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Lighting and Medical Personalization: Optimizing Efficiency and Customer Satisfaction Alice M. Agogino Roscoe and Elizabeth Hughes Professor of Mechanical Engineering – PowerPoint PPT presentation

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1
   Lighting and Medical Personalization
Optimizing Efficiency and Customer Satisfaction
  • Alice M. Agogino
  • Roscoe and Elizabeth Hughes Professor of
    Mechanical Engineering

2
Researchers
  • Professor Alice Agogino, Faculty Advisor
  • Marisela Avalos, MS/PhD student
  • Matt Dubberley, MS student, Fall 2003
  • Jessica Granderson, PhD student
  • Mary Haile, undergraduate student
  • Johnnie Kim, undergraduate student
  • Catherine Newman, MS/PhD student
  • Jaspal Sandhu, PhD student
  • Yao-Jung Wen, MS/PhD student
  • Rebekah Yozell-Epstein, MS student, Spring 2003

3
Motivation
  • Indoor Environmental Quality Lighting
  • Increased productivity
  • Increased quality of experience
  • Energy Efficiency
  • Increased importance world-wide
  • Impact on pollution, global warming, expense

4
Motivation Commercial Lighting
  • Electrical Consumption and Savings Potential
  • 2/3 of electricity generated in US is for
    buildings
  • Lighting consumes 40 of the electricity used
    in buildings
  • Advanced Commercial Control Technologies
  • Up to 45 energy savings possible with occupant
    and light sensors
  • Limited adoption in commercial building sector

5
Background Commercial Lighting
  • Problems With Advanced Control Technologies
  • Simple control algorithms dim the lights in
    direct proportional response to the sensor
    signal uncertainty is not considered --gt sensor
    signals, estimation/maintenance of desktop
    illuminance
  • Time of day/week is not considered, lost savings
    through demand reduction
  • All occupants are treated the same in spite of
    the vast differences in perception and preference
    that exist between individuals

6
Background Commercial Lighting
  • Problems With Advanced Control Technologies
  • Systems are hard-wired into the line electricity
    of the building making retrofitting expensive and
    prohibitive
  • Required calibration and installation expertise
    make successful commissioning difficult
  • Algorithms can result in annoyance to the users
    through inappropriate switching or speed of
    switching

7
Research Goals
  • Increased energy savings through the
    implementation of demand-responsive
    decision-making
  • Increased user satisfaction with the system
  • Personalized, improved decision-making balancing
    conflicting preferences/ perceptions among
    individuals sharing a common light source/switch
  • Improved maintenance of target illuminance at the
    worksurface
  • Increased user satisfaction with the system

8
Benchmark Occupancy
9
Potential Energy Savings for Office Building
10
User Studies
  • Survey Feedback
  • 54 want a dimly lit view of rest of room
  • 59 require slightly different light levels
    throughout the day (desk lamp)
  • 32 want automatic overhead lights with override
    and manual task lamps
  • 77 like same lighting throughout the day
  • 73 want to rely on default settings at first and
    then enter preferences later

11
Life Cycle Assessment of the Intelligent Lighting
System using the Distributed Mote Network
  • MS Project, Matt Dubberly
  • Goals
  • To evaluate the environmental impacts associated
    with implementing the proposed Intelligent
    Lighting
  • Compare the electricity saving benefits of the
    Intelligent Lighting System to the environmental
    burdens associated with implementing the system.
  • Provide insight for design choices, such as what
    type of battery should be used or which materials
    and components should be minimized

12
  • The negative environmental impacts of the
    proposed Intelligent Lighting System range from
    17 to 344 times smaller than that of conventional
    lighting systems for the different environmental
    impact categories.
  • The components that contribute the most to the
    system impact are
  • Mote printed circuit board
  • Mote integrated circuit
  • Lithium battery
  • Ballast housing paint
  • The silicon steel and copper in the ballast
    transformer and inductor

13
Intelligent Decision-Making and Smart Dust Motes
Granderson
  • An intelligent decision algorithm allows
  • Validation fusion of sensor signals
  • Differences in user preferences and perceptions
  • Peak load reduction/demand responsiveness
  • Influence diagrams allow
  • Real-time decision-making and control
  • Uncertainty in knowledge (sensor values and
    non-deterministic relationships)
  • Ability to represent complex interdependencies
  • Rules for combining evidence, based on rigorous
    probability theory or fuzzy logic

