It is a process of collecting and interpreting facts, identifying the problems, and decomposition of a system into its components.
System analysis is conducted for the purpose of studying a system or its parts in order to identify its objectives. It is a problem-solving technique that improves the system and ensures that all the components of the system work efficiently to accomplish their purpose.
Analysis specifies what the system should do.
It is a process of planning a new business system or replacing an existing system by defining its components or modules to satisfy the specific requirements.
Before planning, you need to understand the old system thoroughly and determine how computers can best be used in order to operate efficiently.
System Design focuses on how to accomplish the objective of the system.
System Analysis and Design (SAD) mainly focuses on −
What is a System?
The word System is derived from Greek word Systema, which means an organized relationship between any set of components to achieve some common cause or objective.
A system is “an orderly grouping of interdependent components linked together according to a plan to achieve a specific goal.”
Constraints of a System
A system must have three basic constraints −
- A system must have some structure and behaviorwhich is designed to achieve a predefined objective.
- Interconnectivity and interdependence must exist among the system components.
- The objectives of the organization have a higher priority than the objectives of its subsystems.
For example, traffic management system, payroll system, automatic library system, human resources information system.
Properties of a System
A system has the following properties −
Organization implies structure and order. It is the arrangement of components that helps to achieve predetermined objectives.
It is defined by the manner in which the components operate with each other.
For example, in an organization, purchasing department must interact with production department and payroll with personnel department.
Interdependence means how the components of a system depend on one another. For proper functioning, the components are coordinated and linked together according to a specified plan. The output of one subsystem is the required by other subsystem as input.
Integration is concerned with how a system components are connected together. It means that the parts of the system work together within the system even if each part performs a unique function.
The objective of system must be central. It may be real or stated. It is not uncommon for an organization to state an objective and operate to achieve another.
The users must know the main objective of a computer application early in the analysis for a successful design and conversion.
Elements of a System
The following diagram shows the elements of a system −
Outputs and Inputs
- The main aim of a system is to produce an output which is useful for its user.
- Inputs are the information that enters into the system for processing.
- Output is the outcome of processing.
- The processor is the element of a system that involves the actual transformation of input into output.
- It is the operational component of a system. Processors may modify the input either totally or partially, depending on the output specification.
- As the output specifications change, so does the processing. In some cases, input is also modified to enable the processor for handling the transformation.
- The control element guides the system.
- It is the decision–making subsystem that controls the pattern of activities governing input, processing, and output.
- The behavior of a computer System is controlled by the Operating System and software. In order to keep system in balance, what and how much input is needed is determined by Output Specifications.
- Feedback provides the control in a dynamic system.
- Positive feedback is routine in nature that encourages the performance of the system.
- Negative feedback is informational in nature that provides the controller with information for action.
- The environment is the “supersystem” within which an organization operates.
- It is the source of external elements that strike on the system.
- It determines how a system must function. For example, vendors and competitors of organization’s environment, may provide constraints that affect the actual performance of the business.
Boundaries and Interface
- A system should be defined by its boundaries. Boundaries are the limits that identify its components, processes, and interrelationship when it interfaces with another system.
- Each system has boundaries that determine its sphere of influence and control.
- The knowledge of the boundaries of a given system is crucial in determining the nature of its interface with other systems for successful design.
Types of Systems
The systems can be divided into the following types −
Physical or Abstract Systems
- Physical systems are tangible entities. We can touch and feel them.
- Physical System may be static or dynamic in nature. For example, desks and chairs are the physical parts of computer center which are static. A programmed computer is a dynamic system in which programs, data, and applications can change according to the user’s needs.
- Abstract systems are non-physical entities or conceptual that may be formulas, representation or model of a real system.
Open or Closed Systems
- An open system must interact with its environment. It receives inputs from and delivers outputs to the outside of the system. For example, an information system which must adapt to the changing environmental conditions.
- A closed system does not interact with its environment. It is isolated from environmental influences. A completely closed system is rare in reality.
Adaptive and Non Adaptive System
- Adaptive System responds to the change in the environment in a way to improve their performance and to survive. For example, human beings, animals.
- Non Adaptive System is the system which does not respond to the environment. For example, machines.
Permanent or Temporary System
- Permanent System persists for long time. For example, business policies.
- Temporary System is made for specified time and after that they are demolished. For example, A DJ system is set up for a program and it is dissembled after the program.
