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In the 1950s, Europe, Japan, and the United States began to move towards "barrier-free design," which sought to remove obstacles in built environments for people with physical disabilities. By the 1970s, the emergence of [[Accessibility|accessible design]] began to move past the idea of building solutions specifically for individuals with disabilities towards normalization and integration. In 1973, the United States passed the [[Rehabilitation Act of 1973|Rehabilitation Act]], which prohibits discrimination on the basis of disability in programs conducted by federal agencies, a crucial step towards recognizing that accessible design was a condition for supporting people's civil rights.<ref name=":02">{{Cite web|title=History {{!}} Institute for Human Centered Design|url=https://www.humancentereddesign.org/inclusive-design/history|access-date=2022-01-27|website=www.humancentereddesign.org}}</ref> In May 1974, the magazine ''Industrial Design'' published an article, "The Handicapped Majority," which argued that handicaps were not a niche concern and 'normal' users suffered from poor design of products and environments as well.<ref name=":6">{{Cite book|last=Williamson|first=Bess|url=https://books.google.com/books?id=iT58DwAAQBAJ|title=Accessible America: A History of Disability and Design|date=2019-01-15|publisher=NYU Press|isbn=978-1-4798-9409-3|language=en}}</ref>
In the 1950s, Europe, Japan, and the United States began to move towards "barrier-free design," which sought to remove obstacles in built environments for people with physical disabilities. By the 1970s, the emergence of [[Accessibility|accessible design]] began to move past the idea of building solutions specifically for individuals with disabilities towards normalization and integration. In 1973, the United States passed the [[Rehabilitation Act of 1973|Rehabilitation Act]], which prohibits discrimination on the basis of disability in programs conducted by federal agencies, a crucial step towards recognizing that accessible design was a condition for supporting people's civil rights.<ref name=":02">{{Cite web|title=History {{!}} Institute for Human Centered Design|url=https://www.humancentereddesign.org/inclusive-design/history|access-date=2022-01-27|website=www.humancentereddesign.org}}</ref> In May 1974, the magazine ''Industrial Design'' published an article, "The Handicapped Majority," which argued that handicaps were not a niche concern and 'normal' users suffered from poor design of products and environments as well.<ref name=":6">{{Cite book|last=Williamson|first=Bess|url=https://books.google.com/books?id=iT58DwAAQBAJ|title=Accessible America: A History of Disability and Design|date=2019-01-15|publisher=NYU Press|isbn=978-1-4798-9409-3|language=en}}</ref>


Clarkson and Coleman describe the emergence of inclusive design in the United Kingdom as a synthesis of existing projects and movement.<ref name=":5">{{Cite journal|last1=John Clarkson|first1=P.|last2=Coleman|first2=Roger|date=2015-01-01|title=History of Inclusive Design in the UK|url=https://www.sciencedirect.com/science/article/pii/S0003687013000410|journal=Applied Ergonomics|series=Special Issue: Inclusive Design|language=en|volume=46|pages=235–247|doi=10.1016/j.apergo.2013.03.002|pmid=23570838|issn=0003-6870}}</ref> Coleman also published the first reference to the term in 1994 with ''The Case for Inclusive Design'', a presentation at the 12th Triennial Congress of the [[International Ergonomics Association]].<ref>{{Cite book|url=https://www.worldcat.org/title/proceedings-of-the-12th-triennial-congress-of-the-international-ergonomics-association-toronto-canada-august-15-19-1994-comptes-rendus-du-12e-congres-triennal-de-lassociation-internationale-dergonomie-du-15-au-19-aout-1994/oclc/35932553|title=Proceedings of the 12th Triennial Congress of the International Ergonomics Association: Toronto, Canada, August 15-19, 1994 = Comptes rendus du 12e Congrès triennal de l'Association internationale d'ergonomie : du 15 au 19 août 1994 .|date=1994|publisher=Human Factors Association of Canada = Association canadienne d'ergonomie|isbn=978-0-9698544-0-1|editor-last=International Ergonomics Association|location=Mississauga, Ont., Canada.|oclc=35932553|editor-last2=Congress}}</ref> Much of this early work was inspired by an aging population and people living for longer times in older ages as voiced by scholars like [[Peter Laslett]].<ref name=":5" /> Public focus on accessibility further increased with the passage of the passage of the [[Americans with Disabilities Act of 1990]], which expanded the responsibility of accessible design to include both public and private entities.<ref>{{Cite web|title=What is the difference between accessible, usable, and universal design? {{!}} DO-IT|url=https://www.washington.edu/doit/what-difference-between-accessible-usable-and-universal-design|access-date=2022-02-13|website=www.washington.edu}}</ref>
Clarkson and Coleman describe the emergence of inclusive design in the United Kingdom as a synthesis of existing projects and movement.<ref name=":5">{{Cite journal|last1=John Clarkson|first1=P.|last2=Coleman|first2=Roger|date=2015-01-01|title=History of Inclusive Design in the UK|url=https://www.sciencedirect.com/science/article/pii/S0003687013000410|journal=Applied Ergonomics|series=Special Issue: Inclusive Design|language=en|volume=46|pages=235–247|doi=10.1016/j.apergo.2013.03.002|pmid=23570838|issn=0003-6870}}</ref> Coleman also published the first reference to the term in 1994 with ''The Case for Inclusive Design'', a presentation at the 12th Triennial Congress of the [[International Ergonomics Association]].<ref>{{Cite book|url=https://www.worldcat.org/oclc/35932553|title=Proceedings of the 12th Triennial Congress of the International Ergonomics Association: Toronto, Canada, August 15-19, 1994 = Comptes rendus du 12e Congrès triennal de l'Association internationale d'ergonomie : du 15 au 19 août 1994 .|date=1994|publisher=Human Factors Association of Canada = Association canadienne d'ergonomie|isbn=978-0-9698544-0-1|editor-last=International Ergonomics Association|location=Mississauga, Ont., Canada.|oclc=35932553|editor-last2=Congress}}</ref> Much of this early work was inspired by an aging population and people living for longer times in older ages as voiced by scholars like [[Peter Laslett]].<ref name=":5" /> Public focus on accessibility further increased with the passage of the passage of the [[Americans with Disabilities Act of 1990]], which expanded the responsibility of accessible design to include both public and private entities.<ref>{{Cite web|title=What is the difference between accessible, usable, and universal design? {{!}} DO-IT|url=https://www.washington.edu/doit/what-difference-between-accessible-usable-and-universal-design|access-date=2022-02-13|website=www.washington.edu}}</ref>


