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Article

The Usability Study of a Proposed Environmental Experience Design Framework for Active Ageing

1
ZEMCH Lab, Faculty of Architecture, Building and Planning, The University of Melbourne, Melbourne, VIC 3010, Australia
2
Department of Architecture, School of Design, University of Pennsylvania, Philadelphia, PA 19104, USA
*
Author to whom correspondence should be addressed.
Buildings 2018, 8(12), 167; https://doi.org/10.3390/buildings8120167
Submission received: 14 August 2018 / Revised: 2 November 2018 / Accepted: 20 November 2018 / Published: 28 November 2018
(This article belongs to the Special Issue Human Factors in Green Building)

Abstract

:
Growing ageing population today may be necessitating building design decision makers to reconsider the indoor environmental quality (IEQ) standards in a way that accommodates senior occupants’ diverse and individual needs and demands. An experience design approach to rationalising and individualising end-user experience on how to utilise tangible products may serve to reflect user perceptions. Generally, architectural design practices tend to incorporate neither IEQ monitoring and analysis data, nor environmental experience design today. In response to the need for filling this gap, the authors of this paper conducted a feasibility study previously that led to structuring and defining an ‘Environmental Experience Design’ (EXD) research framework. Based on the previous case study on the collective spatial analysis and IEQ monitoring results, this paper further explored the usability and applicability of this proposed EXD framework particularly to the previously documented aged care facility in Victoria, Australia, which has been stressing active ageing agendas. This EXD framework usability experiment helped to build the capacity for engaging the subjectivity and objectivity of end users’ expectations, desires, and requirements in the architectural design thinking process. Nonetheless, due to the limitation of this initial and fundamental usability study’s resources and the objective, the necessity of adjusting the scale and scope of EXD analyses emerged. Moreover, the universality of this EXD research framework usage under various architectural typologies and user conditions yet require further attempts and investigations.

1. Introduction

The population of Australia is ageing [1,2,3]. There were 3.5 million senior citizens who were aged 65 years and over in 2014 taking up 15% of the population [4]. It is estimated that the proportion of senior citizens will rise to 26% in 2051 and to 27% in 2101 [5,6,7]. The population of Victoria follows the tendencies shown in the wider Australian population (Table 1). As of September 2017, the estimated Victorian population was 6,179,249 [8]. This is an increase of almost 23% since June 2005 [9]. Residents aged 55 and over cover nearly a quarter of the population (22.4%) and those aged 65 years and above form 16.7% of Victoria’s population [1]. The proportion of the population aged 65 years and over is expected to go up to 17.4% in 2021, 18.8% in 2031, 20.4% in 2041, and 21.8% in 2051 [9]. The greatest proportional shift in next few decades to be expected is the number of Victorians aged 85 years and above is projected to increase from 2.6% of the population in 2017 to 4.6% in 2051 [9]. There were 27% of the population aged 65 and over born in a non-English speaking country in contrast to 20% born domestically [10].
The rise of senior population in Victoria led to the increase of aged care facility establishments and the architectural design may need to serve as an agent of engagement for societal needs. The design decisions today tend to be made without favouring user experiences and this challenge might be derived from the discrepancies between prescribed building codes and user perception. The role of built environments may become more prominent in managing increasing sensitives and vulnerabilities that come with ageing. As the Australian population ages, the state of Victoria is actively working towards facilitating effective spatial design strategies through an integrated framework for “active ageing” (Figure 1) [11,12,13,14,15,16,17,18].
It is worth noting that the “experience design” has already been applied to industrial designs and the “user experience design” focuses on improving products’ interface to facilitate the usage in response to end-users’ diverse physical and psychological needs and demands [19]. Pine and Gilmore (1999) stress that experience designs encompass both passive and active participation of end-users [20]. Architectural design has an impact on users’ physical and perceived comfort levels in the built environment. Nonetheless, the notion of such experience design is barely applied to architectural design practices today.
Data analysis or ‘programming’ facilitates stakeholders’ design orientation in response to the project objectives identified for the achievement [21]. De Giuli et al. (2012) articulates the significant impacts of indoor environmental quality (IEQ) research around thermal, acoustic, and visual conditions, as well as air quality on occupants’ health and wellbeing in the built environment [22]. IEQ data collected and/or simulated may provide some insights or indications of what the building in question can perform to maintain the acceptable levels of the occupants’ health and wellbeing [23]. Therefore, IEQ standards need to be well incorporated into architectural design decision making; nonetheless, it may be worth noting that these physical indicators alone need not reflect occupants’ perceived quality. Neither does the environmental design data itself serve as a direct architectural design decision-making tool.
This study explores this challenge through implementing an ‘Environmental Experience Design’ (EXD) research framework, which was previously proposed by this paper’s authors who reviewed the related theories that help to illustrate human physical and psychological needs and demands [24]. The proposed EXD framework devises “function analysis” techniques that help to categorise occupants’ requirements, desires and expectations in the built environment [25]. This study tested the proposed EXD research framework as a systematic approach to further identifying relevant design solutions towards activating senior citizens for the improvement of their health and wellbeing.

