System Definition

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After the determination of the need for a new or modified system, system definition activities are conducted to describe the system in detail. The activities are grouped and described as generic processes that are performed iteratively and/or concurrently depending on the selected development cycle model. These consist of the definition of system requirements, the definition of the logical and physical system architecture, and system analysis. During and/or at the end of each iteration, gap analysis is performed to ensure that all system requirements have been mapped to the architecture and design.

System definition activities build on the artifacts and decisions from concept definition, primarily the articulation of the mission of the system of interest (SoI), the needs and requirements of stakeholders, and preliminary operational concepts. The products of system definition activities (system requirements, architecture, etc.) are inputs to system realization. The specific activities and sequence of system definition activities will be dependent upon the type of life cycle model being utilized.

Topics

Each part of the SEBoK is divided into knowledge areas (KAs), which are groupings of information with a related theme. The KAs in turn are divided into topics. This KA contains the following topics:

See the article Matrix of Implementation Examples for a mapping of case studies and vignettes included in Part 7 to topics covered in Part 3.

System Views and System Elements

To engineer a system, a set of engineering elements, characteristics, and properties have to be defined. These elements can be grouped by several views:

  • Needs and requirements view,
  • Architecture view,
  • Boundary and interface view, or
  • System breakdown view.

Each of these views is described in the following sections.

Needs and Requirements View

The following characteristics provide a global understanding of the system in its context of use and when seen as a black box:

  • The purpose states the relevance of the system within the context of use.
  • The mission expresses the set of services the system provides, the main and global transformation it performs, and how it fulfills a capability or need for the enterprise.
  • The objectives are elements that quantify the mission as a set of measurable data related to space, time and effectiveness.
  • The expression of the mission is generally an abstraction of a set of actions performed by the system within its context of use and under operational conditions. This set of actions is called operational scenario and describes how these actions are related to each other, as well as what they exchange with the elements of the context.

All these elements are refined iteratively until a comprehensive view of the system within its context is obtained. They are used to elicit needs, to define stakeholder requirements, then system requirements.

Architecture View

There are several architectural representations or views/models of the system:

  • The logical architecture supports the logical operation of the system all along its life cycle, and includes functional, behavioral, and temporal views/models. Operational scenarios refine the mission into a collection of functions and dynamic structures that describe how the mission is performed (behavior).
  • The physical architecture is a set of system elements performing functions of the system. Those system elements can be either material or immaterial (e.g., equipments made of hardware, software and/or human roles).

The logical and physical representations of the system architecture are mapped onto each other. The interactions between system elements are defined by interfaces whose complexity strongly depends on the way the system architecture is defined.

Boundary and Interface View

Boundary of the system depends on what engineers include within the scope of the system and outside of it. This view encompasses

Interactions are modeled and defined using operational scenarios.

System breakdown View

Facing the potential number of system elements that constitute the physical architecture, sets of system elements can be grouped to form systems. The decomposition of the SoI (highest level) may include several layers of systems (intermediate levels of systems) until technological system elements (lowest level) are defined. Any layer of the decomposition may include systems and non-decomposable technological system elements.

Because a system element is primarily a system, it can be characterized in its turn using the previous views in its own context. The notion of system as described and defined here is recursive.

Other views of a system are possible to describe a more complete set of characteristics – refer to architectural frameworks (DoDAF, MODAF, NAF, TOGAF, etc.) discussed in the Concept Definition article.

Top-down and Recursive Approach to System Decomposition

System definition is managed through methodical top-down decomposition of the SoI into systems and system elements. As the system architecture definition advances, emerging systems and system elements form a system breakdown structure (SBS). For project management purposes, every system of the SBS may be included in a building block, a notion introduced in (ANSI/EIA 1998), also called system block.

Stakeholder requirements and system requirements exist at all layers of the SBS. In ISO/IEC/IEEE (2011), these layers are known as levels of abstraction. Along with systematically introducing layers of systems, the architecture and design process manages the transformation of system requirements through levels of abstraction. Figure 1 portrays this approach.