In the 1990s, the United States followed the United Kingdom in shifting focus from universal design to inclusive design.<ref name=":02" /> Around this time, Selwyn Goldsmith (in the UK) and Ronald 'Ron' Mace (in the US), two architects who had both survived polio and were wheelchair users, advocated for an expanded view of design for everyone. Along with Mace, nine other authors from five organizations in the United States developed the Principles of Universal Design in 1997.<ref name=":02" /> In 1998, the United States amended Section 508 of the Rehabilitation Act to include inclusivity requirements for the design of information and technology.
In the 1990s, the United States followed the United Kingdom in shifting focus from universal design to inclusive design.<ref name=":02" /> Around this time, Selwyn Goldsmith (in the UK) and Ronald 'Ron' Mace (in the US), two architects who had both survived polio and were wheelchair users, advocated for an expanded view of design for everyone. Along with Mace, nine other authors from five organizations in the United States developed the Principles of Universal Design in 1997.<ref name=":02" /> In 1998, the United States amended Section 508 of the Rehabilitation Act to include inclusivity requirements for the design of information and technology.
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[[Universal design]] is design for everyone: the term was coined by Ronald Mace in 1980, and its aim is to produce designs that all people can use fully, without the need for adaptations. Universal design originated in work on the design of built environments, though its focus has expanded to encompass digital products and services as well.<ref name=":2" />
[[Universal design]] is design for everyone: the term was coined by Ronald Mace in 1980, and its aim is to produce designs that all people can use fully, without the need for adaptations. Universal design originated in work on the design of built environments, though its focus has expanded to encompass digital products and services as well.<ref name=":2" />


Universal design principles include usefulness to people with diverse abilities; intuitive use regardless of user's skill level; perceptible communication of necessary information; tolerance for error; low physical effort; and appropriate size and space for all users.<ref>{{Cite web|last=Zheng|first=Ruby|title=Learn to Create Accessible Websites with the Principles of Universal Design|url=https://www.interaction-design.org/literature/article/learn-to-create-accessible-websites-with-the-principles-of-universal-design|access-date=2022-01-27|website=The Interaction Design Foundation|language=en}}</ref> Many of these principles are compatible with accessible and inclusive design, but universal design typically provides a single solution for a large user base, without added accommodations.<ref name=":3" /> Therefore, while universal design supports the widest range of users, it does not aim to address individual accessibility needs. Inclusive design acknowledges that it is not always possible for one product to meet every user's needs, and thus explores different solutions for different groups of people.
Universal design principles include usefulness to people with diverse abilities; intuitive use regardless of user's skill level; perceptible communication of necessary information; tolerance for error; low physical effort; and appropriate size and space for all users.<ref>{{Cite web|last=Zheng|first=Ruby|title=Learn to Create Accessible Websites with the Principles of Universal Design|url=https://www.interaction-design.org/literature/article/learn-to-create-accessible-websites-with-the-principles-of-universal-design|access-date=2022-01-27|website=The Interaction Design Foundation|date=21 May 2021 |language=en}}</ref> Many of these principles are compatible with accessible and inclusive design, but universal design typically provides a single solution for a large user base, without added accommodations.<ref name=":3" /> Therefore, while universal design supports the widest range of users, it does not aim to address individual accessibility needs. Inclusive design acknowledges that it is not always possible for one product to meet every user's needs, and thus explores different solutions for different groups of people.


== Approaches to inclusive design ==
== Approaches to inclusive design ==
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# Offer various ways to engage: When a user is given different options, they can choose a method that serves them best.
# Offer various ways to engage: When a user is given different options, they can choose a method that serves them best.
# Provide equivalent experiences to all users: When designing different ways for people to engage with your product, ensure that the quality of these experiences is comparable for each user.
# Provide equivalent experiences to all users: When designing different ways for people to engage with your product, ensure that the quality of these experiences is comparable for each user.



For [[Google]], the inclusive design process is slightly different and is called product inclusion, and looks at 13 dimensions of identity and the intersections of those dimensions throughout the product development and design process.https://about.google/belonging/in-products/


=== Participatory design ===
=== Participatory design ===
Participatory design is rooted in the design of Scandinavian workplaces in the 1970s, and is based in the idea that those affected by a design should be consulted during the design process.<ref name=":7">{{Cite journal|last1=Björgvinsson|first1=Erling|last2=Bjögvinsson|first2=Erling|last3=Ehn|first3=Pelle|last4=Hillgren|first4=Per-Anders|date=2012|title=Design Things and Design Thinking: Contemporary Participatory Design Challenges|url=https://www.jstor.org/stable/23273842|journal=Design Issues|volume=28|issue=3|pages=101–116|doi=10.1162/DESI_a_00165|jstor=23273842|hdl=2043/14805|s2cid=54666697|issn=0747-9360}}</ref> Designers anticipate how users will actually use a product—and rather than focusing on merely designing a useful product, the whole infrastructure is considered: the goal is to design a good environment for the product at use time.<ref name=":7" /> This methodology treats the challenge of design as an ongoing process. Further, rather than viewing the design process in phases, such as analysis, design, construction, and implementation, the participatory design approach looks at projects in terms of a collection of users and their experiences.
Participatory design is rooted in the design of Scandinavian workplaces in the 1970s, and is based in the idea that those affected by a design should be consulted during the design process.<ref name=":7">{{Cite journal|last1=Björgvinsson|first1=Erling|last2=Bjögvinsson|first2=Erling|last3=Ehn|first3=Pelle|last4=Hillgren|first4=Per-Anders|date=2012|title=Design Things and Design Thinking: Contemporary Participatory Design Challenges|url=https://www.jstor.org/stable/23273842|journal=Design Issues|volume=28|issue=3|pages=101–116|doi=10.1162/DESI_a_00165|jstor=23273842|hdl=2043/14805|s2cid=54666697|issn=0747-9360|hdl-access=free}}</ref> Designers anticipate how users will actually use a product—and rather than focusing on merely designing a useful product, the whole infrastructure is considered: the goal is to design a good environment for the product at use time.<ref name=":7" /> This methodology treats the challenge of design as an ongoing process. Further, rather than viewing the design process in phases, such as analysis, design, construction, and implementation, the participatory design approach looks at projects in terms of a collection of users and their experiences.


