Description
Files to submit to Web-CAT (both files must be submitted together):
• PentagonalPyramid.java
• PentagonalPyramidApp.java
Specifications
Overview: You will write a program this week that is composed of two classes: (1) one named
PentagonalPyramid that defines PentagonalPyramid objects, and (2) the other,
PentagonalPyramidApp, which has a main method that reads in data, creates a PentagonalPyramid object, and then prints the object.
A PentagonalPyramid has a pentagon base and five isosceles triangle faces, six vertices, and 10 edges as depicted below with base edge length a and height h. The formulas are provided to assist you in computing return values for the respective methods in the PentagonalPyramid class described in this project.
Ref: Do a “Google” search on “pentagonal pyramid surface area” for details and an interactive solver.
Surface Area
(A)
Volume (V)
Edge length
(a)
Height (h)
• PentagonalPyramid.java
Requirements: Create a PentagonalPyramid class that stores the label, base edge (i.e., length of an edge in the pentagonal base), and height. The base edge and height must be greater than zero. The PentagonalPyramid class also includes methods to set and get each of these fields, as well as methods to calculate the surface area and volume of a PentagonalPyramid object, and a method to provide a String value of a PentagonalPyramid object (i.e., a class instance).
Design: The PentagonalPyramid class has fields, a constructor, and methods as outlined below.
(1) Fields (instance variables): label of type String, base edge of type double, and height of type double. Initialize the String to “” and the double to 0 in their respective declarations. These instance variables should be private so that they are not directly accessible from outside of the PentagonalPyramid class, and these should be the only instance variables in the class.
(2) Constructor: Your PentagonalPyramid class must contain a public constructor that accepts three parameters (see types of above) representing the label, base edge, height. Instead of assigning the parameters directly to the fields, the respective set method for each field (described below) should be called. For example, instead of the statement label = labelIn; use the statement setLabel(labelIn); Below are examples of how the constructor could be used to create PentagonalPyramid objects. Note that although String and numeric literals are used for the actual parameters (or arguments) in these examples, variables of the required type could have been used instead of the literals.
PentagonalPyramid ex1 = new PentagonalPyramid(“Ex 1″, 1, 2);
PentagonalPyramid ex2 = new PentagonalPyramid(” Ex 2 “, 12.3, 25.5);
PentagonalPyramid ex3 = new PentagonalPyramid(“Ex 3”, 123.4, 900);
(3) Methods: Usually a class provides methods to access and modify each of its instance variables (known as get and set methods) along with any other required methods. The methods for PentagonalPyramid, which should each be public, are described below. See formulas in Code and Test below. o getLabel: Accepts no parameters and returns a String representing the label field.
o setLabel: Takes a String parameter and returns a boolean. If the string parameter is not null, then the label field is set to the “trimmed” String and the method returns true. Otherwise, the method returns false and the label field is not set.
o getBaseEdge: Accepts no parameters and returns a double representing the base edge field.
o setBaseEdge: Accepts a double parameter and returns a boolean as follows. If the double is greater than zero, sets the base edge field to the double passed in and returns true. Otherwise, the method returns false and does not set the base edge field. o getHeight: Accepts no parameters and returns a double representing the height field.
o setHeight: Accepts a double parameter and returns a boolean as follows. If the double is greater than zero, sets the height field to the double passed in and returns true. Otherwise, the method returns false and does not set the height field.
o surfaceArea: Accepts no parameters and returns the double value for the total surface area calculated using formula above and the values of the base edge and height fields. See code and test below regarding the Math.tan(x) method.
o volume: Accepts no parameters and returns the double value for the volume calculated using formula above and the values of the base edge and height fields.
o toString: Returns a String containing the information about the PentagonalPyramid object formatted as shown below, including decimal formatting (“#,##0.0######”) for the double values. Newline and tab escape sequences should be used to achieve the proper layout. In addition to the field values (or corresponding “get” methods), the following methods should be used to compute appropriate values in the toString method: surfaceArea() and volume(). Each line should have no trailing spaces (e.g., there should be no spaces before a newline ( ) character). The toString value for ex1, ex2, and ex3 respectively are shown below (the blank lines are not part of the toString values).