Figure 1. Top-down Development of Architecture and Design, and Requirements (Faisandier 2012). Permission granted by Sinergy'Com. All other rights are reserved by the copyright owner.

As shown in Figure 1

  • The white ovals represent requirements at decreasing levels of abstraction, and the arrows represent the transformation of those requirements through the levels using architecture and design process. Stakeholder expressions of needs, expectations, and constraints are transformed into stakeholder requirements.
  • The next transformation crosses the boundary between the problem and solution areas by converting stakeholder requirements into system requirements, reflecting the bounded solution space.
  • At the SoI level, the system architecture is developed that serves to identify systems, system elements, and how they operate together to address the SoI requirements.

This approach is applied recursively for each level of abstraction/decomposition recognizing that the same generic processes are applied at multiple levels of abstraction. Figure 2 below portrays the engineering that occurs in each system block. As necessary, system elements are defined through sets of system element requirements, which become inputs to other system blocks (level n+1). The approach is then recursively applied using the system definition processes.

Figure 2. Recursive Instantiation of Definition Processes (Faisandier 2012). Permission granted by Sinergy'Com. All other rights are reserved by the copyright owner.

At the n+1 level, the systems or system elements may also collect other stakeholder requirements that are directly pertinent to this level of architecture and design. Processes within each system are generic, but unique in local purpose, scope and context.

System Architecture

Within the SE community, notions of architecture seem to have been heavily influenced by ISO/IEC 15288 (2008), which even today presents a somewhat implicit view of architecture, conflating it with design as part of a single system life cycle process called architectural design. Although there are diverse viewpoints on architecture, the different perspectives have much in common. We consider systems engineering to cover all aspects of the creation of a system, including system architecture.

The majority of interpretations of system architecture are based on the fairly intangible notion of structure – i.e. relationships between elements.

Some authors limit the types of structure considered to be architectural; say, for example, restricting themselves to functional and physical structure. Recent practice has extended consideration to include temporal and other dimensions of structure within specified architectural frameworks (DoDAF (DoD 2010) and MODAF (MOD 2010)).

ISO/IEC/IEEE 42010 (2011) provides a useful description of the architecture considering the stakeholder concerns, architecture viewpoints, architecture views, architecture models, architecture descriptions, and architecting in the life cycle. A discussion of the features of systems architectures can be found in Maier and Rechtin (2009).

While architectural concepts are very useful and widely used in SE, there is a lack of consistency across communities of practice with potential for confusion. An attempt to develop and apply a systematic approach to characterizing architecture belief systems in systems engineering has been described by the INCOSE UK Architecture Working Group (Wilkinson et al.2010, Wilkinson 2010).

System Design

In industrial practices, the term design is often used to mean both architecture and design as defined in the SEBoK. In the recent past, professionals used the term design when they dealt with simpler technological products - ones that do not include several different and interconnected technological components such as hardware, software, operators, services, etc. In the development of new multi-technology products and services, professionals have recognized the usefulness of the notion of system in dealing with complexity (interconnections level, multi-techno, emergence, etc.).

It was in light of complexity that structuring what composes a system became necessary. This structure explains the functional, behavioral, temporal, physical, and other aspects of a system as previously described. Practitioners found the term structure inadequate to describe all of these aspects of a system. The terms architecture and architectural design have been used for approximately 30 years, particularly in software intensive systems and in some domains such as the space industry. The set of different types and interrelated structures can be understood as the architecture of the system.

The trend today is to consider system architecture and design as different sets of activities; attempts are made to define separate concurrent processes, but they are strongly intertwined:

  • System design includes activities to conceive a system that answers an intended purpose, using principles and concepts; it includes assessments and decisions to select elements that compose the system, fit the architecture of the system, and comply traded-off system requirements. It is the complete set of detailed models, properties or characteristics described into a form suitable for implementation.
  • System architecture is more abstract, conceptualization-oriented, global, and focused on mission success and on high level structure in (sub)systems.

The purpose of system design is to make the link between the system architecture and the implementation of technological system elements that compose the physical architecture of the system.