== Examples of inclusive design ==
== Examples of inclusive design ==
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=== Interfaces and technology ===
=== Interfaces and technology ===


* <u>Text legibility for older users:</u> To ensure legibility of text for users of all ages, designers must use "reasonably large font sizes, have high contrast between characters in the foreground and background, and use a clean typeface."<ref name=":42">{{Cite web|last=Joyce|first=Alita|title=Inclusive Design|url=https://www.nngroup.com/articles/inclusive-design/|access-date=2022-02-13|website=Nielsen Norman Group|language=en|date=2022-01-30}}</ref> This is an example of an inclusive design pattern in that these design elements are beneficial to all users of an interface, but they are implemented to address the needs of senior users in particular. Other inclusive design solutions include adding buttons that allow users to adjust the font size of a website to their liking, or giving users the option to switch to a "dark mode" that is easier on the eyes for some users.
* Text legibility for older users: To ensure legibility of text for users of all ages, designers must use "reasonably large font sizes, have high contrast between characters in the foreground and background, and use a clean typeface."<ref name=":42">{{Cite web|last=Joyce|first=Alita|title=Inclusive Design|url=https://www.nngroup.com/articles/inclusive-design/|access-date=2022-02-13|website=Nielsen Norman Group|language=en|date=2022-01-30}}</ref> This is an example of an inclusive design pattern in that these design elements are beneficial to all users of an interface, but they are implemented to address the needs of senior users in particular. Other inclusive design solutions include adding buttons that allow users to adjust the font size of a website to their liking, or giving users the option to switch to a "dark mode" that is easier on the eyes for some users.
* <u>Assistive clothing:</u> Individuals who are physically disabled often have trouble putting on clothing, and the fashion industry does not focus too much on designing clothing for the physically disabled. Therefore, two textile engineering programs located in Brazil and Portugal decided to create technology implanted in clothing that would help assist people who are physically disabled. The programs created trousers with an infrared irradiator, which provides better blood circulation. In addition, they produced a jacket "with a Wi-Fi microcontroller inside to detect falls of users with poor mobility in the upper and lower limbs."<ref>{{Citation|last1=Aguiar|first1=Grazyella C. O.|title=Fashion and Inclusive Design: Assistive Technologies Applied to Clothing|date=2020|url=http://dx.doi.org/10.1007/978-3-030-51194-4_5|work=Advances in Industrial Design|pages=32–37|place=Cham|publisher=Springer International Publishing|isbn=978-3-030-51193-7|access-date=2022-02-13|last2=Rincon|first2=Leonardo M.|last3=Carvalho|first3=Miguel A. F.|last4=Mailer|first4=Christian|last5=Breier|first5=Fabieli D.|last6=Ferreira|first6=Fernando B.|doi=10.1007/978-3-030-51194-4_5|s2cid=225611538}}</ref>
* Assistive clothing: Individuals with physical disabilities may experience barriers with dressing or undressing due to commonly inaccessible clothing garments and products. In recent years, inclusive design practices have been implemented in the fashion industry by leading brands including Kohl’s, Nike, Target, Tommy Hilfiger, and Zappos. <ref>{{Cite journal |last1=McBee-Black |first1=Kerri |last2=Ha-Brookshire |first2=Jung |date=July 2020 |title=Words Matter: A Content Analysis of the Definitions and Usage of the Terms for Apparel Marketed to People Living With Disabilities |url=http://journals.sagepub.com/doi/10.1177/0887302X19890416 |journal=Clothing and Textiles Research Journal |language=en |volume=38 |issue=3 |pages=166–181 |doi=10.1177/0887302X19890416 |issn=0887-302X}}</ref> Such adaptive clothing products can take the form of magnets or velcro on the side of pants, zippers on the sleeves of tops to become detachable, and natural fibers to ensure breathability, temperature control, and overall comfort. <ref>{{Cite thesis |last=Rutledge |first=Brittany |title=Autoethnograhic Study in the Process of Applied Design: Creating Adaptive Clothing for a Child with Spinal Muscular Atrophy |date=2017 |url=https://scholarworks.gsu.edu/art_design_theses/212 |doi=10.57709/10025817 |degree=MAEd |publisher=Georgia State University}}</ref> A connection between assistive clothing and technology can be seen within the work of two textile engineering programs located in Brazil and Portugal that implanted technology in clothing with the purpose of increasing accessible dressing to people with physical disabilities. The programs created trousers with an infrared irradiator, which provides better blood circulation, along with the production of a jacket "with a Wi-Fi microcontroller inside to detect falls of users with poor mobility in the upper and lower limbs."<ref>{{Citation|last1=Aguiar|first1=Grazyella C. O.|title=Fashion and Inclusive Design: Assistive Technologies Applied to Clothing|date=2020|url=http://dx.doi.org/10.1007/978-3-030-51194-4_5|work=Advances in Industrial Design|pages=32–37|place=Cham|publisher=Springer International Publishing|isbn=978-3-030-51193-7|access-date=2022-02-13|last2=Rincon|first2=Leonardo M.|last3=Carvalho|first3=Miguel A. F.|last4=Mailer|first4=Christian|last5=Breier|first5=Fabieli D.|last6=Ferreira|first6=Fernando B.|series=Advances in Intelligent Systems and Computing |volume=1202 |doi=10.1007/978-3-030-51194-4_5|s2cid=225611538|hdl=1822/90625|hdl-access=free}}</ref>



