To deal with various technologies which provide smart sensing in healthcare and compare them for their energy usage and battery life and discuss the format of communication to the database of these devices. To put forward devices which use smart sensors in advanced medical check-ups. To discuss the prospects of upcoming technology called Smart Dust in e-health and its advantages and effects for better deployment of trustworthy services in healthcare keeping in mind all the capabilities of the Smart Sensor.
Now-a-days, a growing number of people in a developing countries like India forces to look for new solutions for the continuous monitoring of health check-up. It has become a necessity to visit hospitals frequently for doctor’s consultation, which has become financially related and a time consuming process. To overcome this situation, we propose a design to monitor the patient’s health conditions such as heart beat, temperature, ECG and BP and send the message to guardian using GSM. In the recent development of internet of things(IoT) makes all objects interconnected and been recognized as the next technical revolution. Patient monitoring is one of the IoT application to monitor the patient health status. Internet of things makes medical equipments more efficient by allowing real time monitoring of health. Using IoT doctor can continuously monitor the patient’s on his smart phone and also the patient history will be stored on the web server and doctor can access the information whenever needed from anywhere.
Health monitoring is the major problem in today’s world. Due to lack of proper health monitoring, patient suffer from serious health issues. There are lots of IoT devices now days to monitor the health of patient over internet. Health experts are also taking advantage of these smart devices to keep an eye on their patients. With tons of new healthcare technology start-ups, IoT is rapidly revolutionizing the healthcare industry.
Here in this project, we will make an IoT based Health Monitoring System which records the patient heart beat rate and body temperature and also send an email/SMS alert whenever those readings goes beyond critical values. Pulse rate and body temperature readings are recorded over ThingSpeak and Google sheets so that patient health can be monitored from anywhere in the world over internet. A panic will also be attached so that patient can press it on emergency to send email/sms to their relative
It is ultrathin electronics device attaches to the skin
like a sick on a tattoo which can measure electrical
the activity of heart, brain waves & other vital signals. There are various names of artificial skin in the biomedical field it is called as artificial skin, in our electronics field it is called as electronic skin, some scientist it called as sensitive skin, in other way it also called as synthetic skin, some people says that it is fake skin.
It is skin replacement for people who have suffered skin trauma, such as severe burns or skin diseases or Robotic application and so on.
Now-a-days, a growing number of people in a developing countries like India forces to look for new solutions for the continuous monitoring of health check-up. It has become a necessity to visit hospitals frequently for doctor’s consultation, which has become financially related and a time consuming process. To overcome this situation, we propose a design to monitor the patient’s health conditions such as heart beat, temperature, ECG and BP and send the message to guardian using GSM. In the recent development of internet of things(IoT) makes all objects interconnected and been recognized as the next technical revolution. Patient monitoring is one of the IoT application to monitor the patient health status. Internet of things makes medical equipments more efficient by allowing real time monitoring of health. Using IoT doctor can continuously monitor the patient’s on his smart phone and also the patient history will be stored on the web server and doctor can access the information whenever needed from anywhere.
Health monitoring is the major problem in today’s world. Due to lack of proper health monitoring, patient suffer from serious health issues. There are lots of IoT devices now days to monitor the health of patient over internet. Health experts are also taking advantage of these smart devices to keep an eye on their patients. With tons of new healthcare technology start-ups, IoT is rapidly revolutionizing the healthcare industry.
Here in this project, we will make an IoT based Health Monitoring System which records the patient heart beat rate and body temperature and also send an email/SMS alert whenever those readings goes beyond critical values. Pulse rate and body temperature readings are recorded over ThingSpeak and Google sheets so that patient health can be monitored from anywhere in the world over internet. A panic will also be attached so that patient can press it on emergency to send email/sms to their relative
It is ultrathin electronics device attaches to the skin
like a sick on a tattoo which can measure electrical
the activity of heart, brain waves & other vital signals. There are various names of artificial skin in the biomedical field it is called as artificial skin, in our electronics field it is called as electronic skin, some scientist it called as sensitive skin, in other way it also called as synthetic skin, some people says that it is fake skin.
It is skin replacement for people who have suffered skin trauma, such as severe burns or skin diseases or Robotic application and so on.
