Mobile Robot Control 2020 Group 4: Difference between revisions

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===Escape room challenge results===  
===Escape room challenge results===  
With the wall-following algorithm, the PICO achieved second place in the escape room challenge. The exit was reached within 27 seconds. The result of the challenge can be seen in the video below.
With the wall-following algorithm, the PICO achieved second place in the escape room challenge. The exit was reached within 27 seconds. The result of the challenge can be seen in the video below.
[[Image:MRC2020_G4_ROOM_ESCAPE.gif|Escape Room results]]
[[Image:MRC2020_G4_ROOM_ESCAPE.gif|Escape Room results|400 px]]


=Hospital Challenge=
=Hospital Challenge=

Revision as of 14:38, 7 June 2020

Group Members

Name Student Number Email
M. Katzmann 1396846 m.katzmann@student.tue.nl
B. Kool 1387391 b.kool2@student.tue.nl
R.O.B. Stiemsma 0852884 r.o.b.stiemsma@student.tue.nl
A.S.H. Vinjarapu 1502859 a.s.h.vinjarapu@student.tue.nl
D. van Boven 0780958 d.v.boven@student.tue.nl
R. Konings 1394819 r.konings@student.tue.nl


Escape Room Challenge

To safely get the PICO robot to the exit of the escape room, the strategy to implement a wall-follow algoritm is chosen. If the Algoritm is implemented succesfully it should be a safe and quick solution to the problem. The PICO will follow move to a wall, after which he will align perpendicular to the wall. When aligned to the wall, PICO will move left until it reaches either a wall or a gap. It will choose to rotate or drive into the gap accordingly. This algorithm is being chosen because by researching Escape Room project of previous years, this algorithm scored well, based on time and whether the PICO finished at all.

EscapeRoom.png

The wall-follow algorithm is divided into the following subparts:

Step 1: The PICO moves forward

The PICO moves forward until it reaches a wall. The PICO will start at a random location inside the escame room. This means the robot can be anywhere inside the room. Thus, the first thing PICO does is move forward until it detects a wall getting closer. As the wall gets closer, the velocity of PICO decreases until it reaches a certain threshold from the wall, which means the PICO will stop moving.

Step 2: The PICO aligns to the wall

When PICO reaches the wall and completely stops moving, PICO starts rotating. It will rotate until it is perpendicular to the wall. This is achieved by having PICO stop rotating once the the middle LFR sensor has the smallest value. Here, the rotational velocity also decreases when the distance to the end point decreases.

Step 3: The PICO follows the wall

Once the PICO is perpendicular to the wall, it is ready to start following the wall. This is done by moving the PICO to the left until it detects a corner. If the PICO detects a convex corner, this means there is a corner approaching, and if the PICO detects a concave corner, this means there is a corridor approaching. The PICO will take the correct measures in the next step according to what it detects.

Step 4: The PICO makes choices according to what it detects

If this corner is convex
The PICO will align to the wall which is perpendicular to the previous wall. Wehn aligned correctly it will go back to step 3 and repeat the process.
If this corner is concave
The PICO drives a little further until the PICO is aligned to the exit. Once it is aligned to the corridor and feels safe enough to move, the PICO will move forward until the exit is reached.

During the wall-follow algoritm, the PICO checks if it is too close to a wall and if it is well alligned at all times.

Escape room challenge results

With the wall-following algorithm, the PICO achieved second place in the escape room challenge. The exit was reached within 27 seconds. The result of the challenge can be seen in the video below. Escape Room results

Hospital Challenge

[Under construction]

For the Hospital Challenge, the design of the algorithm is divided into four parts: interaction, supervisory, mapping and navigation. Each part has its own functionality and needs to work with the other parts. This functionality is explained below:

Interaction

These are all low-level interactions consisting mostly of calls to the IO API (which represents communication with PICO).

Supervisory

This section covers the governing control logic of the proposed system. The idea is that the supervisor makes choices, tunes parameters, and controls flow-of-command with in remaining code depending on its mode, and changes modes dynamically.

Mapping

Feature Recognition

SLAM

The chosen algorithm for localizing PICO and updating the map with real-world information is fastSLAM2, with the actual implementation largely supported by online lectures and research by Cyrill Stachniss.

The core idea of fastSLAM (especially in its comparison to normal Extended Kalman Filter (EKF) Particle Filter SLAM approaches) is the concept that the relationship between a robot's motion and sensors, and the outside world, is such that given a perfect model, landmarks will always be in the same position. In a more reduced form, using a particle filter to sample the robot's path, this relationship still holds, allowing one to model the outside world as a list of landmarks with a much more static nature than an ever growing hypothetical map of the outside world (which is what normal EKF filters do). Due to this, the measurement covariance element of a single landmark is nothing more than a 2x2 matrix, which, given that it has to be inverted and the most efficient inversion algorithm is O(n3), is a very big deal.

The core idea of fastSLAM2 is to patch a hole in fastSLAM1 where information is lost. Specifically, in the part of the algorithm that is described as 'sampling the pose' - making a prediction, for a particle, of the robot state in the next measurement iteration - fastSLAM2 does not make use of that iteration's measurements. However, by nature of the above relationship, measurements and odometry data are almost equivalently tied to the robot's behaviour. As such, fastSLAM2 includes measurement data when it predicts a robot's state, which, as the paper linked above explains, dramatically improves performance of the algorithm.

Map Updating

PICO segmentation.gif

Navigation

This section covers the system functionalities responsible for (intelligent) navigation. All functions here have read access to the world model’s internal map and LRF envelope. The navigation can be split into two parts: pathfinding and path movement.

Path Finding

For pathfinding, A* is chosen. A* is a pathfinding algorithm based and built on Dijkstra's Algorithm. Dijkstra's Algorithm looks at every available cell all around the start point, until it reaches the goal. A* is smarter, and attaches more value to the cells towards the goal. Because of this, A* needs fewer iterations and is faster.

Dijkstra's Algorithm A* Algorithm
Figure 1: Difference between Dijkstra's algorithm (left figure) and A* (right figure).

Path Movement

Path movement translates the points of the trajectory of the A* algorithm to a vector of necessary x and y speed values for the PICO robot to follow the trajectory.

List of Meetings

Date/Time Roles
Meeting 1 01-05-2020

11:00

Chairman: Bas
Secretary: Max

Meeting 2 04-05-2020

11:00

-

Meeting 3 08-05-2020

11:00

Chairman: Max
Secretary: Dominic

Meeting 4 11-05-2020

10:00

-

Meeting 5 12-05-2020

10:00

-

Meeting 6 15-05-2020

11:00

Chairman: Dominic
Secretary: Roel

Meeting 7 18-05-2020

11:00

-

Meeting 8 22-05-2020

11:00

Chairman: Roel
Secretary: Rob

Meeting 9 27-05-2020

15:00

-

Meeting 10 29-05-2020

11:00

Chairman: Rob
Secretary: Ananth

Meeting 11 02-06-2020

11:00

-

Meeting 12 04-06-2020

11:00

Chairman: Ananth
Secretary: Bas


Links

These will probably be invite-based but a backup link could be useful.

Gitlab: https://gitlab.tue.nl/MRC2020/group4

Overleaf design document: https://www.overleaf.com/project/5eabeda72b3e4100010f8b40

Sharepoint: https://tuenl-my.sharepoint.com/:f:/r/personal/r_konings_student_tue_nl/Documents/4SC020%20EMC?csf=1&web=1&e=g6PXRQ

Deliverables