, we use a command of the form > int ( expr , var = a . . b ) ; .int(Y,x=0..2);

NiMjIiN3IiM6

We may again use the Int command name to write the definite integral in text form.Int(Y,x=0..2)=int(Y,x=0..2);

NiMvLUkkSW50RzYkSSpwcm90ZWN0ZWRHRidJKF9zeXNsaWJHNiI2JCwoKiRJInhHRikiIiUiIiIqJEYtIiIkISIiKiRGLSIiI0YvL0YtOyIiIUY0IyIjdyIjOg==

16. Inserting a Prompt Sign Between Two Maple Commands In order to insert a new prompt sign between two existing Maple commands, just move the cursor to the end of the first command line ( i.e., just to the right of the terminal : or ; ) and click on the " [ > " icon located on the top tool bar . This will have the desired effect of causing a prompt sign to appear between the two existing command lines. 17. Commands for Adding Text to Maple Worksheets Maple may be used as a word processor to add text to a Maple worksheet. When the cursor is flashing just to the right of a prompt sign you may add comments in text form by clicking on the text icon which appears as a bold capital T in the middle of the tool bar . This will cause the prompt sign to disappear and all characters entered now will appear in black type. The black type indicates that these symbols are in text format. Maple commands cannot be entered while in text mode. After you have completed typing all your comments in the section you may return to Maple command mode by clicking on the capital sigma icon " NiMlJlNpZ21hRw== " which appears on the tool bar . This will cause a prompt sign to appear on the next line of the worksheet with a flashing cursor positioned just to its right. At this point, commands may be entered in the usual way and all characters will appear in red once again. To insert mathematical symbols or expressions while in text mode, first press the space bar on the keyboard once, then click on the sigma icon " NiMlJlNpZ21hRw== " on the tool bar . This will cause a bold black question mark to appear inscribed in a box at the position where the cursor had been flashing. Now enter the appropriate Maple string for the desired mathematical symbol, just as you would as if Maple were in its command mode. The desired mathematical symbol will now appear inside the box that had previously contained the question mark. Finally, click on the T icon on the tool bar to delete the circumscribed box and to continue typing comments in text mode. For instance, to add the expression NiMqJiUieEciIiQsJiokRiQiIiUiIiIqJiUjUGlHRilGJEYpRikhIiI= to a comment while in text mode : 1. Press the space bar once . 2. Click on the " NiMlJlNpZ21hRw== " icon . 3. Enter : x ^ 3 / ( x ^ 4 + Pi * x ) 4. Click on the T icon .