=== Consumer products ===
=== Consumer products ===


* <u>OXO Vegetable Peeler:</u> The traditional metal vegetable peeler has an unusual handle and is generally ineffective when peeling vegetables, which is frustrating for users, especially individuals with physical disabilities such as [[arthritis]]. A man named Sam Farber created a company named OXO and developed a new vegetable peeler that was more comfortable to hold and easier to use. Although this development may seem unimportant to most, it inspired other companies to come up with better designs that made the vegetable peeler even easier to use.<ref>{{Cite book|last=Norman|first=Don|title=The Design of Everyday Things|publisher=Basic Books|year=2013|isbn=978-0-465-05065-9|location=New York|pages=244–245|language=English}}</ref>
* OXO Vegetable Peeler: The traditional metal vegetable peeler has an unusual handle and is generally ineffective when peeling vegetables, which is frustrating for users, especially individuals with physical disabilities such as [[arthritis]]. A man named Sam Farber created a company named OXO and developed a new vegetable peeler that was more comfortable to hold and easier to use. Although this development may seem unimportant to most, it inspired other companies to come up with better designs that made the vegetable peeler even easier to use.<ref>{{Cite book|last=Norman|first=Don|title=The Design of Everyday Things|publisher=Basic Books|year=2013|isbn=978-0-465-05065-9|location=New York|pages=244–245|language=English}}</ref>
* <u>The ROPP Closure:</u> Because most elderly and disabled people do not have the necessary strength to open packaging, a project was conducted that centered on modifying the packaging for plastic and glass containers. The roll-on pilfer-proof (ROPP) closure, a design used to seal spirit bottles, was used as a model in the project to determine the capable strength of consumers and the physical strength required to open the glass and plastic containers while also keeping the container properly sealed. If the strength limits of consumers and the design limits of the ROPP closure are solved, the majority of the public will be able to open a container, and the containers will be fully closed.<ref>{{Cite journal|last1=Langley|first1=J.|last2=Janson|first2=R.|last3=Wearn|first3=J.|last4=Yoxall|first4=A.|date=2005|title='Inclusive' design for containers: improving openability|url=http://dx.doi.org/10.1002/pts.699|journal=Packaging Technology and Science|volume=18|issue=6|pages=285–293|doi=10.1002/pts.699|s2cid=109131296 |issn=0894-3214}}</ref>
* The ROPP Closure: Because most elderly and disabled people do not have the necessary strength to open packaging, a project was conducted that centered on modifying the packaging for plastic and glass containers. The roll-on pilfer-proof (ROPP) closure, a design used to seal spirit bottles, was used as a model in the project to determine the capable strength of consumers and the physical strength required to open the glass and plastic containers while also keeping the container properly sealed. If the strength limits of consumers and the design limits of the ROPP closure are solved, the majority of the public will be able to open a container, and the containers will be fully closed.<ref>{{Cite journal|last1=Langley|first1=J.|last2=Janson|first2=R.|last3=Wearn|first3=J.|last4=Yoxall|first4=A.|date=2005|title='Inclusive' design for containers: improving openability|url=http://dx.doi.org/10.1002/pts.699|journal=Packaging Technology and Science|volume=18|issue=6|pages=285–293|doi=10.1002/pts.699|s2cid=109131296 |issn=0894-3214}}</ref>
* <u>Oneware kitchen tool:</u> A student named Loren Lin designed a special kitchen tool called Oneware for people who have one arm or other hand/arm disabilities. This tool consists of a "a chopping board to facilitate cutting and a silicone net for more efficient dishwashing."<ref>{{Cite web|title=One inclusive design|url=https://news.nus.edu.sg/one-inclusive-design/|access-date=2022-02-17|website=One inclusive design|language=en-sg}}</ref> Disabled individuals have a difficult time preparing meals because regular kitchen tools are designed for people who have two functioning arms. Lin was aware of this issue, so he created a cutting board that made it easier for disabled people to make meals.
* Oneware kitchen tool: A student named Loren Lin designed a special kitchen tool called Oneware for people who have one arm or other hand/arm disabilities. This tool consists of a "a chopping board to facilitate cutting and a silicone net for more efficient dishwashing."<ref>{{Cite web|title=One inclusive design|url=https://news.nus.edu.sg/one-inclusive-design/|access-date=2022-02-17|website=One inclusive design|language=en-sg}}</ref> Disabled individuals have a difficult time preparing meals because regular kitchen tools are designed for people who have two functioning arms. Lin was aware of this issue, so he created a cutting board that made it easier for disabled people to make meals.


