From city’s station to station city


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Towards a Human Centred 
Approach for Adaptive Façades
An Overview of User Experiences in Work Environments

Mine Koyaz1-2*, Alejandro Prieto3-5, Aslıhan Ünlü4, Ulrich Knaack3

*  Corresponding author
1 Istanbul Technical University, Construction Sciences Doctoral Program. Turkey, koyaz@itu.edu.tr 
2 Istanbul Bilgi University, Faculty of Architecture, Department of Architecture. Turkey 
3 Delft University of Technology, Faculty of Architecture and the Built Environment, Department of Architectural Engineering + 

Technology, Architectural Facades & Products Research Group. The Netherlands 
4 Özyeğin University, Faculty of Architecture and Design. İstanbul, Turkey 
5 Universidad Diego Portales, School of Architecture; Faculty of Architecture, Art and Design. Santiago, Chile 

Abstract 

Adaptive façades are multifunctional systems that are able to change their functions, features, or 

behaviour over time in response to changing boundary conditions or performance requirements. 

As one of the significant developments in the façade industry over the last decade, the adaptive façade 

offers an intelligent solution that can decrease energy consumption and potentially increase users’ 

comfort in a building. From an engineering perspective, these advanced technologies aim to improve 

the overall performance of the building while generating a better indoor environment for the users, 

but unfortunately, investigations show that this goal is not always achieved. This is why, to bridge this 

performance gap, we embark on a change of perspective in façade design, from a technology-centred 

to a human-centred one. This research emphasizes that, with their changeability aspects, adaptive 

façade technologies offer unique potential, although the design of such façades requires a deeper 

understanding of users. With this as its focus, this paper aims to identify the factors affecting the user 

experience in a working environment, considering the interactions of the user with building services and 

façade systems from a holistic point of view, in which façade-user relationships are to be distinguished, 

towards the larger aim of developing a human-centred approach for adaptive façade design. 

Keywords

human centred design, user experience, adaptive behaviour, adaptive façade, façade design, 

changeability, interaction

DOI

http://doi.org/10.47982/jfde.2022.1.02



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1 INTRODUCTION

The complex multifunctional aspects of façade design hold an inherent duality between optimizing 

the energy performance of a building and providing comfort for its users (Klein, 2013). Although 

these two sides are inseparable and highly intertwined, as a result of their conflicting nature 

one could be easily overlooked in favour of the other, which unfortunately would result in poor 

design on both sides. 

Worldwide, there have been several research projects that have searched for new ways and 

developed new technologies to design more energy efficient buildings for a more sustainable future 

(Aelenei et al., 2018). The belief that “technology will save us” has been a clear trend in building 

engineering, but there has been a general disregard for the people who will use it. Even with the 

use of high technology solutions, in practice we may end up with the following scenarios: a building 

may be highly energy efficient but its users could be dissatisfied or because of users’ interference 

the building may not achieve the predicted levels of energy performance and we may end up with 

dissatisfied users anyway (Lazarova-Molnar & Mohamed, 2017).

Since the façade is the mediator between the exterior and interior environments, it could be said 

that its design is the key to shaping the whole performance of the building (Knaack et al., 2014). 

However, implementing high technology solutions to reduce energy consumption should not turn 

the façade into a barrier between the indoor and outdoor, which would create hermetically sealed 

spaces in which every physical aspect is regulated through HVAC systems (Addington, 2009). 

Instead, the façade needs to be carefully designed and integrated with the service systems, where 

smart technologies would be used as the tools to provide desired indoor environmental conditions 

in harmony with the users and to find an optimal energy efficient balance. In order to achieve 

that goal, a human-centred approach in façade design, rather than a technology centred focus, 

needs to be embraced.

The current applications of high performance buildings with smart building automation systems 

stress even further the need for such human-centred approach (Capeluto & Ochoa, 2017). These so-

called intelligent systems are creating new pathways for user interactions, where user expectations 

and user experiences are changing along with it (Kaasinen et al., 2013). Wigginton and Harris used 

the analogy of the human body’s neural system to explain their user-centred perspective on the 

topic, in which the somatic system that is responsible for the voluntary actions of the muscles that 

create movement is likened to the actions of the users in the building. Conversely, the autonomic 

system refers to the building’s intrinsic responsive envelope (Wigginton & Harris, 2002). This 

approach highlights the co-existent nature of users’ adaptive behaviours and the automated dynamic 

responses of the building systems.

A paradigm shift from occupants being passive subjects in a building to being active participants 

has begun by acknowledging the effects of occupant behaviour on the energy performance of the 

building (Yan & Hong, 2018). Although significant efforts are being made to better understand and 

simulate the adaptive behaviours of the users, the influencing factors behind these interactions 

and how these affect the user experience in the first place, are still quite theoretical (Heydarian et 

al., 2020). There needs to be further interdisciplinary studies investigating multi-domain exposure 

situations on users’ satisfaction and behaviour, humans’ perception of the built environment, and 

user-oriented design of the control interfaces, in order to achieve an occupant-centric building 

design approach (O’Brien et al., 2020).



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FIG. 1 Façade – User – Building relationships

There are many factors affecting and shaping users’ experience in a building (Figure 1). The feeling 

of comfort (or discomfort) brought about by the effects of the factors related to the indoor and/or 

outdoor environment, spatial conditions, as well as the individual parameters related to the user 

itself are the main elements that could be listed. It is not just the comfort-related satisfaction, but 

also the overall user sensation and perception that results in interactions with the building façade 

and/or service systems, that are important parts of the user experience in the indoor environment 

(Law et al., 2009). Considering the amount of time we spend inside, especially in work environments, 

several studies highlight the importance of users’ comfort and wellbeing on their health and 

productivity (Bluyssen, 2019; Fisk, 2000; Humphreys, 2005). 

Even though the façade is highly significant in shaping the indoor environment, there seems 

to be a lack of understanding about its effects on the overall user experience (Alavi et al., 2017).  

Even in low technology buildings, the façade is a system that users commonly engage with, by 

opening the windows, closing the window blinds, or simply by looking outside. It does not seem 

far-fetched to state that these interactions have a crucial effect on users’ experience, while they 

also create a gap between the predicted and achieved performance of the building (Masoso & 

Grobler, 2010). Such adaptive behaviours of users are one of the key factors that influences a 

building’s design, performance optimization, and energy simulation (Yan & Hong, 2018). In the 

case of adaptive façades, with their smart and dynamic automation systems, it could be said that 

interactions between the façade and the user become even more significant. From an engineering 

perspective, being able to change façade properties would enhance their performance –by providing 

dynamic responses to ever-changing external stimuli–, but this dynamic character may also 

enhance the effect of the façade on the user experience, hence, it may also potentially deepen the 

aforementioned performance gap. 

There is a limited number of studies focusing on adaptive façades, investigating the comfort and 

well-being of the users as they relate to their interactions. In a recent study, Luna-Navarro presents 

a classification scheme for different pathways in occupant façade interaction, which offers a deeper 

understanding of the conflicts and relationships between the user and intelligent control strategies 

in adaptive façades (Luna-Navarro et al., 2020). Another study on occupant-centric control strategies 

for adaptive façades discusses the implementations of adaptive comfort models and personalized 

control strategies to improve user satisfaction (Tabadkani et al., 2021). In addition, there are a few 

other research studies on post-occupancy evaluations and real-time occupant feedback in buildings 

with adaptive façades, demonstrating the influences of different physical factors on the feeling of 

comfort in users (Alavi et al., 2017; Attia et al., 2018; Bakker et al., 2014; Lassen et al., 2021; Luna-

Navarro et al., 2021).



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Acknowledging the contributions of such research towards reaching a human-centred adaptive 

façade, the influence of human factors on user behaviours and the indirect effects of interactions 

on the user experience still requires further investigation. Therefore, this paper (1) investigates 

how different factors affect the user experience in a working environment, (2) presents an overview 

of adaptive user behaviours with a human-centred approach, (3) distinguishes the façade - user 

relationship within the larger context, and (4) identifies the missing links towards reaching the full 

potential of adaptive façades. 

A holistic perspective is embraced in this study and the presented overview is built over the user 

experience concept, which covers all human senses, emotions, behaviours, and interactions with 

the façade and/or environment. With this focus, this paper aims to bring the scattered information 

in the literature from different fields of expertise like engineering, architecture and social sciences 

together, ensuring that not just the effects of the environmental factors but also the human factors 

on user experience are investigated. As a broader aim, the information provided in this paper offers a 

starting point towards developing a human-centred approach for adaptive façades.   

2 SCOPE AND METHOD OF RESEARCH

Research presented in this paper starts with an initial exploration of literature, which draws the 

context for further investigation. Exploratory research is conducted using Science Direct, Google 

Scholar, ITU and TU Delft Libraries, with the keywords: human-centred design, adaptive façade, user 

experience. Because of the lack of literature specifically focused on the façade and user relationship, 

the scope of the overview later widens to involve: human-centred design in various fields, façade 

technologies and applications (traditional or advanced), façade properties and performances in general 

(physical and energy related), user comfort, satisfaction, well-being, and related studies to improve 

indoor environment quality. After reading the titles, abstracts, keywords, and highlights of the papers 

collected in the initial exploration, the context of the detailed investigation is formulated. Figure 

2 below portrays the research boundaries around respective keywords and concepts, presents an 

outline of this paper, and draws the relationship of its sections. 

The users or the occupants are the main subjects of this overview. The scope of the study evolves 

around the user experience concept, which embraces a holistic approach to cover the users’ 

comfort, satisfaction, and well-being, as well as users’ emotions, behaviours, and interactions. 

