Working in a Smart Home-office: Exploring the Impacts on
Productivity and Wellbeing
Davit Marikyan
1
, Savvas Papagiannidis
1
, Rajiv Ranjan
2
and Omer Rana
3
1
Newcastle University Business School, 5 Barrack Road, Newcastle Upon Tyne, NE14SE, U.K.
2
Newcastle University, School of Computing, 1, Urban Sciences Building, Science Square,
Newcastle Upon Tyne, NE4 5TG, U.K.
3
School of Computer Science and Informatics, Cardiff University, Cardiff CF24 3AA, U.K.
Keywords: Digitalisation, Smart Home, COVID-19, Pandemic, Remote Work.
Abstract: Following the outbreak of the Coronavirus (COVID-19) pandemic, many organisations have shifted to remote
working overnight. The new reality has created conditions to use smart home technologies for work purposes,
for which they were not originally intended. The lack of insights into the new application of smart home
technologies has led to two research objectives. First, the paper aimed to investigate the factors correlating
with productivity and perceived wellbeing. Second, the study tried to explore individuals’ intentions to use
smart home offices for remote work in the future. 528 responses were gathered from individuals who had
smart homes and had worked from home during the pandemic. The results showed that productivity positively
relates to service relevance, perceived usefulness, perceived ease of use, hedonic beliefs, control over
environmental conditions, innovativeness and attitude. Task-technology fit, service relevance, attitude to
smart homes, innovativeness, hedonic beliefs, perceived usefulness, perceived ease of use and control over
environmental conditions correlate with perceived wellbeing. The intention to work from smart home-offices
in the future is determined by perceived wellbeing. Findings contribute to the research on smart homes and
remote work practices, by providing the first empirical evidence about the new applications and outcomes of
smart home use in the work context.
1 INTRODUCTION
The Coronavirus (COVID-19) pandemic is one of the
worst emergency events in modern history, having
adverse implications for people and economies
(Papagiannidis et al., 2020; Venkatesh, 2020).
Measures imposed by the government to cope with
the virus forced companies to adapt to new working
conditions to ensure business continuity (Barnes,
2020). In such contingency events, the digitalisation
of work practices has been carried out regardless of
companies’ resources and capabilities. The pandemic
emergency set the conditions for examining the
viability of remote working in the new context, in
which employees have been confined to their home
environment. On the one hand, such conditions entail
pressure both on organisations and employees. On the
other hand, the situation has erased the boundaries
between home and work practices and spaces. With
the blending of work and home spaces into a hybrid
environment, the usage of smart homes has increased
exponentially (Maalsen & Dowling, 2020). Due to
intelligent functionality and the ability of smart
homes to enhance users’ comfort and efficiency, the
technology has become useful in accommodating the
needs of workers from home. The accidental
applications of smart homes in the work context
creates new unexplored use experiences, potentially
contributing to the employees’ psychological state
and work performance. In light of debates about the
future of work after the pandemic and the lack of
research on that front (Barnes, 2020; Venkatesh,
2020), it is important to examine the spillover of
smart home utilisation into remote work practices and
its job- and individual-related outcomes. Hence, the
study pursues two objectives. The first objective is to
investigate the impact of smart home application in
the work context by examining the factors that could
contribute to the quality of work and life in a smart
home-work environment. The study aims to explore
the relationship of three groups of factors referring to
work and work environment characteristics, smart
Marikyan, D., Papagiannidis, S., Ranjan, R. and Rana, O.
Working in a Smart Home-office: Exploring the Impacts on Productivity and Wellbeing.
DOI: 10.5220/0010652200003058
In Proceedings of the 17th International Conference on Web Information Systems and Technologies (WEBIST 2021), pages 275-282
ISBN: 978-989-758-536-4; ISSN: 2184-3252
Copyright
c
2021 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
275
technology and individual factors with individuals’
productivity and wellbeing. The second objective of
the research is to explore the willingness to use smart
home technologies in the work environment in the
future by exploring the correlation of use outcomes
productivity and wellbeing on intention to use smart
homes in the home-office settings.
2 LITERATURE REVIEW
2.1 Smart Home
The literature on the utilisation of smart home
technologies is relatively scarce (Marikyan et al.,
2019). The majority of prior research investigated
smart home technology through technical lenses
(Ford et al., 2017; Yang et al., 2018). Scholars
focused on the development and deployment of a
particular technology, such as smart meters and smart
sensors (Warkentin et al., 2017; Yang et al., 2018).