=== Infrastructure ===
=== Infrastructure ===


* <u>Playgrounds/parks in urban areas:</u> Children are often excluded from accessible public places in cities due to safety concerns, so spatial planners design playgrounds and parks within cities in order to give children the opportunity to freely examine their curiosities. These areas are significant for a child's growth because children can socialize with each other, explore their surroundings, and stay physically active without worrying about any common dangers that can occur in an urban environment.<ref>{{Citation|last1=Ramioul|first1=C.|title=Exploring with Children What Makes a City Child-Friendly|date=2020|url=http://dx.doi.org/10.1007/978-3-030-43865-4_10|work=Designing for Inclusion|pages=99–106|place=Cham|publisher=Springer International Publishing|isbn=978-3-030-43864-7|access-date=2022-02-04|last2=Tutenel|first2=P.|last3=Heylighen|first3=A.|doi=10.1007/978-3-030-43865-4_10|s2cid=218813927}}</ref>
* Playgrounds/parks in urban areas: Children are often excluded from accessible public places in cities due to safety concerns, so spatial planners design playgrounds and parks within cities in order to give children the opportunity to freely examine their curiosities. These areas are significant for a child's growth because children can socialize with each other, explore their surroundings, and stay physically active without worrying about any common dangers that can occur in an urban environment.<ref>{{Citation|last1=Ramioul|first1=C.|title=Exploring with Children What Makes a City Child-Friendly|date=2020|url=http://dx.doi.org/10.1007/978-3-030-43865-4_10|work=Designing for Inclusion|pages=99–106|place=Cham|publisher=Springer International Publishing|isbn=978-3-030-43864-7|access-date=2022-02-04|last2=Tutenel|first2=P.|last3=Heylighen|first3=A.|doi=10.1007/978-3-030-43865-4_10|s2cid=218813927}}</ref>
* <u>Musholm:</u> The majority of fitness centers do not have sufficient accessibility provisions for disabled people; this inactivity can exacerbate the effects of illness.<ref>{{Cite journal|last1=Nikolajsen|first1=Helene|last2=Richardson|first2=Emma Victoria|last3=Sandal|first3=Louise Fleng|last4=Juul-Kristensen|first4=Birgit|last5=Troelsen|first5=Jens|date=2021-07-30|title=Fitness for all: how do non-disabled people respond to inclusive fitness centres?|journal=BMC Sports Science, Medicine and Rehabilitation|volume=13|issue=1|pages=81|doi=10.1186/s13102-021-00303-2|issn=2052-1847|pmc=8325230|pmid=34330328}}</ref> Musholm is a sports center located in Denmark where everyone can participate in various physical activities. It contains a 110 meter-long activity ramp with landings and recreational zones, where wheelchair users can engage in activities such as a climbing wall and even a cable lift.<ref name=":8">{{Cite web|title=Musholm|url=https://aart.dk/en/projects/musholm|access-date=2022-02-04|website=English|language=en-US}}</ref> The initial objective for the designers of this building was making sure that the facilities were accessible to everyone, and because of their commitment, Musholm was voted the world's most socially inclusive building.<ref name=":8" /> Although it is challenging for architects to construct inclusive infrastructure, the structure of Musholm proves that it is possible.
* Musholm: The majority of fitness centers do not have sufficient accessibility provisions for disabled people; this inactivity can exacerbate the effects of illness.<ref>{{Cite journal|last1=Nikolajsen|first1=Helene|last2=Richardson|first2=Emma Victoria|last3=Sandal|first3=Louise Fleng|last4=Juul-Kristensen|first4=Birgit|last5=Troelsen|first5=Jens|date=2021-07-30|title=Fitness for all: how do non-disabled people respond to inclusive fitness centres?|journal=BMC Sports Science, Medicine and Rehabilitation|volume=13|issue=1|pages=81|doi=10.1186/s13102-021-00303-2|issn=2052-1847|pmc=8325230|pmid=34330328 |doi-access=free }}</ref> Musholm is a sports center located in Denmark where everyone can participate in various physical activities. It contains a 110 meter-long activity ramp with landings and recreational zones, where wheelchair users can engage in activities such as a climbing wall and even a cable lift.<ref name=":8">{{Cite web|title=Musholm|url=https://aart.dk/en/projects/musholm|access-date=2022-02-04|website=English|language=en-US}}</ref> The initial objective for the designers of this building was making sure that the facilities were accessible to everyone, and because of their commitment, Musholm was voted the world's most socially inclusive building.<ref name=":8" /> Although it is challenging for architects to construct inclusive infrastructure, the structure of Musholm proves that it is possible.
* <u>The Friendship Park:</u> Located in Uruguay, this park was built so that it can be easily accessible for every child, especially children with disabilities. The park has swings available for children in wheelchairs, wide walkways, curved corners instead of sharp edges, and flooring that is cushioned and slip resistant. These unique features were added in order "to not only make the space safe, but to also make the space easy to use."<ref>{{Cite journal|title=2016 Project Elijah Final Report PDF|doi=10.17307/wsc.v1i1.183.s6|doi-access=free}}</ref>
* The Friendship Park: Located in Uruguay, this park was built so that it can be easily accessible for every child, especially children with disabilities. The park has swings available for children in wheelchairs, wide walkways, curved corners instead of sharp edges, and flooring that is cushioned and slip resistant. These unique features were added in order "to not only make the space safe, but to also make the space easy to use."<ref>{{Cite conference |last1=Furey |first1=Joshua |last2=Maraccini |first2=Jared |last3=Phakousonh |first3=Cheyenne |last4=Rasmussen |first4=Justin |last5=Schotte |first5=Jonathan |title=2016 Project Elijah Final Report PDF |conference=Proceedings of the Wisconsin Space Conference |volume=1 |issue=1 |doi=10.17307/wsc.v1i1.183.s6 |doi-access=free}}</ref>
* <u>Tactile Pavement in Urban Area:</u> Visually impaired individuals often feel excluded from the community because they have hard time navigating their surroundings. Implementing tactile pavement around the community assists them in locating their route and directions to minimize time used on the road. These pavements have different but identifiable textures allowing them to understand what is ahead and alert them to possible danger. Some indicators includes blister paving patterns, where it locates around crosswalks to indicate road crossing ahead, cycleway tactile paving that help alert people of cyclist path, where the pavements has lined tile along the path for the cyclist and most importantly the directional tactile paving that help indicate the direction of the sidewalks when there are no other indicators on the street.<ref>“Blindness and Vision Loss: Chapter 2: Travel by Pedestrians Who Are Blind or Who Have Low Vision.” Accessible Pedestrian Signals: Blindness and Vision Loss, National Cooperative Highway Research Program, www.apsguide.org/chapter2_blindness.cfm.</ref>
* Tactile Pavement in Urban Area: Visually impaired individuals often feel excluded from the community because they have hard time navigating their surroundings. Implementing tactile pavement around the community assists them in locating their route and directions to minimize time used on the road. These pavements have different but identifiable textures allowing them to understand what is ahead and alert them to possible danger. Some indicators includes blister paving patterns, where it locates around crosswalks to indicate road crossing ahead, cycleway tactile paving that help alert people of cyclist path, where the pavements has lined tile along the path for the cyclist and most importantly the directional tactile paving that help indicate the direction of the sidewalks when there are no other indicators on the street.<ref>“Blindness and Vision Loss: Chapter 2: Travel by Pedestrians Who Are Blind or Who Have Low Vision.” Accessible Pedestrian Signals: Blindness and Vision Loss, National Cooperative Highway Research Program, www.apsguide.org/chapter2_blindness.cfm.</ref>


== See also ==
== See also ==
Line 111: Line 116:
* [[Empathic design]]
* [[Empathic design]]
* [[Human-centered design]]
* [[Human-centered design]]

== References ==
== References ==
{{reflist}}
{{reflist}}

Latest revision as of 01:25, 20 August 2024

Inclusive design is a design process in which a product, service, or environment is designed to be usable for as many people as possible, particularly groups who are traditionally excluded from being able to use an interface or navigate an environment. Its focus is on fulfilling as many user needs as possible, not just as many users as possible.[1] Historically, inclusive design has been linked to designing for people with physical disabilities, and accessibility is one of the key outcomes of inclusive design.[2] However, rather than focusing on designing for disabilities, inclusive design is a methodology that considers many aspects of human diversity that could affect a person's ability to use a product, service, or environment, such as ability, language, culture, gender, and age.[3] The Inclusive Design Research Center reframes disability as a mismatch between the needs of a user and the design of a product or system, emphasizing that disability can be experienced by any user.[4] With this framing, it becomes clear that inclusive design is not limited to interfaces or technologies, but may also be applied to the design of policies and infrastructure.

Three dimensions in inclusive design methodology identified by the Inclusive Design Research Centre include:[5]

  1. Recognize, respect, and design with human uniqueness and variability.
  2. Use inclusive, open, and transparent processes, and co-design with people who represent a diversity of perspectives.
  3. Realize that you are designing in a complex adaptive system, where changes in a design will influence the larger systems that utilize it.

Further iterations of inclusive design include product inclusion, a practice of bringing an inclusive lens throughout development and design. This term suggests looking at multiple dimensions of identity including race, age, gender and more.

History

[edit]

In the 1950s, Europe, Japan, and the United States began to move towards "barrier-free design," which sought to remove obstacles in built environments for people with physical disabilities. By the 1970s, the emergence of accessible design began to move past the idea of building solutions specifically for individuals with disabilities towards normalization and integration. In 1973, the United States passed the Rehabilitation Act, which prohibits discrimination on the basis of disability in programs conducted by federal agencies, a crucial step towards recognizing that accessible design was a condition for supporting people's civil rights.[6] In May 1974, the magazine Industrial Design published an article, "The Handicapped Majority," which argued that handicaps were not a niche concern and 'normal' users suffered from poor design of products and environments as well.[7]

Clarkson and Coleman describe the emergence of inclusive design in the United Kingdom as a synthesis of existing projects and movement.[8] Coleman also published the first reference to the term in 1994 with The Case for Inclusive Design, a presentation at the 12th Triennial Congress of the International Ergonomics Association.[9] Much of this early work was inspired by an aging population and people living for longer times in older ages as voiced by scholars like Peter Laslett.[8] Public focus on accessibility further increased with the passage of the passage of the Americans with Disabilities Act of 1990, which expanded the responsibility of accessible design to include both public and private entities.[10]

In the 1990s, the United States followed the United Kingdom in shifting focus from universal design to inclusive design.[6] Around this time, Selwyn Goldsmith (in the UK) and Ronald 'Ron' Mace (in the US), two architects who had both survived polio and were wheelchair users, advocated for an expanded view of design for everyone. Along with Mace, nine other authors from five organizations in the United States developed the Principles of Universal Design in 1997.[6] In 1998, the United States amended Section 508 of the Rehabilitation Act to include inclusivity requirements for the design of information and technology.