The relationship between these concepts and their relevance to user experience are examined 

through studies of human-centred design, from different fields (social sciences, industrial 

design, environmental psychology, etc.). Although the main focus is on the adaptive façades and 

distinguishing its dynamic relationship with the users, since there is a scarcity of literature with 

this specific focus, studies related to user experience in indoor environments are investigated in 

general. Workplaces are chosen as the main domain of the research. In order to define a whole 

list of influencing factors, several agents of the indoor environment and adaptive façades are 

searched within the context of user experience. Thus, various studies evaluating users’ comfort 

during the occupancy stage, theoretical studies investigating different parameters affecting user’s 

satisfaction, studies regarding users’ adaptive behaviours and the motivations behind that, users’ 

effects on the energy performance of the building, studies investigating occupant-centric design and 

automation of the adaptive façade, and other relevant studies within its broader reach, formed part 

of the review process.



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FIG. 2 Scope and boundaries of the research

As for the structure of the paper, Section 3 presents background information on different approaches 

of human-centred design to establish the point of view of this research, and to describe the 

relationship between adaptive behaviour and user experience. Section 4 introduces the potentials 

of adaptive façades, presents a brief overview of their relationship with the users, identifying 

the missing links, demonstrating the perspective of the authors and relevance of the research. 

Section 5 is the main body of the paper, where the findings of the review process are presented 

in a systematic way and different factors affecting user experience in working environments 

are identified, through a mechanism of change. Lastly, Section 6 presents an overall discussion 

and highlights relevant issues that require further investigation for a human-centred approach 

for adaptive façades. 

3 HUMAN-CENTRED DESIGN

Human-centred (or centric) design is a concept which, over the years, has found application in 

various different fields, mainly in industrial design and software engineering (Hoffman et al., 2002). 

Different approaches to the concept in architecture and related behavioural theories that highlight a 

deeper understanding of the user experience are overviewed in this section. 

3.1 HUMAN-CENTRED DESIGN APPROACHES 

Norman describes human centred design as the process which ensures that the designs match the 

needs and capabilities of the people for whom they are intended (Norman, 1988). In other words, it 

is a philosophy that starts with understanding humans, to support the design of a useful, usable, 

pleasurable, and meaningful product/system (IDEO.org, 2015; Norman, 2013). 

Designing for the users has been a part of design thinking since early ages. The evolution of the 

concept has started with the consideration of the physical ergonomics of the users while engaging 

with the product/system (Verbeek & Slob, 2006). Later, this concept evolved into usability, which 

covers the effectiveness, efficiency, and satisfaction in a specified context of use (ISO 9241-210, 2010). 

Then, the consideration of emotions, behaviours, and users’ experiences became part of the approach, 

often referred to as interaction design in the literature (T. Zhang & Dong, 2008). Recent approaches 

aim to cover not just the present experiences but also the needs and aspirations of the future (van 



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der Bijl-Brouwer & Dorst, 2017). Designing with the users on the other hand, by means of involving 

them in the design process (participatory design and generative techniques) or asking for feedback 

regarding the design (human-computer interaction), could be traced back to the 1970s – 1980s 

(Damodaran, 1996; Maguire, 2001; Visser et al., 2005; Zoltowski et al., 2012). 

Sanders maps the different human-centred approaches in design practice and defines the designer’s 

mindset as two categories; expert or participatory (Sanders, 2008). Expert mindset refers to the case 

where users are seen as subjects and the design aims to achieve the best possible usability for 

them. Participatory mindset, on the other hand, refers to the case when users are seen as partners 

and are actively involved in the design process from the beginning (Abras et al., 2004). Involvement 

of the users in the design phase is a way of ensuring that the design would match their needs, but 

unfortunately, there are operational barriers (Chammas et al., 2015). Consequently, in the case of 

building design, engagement of the users mostly occurs only at the occupancy phase, in the form 

of post-occupancy evaluations with real-time occupant sensing and/or feedback technologies 

(Wagner et al., 2018).  

A collective perspective of the different approaches is offered by ISO 9241-210, where the 

human-centred design is defined as an approach to systems design and development that aims 

to make interactive systems more usable by focusing on the use of the system and applying human 

factors/ergonomics and usability knowledge and techniques (ISO 9241-210, 2010). Feedback and 

communication between the stakeholders (users and designers) are highlighted as the key to this 

approach. By acknowledging ISO’s definition of human-centred design and embracing an expert 

mindset, we are taking the user as the subject of this research. Hence, we start by investigating how 

users interact with and experience their surroundings, thereby aiming to translate and transfer the 

information learned from users to the designers. 

3.2 ADAPTIVE BEHAVIOUR AND USER EXPERIENCE RELATIONSHIP

The term experience is used to define the encounter of an event or occurrence and the takeaways 

from it. It could be a piece of knowledge, a skill or an impression, a feeling. In other words, experience 

defines how people remember their interactions (Norman, 2013). From a human centred point of view, 

any system that interacts in some way with its users should be designed with consideration given to 

users’ needs and capabilities. Therefore, in order to achieve the best user experience, it is crucial to 

understand the factors that shape the nature of such interactions and how these may differ from one 

individual to another. 

According to the stages of action model (Norman, 2013), an action (or behaviour) like opening 

a window is a goal-driven activity that could be triggered by various different physiological, 

psychological, or sociological factors. The activity starts by making the decision to take action, which 

is defined as the planning stage, followed by specifying the action and performing it by engaging 

with the window. The effects of the action will begin to show themselves, like creating changes in 

the air quality and temperature of the room. Then the user will perceive the new condition, interpret 

the reason behind it, compare it with the previous situation and make a decision to either close the 

window or keep it open. In this instance a data/event-driven activity occurs, which has surfaced as a 

result of the user’s emotions in the initial condition (Naqvi et al., 2006). In other words, the perception 

of the environment triggered the interaction with the surroundings, while at the same time the 

interaction created a change in the perception. 



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Even though Norman’s model defines a certain loop between perception and behaviour, it does not 

explain what exactly drives the behaviour itself. There are several other cognitive behaviour theories 

used in explaining occupant interactions with different building systems. From these theories, five 

commonly acknowledged models could be listed as: Theory of Reasoned Action - TRA, Theory of 

Planned Behaviour - TPB, Theory of Interpersonal Behaviour -TIB, Norm Activation Model – NAM 

and Value, Belief, Norm Theory – VBNT (Ajzen, 1991; Heydarian et al., 2020; Triandis, 1977), in which 

affect, attitude, social norms, perceived control, and habits are referred to as the main elements that 

create the intention of taking an action. Affect refers to what the organism feels, and defines the 

value, in other words, the quality of the experience. Interpretation of such feelings could be referred 

to as emotions that shape preferences for the future or moods for the present situation (Ortony et 

al., 2005). Along with the affect, different personal or social norms and individual beliefs are also 

related to the intention of a behaviour (Pee et al., 2008). The perceived control and individual’s attitude 

towards taking an action are other elements that generate behavioural motivations (Heydarian et 

al., 2020). In addition to these conscious behaviours, habit refers to a sequence of behaviour that has 

become an automatic response to specific cues in the environment (Verplanken & Aarts, 1999), which 

can be defined as an unconscious behaviour or an intentional one. 

All in all, a behaviour could surface because of a poor affect, with the intention to make it better and 

as a result, it will create an interaction to change the values of the experience. This phenomenon 

could also be explained with the concept of adaptive behaviour which is often referred to in the 

literature as follows: if a change occurs such as to produce discomfort, people react in ways that tend to 

restore their comfort (Nicol & Humphreys, 2002). Such comfort-driven behaviours are an important 

part of the user experience and simultaneously affect the overall energy performance of the building 

by creating unforeseen energy consumptions (Jia et al., 2017; Stern, 1992)

FIG. 3 The dynamic cycle of the user experience: the mechanism of change

Within the context of the built environment, users’ behaviours, in terms of interactions with the 

building’s service systems or façades, are significant elements of the user experience, which 

either (1) shape or (2) reflect upon the experience itself (Alavi et al., 2017). These behaviours 

may differ for each individual, due to their different physiological, psychological, or sociological 

conditions/backgrounds (Khalid, 2006). Therefore, understanding the mechanism of change is 

considered to be an important step towards defining how different factors affect the user experience 

in work environments.



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4 POTENTIALS OF ADAPTIVE FAÇADES

The previous section introduced the dynamic cycle of user experience over a mechanism of change 

(Figure 3). In the case of adaptive behaviours, users are the actors that trigger the mechanism of 

change. Influencers that affect the users’ behaviours may be related to human or environmental 

factors, which will be overviewed in the following section in relation to the user experience. Triggered 

by those factors in a case of discomfort, to achieve a more desired comfort condition, users can either 

choose to alter themselves, like changing their clothing level or the occupancy conditions, or they can 

alter their environmental conditions by interacting with the building’s façade and/or service systems 

(O’Brien & Gunay, 2014) (Figure 4). Adaptive façades with their smart automation systems have a 

similar mechanism of change, by creating an artificial response to certain impulses, which results in 

a change in the indoor environmental conditions.

FIG. 4 Relationship of factors indirectly affecting user experience

If we take a holistic approach to façade design, it could be said that today’s challenge is to find 

an energy efficient façade solution that would also create a positive user experience. To deal with 

that complexity, and with their changeability aspect, adaptive façades offer a unique opportunity. 

This research explores the hypothesis that there is a missing link (shown in red lines on Figure 4) 

between the human factor and the adaptive façade. The operation of the adaptive façade by means 

of automation should regard the human factors as agents, along with the environmental factors. 

Moreover, automation systems should be designed to co-exist with and learn from the users’ adaptive 

behaviours, and to consider the indirect effects on the user experience. If these gaps could be 

bridged, only then would adaptive façades reach their full potential.