These related processes are presented together in the present version of the SEBoK, though effort has been made to distinguish between the corresponding activities.

General System Architecture and Design principles and Concepts

Classification of Principles and Heuristics

Engineers and architects use a mixture of mathematical principles and heuristics learned from experience. When an issue is identified through system requirements, principles and heuristics may or may not be able to address it. Principles and heuristics that are used in system views/models can be classified into the following domains:

  1. Static domain relates to physical structure or organization of the SoI broken down into systems and system elements. It deals with partitioning systems, system elements, and physical interfaces.
  2. Dynamic domain relates to logical architecture models; in particular, to the representation of the behavior of the system. It includes a description of functions (i.e. transformations of input/output flows) and interactions between functions of the system and between those of the external objects or systems. It takes into account reactions to events that launch or stop the execution of functions of the system. It also deals with the effectiveness (performances, operational conditions) of the system.
  3. Temporal domain relates to temporal invariance levels of the execution of functions of the system. This means that every function is executed according to cyclic or synchronous characteristics. It includes decisional levels that are asynchronous characteristics of the behavior of some functions.
  4. Environmental domain relates to enablers (production, logistics support, etc.), but also to survivability of the system in reaction to natural hazards or threats and to the integrity of the system in reaction to internal potential hazards. This includes, for example, climatic, mechanical, electromagnetic, and biological aspects.

More detailed classification can be found in Maier and Rechtin (2009).

Transition from System Requirements to Physical Architecture

The aim of the approach is to progress from system requirements (representing the problem from a supplier/designer point of view, as independent of technology as possible) to an intermediate model of logical architecture , then to allocate the elements of the logical architecture to system elements of candidate physical architectures.

Design decisions and technological solutions are selected according to performance criteria and non-functional requirements such as operational conditions and life cycle constraints (e.g., environmental conditions, maintenance constraints, realization constraints, etc.) as illustrated in Figure 3. Creating intermediate models such as logical architecture models enables facilitation of the validation of functional, behavioral, temporal properties of the system against system requirements which have no major technological influence, and changing during the life of the system the physical interfaces or the technological layer without completely questioning the logical functioning of the system.

Figure 3. Usage of Intermediate Logical Architecture Models During Architecture and Design (Faisandier 2012). Permission granted by Sinergy'Com. All other rights are reserved by the copyright owner.

Iterations between Logical and Physical Architecture definition

Architecture and design activities require spending several iterations from logical architecture models definitions to physical architecture models definitions and vice versa, until both logical and physical architecture models are exhaustive and consistent. The first architecture and design activity is the creation of a logical architecture model based on nominal scenarios (of functions). Physical architecture is used to determine main system elements that could perform system functions and to organize them into a physical architecture model.

A second logical architecture iteration can take into account allocations of functions to system elements and derived functions coming from physical solution choices. It also supplements the initial logical architecture model by introducing other scenarios, failure analyses, and every operational requirement not taken before. Derived functions must, in their turn, be allocated to system elements. This, in turn, affects the physical architecture models.

Additional architecture and design iterations can produce an exhaustive and consistent logical and physical solution. During system design, technological choices can potentially lead to new functions, new input/output and control flows, and new physical interfaces. These new elements can conduct to creation of new system requirements, called “derived requirements”.

Concept of Interface

The concept of interface is one of the most important to consider when defining the architecture of a system. The fundamental aspect of an interface is functional and is defined as inputs and outputs of functions. As functions are performed by physical elements (system elements), inputs/outputs of functions are also carried by physical elements; these are called physical interfaces. Consequentially, both functional and physical aspects are considered in the notion of interface. A detailed analysis of an interface shows the function “send,” located in one system element, the function “receive,” located in the other one, and the function “carry,” performed by the physical interface which supports the input/output flow (see Figure 5).

Figure 4. Complete Interface Representation (Faisandier 2012). Permission granted by Sinergy'Com. All other rights are reserved by the copyright owner.

In the context of complex exchanges between system elements, particularly in software-intensive systems, a protocol is seen as a physical interface that carries exchanges of data.