In 2016, the Design for All Showcase at the White House featured a panel on inclusive design.[11][7] The show featured clothing and personal devices either on the market or in development, modeled by disabled people.[12] Rather than treating accessible and inclusive design as a product of compliance to legal requirements, the showcase positioned disability as a source of innovation.

Differentiation from accessible and universal design

[edit]

Inclusive design is often equated to accessible or universal design, as all three concepts are related to ensuring that products are usable by all people. However, subtle distinctions make each approach noteworthy.

Accessibility

[edit]

Accessibility is oriented towards the outcome of ensuring that a product supports individual users' needs.[13] Accessible design is often based upon compliance with government- or industry-designated guidelines, such as Americans with Disabilities Act (ADA) Accessibility Standards or Web Content Accessibility Guidelines (WCAG). As a result, it is limited in scope and often focuses on specific accommodations to ensure that people with disabilities have access to products, services, or environments. In contrast, inclusive design considers the needs of a wider range of potential users, including those with capability impairments that may not be legally recognized as disabilities.[14] Inclusive design seeks out cases of exclusion from a product or environment, regardless of the cause, and seeks to reduce that exclusion. For example, a design that aims to reduce safety risks for people suffering from age-related long-sightedness would be best characterized as an inclusive design. Inclusive design also looks beyond resolving issues of access to improving the overall user experience.

As a result, accessibility is one piece of inclusive design, but not the whole picture. In general, designs created through an inclusive design process should be accessible, as the needs of people with different abilities are considered during the design process. But accessible designs aren't necessarily inclusive if they don't move beyond providing access to people of different abilities and consider the wider user experience for different types of people—particularly those who may not suffer from recognized, common cognitive, or physical disabilities.[15]

Universal design

[edit]

Universal design is design for everyone: the term was coined by Ronald Mace in 1980, and its aim is to produce designs that all people can use fully, without the need for adaptations. Universal design originated in work on the design of built environments, though its focus has expanded to encompass digital products and services as well.[13]

Universal design principles include usefulness to people with diverse abilities; intuitive use regardless of user's skill level; perceptible communication of necessary information; tolerance for error; low physical effort; and appropriate size and space for all users.[16] Many of these principles are compatible with accessible and inclusive design, but universal design typically provides a single solution for a large user base, without added accommodations.[15] Therefore, while universal design supports the widest range of users, it does not aim to address individual accessibility needs. Inclusive design acknowledges that it is not always possible for one product to meet every user's needs, and thus explores different solutions for different groups of people.

Approaches to inclusive design

[edit]

In general, inclusive design involves engaging with users and seeking to understand their needs. Frequently, inclusive design approaches include steps such as: developing empathy for the needs and contexts of potential users; forming diverse teams; creating and testing multiple solutions; encouraging dialogue regarding a design rather than debate; and using structured processes that guide conversations toward productive outcomes.[17]

Principles of Universal Design (1997)

[edit]

Five United States organizations—including the Institute for Human Centered Design (IHCD) and Ronald Mace at North Carolina State University—developed the Principles of Universal Design in 1997. The IHCD has since shifted the language of the principles from 'universal' to 'inclusive.'[2]

  1. Equitable Use: Any group of users can use the design.
  2. Flexibility in Use: A wide range of preferences and abilities is accommodated.
  3. Simple, Intuitive Use: Regardless of the user's prior experience or knowledge, the use of the design is easy to understand.
  4. Perceptible Information: Any necessary information is communicated to the user, regardless of environment or user abilities.
  5. Tolerance for Error: Any adverse or hazardous consequences of actions is minimized.
  6. Low Physical Effort: The design can be used efficiently and comfortably.
  7. Size and Space for Approach & Use: Regardless of the user's body size, posture, or mobility, there is appropriate size and space to approach and use the design.

UK Commission for Architecture and Built Environment (2006)

[edit]

The Commission for Architecture and the Built Environment (CABE) is an arm of the UK Design Council, which advises the government on architecture, urban design and public space. In 2006, they created the following set of inclusive design principles:

  1. Inclusive: Everyone can use it safely, easily, and with dignity.
  2. Responsive: Takes account of what people say they need and want.
  3. Flexible: Different people can use it differently.
  4. Convenient: Usable without too much effort.
  5. Accommodating: For all people, regardless of age, gender, mobility, ethnicity, or circumstances.
  6. Welcoming: No disabling barriers that might exclude some people.
  7. Realistic: More than one solution to address differing needs.
  8. Understandable: Everyone can locate and access it.

Inclusive Design Toolkit

[edit]

The University of Cambridge's Inclusive Design Toolkit[18] advocates incorporating inclusive design elements throughout the design process in iterative cycles of:

  1. Exploring the needs
  2. Creating solutions
  3. Evaluating how well the needs are met

Corporate inclusive design approaches

[edit]

Microsoft emphasizes the role of learning from people who represent different perspectives in their inclusive design approach. They advocate for the following steps:[19]

  1. Recognize exclusion: Open up products and services to more people.
  2. Solve for one, extend to many: Designing for people with disabilities tends to result in designs that benefit other user groups as well.
  3. Learn from diversity: Center people from the start of the design process, and develop insight from their perspectives.

For Adobe, the inclusive design process begins with identification of situations where people are excluded from using a product. They describe the following principles of inclusive design:[20]

  1. Identify ability-based exclusion: Proactively understand how and why people are excluded.
  2. Identify situational challenges: These are specific scenarios where a user is unable to use a product effectively, such as when an environmental circumstance makes it difficult to use a design. For example, if a video does not include closed-captioning, it may be difficult to understand the audio in a noisy environment.
  3. Avoid personal biases: Involve people from different communities throughout the design process.
  4. Offer various ways to engage: When a user is given different options, they can choose a method that serves them best.
  5. Provide equivalent experiences to all users: When designing different ways for people to engage with your product, ensure that the quality of these experiences is comparable for each user.


