Difference between revisions of "Diversity, Equity, and Inclusion"

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Revision as of 19:12, 18 May 2021


Lead Authors: Alan Harding, Alice Squires


Diversity, Equity, and Inclusion (DEI) foster increased engagement, productivity, and innovation in an organization.

Introduction

Systems engineers play a pivotal role in integrating concepts of diversity, equity, and inclusion within both the team and in the system design and development:

  1. Ensuring that the systems engineering team and its leadership is inclusive and welcomes a diverse range of talent, and where necessary taking deliberate action to provide equity.
  2. Ensuring that the systems we realise are as accommodating as possible of the differences within the entire stakeholder community. This is known as “inclusive engineering”.

Failure to address either aspect results in sub-optimal outcomes whether in terms of missed solutions, lower productivity, or delivering a system that does not fully meet the needs of the whole stakeholder community, i.e. failing to meet the ultimate goal of delivering a total optimal system solution. Systems engineers are responsible for effectively communicating the importance and value of diversity, equity, and inclusion in enabling, promoting, and advancing systems engineering and systems approaches to address complex societal and technical global challenges.

Figure 1 shows how an inclusive development approach contributes to realizing inclusive solutions, within the context of the human system (whether within an organisation, country, or the world), itself set within the context of the natural world. The natural world is shown because of the strong linkage between the full lifecycle of engineered products (from concept to disposal) and sustainable development. For instance:

  • Water pollution from industrial plants affecting those who live nearby
  • Air pollution from cars affecting pedestrians and those who live near major roads
  • Product end of life/disposal effects e.g. hazardous substances, contribution to land-fill
Figure 1. Relationship between Inclusive Approach and Inclusive Product. (SEBoK Original)

Definitions of Diversity, Equity, and Inclusion

The following definitions are taken from the Accreditation Board for Engineering and Technology (ref. 1), where they provide a reference point for conversations and materials about diversity, equity and inclusion.

  • DiversityDiversity is the range of human differences, encompassing the characteristics that make one individual or group different from another. Diversity includes, but is not limited to, the following characteristics: race, ethnicity, culture, gender identity and expression, age, national origin, religious beliefs, work sector, physical ability, sexual orientation, socioeconomic status, education, marital status, language, physical appearance, and cognitive differences.
  • EquityEquity is the fair treatment, access, opportunity and advancement for all people, achieved by intentional focus on their disparate needs, conditions and abilities. Achieving equity requires understanding of historical and systemic patterns of disparity to address and eliminate barriers, and remove participation gaps as part of a comprehensive strategy to achieve equitable outcomes and social justice.
  • InclusionInclusion is the intentional, proactive, and continuing efforts and practices in which all members respect, support, and value others. An inclusive environment provides equitable access to opportunities and resources, empowers everyone to participate equally, and offers respect in words and actions for all.

In its work, the International Council on Systems Engineering (INCOSE) uses the compound term Diversity, Equity and Inclusion (abbreviated to DEI) when referring to the broad subject matter. The definition of diversity given encompasses a wide range of characteristics. As an example, Figure 2 shows 28 of these characteristics recognised by INCOSE (ref. 2) grouped into five areas: intrinsic, employment, environment, interaction, and family. The figure shows the relevance of these characteristics to the INCOSE Systems Engineering Certification Program.

Figure 2. Categorized Dimensions of Diversity. (SEBoK Original, adapted from (Harding and Pickard 2019))

Relevance of Diversity, Equity, and Inclusion to Engineering

Engineers apply ingenuity, innovation, and systematic approaches to solve challenging problems. Life experience and academic research shows us that bringing a wide range of skills, knowledge, and thinking styles to bear on a problem is the most effective way to accelerate and improve the intended outcomes. These outcomes include improved “…financial performance, greater innovation and creativity, increased employee productivity and retention, improved customer or client orientation, and increased customer or client satisfaction.” (ref. 3). Hunt et al. (ref. 4) have found that companies at the forefront of gender and ethnic/cultural diversity in their leadership perform better financially. By contrast, a team of people with the same cultural background, life experiences, education, and thinking style could be expected to be relatively less effective and more prone to identifying predictable solutions. The US National Academy of Engineering (ref. 5) note the opportunity cost of a lack of diversity in terms of “designs not thought of, in solutions not produced.”

