1 / 12

Outline

Outline. Previous Accomplishments Last year's SURG Mapkin Proposal Concept Why is this useful? The MikroKopter platform Previous work Criteria For Success. Previous Accomplishments. http://www.youtube.com/watch?v=TkMKTtFGlxc&feature=player_embedded Quadrotor with AeroQuad base

stacey-riddle
Download Presentation

Outline

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. Outline • Previous Accomplishments • Last year's SURG • Mapkin • Proposal Concept • Why is this useful? • The MikroKopter platform • Previous work • Criteria For Success

  2. Previous Accomplishments http://www.youtube.com/watch?v=TkMKTtFGlxc&feature=player_embedded Quadrotor with AeroQuad base •     Flexible platform for aerial robotics research. •     Implemented full automatic stabilization • Only inputs required are desired translation and rotation. • PID Tuned from AeroQuad base • Sonar based altitude hold •     Controller capable of supporting other aerial platforms.

  3. Quadrotor in action • Flown by remote control • "Stable mode" lets the quadrotor balance itself • "Acrobatic mode" is rate control for the quadrotor's movement.

  4. Mapkin • Our Build 18 Project, first week of the semester • Ground vehicle • XBOX Kinect sensor • Map out obstacles in a 2D Grid • Future goal: SLAM in 2D to learn concepts to apply to Quadrotor

  5. Proposal Concepts "Aerial Point-Cloud Generation using the Microsoft Kinect on an Autonomous Quadrotor" • Last SURG: outdoor, unstructured environments, control of the quadrotor and mapping. • Current proposal: • Constrained to indoor environments, tight obstacles to avoid • XBOX Kinect depth and color sensing • Point-Cloud generation in 3D (offboard) • More online computation for autonomous navigation • Goal: quadrotor navigates itself a short distance indoor, builds a point-cloud representation on a nearby computer

  6. Why is this useful? • Feedback from robots needs to be useful for humans • Applications: • Exploring disaster zones • Exploring unreachable areas • Military • Navigation can be autonomous or RC • Point-clouds mean the robot's perspective could easily be understood by a human operator

  7. The MikroKopter Platform • Quadrotor kit • Many parts of the navigation, etc are done (most are editable code) • Waypoint navigation provided • We'll need to add: • Microsoft Kinect sensor for vision • Any additional sensors (e.g. downward sonar) • BeagleBoard processor for onboard control

  8. Previous Work • CMU Robotics Institute, including the Micro Air Vehicle Lab • University of Pennsylvania, "Aggressive Maneuvers" • We'd like our perception and obstacle detection onboard. • Our own last SURG • We're confident we can get a flying quadrotor quickly and move on to complex behaviors  • Other mapping/SLAM projects • http://www.youtube.com/watch?v=D_nt5Qg1Nag

  9. Criteria For Success • Successfully fly a Kinect around inside using RC • Navigate inside autonomously over a short distance • Produce a point-cloud map from Kinect imagery • Final Question: Is our product usable?

  10. Questions?

More Related