These are the devices that can be wear by human beings so that they provide information about their health, pulse rating, blood circulation and so many. They are widely used in medical field, defence and other fields.
As elderly population increases day by day caretaking demands are also increasing. Hence patient health monitoring systems are gaining importance these days. This paper is based on monitoring of patients. We have designed and developed a reliable, energy efficient patient monitoring system. It is able to send parameters of patient in real time. It enables the doctors to monitor patient's health parameters (temp, heartbeat, ECG, position) in real time. In the current proposed system the patient health is continuously monitored using different sensors which is connected to the Arduino board. And the acquired data is send to the server using Ethernet shield attached to the Arduino board. If any of the parameter values goes beyond the threshold value an alert is given to the doctor using an Android application installed in the doctor’s smartphone.
This is a advance technology for the checkup of the patient by the doctor. IN this there is a microcontroller whis encode all the sensor data and display on lcd screen and also send to gsm module by this all the pateint psychological data send to mobile in the form of sms .
Trends in Sensors, Wearable Devices and IoTWalt Maclay
Today, it is all about being connected and staying connected. Low-cost sensors are revolutionizing medical, home health and wearable devices, as well as other internet of things gadgets. Walt Maclay explains how these smart devices are benefiting from the ongoing development of low-cost high-volume sensors. Whether it is temperature, pressure, vibration, acceleration, flow, sound or vision, it is all about sensors. They are critical to many advances and to the rapid innovation we are seeing today. In this video, Walt Maclay presents the latest trends and challenges he sees for sensors, wearable devices and IoT.
These are the devices that can be wear by human beings so that they provide information about their health, pulse rating, blood circulation and so many. They are widely used in medical field, defence and other fields.
As elderly population increases day by day caretaking demands are also increasing. Hence patient health monitoring systems are gaining importance these days. This paper is based on monitoring of patients. We have designed and developed a reliable, energy efficient patient monitoring system. It is able to send parameters of patient in real time. It enables the doctors to monitor patient's health parameters (temp, heartbeat, ECG, position) in real time. In the current proposed system the patient health is continuously monitored using different sensors which is connected to the Arduino board. And the acquired data is send to the server using Ethernet shield attached to the Arduino board. If any of the parameter values goes beyond the threshold value an alert is given to the doctor using an Android application installed in the doctor’s smartphone.
This is a advance technology for the checkup of the patient by the doctor. IN this there is a microcontroller whis encode all the sensor data and display on lcd screen and also send to gsm module by this all the pateint psychological data send to mobile in the form of sms .
Trends in Sensors, Wearable Devices and IoTWalt Maclay
Today, it is all about being connected and staying connected. Low-cost sensors are revolutionizing medical, home health and wearable devices, as well as other internet of things gadgets. Walt Maclay explains how these smart devices are benefiting from the ongoing development of low-cost high-volume sensors. Whether it is temperature, pressure, vibration, acceleration, flow, sound or vision, it is all about sensors. They are critical to many advances and to the rapid innovation we are seeing today. In this video, Walt Maclay presents the latest trends and challenges he sees for sensors, wearable devices and IoT.