Inclusion, or ensuring a sense of inclusion in everyone, is necessary to ensure that all team members genuinely feel and believe that they belong and hence are able to use their talents and unique outlook to the maximum degree. By contrast, a lack of inclusion might make someone feel present but not involved or valued with the effect that the team as a whole does not deliver its best possible results.

Equity is not the same as equality, nor is it the same as inequality. It is simply giving more to those who need it, which is proportionate to their own circumstances, in order to ensure that everyone has the same opportunities. In an engineering context this might mean providing more support to a disadvantaged student so they can reach their full potential, or providing additional support or time to a team member with a condition such as dyslexia.

Relevance of Diversity, Equity, and Inclusion to Systems Engineering

DEI is vital to successful systems engineering because of the range of contexts in which it is applied and the consideration of multiple stakeholder viewpoints at the heart of the approach. Systems engineering is applied to a wide range of system types in a broad variety of contexts–engineered systems range from micro­electronics to aircraft, from abstract systems to smart cities. Systems engineers may be working with a customer, a prime contractor or integrator, a supplier or product manufacturer, a research/technology organisation, or a government body. And these activities take place all over the globe, often as part of consortiums or complex partnered programmes involving multiple organisations, countries, and cultures.

Applying systems engineering requires consideration of multiple viewpoints (such as the user, maintenance, safety, security) to achieve the proper holistic view of problem and solution. This means that the systems engineering team must be able to understand and work with a wide range of stakeholders. The transdisciplinary and integrative nature of systems engineering across other disciplines and activities, again, means that the systems engineering team needs to understand and work well with all the disciplines and specialities involved in realising a system (ref. 6).

Given this diversity of context and of types of systems engineered, and the wide range of stakeholders with whom they need to work, systems engineering workforce and culture should be at the forefront of DEI. In this way, we can represent as many aspects of the diverse community and their needs as possible within the team, and the diverse nature of the team also creates the innovation from which we can realise the best solutions.

Like most of engineering, systems engineering was historically not practiced by a diverse group of people. Therefore, it is necessary to apply the notions of equity (as defined) in order to ensure that the widest range of people are enabled and empowered to become and develop as systems engineers.

Inclusion (as defined) is about ensuring that the whole (diverse) team is engaged, supported and feels safe and able to give of their best to the team’s activity. An inclusive team will produce increased productivity and better-quality outcomes than the alternative. It also provides increased potential for inclusive products because of the greater range of stakeholder views within the team.

Inclusive Engineering

Inclusive Engineering (ref. 7) is the discipline of ensuring that engineering products and services are accessible to and inclusive of all users and are as free as possible from discrimination and bias. This should consider as far as possible all human differences (characteristics of diversity). It is a way of ensuring that engineering is appropriate, ethical, accessible, and as risk free as possible. The extent to which an engineered system is inclusive reduces the degree to which adaptation has to be applied to address the needs of people with differences e.g., differing vision, differing strength or motor functions.

In their enthusiasm for solutions engineers often do not stop to think about whether they have considered all of the things that impact on their design – and in particular all of the non-technical requirements that are not specified by the client or potential beneficiary. As a result, proposed solutions often lack the perspectives of people who have not been involved in their development – and in an industry which is notoriously lacking in diversity – this often means that they fail to include the perspectives of women, people with disabilities, the ageing population, and those with other under-represented characteristics.

Figure 3 shows an inclusive engineering framework (ref. 8) which has eight elements, all of which are important factors for systems engineers to address even if the stated requirements do not cover them.

Figure 3 Inclusive Engineering Framework

One way that systems engineers can maximise the potential for inclusive and sustainable solutions is to ensure that DEI considerations are through application of the ISO/IEC/IEEE 15288:2015 Technical Processes. Table 1 illustrates the application of Inclusive Engineering these processes.

Table 1. Mapping of the application of ISO/IEC/IEEE 15288:2015 Technical Processes to Inclusive Engineering considerations.

ISO/IEC/IEEE 15288:2015 Technical Process Inclusive Engineering considerations
Business or Mission Analysis ·       Ensure all stakeholders are identified, both the obvious (beneficial) stakeholders, and those potentially affected by the system and the associated project (referred to as “unwilling” stakeholders).
Stakeholder Needs and Requirements Definition ·       Identify stated stakeholder needs and the unstated but necessary needs arising from inclusive design – e.g. access, language, disability.