Adaptive technologies have the potential to significantly reduce the energy use of the buildings 

(Perino & Serra, 2015) along with having a profound influence on user satisfaction ( Attia, 2017). 

The performance of the adaptive façade – in terms of comfort and energy – is highly dependent on 

its dynamic operation strategies (Favoino et al., 2018). The automation system is another actor like 

the user, which is used to manipulate the change in indoor environmental conditions, thus directly 

and/or indirectly altering the user experience. Therefore, design consideration of an adaptive façade 

system should consider the implementation of occupant-centric automation and integration with the 

operation of other building services systems, along with the functional requirements of the façade. 

Each adaptive façade technology (such as movable solar shading, switchable glazing, phase change 

materials, dynamic insulation, multifunctional façades …etc.) requires a unique consideration 

since they offer different ways of interaction with the user and may have different effects on users 

satisfaction and well-being ( Attia et al., 2019). In terms of a human-centred design approach to 



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adaptive technologies, existing studies and performance modelling approaches are limited to 

considering environmental factors as the main agent of change, thus missing the relationship with 

the human factors and user experience. 

Along this path, one of the key issues that needs to be investigated is the balance between 

automation and user control. Adaptive façades controlled by an intelligent automation system 

could be designed to predict a possible result of discomfort and act on behalf of the users to alter 

the indoor environmental conditions (Böke et al., 2020). However, there are also studies indicating 

that users are more satisfied, happier, and more productive when they are given at least a certain 

degree of control (Samani, 2015). This opens up the discussion on how much control should be left 

to the users considering the building’s energy performance. Educating the users and improving the 

response feedback mechanism would be the highlighted ways to deal with a possible performance 

gap between the predicted and actual energy consumption of the building (Al-Obaidi et al., 2017).

Another issue is the diversity of each user’s needs and preferences. There have been several studies 

aiming to model the reasoning behind users’ behaviours and simulate them in order to demonstrate 

the actual energy performance (Yan et al., 2015). However, it is quite impossible to predict how each 

user would react to a certain situation. From another perspective, despite the variety of each human 

factor and its endless combinations, by observing user’s behaviour under certain conditions, it 

could be possible to identify some user types (Ortiz, 2019), which requires a deeper understanding 

of the human factor and an interdisciplinary study that incorporates architecture, engineering, and 

social science. From an expert point of view, by identifying what are the key factors that affect the 

experience and how they show diversity, the level and type of adaptation that is needed for certain 

user types could be defined. Thus, this would be used as a starting point towards a human-centred 

adaptive façade design approach. 

From this perspective, which aims towards a human centred design approach, we are looking 

from the users’ point of view to understand what experiences that they expect from their façades. 

Identifying the complex and dynamic mechanisms of the user experience in an indoor environment 

(workspaces in the context of this paper) would be the first step. To that end, this research 

investigates how each factor affects the mechanism of change and portrays a better understanding 

of the triggers that make users take action. From there, it would be possible to (1) identify certain 

patterns in users’ adaptive behaviours that could be mimicked with the adaptive façades, (2) 

determine the effects of human factors and define certain expectancies of different user groups, 

(3) distinguish certain aspects of the façades that need to be variable in order to satisfy individual 

adaptive comfort needs. 

5 USER EXPERIENCE IN WORK ENVIRONMENTS

User experience is defined as a person’s perceptions and responses that result from the use or 

anticipated use of a product, system, or service (ISO 9241-210, 2010; Law et al., 2009). It is a concept 

that not only covers the past and present experiences but also those anticipated for the future. 

In the context of this paper, experience is used as a holistic term to cover all human senses and 

refers to any kind of emotion, perception, sensation over interaction, and any feeling of comfort, 

satisfaction, or well-being. 



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Although the façade is one of the main systems that shapes the indoor environment, there has been 

only a limited number of studies exploring how it affects users’ experiences. The ways in which users 

engage with their façade and experience it could be defined in two ways: active or passive. (1) Passive 

experience refers to the perception, for instance, of feeling the sunlight coming through the glazing 

or looking outside the window. (2) Active experience refers to interaction, for instance, opening the 

window because of feeling warm, closing the window blind to prevent glare. In other words, passive 

experience indicates a path for the direct effect of an influencer, while active experience draws an 

indirect path where certain behaviour is triggered.

Based on the review of the existing literature, the effects of different factors on the user experience, 

in a working environment, are identified. Figure 5 shows the relationship of the parameters from 

the findings of the review, which are systematically organized in a way to demonstrate the dynamics 

between the influencing factor, the mechanism that is triggered by it, the response that results in a 

change of the initial state, and how this whole cycle affects related user experiences (Figure 3).

Referring to the aforementioned mechanism of change, we classify the influencing factors under two 

main groups: human and environment. According to occupant behaviour studies, it could be said that 

it is not only physical factors of the environment, but also the individual factors for each user, that 

influence the experience in an indoor environment (Frontczak & Wargocki, 2011). As the elements 

that could be easily manipulated by the building design, the general tendency in the related research 

projects is to focus on the environmental factors. There are only a few studies that investigate the 

diversity of individual factors and their relationship with users’ adaptive behaviours (Hong et al., 

2017). Taking the human as the centre of focus, first of all, personal descriptors and needs that are 

different for each individual and which affect the experience are outlined. Environmental factors, 

on the other hand, are related to the surroundings of the user. On a building scale, these would be 

divided into three subcategories: external, internal, and spatial factors. 

FIG. 5 Relationship between the parameters within the mechanism of change

The main adaptive behaviours that users would take to alter their indoor environment, based 

on the common mentions within the existing literature as potential causes of unpredicted 

energy consumptions, could be listed as (1) opening/closing windows, (2) adjusting window blinds 

(shading elements), (3) adjusting HVAC systems (heating, cooling, ventilation units), (4) turning on/off 

lighting (Boerstra, 2016; Delzendeh et al., 2017; Nicol & Humphreys, 2002). In addition to these, in 

cases of discomfort, users may also choose to (5) adjust their clothing or upon arriving/departing the 

space (6) change their presence without engaging with their surroundings (Haldi & Robinson, 2008; 

Zhang et al., 2018). The main focus of this paper is on the experiences of the users that resulted 



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from their comfort-driven interactions with their façade and integrated service systems, thus the 

first four behaviours that require engagement with the windows, shading, HVAC, or lighting systems 

are investigated, in the context of a working environment. Each of these actions creates a reaction 

and alters at least one of the properties of the façade and/or the indoor environment. These could 

be respectively defined as the changes at (1) air exchange rate, level of (2) sunlight transmittance, 

value of (3) indoor temperature, (4) illumination level (Frontczak & Wargocki, 2011; Wagner et al., 

2018). The changed conditions that resulted from the adaptive behaviours indirectly affect the user 

experience, and thereby become an influencer once again.   

As mentioned before, within the context of this research, the user experience concept is issued from 

a holistic point of view that covers all human senses, emotions, behaviours and interactions with 

the façade and/or environment. It not only refers to a state of comfort or discomfort, but it is about 

the overall sense of satisfaction that occurs before, during, and after use (ISO 9241-210, 2010; Law 

et al., 2009). Therefore, from a human-centred point of view, this paper takes the human senses 

to its centre and classifies user experiences as seeing, feeling, hearing, and controlling. The aim 

is to broaden the commonly used visual, thermal, air quality, and acoustical comfort titles, and to 

investigate the indirect effects of comfort-driven adaptive behaviours on the user experience. With 

that perspective, seeing refers to any experience related to sight, issues regarding visual comfort and 

aesthetics are covered under this title. Feeling is used to cover the experiences related to the haptic 

and olfactory senses of the human. The factors that are mentioned in relation to the experience of 

feeling show a similar mechanism of change and are related to the thermal comfort and indoor air 

quality collectively, and therefore could not be separated. Hearing refers to the audial experiences and 

is related to acoustical comfort. Controlling is added since the main focus of this study is adaptive 

façades and it refers to the anticipation of control during user interaction and its psychological 

effect on user experience. In addition to these, the overall experience title is also used, referring to 

the factors that may not have a direct effect on a specific sense, but still found to be in relation to a 

general positive sensation of the human being.  

Based on the above-mentioned classification, collected and interpreted information from the 

literature on how each human or environmental factor triggers each comfort-driven adaptive 

behaviour, which in turn creates a change in the environment that affects user experience, (Figure 5), 

are systematically presented in this section over the defined mechanism of change.

5.1 HUMAN FACTORS

Each person by nature has their own unique traits. These are not just physiological factors, but also 

psychological, social, cultural, economic, or other contextual factors that show diversity among each 

individual. These different characteristics alter a person’s needs, habits, aspirations and influence 

his/her experience (Khalid, 2006). These human factors are grouped as personal descriptors and 

needs. A holistic approach to how each human factor triggers an adaptive behaviour and alters 

the experience in a working environment is found to be lacking in the literature. Therefore, an 

attempt to gather the existing but scattered information from the literature is made and presented 

in detail in this section. Table 1 below presents the relationship of each factor with each adaptive 

behaviour and user experience



 040 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

TABLE 1 The human factors that affect user experience in a mechanism of change

IMPULSE
(Influencer / Agent)

MECHANISM
(Action / Behaviour)

RESPONSE
(Effect / Change)

RELATED EXPERIENCE

HUMAN 
FACTORS

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Personal 
Descriptors

Age + - + - + - + - + + - + o

Gender + - o - + - + - + + - o +

Country of Origin - - o o - - o o o + + o +

EducationLevel o - o o o - o o o + - + +

Type of Job + + + + + + + + + + o + +

Socio-personal traits + + + o + + + + + + o + o

Personal Needs Security + o - - o o o o o o - + +

Privacy - + - - - o - o + o + o o

Hygiene o - - - o - o - o o - - +

View - + - o - + - + + o - o +

(+) Direct mention in the literature, (o) Interpreted from the literature, (-) Not mentioned in the literature

5.1.1 Personal Descriptors

The factors mentioned in this category refer to the characteristic features of an individual, which 

may be quantifiable tangible conditions or identifiable intangible aspects of the users. 