IOT is connecting every physical object in the world using wireless technologies to track and control them from every where in the world...Every object is uniquely identified using ip addresses(IPv6)
A Low Power Wearable Physiological Parameter Monitoring Systemijsrd.com
The design and development of a low power wearable physiological parameter monitoring system have been developing and reporting in this paper. The system can be used to monitor physiological parameters, such as ECG signals, temperature and heartbeat. The system consists of an electronic device which is worn on the wrist and finger, by an at-risk person. Using several sensors to measure different vital signs, the person is wirelessly monitored within his own home. An epic sensor has been used to detect ECG signals. The device is battery powered for use outdoors. The device can be easily adapted to monitor athletes and infants. The low cost of the device will help to lower the cost of home monitoring of patients recovering from illness. A prototype of the device has been fabricated and extensively tested with very good results.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
Real Time Physiological Status Monitorinig through Telemetry System for on Sp...ijtsrd
In todays era, Internet of Things is playing an important role in health care management systems, which is not only for monitoring but also to communicate, stores and display. The prime aim of this study is to design and implement effective real time healthcare monitoring dashboard for on spot accident patients who is injured and went to unconscious state. The proposed system monitor the ECG, EEG, EMG waveforms, Temperature, heart beats etc, and transmit those vital parameters wirelessly through wifi technology. The transmitted patients data is displayed in the PC based application called the central nurse station where PC with the receive wifi acts as hub. This data gets updated into database continuously. From the database of the android application fetches all the updated data, stores and displays it. This enables the doctor to receive the current status of an accident patient in real time. The parameters of a particular patient go beyond a threshold value an automated notification will pop up in doctor android mobile application. This android application can also generate call option if the doctor will not notifynotification messages. Additionally system is also able to generate alarm to notify nurse around for emergency treatment and by using GSM module the patient datas can also be send to the authorized person i.e friends, relatives etc. Ultimate goal of this project is to implement a low cost, high efficient and effective wireless real time system for health monitoring through telemetry system. S. Rabia Jebin | N. Mohamedbeemubeen ""Real Time Physiological Status Monitorinig through Telemetry System for on-Spot-Accident Patients using IoT"" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-3 , April 2019, URL: https://www.ijtsrd.com/papers/ijtsrd23470.pdf
Paper URL: https://www.ijtsrd.com/engineering/bio-mechanicaland-biomedical-engineering/23470/real-time-physiological-status-monitorinig-through-telemetry-system-for-on-spot-accident-patients-using-iot/s-rabia-jebin
IOT BASED HEALTH MONITORING BY USING PULSE OXIMETER AND ECGPonselvanV
Monitoring and Recording of various medical parameters of patient outside hospitals has become Widespread phenomenon. The Reason behind this project is to design a system for monitoring the patient’s body at any time using internet connectivity. The function of this system is measuring and detecting the heart pulse rate of the patient’s body by using Heart beat sensors and sends the values to IOT Cloud platform through WIFI-Module. All information about the patient heart pulse rate and health will be stored on the cloud, it enables the doctors to monitor patient’s health, where the doctor can continuously monitor the patient’s heart condition on his Smart phone.This project is implemented with Arduino Controller.
Implementation Of Real Time IoT Based Health monitoring systemkchakrireddy
The main aim of this project is to interconnect the available medical resources and offer smart, reliable, and effective healthcare service to elderly people. Health monitoring for active and assisted living is one of the paradigms that can use the IOT advantages to improve the elderly lifestyle in this project we present an IOT architecture customized for healthcare applications. The proposed architecture collects the data and relays it to the cloud where it is processed and analyzed. Feedback actions based on the analyzed data can be sent back to the user.
Recently, in many cases, the reason for a patient staying in the hospital is not that he or she actually needs active medical care. Often, the principal reason for a lengthy stay in the hospital is simply continual observation. Therefore, efforts have been made to avoid acute admissions and long lengths of stay in the hospital. In recent years, emergency admissions and long lengths of stay have become extremely costly. So the focus of health policy has shifted away from the provision of reactive, acute care toward preventive care outside the hospital. As models of care are redesigned, health economies are seeking to provide more care outside large acute centers. The drivers for this shift are two-fold; first, there is a quality-of-care issue and second, there is a resource allocation issue. Being cared for in a patient’s own home is a key aim of current U.K. government health policy and that is driven by an imperative to provide better quality care to people without the need to disrupt their lives. Investment in technologies that enable remote monitoring would lead to long-term gains in terms of hospital finances and patient care.
GDG Cloud Southlake #33: Boule & Rebala: Effective AppSec in SDLC using Deplo...James Anderson
Effective Application Security in Software Delivery lifecycle using Deployment Firewall and DBOM
The modern software delivery process (or the CI/CD process) includes many tools, distributed teams, open-source code, and cloud platforms. Constant focus on speed to release software to market, along with the traditional slow and manual security checks has caused gaps in continuous security as an important piece in the software supply chain. Today organizations feel more susceptible to external and internal cyber threats due to the vast attack surface in their applications supply chain and the lack of end-to-end governance and risk management.
The software team must secure its software delivery process to avoid vulnerability and security breaches. This needs to be achieved with existing tool chains and without extensive rework of the delivery processes. This talk will present strategies and techniques for providing visibility into the true risk of the existing vulnerabilities, preventing the introduction of security issues in the software, resolving vulnerabilities in production environments quickly, and capturing the deployment bill of materials (DBOM).
