Unit 4 Pharmaceutical Organic Chemisty 3 Quinoline
A5.pptx
1. 1
IoT BASED HEALTH MONITORING SYSTEM
PRESENTING BY :
MOHANRAJ M [20BEE007]
DHANUSH G[20BEE031]
BALAKRISHNAN K[20BEE043]
Dr. MAHALINGAM COLLEGE OF ENGINEERING AND
TECHNOLOGY, POLLACHI.
GUIDED BY :
Mr. T. SATHESH KUMAR ,M.E,
Designation: ASSISTANT PROFESSOR/EEE
EEE Department 19EEPN6601-Innovative and Creative Project
BATCH NO : A-05
Department Of Electrical and Electronics Engineering
2. OBJECTIVES
The main objective of our project is to design a health monitoring system.
We design a mobile application for collecting the data of the patient.
2
EEE Department 19EEPN6601-Innovative and Creative Project
3. INTRODUCTION
Health play a very important role in our day today life. With the increased rate of
medically challenged people, remote healthcare has become a part of our life.
To enable seamless networking between the patients, medical devices and
physicians.
Keeping track of the health status of your patient at home is a difficult task,
because of the busy schedules and our daily life work.
We determine heart rate, oxygen level, body temperature and stress level these
data are stored in the mobile applications.
EEE Department 19EEPN6601-Innovative and Creative Project 3
4. The nodemcu(esp32) is a wifi module ,which we connect to the mobile for
transferring and receiving data.
The pulse rate, oxygen level, stress level, body temperature are sensed using the
respective sensors.
The data are collected and transferred to the mobile application for reference.
And the received data are compared to the actual data and says whether he/she is
healthy or unhealthy.
EEE Department
19EEPN6601-Innovative and Creative 4
WORKING PRINCIPLE
5. EEE Department 19EEPN6601-Innovative and Creative Project 5
S.NO TITTLE
OF THE PAPER
YEAR AND
PUBLICATION
COMMENTS
1 An IoT based patient health monitoring
system.
" IEEE Conference on
Information and
Communication
Technologies(ICACCE)”
2018.
Ahmed Issa have
suggested a method
to develop health care
and monitoring
system for the elderly
person.
2 A Novel IoT Based Health Monitoring System
Using LPC2129.
“IEEE International
Conference on Recent Trends
in Electronics Information &
Communication Technology”.
2017.
Melisa pereira
suggested to
implement IOT based
health monitoring
transportable system
for the measurement
of the Heart rate.
LITERATURE SURVEY
6. EEE Department 19EEPN6601-Innovative and Creative Project 6
S.NO TITTLE
OF THE PAPER
YEAR AND
PUBLICAT-
ION
COMMENTS
3 An Efficient Wireless Health
Monitoring System.
2018 2nd International
Conference on I-SMAC
(IoT in Social,
Mobile, Analytics).
Monitoring and
controlling patient health
with wireless
Transmission sensors in
our system.
4 Health monitoring and tracking system for
soldiers using Internet of Things(IoT).
International Conference
on Computing,
Communication and
Automation (ICCCA).
2016.
Niket patii proposed
system can be mounted
on the soldier's body to
track their health status.
LITERATURE SURVEY
7. BLOCK DIAGRAM
7
EEE Department 19EEPN6601-Innovative and Creative Project
E
S
P
3
2
W
I
F
I
PULSE OXIMETER
SENSOR
DS18B20 BODY
TEMPRATURE
SENSOR
DTH11 ROOM
TEMPRATURE
SENSOR
BLYNK
APP
POWER
SUPPLY
9. EEE Department
19EEPN6601-Innovative and Creative 9
ESP32 BOARD:
Memory: 320 KB RAM, 448 KB ROM
Power:3.3V DC
CPU: Xtensa LX7 dual-core microprocessor or
a single-core RISC-V microprocessor
Range: more than 1.2km using Wi-Fi 802.11b.
COMPONENTS
10. EEE Department
19EEPN6601-Innovative and Creative 10
MAX30100 PULSE OXIMETER:
Input power: 1.7 to 2.0 V
Temperature range: -40 to +85 °C.
LED Current: 0mA to 50mA .
LED pulse width: 200µs to 1.6ms
COMPONENTS
11. EEE Department
19EEPN6601-Innovative and Creative 11
DS18B20 TEMPRATURE SENSOR:
Power supply range: 3.0V to 5.5V
Temperature Range: -55°C to +125°C
Accuracy: ±0.5°C
Output Resolution: 9-bit to 12-bit (programmable)
Conversion time: 750ms at 12-bit
COMPONENTS
12. EEE Department
19EEPN6601-Innovative and Creative 12
DTH11 SENSOR:
Operating Voltage: 3.5V to 5.5V
Temperature Range: 0°C to 50°C
Humidity Range: 20% to 90%
Accuracy: ±1°C and ±1%
Measure temperature and Environment monitoring.
COMPONENTS
15. REFERENCES
1. S.H. Almotiri, M. A. Khan, and M. A. Alghamdi. Mobile health (m- health)
system in the context of iot. In 2016 IEEE 4th International Conference on Future
Internet of Things and Cloud Workshops (FiCloudW), pages 39–42, Aug 2016.
2. Gulraiz J. Joyia, Rao M. Liaqat, Aftab Farooq, and Saad Rehman, Internet of
Medical Things (IOMT): Applications, Benefits and Future Challenges in
Healthcare Domain, Journal of Communications Vol. 12, No. 4, April 2017.
3. Shubham Banka, Isha Madan and S.S. Saranya, Smart Healthcare Monitoring
using IoT. International Journal of Applied Engineering Research ISSN 0973-4562
Volume 13, Number 15, pp. 11984-11989, 2018.
4. K. Perumal, M. Manohar, A Survey on Internet of Things: Case Studies,
Applications, and Future Directions, In Internet of Things: Novel Advances and
Envisioned Applications, Springer International Publishing, (2017) 281-297.
5. S.M. Riazulislam, Daehankwak, M.H.K.M.H., Kwak, K.S.: The Internet of
Things for Health Care: A Comprehensive Survey. In: IEEE Access (2015).
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EEE Department 19EEPN6601-Innovative and Creative Project
16. EEE Department
19EEPN6601-Innovative and Creative 16
6. P. Rizwan, K. Suresh. Design and development of low investment smart hospital
using Internet of things through innovative approaches, Biomedical Research. 28(11)
(2017).
7. K.R. Darshan and K.R. Anandakumar, “A comprehensive review on usage of
internet of things (IoT) in healthcare system,” in Proc. International Conference on
Emerging Research in Electronics, Computer Science and Technology, 2015.
8. P. Chavan, P. More, N. Thorat, S. Yewale, and P. Dhade, “ECG - Remote patient
monitoring using cloud computing,” Imperial Journal of Interdisciplinary Research,
vol. 2, no. 2, 2016.
9. Ruhani Ab. Rahman, NurShima Abdul Aziz, MurizahKassim, Mat IkramYusof, IoT-
based Personal Health Care Monitoring Device for Diabetic Patients ,978-1-5090-
4752-9/17/2017 IEEE.