Age 

Age is mentioned as one of the physiological factors that have an impact on the users’ comfort 

requirements and mainly on the thermal comfort perceived by the occupants (Al horr et al., 2016; 

D’Oca et al., 2016; Fanger, 1970). Frontczak & Wargocki, in their research, portray how individual 

characteristics influence satisfaction with indoor environmental quality, and age is associated with 

subjective air quality, visual satisfaction, and adverse perception (Frontczak & Wargocki, 2011). 

In another study that identifies the influencing factors on occupants’ energy related behaviours, age 

is listed as one of the social and personal parameters (Delzendeh et al., 2017). In terms of adaptive 

behaviours, window opening behaviour (Fabi et al. 2012; Zhang et al. 2018), heating thermostat 

adjustment (Deme Belafi et al., 2018), and in general the need for personal control (Boerstra, 2016) 

are affected by the age factor.

Gender 

Another frequently mentioned physiological factor that influences thermal satisfaction and the 

overall comfort perception of the users is gender (Al horr et al., 2016; Boerstra, 2016; D’Oca et al., 



 041 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

2016; Day & Gunderson, 2015). It is an acknowledged fact in the field that in general, due to different 

body compositions, thermal preference and satisfactory set temperature for a female and a male 

differ from each other (Delzendeh et al., 2017; Fanger, 1970; Huizenga et al., 2006). In the case of 

discomfort, altering clothing (Holopainen et al., 2014) could be the initial act followed by heating 

thermostat adjustment (Deme Belafi et al., 2018), opening or closing the windows (Fabi et al., 2012; 

Zhang et al., 2018) or interfering with the HVAC system to alter the intensity of airflow (Fountain et 

al., 1996). Along with thermal sensation, Frontczak & Wargocki also mention gender as influencing 

the satisfaction with air quality and the visual satisfaction along with general preference on indoor 

environmental conditions (Frontczak & Wargocki, 2011).  

Country of Origin 

Country of origin is listed as another human factor that has both physical and socio-economic 

aspects. First of all, due to racial features and/or accustomed climatic conditions, users may have 

different means of thermal comfort (Al horr et al., 2016). In addition, the expectation of thermal 

conditions would also vary from country to country due to cultural differences and defined local 

standards, which would result in different experiences in terms of feeling (Day & Gunderson, 2015). 

As a result of various customs and habits, individuals’ acoustical dissatisfaction and any overall 

adverse perceptions would also show diversity (Frontczak & Wargocki, 2011). Lastly, in terms of 

adaptive behaviour, cultural norms are mentioned as an influence on the use of electrical systems 

(O’Brien & Gunay, 2014).

Education Level 

The level of education is mentioned in relation to the user’s knowledge and awareness. As a socio-

personal factor, education affects users’ attitudes, motivations, and behaviours in their working 

environment (Delzendeh et al., 2017). Although it is not possible to define a direct correlation, 

users with different levels of education have a different perception of thermal comfort, air quality, 

and overall satisfaction (Frontczak & Wargocki, 2011). Day & Gunderson states that to minimize 

energy consumption, especially in high-performance buildings, training and education have a crucial 

effect (Day & Gunderson, 2015). Informing users on how to control the façade and service systems, 

and in which way their actions would affect the energy performance of the , greatly influence 

adaptive behaviours such as opening/closing windows, adjusting HVAC units, and turning on/off 

lighting (Yan & Hong, 2018). 

Type of Job

Type of job is one of the most comprehensive factors that covers dress codes and activity levels, 

working hours, time pressure and stress levels, relationship with colleagues, relationship with 

employees/employers, and overall contentment with the job. According to Frontczak & Wargocki 

different factors related to different professions, defining a variety of needs and influencing 

the perception of thermal comfort, visual comfort, and air quality, as well as overall satisfaction 

(Frontczak & Wargocki, 2011). Job satisfaction in general is shown to have a significant effect on 

work performance, productivity, and psychological well-being (Samani, 2015). Depending on the job 

description, the required level of activity would define a metabolic rate and clearly have an influence 

on the thermal comfort parameters (Delzendeh et al., 2017; Haldi & Robinson, 2008; Holopainen 



 042 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

et al., 2014; Nicol & Humphreys, 2002). Another influencing factor in terms of thermal satisfaction 

is clothing (Al horr et al., 2016; Day & Gunderson, 2015). The level of clothing could be defined by 

a dress code for certain professions or it could be a parameter that is for users to alter and adapt 

(Fanger, 1970; Huizenga et al., 2006). In any case, clothing could be mentioned as one of the factors 

that influences users to take adaptive actions in order to control the indoor temperature (Fountain 

et al., 1996). In addition to these, working routine and arrival and departure patterns are found to 

be important motivational factors for adaptive behaviours (D’Oca et al., 2016). Opening the windows 

on arrival to the office and closing them upon departure is a common habit (O’Brien & Gunay, 2014). 

Adjusting the window blinds, turning on/off heating and lighting are other actions that are consistent 

with the working schedule (Deme Belafi et al., 2018; Wagner et al., 2018). Moreover, these could 

be listed as some of the main occupant behaviours that create the gap in the predicted and actual 

energy performance of the buildings (Masoso & Grobler, 2010).

Socio-Personal Traits 

The main intangible factors that show diversity among the users and influence behaviours in various 

different ways are grouped under the title socio-personal traits. There are several behavioural 

models that try to portray the intentions and motivations of users’ adaptive behaviours based on 

their personal and social properties (Deme Belafi et al., 2018). Personal factors could be listed as 

individual traits, beliefs, and attitudes which are the reflections of one’s character (Fabi et al., 2012). 

A study investigating the influence of personality traits on occupant behaviour shows how the Big 

Five Personality Traits influence the behaviours associated with window opening, adjusting blinds, 

fans, or clothing, in addition to how thermal sensation and preference are affected (Schweiker et 

al., 2016; Wagner et al., 2018). Briefly, it states that people with high neuroticism traits tend to stick 

to the actions that they know and are able to control more, like clothing adjustments or operating 

windows. On the other hand, the extraversion trait could define a person who may very likely act 

quickly against any discomfort. Similarly, people with a high degree of openness to experience would 

be more open to changes, and hence feel less need to engage in adaptive behaviour. In other words, 

depending on their level of willingness to take action, a person could be defined as more active or 

passive (D’Oca et al., 2016). Apart from the personal profiles, social parameters could also be highly 

influential as a behavioural motivation (Zhang et al., 2018). Social constraints, norms, and pressure in 

a shared office are some of the most effective factors in terms of energy awareness and influence the 

adaptive behaviours related to energy usage (Day & Gunderson, 2015; Wagner et al., 2018). Besides, 

one’s cultural belonging or certain lifestyle is another factor that affects human cognition and would 

alter the user behaviour (Delzendeh et al., 2017). All in all, perception and preference of comfort are 

highly interrelated with the socio-personal traits, thus these factors are significant influencers on 

the user experience. 

5.1.2 Personal Needs

The factors mentioned in this category cover the main psychological elements in terms of users’ 

needs and stressors that affect users in positive or negative ways. 



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Security

The need for security is a factor that influences the experience both directly and indirectly. According 

to Vischer, health and safety are part of the physical comfort parameters that are the first step of the 

habitability pyramid (Vischer, 2007). Additionally, the feeling of safety and security is a significant 

psychological factor that affects the indoor environmental satisfaction of the users (Russell et al., 

2013; Zagreus et al., 2004). In terms of adaptive behaviours, in residential or working places, the act 

of window opening and closing is influenced by the means of providing security (O’Brien & Gunay, 

2014; Roulet et al., 2006). To indicate whether someone is outside, adjusting window blinds could also 

be another adaptive behaviour that is influenced by the feeling of security (Deme Belafi et al., 2018).

Privacy

The need for privacy is another psychological factor (like security) that both directly and indirectly 

affects users’ experience in a working environment (Vischer, 2007). The need for privacy applies 

to both visual and acoustical environments (Kim & de Dear, 2012). Especially for open-plan 

offices, communication privacy is an important parameter that affects the level of satisfaction and 

productivity in the physical work environment (Al horr et al., 2016; Samani, 2015). For visual privacy, 

controlling the shading elements could be listed as the main influenced adaptive user behaviour, 

which applies to homes as well as offices (Deme Belafi et al., 2018; Lee et al., 2013).

Hygiene

The need for hygiene is one of the basic human needs as a part of physical comfort (Vischer, 2007). 

Cleanliness of the working space and maintenance of the building directly influence occupants’ level 

of satisfaction and productivity in the work environment (Huizenga et al., 2006; Kim & de Dear, 2012; 

Roulet et al., 2006; Samani, 2015; Zagreus et al., 2004). Although there is no mention in the literature 

about it triggering an adaptive behaviour, by means of protecting the indoor environment it may be 

interpreted that there is an indirect effect on the window closing action. 

View

The need for a view is mentioned in relation to outside view, visual quality, and aesthetic appearance, 

which would influence the level of satisfaction with the working environment (Samani, 2015). 