14
Intelligent Decision-Making and Smart Dust Motes
  • Smart dust motes potentially offer
  • wireless sensing at the work surface, increased
    sensing density, simpler retro-fitting and
    commissioning, wireless actuation, and an
    increased number of control points

15
Intelligent Framework Modeling the Decision Space
  • Initially models demand-responsive and
    personalization aspects of the problem.
  • Variables Included
  • Day, time, electricity price, workstation
    occupancy, sensed workstation occupancy,
    actuation decision, task type, resulting
    illuminance (following actuation), resulting
    perception of the occupant
  • Constants Included
  • Preferred ideal illuminance, min/maximum
    actuation, ideal reward, vacancy penalty/reward

16
Regional Decision Space with Local/Individual
Factors
           
17
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18
Intelligent Framework Modeling the Decision Space
  • After developing the personalized,
    demand-responsive decision model, daylighting
    factors were incorporated
  • Variables added
  • Month, weather (cloudy), latitude, solar azimuth
    and altitude, room geometry, sensed and true
    solar contribution to to the region, solar
    contribution to the ith worksurface

19
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20
Empirical Preference Testing
  • Purpose to identify the illuminance ranges over
    which occupants find the lighting to be ideal,
    too dark, and too bright at their personal
    workstations
  • This gives us
  • conditional probabilities required for the
    decision model
  • information to use in the value function

21
Empirical Preference Testing
  • Results
  • Probabilistic conditional preference data of the
    form P(IlluminancePerception), P(Perception),
    that can be used in the personalized,
    preference-balancing control model

22
Preference Testing - Results
  • Paper-based tasks required significantly more
    light than computer-based tasks

23
Preference Testing - Results
  • No illuminance range proved to be ideal for all
    four occupants, even though all share the same
    switch (computer histogram)

24
Preference Testing - Results
  • No illuminance range proved to be ideal for all
    four occupants, even though all share the same
    switch (paper histogram)

25
Preference-balancing Value Function
  • Goal is to create a function that
  • heavily favors meeting the ideal illuminances of
    those present
  • heavily favors turning the lights off/min in the
    absence of occupants
  • heavily penalizes turning the lights on/max in
    the absence of occupants
  • assigns a value of difference-from-ideal for each
    occupant present, and each possible actuation
    decision

26
Future Research Evaluation of Research Goals
  • Evaluation of preference-balancing value function
    computer simulation
  • Evaluation of target illuminance maintenance
    hardware simulation
  • Evaluation of energy savings achieved with
    demand-responsiveness computer simulation
  • Evaluation of user satisfaction w/ the system -
    implementation in a daylighted test space,
    complimented with user surveys

27
Validation of Motes and Network
  • Construct test architectures for mote sensor
    networks in target office spaces
  • Characterize the motes signals and failure
    patterns
  • Develop appropriate validation and fusion
    algorithms
  • Calibration on mote sensors
  • Evaluate fuzzy probabilistic fusion algorithm
    on sensor networks

28
Illuminance Calibration
  • Hardware/Experimental Set-up
  • Light sources
  • Fluorescent room light
  • Incandescent desk lamp (75W bulb) .
  • Halogen floor lamp.
  • Minolta T-10 illuminance meter

29
Illuminance Calibration
30
Illuminance Calibration
31
Illuminance Calibration
32
Probability Distribution of the Mapping Curve
  • Illustration of probability distribution when
    mapped readings are around 500 lux

33
Temperature Calibration
34
Temperature Calibration
Thermometer on basic sensor board
Thermometer on MICA sensor board
35
Fuzzy Validation and Fusion on BESTnet v1.0
  • Real-time Fuzzy Sensor Validation And Fusion
    (FUSVAF) algorithm

36
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37
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38
Feasibility of Using Accelerometer as Occupancy
Sensor
  • Hardware setup

39
Motes as Decentralized Autonomous Agents Sandhu
  • Agents with collective intelligence may be more
    efficient than centralized control.
  • Model the motes as a collection of intelligent
    agents that share the same global utility
    function.
  • Agents communicate on wireless network to
    maximize their local and gobal utilities.

40
Agents with Collective Intelligence have Been
Successful in other Domains
MINI-ROBOT RESEARCH Sandia National
Laboratories (Photo by Randy Montoya)
Entertainment computing
Large groups of small vehicles
41
Lighting Mote Collectives
  • z worldline - action/state vector of agents and
    environment (sensors actuators)
  • ? agent, ? other agents
  • z? , z?
  • The key is finding good utility functions
  • G(z) global utility that balances energy and
    performance multiobjective function.
  • g?(z) private utility that might take on the
    preferences on different room occupants.

