An IOT Based Low Power Health Monitoring with Active Personal Assistance

International Journal of Trend in Scientific Research and Development (IJTSRD)
Volume 4 Issue 1, December 2019 Available Online: www.ijtsrd.com e-ISSN: 2456 – 6470
@ IJTSRD | Unique Paper ID – IJTSRD29603 | Volume – 4 | Issue – 1 | November-December 2019 Page 486
An IOT Based Low Power Health Monitoring with
Active Personal Assistance
B. N. Meenakshi1, Mrs. N. V. Durga2
1M.Tech Scholar, 2Assistant Professor,
1,2V. S. Lakshmi Engineering College, Matlapalem, Andhra Pradesh, India
ABSTRACT
Among sensible goals of active and assisted livingparadigmistheunobtrusive
monitoring of daily living activities. A lot of research has been going on
continuous home and personal monitoring applications. There are many
solutions were adapted by these technologies to make better remote
monitoring applications. The traditional continuous home and personal
monitoring systems which are implemented with traditional client-server
architecture which may fail in factors like low power consumption, un-
deterministic data deliverytime,Moresensitivetoexternal connectivityissues
(temporary failures of servers), adhoc networks (using ZigBee and Z-wave
etc.) and also increase the cost of implementation. However, when dealing
with the home environment, and especially with older adults, obtrusiveness,
usability, and cost concerns are of the utmost relevanceforactiveandassisted
Living (AAL) joint program. With advent of cloud services, the continuous
remote monitoring based applicationsbecametruly“plug-and-play”approach
implementation and also reduce the problems of temporary failures. One of
the biggest challenges in this area is to make such application devices work
with low power (battery based applications). The main drawback comesfrom
the higher power consumption,inherentlyneededtosustainmuchhigherdata
rates. In this project, a solution is proposed to improve the low power
consumption in Wi-Fi sensors by making use of advanced RF based
Microprocessor from Texas instruments (CC3200). Bed Occupancy sensor
automation has been designed and implemented to test the feasibility of the
approach. The TI CC3200 comes with ARM-Cortex-M4 as a core and inbuilt
Wi-Fi subsystem. The CC3200 provides different power modes to make the
device enter into sleep or hibernate mode. This device will only enter only in
work phase when the sensor is active state. During this phase, the processor
sample and processes the sensor data and uploads to the cloud using REST
API. Thing speak is an IoT cloud service used to present the sensory data as
graphs, bar charts, and dashboards on the cloud remaining time it will enter
into sleep phase to save the power of the device, so that it will extend the
battery life time of the device.
KEYWORDS: SoC, WBAN, IoT, Rest, AAL, ZigBee
How to cite this paper: B. N. Meenakshi |
Mrs. N. V. Durga "An IOT Based Low
Power Health Monitoring with Active
Personal Assistance"
Published in
International Journal
of Trend in Scientific
Research and
Development(ijtsrd),
ISSN: 2456-6470,
Volume-4 | Issue-1,
December 2019, pp.486-489, URL:
https://www.ijtsrd.com/papers/ijtsrd29
603.pdf
Copyright © 2019 by author(s) and
International Journal ofTrendinScientific
Research and Development Journal. This
is an Open Access article distributed
under the terms of
the Creative
CommonsAttribution
License (CC BY 4.0)
(http://creativecommons.org/licenses/by
/4.0)
I. INRODUCTION
The average population age [1] has been increment in a
progressive manner, which has a deep social and economic
impact, most importantly. The effects of social and
healthcare policies between younger and older class-ages
creating a progressive imbalance, questioning the
sustainability of long-established welfare models. Reducing
the need of social and health-care services currently
associated with aging is a primary goal, in order to preserve
quality of life of aging population in an affordable way. The
current popular Communication and Information
technologies may contribute to the development of active
aging scenarios [2], and are at the core of many worldwide
research initiatives and programs. Among them, the “active
and assisted Living joint program” (AAL-JP) [3] is exploring
opportunities fostered by Communication and Information
Technologies to improve the conditions of life for older
adults.
