The Rapid Application Development Model was first proposed by IBM in 1980’s. The critical feature of this model is the use of powerful development tools and techniques.
A software project can be implemented using this model if the project can be broken down into small modules wherein each module can be assigned independently to separate teams. These modules can finally be combined to form the final product.
Development of each module involves the various basic steps as in waterfall model i.e analyzing, designing, coding and then testing, etc. as shown in the figure.
Another striking feature of this model is a short time span i.e the time frame for delivery(time-box) is generally 60-90 days.
The use of powerful developer tools such as JAVA, C++, Visual BASIC, XML, etc. is also an integral part of the projects.
This model consists of 4 basic phases:
- Requirements Planning –
It involves the use of various techniques used in requirements elicitation like brainstorming, task analysis, form analysis, user scenarios, FAST (Facilitated Application Development Technique), etc. It also consists of the entire structured plan describing the critical data, methods to obtain it and then processing it to form final refined model.
- User Description –
This phase consists of taking user feedback and building the prototype using developer tools. In other words, it includes re-examination and validation of the data collected in the first phase. The dataset attributes are also identified and elucidated in this phase.
- Construction –
In this phase, refinement of the prototype and delivery takes place. It includes the actual use of powerful automated tools to transform process and data models into the final working product. All the required modifications and enhancements are too done in this phase.
- Cutover –
All the interfaces between the independent modules developed by separate teams have to be tested properly. The use of powerfully automated tools and subparts makes testing easier. This is followed by acceptance testing by the user.
The process involves building a rapid prototype, delivering it to the customer and the taking feedback. After validation by the customer, SRS document is developed and the design is finalised.
- Use of reusable components helps to reduce the cycle time of the project.
- Feedback from the customer is available at initial stages.
- Reduced costs as fewer developers are required.
- Use of powerful development tools results in better quality products in comparatively shorter time spans.
- The progress and development of the project can be measured through the various stages.
- It is easier to accommodate changing requirements due to the short iteration time spans.
- The use of powerful and efficient tools requires highly skilled professionals.
- The absence of reusable components can lead to failure of the project.
- The team leader must work closely with the developers and customers to close the project in time.
- The systems which cannot be modularized suitably cannot use this model.
- Customer involvement is required throughout the life cycle.
- It is not meant for small scale projects as for such cases, the cost of using automated tools and techniques may exceed the entire budget of the project.
- This model should be used for a system with known requirements and requiring short development time.
- It is also suitable for projects where requirements can be modularized and reusable components are also available for development.
- The model can also be used when already existing system components can be used in developing a new system with minimum changes.
- This model can only be used if the teams consist of domain experts. This is because relevant knowledge and ability to use powerful techniques is a necessity.
- The model should be chosen when the budget permits the use of automated tools and techniques required.
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- Steps in Rapid Application Development (RAD) model
- Modern Principles Of Software Development
- Software Engineering | Project size estimation techniques
- Types of Software Testing
- Software Testing | Basics
- Software Engineering | Architectural Design
- Software Engineering | Halstead’s Software Metrics
- Beta Testing | Software Testing
- Software Engineering | Debugging Approaches
- Personal Software Process (PSP)
- Pairwise Software Testing
- Software Engineering | COCOMO Model
- Software Engineering | Classification of Software Requirements
- Software Engineering | Classical Waterfall Model
- Software Engineering | Iterative Waterfall Model
- Software Engineering | Spiral Model
- Software Engineering | Requirements Engineering Process
- Software Engineering | Requirements Elicitation
- Software Engineering | System configuration management
- Software Engineering | Challenges in eliciting requirements