2. Environmental Experience Design Research Framework Review

A human-environment integrated approach that assists architectural design stakeholders in understanding the occupants’ physical and psychological needs and demands is required. In response to this need, the authors of this paper proposed a conceptual ‘Environmental Experience Design’ (EXD) research framework in 2017 [24]. This proposed EXD framework was designed to identify overall project objectives, analyse user perception, and propose design strategies and solutions. It is an interdisciplinary trajectory that is relatively new to architectural practices, aimed at embracing a human-environment integration into the design decision making process. The EXD framework devises a function analysis methodology that helps to identify “performance of a user function” and refine the design procedure to “fulfil a user requirement” by questioning what user needs are and how designers meet them [25]. The Function Analysis System Technique (FAST) diagram is first generated as a process to logically visualise the project’s key objectives or functions for prioritisation. The FAST diagram serves as a map or pathway towards the scrutiny of possible design solutions in response to the users’ physical and psychological needs and demands identified (Figure 2).
Contextualising the human-environment relationship is of importance in the built environment, since the space affects users’ activities of daily living [26,27]. Spatial design strategies need to be set in a way that matches both objective physical parameters (e.g., natural and built environment settings) and subjective user perception (e.g., psychological needs and demands). In the EXD research framework, in response to FAST implementation results, user experience related functions and the associated spatial design strategies and solutions are contextualised through the development of a human-environment matching ‘EXD evaluation matrix’ (Figure 2) [24]. The enumeration helps to visualise the relationship between the occupants’ physical and psychological requirements, desires and expectations, and the potential architectural design strategies and solutions applied to shaping the space accordingly.
The EXD research framework was developed conceptually as a tool that any stakeholders can apply to identifying projects’ objectives and relevant design solutions (Figure 3). Nonetheless, the actual usability and applicability are still in question. Thus, the following sections will demonstrate how this conceptual EXD tool can be applied to upgrading a selected aged care facility in Victoria, Australia, in consideration of the Victorian government’s active ageing agenda.

3. Proposed EXD Framework Implementation

This study revisited an aged care facility located in Victoria, Australia, with the aim to test the usability and applicability of the Environmental Experience Design (EXD) research framework proposed initially by authors of this paper in 2017 (Figure 4) [24]. It is also aimed at demonstrating the human-environment matching mechanism oriented towards activating the senior residents for their health and wellbeing.
To make sure that the selected aged care facility was designed to maintain the minimal levels of physical indoor environmental quality (IEQ) conditions, IEQ monitoring of the temperature, and the levels of particulate matter and carbon dioxide concentration was conducted over a one-week period from 29th May to 4th June 2017 (Figure 5) [24]. The study confirmed that the overall IEQ conditions were generally satisfactory. Nonetheless, it also led to stressing a potential consideration, as indicated “Although the thermal condition of both bedroom and communal space are in the lower range of thermal comfort zone defined by ANSI/ASHRAE Standard 55-2013, a warmer environment is recommended … the 20–24 °C comfort zone is not warm enough for older adults and older adults generally prefer a warmer environment than younger subjects” (Figure 6) [24].
Based on the spatial analysis of the aged care facility revisited, the EXD FAST diagram was developed with the aim to outline the relevant functions that reflect the senior residents’ general needs and demands around their activities of daily living, as well as to identify sensitive spaces and the upgrading approaches to activating the elderly physically and psychologically. The function analysis aims to encompass both the subjectivity and objectivity of users’ needs and demands; therefore, all stakeholders including not only the residents and visitors but also designers and builders may ideally be involved in the thinking process. Nonetheless, due to the main aim of this study that attempts to demonstrate and analyse the framework usability, the EXD FAST diagram was shaped by the researchers who observed, documented, and analysed the building, in addition to the IEQ monitoring on behalf of the stakeholders (Figure 7).
Based on the observations of the spatial settings throughout the ground floor, level differences are well avoided, and this inclusive design fundamental allows for enhanced accessibility and safety of the senior users with mobility aids. Partitions set between the dining and kitchen area tend to discourage visual and physical interaction, while limiting the circulation of unfavourable smells. Staff areas, including the office, reception, and nurses’ station are located next to the dining room, which serves as the residents’ social activities. The bedrooms were dimensionally adequate and were lit by natural light coming through the transparent window that is centered in the external wall. Outdoor spaces are equipped with accessible garden pedestrian paths, communal spaces with barbeque facilities, visually stimulating artefacts, and seasonal plants—those that to some extent contribute to the creation of atmosphere that supports the notion of active aging. Based on the spatial setting observation and FAST diagram results, an EXD evaluation matrix was developed with the aim of identifying the potential upgrading solutions that reflect the Victorian government’s active ageing agenda (Table 2).
In this study, the EXD evaluation matrix contents were further simplified and illustrated to articulate the selected aged care facility’s human-environment relationship (Figure 8). EXD visualisation serves as a medium that all stakeholders, such as the facility’s staff, users, visitors, and appointed architects, can understand today’s spatial circumstances and the future upgrading potentials that contribute to turning passive senior residents into active ones for their physical and mental health and wellbeing.