Natural and Manufactured System
- Natural systems are created by the nature. For example, Solar system, seasonal system.
- Manufactured System is the man-made system. For example, Rockets, dams, trains.
Deterministic or Probabilistic System
- Deterministic system operates in a predictable manner and the interaction between system components is known with certainty. For example, two molecules of hydrogen and one molecule of oxygen makes water.
- Probabilistic System shows uncertain behavior. The exact output is not known. For example, Weather forecasting, mail delivery.
Social, Human-Machine, Machine System
- Social System is made up of people. For example, social clubs, societies.
- In Human-Machine System, both human and machines are involved to perform a particular task. For example, Computer programming.
- Machine System is where human interference is neglected. All the tasks are performed by the machine. For example, an autonomous robot.
Man–Made Information Systems
- It is an interconnected set of information resources to manage data for particular organization, under Direct Management Control (DMC).
- This system includes hardware, software, communication, data, and application for producing information according to the need of an organization.Man-made information systems are divided into three types −
- Formal Information System − It is based on the flow of information in the form of memos, instructions, etc., from top level to lower levels of management.
- Informal Information System − This is employee based system which solves the day to day work related problems.
- Computer Based System − This system is directly dependent on the computer for managing business applications. For example, automatic library system, railway reservation system, banking system, etc.
- A schematic model is a 2-D chart that shows system elements and their linkages.
- Different arrows are used to show information flow, material flow, and information feedback.
Flow System Models
- A flow system model shows the orderly flow of the material, energy, and information that hold the system together.
- Program Evaluation and Review Technique (PERT), for example, is used to abstract a real world system in model form.
Static System Models
- They represent one pair of relationships such as activity–time or cost–quantity.
- The Gantt chart, for example, gives a static picture of an activity-time relationship.
Dynamic System Models
- Business organizations are dynamic systems. A dynamic model approximates the type of organization or application that analysts deal with.
- It shows an ongoing, constantly changing status of the system. It consists of −
- Inputs that enter the system
- The processor through which transformation takes place
- The program(s) required for processing
- The output(s) that result from processing.
Categories of Information
There are three categories of information related to managerial levels and the decision managers make.
- This information is required by topmost management for long range planning policies for next few years. For example, trends in revenues, financial investment, and human resources, and population growth.
- This type of information is achieved with the aid of Decision Support System (DSS).
- This type of Information is required by middle management for short and intermediate range planning which is in terms of months. For example, sales analysis, cash flow projection, and annual financial statements.
- It is achieved with the aid of Management Information Systems (MIS).
- This type of information is required by low management for daily and short term planning to enforce day-to-day operational activities. For example, keeping employee attendance records, overdue purchase orders, and current stocks available.
- It is achieved with the aid of Data Processing Systems (DPS).
“What are the benefits of system analysis?”
Costs, Efficiency & Flexibility
When a system analysis is properly performed, it makes certain that the correct path is taken with regards to applications and it helps to minimize errors which reduce future IT requirements for fixing problems. If the above process is performed properly, it will not only save the company money up front but ensures that the right application path is being taken the 1st time, growth and business charge considerations have been accounted to accommodate future plans, and errors are kept to a minimum thereby mitigating future IT overhaul requirements.
Better Management; Better controls
System analysis allows for better management through changing the software to suit any business changes, this means that the final product will be totally controllable. If changes or enhancements are required, the requirement of rewriting the whole software will be removed, which is normally costly.
Through the process potential threats are identified. A risk assessment is carried out to evaluate all the negative impacts on the processes. After deeply considering this, a comparison of the risk is made against the related benefits and a decision is taken accordingly.
The quality of the systems is ensured through the checking of the system constantly through system analysis.
Although System analysis offers an extensive range of benefits it might also have some disadvantages. One of the main disadvantages which is mostly overlooked is the risk of too much analysing which may be costly and time-consuming. It is therefore part of the analyst’s job to find the right balance.
Here at FTIAS we constantly focus on providing deep system analysis in order to custom build the system according to the company’s requirements.
This also includes certain off-the-shelf software such as SAP. This will allow us to continuously enhance and develop the systems to provide further efficiency into our processes.
We also use external diagramming and graphics applications such as Microsoft Visio in order to produce detailed flowcharts to highlight all the movement and actions involved in a particular system,
System analysis is the first step of a 7 step approach called System Development Life Cycle as highlighted in the diagram above used to achieve a successful system implementation.