CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 63, 2018 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Jeng Shiun Lim, Wai Shin Ho, Jiří J. Klemeš
Copyright © 2018, AIDIC Servizi S.r.l. 
ISBN 978-88-95608-61-7; ISSN 2283-9216 

Survey of Resident Behaviour Related to Air Conditioner 
Operation in Low-Cost Apartments of Kuala Lumpur  

Sheikh Ahmad Zakia,*, Nur Fadhilah Mat Hanipa, Aya Hagishimab, Fitri Yakuba, 
Mohamed Sukri Mat Alia 
aMalaysia-Japan International Institute of Technology, Universiti Teknologi Malaysia, 54100 Kuala Lumpur, Malaysia 
bInterdisciplinary Graduate School of Engineering Sciences (IGSES), Kyushu University, Japan 
 sheikh.kl@utm.my 

Predictions of air conditioner (AC) use can greatly facilitate efforts to increase energy efficiency in buildings 
and promote sustainability. In order to determine the statistical characteristics of occupant behaviour related to 
AC operation, a series of surveys were conducted between September 2013 and December 2015 in 63 
dwellings within two apartments in Kuala Lumpur, Malaysia. Measurements were taken either in the bedroom 
or living room of each dwelling. The results indicate that occupants who use ACs more frequently tend to use 
them for longer periods. It was found that AC use in bedrooms is not affected by outdoor temperature but is 
controlled by the habitual behaviour of the occupant. AC usage in living rooms slightly increases with 
increases in outdoor temperature. AC usage predominantly occurs at night time, with a maximum of 50 % of 
occupants using ACs in bedrooms. The start time and duration of use vary for each dwelling. These findings 
on stochastic resident behaviour might be useful for various building energy simulations in predicting realistic 
AC loads, particularly in tropical climates.  

1. Introduction 

Occupant behaviour describes how people respond to their indoor environment by making use of the building 
controls, for example, by switching on the lights, opening windows, or turning on the air conditioners (AC). 
Several studies have investigated occupant behaviour regarding window opening (Rijal et al., 2007), lighting 
(Reinhart, 2004), adaptation of thermal comfort in office buildings in Malaysia, Singapore, Indonesia, and 
Japan (Damiati et al., 2016), in Japanese university building with free running and cooling mode offices  
(Mustapa et al., 2016), university classroom in Malaysia and Japan (Zaki et al., 2017a), and switching on/off 
AC (Tanimoto and Hagishima, 2005). These studies were conducted in different countries with varying climate 
conditions. They also involved different building types and climate. It is very important to conduct the studies 
on energy consumption-related occupant behaviour for developing stable energy grids. These studies are 
often then used to develop behavioural models based on statistical algorithms that predict the probability of 
user action. In order to know the reality of energy use of AC, there are several factors. First is human factor 
such as when and how long people want to use AC, thermal environment that occupants satisfy or accept in 
reality (Hwang et al., 2009), and AC setpoint of temperature. Second is AC performance and building 
insulation. The amount of thermal energy which AC remove from the room air and AC electricity consumption 
can be estimated using building energy consumption (Tanimoto and Hagishima, 2010). Accurate estimations 
of the stochastic natures of energy demand for AC use, which are affected by the diverse occupant behaviour, 
are needed, for the design and operation of residential cogeneration systems and distributed generation 
systems coupled with renewable energy sources and supply-demand management technologies. Past studies 
have mainly focused on developed countries and knowledge of tropical regions, including many emerging 
countries with large populations, remains limited. For example, Zaki et al. (2017b) developed a simple 
algorithm to synthesise stochastic time patterns of AC operation schedules based on field measurement of 
usage behaviour of AC in low cost apartment in Malaysia. Ranjbar et al. (2017a) carried out the measurement 
of total and AC electricity consumption for middle-income family in Kuala Lumpur, Malaysia. They found that 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1863044

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Sheikh Ahmad Zaki, Nur Fadhila Mat Hanip, Aya Hagishima, Fitri Yakub, Mohamd Sukri Mat Ali, 2018, Survey of 
resident behaviour related to air conditioner operation in low-cost apartments of kuala lumpur, Chemical Engineering Transactions, 63, 259-
264  DOI:10.3303/CET1863044   

259



1-min resolution is more accurately measured electricity energy consumption of household. Ranjbar et al. 
(2017b) had extended the investigation of similar study and noticed the pattern of electricity energy 
consumption is based on the occupancy schedule of each dwelling, and AC is the main contribution of 
electricity consumption.  The main purpose of this research is to identify the factors that influence occupant 
decisions regarding AC usage in order to construct a model of AC temporal patterns in tropical regions. Field 
measurements of occupants’ AC usage behaviour were conducted in 63 dwellings from two low-cost 
apartments in Kuala Lumpur, Malaysia. 