The implementation age-friendly home environments is a
relevant goal: concepts such as smart homes [4]–[6],
ambient intelligence [7], telemedicine [8], [9], and
telemonitoring [10]–[12] converge in such a perspective.
Key enabling technologies include sensing, reasoning,
communicating, and interacting components. In order to be
effective, deployment of ICT solutions within the home
environment should not be perceived as intrusive, should
not require bothersome changes in lifestyles and habits and
needs to be accessible and trustworthy to (possibly
unskilled) older adults. This scenario introduces stringent
and peculiar design constraints. According topeople-centric
paradigms we describe how the above concepts have driven
the evolution of “smart home” systems.
Based on such experiences, we focus here on the need of
solutions being reliable, inexpensive, easy to deploy and
maintain, interoperable and highly customizable (for
personalizationandmanagingofneedsevolvingovertime).A
IJTSRD29603

International Journal of Trend in Scientific Research and Development (IJTSRD) @ www.ijtsrd.com eISSN: 2456-6470
promising AAL objective consists of the exploitation of data
coming from the home environment (through nonintrusive
sensors) for the inference of “behavioral” data patterns,
possibly meaningful in evaluating risk conditions or needs
related to health and well-being.
For instance, behavioral remotemonitoringisexpectedto be
most relevant in early assessment and identification of
dementia and in the related safety provision[15].Inorder to
implement low cost and low power AAL based age-friendly
home environments, the requirement of making use of low
power Source technology.Withtheadventofminiaturization
of SOC chip technology, chip manufacturing companieshave
been developing high performance digital microcontroller
along with inbuilt Wi-Fi technology for the development of
it.The Texas Instruments (TI)companydevelopeda lowcost,
high speed and low power microcontrollers (named simple
link wireless MCUs – CC3200) as SoC with a size9mmx9mm.
In this project, CC3200 is used as independent wireless
sensor nodes for developing the application as per
requirement. This CC3200 SoC comes as an integration of
Wi-Fi-module along with ARM-Cortex M4 digital processor.
This chip also has analog sub modules like, programmable
comparator, and Analog to Digital converters. A cloud based
application is developed to monitor and display the
information coming from CC3200 sensor node [5].
The rest of the paper is organized as follows. Section II
describes the proposed system related work of this paper.
Section III presents the overall architecture and complete
block diagram of proposed system forthisproject.SectionIV
presents the software and hardware implementation of the
proposed system. Section V presents theresultsofhardware
and BED Occupancy sensor which is on the Things Speak
cloud service of this paper. Section VI provides the
conclusion of the paper.
Figure1: AAL Based Wi-fi home monitoring system
Figure2: A simple model of Existing System
architecture for active-assisted living.
II. PROPOSED SYSTEM
The present research on active and assisted living focusing
on home-monitoring systems have been reported in [18]-
[20] by. Such systems use a large number of different
sensors to track the daily activities. In figure 1, a generic
architecture of the home-monitoring is shown figure 1.
Referring to different variety of classes of home sensors, a
home gateway, which stores, aggregates, and processes
sensor data, and an Internet gateway providing access to
cloud-based services like thing speakexcite, etc. Deploying
the sensor based network in a user’s home is a highly
demanding design task, due to the non-intrusiveness,
usability, and acceptability concerns mentioned in the
introduction above: initially, home sensor systems-based
there connectivity over wired technologies,exploiting either
proprietary protocol [21]–[23] (E.g., X10, KNX, and LON), or
open standards such as Ethernet [24]. With the advent of
Wireless communicationthe connectivityofthehomesensor
network is providing much higher flexibility andinstallation
ease, at the expense of some delicate design issues, dealing
with the propagation of radio signals within a built
environment. Also, some maintenance tasks are introduced
(checking and replacing/recharging batteries, for battery-
operated devices). In this case too, a number of different
varieties of technologies have been introduced: among the
most diffused, Bluetooth is mostly exploited for short-range
communication (e.g., body area networks(BAN))whereas Z-
wave [25] and ZigBee [26]–[28], protocols (among many
others) have emerged as most practical options for the
implementation of a home sensor network.