42
Medical Home SecurityMarisela Avalos
  • High density wireless motes could detect changes
    in patient patterns in a manner that is less
    intrusive than other devices such as cameras or
    pressure sensors on toilets.
  • Such networks could be useful for other security
    concerns
  • Intruders
  • Fire or extreme temperatures
  • Extend network for self-reporting of injuries

43
Personalization in Medical Care - Avalos, Newman,
Ng, Rahmani Sandhu
A sense of community beyond that contained
within the walls of a long-term care residence is
important to improving the quality of life of the
confined elder. Without a community presence
relieving the isolation, the culture of illness
and debilitation overtakes a culture of
living. Susan E. Mazer, President of Healing
HealthCare Systems
Personal mote on keychain
THE CONCEPT CommuniCast is an electronic
broadcast display, or bulletin board, that
dynamically posts events, activities, and other
pertinent information in the presence of a
wireless device and based on the users display
preferences. The goal is to improve the level of
communication and social interaction among the
senior citizen community.
44
MS Project Proposal -Newman
  • To construct a complete product prototype
    integrating
  • Develop system for assigning preferences to
    announcements that takes privacy
  • considerations into account.
  • HCI Considerations
  • Display Readability and Comprehension
  • Unobtrusive Wearable Motes
  • Customer System Preferences
  • Ethnography Study
  • Manufacturing Issues
  • Expect prototype to be designed for
    manufacturability


45
System Architecture
Administrative Office
Upon finding a user in range, display device uses
user identification to request appropriate
information to display for that user. This
information is then displayed to the end-user.
Display device (WLAN- mote- enabled)
Web interface
Web interface connects to server application in
order to view and update information in the
database.
Display device requests are forwarded to server
application.
server application
WLAN
database
Server application queries and modifies database
based on incoming requests from local Web
interface or remote display devices.
Mote-based keychain
Mote-enabled display scans for mote-based
keychains containing user identification over RF.
Slide care of Sir Jaspal Sandhu
46
Evaluation Research Goal 1
  • Computer simulation (McGrath) of personalized,
    preference-balancing decision-making
  • Model a room w/o windows in order to control the
    simulation, restrict attention to preference
    only. The room should contain multiple users
    sharing one switch, or bank of lights.
  • Specify various occupancy patterns in the space,
    and backtrack from preference testing data to
    determine how many ideal perceptions, too dark
    and too bright perceptions are registered under
    the two competing control algorithms.
  • Preference data was obtained though an
    experimental hardware simulation in this case we
    are computer-simulating these preferences for the
    group of occupying the space

47
Evaluation Research Goal 2
  • Experimental simulation (McGrath) of improved
    target illuminance levels
  • The goal is to quantify how the intelligent
    controller compares to a commercial controller in
    maintaining target illuminance at the worksurface
  • In order to do so, test the commercial and
    intelligent systems under the same external
    (room) conditions, perturbing/varying the
    worksurface illuminance.
  • Each system will have a target illuminance that
    it is trying to maintain. Therefore, by recording
    the deviation from target for each perturbation,
    a comparison of the two systems is possible.

48
Evaluation Research Goal 3
  • Computer simulation (McGrath) of increased E
    savings through demand-responsiveness
  • Model a space without natural light, in order to
    provide the most conservative estimate, and to
    control the simulation.
  • Condition the space throughout one 24hr. weekday,
    assuming a typical 8hr workday. To provide an
    upper bound on savings, simulate a second case,
    in which all bodies are present throughout the
    entire 24hr. day.
  • Commercial algorithms will set one target
    illuminance for that whole period, while the
    intelligent algorithm will set varying targets
    depending upon the price schedule. The
    illuminance will determine the luminance (output)
    of the lights, from which we can calculate energy
    consumption, and cost.

49
Evaluation Research Goal 4
  • Laboratory experiment, sample survey (McGrath) to
    evaluate user satisfaction
  • Select a test space with significant amounts of
    natural light throughout the day. Install a
    commercial daylighting system, run it for a week
    under variable cloud conditions and issue a
    survey.
  • Install the intelligent daylighting system, run
    it for a week, under the same conditions, and
    issue a second survey. The surveys are to be
    complimented with bottom-line data number of
    manual overrides, electricity consumption and
    expense, and worksurface illuminance patterns.
  • Candidate test spaces include the BID office
    space (full-scale test), and LBNLs
    electrochromic windows test-bed (controlled
    prototype test).
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