They also examined the architecture, connectivity and
the algorithms that transform technologies into smart
ones (Yang & Cho, 2016). The other stream of
research revolved around the services that smart
home appliances can deliver, such as comfort,
monitoring, health therapy, support and consultancy,
and the benefits that they realise (Marikyan et al.,
2019). Comfort can be delivered by creating an
intelligent environment, whereby home residents rely
on smart devices to automate and manage their daily
routine (Balta-Ozkan et al., 2014). The embeddedness
of smart sensors in homes makes it possible to
monitor individuals’ behaviour, the consumption of
natural resources and health metrics (Marikyan et al.,
2019). Health therapy services are realised through
remote connectivity of home residents with health-
care centres, which can provide virtual medical
consultancy (Yang et al., 2016). The above services
deliver the benefits concerning psychological and
health-related assistance, environmental
sustainability, a reduction of financial costs,
wellbeing and social inclusion (Chan et al., 2008;
Marikyan et al., 2020). The provision of remote
medical care ensures a better quality of life and
improvement of health conditions (Talal et al., 2019;
Yang et al., 2016). The reduction of water, gas and
electricity consumption brings financial benefits to
users and positively contributes to environmental
sustainability (Ford et al., 2017). The capability of
smart homes to connect home residents with the
world outside can facilitate social inclusion
(Marikyan et al., 2019), which is especially important
in an emergency event, such as the pandemic, as this
aggravates the feeling of isolation and loneliness.
Smart homes can facilitate the subjective perception
of wellbeing, by automating the control over the
home environmental conditions, such as lighting,
temperature and air quality (Marikyan et al., 2019).
When it comes to the consequences of smart home
utilisation, it has been shown that smart home usage
contributes to satisfaction and wellbeing (Marikyan et
al., 2020; Shin et al., 2018). While the smart home
literature postulates the capability of technology to
improve living conditions and the performance of
household tasks (Marikyan et al., 2019; Talal et al.,
2019), there is no evidence about the applications of
smart homes to remote work and their impact on work
related outcomes. Following the literature, three
groups of factors were identified: a) work and the
work-environment, b) smart technology and c)
individual factors.
3 HYPOTHESIS DEVELOPMENT
3.1 Work and the Work Environment
The work and work environment factors include task
technology fit, service relevance and control over the
work environment conditions. These factors reflect
new work characteristics, practices and the conditions
brought about by the new work context and tools. The
examination of task-technology fit is important as the
utilisation of technology can be discontinued if users
find a lack of fit between task requirements and the
capabilities of technology to implement them
(Goodhue & Thompson, 1995; Marikyan et al.,
2021). The perception that technology matches tasks
improves the perception of the usefulness of the
technology. The use of smart homes can help manage
the environment in which people work and improve
job outcomes in two ways. First, smart homes
appliances, such as voice-controlled assistants,
ensure seamless connectivity and automation,
facilitating the adaptability to virtual collaborations.
Secondly, smart homes increase the effectiveness of
the implementation of personal tasks (Marikyan et al.,
2019). Therefore, the first hypothesis states that:
H1: Task-technology fit positively correlates with a)
productivity in a smart home-office environment and
b) wellbeing in a smart home-office environment.
Service relevance could be conceptualised as the
degree to which the services offered by the system are
applicable to individuals’ jobs (Venkatesh & Davis,
2000). In the smart home-office context, service
relevance refers to individuals’ beliefs regarding the
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relevance of services made possible by smart home
technology for remote work purposes, such as
controlling the workplace conditions. Therefore, it is
assumed that the creation of a comfortable
environment while working from home is relevant to
individuals tasks implementation, in turn, having
positive implications for job outcomes and
satisfaction with life. Given that, we hypothesise the
following:
H2: Smart home service relevance positively
correlates with a) productivity in a smart home-office
environment and b) wellbeing in a smart home-office
environment.
As the pandemic forced many individuals to work
from home, smart home technology can be used to
control environmental factors, which otherwise was
not possible (Balta-Ozkan et al., 2014; Marikyan et
al., 2020). Smart homes can enable remote workers to
control temperature and lighting to ensure optimal
thermal and visual conditions. Individuals working
from home can regulate the noise level by ambient
sounds using voice-controlled devices. Also, the use
of smart appliances can help design ergonomic space
to ensure comfort and accommodate job-related
needs. Hence, this study proposes the following
hypotheses:
H3: Control over the workplace environment using
smart home technologies positively correlates with a)
productivity in a smart home-office environment and
b) wellbeing in a smart home-office environment.