For Google, the inclusive design process is slightly different and is called product inclusion, and looks at 13 dimensions of identity and the intersections of those dimensions throughout the product development and design process.https://about.google/belonging/in-products/

Participatory design

[edit]

Participatory design is rooted in the design of Scandinavian workplaces in the 1970s, and is based in the idea that those affected by a design should be consulted during the design process.[21] Designers anticipate how users will actually use a product—and rather than focusing on merely designing a useful product, the whole infrastructure is considered: the goal is to design a good environment for the product at use time.[21] This methodology treats the challenge of design as an ongoing process. Further, rather than viewing the design process in phases, such as analysis, design, construction, and implementation, the participatory design approach looks at projects in terms of a collection of users and their experiences.

Examples of inclusive design

[edit]

There are numerous examples of inclusive design that apply to interfaces and technology, consumer products, and infrastructure.

Senior users may have cataracts or cloudy ocular media, vision issues that make it difficult to process interfaces in light mode.[22] Implementing a dark mode option can support the needs of these users.

Interfaces and technology

[edit]
  • Text legibility for older users: To ensure legibility of text for users of all ages, designers must use "reasonably large font sizes, have high contrast between characters in the foreground and background, and use a clean typeface."[23] This is an example of an inclusive design pattern in that these design elements are beneficial to all users of an interface, but they are implemented to address the needs of senior users in particular. Other inclusive design solutions include adding buttons that allow users to adjust the font size of a website to their liking, or giving users the option to switch to a "dark mode" that is easier on the eyes for some users.
  • Assistive clothing: Individuals with physical disabilities may experience barriers with dressing or undressing due to commonly inaccessible clothing garments and products. In recent years, inclusive design practices have been implemented in the fashion industry by leading brands including Kohl’s, Nike, Target, Tommy Hilfiger, and Zappos. [24] Such adaptive clothing products can take the form of magnets or velcro on the side of pants, zippers on the sleeves of tops to become detachable, and natural fibers to ensure breathability, temperature control, and overall comfort. [25] A connection between assistive clothing and technology can be seen within the work of two textile engineering programs located in Brazil and Portugal that implanted technology in clothing with the purpose of increasing accessible dressing to people with physical disabilities. The programs created trousers with an infrared irradiator, which provides better blood circulation, along with the production of a jacket "with a Wi-Fi microcontroller inside to detect falls of users with poor mobility in the upper and lower limbs."[26]


Consumer products

[edit]
  • OXO Vegetable Peeler: The traditional metal vegetable peeler has an unusual handle and is generally ineffective when peeling vegetables, which is frustrating for users, especially individuals with physical disabilities such as arthritis. A man named Sam Farber created a company named OXO and developed a new vegetable peeler that was more comfortable to hold and easier to use. Although this development may seem unimportant to most, it inspired other companies to come up with better designs that made the vegetable peeler even easier to use.[27]
  • The ROPP Closure: Because most elderly and disabled people do not have the necessary strength to open packaging, a project was conducted that centered on modifying the packaging for plastic and glass containers. The roll-on pilfer-proof (ROPP) closure, a design used to seal spirit bottles, was used as a model in the project to determine the capable strength of consumers and the physical strength required to open the glass and plastic containers while also keeping the container properly sealed. If the strength limits of consumers and the design limits of the ROPP closure are solved, the majority of the public will be able to open a container, and the containers will be fully closed.[28]
  • Oneware kitchen tool: A student named Loren Lin designed a special kitchen tool called Oneware for people who have one arm or other hand/arm disabilities. This tool consists of a "a chopping board to facilitate cutting and a silicone net for more efficient dishwashing."[29] Disabled individuals have a difficult time preparing meals because regular kitchen tools are designed for people who have two functioning arms. Lin was aware of this issue, so he created a cutting board that made it easier for disabled people to make meals.

Infrastructure

[edit]
  • Playgrounds/parks in urban areas: Children are often excluded from accessible public places in cities due to safety concerns, so spatial planners design playgrounds and parks within cities in order to give children the opportunity to freely examine their curiosities. These areas are significant for a child's growth because children can socialize with each other, explore their surroundings, and stay physically active without worrying about any common dangers that can occur in an urban environment.[30]
  • Musholm: The majority of fitness centers do not have sufficient accessibility provisions for disabled people; this inactivity can exacerbate the effects of illness.[31] Musholm is a sports center located in Denmark where everyone can participate in various physical activities. It contains a 110 meter-long activity ramp with landings and recreational zones, where wheelchair users can engage in activities such as a climbing wall and even a cable lift.[32] The initial objective for the designers of this building was making sure that the facilities were accessible to everyone, and because of their commitment, Musholm was voted the world's most socially inclusive building.[32] Although it is challenging for architects to construct inclusive infrastructure, the structure of Musholm proves that it is possible.
  • The Friendship Park: Located in Uruguay, this park was built so that it can be easily accessible for every child, especially children with disabilities. The park has swings available for children in wheelchairs, wide walkways, curved corners instead of sharp edges, and flooring that is cushioned and slip resistant. These unique features were added in order "to not only make the space safe, but to also make the space easy to use."[33]
  • Tactile Pavement in Urban Area: Visually impaired individuals often feel excluded from the community because they have hard time navigating their surroundings. Implementing tactile pavement around the community assists them in locating their route and directions to minimize time used on the road. These pavements have different but identifiable textures allowing them to understand what is ahead and alert them to possible danger. Some indicators includes blister paving patterns, where it locates around crosswalks to indicate road crossing ahead, cycleway tactile paving that help alert people of cyclist path, where the pavements has lined tile along the path for the cyclist and most importantly the directional tactile paving that help indicate the direction of the sidewalks when there are no other indicators on the street.[34]

See also

[edit]

