1 / 11

Indoor Positioning

Indoor Positioning. Kalid Azad Advisor: Prof. Littman (MAE dept) Co-advisor: Prof. Cook Cs398 Project Proposal. Problem Description . What is indoor positioning? Find your location accurately indoors (like GPS) Why is it important? Unsolved problem

afra
Download Presentation

Indoor Positioning

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Indoor Positioning Kalid Azad Advisor: Prof. Littman (MAE dept) Co-advisor: Prof. Cook Cs398 Project Proposal

  2. Problem Description • What is indoor positioning? • Find your location accurately indoors (like GPS) • Why is it important? • Unsolved problem • Indoor robots, underground surveying, detailed maps/directions…

  3. Why is it hard? • GPS doesn’t work indoors! No line of sight… • No obvious alternative • Previous approaches: Psuedo-GPS, IR signal strength, RF, ultrasonic/acoustic… • Indoor radio propagation not well studied • Reflection, absorption from obstacles • Walls/windows/doors have different delays • Cost! No $100,000 atomic clocks allowed. • Light travels ~ 1 ft/ns • Hard to measure propagation delays w/o good clocks • Resolution • Want ~ 1 ft resolution (not room-level granularity)

  4. Approaches • My approach: use phase differences • Multiple transmitters send sine waves • Receiver notes relative phase differences • Calculates how many wavelengths away from transmitter • Receiver solves for its position • Or, transmit data to central server, which calculates position and sends it back (via wireless network)

  5. My Approach T2 T1 1 wavelength = Possible location

  6. My Approach • Advantages • No atomic clock/synchronization, works on RF, good resolution, phase easy to detect • Done before? • On google, only found 1 paper describing use of phase differences • Not done in hardware

  7. Methodology, milestones, and deliverables • Steps • Extensive survey of current technology • Create a method • Develop algorithm, order hardware • Develop software • Proof-of-principle • Web-based, GUI • Implement in hardware

  8. Methodology, milestones, and deliverables • By checkpoint (~1 month) • Thoroughly examined existing technology • Created algorithm • Ordered hardware • Begin coding software • Deliverables • Report • Detailed description of algorithm • Hardware Requirements • Portion of software implementing algorithm

  9. Methodology, milestones, and deliverables • Remaining steps for semester • Implement algorithm in hardware • If possible, use on a vehicle • Deliverables by end of semester • Detailed algorithm • Software implementation • Hardware implementation

  10. Methodology, milestones, and deliverables • Difficulties • A good algorithm is… • Cost-effective, precise, easy to implement, without atomic clocks/synchronization, robust… • Getting hardware to work properly • No specialized hardware for my algorithm • Method may not be as precise as planned

  11. Methodology, milestones, and deliverables • Fall-back plan • Explain what I found with my algorithm • Benefits, drawbacks, tradeoffs • Measure position with the precision I can • Find limitations, sources of errors, effect of various obstacles (walls, doors, windows) • If it doesn’t work… • Document what doesn’t work, and why • Lesson for others =)

More Related