Architectural features of the space, colours, textures, materials, and components affect the sense of 

aesthetics and positively influence the seeing experience (Delzendeh et al., 2017). In addition, view 

out is one of the significant factors that affects visual comfort. Lack of view to outside may cause 

eye tiredness (Day & Gunderson, 2015), but having a pleasant view like a green landscape positively 

influences the overall satisfaction (Kim & de Dear, 2012). After sunlight levels, quality of view is 

the next main factor that triggers the window blind controls (Bakker et al., 2014; Kwon et al., 2019; 

O’Brien & Gunay, 2014; Vischer, 2007; Wagner et al., 2018).



 044 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

5.2 ENVIRONMENTAL FACTORS 

Apart from the human factors, the conditions of the environment surrounding the users directly 

affect their comfort, both physically and psychologically (Vischer, 2007). As the barrier between 

the exterior and interior environments, façades undertake multiple functions with the main goal 

of providing a comfortable indoor environment (Klein, 2013). Therefore, its design is surfaced 

with regard to external conditions and it is the main element that shapes the internal conditions. 

Besides, other design characteristics related to the functionality of the building, referred to as 

spatial conditions, would also be factors that affect users’ comfort in their environment. Effects 

of environmental factors on users’ comfort and behaviours are a more commonly studied aspect, 

therefore the information presented in this section is a brief mention within the context of the 

mechanism of change. Table 2 below represents the relationship of each factor with each adaptive 

behaviour and user experience.

5.2.1 External Factors

The factors mentioned in this category are the main climate-related factors that depend on the 

geographic location and show variety for each season, time of year, or time of day.

Outdoor Temperature

Outdoor temperature is one of the main factors that affects thermal comfort. In different seasons, it 

influences the window opening/closing behaviours of the users, as well as the adjustment of window 

blinds and heating/cooling units (Al horr et al., 2016; Bakker et al., 2014; Brager et al., 2004; Buso 

et al., 2015; Day & Gunderson, 2015; Delzendeh et al., 2017; Fabi et al., 2012; Frontczak & Wargocki, 

2011; Haldi & Robinson, 2008; Wagner et al., 2018;  Zhang et al., 2018)

Solar Access

Solar access, depending on the orientation of the building, is one of the main factors that affects 

visual comfort. Along with the time of the day, the intensity of the daylight and sky conditions are 

mainly effective on the shading elements opening/closing behaviours of the users and turning on/off 

artificial lighting. Besides, the effect of sunlight may cause overheating which is related to thermal 

comfort. In terms of temperature adjustment, closing window blinds or altering the HVAC systems 

could also be listed as other influenced adaptive actions (Day & Gunderson, 2015; Delzendeh et al., 

2017; Fabi et al., 2012; Huizenga et al., 2006; Wagner et al., 2018; Zhang et al., 2018).



 045 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

TABLE 2 The environmental factors that affect user experience in a mechanism of change

IMPULSE
(Influencer / Agent)

MECHANISM
(Action / Behaviour)

RESPONSE
(Effect / Change)

RELATED EXPERIENCE

ENVIRONMENTAL FACTORS

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External Factors Outdoor Temperature + + o - + + + o o + - + o

Solar Access + + o + + + + + + + - + o

Wind/Rain + - - - + - + - - + - o o

Relative Humidity + - o - + - + - - + - o o

Outdoor  Noise Level o - - - o - o - - - + o +

Internal Factors Indoor Temperature + + + - + + + o o + - + +

Lighting Conditions o + - + o + o + + o - + +

Air quality + - o - + - o - - + - o +

Relative Humidity + - O - + - o - - + - o +

Indoor Noise Level o o o - o o o o - - + o +

Spatial Factors Building Function + + + + + + + + o o o o +

Building Layout + + o o + + + + + + + o o

Façade Characteristics + + o o + + + + + + o + o

Service Systems o o + + o o + + + + o + +

(+) Direct mention in the literature, (o) Interpreted from the literature, (-) Not mentioned in the literature

Wind and Rain

Wind and rain conditions are listed together as factors that affect the window opening/closing 

behaviours of the users. Due to their effect, it results in changes in the indoor air quality and it 

also affects thermal comfort (Delzendeh et al., 2017; Fabi et al., 2012; Haldi & Robinson, 2008; 

Zhang et al., 2018).

Relative Humidity

The outdoor relative humidity is linked with thermal comfort and indoor air quality, in relation to the 

window opening behaviour and if there is an active ventilation system, by means of adjusting its air 

flow (Al horr et al., 2016; Delzendeh et al., 2017; Deme Belafi et al., 2018;  Zhang et al., 2018).

Outdoor Noise Levels

Outdoor noise levels have a direct effect on acoustical comfort, and the resulting hearing experience, 

and they are also mentioned as one of the factors that influence window closing behaviour (Day & 

Gunderson, 2015; Haldi & Robinson, 2008; Roulet et al., 2006; Vischer, 2007)



 046 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

5.2.2 Internal Factors

The factors mentioned in this category are the main quantifiable/measurable conditions of 

the indoor environment.

Indoor Temperature

Indoor temperature is one of the main factors that affects thermal comfort. Its effects could be 

investigated under two main sub-categories: mean radiant temperature and temperature variability 

created by the air movement, in other words, draught (Frontczak & Wargocki, 2011). Due to different 

needs, it influences the window opening/closing behaviours of the users as well as the adjustment of 

window blinds and heating/cooling units (Al horr et al., 2016; Bakker et al., 2014; Boerstra et al., 2012; 

Boerstra, 2016; Bordass et al., 1993; Brager et al., 2004; D’Oca et al., 2016; Day & Gunderson, 2015; 

Delzendeh et al., 2017; Deme Belafi et al., 2018; Fabi et al., 2012; Fanger, 1970; Frontczak & Wargocki, 

2011; Haldi & Robinson, 2008; Holopainen et al., 2014; Huizenga et al., 2006; Kim & de Dear, 2012; 

Kwon et al., 2019; Nicol & Humphreys, 2002; O’Brien & Gunay, 2014; Roulet et al., 2006; Samani, 2015; 

Wagner, 2018; Zagreus et al., 2004; Zhang et al., 2018) 

Lighting Conditions

Lighting conditions are the primary indicator of visual comfort. It covers the level of illumination 

within the space, homogeneity of the brightness, and formation of glare. It is affected by the external 

conditions, mainly solar access, and regulated initially by adjusting the window blinds and later by 

means of artificial lighting. In relation to the outside view and sunlight’s overheating capability, it is 

linked with the window opening behaviour as well as the adjustment of window blinds (Bakker et al., 

2014; Boerstra et al., 2012; Boerstra, 2016; Bordass et al., 1993; D’Oca et al., 2016; Day & Gunderson, 

2015; Delzendeh et al., 2017; Deme Belafi et al., 2018; Fabi et al., 2012; Kim & de Dear, 2012; Kwon et 

al., 2019; O’Brien & Gunay, 2014; Roulet et al., 2006; Samani, 2015; Vischer, 2007; Wagner, 2018).

Air Quality

Indoor air quality refers to the CO
2
 concentration of the air, odours, and air composition as in the 

content of dust/electrical particles/microorganisms. It is related to the feeling experience and 

affects the window opening/closing behaviours of the users (Bakker et al., 2014; Boerstra et al., 

2012;  Boerstra, 2016; Bordass et al., 1993; D’Oca et al., 2016; Deme Belafi et al., 2018; Fabi et al., 2012; 

Fanger, 1970; Haldi & Robinson, 2008; Huizenga et al., 2006; Kim & de Dear, 2012; Kwon et al., 2019; 

Roulet et al., 2006; Samani, 2015; Zagreus et al., 2004; Zhang et al., 2018).

Relative Humidity

The indoor relative humidity, similarly to the external conditions, influences thermal comfort and 

indoor air quality, in relation to the window opening behaviour and if there is an active ventilation 

system, by means of adjusting its air flow (Al horr et al., 2016; Day & Gunderson, 2015; Deme Belafi 

et al., 2018; Holopainen et al., 2014; Huizenga et al., 2006; Kwon et al., 2019; Roulet et al., 2006; 

Zhang et al., 2018).



 047 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

Indoor Noise Levels

Indoor noise levels is one of the main factors that creates discomfort in a working environment. 

It directly affects acoustical comfort. Depending on the source of the noise - if it is from the outside 

it impacts window closing behaviour, and if it is an operational sound interfering the window blinds 

and/or HVAC systems, operations would be influenced (Boerstra, 2016; Day & Gunderson, 2015; Kim & 

de Dear, 2012; Roulet et al., 2006; Samani, 2015; Vischer, 2007; Zagreus et al., 2004). 

5.2.3 Spatial Factors

The factors mentioned in this category are the properties related to the design of the 

space and its function.

Building Function 

The function of the building is one of the main factors that defines the user requirements. It defines 

the function of the space and its spatial needs for comfortable usage. Therefore, it  influences all 

adaptive behaviours in various ways and could be linked with all the user experiences (Al horr et 

al., 2016; Boerstra, 2016; Brager et al., 2004; Delzendeh et al., 2017; Frontczak & Wargocki, 2011; 

Huizenga et al., 2006; Kwon et al., 2019; Nicol & Humphreys, 2002; Roulet et al., 2006; Samani, 2015; 

Vischer, 2007; Wagner, 2018). 

Building Layout

Building layout is the other factor that covers a wide range of design aspects like private or open-

plan working environments, area of workspace per person, and position of each user within the 

space. It may affect all experiences in terms of seeing, feeling, and hearing. Users’ interactions with 

their façade vary due to their distance from it, hence building layout is listed as one of the influential 

factors for opening/closing windows and adjusting shading elements behaviours (Kwon et al., 2019; 

Luna-Navarro et al., 2021). In addition to that, as was also mentioned under the socio-personal traits, 

being in a private or shared office may alter ones adaptive behaviours by creating social pressure 

(Bakker et al., 2014; Boerstra, 2016; Brager et al., 2004; Buso et al., 2015; D’Oca et al., 2016; Day & 

Gunderson, 2015; Delzendeh et al., 2017; Fabi et al., 2012; Huizenga et al., 2006; Kim & de Dear, 2012; 

O’Brien & Gunay, 2014; Roulet et al., 2006; Samani, 2015; Vischer, 2007; Wagner, 2018; Zagreus et al., 

2004; Zhang et al., 2018). 