3.2 Smart Technology
Smart technology factors include individuals’ beliefs
about technology performance and capabilities,
which are important while working from home in
emergency situations. The factors include perceived
usefulness, perceived ease of use and social presence.
According to the research on technology acceptance,
perceived ease of use and perceived usefulness are the
beliefs which can translate into technology use
behaviour (F. D. Davis, 1989). Given the benefits of
smart homes in creating comfort in the home
environment (Marikyan et al., 2019; Papagiannidis &
Marikyan, 2019), their application therefore can be
useful in improving the conditions of remote work,
which are so much needed for higher job productivity
and wellbeing (Papagiannidis & Marikyan, 2019).
Therefore, we hypothesise that:
H4: Perceived usefulness of smart home technology
positively correlates with a) productivity in a smart
home-office environment and b) wellbeing in a smart
home-office environment.
H5: Perceived ease of use of smart home technology
positively correlates with a) productivity in a smart
home-office environment and b) wellbeing in a smart
home-office environment.
3.3 Individual Factors
The group of individual factors includes individual
attitudes, beliefs and personality traits, facilitating the
utilisation of the technology. Attitude is an
individual’s disposition towards a specific behaviour
resulting from their overall evaluation of that
behaviour. Through attitude, scholars have explored
individuals’ purchasing intention, technology
adoption, satisfaction, as well as the likelihood of job-
related outcomes (Dawkins & Frass, 2005; Minton et
al., 2018). Therefore, we assume the following:
H6: Attitude towards the smart home-office positively
correlates with a) productivity in a smart home-office
environment and b) wellbeing in a smart home-office
environment.
Innovativeness is a personality trait which explains
individualsinclination to engage in a new behaviour.
It has been shown that innovative individuals tend to
be early adopters of technology (Agarwal & Prasad,
1998). Individuals with a high innovativeness trait
tend to be more experienced and knowledgeable
about new technologies, services and potential
performance (Agarwal & Prasad, 1998). It can be
assumed that they are more open to experimentation,
such as employing smart home technology to improve
personal productivity in a home-office space and
ensure satisfaction with conditions while working
remotely. Therefore, we suggest the following
hypothesis:
H7: Individual innovativeness positively correlates
with a) productivity in a smart home-office
environment and b) wellbeing in a smart home-office
environment.
Hedonic value refers to individual factors, as it
measures the level of perceived enjoyment,
playfulness and fun resulting from the interaction
with smart home technologies in the home-office
setting. Several studies have empirically confirmed
the direct and indirect relationships of hedonic values
with technology adoption (Atulkar & Kesari, 2017;
Kim & Hwang, 2012). For instance, it was found that
hedonic beliefs has a direct positive effect on
individuals’ intention to use mobile applications
Working in a Smart Home-office: Exploring the Impacts on Productivity and Wellbeing
277
(Ozturk et al., 2016) and influences outcome
satisfaction and use behaviour through task-
technology fit (Marikyan et al., 2021). Given the
above evidence, the next hypothesis states that:
H8: Hedonic values positively correlate with a)
productivity in a smart home-office environment and
b) wellbeing in a smart home-office environment.
3.4 Intention to Use Smart Home
Technologies
The relationship between productivity in a smart
home-office environment, wellbeing and intention to
work in a smart home-office in the future is rooted in
evidence that individuals tend to continue the
behaviour that produces positive outcomes (Anıtsal,
2005; Kim et al., 2014). In a similar vein, it is
expected that the positive implications of the
technology use for individuals’ wellbeing will induce
the desire to continue using the technology to receive
similar benefits in the future. Given the above, this
study postulates that if the work from home using
smart home technologies brings positive results, such
as productivity and wellbeing, individuals will have
the intention to work in a smart home-office in the
future.
Hypothesis 9: a) Productivity in a smart home-office
environment and b) wellbeing in a smart home-office
environment positively correlate with intention to use
smart home technologies in the future when working
from home.
4 METHODOLOGY
4.1 Data Collection and Sample
A cross-sectional research design and a survey data
collection tool were employed. The survey consisted
of questions about the socio-demographic profile and
measurement items of 11 constructs (table 1). A
research company was employed to recruit
respondents, working from home during the
pandemic and with experience of using smart home
devices. 528 valid responses were collected.
Table 1: Measurement items of constructs.