·       Use understanding of Sustainable Development Goals, circular economies etc. to inform future-looking discussions about needs.

System Requirements Definition ·       Ensure that inclusion considerations result in well-specified requirements drawing on standards and legislation as necessary.

·       Ensure that definition of the System Boundary is informed by its intended and unintended emergent effects on its wider context.

·       Facilitate careful trade-off and option analysis to optimise equitable outcomes.

Architecture Definition ·       Ensure that all necessary Architecture viewpoints are considered to ensure that inclusion and sustainability factors can be given due consideration.

·       Ensure that Architectures are open to allow future technology adoption where beneficial during the system lifecycle.

Design Definition ·       Ensure that technology choices and principles for design evolution are informed by Sustainable Development Goals, circular economies etc.
System Analysis ·       Ensure that System Analysis includes the modelling and prediction of inclusive engineering and sustainable development factors, in particular modelling to understand key emergent outcomes.
Implementation ·       Ensure that the design team is diverse, properly trained, and understands the principles of diversity, equity, inclusion, sustainability, circular economy, etc.
Integration ·       Ensure that the integration process is safe, secure, and environmentally compliant.
Verification ·       Ensure that planned verification activities fully address all aspects of diversity, equity, and inclusion for all relevant stakeholders and are safe, secure, and environmentally compliant.
Transition ·       Ensure that transition plans fully cover all stakeholders and are safe, secure, and environmentally compliant, and that any temporary/transitional arrangements do not have accidental negative effects on unwilling stakeholders or the natural environment i.e., there is an equitable transition plan.
Validation ·       Ensure that that planned validation activities fully address all aspects of diversity, equity, and inclusion for all relevant stakeholders including indirect/unwilling stakeholders and the natural environment and are safe, secure, and environmentally compliant.
Operations ·       Ensure that selection and training for operations staff is sufficient that a diverse group of operators can correctly operate all aspects of the system such that the system remains safe, secure, and environmentally compliant.
Maintenance ·       Ensure that selection and training for maintenance staff is sufficient that a diverse group of maintainers can correctly operate all aspects of the system such that the system remains safe, secure, and environmentally compliant.

·       Ensure that planned maintenance ensures that the system fully meets its initial specification throughout its service life e.g., energy use, emissions, pollution.

Disposal ·       Ensure that selection and training for disposal staff is sufficient that a diverse group of staff can correctly dispose of hazardous materials such that the system remains safe, secure, and environmentally compliant.

·       Ensure that disposal of hazardous materials is carefully planned, and that recycling and reuse opportunities are maximised.

References

Works Cited

ABET. 2020. "Diversity, Equity, and Inclusion." Accrediting Board for Engineering and Technology (ABET) website. https://www.abet.org/about-abet/diversity-equity-and-inclusion/ Accessed 31 Dec 2020.

Harding, A. and A. Pickard. "Towards a more Diverse INCOSE." INCOSE INSIGHT Practitioner Magazine. 22(3). Oct 2019.

Royal Academy of Engineering. 2015. “Increasing Diversity and Inclusion in Engineering–A Case Study Toolkit.” Case study, Royal Academy of Engineering. https://www.raeng.org.uk/policy/diversity-in-engineering/diversity-inclusion-toolkit-re-sources/documents/increasing-diversity-and-inclusion-in-engi-neering.

Hunt, V., S. Prince, S. Dixon­Fyle, and L. Yee. 2018. “Delivering Through Diversity.” Report, Mckinsey & Company. https://www.mckinsey.com/~/media/McKinsey/Business%20Functions/Organization/Our%20Insights/Delivering%20through%20diversity/Delivering-through-diversity_full-report.ashx

National Academy of Engineering. 2002. "Diversity in En­gineering: Managing the Workforce of the Future." Wash­ington, DC: The National Academies Press. https://doi.org/10.17226/10377

INCOSE. 2020. "Definition of systems engineering." https://www.incose.org/about-systems-engineering/about-systems-engineering Accessed 31 Dec 2020.

Inclusive Engineering downloaded 31 Dec 2020 http://www.inceng.org/

Inclusive Engineering framework downloaded 31 Dec 2020 http://www.inceng.org/inclusive-engineering-framework.html

Primary References

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Additional References

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