III. PROPOSED SYSTEM ARCHITECTURE
The proposed system active and assistive home monitoring
is shown in figure 2.
Figure3: Implemented block diagram Proposed
System for active-assisted living
The proposed system architecture is a single SystemonChip
(SoC) and Wi-Fi connectivity can be used to monitor all the
normal human vitals and directly send such information to
web services without using any personal servers.Therecent
advancements in Wi-Fi technology will allow the Wi-Fi
devices to operate with low power. So by using this IP based
multiple sensor node instead of multiple BIN’s will reduce
the cost and power requirement for remote heath
monitoring systems. Because of the Internet of Things, the
multiple sensor data from proposed device can be viewed
from anywhere and anytime.
The proposed system consists of i) Bed-Occupancy Sensor,
which converts the analog pressure into analog voltage. ii)
Sampling and ADC section, which converts analog electrical

signals to digital signals, which in turn processedbythehigh
performance digital ARM microcontroller. iii) The ARM
microcontroller processes the digital data and converts
internet IPv6 data packets. iv) The wireless transceiver
module allow the device to get connect to router.
IV. PROPOSED SYSTEM IMPLEMENTATION
The working of the proposed system implementation is
divided into three parts. Since the embeddedprocessorused
in this device runs with Real Time Embedded Operating
System. The following sections will be executed as an
independent parallel task in the processor itself using real
time operating system.
1. Bed-Occupancy Sensor
2. Display Section (LCD Booster pack)
3. Processing Section
4. IoT Connectivity
1. Bed-Occupancy Sensor:
The bed occupancy sensor consists of a bed pressure pad
[49], which is placed underneath the mattress of the user.
The pressure sensor behaves as a variable resistor,lowering
its resistance value when pressed. It is therefore connected
as a pull-down element in a voltage divider, theoutputofthe
pressure sensor is connected to an analog input of the
microcontroller hardware board. The long cable features a
plug and play connector, to avoid tearing off the cable (for
instance while making the bed). An additional digital input,
therefore, comes from the cable connector, to signal a fault
condition (disconnected pad). Furthermore, the battery
voltage is transmitted, to allow for remote maintenance
tasks. The chair occupancy sensor works in the same way,
consisting of chair pressure pad in order to provide a
complete occupancy solution.
Fig Figure 4: Bed-Occupancy Sensor.
2. The Display Section:
The Sharp Memory LCD Booster Pack display module
comprised of 96x96 pixels to render of smooth-moving
graphics with 50% reflectance as shown in figure 5. We will
give the operating supply voltage from 3v to 5v.This display
is based on the LS013B4DN04 display and comes as a plug
and play module, so CC3200 Launch Pad Evaluation Kit
programmers can use this readymade Booster Pack to
display analog sensor readings, time & other related
information. This display will consume low power use of
10uW. The booster pack LCD is visible in a 0.5-lux
environment without requirement of external light source.
A Reflective panel of the display comes as white and
black with aspect ratio of 1:1
It has operating supply voltage of 3v and operating
temperature of -10c to +60c.
1.3-inch display screen has the resolution of 96x96
pixels (9216 pixel stripe array)
Display control can be controlled by serial peripheral
interface protocol (SPI)
Typical power consumption ofthedisplaymodule6uW-
10uW(static mode, depends on update rate)
Figure5: LCD booster pack
3. Processing section:
The CC3200 launch pad is a low cost evalution platform for
ARM cortex-M4 processor, which process the Bed-
Occupancy sensor and temperature samples and converts
them into digital values using its internal 12-bit ADC. The
ARM processor further process the ADC values and then
converts them as TCP packets, which can be easy to send via
internet using TCP/IP reference model. This CC3200 launch
pad also comeswithintegratedtemperaturesensorTMP006,
these temperature values taken as body temperature and
sends it to the network.