Speakers:
Bob Boule
Robert Boule is a technology enthusiast with PASSION for technology and making things work along with a knack for helping others understand how things work. He comes with around 20 years of solution engineering experience in application security, software continuous delivery, and SaaS platforms. He is known for his dynamic presentations in CI/CD and application security integrated in software delivery lifecycle.
Gopinath Rebala
Gopinath Rebala is the CTO of OpsMx, where he has overall responsibility for the machine learning and data processing architectures for Secure Software Delivery. Gopi also has a strong connection with our customers, leading design and architecture for strategic implementations. Gopi is a frequent speaker and well-known leader in continuous delivery and integrating security into software delivery.
Builder.ai Founder Sachin Dev Duggal's Strategic Approach to Create an Innova...Ramesh Iyer
In today's fast-changing business world, Companies that adapt and embrace new ideas often need help to keep up with the competition. However, fostering a culture of innovation takes much work. It takes vision, leadership and willingness to take risks in the right proportion. Sachin Dev Duggal, co-founder of Builder.ai, has perfected the art of this balance, creating a company culture where creativity and growth are nurtured at each stage.
Accelerate your Kubernetes clusters with Varnish CachingThijs Feryn
A presentation about the usage and availability of Varnish on Kubernetes. This talk explores the capabilities of Varnish caching and shows how to use the Varnish Helm chart to deploy it to Kubernetes.
This presentation was delivered at K8SUG Singapore. See https://feryn.eu/presentations/accelerate-your-kubernetes-clusters-with-varnish-caching-k8sug-singapore-28-2024 for more details.
Slack (or Teams) Automation for Bonterra Impact Management (fka Social Soluti...Jeffrey Haguewood
Sidekick Solutions uses Bonterra Impact Management (fka Social Solutions Apricot) and automation solutions to integrate data for business workflows.
We believe integration and automation are essential to user experience and the promise of efficient work through technology. Automation is the critical ingredient to realizing that full vision. We develop integration products and services for Bonterra Case Management software to support the deployment of automations for a variety of use cases.
This video focuses on the notifications, alerts, and approval requests using Slack for Bonterra Impact Management. The solutions covered in this webinar can also be deployed for Microsoft Teams.
Interested in deploying notification automations for Bonterra Impact Management? Contact us at sales@sidekicksolutionsllc.com to discuss next steps.
Search and Society: Reimagining Information Access for Radical FuturesBhaskar Mitra
The field of Information retrieval (IR) is currently undergoing a transformative shift, at least partly due to the emerging applications of generative AI to information access. In this talk, we will deliberate on the sociotechnical implications of generative AI for information access. We will argue that there is both a critical necessity and an exciting opportunity for the IR community to re-center our research agendas on societal needs while dismantling the artificial separation between the work on fairness, accountability, transparency, and ethics in IR and the rest of IR research. Instead of adopting a reactionary strategy of trying to mitigate potential social harms from emerging technologies, the community should aim to proactively set the research agenda for the kinds of systems we should build inspired by diverse explicitly stated sociotechnical imaginaries. The sociotechnical imaginaries that underpin the design and development of information access technologies needs to be explicitly articulated, and we need to develop theories of change in context of these diverse perspectives. Our guiding future imaginaries must be informed by other academic fields, such as democratic theory and critical theory, and should be co-developed with social science scholars, legal scholars, civil rights and social justice activists, and artists, among others.
Smart TV Buyer Insights Survey 2024 by 91mobiles.pdf91mobiles
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DevOps and Testing slides at DASA ConnectKari Kakkonen
My and Rik Marselis slides at 30.5.2024 DASA Connect conference. We discuss about what is testing, then what is agile testing and finally what is Testing in DevOps. Finally we had lovely workshop with the participants trying to find out different ways to think about quality and testing in different parts of the DevOps infinity loop.
From Daily Decisions to Bottom Line: Connecting Product Work to Revenue by VP...
Smart sensor technology in healthcare & protection
1.
2. PARTS PLAYED BY
US:-
DEEPIKA :: Handled the research Biosensors & various
connecting services like (ZigBee/ IEEE standard 804.15.6,
Bluetooth, WPAN, WLAN) and networks with the main
station.
