Some syntax rules must be complied with: name(var1[, var2])=term [;extensions] name The function name. If the first character is r the parser assumes that you are using polar coordinates. If the first character is x (for instance xfunc) the parser expects a second function with a leading y (here yfunc) to define the function in parametric form. var1 The function's variable var2 The function group parameter. It must be separated from the function's variable by a comma. You can use the group parameter to, for example, plot a number of graphs from one function. The parameter values can be selected manually or you can choose to have a slider bar that controls one parameter. By changing the value of the slider the value parameter will be changed. The slider can be set to an integer between 0 and 100. term The expression defining the function. All the predefined functions and constants that &kmplot; knows can be shown by selecting HelpPredefined Math Functions . They are: sqr, sqrt Return the square and square root of a number, respectively. exp, ln Return the exponential and natural logarithm of a number, respectively. log Returns the logarithm to base 10 of a number. sin, arcsin Return the sine and inverse sine of a number, respectively. Note that the argument to sin and the return value of arcsin are in radians. cos, arccos Return the cosine and inverse cosine of a number, respectively. Also in radians. tan, arctan Return the tangent and inverse tangent of a number, respectively. Also in radians. sinh, arcsinh Return the hyperbolic sine and inverse hyperbolic sine of a number, respectively. cosh, arccosh Return the hyperbolic cosine and inverse hyperbolic cosine of a number, respectively. tanh, arctanh Return the hyperbolic tangent and inverse hyperbolic tangent of a number, respectively. sin, arcsin Return the sine and inverse sine of a number, respectively. Note that the argument to sin and the return value of arcsin are in radians. cos, arccos Return the cosine and inverse cosine of a number, respectively. Also in radians. pi, e Constants representing &pgr; (3.14159...) and e (2.71828...), respectively. These functions and constants and even all user defined functions can be used to determine the axes settings as well. See . An extension for a function is specified by entering a semicolon, followed by the extension, after the function definition. The extension can either be written in the Quick Edit box or by using the &DCOP; method Parser addFunction. None of the extensions are available for parametric functions but N and D[a,b] work for polar functions too. For example: f(x)=x^2; A1 will show the graph y=x2 with its first derivative. Supported extensions are described below: N The function will be stored but not be drawn. It can be used like any other user-defined or predefined function. A1 The graph of the derivative of the function will be drawn additionally with the same color but less line width. A2 The graph of the second derivative of the function will be drawn additionally with the same color but less line width. D[a,b] Sets the domain for which the function will be displayed. P[a{,b...}] Give a set of values of a group parameter for which the function should be displayed. For example: f(x,k)=k*x;P[1,2,3] will plot the functions f(x)=x, f(x)=2*x and f(x)=3*x. You can also use functions as the arguments to the P option. Please note that you can do all of these operations by using the function editor dialog too. &kmplot; uses a common way of expressing mathematical functions, so you should have no trouble working it out. The operators &kmplot; understands are, in order of decreasing precedence: ^ The caret symbol performs exponentiation. ⪚, 2^4 returns 16. *, / The asterisk and slash symbols perform multiplication and division . ⪚, 3*4/2 returns 6. +, - The plus and minus symbols perform addition and subtraction. ⪚, 1+3-2 returns 2. Note the precedence, which means that if parentheses are not used, exponentiation is performed before multiplication/division, which is performed before addition/subtraction. So 1+2*4^2 returns 33, and not, say 144. To override this, use parentheses. To use the above example, ((1+2)*4)^2 will return 144. By default, explicitly given functions are plotted for the whole of the visible part of the x-axis. You can specify an other range in the edit-dialog for the function. For every pixel on the x-axis &kmplot; calculates a function value. If the plotting area contains the resulting point it is connected to the last drawn point by a line. Parametric functions are plotted for parameter values from 0 up to 2&pgr;. You can set the plotting range in the dialog for the function too. While the mouse cursor is over the plotting area the cursor changes to a cross hair. The current coordinates can be seen at the intersections with the coordinate axes and also in the status bar at the bottom of the main window. You can trace a function's values more precisely by clicking onto or next to a graph. The selected function is shown in the status bar in the right column. The cross hair then will be caught and be colored in the same color as the graph. If the graph has the same color as the background color, the cross hair will have the inverted color of the background. When moving the mouse or pressing the keys Left or Right the cross hair will follow the function and you see the current x- and y-value. If the cross hair is close to y-axis, the root-value is shown in the statusbar. You can switch function with the Up and Down keys. A second click anywhere in the window or pressing any non-navigating key will leave this trace mode. Note that tracing is only possible with explicitly given functions. The coordinates are always displayed according to a Cartesian system of coordinates. Neither non-single-point parametric functions nor functions given in polar coordinates can be traced in this way.