Computational analysis can help us create more liveable aged care environments for people with dementia
School of Built Environment
School of Built Environment
A new computational analysis tool combined with spatial analysis will optimise aged care design to make it more fit-for-purpose for people living with dementia.
An architectural assessment tool, paired with advanced spatial analysis, can be used to improve aged care design for people with dementia. The tool, , assesses a facility鈥檚 layout to evaluate the quality of its design in relation to residents鈥 needs.
Then, using advanced computational methods 鈥 machine learning, agent-based modelling, space syntax and fractal analysis 鈥 improvements can be made to a design to increase its effectiveness.
is the first tool suitable for architectural floorplan-based assessment of residential care facilities that can be applied at the design phase. Designing 鈥 rather than retrofitting 鈥 facilities ensures they are truly fit-for-purpose and will enhance the welfare of people living with dementia in care.
People with dementia face specific challenges in their interactions with space, says UNSW鈥檚 Professor Michael J. Ostwald, who is leading part of this international project.
鈥淭heir independence and wellbeing can be significantly influenced by the physical environments around them. As our population ages, and the number of people living with dementia increases, we need to design more effective aged care facilities to better accommodate their needs,鈥 says the Professor of Architectural Analytics and Associate Dean, Research from UNSW鈥檚 Faculty of Arts, Design & Architecture.
. However, 鈥渢he majority of residential care facilities were designed for people who have deteriorating physical mobility, rather than for people with dementia,鈥 Prof. Ostwald says.
The care needs of people with dementia are quite different from other aged care residents. They can include managing wandering behaviours, cognition issues and difficulties in undertaking daily activities, such as communicating, toileting and eating meals.聽
Plan-EAT evaluates the floorplans of proposed or existing residential care facilities using evidence-based principles, including safety, size and scale, reduction of stimuli, movement and engagement, privacy and social interaction, Prof. Ostwald says. These 鈥渄ementia design principles鈥 reduce symptoms and increase wellbeing; but their implementation remains difficult in architecture.
鈥淚n a practical sense, Plan-EAT produces a kind of index against which the properties of architectural plans can be measured by expert assessors and then used to change a design for the better,鈥 he says. For example, the tool can assess the effect of floorplans on wayfaring and security. These are important factors for supporting care of people with dementia, because people with dementia can be more likely to become lost, confused or upset.聽
Once a design is assessed, we can use computational analysis to propose ways to improve the plans, promoting spaces which accommodate a kind of circling wandering movement that can be securely monitored, he says.
鈥淎dditionally, becoming lost can have unwelcome consequences. Designs need to prioritise the visibility of bathrooms and kitchen/dining facilities from multiple key points within the facility to provide visual reminders of these daily functions,鈥 he says.
鈥淰iews of nature and natural engagement also potentially improve mental health, and this is another factor that can be assessed using Plan-EAT and improved using computational analysis of a design.鈥
While there is no such thing as a single formula for such a complex design issue, the tool is invaluable in its research-driven assessment of residential aged care design, he says.
The research team behind this project, which includes experts from the Centre from Environment, Dementia and Ageing Research at the University of Stirling, the University of Wollongong and UNSW Sydney, is examining how its findings can be complemented by additional computational modelling and optimisation techniques to improve facility designs.
Prof. Ostwald and his UNSW colleagues, Dr JuHyun Lee and Dr Michael Dawes, have expertise in both the use of diverse cognitive principles in design and the computational optimisation of space in buildings and cities. The team鈥檚 expertise has previously been applied in a wide range of environments, from office buildings to housing and shopping malls.
鈥淭hese skills and experience are combined in the Plan-EAT project to offer significant opportunities for improving the design of residential facilities,鈥 says Prof. Ostwald. 鈥淚t鈥檚 a world-first approach to the creation of environments specifically designed for people living with dementia.鈥澛
Computational design is a data intensive, technically advanced approach which helps in the creation of smarter, more socially cohesive and responsive environments. Prof. Ostwald鈥檚 research uses predictive mathematical models, supported by neurophysiology (brain scans and eye movement analysis), to analyse, optimise and understand architectural and urban space.
鈥淢y team models and predicts the way people interact with, understand and move through spaces,鈥 he says. 鈥淥ver many years, architects and behavioural psychologists have identified that certain types of spaces encourage certain types of behaviours.鈥
For example, corridors tend to draw people down them, while alcoves encourage small gatherings, he says. Computational modelling predicts typical behaviours in space to enable design optimisation in line with desirable social or behavioural patterns. It is a way to understand things about designs that are not visible, he says.
Computational design software can analyse small to large-scale designs and optimise walking distances, sight lines, ventilation, access to natural light and other elements.
鈥淲e can overlay our computational models on building plans and we can predict where people will loiter or gather鈥 We can predict where there'll be lots of visual connectivity which supports social cohesion and a sense of place or ownership. And we can also predict where crime might occur if there are too many nooks and crannies and dead ends or too many unobserved or un-surveilled positions.鈥
Interpreting the analytics requires nuance, he says. 鈥淪ocial connectivity isn鈥檛 always about talking to people, although that鈥檚 optimal, it鈥檚 even about being able to nod to someone across a garden each day.鈥
By modelling sight lines, designers can identify where people鈥檚 gazes will intersect, 鈥渁nd that becomes an ideal space for a park bench, or a table and seating area. Someone can glance out and see it鈥檚 empty鈥 and they can go out and sit there themselves. This can be achieved by moving a few windows or making a window taller or wider,鈥 he says.
Prof. Ostwald has consulted on the design and optimisation of remote mining communities, correctional facilities and Indigenous communities as well as commercial retail, accommodation and entertainment precincts. He has worked with major industry clients, including BHP Billiton, Stockland Group, Lendlease, Civil & Civic as well as for local and state government, assessing commercial and public designs using computational modelling and analysis.
鈥淲e can, for example, predict levels of visual confusion using fractal geometry and mathematics to calculate how complex an environment is. And to determine if that鈥檚 a good thing? And does that reduce or increase depending on the ways we move or walk through a space?鈥
Our understanding of space is refracted through the prism of our experience, he says. 鈥淭he relationship between buildings and behaviour is flexible. It depends on age, there鈥檚 a gender slant to it, there's a cultural difference as well. And that makes it both rich, and difficult.鈥
Additionally, we all have slightly different cognitive understandings of space, he says. For example, recent research has shown that younger millennials are comfortable with a greater level of visual complexity in environments than other age-demographics; 鈥渁t a certain age, though people like less visual complexity," he says.
Prof. Ostwald also applies these logics to iconic contemporary and ancient buildings. 鈥淚 have a great love of famous historic and modern architecture, and I enjoy the challenge of applying these complex computational models and mathematics to better understand, for example, a building from the 17th century,鈥 he says.
While his team is largely focused on contemporary pragmatic challenges, it draws on research from diverse fields, then considers how those lessons can be spatialised or embedded in architecture by adapting or developing computational modelling to work out what鈥檚 the best way to design.
It鈥檚 about creating a legacy of real-world change: 鈥淭he successes we have then feed into the next generation of laws that control the next generation of buildings,鈥 he says.
Lead image: The care needs of people with dementia are quite different from other aged care residents. Image: Shutterstock
This article was originally published in 2022.