OSHIN :: Handled the research on various applications and
devices which work as Smart Sensors in healthcare and their
future prospects and firmness in e-health fields.
3. OBJECTIVE
To deal with various technologies which provide smart
sensing in healthcare and compare them for their
energy usage and battery life and discuss the format of
communication to the database of these devices. To put
forward devices which use smart sensors in advanced
medical check-ups. To discuss the prospects of
upcoming technology called Smart Dust in e-health and
its advantages and effects for better deployment of
trustworthy services in healthcare keeping in mind all
the capabilities of the Smart Sensors.
4. SENSORS USED IN
HOSPITALS
What do they measure?
•Temperature
•Blood Pressure
•Pulse
•ECG (Heart Rate)
•Respiratory Rate
•Blood Sugar
5. APPLICATIONS OF E-
HEALTH SENSORS
• Patient Monitoring Blood pressure, blood
sugar etc.
• Environmental Tests Environmental
Pollution
• Diagnosis Patient Monitoring,
Dope Testing,
Cancer or Tumor
analysis.
6. BIOSENSO
RS
• A biosensor is an analytical device,
used for the detection of an analyte,
that combines a biological component
with a physiochemical detector.
• The sensitive biological element(e.g.
tissue, microorganisms, organelles,
cell receptors, enzymes, antibodies,
nucleic acids, etc.), a biologically
derived material or biomimetic
component that interacts (binds or
recognizes) with the analyte under
study.
The sensor which can
measure heart and brain
activity (ECG, EEG and EMG).
7. BIOSENSORS-AN
EXAMPLE
• A common example of a commercial biosensor is the blood glucose
biosensor, which uses the enzyme glucose oxidase to break blood
glucose down.
• In doing so it first oxidizes glucose and uses two electrons to reduce
the FAD (a component of the enzyme) to FADH2.
• This in turn is oxidized by the electrode (accepting two electrons from
the electrode) in a number of steps.
• The resulting current is a measure of the concentration of glucose. In
this case, the electrode is the transducer and the enzyme is the
biologically active component.
8. APPLICATIONS OF
BIOSENSORS
• Glucose monitoring in diabetes ← historical market driver.
• Detection of pathogens.
• Routine analytical measurement of folic acid, vitamin B12 etc
as an alternative to microbiological assay.
• Drug discovery & evaluation of new compound biological
activity.
9. Smart sensor enhances the following applications:
Self calibration: Adjust deviation of o/p of sensor from desired value.
Communication: Broadcast information about its own status.
Computation: Allows one to obtain the average, variance and standard
deviation for the set of measurements.
Multisensing: A single smart sensor can measure pressure, temperature,
humidity, gas flow and infrared, chemical reaction surface
acoustic vapour etc.
Cost effective: less hardware and reduction of repetitive testing make smart
sensor cost effective.
10. 1. Mertia Sensing Device :-
A small sensor is worn on the body and is attached using a
skin-friendly adhesive. The low-profile design makes it
suitable for daily activities like showering and exercise. The
sensor is built to gather a variety of patient information,
from heart rate and respiration to sleep duration and activity
levels.
11. ZigBee is targeted at applications that
require a low data rate, long battery life,
and secure networking. ZigBee has a
defined rate of 250 kbit/s, best suited for
periodic or intermittent data or a single
signal transmission from a sensor or input
device
ZigBee is a specification for a suite
of high level communication
protocols using small, low-power
digital radios based on an IEEE 802
standard for personal area
networks.
ZigBee is seen as a key technology
for home automation and sensor
networks, but its characteristics
can be extremely valuable in some
healthcare applications as well.
2. ZigBee(IEEE 802.15.4)
12. 3. MEDIC
• Acquire data from patients in real world
• It sends data to the centralized server and the
centralized server forwards data to all the nodes
• It can be configured from the remote server
• Wearable sensors to patients for comfortability
13. 4. Smart dust:- Smart dust is a theoretical concept of a tiny
wireless sensor network, made up of microelectromechanical
sensors (called MEMS), robots, or devices, usually referred to as
motes, that have self-contained sensing, computation,
communication and power.
• Blood pressure sensor, Weight scale.
