UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 Computing.

Slides:

Advertisements

Similar presentations

UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY TYNDALL NATIONAL INSTITUTE Fig 1. Exampleschematic of a wireless sensor platform Current flow control.

Advertisements

UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 TEMPORAL.

Science Department Open House Integrating Technology into Science Courses.

BACK CARE 101: Body Mechanics & Tips For Safe Lifting

European Textile Lead Markets William H. Lakin Director General of Euratex Member of the Governing Council of the ETP for the Future of Textiles & Clothing.

Training to care for people with dementia Dementia Training Partner logo here Training support Skills development Competency Assessment Scholarships Education.

ECG Signal Processing Ojasvi Verma

The integration of smart textiles enabling a non- invasive approach in monitoring the user’s vitals and activities Prof. Lieva Van Langenhove Department.

MICROFLEX S Beeby, J Tudor, University of Southampton Introduction to MEMS What is MEMS? What do MEMS devices look like? What can they do? How do we make.

UNIVERSITY COLLEGE DUBLINDUBLIN CITY UNIVERSITY SMI || NCSR || CDVP Minimally Invasive Gathering of Body Context Information from Garment Interactions.

THERMOREGULATORY SYSTEM’S INTEGRATED IN THE CLOTHES EFFECT ON THE HUMAN MICROCLIMATE Ingrida Shahta 1, Juris Blums 2, Ilze Baltina 1, Vilnis Jurkans 3.

Heterogeneous Technology Alliance Template HTA General Assembly November 12 – 13, 2013.

UNIVERSITY COLLEGE DUBLIN  DUBLIN CITY UNIVERSITY  TYNDALL NATIONAL INSTITUTE Investigating the Role of Novel Sensing Technology in Tennis N. E. O’Connor*,

Mobile and Ubiquitous Computing. Overview Attributes Discussion.

UNIVERSITY COLLEGE DUBLINDUBLIN CITY UNIVERSITY SMI || NCSR || CDVP Ruzzelli, Cotan O’Hare, Tynan, Havinga Protocol assessment.

UNIVERSITY COLLEGE DUBLINDUBLIN CITY UNIVERSITY SMI || NCSR || CDVP The Adaptive Information Cluster First Annual Conference Professor Dermot Diamond Crowne.

Micro-Technologies for Implantable Strain Gauge Arrays

UNIVERSITY COLLEGE DUBLIN  DUBLIN CITY UNIVERSITY  TYNDALL NATIONAL INSTITUTE This work is supported by Science Foundation Ireland under grant 07/CE/I1147.

Industrial and Medical Use of Enzymes. Biosensors.

Smart and Technical Textiles

Smart Materials Lesson objective – to understand that the development of smart materials allows the designer to meet a variety of user needs in new and.

ATWARM Advanced Technologies for Water Resource Management Marie Curie Initial Training Network Next Generation Autonomous Analytical Platforms for Remote.

Homeostasis: The Foundation of Physiology

Nanotechnologies for Textiles, Clothing and Footwear Dr. Jimmy Lam Institute of Textiles & Clothing.

IntroOH-1 CSE 5810 Wireless Body Sensor Networks (WBSN) in Healthcare Aljoharah A. Algwaiz Computer Science & Engineering Department The University of.

Smart Materials Smart textiles are materials and structures that sense and react to environmental conditions or stimuli, such as those from mechanical,

Kelsey Kunkel BME 281 Section 1 October 10 th, 2012.

Presenter : Hyotaek Shim

IEEE n SubmissionLiang Li, VinnotechSlide 1 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs) Submission.

Career Focus Medical Laboratory Technician Copyright Texas Education Agency (TEA)

UNIVERSITY COLLEGE DUBLIN  DUBLIN CITY UNIVERSITY  TYNDALL NATIONAL INSTITUTE Recent Progress in Disposable Ion-selective Sensors for Environmental Applications.

Funded by the European Union This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement.

Power Plant Construction and QA/QC Section 5.4 – Key Systems and Components Engineering Technology Division.

Performance Monitoring Wearable Technology to monitor performance.

26 giugno 2008Department of Textile Engineering, Isfahan University of Technology, , Isfahan 1 INVESTIGATION OF CHARGING PROPERTIES OF CHARGEABLE.

6 H UMAN F ACTORS T O A CCEPTABILITY O F W EARABLE C OMPUTER C HERRYLYN B UENAFLOR AND H EE -C HEOL K IM Archana Prakash Shyam Sajan.

1 SmartSpaghetti: Use of Smart Devices to Solve Health Care Problems Mostafa Uddin,A. Gupta, T. Nadeem, K. Maly Sandip Godambe, Arno Zaritsky BIBM/BIH.

Experimental Results ■ Observations:  Overall detection accuracy increases as the length of observation window increases.  An observation window of 100.

Microwave Assisted ZnO Nanorod Growth for Biosensing This material is based upon work supported by the National Science Foundation.

March 17, 2008Doc: IEEE Jean Schwoerer (France Telecom R&D) Slide1 Project: IEEE P Working Group for Wireless Personal Area.

Fuel Cell Electrode Properties Relva C. Buchanan, University of Cincinnati Main Campus, DMR Thin film materials with properties suitable for fuel.

To be handed into teacher after end of term.