Measurement Items Loading α
TTF (Lin & Huang, 2008; Yen et
al., 2010)
0.929
TTF1 0.894
TTF2 0.928
TTF3 0.886
Service relevance (Venkatesh &
Bala, 2008)
0.918
SR1 0.889
SR2 0.903
SR3 0.874
Control (Venkatesh, 2000) 0.924
CON1 0.909
CON2 0.905
CON3 0.875
Perceived usefulness (F. D. Davis,
1989)
0.967
PU1 0.932
PU2 0.932
PU3 0.955
PU4 0.932
Perceived ease of use (F. D. Davis,
1989)
0.929
PEU1 0.894
PEU2 0.920
PEU3 0.894
Attitude towards smart homes
(Elliott et al., 2007)
0.933
ATT1 0.864
ATT2 0.904
ATT3 0.852
ATT4 0.908
Innovativeness (Agarwal &
Prasad, 1998)
0.925
INN1 0.831
INN2 0.809
INN3 0.916
INN4 0.920
Hedonic benefits (Voss et al.,
2003)
0.937
HBEN1 0.900
HBEN2 0.878
HBEN3 0.884
HBEN4 0.890
Productivity in a smart home-
office (Goodhue & Thompson,
1995)
0.946
PROD1 0.859
PROD2 0.884
PROD3 0.884
PROD4 0.898
PROD5 0.884
Wellbeing (El Hedhli et al., 2013) 0.852
WELL1 0.838
WELL2 0.757
WELL3 0.846
Future intention to use
(Venkatesh & Goyal, 2010)
0.965
FINT1 0.927
FINT2 0.962
FINT3 0.958
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5 RESULTS
5.1 Data Analysis
As a first step, confirmatory factor analysis (CFA)
and construct reliability analysis were conducted. The
results showed that Cronbach’s α values (>0.7), factor
loadings (>0.7), the average variance extracted (AVE
> 0.5) and construct reliability results (C.R. > 0.7)
were above the acceptable threshold. That showed
that there were no validity and reliability issues (Hair
et al., 2014).
5.2 Path Analysis
We made sure that structural model fit indices were
satisfactory to proceed with path analysis, as follows:
χ2(656) = 1537.485, CMIN/DF = 2.344, CFI = 0.962,
RMSEA = 0.050. The model explains 78% of the
variance in perceived wellbeing, 59% in productivity
and 70% in intention to work from a smart home-
office in the future. Out of 18 hypothesised paths, 4
were found to be not significant (Table 2).
Table 2: The results of the tests of hypotheses.
H Path Coef. t-test, sig
H1a TTFPROD 0.145
(
1.676ns
)
H1b TTFWELL 0.218 (2.975**)
H2a SRPROD 0.340 (5.417***)
H2b SRWELL 0.150
(
2.855**
)
H3a CONPROD -0.521
(
-5.195***
)
H3b CONWELL -0.291
(
-3.463***
)
H4a PUPROD 0.575 (6.616***)
H4b PUWELL 0.362 (4.963***)
H5a PEUPROD -0.050 (-0.707ns)
H5b PEUWELL 0.195
(
3.216**
)
H6a ATTPROD 0.011
(
0.195ns
)
H6b ATTWELL 0.107
(
2.247*
)
H7a INNPROD 0.121 (3.069**)
H7b INNWELL 0.126 (3.765***)
H8a HBPROD 0.201
(
3.882***
)
H8b HBWELL 0.188
(
4.273***
)
H9a PRODFINT -0.076
(
-1.826ns
)
H9b WELLFINT 0.881 (17.415***)
6 DISCUSSION AND
CONCLUSION
The analysis showed that work and work environment
factors correlate with productivity in a smart home-
office and wellbeing, except for perceived task-
technology, which is important only in relation to
wellbeing. The positive effect of service relevance on
both productivity and wellbeing suggests that the
ability of smart home technologies to create
comfortable conditions while working at home is
important for ensuring good performance at work and
improving the quality of life. The negative path
between control over environmental conditions,
productivity and perceived wellbeing was rather
surprising. The finding goes against the opinion that
the application of smart technologies in the work
context could potentially increase individuals’ overall
performance and satisfaction (Papagiannidis &
Marikyan, 2019). The potential explanation is that
respondents do not have the right configuration of
devices to ensure the full connectivity between the
devices that help efficiently manage the quality of air,
noise, temperature and other environmental factors.
The significant path between task-technology fit and
wellbeing is consistent with prior literature
(Marikyan et al., 2020). The non-significant role of
task-technology fit on productivity could be due to
smart home technologies being originally designed
and developed for a private context. In such a context,
the integration of smart homes fits the purpose of
making daily routine tasks more comfortable to
improve the quality of life while being in the house,
rather than improve the productivity of work-related
tasks (Balta-Ozkan et al., 2014). Such an explanation
is supported by the significant path between task-
technology fit and wellbeing.
