Limitations of the Use of Mobile Devices and Smart Environments for
the Monitoring of Ageing People
Ivan Miguel Pires
1,2,3
, Nuno M. Garcia
1,3,4
, Nuno Pombo
1,3,4
and Francisco Flórez-Revuelta
5
1
Instituto de Telecomunicações, Universidade da Beira Interior, Covilhã, Portugal
2
Altranportugal, Lisbon, Portugal
3
ALLab - Assisted Living Computing and Telecommunications Laboratory, Computer Science Department,
Universidade da Beira Interior, Covilhã, Portugal
4
Universidade Lusófona de Humanidades e Tecnologias, Lisbon, Portugal
5
Department of Computer Technology, Universidad de Alicante, Spain
Keywords: Activities of Daily Living, Elderly People, Recognition, Mobile Devices, Smart Environments.
Abstract: The monitoring of the daily life of ageing people is a research topic widely explored by several authors,
which they presented different points of view. The different research studies related to this topic have been
performed with mobile devices and smart environments, combining the use of several sensors and
techniques in order to handle the recognition of Activities of Daily Living (ADL) that may be used to
monitor the lifestyle and improve the life’s quality of the ageing people. However, the use of the mobile
devices has several limitations, including the low power processing and the battery life. This paper presents
some different points of view about the limitations, combining them with a research about use of a mobile
application for the recognition of activities. At the end, we conclude that the use of lightweight methods
with local processing in mobile devices is the best method to the recognition of the ADL of ageing people in
order to present a fast feedback about their lifestyle. Finally, for the recognition of the activities in a
restricted space with constant network connection, the use of smart environments is more reliable than the
use of mobile devices.
1 INTRODUCTION
Over the last few years, research on recognizing
activities using sensors available on technological
devices is growing because of new techniques and
new devices. Based on (He, Goodkind, and Kowal,
2016), the number of older people in the world is
growing, with 8.5% of the people in the world being
65 or older, and technology can promote
independent living, reduce solitude and isolation
among other benefits (Age, 2010). The promotion of
independent living may include recognition of the
activities of the elderly using artificial intelligence
methods in the day-to-day care systems of the
elderly, health-related systems, social assistance
systems, telecare systems, including Others (Age,
2010). Due to the increase in the number of elderly,
the development of care systems is of great
importance for improving the quality of life of older
people (Jin, Simpkins, Ji, Leis, and Stambler, 2015),
which is included in the development of the systems
Ambient Assisted Living (AAL) and Enhanced
Living Environments (ELE) systems (Botia, Villa,
and Palma, 2012; Dobre, Mavromoustakis, Garcia,
Goleva, and Mastorakis, 2016; Garcia, 2016; Garcia,
Rodrigues, Elias, and Dias, 2014; Goleva et al.,
2017; Huch et al., 2012; Siegel, Hochgatterer, and
Dorner, 2014).
However, the development of these systems may
have limitations in the recognition of the activities
performed, including the positioning of the sensors
in smart environments, the environmental noise, the
implementation of the developed methods, the large
number of activities performed by older people, the
limited resources of the mobile devices, and other
software and hardware limitations. This paper will
explore this limitations and present the possible
solutions for each limitations, finalizing with a real
environment analysis of some limitations.
This paragraph finalizes the Section 1 of this
paper, which introduces its topic. Section 2 presents
the background of the recent development in this
Pires, I., Garcia, N., Pombo, N. and Flórez-Revuelta, F.
Limitations of the Use of Mobile Devices and Smart Environments for the Monitoring of Ageing People.
DOI: 10.5220/0006817802690275
In Proceedings of the 4th International Conference on Information and Communication Technologies for Ageing Well and e-Health (ICT4AWE 2018), pages 269-275
ISBN: 978-989-758-299-8
Copyright
c
2019 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
269
topic. Our view of this topic and the validation of the
problem will be presented in the Section 3. Section 4
presents the discussion and results obtained. Finally,
the conclusions of this study will be presented in the
Section 5.
2 BACKGROUND
The monitoring of the activities performed by ageing
people may be performed in controlled or
uncontrolled environments. Firstly, the controlled
environments considered in this study are the smart
environments (e.g., smart homes), where the ageing
people are living, equipped with several sensors for
the recognition of the activities. Finally, the
uncontrolled environments considered in this study
are the different environments in real life, using the
mobile devices for the data acquisition and further
recognition of the activities.