4. IoT Connectivity:
The CC3200 launch pad board comes with integrated on-
chip Wi-Fi module. This Wi-Fi module consumes very low
power during the transmission/reception of the wireless
data. It's just to program as station mode to connect tohome
router, which in turn connects to internet. Alternatives to
ThingSpeak are Android Things, Beebotte, DataGekko etc.
ThingSpeak portal is an IoT cloud based services, where we
can upload the sensor data and plot that data as graphs and
bar charts. Through programming, it's possible to configure
to different cloud based services.
V. RESULTS
The Proposed System implementation show in figure6, the
right side of the figure shows the pressure sensor. Bottom
red color board of the figure is CC3200 MCU launch pad
board, which is it consists of ARM cortex--M4 processor and
on-chip Wi-Fi module.Thedisplay(96x96LCDbooster pack)
showing message about the IoT cloud (Thingspeak)
connectivity.
Figure6: Hardware implementation of proposed
system (CC3200, LCD Booster Pack, Pressure sensor).

The figure 7 showing both temperature and bed occupancy
sensor data on the display and at the same time on the
Thinks peak IoT cloud based service as shown in figure 9.
Here the field1 represents the temperature data and field2
represents Bed Occupancy data.
Figure7: Temperature and Bed Occupancy data
The below figure 8 shows the amount of current in mill-
amperes is shown, the system connecting with cloud based
services. Therefore, the entire system will consume a
maximum of 2mA current while transmitting the data to
cloud. Because of this, CC3200 is the mostsuitableprocessor
module for developing Active and Assisted Living Home
Automation.
Figure8: The amount current consuming by the system
when connecting with cloud based services
The figure 9 shows, live data plotting on the Things peak IoT
cloud based services. The right side graph is for bed
occupancy and left one is temperature data.
Figure9: shows the both temperature and bed
occupancy data wave forms on Things peak cloud.
VI. CONCLUSION
In this paper, CC3200 MCU Launchpad is the one of the best
suitable processor for development of active and assisted
living for home automation. The Integration of ARM cortex
M4 processor and on-chip Wi-Fi module will reduce the
space and wiring connections. At the same time, everything
wills ease configured. As the results shows, it will take very
less power and available in reasonable price which is main
requirement for AAL.
REFERENCES
[1] World Health Statistics2016:MonitoringHealthforthe
SDGs, WHO Report. Accessed: Sep. 2017. [Online].
Available:http://www.who.int/Gho/publications/worl
d_health_statistics/2016/en/
[2] C. Siegel and T. E. Dorner, “Information technologies
for active and assisted living—Influencestothequality
of life of an ageing society,” Int. J. MED. Inform., vol.
100, pp. 32–45, Apr. 2017.
[3] AAL Programmed Website. Accessed - Sep, 2017.
[Online]. Available: http://www.aal-europe.eu/
[4] L. Liu, E. Stroulia, J. Nikolaidis, A. Miguel-Cruz, andA.R.
Rincon, “Smart homes and home health monitoring
technologies for older adults: Asystematicreview,”Int.
J. MED. Inform., vol. 91, pp. 44–59, Jul. 2016.
[5] G. Sprint, D. J. Cook, R. Fritz, and M. Schmitt-
Edgecombe, “Using smart homes to detect and analyze
health events,” Computer, vol. 49, no. 11, pp. 29–37,
Nov. 2016.
[6] R. Li, B. Lu, and K. D. McDonald-Maier, “Cognitive
assisted living ambient system: A survey,” Digit.
Common. Netw. Vol. 1, no. 4, pp. 229–252, Nov. 2015.
[7] D. J. Cook, J. C. Augusto, and V. R. Jakkula, “Ambient
intelligence:- Technologies, applications, and
opportunities,” Pervasive Mobile Comput., vol. 5, no. 4,
pp. 277–298, Aug. 2009.
[8] M. Krol, “Telemedicine,” IEEE Potentials, vol. 16, no. 4,
pp. 29–31, Oct. 1997.

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