PentagonalPyramid “Ex 1” with base edge = 1.0 and height = 2.0 units has:
surface area = 7.008203 square units volume = 1.1469849 cubic units
PentagonalPyramid “Ex 2” with base edge = 12.3 and height = 25.5 units has:
surface area = 1,086.4892066 square units volume = 2,212.4737204 cubic units
PentagonalPyramid “Ex 3” with base edge = 123.4 and height = 900.0 units has: surface area = 305,081.9691528 square units volume = 7,859,601.8538338 cubic units
Code and Test: Math.tan(x) expects x to be in radians rather than degrees. In the formula, 54 degrees can be converted to radians using Math.toRadians(54). The following combines the two methods: Math.tan(Math.toRadians(54))
• PentagonalPyramidApp.java
Requirements: Create a PentagonalPyramidApp class with a main method that reads in values
for label, base edge, and height. After the values have been read in, main creates a PentagonalPyramid object and then prints a new line and the object.
Design: The main method should prompt the user to enter the label, base edge, and height. After a value is read in for base edge, if the value is less than or equal to zero, an appropriate message (see examples below) should be printed followed by a return from main. Similarly, after a value is read in for height, if the value is less than or equal to zero, an appropriate message (see examples below) should be printed followed by a return from main. Assuming that base edge and height are positive, a PentagonalPyramid object should be created and printed.
Below is an example where the user has entered a non-positive value for base edge. Your program input/output should be exactly as follows.
Line # Program input/output
1
2
3
4 Enter label, base edge, and height for a pentagonal pyramid.
label: PentagonalPyramid with a bad base edge value base edge: -5
Error: base edge must be greater than 0.
Below is an example where the user has entered a non-positive value for height. Your program input/output should be exactly as follows.
Line # Program input/output
1
2
3
4
5 Enter label, base edge, and height for a pentagonal pyramid.
label: PentagonalPyramid with a bad height value
base edge: 10.0 height: 0
Error: height must be greater than 0.
Below is an example where the user has the values from ex1, the first example, above for label, base edge, and height. Your program input/output should be exactly as follows.
Line # Program input/output
1
2
3
4
5
6
7
8
9 Enter label, base edge, and height for a pentagonal pyramid.
label: Ex 1 base edge: 1 height: 2
PentagonalPyramid “Ex 1″ with base edge = 1.0 and height = 2.0 units has:
surface area = 7.008203 square units volume = 1.1469849 cubic units
Code: Your program should use the nextLine method of the Scanner class to read user input. Note that this method returns the input as a String. Whenever necessary, you can use the Double.parseDouble method to convert the input String to a double. For example:
Double.parseDouble(s1) will return the double value represented by String s1. For the printed lines requesting input for label, base edge, and height, use a tab ” ” rather than three spaces. After you have created the object, it can be printed simply by using its variable name;
i.e., when the object variable name is evaluated in the println statement, its toString() method is automatically called. Thus, printing the object reference variable myObj is equivalent to printing the return value of the myObj.toString() method call.
General Notes
1. All input from the keyboard and all output to the screen should done in the main method. Only one Scanner object on System.in should be created and this should be done in the main method. All printing (i.e., using the System.out.print and System.out.println methods) should be in the main method. Hence, none of your methods in the PentagonalPyramid class should do any input/output (I/O).
2. When a method has a return value, you can ignore the return value if it is no interest in the current context. For example, when setBaseEdge(3.5) is invoked, it returns true to let the caller know the base edge field was set; whereas setBaseEdge(-3.5) will return false indicating the edge field was not set. If the caller knows that x is positive, then the return value of setBaseEdge(x) can safely be ignored since it can be assumed to be true.