Smart environments used for the recognition of
the activities performed by ageing people may be
equipped with cameras, temperature sensors,
altimeter sensors, accelerometer sensors, contact
switches, pressure sensors and Radio-frequency
identification (RFID) sensors. The recognition of the
activities in these environments are performed using
server-side processing methods. Botia et al. (2012)
used the cameras for the recognition of the presence
of the ageing people in home office, kitchen, living
room and outdoor spaces, and several activities,
including making coffee, walking on stairs and
working on a computer.
In (Chernbumroong, Cang, Atkins, and Yu,
2013), the authors used the altimeter, accelerometer
and temperature sensors for the recognition of
brushing teeth, feeding, dressing, sleeping, walking,
lying, ironing, walking on stairs, sweeping, washing
dishes and watching TV. (Kasteren and Krose, 2007)
implemented a method that used pressure sensors,
accelerometer sensors and contact switches for the
recognition of bathing, eating and toileting activities.
The accelerometers and RFID sensors may be
used for the recognition of pushing a shopping cart,
sitting, standing, walking, phone calling, taking
picture, running, lying, wiping, switching on skin
conditioner, hand shaking, reading, jumping and hair
brushing activities (Hong, Kim, Ahn, and Kim,
2008).
Other studies making use of only one type of
sensors available in smart environments. Firstly,
other authors used only accelerometer for the
recognition of making coffee, brushing teeth and
boiling water activities (Liming, Hoey, Nugent,
Cook, and Zhiwen, 2012). Secondly, other authors
used only RFID sensors for the recognition of phone
calling, preparing a tea, preparing a meal, making
soft-boiled eggs, using the bathroom, taking out the
trash, setting the table, eating, drinking, preparing
orange juice, cleaning the table, cleaning a toilet,
cleaning the kitchen, making coffee, sleeping,
getting a drink, getting a snack, using a dishwasher,
using a microwave, taking a shower, adjusting the
thermostat, using a washing machine, using the
toilet, vacuuming, leaving the house, reading,
receiving a guest, boiling a pot of tea, doing laundry,
boiling water, brushing hair, shaving face, washing
hands, watching TV and brushing teeth activities
(Cheng, Tsai, Liao, and Byeon, 2009; Danny,
Matthai, and Tanzeem, 2005; Hoque and Stankovic,
2012). Finally, other authors used ZigBee wireless
sensors for the recognition of watching TV,
preparing a meal and preparing a tea activities
(Suryadevara, Quazi, and Mukhopadhyay, 2012).
Related to the use of the data acquired from the
mobile devices, the implemented methods for the
recognition of activities may be implemented locally
on the mobile devices as a mobile application or
server-side, requiring a constant network connection.
Another challenge in the use of the mobile devices
for the recognition of activities is related to the
positioning of the mobile device, that affects the
reliability of the recognition methods. In addition,
the use of these devices should be adapted to the
hardware condition of these devices, such as limited
processing, battery, and storage capabilities.
The most used sensor for the recognition of
activities is the accelerometer sensor embedded in
the mobile devices, enabling the recognition of
several activities, including rowing, walking,
walking on stairs, jumping, jogging, running, lying,
standing, getting up, cycling, sitting, falling and
travelling with different transportation facilities
(Büber and Guvensan, 2014; Cardoso, Madureira,
and Pereira, 2016; Ivascu, Cincar, Dinis, and Negru,
2017; Khalifa, Lan, Hassan, Seneviratne, and Das,
2017; Tsai, Yang, Shih, and Kung, 2015).
The combination of the data acquired from the
accelerometer and the Global Positioning System
(GPS) receiver embedded on the mobile devices can
increase the number and accuracy of the recognition
of activities, including the sitting, standing, walking,
lying, walking on stairs, cycling, falling, jogging,
running, playing football and rowing (Ermes,
Parkka, Mantyjarvi, and Korhonen, 2008; Fortino,
Gravina, and Russo, 2015; Zainudin, Sulaiman,
Mustapha, and Perumal, 2015).
HSP 2018 - Special Session on Healthy and Secure People
270
Table 1. Relation between the activities recognized in smart environments and with mobile devices.