EXD Spatial Upgrading Potentials

The EXD evaluation matrix was contextualised for value visualisation and it led to identifying some potential architectural design or space upgrading solutions for active ageing (Figure 9). Three spaces of the selected aged care facility were used for the demonstration of the proposed EXD framework. Before-and-after design upgrades of these selected spaces were illustrated based on the EXD evaluation outcomes. The annotations appearing in Figure 9, Figure 10 and Figure 11 reflect the design solutions that are listed on the 6th column from the left of Table 2.
Suggestions for the minor renovation included: the replacement of fabric carpets with anti-bacterial titles for the elderly users’ smooth walk and enhanced sanitation; the change of existing window blinds to double-layered fabric curtains, which allow for more flexibility in modulating the intensity of natural light being introduced into the internal space; and, the introduction of indoor potted plants that encourage the senior residents’ engagement with nature in the controlled built environment. These renovations can be realised within the building’s existing structure, dimension, volume, and layout; nonetheless, some low-care units that are occupied by immobile senior users may desire major high-care upgrades (Figure 10).
Suggestions for the ground floor improvement extended to the relocation of low care bedrooms to places adjacent to rooms that embrace social and physical activities (Figure 11). This may create opportunities for immobile senior residents to be linked to visual and acoustic stimuli. The reduction of physical and visual barriers (i.e., open floor planning) might also lead to the enhancement of users’ social networking opportunities. Non-structural rigid partitions can be replaced with collapsible or movable partitions that can separate or open spaces according to the users’ specific needs and demands.
Outdoor settings may also need to be designed for enhancement of the senior occupants’ safety, accessibility, comfort, and stimulation for active ageing. Exposure to the full spectrum of natural light may contribute to activating the occupants along with humans’ circadian rhythms. The proposed designs included features that aim to promote visual, acoustic, and olfactory stimuli, and the placement of vegetation (and pets) would also serve as an active ageing driver. Dubos (1980) argues that “people want to experience the sensory, emotional, and spiritual satisfactions that can be obtained only from an intimate interplay, indeed from an identification with the places which [they] live” [28]. However, such human satisfaction may be continuously reliant on perceiving and responding to sensory variability [29]. Senses of sound, touch, and smell form the sensory richness [29]. Although walking pathways exist in the selected aged care facility, there is no intent or consideration of adding pleasant visual and olfactory stimuli to the users’ experience. If these spaces are equipped with interactive green gardens, senior residents may be more attracted to taking a stroll or even the upkeep.

