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Does anyone have any experience with developing or working on the autonomous robot problem, in particular developing the SLAM algorithm? I would like to know where would be a good place to get started on developing a very very basic version on SLAM. Also any pointers to resources on the topics (other than the obvious google searches) would be appreciated.

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up vote 21 down vote accepted

The book Probabilistic Robotics by Thrun, et al spends a good deal of time on SLAM.

OpenSLAM has a lot of SLAM resources and implementations of different SLAM algorithms.

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Great book! Exactly what I was looking for, this book introduces everything from scratch, read about 1/5th into the book now and have a much better understanding. – ldog Jan 16 '10 at 21:51
Ya, it is definitely a great book. Make sure you check out the errata page though, since there are some math errors here and there depending on which printing you have. robots.stanford.edu/probabilistic-robotics/errata.html – Eric Perko Jan 18 '10 at 9:18

Probabilistic Robotics is definitely a great book to start from, but current algorithms have moved past much of the scope that it covers.

Grisetti's TORO (available from OpenSLAM) is a speedy algorithm that can close loops in O(N) time (where N is the size of the loop). It might suit you under the following conditions:

  • You don't need optimal accuracy (e.g. you're not using this to perform structure-from-motion, or narrow the search range for visual features)
  • You don't use position-only sensors, such as GPS.

Kaess' iSAM is very good if you want optimal accuracy (optimal in a least-squares sense). It may suit you under the following conditions:

  • You use GPS.
  • You would benefit from optimal accuracy.
  • You don't mind that it closes loops in O(N^2) time, where N is the number of poses in the loop.
  • Your robot can stop to re-solve the map from scratch every few hundred waypoints. This will take a few seconds. (This weakness has been overcome in his recent tech report though).
  • Your initial pose estimates are decent. Otherwise, iSAM can get stuck in local minima.

Finally, you can skim my IROS 2010 paper on flexible SLAM, which gives you a knob with which you can adjust the cost of closing a loop, where more cost means more accuracy. The cost can be set anywhere from O(N) to O(N^2). Even at its least accurate, it is still more accurate than TORO. Use it if:

  • You would like to process even large loop-closures in real-time.
  • You want to use GPS

Also consider the goodness of your initial pose estimates. When using a good laser-scan matching algorithm in limited indoor areas, the pose drift can be quite small. This takes much of the accuracy burden off of SLAM, and the difference between the output of approximate techniques such as TORO and exact techniques such as iSAM becomes slim.

Good luck,

-- Matt

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your link to "IROS 2010 paper" on flexible SLAM is broken. Could you update it? I am interesting in reading it. – Snowman Sep 29 '15 at 3:10
@Snowman Thanks for the heads-up! I've fixed the link. – SuperElectric Oct 11 '15 at 14:16

I know I'm coming to this party a bit late, but I have an extremely simple SLAM implementation that runs in MATLAB (or the free Octave) that is useful for learning the basics. The implementation is about as simple as it gets, comprising only 283 lines of code.

Check it out here: https://github.com/randvoorhies/SimpleSLAM

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Better late than never :) Thanks for the link (and code) I will check this out in more detail once I have some more time. – ldog Jun 13 '11 at 23:44

Some of the people working on robots at the university bielefeld rely on the following papers in their work with a robot.

  • I. Esteban, O. Booij, Z. Zivkovic, and B. Kröse. Omnivision trajectory based slam. In RSS Submitted. IEEE, 2008

  • A Harati, S Gachter, and R Siegwart. Fast range image segmentation for indoor 3D-SLAM. In The 6th IFAC Symposium on Intelligent Autonomous Vehicles (IAV), 2007.

  • A Harati and R Siegwart. Orthogonal 3D-SLAM for indoor environments using right angle corners. In The 3rd European Conference on Mobile Robotics (ECMR), 2007.

Another paper that could give you a starting point is:

  • R. SIEGWART, I.R.NOURBAKHSH (2004). Introduction to Autonomous Mobile Robots. MIT Press

Most of the paper should be found in google scholar.

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Another late answer, but I just came across a tutorial on building EKF slam in Matlab or Octave by Dr. Joan Sola here: http://www.joansola.eu/JoanSola/eng/course.html.

It's about 8 hours of video and it's a little slow, but it does walk you through a working implementation of SLAM.

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In addition, if you write C++, MRPT should be one of your choice in implementing SLAM.

MRPT is Mobile Robot Programming Toolkit purposing on SLAM, computer vision and motion planning algorithm. You will find lots of easy examples and some useful applications like Kalman filter SLAM, graph-SLAM, kinect 3D SLAM, etc.. here.

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openCV is your best bet for this, it is a large library that handles a ton of Computer Vision problems that has a great history, community, and support.


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OpenCV is good for image processing but besides a kalman filter there are no complete mapping algorithms included – Janusz Jul 3 '09 at 19:43
OpenCV is not a SLAM platform. You could possibly build a SLAM framework using it but by itself it has no relation to SLAM. – twerdster Nov 4 '10 at 20:57
Not only does OpenCV not have any SLAM functionality, you're assuming his SLAM front-end is visual. Not an implausible scenario, but laser scan-matching is more common. – SuperElectric Nov 9 '10 at 19:41

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