Activities:
Smart Environments:
Mobile devices:
Adjusting the thermostat; brushing hair;
cleaning a toilet; cleaning the kitchen; doing
laundry; getting a drink; getting a snack;
receiving a guest; setting the table; shaving
face; taking a shower; taking out the trash;
using a dishwasher; using a microwave;
using a washing machine; vacuuming;
washing hands; preparing orange juice;
making soft-boiled eggs
RFID sensors
-
Bathing
pressure sensors; accelerometers;
contact switches; RFID sensors
-
Boiling water; hair brushing; hand shaking;
phone calling; pushing a shopping cart;
switching on skin conditioner; taking
picture; wiping
Accelerometer; RFID sensors
-
Brushing teeth; dressing; Feeding; washing
dishes; Ironing; sweeping
Altimeter; Accelerometer;
Temperature sensor
-
Cleaning the table
RFID sensors
Accelerometer; Microphone
Cooking; Driving; Shopping; Using a
smartphone
-
Accelerometer; Microphone
Cycling
-
Accelerometer; Microphone;
GPS receiver
Drinking; leaving the house
RFID sensors; Cameras
Accelerometer; Microphone;
GPS receiver
Eating; toileting
pressure sensors; accelerometers;
contact switches; RFID sensors;
Cameras
Accelerometer; Microphone;
GPS receiver
Falling; Jogging; Playing football; Rowing
-
Accelerometer; GPS receiver
Getting up; Travelling
-
Accelerometer
Jumping
Accelerometer; RFID sensors
accelerometer
Lying
Altimeter; Accelerometer;
Temperature sensor
Accelerometer; GPS receiver
Making coffee
Cameras; Accelerometer; RFID
sensors
-
Preparing a meal; preparing a tea
RFID sensors; ZigBee sensors
-
Reading
Accelerometer; RFID sensors
Accelerometer; Microphone
Running; Sitting; standing
Accelerometer; RFID sensors
Accelerometer; GPS receiver
Sleeping
Altimeter; Accelerometer;
Temperature sensor; RFID
sensors; Cameras
Accelerometer; Microphone;
GPS receiver
Walking
Altimeter; Accelerometer;
Temperature sensor; RFID
sensors
Accelerometer; GPS receiver
Walking on stairs
Cameras; Altimeter;
Accelerometer; Temperature
sensor
Accelerometer; GPS receiver
Watching TV
Altimeter; Accelerometer;
Temperature sensor; RFID
sensors; ZigBee sensors
Accelerometer; Microphone
Using a computer
Cameras
Accelerometer; Microphone
Limitations of the Use of Mobile Devices and Smart Environments for the Monitoring of Ageing People
271
The combination of the data acquired from the
accelerometer and microphone embedded on mobile
the mobile devices allows the recognition of cycling,
cleaning table, shopping, toileting, cooking,
watching TV, eating, working on a computer,
reading, using a smartphone, driving, sleeping and
nursing activities (Inoue, Ueda, Nohara, and
Nakashima, 2015; Nishida, Kitaoka, and Takeda,
2014).
Finally, the combination of the sensors available
in smart environments, i.e., cameras and RFID
sensors, and the sensors available in the mobile
devices, i.e., accelerometer, GPS receiver and
microphone, may increase the accuracy of the
recognition of activities, including leaving the
house, toileting, sleeping, eating and drinking
(Ordonez, de Toledo, and Sanchis, 2013).
Table 1 summarizes the activities recognized by
sensors presented in this section as example of
activities that may be recognized in smart
environments and/or with mobile devices.
Regarding several studies (Alam, Reaz, and Ali,
2012; Arif, El Emary, and Koutsouris, 2014;
Jakkula, 2007; Montoro-Manrique, Haya-Coll, and
Schnelle-Walka; Poslad, 2011), the main problems
using smart environments for the monitoring of the
activities of ageing people are:
The positioning of the sensors in the smart
environment may affect the correct
identification of the object, environment
and/or people;
The sensors should cooperate between them
and, in case of fails, the system will return
incorrect results;
These environments require a constant
connection to a server and, when the sensors
fails, the activities are not recognized or have
invalid results;
The different number of sensors available
may affect the recognition of the activities;
Due to the use of distributed systems, the
security and the resilience of the data is
important for the recognition of the activities.