Re-use of System Elements

Systems engineers frequently utilize existing system elements. This re-use constraint has to be identified as a system requirement and carefully taken into account during architecture and design. One can distinguish three general cases when re-using system elements, as shown in Table 1.

Table 1. System Element Re-use Cases (Faisandier 2012). Permission granted by Sinergy'Com. All other rights are reserved by the copyright owner.
Re-use Case Actions and Comments
Case 1: The requirements of the system element are up-to-date and it will be re-used with no modification required
  • The system architecture to be designed will have to adapt to the boundaries, interfaces, functions, effectiveness, and behavior of the re-used system element.
  • If the system element is not adapted, costs, complexity, and risks will increase.
Case 2: The requirements of the system element are up-to-date and it will be re-used with possible modifications
  • The system architecture to be designed is flexible enough to accommodate the boundaries, interfaces, functions, effectiveness, and behavior of the re-used system element.
  • The design of the reused system element, including its test reports and other documentation, will be evaluated and potentially redesigned.
Case 3: The requirements are not up-to-date or do not exist
  • It is necessary to reverse engineer the system element to identify its boundaries, interfaces, functions, performances, and behavior.
  • This is a difficult activity, since the extant documentation for the re-used system element is likely unavailable or insufficient.
  • Reverse engineering is expensive in terms of both time and money, and brings with it increased risk.


There is a common idea that re-use is "free"; however, if not approached correctly, re-use may introduce risks that can be significant for the project (costs, deadlines, complexity).

References

Works Cited

ANSI/IEEE. 2000. Recommended Practice for Architectural Description for Software-Intensive Systems. New York, NY, USA: American National Standards Institute (ANSI)/Institute of Electrical and Electronics Engineers (IEEE), ANSI/IEEE 1471-2000.

ANSI/EIA. 1998. Processes for Engineering a System. Philadelphia, PA, USA: American National Standards Institute (ANSI)/Electronic Industries Association (EIA), ANSI/EIA-632-1998.

DOD. 2010. “DOD Architecture Framework.” Version 2.02. Arlington, VA, USA: US Department of Defense. Available at: http://cio-nii.defense.gov/sites/dodaf20/

Faisandier, A. 2012. Systems Architecture and Design. Belberaud, France: Sinergy'Com.

INCOSE. 2010. INCOSE Systems Engineering Handbook. Version 3.2. San Diego, CA, USA: International Council on Systems Engineering (INCOSE), INCOSE-TP-2003-002-03.2.

ISO/IEC 2008. Systems and Software Engineering -- System Life Cycle Processes. Geneva, Switzerland: International Organisation for Standardisation / International Electrotechnical Commissions. ISO/IEC/IEEE 15288:2008 (E).

ISO/IEC/IEEE. 2011. Systems and software engineering - Requirements Engineering. Geneva, Switzerland: International Organization for Standardization (ISO)/International Electrotechnical Commission/ Institute of Electrical and Electronics Engineers (IEEE), (IEC), ISO/IEC/IEEE 29148.

ISO/IEC/IEEE. 2011. Systems and software engineering - Architecture description. Geneva, Switzerland: International Organization for Standardization (ISO)/International Electrotechnical Commission (IEC)/Institute of Electrical and Electronics Engineers (IEEE), ISO/IEC/IEEE 42010.

Maier, M., and E. Rechtin. 2009. The Art of Systems Architecting. 3rd ed. Boca Raton, FL, USA: CRC Press.

MOD. 2010. “MOD Architecture Framework”. Version 1.2.004. UK Ministry of Defence. Available at: http://www.mod.uk/DefenceInternet/AboutDefence/WhatWeDo/InformationManagement/MODAF/.

Stevens, R. P. Brook, K. Jackson, S. Arnold. 1998. Systems Engineering - Coping with Complexity. Englewood Cliffs, NJ, USA: Prentice-Hall.

Wilkinson, M., A. James, M. Emes, P. King, P. Bryant. 2010. “Belief Systems in Systems Architecting: Method and Preliminary Applications," paper presented at the IEEE SMC Society’s 5th International Conference on System of Systems Engineering (SoSE). 22nd-24th June 2010. Loughborough University, UK.