4. Conclusions

The proposed ‘Environmental Experience Design’ (EXD) research framework was an attempt to connect the domains of environmental design and experience design. It addressed complexities of the human-environment relationship and served as a design decision-making support tool that helps visualise end-users’ needs and demands, as well as build a pathway towards identification of the associated design solutions. This study was an extension of the authors’ previous research project that conceptualised the EXD research framework itself. In this paper, the usability and application to a selected aged care facility’s spatial design upgrades for active ageing were explored and demonstrated conceptually. In addition to the IEQ building performance check, this EXD framework usability experiment helped to build the capacity for engaging the subjectivity and objectivity of end users’ expectations, desires, and requirements in the architectural design thinking process. Nonetheless, this study was limited to an initial and fundamental demonstration of the EXD decision making process that targeted the potential design improvements of a selected aged care facility in Victoria, Australia; therefore, the universality of this EXD research framework usage under various architectural typologies and user conditions still requires further attempts and investigations. Moreover, the scale and scope of EXD analyses need to be narrowed and focused much further for in-depth exploration of each functional space in the built environment, while the stakeholders’ direct involvement in the function analysis stage is necessitated to identify their precise perceived needs and demands rather than the speculations. A subsequent validation study of the EXD experiential effect on IEQ improvements may require further justification of the usability and universality.

Author Contributions

M.N. and N.M. led overall research activities and contributed to structuring the proposed environmental experience design diagnostic framework and writing this paper. C.M.M.W. contributed to the editorial coordination. H.-w.C. documented the aged care facility selected in Victoria. J.Z. contributed to the IEQ monitoring and data analysis.

Acknowledgments

The authors would like to express their sincere gratitude to Adare SRS which allowed them to access their aged care facility rooms for in-depth documentation and IEQ monitoring.

Conflicts of Interest

The authors declare no conflict of interest.