Regarding several studies (Arif et al., 2014; Bert,
Giacometti, Gualano, and Siliquini, 2014;
Choudhury et al., 2008; Montoro-Manrique et al.;
Poslad, 2011; Santos et al., 2016), the main
problems using the sensors available in mobile
devices for the monitoring of the activities of ageing
people are:
The use of multiple sources for the data
acquisition (i.e., smartphone and smartwatch
sensors) allows the acquisition of more
physical and physiological parameters, but it
required a constant connection by Bluetooth
between them;
The use of the sensors and the Bluetooth
and/or Wi-Fi connection increases the speed
of battery draining;
The execution of the data processing in the
mobile devices may decrease their
performance;
Due to the low resources of these devices, the
accuracy of the sensors may not be constant
during the data acquisition process;
The user may not use their equipments in the
correct placement during the data acquisition
process;
Some studies present methods that require a
constant data connection for further
processing of the data acquired;
The different number of sensors embedded in
the mobile devices may affect the recognition
of the activities;
Due to the use of multiple devices, the
security and the resilience of the data is
important for the recognition of the activities;
Finally, the ageing people commonly do not
use these devices and they needs a
familiarization with these devices.
3 METHODS AND MATERIALS
For the research about the limitation of the use of
mobile devices and smart environments
technologies, we have discovered several limitations
of these technologies in the regular use for the
recognition of the daily activities of ageing people,
but these limitations may be reduced with
lightweight methods. Mainly, the limitations of the
use of mobile devices are related to the low
resources and the limitations of the use of smart
environments are related to the positioning of the
sensors.
Based in a mobile application that implements
the framework described in (I. Pires, N. Garcia, N.
Pombo, and F. Flórez-Revuelta, 2016; Pires, Garcia,
and Flórez-Revuelta, 2015; I. M. Pires, N. M.
Garcia, N. Pombo, and F. Flórez-Revuelta, 2016),
we used the mobile application in four mobile
devices (i.e., Sony Ericsson Xperia Neo, Sony
Ericsson Xperia Live Walkman, BQ Aquarius 5.7
and Samsung Galaxy J3) in order to verify the
restrictions in the use of these applications, focusing
on the speed of battery draining, the performance of
the mobile devices during the use of the mobile
HSP 2018 - Special Session on Healthy and Secure People
272
application, and their adaptation to the number of
sensors available in the mobile devices. This mobile
application captures 5 seconds of the sensors data
every 5 minutes and processes the data acquired
with machine learning methods for the recognition
of the activities performed. During the performance
of these experiments, the mobile devices are in use
continuously with other tasks, including receiving
and making calls and/or text messages, accessing to
the Internet and others.
The recognition of the activities does not need a
constant data acquisition and processing, and the use
of a technique to enable and disable the acquisition
and processing of the sensors’ data over the time
may reduce the effects in battery consumption and
processing capabilities. The effects depending on
number of sensors can be avoided with the
construction of mobile applications with methods
that should be a function of the number of sensors
available at the moment of the data acquisition and
processing. The unique limitation that is difficult to
control is the positioning of the mobile devices
related to the users’ body, however it is possible to
stop the data acquisition when the data seems to be
inconsistent.
4 DISCUSSION AND RESULTS
Regarding the experiments performed, we verified
that the performance of the mobile devices is only
affected during the data acquisition and processing
process. In general, the battery consumption is
affected, as verified in the figure 1, but the minimum
time between the fully charged and the empty
battery (16 hours) was achieved with the Sony
Ericsson Xperia Live Walkman (2011) that is an old
device. The maximum performance and battery life
was achieved with the BQ Aquarius 5.7 (2013) that
is more recent than Sony Ericsson Xperia Live
Walkman (2011), reporting approximately 68 hours
of battery life.
As verified, our study confirms the findings that
the data acquisition and process of the sensors’ data
affects the battery life and the power processing
capabilities, but we verified that the minimum value
is 16 hours of battery life. Thus, the recognition of
activities using the mobile devices may be used,
because currently these devices should receive a
daily recharge. The different implementations of the
methods can reduce this impact, and the methods
that should be implemented in the mobile devices
should be lightweight methods. The server-side
processing and the use of multiple device for the
data acquisition may have a lot of connectivity
Figure 1. Battery Consumption using the mobile
application for the recognition of activities. The horizontal
axis represents the time between the fully charged and
empty battery (h). The vertical axis represents the level of
battery charge (%).
issues, needing a constant connection to the Internet
or between devices. Regarding the use of the mobile
devices, the more stable solution consists on the use
of the local processing with methods that needs low
resources. Finally, regarding the use of smart
environments, the implementation of backup
systems and more sensors in strategic placements
may increase the reliability of these systems.