References

[edit]
  1. ^ Joyce, Alita. "Inclusive Design". Nielsen Norman Group. Retrieved 2022-02-13.
  2. ^ a b "History | Institute for Human Centered Design". www.humancentereddesign.org. Retrieved 2022-01-27.
  3. ^ "Philosophy". Inclusive Design Research Centre. Retrieved 2022-01-27.
  4. ^ "Inclusive Design Research Centre". legacy.idrc.ocadu.ca. Retrieved 2022-02-13.
  5. ^ Treviranus, Jutta (2021-11-30). "The Three Dimensions of Inclusive Design: Part One **". fwd50. Retrieved 2022-01-27.
  6. ^ a b c "History | Institute for Human Centered Design". www.humancentereddesign.org. Retrieved 2022-01-27.
  7. ^ a b Williamson, Bess (2019-01-15). Accessible America: A History of Disability and Design. NYU Press. ISBN 978-1-4798-9409-3.
  8. ^ a b John Clarkson, P.; Coleman, Roger (2015-01-01). "History of Inclusive Design in the UK". Applied Ergonomics. Special Issue: Inclusive Design. 46: 235–247. doi:10.1016/j.apergo.2013.03.002. ISSN 0003-6870. PMID 23570838.
  9. ^ International Ergonomics Association; Congress, eds. (1994). Proceedings of the 12th Triennial Congress of the International Ergonomics Association: Toronto, Canada, August 15-19, 1994 = Comptes rendus du 12e Congrès triennal de l'Association internationale d'ergonomie : du 15 au 19 août 1994 . Mississauga, Ont., Canada.: Human Factors Association of Canada = Association canadienne d'ergonomie. ISBN 978-0-9698544-0-1. OCLC 35932553.
  10. ^ "What is the difference between accessible, usable, and universal design? | DO-IT". www.washington.edu. Retrieved 2022-02-13.
  11. ^ "White House Design For All Showcase | AOPA – AMERICAN ORTHOTIC & PROSTHETIC ASSOCIATION". www.aopanet.org. Retrieved 2022-02-13.
  12. ^ Williamson, Bess (2019). Accessible America: A History of Disability and Design. Vol. 2. NYU Press. ISBN 978-1-4798-9409-3. JSTOR j.ctvwrm3zv.
  13. ^ a b May, Matt. "The Same, But Different: Breaking Down Accessibility, Universality, and Inclusion in Design". Adobe Blog. Retrieved 2022-01-27.
  14. ^ "Accessible Design vs Inclusive Design (with Infographic)". Toptal Design Blog. Retrieved 2022-01-27.
  15. ^ a b "Understanding universal design vs accessibility vs inclusive design". Say Yeah!. 2020-05-12. Retrieved 2022-01-27.
  16. ^ Zheng, Ruby (21 May 2021). "Learn to Create Accessible Websites with the Principles of Universal Design". The Interaction Design Foundation. Retrieved 2022-01-27.
  17. ^ LIEDTKA, JEANNE; HOLD, KAREN; ELDRIDGE, JESSICA (2021). Experiencing Design: The Innovator's Journey. Columbia University Press. doi:10.7312/lied19426. ISBN 978-0-231-19426-6. JSTOR 10.7312/lied19426.
  18. ^ "What is inclusive design?". inclusivedesigntoolkit.com. Retrieved 2022-01-27.
  19. ^ "Microsoft Design". www.microsoft.com. Retrieved 2022-01-27.
  20. ^ "What Is Inclusive Design? Principles & Examples | Adobe XD Ideas". Ideas. Retrieved 2022-02-13.
  21. ^ a b Björgvinsson, Erling; Bjögvinsson, Erling; Ehn, Pelle; Hillgren, Per-Anders (2012). "Design Things and Design Thinking: Contemporary Participatory Design Challenges". Design Issues. 28 (3): 101–116. doi:10.1162/DESI_a_00165. hdl:2043/14805. ISSN 0747-9360. JSTOR 23273842. S2CID 54666697.
  22. ^ Joyce, Alita (2022-01-30). "Inclusive Design". Nielsen Norman Group. Retrieved 2022-02-13.
  23. ^ Joyce, Alita (2022-01-30). "Inclusive Design". Nielsen Norman Group. Retrieved 2022-02-13.
  24. ^ McBee-Black, Kerri; Ha-Brookshire, Jung (July 2020). "Words Matter: A Content Analysis of the Definitions and Usage of the Terms for Apparel Marketed to People Living With Disabilities". Clothing and Textiles Research Journal. 38 (3): 166–181. doi:10.1177/0887302X19890416. ISSN 0887-302X.
  25. ^ Rutledge, Brittany (2017). Autoethnograhic Study in the Process of Applied Design: Creating Adaptive Clothing for a Child with Spinal Muscular Atrophy (MAEd thesis). Georgia State University. doi:10.57709/10025817.
  26. ^ Aguiar, Grazyella C. O.; Rincon, Leonardo M.; Carvalho, Miguel A. F.; Mailer, Christian; Breier, Fabieli D.; Ferreira, Fernando B. (2020), "Fashion and Inclusive Design: Assistive Technologies Applied to Clothing", Advances in Industrial Design, Advances in Intelligent Systems and Computing, vol. 1202, Cham: Springer International Publishing, pp. 32–37, doi:10.1007/978-3-030-51194-4_5, hdl:1822/90625, ISBN 978-3-030-51193-7, S2CID 225611538, retrieved 2022-02-13
  27. ^ Norman, Don (2013). The Design of Everyday Things. New York: Basic Books. pp. 244–245. ISBN 978-0-465-05065-9.
  28. ^ Langley, J.; Janson, R.; Wearn, J.; Yoxall, A. (2005). "'Inclusive' design for containers: improving openability". Packaging Technology and Science. 18 (6): 285–293. doi:10.1002/pts.699. ISSN 0894-3214. S2CID 109131296.
  29. ^ "One inclusive design". One inclusive design. Retrieved 2022-02-17.
  30. ^ Ramioul, C.; Tutenel, P.; Heylighen, A. (2020), "Exploring with Children What Makes a City Child-Friendly", Designing for Inclusion, Cham: Springer International Publishing, pp. 99–106, doi:10.1007/978-3-030-43865-4_10, ISBN 978-3-030-43864-7, S2CID 218813927, retrieved 2022-02-04
  31. ^ Nikolajsen, Helene; Richardson, Emma Victoria; Sandal, Louise Fleng; Juul-Kristensen, Birgit; Troelsen, Jens (2021-07-30). "Fitness for all: how do non-disabled people respond to inclusive fitness centres?". BMC Sports Science, Medicine and Rehabilitation. 13 (1): 81. doi:10.1186/s13102-021-00303-2. ISSN 2052-1847. PMC 8325230. PMID 34330328.
  32. ^ a b "Musholm". English. Retrieved 2022-02-04.
  33. ^ Furey, Joshua; Maraccini, Jared; Phakousonh, Cheyenne; Rasmussen, Justin; Schotte, Jonathan. 2016 Project Elijah Final Report PDF. Proceedings of the Wisconsin Space Conference. Vol. 1. doi:10.17307/wsc.v1i1.183.s6.
  34. ^ “Blindness and Vision Loss: Chapter 2: Travel by Pedestrians Who Are Blind or Who Have Low Vision.” Accessible Pedestrian Signals: Blindness and Vision Loss, National Cooperative Highway Research Program, www.apsguide.org/chapter2_blindness.cfm.

Further reading

[edit]