2. Methods 

2.1 Surveys 

63 dwellings within two low-cost apartments were selected for a series of field measurements in the period 
from September 2013 to May 2015, summarised in Table 1.  

Table 1:  Profiles of field surveys conducted in Kuala Lumpur 

Apartment A B 
Location N 3° 11’ 16”, E 101° 43’ 53” N 3° 10’ 7”, E 101° 43’ 25” 
Number of samples 54 dwellings 9 dwellings 
Characteristics of 
dwellings 

19-storey building with a floor area  
of 60 m2 

13-storey and 4-storey buildings with floor 
areas of 55 m2 and 74 m2 

Measurement period 15 to 58 days per dwelling,  
from September 2013 to  
December 2015 

29 to 68 days per dwelling, from February 
2015 to December 2015 

 
The households are comprised of nuclear families (two adults plus children), single-parent families, and 
extended families (including grandparents). Figure 1 shows the number of occupants living in each house. The 
average household size is four with a standard deviation of 1.2. The maximum number of people living in the 
same house is eight. 

 
 
 
 
 
 
 
 
 
 

Figure 1: Number of occupants living in each house 

2.2 Measurement set up 

Figure 2 displays the annual variation in outdoor air temperature during the survey period. Malaysia is located 
on the equator and is categorised as a tropical zone, with a relatively constant outdoor air temperature 
throughout the year. In the figure, there are several short periods during which no data were recorded due to 
maintenance of the weather station. Although there were no field measurements conducted during these 
periods, it does not affect the results of this study. 
A thermo recorder (resolution 0.1 °C, accuracy ± 0.25 °C: 0 °C to 50 °C) was installed at the air outlet of the 
AC unit. The room temperature was measured in the centre of the room using the same sensor. Data were 
collected in 15 min intervals. Measurements were performed in either the living room or bedroom, depending 
on the location of the AC unit. Some of the dwellings had more than one AC installed in different rooms. Due 
to the limited number of instruments available, it was not possible to place sensors inside all of these rooms. 
Occupants were interviewed on their AC usage preferences, and any AC’s that were rarely used were omitted. 
There was an equal distribution of AC’s, in that 50 % of sensors were installed in bedrooms and 50 % were 
installed in living rooms. The measured data was used to determine when the occupants switched on or off 
theirs AC’s in each day. The criteria to decide that AC usage in each dwelling based on the difference 
temperature between AC outlet air and room air temperature. If the temperature difference was 1.5 °C, the 

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Outdoor air temperature (°C)

Average Maximum Minimum(b)

occupant switched on the AC. The times period of occupants switched on and off the AC’s was called as 
event. A weather station for recording outdoor air temperature was installed on the rooftop of the Malaysia-
Japan International Institute of Technology (MJIIT) building, less than 2 km from both apartments. The detail 
setup of the station was described in the previous studies done by Swarno et al. (2017). 
 

 

Figure 2: Outdoor air temperature profiles in Kuala Lumpur observed from the rooftop weather station of the 
MJIIT building 

3. Results and Discussion 

3.1 Outdoor temperature and air conditioner usage 

The effects of outdoor temperature conditions on occupant decisions to use the air conditioner can be 
observed by studying the relationship between the daily hours of AC usage and daily statistics of outdoor air 
temperature, as shown in Figure 3. The size of the plots refers to the number of samples. In Figure 3a, AC 
usage in the living room slightly increases with outdoor temperature. Figure 3b shows that AC usage in the 
bedroom remains constant despite the increasing outdoor temperature. This may be a result of occupants’ 
daily habits, in which the AC in the bedroom is always used at night, regardless of the outdoor temperature.  

 
 
 
 
 
 
 
 
 
 
 

 

Figure 3: Relationship between daily hours of AC usage and daily outdoor air temperature: (a) living rooms 
and (b) bedrooms  

3.2 Statistics of AC events 

To observe how daily habits or schedules affect decisions regarding air conditioner usage, the joint probability 
distributions of events in terms of event start time and duration are displayed in Figure 4. The horizontal axis 
shows the time when occupants turn on the AC in a 24-h clock system. The vertical axis shows the duration of 
AC use in hours. Figure 4a also shows peaks at 11 pm and midnight, but with shorter durations of 0 to 2 
hours. This result is consistent with the questionnaire survey done by Kubota et al. (2011), which AC is mainly 
used during sleeping time in Malaysia. Figure 4b also shows two peaks: at 11 pm and midnight, with a 
duration of 6 to 8 h. This indicates that air conditioner use in the bedroom is determined by the occupants’ 
sleep schedule. 