However, the use of network connections should
implement methods to minimize the security and
privacy problems.
5 CONCLUSIONS
Currently, the use of the technological equipment is
increasing with the ageing people to maintain the
contact with other people and it may be used for the
monitoring of the ageing people, promoting the well
independent living.
This paper confirms that these devices have
several restrictions. In the case of the use of smart
environments, the main problems are related to the
connectivity issues and positioning of the sensors. In
case of the use of mobile devices, the problems are
related to the low resources, the placement of the
mobile device and the connectivity issues.
We performed some experiments with different
devices for the recognition of activities using a
mobile application with local processing methods,
0%
20%
40%
60%
80%
100%
0 8 16 24 32 40 48 56 64 68
Sony Ericsson Xperia Neo
Sony Ericsson Xperia Live Walkman
BQ Aquarius 5.7
Samsung Galaxy J3
Limitations of the Use of Mobile Devices and Smart Environments for the Monitoring of Ageing People
273
verifying that the battery drains with different
speeds, between 16 and 68 hours. The performance
is affected, but it is reduced acquiring a small
window of sensors’ data in every defined time
interval.
The technology can promote the independent
living of ageing people, helping in the emergency
situations, controlling their lifestyle and increasing
their life’s quality.
ACKNOWLEDGEMENTS
This work was supported by FCT project
UID/EEA/50008/2013 (Este trabalho foi suportado
pelo projecto FCT UID/EEA/50008/2013).
The authors would also like to acknowledge the
contribution of the COST Action IC1303
AAPELE Architectures, Algorithms and Protocols
for Enhanced Living Environments.
REFERENCES
Age, U. (2010). Technology and older people evidence
review. Age UK, London.
Alam, M. R., Reaz, M. B. I., and Ali, M. A. M. (2012). A
Review of Smart HomesPast, Present, and Future.
IEEE Transactions on Systems, Man, and Cybernetics,
Part C (Applications and Reviews), 42(6), 1190-1203.
doi:10.1109/tsmcc.2012.2189204
Arif, M. J., El Emary, I. M., and Koutsouris, D. D. (2014).
A review on the technologies and services used in the
self-management of health and independent living of
elderly. Technol Health Care, 22(5), 677-687.
doi:10.3233/THC-140851
Bert, F., Giacometti, M., Gualano, M. R., and Siliquini, R.
(2014). Smartphones and health promotion: a review
of the evidence. J Med Syst, 38(1), 9995.
doi:10.1007/s10916-013-9995-7
Botia, J. A., Villa, A., and Palma, J. (2012). Ambient
Assisted Living system for in-home monitoring of
healthy independent elders. Expert Systems with
Applications, 39(9), 8136-8148.
doi:10.1016/j.eswa.2012.01.153
Büber, E., and Guvensan, A. M. (2014, 21-24 April 2014).
Discriminative time-domain features for activity
recognition on a mobile phone. Paper presented at the
2014 IEEE Ninth International Conference on
Intelligent Sensors, Sensor Networks and Information
Processing (ISSNIP).
Cardoso, N., Madureira, J., and Pereira, N. (2016).
Smartphone-based Transport Mode Detection for
Elderly Care. 2016 Ieee 18th International Conference
on E-Health Networking, Applications and Services
(Healthcom), 261-266.
doi:10.1109/HealthCom.2016.7749465
Cheng, B.-C., Tsai, Y.-A., Liao, G.-T., and Byeon, E.-S.
(2009). HMM machine learning and inference for
Activities of Daily Living recognition. The Journal of
Supercomputing, 54(1), 29-42. doi:10.1007/s11227-
009-0335-0
Chernbumroong, S., Cang, S., Atkins, A., and Yu, H.
(2013). Elderly activities recognition and classification
for applications in assisted living. Expert Systems with
Applications, 40(5), 1662-1674. doi:10.1016/j.eswa.
2012.09.004
Choudhury, T., Borriello, G., Consolvo, S., Haehnel, D.,
Harrison, B., Hemingway, B., . . . Wyatt, D. (2008).
