The event-partitioning approach is explained by Stephen M. McMenamin and John F. Palmer in Essential Systems Analysis.^[1] A brief version of the approach is described in the article on Data Flow Diagrams (DFDs). A more complete discussion is in Edward Yourdon's Just Enough Structured Analysis.^[2] The description focuses on using the technique to create data flow diagrams, but it can be used to identify use cases as well.

The premise of event partitioning is that systems exist to respond to external events: identify what happens in the business environment that requires planned responses, then define and build systems to respond according to the rules of the business. In particular, a business system exists to service the requests of customers. A customer, in the jargon of the Unified Modeling Language (UML), is an "actor".

Actor → Event → Detect → Respond edit

The method has the following steps.

• 1. Identify the external systems by brainstorming a list of the "actors" (external systems), which are the sources of external events. If you find a graphic to be helpful, create a context diagram showing the actors outside of the system under study and the flows/signals between them.
• 2. Putting oneself in the shoes of an "actor" (or working with actor representatives), brainstorm a list of the "external events" / "triggers" that they want the system to have a planned response to. (Note that the system cannot originate external events; only an actor can.)
• 3. Identify what will enable the system to detect the external events:
  • the arrival of one or more pieces of data (possibly in the form of a message)
  • the arrival of one or more points in time (called "temporal" events by M&P, and distinguished by them from external events)
• 4. Identify the planned response(s) that the system may carry out when the events occur. It's the response(s)/use case(s) that will enable the system to achieve its goals.

The technique was extended with "non-event" events by Paul T. Ward and Stephen J. Mellor in Structured Development for Real-Time Systems: Essential Modeling Techniques.^[3]

"Since the terminators [actors] are by definition outside the bounds of the system-building effort represented by the model, the implementors cannot modify the terminator [actor] technology at will to improve its reliability. Instead, they must build responses to terminator [actor] problems into the essential model of the system. A useful approach to modeling responses to terminator [actor] problems is to build a list of 'normal' events and then to ask, for each event, 'Does the system need to respond if this event fails to occur as expected?' " ^[4] [emphasis added]

Data dictionary notation edit

Yourdon/DeMarco style of data dictionary notation may be used to describe the composition and structure of data.

The data structure elements can map to structured programming′s control structures:

• "+" can map to a "sequence" of statements (although this is not necessarily so)
• "[|]" can map to "selection" (conditionals, switch statements)
• "{}", "()" can map to "iteration" (counting loop, pre-test loop, middle-test loop, post-test loop, and infinite loop)

NB. The items defined may be "material" (e.g., room key) as well as "data" (e.g., arrival date-time).

Identifying Requirements and Their Reasons edit

The event-response information may be captured in a table. The event is the raison d’être for the response, which gives "traceability" from the response back to the environment.

Defining requirements edit

This approach helps the analyst to decompose the system into "mentally bite-sized" mini-systems using events that require a planned response. The level of detail of each response is at the level of "primary use cases". Each planned response may be modelled using DFD notation or as a single use case using use case diagram notation.

The basic flow within a process or use case can usually be described in a relatively small number of steps, often fewer than twenty or thirty, possibly using something like "structured English". Ideally, all of the steps would be visible all at once (often a page or less). The intention is to reduce one of the risks associated with short-term memory, namely, forgetting what is not immediately visible ("out of sight, out of mind").

Alternatively, using the notations of structured techniques, an analyst could create a "Nassi–Shneiderman diagram". In the UML, the use case could be modelled using an activity diagram, a sequence diagram, or a communication diagram. This could be problematic if there are many complex scenarios of the use case; the analyst may wish to model all or most of the scenarios.

Complexity versus fragmentation edit

If the response is lengthy or complex (i.e., more than a page of text), an analyst may decompose ("factor out" or deduplicate) into smaller "secondary use cases" to keep the "parent" primary use case smaller and simpler. These secondary use cases may prove to be reusable as well. (In a UML use case diagram, they would be drawn as extended or included use cases, which are related to one or more primary use cases.)

While describing a use case, an analyst may also uncover "business rules". Some analysts suggest capturing business rules in a separate document using the Object Constraint Language or some other formal notation. Then when a business rule must be obeyed in a use case, the analyst makes reference to it. This minimises repetition ^[10] within a specification, but risks fragmentation of a specification. One technique that may reduce this tension is to use hyperlinks in the specification document.

This reductionist approach lies somewhat in contrast to a systems thinking approach as represented by Peter Checkland's soft systems methodology.

In addition to functional requirements captured in a use case description, an analyst may include such non-functional requirements as response time, learnability, etc.

• Business case
• SIPOC
• Use case
• Use case diagram
• User story

• Event partitioning Structured Analysis Wiki