Façade Characteristics

Façade characteristics refer to window size and position, wall to window ratio, mass, robust or 

dynamic character, and other design aspects of the façade. In the case of adaptive façades, it is 

clearly a factor that influences the controlling experience of the users (Tabadkani et al., 2021). 

The level of manual or automated control of the openings and shading units influence the level of 

user interactions and along with that effect the visual and thermal comfort of the occupant (Bakker et 

al., 2014; Buso et al., 2015; Fabi et al., 2012; Kwon et al., 2019; Vischer, 2007; Zhang et al., 2018). 



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Service Systems

Service systems refer to the active, mechanical units of the building, which have a great influence 

on shaping the indoor environment. Their design is outside the context of this paper; however, 

their control and feedback mechanisms can be mentioned as one of the factors that influences the 

controlling experience of the users (O’Brien et al., 2020). Alterations made by engaging with the HVAC 

systems or lighting element can also affect the visual, thermal, and overall comfort of the occupant 

(Brager et al., 2004; Buso et al., 2015; Delzendeh et al., 2017; Fountain et al., 1996; Huizenga et al., 

2006; Kwon et al., 2019; Nicol & Humphreys, 2002; Wagner, 2018; Zhang et al., 2018). 

6 DISCUSSION 

In the previous section, an overview of the factors that affect user experience is systematically 

presented over the mechanism of change. According to the findings, it could be said that the 

most affected experience by the human factors is feeling. There is a direct effect, mainly related 

to the perception of thermal comfort, and an indirect effect as a result of being triggered by users’ 

interactions. Among these, the most commonly investigated adaptive behaviour is found to be 

opening/closing windows, followed by adjusting HVAC. Both of these actions are in relation to the 

changes in the air exchange rate and/or indoor temperature, hence associated with the feeling 

experience. Other commonly affected experiences are seeing and controlling. Related to these 

experiences, the indirect effect of adjusting window blind behaviour needs to be further investigated, 

in terms of user-façade interactions. From the listed human factors, type of job and socio personal 

traits covered a wide range of factors, therefore it was an expected outcome to see that these titles 

are in relation to all the listed adaptive behaviours and experiences. Even though, with a holistic 

perspective, it was possible to gather information regarding the influences of human factors on user 

experience, the number of studies with this focus is limited and research targeted on the experience 

was found to be especially scarce. 

As for the environmental factors, there was more research in the literature investigating direct or 

indirect effects on user experience. From the listed external factors, solar access is found to be the 

most influential one that could trigger all the issued adaptive behaviours. It directly and indirectly 

affects the seeing and feeling experience, and, related to the mechanism of change, could also be 

associated with the controlling experience. It is followed by the outdoor temperature, and from the 

internal factors, indoor temperature. From the listed spatial factors, the function of the building shows 

a clear relationship with all the adaptive behaviours and is related with the overall experience. 

However, based on the existing literature, it is difficult to define a direct effect caused by the 

building’s function on each experience. On the other hand, studies show direct and indirect effects 

of building layout on seeing, feeling, and hearing experiences. By looking at the results of the review, 

studies investigating the effects of the environmental factors in relation to hearing experience seems 

to be lacking. Considering the fact that outside or inside sound levels are indicated as some of the 

main causes for discomfort, the indirect effects of these factors in relation to the mechanism of 

change need to be explored in a deeper way. Besides, controlling experience requires a more targeted 

study, where indirect effects on the experience would be investigated when the façade systems are 

fully or partially left to the users’ control or fully automated. In addition to that, façade and service 

systems characteristics needs to be further explored in terms of their direct effects on each user 

experience. As a final remark on the review, the collective effect of different parameters is another 

issue that needs to be further investigated in terms of user experience. 



 049 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

The presented overview shows that the adaptive mechanisms related to the façade, like opening/

closing windows and adjusting window blinds, are highly influenced by human factors. It could be 

said that the users’ intention behind adaptive behaviours is the reflection of their adaptive comfort 

needs and adaptive control expectations. A similar outcome could be drawn for the behaviours 

related to the building service systems. Each adaptive behaviour is performed to overcome a certain 

discomfort and/or to enhance the user experience. Therefore, users’ adaptive actions reflect their 

way of thinking. With a human centred approach, if the adaptive façades are to be designed in 

harmony with its users, users’ anticipations of their indoor environment, as they relate to their 

experiences, require further research. Transferring this information from the occupancy to the 

design stage is crucial for developing occupant-centric control and operation systems, predicting the 

building’s energy consumption, and enhancing users’ positive interactions with their surroundings, 

with the ultimate aim of reaching the full potentials of the adaptive façades. 

7 CONCLUSION

An overview of human-centred design and user experience in the context of working environments 

is presented in this paper. With a holistic perspective, all of the factors affecting users’ experience are 

investigated through a literature review process. A mechanism of change is defined to explain the 

dynamic cycle of the user experience with respect to users’ interactions with the building façade and 

service systems. According to the findings, factors that trigger a change mechanism by influencing 

an adaptive user behaviour are identified and categorized under two main groups: human and 

environmental factors. 

Human factors are divided into two sub-groups: (1) age, gender, country of origin, education level, 

type of job, and socio-personal traits as personal descriptors; (2) security, privacy, hygiene, and view as 

personal needs. Environmental factors are divided into three sub-groups: (1) outdoor temperature, 

solar access, wind/rain, relative humidity, and outdoor noise level as external factors, (2) indoor 

temperature, lighting conditions, air quality, relative humidity, and indoor noise level as internal 

factors, (3) building function, building layout, façade characteristics, and service systems as spatial 

factors. The main adaptive behaviours are identified as (1) opening/closing windows, (2) adjusting 

window blinds (shading elements), (3) adjusting HVAC systems, (4) turning on/off lighting, and 

the change effects that these actions would result in are listed as (1) air exchange rate, level of 

(2) light transmittance, value of (3) indoor temperature, and (4) illumination level. Through these 

impulse, mechanism, and response relationships, the direct or indirect effects of each factor on user 

experiences are distinguished. Where the user experiences are defined as seeing, feeling, hearing, and 

controlling, they are therefore not only focused on the concept of comfort but also cover all human 

senses, emotions, behaviours, and interactions. 

Based on the outcomes, in the simplest terms, it could be said that every user has different needs, 

perceptions, and thus, different behaviours. With a human-centred point of view, adaptive façades 

with their changeability feature, offer great potential to deal with these diverse needs and to keep 

the indoor environment in its preferred condition with a reduced level of energy consumption. 

An understanding of the users’ relationships with the façade is essential in creating an ideal way 

of interaction, thus improving the user experience. In order to achieve that goal, the relationship 

between the human factor, as an agent of change, and automation systems of the adaptive façades, 

as the actor in the mechanism of change, is pointed out as the missing link. Therefore, relevant 

issues and further research areas towards a human-centred adaptive façade design approach 



 050 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

are introduced. The information presented in this paper could serve researchers in the field as a 

starting point, and show façade designers the adaptive nature of the users, hence transferring the 

knowledge on the dynamics of occupancy to the design phase. 

Acknowledgments
Presented study is a part of Mine Koyaz’s ongoing PhD Thesis, currently named as "Human Centred Adaptive Facades", at 
Construction Sciences Program, Istanbul Technical University. Research presented in this paper is carried during and after 
her visit at Architectural Engineering and Technology Department, Delft University of Technology as a Guest Researcher. The 
scholarship support from Istanbul Bilgi University for this visit is also acknowledged.  

References
Abras, C., Maloney-Krichmar, D., & Preece, J. (2004). User-centred design. Bainbridge, W. Encyclopedia of Human-Computer 

Interaction. https://doi.org/10.1045/january2005-editorial
Addington, M. (2009). Contingent Behaviours. Architectural Design, 79(3), 12–17. https://doi.org/10.1002/ad.882
Aelenei, L., Aelenei, D., Romano, R., Mazzucchelli, E. S., Brzezicki, M., & Rico-Martinez, J. M. (Eds.). (2018). Case Studies – Adaptive 

Façade Network. In COST Action TU 1403 Adaptive Façade Network. Tu Delft Open.
Ajzen, I. (1991). The Theory of Planned Behaviour. ORGANIZATIONAL BEHAVIOUR AND HUMAN DECISION PROCESSES, 50, 179–211. 

https://doi.org/10.1922/CDH_2120VandenBroucke08
Al-Obaidi, K. M., Azzam Ismail, M., Hussein, H., & Abdul Rahman, A. M. (2017). Biomimetic building skins: An adaptive approach. 