• Emfi-sensors for exercise equipments/bed.
• Low resolution IR camera.
• Ultrasound radar.
• Capacitive floor sensors.
• ZigBee sensor network.
• Connection to local and remote servers.
• Strong collaborative, and robust clinical research with population
studies is required!
15. BLUETOOTH VS. ZIGBEE (IEEE
802.15.4)
Bluetooth based WPAN
• Few devices
• Data range is 10m to 100m
• Data rate is nearly 1Mb/s
• Power consumption is a
low.
• Battery life is low.
• Star only.
IEEE 802.15.4 LR-WPAN
• Many devices
• Data range is nearly 10m
• Data rate is 20
kb/s,40kb/s,250kb/s.
• Power consumption is ultra
low.
• Battery lasts years.
• peer to peer, Star.
COMMUNICATION PROTOCOLS :-
16. AN OVERVIEW OF THE PROCESS OF
MEDICAL SENSING :
• Sensors: various types of wearable biomedical sensors with
integrated radio transceivers (ex: accelerometer in bracelet to
detect hand tremors, mertia)
• Radio signal received by cell phone and transmitted to server
• Analysis of raw data performed via wavelet analysis
• Decision tree or artificial neural network used to decide
appropriate action (data is within normal range, outside
normal range and either does or does not require emergency
action, etc.)
• Data stored in server side database and report is generated to
send to healthcare professional
• As shown in next figure:
18. VIVOMETRICS(ANOTHER
ADVANCED TECHNOLOGY)
• A wireless pulse oximeter and wireless two-lead EKG(as given in fig. below)
• These devices collect heart rate (HR), oxygen saturation and EKG data .
• It is over a short-range (100m) wireless network to any number of receiving
devices, including PDAs, laptops, ambulance terminals.
• Data is displayed in real time & integrated into the patient care record.
• The sensor devices can be programmed to process the vital sign data, for
example, to raise an alerts when vital signs fall outside of norms .
• These vital sign sensors consist of a low-power microcontroller and low-power
digital spread-spectrum radio .
• Powered by batteries with a lifetime of up to a year.
19. Pulse Oximeter Wireless two-lead EKG
Accelerometer,
gyroscope, and
electromyogram (EMG)
sensor for stroke patient
monitoringFIG. 1
20. What is wearable smart shirt?
Wearable smart shirt = Wearable + smart shirt
• smart shirt is an analytical
device used for detection of
analyte.
• e.g.RespirationRate,body
temperature ,heart rate etc.
• Object that can be worn on
body.
• e.g. wrist watches, ring,
shirts etc.
Smart ShirtWearable
21. •A noninvasive system
•Based on plethysmography (measuring changes in volume within an organ or
whole body usually resulting from fluctuations in the amount of blood or air it
contains)
•Wearable medical system, which provides constant monitoring of ambulatory
patients by measuring and storing respiratory and cardiac parameters.
•Creates health profile during normal daily activities.
•Embedded sensors collect data on cardiopulmonary function.
•Can be combined with optional peripherals and monitor functions such as
electrocardiogram, electro-myografima, leg movement, body temperature,
blood oxygen saturation, blood pressure etc .
WEARABLE CLOTHES:
LIFESHIRT
22.
23. Remote Monitor the vital sign.
Communicate seamlessly with external devices.
Enhance safety and quality of care for patient through
Telemedicine
Monitoring of individuals who work with hazardous
condition .
24. • GTWM that is outfitted with a microphone or GPS may compromise
the wearer's privacy.
• Technology like Bluetooth and WLAN using for data transfer , having
short range 30-300 m.
• The data that is transferred by the "Smart Shirt" could be viewed
and access by unauthorized people.
25. Advantages
Continuous monitoring.
Right Treatment at the right
time
Easy to wear and takeoff.
Reduce the work load of
medical assistance.
Washable
very fast process.
Disadvantages
Initial cost is high
Battery life is less
Repairing and maintaince
process is tedious.
26. SOME LATEST COMMERCIAL
SENSORS
Plastic Sensor Fiber
Woven Temperature Sensor
inserted into Textile
Accelerometer data
on smart phone
Wearable sensor a 3-axis
accelerometer
27. JAWBONE UP
BASIS
Wristband packed with
vibration and motion sensors
to track and analyze exercise,
diet, and sleep data .