The analysis of smart home factors showed that,
compared to other predictors, perceived usefulness is
the strongest determinant of productivity in a smart
home-office environment and wellbeing. This finding
is in line with technology acceptance research,
postulating that perceived usefulness facilitates
technology adoption behaviour (Fred D Davis, 1989),
which can, in turn, result in productivity and
wellbeing. When it comes to perceived ease of use,
the analysis showed a correlation with wellbeing, but
not with productivity. These results indicate that
respondents find it easy to use smart home devices for
controlling their home-office environment. A
possible explanation for the insignificant correlation
between perceived ease of use and productivity is that
the role of the factor varies depending on knowledge
and the experience of using technology.
Individual factors include attitude towards smart
homes, personal innovativeness and hedonic beliefs.
The analysis made it possible to conclude that
productivity in a smart home-office is not dependent
on the individuals’ attitude towards smart homes.
Technology is utilised in the home-office
environment to improve job performance,
irrespective of personal beliefs about technology.
Working in a Smart Home-office: Exploring the Impacts on Productivity and Wellbeing
279
However, when it came to wellbeing, the importance
of attitude towards smart homes was confirmed. This
result suggests that people holding positive beliefs
about technology have a perception that they have a
better quality of life in their household. The findings
are in line with prior literature, which argued that the
use of smart home technologies results in satisfaction
(Marikyan et al., 2020, 2021). Positive relationships
between innovativeness, productivity and perceived
wellbeing are consistent with the assumptions of this
research rooted in evidence that individuals with a
high innovativeness trait tend to be early adopters of
new applications (Agarwal & Prasad, 1998). Positive
relationships between perceived hedonic benefit,
productivity and wellbeing mean that the enjoyment
that individuals experience while using smart home
devices for controlling their work environment
facilitates employees’ performance at work and
satisfaction. The finding is consistent with prior
research, which found that hedonic benefit enhances
the perception of the fit between technology services
and tasks, subsequent technology adoption and
satisfaction (Marikyan et al., 2021).
Finally, the analysis of the predictors of intention
to work from a smart home-office showed that only
wellbeing correlates with the dependent variables.
The data suggests that the benefit of smart homes for
enhancing wellbeing could potentially underpin
willingness to work from a smart home-office in the
future. However, productivity does not enhance the
intention to continue using smart home technologies
in remote work. Although the pandemic facilitated
the use of smart home technology for work purposes,
the work-related benefit of such technology is rather
a spillover effect, which does not encourage the
intention to use it in the future.
6.1 Theoretical and Practical
Contributions
This study makes two important theoretical
contributions. First, the paper contributes to the
literature on remote workers' behaviour. The findings
complement the research on the consequences of
remote work, which has mostly examined
technologies that are designed for the delivery of
work tasks distantly and collaborations between
employees (Drumea, 2020; Hafermalz & Riemer,
2021). Secondly, the paper contributes to the smart
home literature by bringing a novel insight into the
role that technology can have in the workplace, which
has not been explored before. By examining the
relationships between the determinants and
dependent variables, the study provides evidence with
regards to whether office spaces, equipped with
capabilities similar to those of smart homes, can help
individuals manage their workload by controlling the
environment, improving their comfort and
productivity. Also, the findings of the research bring
practical implications for organisations and smart
home developers. The paper informs managers about
the conditions enabled by smart home technologies
that favour better performance at work and higher
employee satisfaction with their life.
6.2 Limitations and Future Research
Suggestions
There are several limitations in this study, which
future research could address. First, the sample was
based on users located in the United Kingdom. Given
that in other countries, especially in emerging
markets, the technological infrastructure is different,
the perception and experience of individuals towards
smart home-offices could be different. Another
limitation is that we focused on a wide scope of smart
technologies, which made it impossible to evaluate
which technology plays the most important role in
enhancing productivity in a smart home-office and
individuals' satisfaction with life. Therefore, future
research could test the implications of a particular
smart technology (e.g. digital assistants) for remote
workers’ life and work performance.
ACKNOWLEDGEMENTS
1. This project was partly funded by the Engineering
and Physical Sciences Research Council (EPSRC):
PACE: Privacy-Aware Cloud Ecosystems (Project
Reference: EP/R033293/1).
2. The work reported here was part-sponsored by
Research England’s Connecting Capability Fund
award CCF18-7157 Promoting the Internet of
Things via Collaboration between HEIs and Industry
(Pitch-In).
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