Renewable and Sustainable Energy Reviews, 79(May), 1472–1491. https://doi.org/10.1016/j.rser.2017.05.028
Al horr, Y., Arif, M., Katafygiotou, M., Mazroei, A., Kaushik, A., & Elsarrag, E. (2016). Impact of indoor environmental quality on 

occupant well-being and comfort: A review of the literature. International Journal of Sustainable Built Environment, 5(1), 1–11. 
https://doi.org/10.1016/j.ijsbe.2016.03.006

Alavi, H. S., Verma, H., Papinutto, M., & Lalanne, D. (2017). Comfort: A coordinate of user experience in interactive built 
environments. Lecture Notes in Computer Science (Including Subseries Lecture Notes in Artificial Intelligence and Lecture Notes 
in Bioinformatics), 10515 LNCS, 247–257. https://doi.org/10.1007/978-3-319-67687-6_16

Attia, S., Garat, S., & Cools, M. (2019). Development and validation of a survey for well-being and interaction assessment by 
occupants in office buildings with adaptive façades. Building and Environment, 157(April), 268–276. https://doi.org/10.1016/j.
buildenv.2019.04.054

Attia, S. (2017). Evaluation of Adaptive Façades: The case study of Al Bahr Towers in UAE - Essay UK Free Essay Database. 
QScience Proceedings. http://www.essay.uk.com/essays/architecture/evaluation-adaptive-façades/

Attia, S., Luna-Navarro, A., Juaristi, M., Monge-Barrio, A., Gosztonyi, S., & Al-Doughmi, Z. (2018). Post-Occupancy Evaluation for 
Adaptive Façades. Journal of Façade Design & Engineering Volume, 6(3), 1–9. https://doi.org/10.7480/jfde.2018.3.2464

Bakker, L. G., Hoes-van Oeffelen, E. C. M., Loonen, R. C. G. M., & Hensen, J. L. M. (2014). User satisfaction and interaction with auto-
mated dynamic façades: A pilot study. Building and Environment, 78, 44–52. https://doi.org/10.1016/j.buildenv.2014.04.007

Bluyssen, P. M. (2019). Towards an integrated analysis of the indoor environmental factors and its effects on occupants. Intelligent 
Buildings International, 0(0), 1–9. https://doi.org/10.1080/17508975.2019.1599318

Boerstra, A., Beuker, T., Loomans, M., & Hensen, J. (2012). Impact of perceived control on comfort and health in European office 
buildings. 10th International Conference on Healthy Buildings 2012, 1(April), 370–375.

Boerstra, A. C. (2016). Personal Control over Indoor Climate in Offices: Impact on Comfort, Health and Productivity.
Böke, J., Knaack, U., & Hemmerling, M. (2020). Automated adaptive façade functions in practice - Case studies on office buildings. 

Automation in Construction, 113(February), 103113. https://doi.org/10.1016/j.autcon.2020.103113
Bordass, B., Bromley, K., & Leaman, A. (1993). User and Occupant Controls in Office Buildings. February.
Brager, G. S., Paliaga, G., & de Dear, R. (2004). Operable Windows, Personal Control, and Occupant Comfort (RP-1161). ASHRAE 

Transactions, 110(December 2015), 17–35.
Buso, T., Fabi, V., Andersen, R. K., & Corgnati, S. P. (2015). Occupant behaviour and robustness of building design. Building and 

Environment, 94, 694–703. https://doi.org/10.1016/j.buildenv.2015.11.003
Capeluto, G., & Ochoa, C. E. (2017). Intelligent Envelopes for High-Performance Buildings. Springer International Publishing. https://

doi.org/10.1007/978-3-319-39255-4
Chammas, A., Quaresma, M., & Mont’Alvão, C. (2015). A Closer Look on the User Centred Design. Procedia Manufacturing, 3(Ahfe), 

5397–5404. https://doi.org/10.1016/j.promfg.2015.07.656
D’Oca, S., Corgnati, S., Pisello, A. L., & Hong, T. (2016). Introduction to an occupant behaviour motivation survey framework. Clima 

2016, February. http://datos.bancomundial.org/indicador/SL.TLF.CACT.FE.ZS
Damodaran, L. (1996). User involvement in the systems design process- a practical guide for users. Behaviour & Information 

Technology, 15(6), 363–377.
Day, J. K., & Gunderson, D. E. (2015). Understanding high performance buildings: The link between occupant knowledge of passive 

design systems, corresponding behaviours, occupant comfort and environmental satisfaction. Building and Environment, 84, 
114–124. https://doi.org/10.1016/j.buildenv.2014.11.003

Delzendeh, E., Wu, S., Lee, A., & Zhou, Y. (2017). The impact of occupants’ behaviours on building energy analysis: A research 
review. Renewable and Sustainable Energy Reviews, 80(August), 1061–1071. https://doi.org/10.1016/j.rser.2017.05.264



 051 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

Deme Belafi, Z., Hong, T., & Reith, A. (2018). A critical review on questionnaire surveys in the field of energy-related occupant 
behaviour. Energy Efficiency, 11(8), 2157–2177. https://doi.org/10.1007/s12053-018-9711-z

Fabi, V., Andersen, R. V., Corgnati, S., & Olesen, B. W. (2012). Occupants’ window opening behaviour: A literature review of 
factors influencing occupant behaviour and models. Building and Environment, 58, 188–198. https://doi.org/10.1016/j.
buildenv.2012.07.009

Fanger, P. O. (1970). Thermal Comfort: Analysis and Applications in Environmental Engineering. McGraw-Hill.
Favoino, F., Loonen, R. C. G. M., Doya, M., Goia, F., Bedon, C., & Babich, F. (Eds.). (2018). Building Performance Simulation and 

Characterisation of Adaptive Façades – Adaptive Façade Network. In COST Action TU 1403 Adaptive Façade Network. Tu Delft 
Open.

Fisk, W. J. (2000). Health and Productivity Gains from Better Indoor Environments and their Relationship with Building Energy 
Efficiency. Annual Review of Energy and the Environment, 25(1997), 537–566.

Fountain, M., Brager, G., & De Dear, R. (1996). Expectations of indoor climate control. Energy and Buildings, 24(3), 179–182. https://
doi.org/10.1016/S0378-7788(96)00988-7

Frontczak, M., & Wargocki, P. (2011). Literature survey on how different factors influence human comfort in indoor environments. 
Building and Environment, 46(4), 922–937. https://doi.org/10.1016/j.buildenv.2010.10.021

Haldi, F., & Robinson, D. (2008). On the behaviour and adaptation of office occupants. Building and Environment, 43(12), 2163–2177. 
https://doi.org/10.1016/j.buildenv.2008.01.003

Heydarian, A., McIlvennie, C., Arpan, L., Yousefi, S., Syndicus, M., Schweiker, M., Jazizadeh, F., Rissetto, R., Pisello, A. L., Piselli, C., 
Berger, C., Yan, Z., & Mahdavi, A. (2020). What drives our behaviours in buildings? A review on occupant interactions with 
building systems from the lens of behavioural theories. Building and Environment, 179(November 2019), 106928. https://doi.
org/10.1016/j.buildenv.2020.106928

Hoffman, R. R., Ford, K. M., Feltovich, A., Woods, D. D., Feltovich, P. J., & Klein, G. (2002). A Rose by Any Other Name…Would Probably 
Be Given an Acronym. IEEE Intelligent Systems, 17(4), 72–80. https://doi.org/10.1109/MIS.2002.1024755

Holopainen, R., Tuomaala, P., Hernandez, P., Häkkinen, T., Piira, K., & Piippo, J. (2014). Comfort assessment in the context of 
sustainable buildings: Comparison of simplified and detailed human thermal sensation methods. Building and Environment, 
71, 60–70. https://doi.org/10.1016/j.buildenv.2013.09.009

Hong, T., Yan, D., D’Oca, S., & Chen, C. fei. (2017). Ten questions concerning occupant behaviour in buildings: The big picture. 
Building and Environment, 114, 518–530. https://doi.org/10.1016/j.buildenv.2016.12.006

Huizenga, C., Abbaszadeh, S., Zagreus, L., & Arens, E. (2006). Air quality and thermal comfort in office buildings: Results of a large 
indoor environmental quality survey. Proceeding of Healthy Buildings 2006, 3, 399–397. https://doi.org/10.12659/PJR.894050

Humphreys, M. A. (2005). Quantifying occupant comfort: Are combined indices of the indoor environment practicable? Building 
Research and Information, 33(4), 317–325. https://doi.org/10.1080/09613210500161950

IDEO.org. (2015). The Field Guide To Human Centred Design.
ISO 9241-210. (2010). Ergonomics of human–system interaction : Human-centred design for interactive systems.
Jia, M., Srinivasan, R. S., & Raheem, A. A. (2017). From occupancy to occupant behaviour: An analytical survey of data acquisition 

technologies, modeling methodologies and simulation coupling mechanisms for building energy efficiency. Renewable and 
Sustainable Energy Reviews, 68(June 2016), 525–540. https://doi.org/10.1016/j.rser.2016.10.011

Kaasinen, E., Kymäläinen, T., Niemelä, M., Olsson, T., Kanerva, M., & Ikonen, V. (2013). A user-centric view of intelligent 
environments: User expectations, user experience and user role in building intelligent environments. Computers, 2(1), 1–33. 
https://doi.org/10.3390/computers2010001

Khalid, H. M. (2006). Embracing diversity in user needs for affective design. Applied Ergonomics, 37(4 SPEC. ISS.), 409–418. https://
doi.org/10.1016/j.apergo.2006.04.005

Kim, J., & de Dear, R. (2012). Nonlinear relationships between individual IEQ factors and overall workspace satisfaction. Building 
and Environment, 49(1), 33–40. https://doi.org/10.1016/j.buildenv.2011.09.022

Klein, T. (2013). Integral Façade Construction : Towards a new product architecture for curtain walls [TU Delft]. In Architecture and 
the Built Environment. https://doi.org/10.7480/abe.2013.3

Knaack, U., Klein, T., Bilow, M., & Auer, T. (2014). Façades: Principles of Construction (2nd editio). Birkhäuser Verlag GmbH.
Kwon, M., Remøy, H., van den Dobbelsteen, A., & Knaack, U. (2019). Personal control and environmental user satisfaction in office 

buildings: Results of case studies in the Netherlands. Building and Environment, 179, 428–435. https://doi.org/10.1002/
bdra.20073

Lassen, N., Josefsen, T., & Goia, F. (2021). Design and in-field testing of a multi-level system for continuous subjective 
occupant feedback on indoor climate. Building and Environment, 189(October 2020), 107535. https://doi.org/10.1016/j.
buildenv.2020.107535

Law, E. L. C., Roto, V., Hassenzahl, M., Vermeeren, A. P. O. S., & Kort, J. (2009). Understanding, scoping and defining user 
experience: A survey approach. Conference on Human Factors in Computing Systems - Proceedings, 719–728. https://doi.
org/10.1145/1518701.1518813

Lazarova-Molnar, S., & Mohamed, N. (2017). On the complexity of smart buildings occupant behaviour: Risks and opportunities. 
ACM International Conference Proceeding Series, Part F1309(November). https://doi.org/10.1145/3136273.3136274

Lee, E. S., Fernandes, L. L., Coffey, B., McNeil, A., Clear, R., Webster, T., Bauman, F., Dickerhoff, D., Heinzerling, D., & Hoyt, T. (2013). A 
Post-Occupancy Monitored Evaluation of the Dimmable Lighting , Automated Shading , and Underfloor Air Distribution System in 
The New York Times Building Building Technology and.