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Outdoor air temperature (°C)

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Figure 5 shows that there are peak times in which occupants are more likely to switch on their AC. It also 
shows the proportion of AC units that are switched on at different times of the day. In the living room, the peak 
time is around 11 pm to 1 am, with approximately 30 % of occupants using the AC during this time. It is 
evident that air conditioners in the bedroom are used for sleeping, with a maximum 50 % of occupants using 
their AC between 11 pm and 6 am. The proportion of occupants using the AC in the bedroom decreases 
significantly between 8 am and 7 pm. In general, occupants use the AC more during the night.  

 

Figure 4: Joint probability distributions of AC event duration and event start time. Colours refer to the 
probability density of AC event duration and event start time 

 

Figure 5: Proportion of AC that are switched on at different times (with a 95 % confidence interval) 

Figure 6 shows the relationship between the total number of events and the total duration of AC usage. 
Generally, the total duration in a day varies from 0 to 13.7 h. The figure shows a positive relationship, 
indicating that occupants who use the AC more frequently are more likely to use the AC for longer periods. In 
terms of AC usage between the living room and the bedroom, the former had more AC events than the latter 
for a similar daily amount of AC usage. This indicates that AC events in bedrooms tend to be of a longer 
duration than those in living rooms. 
 

 

Figure 6: Comparison between number of AC usage events per day and total duration of AC usage per day for 
63 dwellings 

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Average total duration of AC usage (h /d)

Living Room
Bedroom

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Figure 7 displays the relationship between the total number of events and the total duration, classified by 
working days and holidays for bedrooms and living rooms. One could hypothesise that occupants spend more 
time at home during holidays and are more likely to use the air conditioner when they are present in the room. 
Both figures show negligible differences between holidays and working days. This can be explained by the 
fact that occupants predominantly use the AC at night time, discussed in the following section.  
 

(a) (b) 

 

Figure 7: Comparison between number of AC usage events per day and total duration of AC usage in a day 
classified by working days and holidays for (a) 33 living rooms and (b) 42 bedrooms 

The probability density of indoor air temperature before and during the occupants switch on and the AC 
operation in dwellings is shown in Figure 8. The mean indoor temperature in the both living and bedrooms 
before AC on varied from 29 °C to 31 °C. This indicates the upper limit of the acceptable thermal comfort of 
users that seem more tolerant of heat. They are more likely to withstand higher temperatures before making 
the decision to turn on the air conditioner. The mean indoor air temperatures for living room during event had 
deviated from 28 °C to 30 °C. In contrast, data from bedroom had a wider deviation from approximately 24 °C 
to 29 °C. The reason that exceeded the criteria of thermal comfort of indoor environment might due to the poor 
insulation performance and a tendency of owner to reduce the electricity bills. 

 

Figure 8: Room indoor air temperature before occupants switch on and during the AC operation 

4. Conclusions 

A series of measurements were conducted to determine air conditioner usage patterns among occupants of 
apartments in Kuala Lumpur, Malaysia. The recorded data was used to determine the factors that affect 
occupant decisions to turn on the air conditioner. The 63 target houses were examined according to the 
frequency, start and end time of AC usage. The findings of this study can be concluded as follows: 

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Average total duration of AC usage 
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Workday
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a. Air conditioner usage is not significantly affected by the outdoor temperature but is affected by 
occupants’ habitual behaviour. 

b. Malaysian residents tend to use the air conditioner during sleeping hours, but the start time and 
duration of use varies. AC events rarely occur during the daytime. 

c. AC usage events in living rooms are more numerous than those in bedrooms for a similar daily 
amount of AC usage.  

d. AC events in bedrooms tend to be longer than those in living rooms. 

e. The indoor air temperature for living room before and during events are approximately 27 °C to 31 
°C. The similar condition also observed from bedroom before AC on, but it had a wider deviation 
during AC event approximately 22 °C to 30 °C. The exceeded criteria of indoor thermal comfort might 
contribute from poor condition of existing insulation. 

The findings of this survey could be used to generate an artificial AC operation schedule, with a specific 
emphasis on tropical regions. 

Acknowledgments  

This research was supported by the Malaysian Ministry of Higher Education (MOHE) under the Research 
University Grant (4F267) project of Universiti Teknologi Malaysia and the Takasago Grant Research (4B210).  

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