Wrist-worn device that measures
the wearer’s heart rate, caloric
burn, sleep patterns .
SOME LATEST COMMERCIAL
SENSORS(CONTD.)
28. Withings Wi-Fi Body Scale
Sends body measurements
wirelessly to computer or
iPhone, to track gains or losses
over time .
AgaMatrix
Sensor for tracking blood glucose
levels. It also tracks carbs intake
and insulin dose for users with
diabetes.
SOME LATEST COMMERCIAL
SENSORS(CONTD.)
29. Advantages of biosensors
i.Minimum Interconnecting Cables
i.High Reliability
ii.High Performance
iii.Easy to Design, Use and Maintain
iv.Scalable -Flexible System
v.Minimum Cost
We have various advantages related to access of health related information from
distant areas to the server instantly .This can be very time saving and energy
efficient process. Even very large amount of data can be saved in the database. It
has a promising future.
30. The smart sensor consists of both actuators & sensors, so it is
more complexed than other simple sensors.
The complexity is much higher in the wired smart sensors, as
a consequence the costs are also higher.
31. ACCEPTANCE OF
BIOSENSORS BY PATIENTS
Especially important for elderly patients:
• Tendency to reject technology
• Must be intuitive and easy to operate
A study in which elderly residents of Sydney participated in an open-ended
discussion found:
• Overall positive view of WSNs due to implications for independence
• Ashamed of visible sensors (design as unobtrusive as possible)
• Adherence issues due to forgetfulness
• Distrust of technology
• Privacy
33. REFERENCES:-
Mobile Wireless Sensor Networks: Healthcare in Hospitals by
balakrishna@research.iiit.ac.in , Garimella Ramamurthy, Sujeeth Nanda in ifth
International Conference on eHealth, Telemedicine, and Social Medicine(eTELEMED
2013)
ZigBee Wireless Sensor Applications for Health, Wellness and Fitness - March
2009 at www.zigbee.org
A Health Monitoring System Using Smart Phones and Wearable Sensors Valerie
GAY , Peter LEIJDEKKERS- Faculty of IT, University of Technology Sydney, PO Box
123, Broadway 2007 NSW Australia
On the Use of Wireless Network Technologies in Healthcare Environments Nicolas
Chevrollier Nada Golmie National Institute of Standards and Technology
Gaithersburg, Maryland 20899,2010
Application of Wireless Sensor Networks to Healthcare Promotion Paulo Neves,
Michal Stachyra, Joel Rodrigues,2010
Patient Monitoring Using Personal Area Networks of Wireless Intelligent Sensors
Emil Jovanov, Dejan Raskovic, John Price, John Chapman, Anthony Moore,
Abhishek Krishnamurthy Electrical and Computer Engineering Department,
University of Alabama in Huntsville 301 Sparkman Drive, Huntsville, AL 35899,2009
34. SMART
DUST
FUTURE IMPLICATIONS:-
•Blood pressure sensor,
weight scale.
•Emfi-sensors for exercise
equipments/bed.
•Low resolution IR camera.
•Ultrasound radar.
•Capacitive floor sensors.
•ZigBee sensor network.
•Connection to local and remote
servers.
Smart dust is a theoretical concept of a tiny wireless sensor network, made up
of microelectromechanical sensors (called MEMS), robots, or devices, usually
referred to as motes, that have self-contained sensing, computation,
communication and power.
35. FUTURE OF ”SMART DUST” IN HEALTHCARE
–TO LEAP FORWARD
PROMISES:
- THE NEW TECHNOLOGY AND NEW SENSORS
WILL ENABLE US TO BRING NEW SERVICES FOR
HEALTHCARE, EVENTUALLY.
- FOR THE CUSTOMERS NEW TECHNOLOGY
COULD PROVIDE COMPLETELY NEW AVENUES
ENABLING PERSONALIZED DISEASE
PREVENTION, DISEASE MANAGEMENT AS WELL
AS REHABILITATION AND CARE THAT IS NOT
AVAILABLE TODAY.
STRONG COLLABORATIVE, AND ROBUST
CLINICAL RESEARCH WITH POPULATION