Luna-Navarro, A., Fidler, P., Law, A., Torres, S., & Overend, M. (2021). Building Impulse Toolkit (BIT): A novel IoT system for 
capturing the influence of façades on occupant perception and occupant-façade interaction. Building and Environment, 
193(November 2020), 107656. https://doi.org/10.1016/j.buildenv.2021.107656



 052 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

Luna-Navarro, A., Loonen, R., Juaristi, M., Monge-Barrio, A., Attia, S., & Overend, M. (2020). Occupant-Façade interaction: a review 
and classification scheme. Building and Environment, 177, 106880. https://doi.org/10.1016/j.buildenv.2020.106880

Maguire, M. (2001). Methods to support human-centred design. International Journal of Human Computer Studies, 55(4), 587–634. 
https://doi.org/10.1006/ijhc.2001.0503

Masoso, O. T., & Grobler, L. J. (2010). The dark side of occupants’ behaviour on building energy use. Energy and Buildings, 42(2), 
173–177. https://doi.org/10.1016/j.enbuild.2009.08.009

Naqvi, N., Shiv, B., & Bechara, A. (2006). The Role of Emotion in Decision Making: A Cognitive Neuroscience Perspective. Current 
Directions in Psychological Science, 15(5), 260–264. https://doi.org/10.1111/j.1467-8721.2006.00448.x

Nicol, J. F., & Humphreys, M. A. (2002). Adaptive thermal comfort and sustainable thermal standards for buildings. Energy and 
Buildings, 34(6), 563–572. https://doi.org/10.1016/S0378-7788(02)00006-3

Norman, D. A. (1988). The psychology of everyday things. Basic Books.
Norman, D. A. (2013). The design of everyday things. Basic Books, A Member of the Perseus Books Group All. https://doi.

org/10.5860/choice.51-5559
O’Brien, W., & Gunay, H. B. (2014). The contextual factors contributing to occupants’ adaptive comfort behaviours in offices - A re-

view and proposed modeling framework. Building and Environment, 77, 77–87. https://doi.org/10.1016/j.buildenv.2014.03.024
O’Brien, W., Wagner, A., Schweiker, M., Mahdavi, A., Day, J., Kjærgaard, M. B., Carlucci, S., Dong, B., Tahmasebi, F., Yan, D., Hong, T., 

Gunay, H. B., Nagy, Z., Miller, C., & Berger, C. (2020). Introducing IEA EBC annex 79: Key challenges and opportunities in the field 
of occupant-centric building design and operation. Building and Environment, 178(May), 106738. https://doi.org/10.1016/j.
buildenv.2020.106738

Ortiz, M. A. (2019). Home Occupant Archetypes: Profiling home occupants’ comfortand energy-related behaviours with mixed methods. 
[TU Delft]. https://doi.org/10.7480/abe.2019.5

Ortony, A., Norman, D. A., & Revelle, W. (2005). Affect and Proto-Affect in Effective Functioning. In Who Needs Emotions (pp. 
173–202). https://doi.org/10.1093/acprof

Pee, L. G., Woon, I. M. Y., & Kankanhalli, A. (2008). Explaining non-work-related computing in the workplace: A comparison of 
alternative models. Information and Management, 45(2), 120–130. https://doi.org/10.1016/j.im.2008.01.004

Perino, M., & Serra, V. (2015). Switching from static to adaptable and dynamic building envelopes: A paradigm shift for the energy 
efficiency in buildings. Journal of Façade Design and Engineering, 3(2), 143–163. https://doi.org/10.3233/fde-150039

Roulet, C. A., Flourentzou, F., Foradini, F., Bluyssen, P., Cox, C., & Aizlewood, C. (2006). Multicriteria analysis of health, comfort and 
energy efficiency in buildings. Building Research and Information, 34(5), 475–482. https://doi.org/10.1080/09613210600822402

Russell, R., Guerry, A. D., Balvanera, P., Gould, R. K., Basurto, X., Chan, K. M. A., Klain, S., Levine, J., & Tam, J. (2013). Humans 
and Nature: How Knowing and Experiencing Nature Affect Well-Being. In Ssrn. https://doi.org/10.1146/annurev-envi-
ron-012312-110838

Samani, S. A. (2015). The Impact of Personal Control over Office Workspace on Environmental Satisfaction and Performance. 
Journal of Social Sciences and Humanities, 1(3), 163–172. http://www.aiscience.org/journal/jssh

Sanders, L. (2008). An evolving map of design practice and design research. ACM — Interactions, XV.6(November + December), 1–7. 
https://doi.org/10.1093/beheco/arw006

Schweiker, M., Hawighorst, M., & Wagner, A. (2016). The influence of personality traits on occupant behavioural patterns. Energy 
and Buildings, 131, 63–75. https://doi.org/10.1016/j.enbuild.2016.09.019

Stern, P. C. (1992). What Psychology Knows About Energy Conservation. American Psychologist.
Tabadkani, A., Roetzel, A., Li, H. X., & Tsangrassoulis, A. (2021). A review of occupant-centric control strategies for adaptive façades. 

Automation in Construction, 122(May 2020), 103464. https://doi.org/10.1016/j.autcon.2020.103464
Triandis, H. C. (1977). Interpersonal Behaviour. Brooks/Cole Pub.Co. 
van der Bijl-Brouwer, M., & Dorst, K. (2017). Advancing the strategic impact of human-centred design. Design Studies, 53, 1–23. 

https://doi.org/10.1016/j.destud.2017.06.003
Verbeek, P.-P., & Slob, A. (2006). User Behaviour and Technology Development: Shaping Sustainable Relations Between Consumers 

and Technologies. Springer. 
Verplanken, B., & Aarts, H. (1999). Habit, Attitude, and Planned Behaviour: Is Habit an Empty Construct or an 

Interesting Case of Goal-directed Automaticity? European Review of Social Psychology, 10(1), 101–134. https://doi.
org/10.1080/14792779943000035

Vischer, J. C. (2007). The effects of the physical environment on job performance: Towards a theoretical model of workspace stress. 
Stress and Health, 23, 175–184. https://doi.org/10.1002/smi.1134

Visser, F. S., Stappers, P. J., van der Lugt, R., & Sanders, E. B.-N. (2005). Contextmapping: experiences from practice. CoDesign, 1(2), 
119–149. https://doi.org/10.1080/15710880500135987

Wagner, A. (2018). Occupant behaviour-centric building design and operation EBC Annex 79. In IEA EBC (Issue October).
Wagner, A., O’Brien, W., & Dong, B. (Eds.). (2018). Exploring Occupant Behaviour in Buildings. Springer International Publishing AG. 

https://doi.org/10.1007/978-3-319-61464-9
Wigginton, M., & Harris, J. (2002). Intelligent skins. Butterworth-Heinemann.
Yan, D., & Hong, T. (Eds.). (2018). Definition and Simulation of Occupant Behaviour in Buildings. In IEA, EBC Annex 66 Final Report 

(Issue May).
Yan, D., O’Brien, W., Hong, T., Feng, X., Burak Gunay, H., Tahmasebi, F., & Mahdavi, A. (2015). Occupant behaviour modeling for 

building performance simulation: Current state and future challenges. Energy and Buildings, 107, 264–278. https://doi.
org/10.1016/j.enbuild.2015.08.032

Zagreus, L., Huizenga, C., Arens, E., & Lehrer, D. (2004). Listening to the occupants: a Web-based indoor environmental quality 
survey. Indoor Air, 14(s8), 65–74. https://doi.org/10.1111/j.1600-0668.2004.00301.x



 053 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022

Zhang, T., & Dong, H. (2008). Human-centred design: an emergent conceptual model. Include2009 Proceedings, 2008, 7. https://doi.
org/10.1.1.426.5107

Zhang, Y., Bai, X., Mills, F. P., & Pezzey, J. C. V. (2018). Rethinking the role of occupant behaviour in building energy performance: A 
review. Energy and Buildings, 172, 279–294. https://doi.org/10.1016/j.enbuild.2018.05.017

Zoltowski, C. B., Oakes, W. C., & Cardella, M. E. (2012). Students’ Ways of Experiencing Human-Centred Design. Journal of 
Engineering Education, 101(1), 28–59. https://doi.org/10.1002/j.2168-9830.2012.tb00040.x



 054 JOURNAL OF FACADE DESIGN & ENGINEERING   VOLUME 10 / NUMBER 1 / 2022