Wilkinson, M. K. 2010. “Z8: Systems Architecture”, in Z-guide series. INCOSE UK, available from INCOSE UK at: http://www.incoseonline.org.uk/Program_Files/Publications/zGuides.aspx?CatID=Publications

Primary References

ANSI/EIA. 1998. Processes for Engineering a System. Philadelphia, PA, USA: American National Standards Institute (ANSI)/Electronic Industries Association (EIA), ANSI/EIA 632-1998.

Blanchard, B. S., and W. J. Fabrycky. 2005. Systems Engineering and Analysis. 4th ed. Prentice-Hall International Series in Industrial and Systems Engineering. Englewood Cliffs, NJ, USA: Prentice-Hall.

INCOSE. 2011. INCOSE Systems Engineering Handbook: A Guide for System Life Cycle Processes and Activities. Version 3.2.1. San Diego, CA, USA: International Council on Systems Engineering (INCOSE), INCOSE-TP-2003-002-03.2.1.

ISO/IEC. 2007. Systems Engineering – Application and Management of The Systems Engineering Process. Geneva, Switzerland: International Organization for Standards (ISO)/International Electronical Commission (IEC), ISO/IEC 26702:2007.

ISO/IEC/IEEE. 2008. Systems and Software Engineering - System Life Cycle Processes. Geneva, Switzerland: International Organization for Standardization (ISO)/International Electronical Commission (IEC), Institute of Electrical and Electronics Engineers. ISO/IEC/IEEE 15288:2008 (E).

ISO/IEC/IEEE. 2011. Systems and Software Engineering - Requirements Engineering. Geneva, Switzerland: International Organization for Standardization (ISO)/International Electrotechnical Commission/ Institute of Electrical and Electronics Engineers (IEEE), (IEC), ISO/IEC/IEEE 29148.

ISO/IEC/IEEE. 2011. Systems and Software Engineering - Architecture Description. Geneva, Switzerland: International Organization for Standardization (ISO)/International Electrotechnical Commission (IEC)/Institute of Electrical and Electronics Engineers (IEEE), ISO/IEC/IEEE 42010.

Martin, J.N. 1997. Systems Engineering Guidebook: A process for developing systems and products. 1st ed. Boca Raton, FL, USA: CRC Press.

NASA. 2007. Systems Engineering Handbook. Washington, D.C.: National Aeronautics and Space Administration (NASA), NASA/SP-2007-6105.

Additional References

Baldwin, Carliss Y., and Kim B. Clark. 2000. Design Rules. Cambridge, Mass: MIT Press.

Buede, D.M. 2009. The Engineering Design of Systems: Models and Methods. 2nd ed. Hoboken, NJ, USA: John Wiley & Sons Inc.

DoD. 2010. DOD Architecture Framework. Version 2.02. Arlington, VA, USA: US Department of Defense. Available at: http://cio-nii.defense.gov/sites/dodaf20/

Faisandier, A. 2012. Systems Architecture and Design. Belberaud, France: Sinergy'Com.

Hatley, Derek J., and Imtiaz A. Pirbhai. 1987. Strategies for Real-Time System Specification. New York, NY: Dorset House Pub.

MOD. 2010. MOD Architecture Framework. Version 1.2.004. UK Ministry of Defence. Available at: http://www.mod.uk/DefenceInternet/AboutDefence/WhatWeDo/InformationManagement/MODAF/.

Stevens, R. P. Brook, K. Jackson, S. Arnold. 1998. Systems Engineering - Coping with Complexity. Englewood Cliffs, NJ, USA: Prentice-Hall.

Wilkinson, M., A. James, M. Emes, P. King, P. Bryant. 2010. Belief Systems in Systems Architecting: Method and Preliminary Applications. paper presented at the IEEE SMC Society’s 5th International Conference on System of Systems Engineering (SoSE). 22nd-24th June 2010. Loughborough University, UK.


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