The Mobile Sensing Platform: An Embedded Activity
Recognition System. IEEE Pervasive Computing,
7(2), 32-41. doi:10.1109/mprv.2008.39
Danny, W., Matthai, P., and Tanzeem, C. (2005).
Unsupervised activity recognition using automatically
mined common sense Proceedings of the 20th national
conference on Artificial intelligence - Volume 1 %@
1-57735-236-x (pp. 21-27). Pittsburgh, Pennsylvania:
AAAI Press.
Dobre, C., Mavromoustakis, C. x., Garcia, N., Goleva, R.
I., and Mastorakis, G. (2016). Ambient Assisted Living
and Enhanced Living Environments: Principles,
Technologies and Control: Butterworth-Heinemann.
Ermes, M., Parkka, J., Mantyjarvi, J., and Korhonen, I.
(2008). Detection of Daily Activities and Sports With
Wearable Sensors in Controlled and Uncontrolled
Conditions. Trans. Info. Tech. Biomed., 12(1), 20-26.
doi:10.1109/titb.2007.899496
Fortino, G., Gravina, R., and Russo, W. (2015, 6-8 May
2015). Activity-aaService: Cloud-assisted, BSN-based
system for physical activity monitoring. Paper
presented at the 2015 IEEE 19th International
Conference on Computer Supported Cooperative
Work in Design (CSCWD).
Garcia, N. M. (2016). A Roadmap to the Design of a
Personal Digital Life Coach ICT Innovations 2015:
Springer.
Garcia, N. M., Rodrigues, J. J. P. C., Elias, D. C., and
Dias, M. S. (2014). Ambient Assisted Living: Taylor
and Francis.
Goleva, R. I., Garcia, N. M., Mavromoustakis, C. X.,
Dobre, C., Mastorakis, G., Stainov, R., . . . Trajkovik,
V. (2017). AAL and ELE Platform Architecture.
He, W., Goodkind, D., and Kowal, P. R. (2016). An aging
world: 2015: United States Census Bureau.
Hong, Y.-J., Kim, I.-J., Ahn, S. C., and Kim, H.-G. (2008).
Activity Recognition Using Wearable Sensors for
Elder Care. Paper presented at the Future Generation
Communication and Networking, 2008. FGCN '08.
Second International Conference on, Hainan Island.
Hoque, E., and Stankovic, J. (2012, 21-24 May 2012).
AALO: Activity recognition in smart homes using
Active Learning in the presence of Overlapped
activities. Paper presented at the Pervasive Computing
Technologies for Healthcare (PervasiveHealth), 2012
6th International Conference on.
Huch, M., Kameas, A., Maitland, J., McCullagh, P. J.,
Roberts, J., Sixsmith, A., and Augusto, R. W. J. C.
HSP 2018 - Special Session on Healthy and Secure People
274
(2012). Handbook of Ambient Assisted Living:
Technology for Healthcare, Rehabilitation and Well-
being - Volume 11 of Ambient Intelligence and Smart
Environments: IOS Press.
Inoue, S., Ueda, N., Nohara, Y., and Nakashima, N.
(2015). Mobile activity recognition for a whole day:
recognizing real nursing activities with big dataset.
Paper presented at the Proceedings of the 2015 ACM
International Joint Conference on Pervasive and
Ubiquitous Computing, Osaka, Japan.
Ivascu, T., Cincar, K., Dinis, A., and Negru, V. (2017, 22-
24 June 2017). Activities of daily living and falls
recognition and classification from the wearable
sensors data. Paper presented at the 2017 E-Health
and Bioengineering Conference (EHB).
Jakkula, V. (2007). Predictive Data Mining to Learn
Health Vitals of a Resident in a Smart Home. Paper
presented at the Seventh IEEE International
Conference on Data Mining - Workshops.
Jin, K., Simpkins, J. W., Ji, X., Leis, M., and Stambler, I.
(2015). The Critical Need to Promote Research of
Aging and Aging-related Diseases to Improve Health
and Longevity of the Elderly Population. Aging Dis,
6(1), 1-5. doi:10.14336/AD.2014.1210
Kasteren, T. v., and Krose, B. (2007, 24-25 Sept. 2007).
Bayesian activity recognition in residence for elders.
Paper presented at the Intelligent Environments, 2007.