References

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Figure 1. Aged care agenda timeline.
Figure 1. Aged care agenda timeline.
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Figure 2. General Function Analysis System Technique (FAST) diagram image.
Figure 2. General Function Analysis System Technique (FAST) diagram image.
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Figure 3. Environmental Experience Design (EXD) matrix evaluation process for human-environment element integration.
Figure 3. Environmental Experience Design (EXD) matrix evaluation process for human-environment element integration.
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Figure 4. Exterior view of Adare SRS studied.
Figure 4. Exterior view of Adare SRS studied.
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Figure 5. Locations of Indoor Environmental Quality (IEQ) Measurements.
Figure 5. Locations of Indoor Environmental Quality (IEQ) Measurements.
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Figure 6. Thermal condition of the bedroom (left) and lounge space (right) in psychometric chart. The shaded areas represent comfort zone boundary [24].
Figure 6. Thermal condition of the bedroom (left) and lounge space (right) in psychometric chart. The shaded areas represent comfort zone boundary [24].
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Figure 7. EXD FAST diagram of senior residents’ physical and metaphysical functions.
Figure 7. EXD FAST diagram of senior residents’ physical and metaphysical functions.
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Figure 8. EXD human-environment relationship visualisation.
Figure 8. EXD human-environment relationship visualisation.
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Figure 9. An existing bedroom unit (top) and the EXD upgrading potentials (bottom).
Figure 9. An existing bedroom unit (top) and the EXD upgrading potentials (bottom).
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Figure 10. An existing low-care room (top) and a suggested high-care upgrade (bottom).
Figure 10. An existing low-care room (top) and a suggested high-care upgrade (bottom).
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Figure 11. Proposed articulation for visual and physical connectivity between spaces.
Figure 11. Proposed articulation for visual and physical connectivity between spaces.
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Table 1. Population of people aged 55 years and over in Victoria [1].
Table 1. Population of people aged 55 years and over in Victoria [1].
AgeMenWomenTotal
55+336,334 (11.0%)354,377 (11.3%)690,711 (22.4%)
65+251,532 (8.2%)265,111 (8.5%)516,643 (16.7%)
75+130,624 (4.3%)154,595 (5.0%)285,219 (9.2%)
85+47,602 (1.6%)79,750 (2.6%)127,352 (4.1%)
All ages3,056,4343,122,8156,179,249
Table 2. EXD evaluation matrix enumerating potential senior users’ physical attributes and psychological perceptions towards identification of possible design solutions [24].
Table 2. EXD evaluation matrix enumerating potential senior users’ physical attributes and psychological perceptions towards identification of possible design solutions [24].
Design CriteriaDesign SettingsObjectivesDesign ElementsOpportunitiesDesign Solutions
Physical Activation CriteriaNatural settingNatural variabilitySoundsProviding pleasing effectsEuphonic sounds increase
Providing soothing effectsChaotic sounds reduction
Touch responsesInteraction with vegetationGarden walking pathways
Interaction with animalsFreedom of feeding pets
Smell responsesOlfactory stimuliDifferent scented plants
Ageing and changingThe rhythm of lifeSeasonal plants assembly
Natural harmonyComplex orderRich sensory informationDifferent types of flowers and trees gardening
Patterned wholesIntriguing balance between boring and overwhelmingSymmetric and fractal geometries of integrated pavements
NaturalnessOutdoor gardensEcological connectivityCommunal spaces in the garden
Garden craftsCulture and ecology integrationThe elderly engaged gardening
Built environment settingSpatial adaptabilityPresent spatial needsAchieving the elderly’s satisfactionsCalming colours of wall and ceiling paintings
Natural textured material of floorings
Two layered curtains: gauze and fabric curtains with natural colours
Freedom of bringing personal belongings
Lockable interior doors
Keep gardens open
Spatial flexibilityFuture spatial needsPliable temporal limitationMoveable partitions
Spatial durabilityEase of maintenance spacesCleanliness guaranteeFlooring with vinyl
Spatial arrangementSpatial requirementFriendly, comfortable and welcoming living conditionsKitchen adheres to dining areas
Communicative living rooms
Bedrooms with private bathroom
Multi-activity rooms
Corridors with hand rails
Clinic and therapy areas
A nurse’s station
Spatial relationshipKitchen next to dining room (5)
Nurses station away from dining room (5)
Nurses station away from reception and entrance (5)
Nurses station away from high-care residents’ bedrooms (5)
Nurses station away from clinic and therapy areas (5)
Nurses station away from staff office (3)
Low-care elderly’s bedrooms next to activity rooms (4)
Spatial layoutUsing bubble diagrams
Indoor environmental qualityDry bulb temperatureElderly wellbeing, comfort and healthDirect heat exposure avoidance: ranging between 19.4 to 27.8 °C
Radiant temperatureShading provision: within the comfort zone
Relative humidityFresh air ventilation: less than 61%
Indoor air qualityFresh air ventilation: Carbon Dioxide concentration below 1000 ppm
Particulate matter (PM10) less than 150 µm/m3 (in 24 hrs)
Particulate matter (PM25) less than 35 µm/m3 (in 24 hrs)
Psychological Activation CriteriaPsychological demandsEmotional wellnessAnxiety reductionHarmful effects on health and the overall quality of lifeRespect the elderly’s personal choices and decisions
Anger reduction
Depression reduction
Passive participationActivating physical walkingIncrease engagement and participationLow-care elderly’s bedrooms with a distance away to living rooms
Visual connection to activity roomsLayout of the low-care elderly’s bedrooms adjacent to activity rooms
Psychological needsSecurityEmpowering a sense of individual dignityBeing free from injuryNon-hierarchical spaces
Manageable spaces
Controllable spaces
Safety
Active participation
Generating a sense of belongingnessBeing protected from riskLocating residential care facilities in the neighbourhood
Rooms have visual connections with outdoors
Stimulating the elderly bringing distinctive vernacular objects
Stimulating the elderly engaged gardening
A space with the passage of time
Barrier-free spatial conditionsPhysical activity stimulationLevel difference avoidance
Slip-resistant and firm flooring surfaces
Physical and visual barriers elimination
Wide interior doors, corridors and turning spaces associated with the elderly movements
Open floor planningSocial interactionMaximising the use of limited spaces
Minimising partitions
Multi-activity rooms’ designRestorative activityEvoking and developing the elderly’s interests

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MDPI and ACS Style

Noguchi, M.; Ma, N.; Woo, C.M.M.; Chau, H.-w.; Zhou, J. The Usability Study of a Proposed Environmental Experience Design Framework for Active Ageing. Buildings 2018, 8, 167. https://doi.org/10.3390/buildings8120167

AMA Style

Noguchi M, Ma N, Woo CMM, Chau H-w, Zhou J. The Usability Study of a Proposed Environmental Experience Design Framework for Active Ageing. Buildings. 2018; 8(12):167. https://doi.org/10.3390/buildings8120167

Chicago/Turabian Style

Noguchi, Masa, Nan Ma, Catherine Mei Min Woo, Hing-wah Chau, and Jin Zhou. 2018. "The Usability Study of a Proposed Environmental Experience Design Framework for Active Ageing" Buildings 8, no. 12: 167. https://doi.org/10.3390/buildings8120167

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