4267a7e91085dd1a999fa832e90e73530f8e4c91
[bachelor-thesis/written-stuff.git] / Ausarbeitung / introduction.tex
1 \chapter{Introduction}
2 The world nowadays depends more and more on robots. But not only stationary
3 robots, like those used in assembly lines, improve our lives and make it
4 possible to excel at industrial and exploratory challenges. Also, mobile robots
5 could be an integral part of our world in the near future. Not only are they
6 predestined for dangerous duties which would much certainly cost lives if
7 humans had to do them, like detecting disarming mines in war zones, they are
8 also much more specialized to their challenges.
9
10 However, in most cases, mobile robots become useless if they don't know anything
11 about their environment. Especially their location is a basic to know,
12 and particularly autonomous mobile robots benefit from the knowledge about their
13 location. This knowledge gives them the ability to create a map of their
14 environment, to find ways between certain points of interest, and to contact
15 both human beings as well as other robots.
16
17 There are several methods to achieve knowledge about the location of mobile
18 robots. At first, they can be classified as absolute or relative methods. For
19 example, absolute positioning methods rely on a fixed, distributed
20 infrastructure which allows the robot to determine its absolute location inside
21 a specific region. For example, the \ac{GPS} only works because satellites orbit
22 around the earth and constantly send a signal. There are also approaches using
23 navigation beacons or by matching the observed environment to a previously
24 known map.
25
26 All of that positioning methods however depend on the infrastructure, which can
27 be expensive to deploy and maintain. Also, most of the algorithms used are
28 fairly complex and need highly specialized hardware or a certain computing
29 power, and therefore cannot (yet) be used in real time. And sometimes, they are
30 even more imprecise than relative approaches.~\cite{umbmark}
31
32 Relative positioning methods however only yield a position relative to a
33 defined point, and mostly can be applied with cheap hardware. The best-known
34 approach in this field is \definition{dead reckoning}, which computes the
35 position relative to an initial starting point by considering the covered
36 distance and course the robot has moved. In the case of mobile robots, the
37 covered distance can be simply computed in real time from the revolution of its
38 wheels, or by accelerometers the robot may be equipped with.
39
40 The advantage of dead reckoning is that it is easy and fast to implement.
41 However, there is also a drawback. The vehicle's current position is based on
42 its previous position, and distance and course measurement is mostly imprecise.
43 the error of the calculated position grows with time. In order to maintain a
44 certain accuracy, countermeasures need to be taken to keep the error as small as
45 possible.
46
47 In this thesis, the popular Roomba manufactured by the iRobot Corporation is
48 used as an instance for an mobile robot, since it is cheap, small, and can be
49 simply controlled over a serial interface. The Roomba is accompanied with a
50 netbook sitting on top of it, on which runs an application to represent the
51 autonomous aspect. This application in turn uses the Wiselib library to control
52 the Roomba.
53
54 In the first experiment, the Roomba's movement behaviour will be analyzed. Then,
55 two different easy approaches for minimizing the positioning error are presented
56 and tested for their suitability.
57
58 \chapter{Related Work}
59 There are already some results on the problem. Yamauchi proposes to use dead
60 reckoning with evidence grids to represent the robot's view of the
61 world.~\cite{yamauchi} Evidence grids are subdivisions of the Cartesian space
62 into cells, and each cell is assigned a probability value representing the
63 estimated probability of occupancy by the robot. The robot now explores its
64 environment, using its sensors to detect moving and fixed obstacles, and finally
65 tries to find its home location again using dead reckoning. On its way back, it
66 creates a second evidence grid. Finally, both grids are incorporated by an
67 algorithm, which estimates the error in orientation and translation.
68 Experimental results with a real robot showed a maximum translation error of 28\%
69 and an orientation error of 25\%.
70
71 Chong and Kleeman use high-precision odometry to increase the accuracy
72 of position estimation by dead reckoning.~\cite{chongkleeman} They succeeded in
73 building a odometry system that is as good as the best reported system, but can
74 be fabricated at low-cost.
75
76 Borenstein and Feng design a benchmark for mobile robots.~\cite{umbmark} They
77 show how to measure systematic and non-systematic errors, and how to correct
78 them.
This page took 0.053067 seconds and 3 git commands to generate.