IE 07. 3rd IET International Conference on.
Khalifa, S., Lan, G., Hassan, M., Seneviratne, A., and Das,
S. K. (2017). HARKE: Human Activity Recognition
from Kinetic Energy Harvesting Data in Wearable
Devices. IEEE Transactions on Mobile Computing,
PP(99), 1-1. doi:10.1109/TMC.2017.2761744
Liming, C., Hoey, J., Nugent, C. D., Cook, D. J., and
Zhiwen, Y. (2012). Sensor-Based Activity
Recognition. IEEE Transactions on Systems, Man, and
Cybernetics, Part C (Applications and Reviews),
42(6), 790-808. doi:10.1109/tsmcc.2012.2198883
Montoro-Manrique, G., Haya-Coll, P., and Schnelle-
Walka, D. Internet of Things: From RFID Systems to
Smart Applications. Upgrade: European Journal for
the Informatics Professional, XII(1).
Nishida, M., Kitaoka, N., and Takeda, K. (2014, 9-12 Dec.
2014). Development and preliminary analysis of
sensor signal database of continuous daily living
activity over the long term. Paper presented at the
Signal and Information Processing Association Annual
Summit and Conference (APSIPA), 2014 Asia-Pacific.
Ordonez, F. J., de Toledo, P., and Sanchis, A. (2013).
Activity recognition using hybrid generative/
discriminative models on home environments using
binary sensors. Sensors (Basel), 13(5), 5460-5477.
doi:10.3390/s130505460
Pires, I., Garcia, N., Pombo, N., and Flórez-Revuelta, F.
(2016). From Data Acquisition to Data Fusion: A
Comprehensive Review and a Roadmap for the
Identification of Activities of Daily Living Using
Mobile Devices. Sensors, 16(2), 184.
Pires, I. M., Garcia, N. M., and Flórez-Revuelta, F. (2015).
Multi-sensor data fusion techniques for the
identification of activities of daily living using mobile
devices. Paper presented at the Proceedings of the
ECMLPKDD 2015 Doctoral Consortium, European
Conference on Machine Learning and Principles and
Practice of Knowledge Discovery in Databases, Porto,
Portugal.
Pires, I. M., Garcia, N. M., Pombo, N., and Flórez-
Revuelta, F. (2016). Identification of Activities of
Daily Living Using Sensors Available in off-the-shelf
Mobile Devices: Research and Hypothesis. Paper
presented at the Ambient Intelligence-Software and
Applications7th International Symposium on
Ambient Intelligence (ISAmI 2016).
Poslad, S. (2011). Ubiquitous computing: smart devices,
environments and interactions: John Wiley and Sons.
Santos, J., Rodrigues, J. J. P. C., Silva, B. M. C., Casal, J.,
Saleem, K., and Denisov, V. (2016). An IoT-based
mobile gateway for intelligent personal assistants on
mobile health environments. Journal of Network and
Computer Applications, 71, 194-204.
doi:10.1016/j.jnca.2016.03.014
Siegel, C., Hochgatterer, A., and Dorner, T. E. (2014).
Contributions of ambient assisted living for health and
quality of life in the elderly and care services--a
qualitative analysis from the experts' perspective of
care service professionals. BMC Geriatr, 14, 112.
doi:10.1186/1471-2318-14-112
Suryadevara, N. K., Quazi, M. T., and Mukhopadhyay, S.
C. (2012, 26-29 June 2012). Intelligent Sensing
Systems for Measuring Wellness Indices of the Daily
Activities for the Elderly. Paper presented at the
Intelligent Environments (IE), 2012 8th International
Conference on.
Tsai, P. Y., Yang, Y. C., Shih, Y. J., and Kung, H. Y.
(2015, 6-9 Sept. 2015). Gesture-aware fall detection
system: Design and implementation. Paper presented
at the 2015 IEEE 5th International Conference on
Consumer Electronics - Berlin (ICCE-Berlin).
Zainudin, M. N. S., Sulaiman, M. N., Mustapha, N., and
Perumal, T. (2015). Activity Recognition based on
Accelerometer Sensor using Combinational
Classifiers. 2015 Ieee Conference on Open Systems
(Icos), 68-73. doi:10.1109/icos.2015.7377280
Limitations of the Use of Mobile Devices and Smart Environments for the Monitoring of Ageing People
275