CONVERTING DESIGN DIAGRAMS INTO PROGRAM CODE

CONVERTING DESIGN DIAGRAMS INTO PROGRAM CODE

The primary theme of the paper is CONVERTING DESIGN DIAGRAMS INTO PROGRAM CODE in which you are required to emphasize its aspects in detail. The cost of the paper starts from $109 and it has been purchased and rated 4.9 points on the scale of 5 points by the students. To gain deeper insights into the paper and achieve fresh information, kindly contact our support.

Task

In this assignment, you are required to complete the followings to validate your system designs. 

You have the following two choices to develop detailed object-oriented design models. You also need to submit a proper documentation describing the different aspect of developed component, within 2000 words.

Task 1: The students who have expertise in object-oriented programming are required to validate their system design through developing a prototype for at least one subsystem of chosen case study. You have an option to use any object-oriented programming language such as C++, Java, C#, etc. to develop this subsystem.

OR

Task 2: The students who have no expertise in object-oriented programming are required to validate their system design using interaction diagrams (i.e., communication diagrams or sequence diagrams) for at least one subsystem of chosen case study. To do this, identify 3 (three) most important use cases for the subsystem and develop communication diagrams or sequence diagrams for these use cases.


 

Rationale

The purpose of this assessment task is to develop student`s skills and knowledge in :
• validating an OO design through the construction of a prototype
• converting design diagrams into program code
• preparing project documentation
• developing presentations, and through peer review to reflect on their own practice and improve their design.

This assessment item links to the learning outcomes (LO) 1,2,3,4,5 and 6.   

Marking criteria

 

Criteria

HD

DI

CR

PS

FL

Task 1 (70%): The students who have expertise in object-oriented programming are required to validate their system design through developing a prototype for at least one subsystem of chosen case study. You have an option to use any object-oriented programming language such as C++, Java, C#, etc. to develop this subsystem.

OR

Task 2 (70%): The students who have no expertise in object-oriented programming are required to validate their system design using interaction diagrams (i.e., communication diagrams or sequence diagrams) for at least one subsystem of chosen case study. To do this, identify all possible use cases for the subsystem and develop communication diagrams or sequence diagrams for these use cases.
 


Task 1:
Fully functional prototype using major principles of object-oriented programming such as encapsulation, data abstraction, polymorphism and inheritance. Each variable, function/method, loops, if/else statements, etc are well commented.

 

 

 

 

 


OR


Task 2:
All possible use cases of the subsystem are identified; developed communication or sequence diagrams are correctly showing logical flow of the system activities, input/output messages, and accurate symbols/notations. 
 


Task 1:
Mostly fully functional prototype using major principles of object-oriented programming such as encapsulation, data abstraction, polymorphism and inheritance. Each variable, function/method, loops, if/else statements, etc are well commented.

 

 


OR


Task 2:
Major use cases of the subsystem are identified; developed communication or sequence diagrams are correctly showing logical flow of the system activities, input/output messages, and accurate symbols/notations. 
 


Task 1:
Mostly fully functional prototype using major principles of object-oriented programming such as encapsulation, data abstraction, polymorphism and inheritance. Each variable, function/method, loops, if/else statements, etc are well commented. 
Minor omission only

 

 

 


OR


Task 2:
Major use cases of the subsystem are identified; developed communication or sequence diagrams are correctly showing logical flow of the system activities, input/output messages, and accurate symbols/notations. 
Minor omission only
 


Task 1:
Prototype not always functional using major principles of object-oriented programming such as encapsulation, data abstraction, polymorphism and inheritance. Each variable, function/method, loops, if/else statements, etc are not well commented.

 

 

 

 


OR


Task 2:
Some use cases of the subsystem are identified; developed communication or sequence diagrams are mostly correct showing logical flow of the system activities, input/output messages, and accurate symbols/notations. 
 


Task 1:
Prototype has major errors and not working.

 

 

 

 

 

 

 

 

 

 

 


OR


Task 2:
Few use cases of the subsystem are identified; developed communication or sequence diagrams are wrong. 
 

Task 1 & Task 2 (30%)
Submit a proper documentation describing the different aspect of developed component, within 2000 words.
 

Task 1 & Task 2:

Comprehensive documentation which describes each component of developed system and has insights and awareness of deeper more subtle aspects of the case study.
 

Task 1 & Task 2:

Mostly comprehensive documentation which describes each component of developed system and has insights and awareness of deeper more subtle aspects of the case study.
 

Task 1 & Task 2:

Mostly comprehensive documentation which describes each component of developed system and has insights and awareness of deeper more subtle aspects of the case study.
Minor emission only
 

Task 1 & Task 2:

Reasonable documentation describes few components of developed system.
 

Task 1 & Task 2:

Documentation is wrong and not matching with system components. 
 

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