Performancing enhancing clothing is seen in:

Outline of the presentation

Ambient Intelligence: Everyday Living Aid System for Elders

A SMART FABRIC IS A FABRIC THAT HAS BEEN DESIGNED TO REACT AUTOMATICALLY TO CHANGES IN ITS SURROUNDINGS. THEY CAN BE PRODUCED IN A VARIETY OF WAYS FOR.

Chapter 10 Health-Related Fitness and Conditioning 10 Health-Related Fitness and Conditioning C H A P T E R.

Potential topic for Thematic Networks: Wearable Computing and Smart Clothing – > Active Clothing Brussels, May 15, 2007 Ilkka Saarnio.

788.11J Presentation Wearable Wireless Body Area Networks (WWBAN) Presented by Jingjing He.

Wearable health systems: from smart technologies to real applications Lymberis A, Gatzoulis L European Commission, Information Society and Media Directorate-

ENGINEERING INNOVATION AWARDS NATIONAL ENGINEERING INNOVATION PRIZE (NIEP) CARDIOCAST.

Smart Materials and other bit and bobs!. What are Smart Materials? Smart materials are materials that have one or more properties that can be significantly.

* E-textiles with classical electronic devices such as conductors, integrated circuits, LEDs, and conventional batteries embedded into garments.

Fitness principles Intro to fitness and nutrition.

Electroplating Applying metal to a conductive surface by David Clark.

IntroOH-1 CSE 5810 Remote Health Care Monitoring by Wearable Sensors and Mobile Devices Kanchan Jha Computer Science & Engineering Department The University.

Wearable Chemical Sensors: Characterization of ECG Electrodes with Electrochemical Impedance Spectroscopy Jennifer Deignan1, Michael McBrearty2, Javier.

From Wearables to Continuous Diagnostics, Monitoring, and Evaluation (CDME) Shahid N. Shah.

CONTENTS Introduction What is a biosensor ? Types Of Wearable Biosensors Applications Advantages Disadvantages Conclusion References Need of wearable.

Stefan Poslad, PhD School of Electronic Engineering & Computer Science

Single-molecule transistors: many-body physics and possible applications Douglas Natelson, Rice University, DMR (a) Transistors are semiconductor.

FINISHES Finishing is done to improve a materials appearance, properties and quality. It covers many different processes, some mechanical and some chemical.

ASP2 Healthcare Systems

WEARABLE BIOSENSOR SYSTEM USING ZIGBEE TECHNOLOGY

BIO-NANOTECHNOLOGY Size: 1mm x 1mm x 5mm

Safety Valve Suppliers inn UAE | Ali Salman Trading Company

How to Build Smart Appliances?

Chapter 2-1 Wearable Bio and Chemical Sensors

Brussels, May 15, 2007 Ilkka Saarnio

Transparent Conductive Films Market Research Report - Forecast to 2023 Industry Survey, Growth, Competitive Landscape and Forecasts to 2023 PREPARED BY.

Presentation transcript:

UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 Computing and Material Sciences for LifeLogging Alan F.Smeaton 1, Dermot Diamond 1 and Barry Smyth 2 Adaptive Information Cluster, 1 Dublin City University 2 University College Dublin

This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY Lifelogging in Practice Contemporary lifelogging senses the mind, the body, and the place; Uses a variety of devices to do so; What they have in common is that they do not seamlessly integrate into our lives; True lifelogging moves from SciFi to reality when we integrate the lifelogging into the fabric of our lives, and make the “sensor” not only disappear, but part of the environment;

This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY AIC Lifelogging Within the AIC we make the lifelogging devices the clothes we wear by developing materials which have ‘switchable properties’; These adapt to changing circumstances like wettability, permeability, colour, conductivity and even surface activity; We use these functionalised fabrics in garments as opposed to discrete sensors and electronic components attached to the fabric of a garment;

This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY Polypyrrole coatings (conducting polymers) on fabrics mean that the electrical conducting properties of the fabrics themselves change as they are subjected to physical stretching or compression. If we coat foam or lycra with polypyrrole and use this in wearable garments we functionalise specific locations on the garment to sense stretching, bending, pressure or other fabric movement; We have integrated these smart materials into clothing to monitor breathing, limb movements and posture in vests, t-shirts, arm bands etc., and in shoes to monitor steps/activity; Used in applications in sports performance monitoring, posture sensing and in dance/yoga- exercise applications Smart Materials - Physical

This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY Smart Materials - Chemical Integrating chemical biosensors into textiles depends on selective reactions happening when directly exposed to a sample, such as a bodily fluid; Involves issues such as sample handling, calibration, safety and power consumption; The textile itself is the sensor and can be integrated into suitable apparel. Currently, target users include ambulatory healthcare workers, isolated people, convalescents and patients with chronic diseases such as diabetes and obesity and in assessing sports performance and training; Our primary goal is wearable pH sensing, with subsequent integration of others such as electrolytes, lactate, conductivity etc. The wearable fluidic handling manifold which has to work with ultra-small volumes of body fluids is already developed;

This material is based upon work supported by Science Foundation Ireland under Grant No. 03/IN3/1361 UNIVERSITY COLLEGE DUBLIN DUBLIN CITY UNIVERSITY Conclusion On-body logging of a variety of activity indicators can be done using smart materials and fabrics; Makes the sensing and recording devices almost transparent; Ultimately, with further development, these will be scalable and will enable a host of new lifelogging possibilities but in a more seamless manner than heretofore;