Embedded Motion Control 2013 Group 5: Difference between revisions

Group members

Tutor:
Sjoerd van den Dries

Planning

Figure 1:Coordinate system for PICO

Figure 2: Line detection OpenCV

Figure 3: Structure ROS

Figure 4: Graphical representation of drive-straight node

Figure 5:Strategy, steps for driving

Fig 6:Different types of junctions

Progress

Week 1:

• Installed the software

Week 2:

• Did tutorials for ROS and the Jazz simulator
• Get familiar to 'safe_drive.cpp' and use this as base for our program
• Defined coordinate system for PICO (see Figure 1)

Week 3:

• Played with the Pico in the Jazz simulator by adding code to safe_drive.cpp
• Translated the laser data to a 2d plot
• Implemented OpenCV
• Used the Hough transform to detect lines in the laser data
• Tested the line detection method mentioned above in the simulation (see Figure 2)
• Started coding for driving straight through a corridor (drive straight node)
• Started coding for turning (turn node)

Week 4:

• Reorganize our software architecture after the corridor competition
• Created structure of communicating nodes (see Figure 3)
• Finish drive straight node (see Figure 4)
• Finish turn node
• Started creating a visualization node

Week 5:

• Finish visualization node
• Started creating node that can recognize all possible junctions in the maze (junction node)
• Started creating node that generates a strategy (strategy node) (see Figure 5)
• Tested drive-straight and turn node on Pico, worked great!

Week 6:

• Finished junction node (see Figure 6)
• Started fine tuning strategy node in simulation
• Tested visualization and junction node on Pico, worked fine!

Week 7:

• Finished strategy node (in simulation)
• Tested strategy node on Pico, did not work as planned
• Did further fine tuning of strategy node

Week 8:
...

Software architecture

The software architecture is shown in figure 3. In this section the architecture is explained in more detail. First we present an overview of all nodes, inputs and outputs. Then the most challenging problems that have to be tackled to solve the maze and the solutions are discussed.

Overview nodes

The software to solve the maze is build around the strategy node. This node receives all the information that is needed to solve the maze, and sends information to the nodes that actuate Pico. An overview of all nodes is given below. The column "PROBLEMS SOLVED" give a short description of the problems that are solved in the node, more information about the solution can be found in the chapter Problems and solutions

Problems and solutions

The main problem in this course is making sure that Pico can solve a maze. This problem can be divided into sub-problems, these are explained here. On this page a short description of the problem and the answer is given. The more detailed description can be found by clicking on the title.

Localization

Problem: Localization is a problem in which Pico needs to determine what the geometry of its surrounding. More specific, for the purpose of solving the maze, the walls surrounding Pico must be identified based on the laser data.
Solution:

Generate reference point

Problem:
When Pico is located in a corridor, it needs to drive trough the corridor until a junction appears at his path. The problem is to let Pico move through the corridor, preferably in the middle of the corridor but at least without hitting the wall. Solution:
Figure 4 is an example of a situation of Pico in the corridor. The current position (p1) of Pico is the intersection between the blue and red line. The orientation of Pico is displayed by the blue line. The red line connects the current position (p1) with the reference point (p2). The error angle, which is given by the difference between the current angle of Pico and the reference angle. This error angle is used as control input fot the velocity of Pico.

Control motion: drive straight

Problem:
Pico is driving through a rather narrow corridor and may not hit the wall. Since Pico is not moving slip-free, it will not drive straight by itself. Not even when only a translation velocity command is given. Solution:
To make sure Pico drives straight through the corridor in a direction parallel to the walls, a feedback controller is implemented. An error is calculated based on the reference point and its current position/orientation. This error is used to determine the translation and rotation velocity to ensure that Pico drives straight in the corridor.

Control motion: turning

Problem:
Solution:

Create user interface

Problem:
Solution:

Finding the next best step

Problem:
Solution:

Junction recognition

Problem:
Solution:

Evaltuation

Project

Peer review

References

• A. Alempijevic. High-speed feature extraction in sensor coordinates for laser rangefinders. In Proceedings of the 2004 Australasian Conference on Robotics and Automation, 2004.
• J. Diaz, A. Stoytchev, and R. Arkin. Exploring unknown structured environments. In Proc. of the Fourteenth International Florida Artificial Intelligence Research Society Conference (FLAIRS-2001), Florida, 2001.
• B. Giesler, R. Graf, R. Dillmann and C. F. R. Weiman (1998). Fast mapping using the log-Hough transformation. Intelligent Robots and Systems, 1998.
• Laser Based Corridor Detection for Reactive Navigation, Johan Larsson, Mathias Broxvall, Alessandro Saffiotti http://aass.oru.se/~mbl/publications/ir08.pdf