About the group

Student information
	Name	Student id	E-mail
Student 1	Camiel Beckers	0766317	c.j.j.beckers@student.tue.nl
Student 2	Brandon Caasenbrood	0772479	b.j.caasenbrood@student.tue.nl
Student 3	Chaoyu Chen	0752396	c.chen.1@student.tue.nl
Student 4	Falco Creemers	0773413	f.m.g.creemers@student.tue.nl
Student 5	Diem van Dongen	0782044	d.v.dongen@student.tue.nl
Student 6	Mathijs van Dongen	0768644	m.c.p.v.dongen@student.tue.nl
Student 7	Bram van de Schoot	0739157	b.a.c.v.d.schoot@student.tue.nl
Student 8	Rik van der Struijk	0739222	r.j.m.v.d.struijk@student.tue.nl
Student 9	Ward Wiechert	0775592	w.j.a.c.wiechert@student.tue.nl

Update Log

28-04: Updated the page with planning and initial design.

29-04: Updated page with initial design PDf (not yet "wikistyle")

07-05: Small changes in wiki page

09-05: Changes in design (incl. composition pattern, removed components&specifications)

11-05: Changes in design (incl. composition pattern), evaluating first experiment

13-05: Evaluating second experiment, corridor competition and discuss initial software

14-05: Evaluating corridor competition, update initial ideas wrt detection, movement etc.

16-05: Update Movement.

20-05: Evaluatue third experiment.

24-05: Update Design, Detection, Movement, SLAM and overall Planning.

27-05: Correct design, detection, movement, SlAM etc. to last design.

03-06: Revised composition pattern.

Planning

Week 7: 1 June - 7 June

2 June: Revised Detection, correcting Hough Transform and improving robustness
2 June: Back-up plan considering homing of PICO (driving based on potential field)
3 June: SLAM finished, functionality will be discussed (will it or will it not be used?)
4 June: New experiment: homing, SLAM, ....
Working principle of decision maker
Add filter to Detection: filter markers to purely corners

Week 8: 8 June - 14 June

10 June: Final design presentation - design and "educational progress"

Week 9: 15 June - 22 June

17 June: Maze Competition

Introduction

Robots Pico and Taco

For the course Embedded Motion Control the "A-MAZE-ING PICO" challenge is designed, providing the learning curve between hardware and software. The goal of the "A-MAZE-ING PICO" challenge is to design and implement a robotic software system, which should make Pico or Taco be capable of autonomously solving a maze in the robotics lab.

PICO will be provided with lowlevel software (ROS based), which provides stability and the primary functions such as communication and movement. Proper software must be designed to complete the said goal. Various models are used to design the behavior and structure of the software, see Software Design. The final software design, including Git-links, is also dicussed in this section. The details of the various software functions can be found in the Software Subsystems. At the end of the page, the Maze challenge is discussed and an overall conclusion is presented.

Software Design

The software design is discussed in the following subsections. The requirements and functions of the software are listed and two different models are used to characterize the behavior and structure of the software. Note that the actual functionality of the software is not discussed in this section. More detailed information about the individual software functions can be found in Software subsystems.

Requirements and functions

Functions and requirements

The requirements specify what expectations the software should fulfill. In order for the robot to autonomously navigate trough a maze, and being able to solve this maze the following requirements are determined with respect to the software of the robot. It is desired that the software meets the following requirements:

Move from one location to another
No collisions
Environment awareness: interpreting the surroundings
Fully autonomous: not depending on human interaction
Strategic approach

To satisfy the said requirements, one or multiple functions are designed and assigned to the requirements. The figure describes which functions are considered necessary to meet a specific requirement.

Behaviour model - The task-skill-motion pattern

Interface

In order to further specify the behavior of the software, a task-skill- motion pattern is constructed. This pattern describes the communication between the specified contexts and functions necessary to perform the task. The contexts and functions are represented by blocks in the interface and correspond with the requirements, functions, components and specifications previously discussed.

The robot context describes the lower level abilities and properties of the robot. In this case motors + wheels, the motor encoders and the laser range finder are mentioned. The EMC-framework controls this hardware and functions as an abstraction layer for the rest of the skills.

The environment context describes the ways the robot stores the information it knows about its surroundings. A geometric world model is used to store the location of corners, while a semantic world model is used to store the different junctions that are available and which of these the robot has already visited. Note that both these world models are implicit and temporary. There is no explicit world model in the software.

The task context describes the control necessary for the robot to deal with certain situations (such as a corner, intersection or a dead end). The skill context contains the functions which are considered necessary to realize the task. Note that the block `decision making` is considered as feedback control, it acts based on the situation recognized by the robot. However `Strategic Algorithm` corresponds with feed-forward control, based on the algorithm certain future decisions for instance can be ruled out or given a higher priority.

Furthermore, the skill context is divided into two subsections, which correspond to two of the subsections in the composition pattern, and contains all the skills the robot possesses.

Structure model - The composition pattern

Composition Pattern

The composition pattern, which functions as the structural model for the code, decouples the behavior model functionalities into the 5C’s. The code is divided into these five separate roles:

Computational entities which deliver the functional, algorithmic part of the system.
Coordinators which deal with event handling and decision making in the system.
Monitors check if what a function is supposed to accomplish is also realized in real life.
Configurators which configure parameters of the computational entities.
Composers which determine the grouping and connecting of computation entities.

The complete system is split into three subsystems, consisting of the movement subsystem, the detection subsystem and the strategy subsystem. The operation of each of these subsystems is explained in the sections below. The way in which these three work together is determined by the monitor, coordinator and composer of the main system.

Main

The main task of the main file is to schedule the different subsystems correctly. Initially, only the detection subsystem and the movement subsystem are active. In this state, the robot moves forward by use of a potential field, while situations are searched. Once the detection subsystem recognizes a certain situation, the strategy subsystem is included in the main loop. This subsystem makes a decision regarding the direction of the robot, based on the information provided by the detection subsystem. New orders are then send to the movement subsystem, which determines and sets the robot velocity. In the case that the strategy thinks a door request should be called, this is also scheduled in the main file.

Detection

The detection subsystem is used to process the data of the laser sensors. Its main function is to observe the environment and send relevant information to the other subsystem and the main coordinator. The coordinator of the detection subsystem receives the unprocessed data from the EMC-framework and corrects the odometry data for a possible offset. As commissioned by the coordinator the composer then triggers all computational entities, which are then carried out consecutively. The computational entities are shortly explained, and further elaborated in the "Software Design".

Measurement Processing: using Hough transform to convert LFR data to lines and markers.
Situation Recognition: detecting corners, corridors and doors based on lines obtained by the Measurement Processing function.
SLAM: creating global coordinate frame in order to localize PICO in the maze. (not used in final version of the code)
Odometry correction: sending out the odometry data with respect to a certain origin. This origin can be replaced by use of the configurator.

Strategy

When the detection subsystem recognizes a situation (junction, T-junction or cross-junction) a discrete event is send to the coordinator of the strategy subsystem which then will make a decision regarding the direction the robot should move, based on the available options (as detected by the detection subsystem) and junction memory. The junction memory records which of the junctions of the situation have already been investigated. Based on this information one of the two movement types is chosen, see movement subsection, to guide to robot in the right direction. The movement type + direction is sent to the movement subsection. The strategy subsystem also has the possibility to request the opening of doors.

Movement

The movement subsystem controls the movement of the robot, based on the input it receives from the other subsystems. This subsystem has two different composers, the last of which is not used in the final version of the script.

Strategy

The Strategy consists of two plant, the initial plan and the final plan as used during the Maze challenge.

Initial Plan

The initial strategy plan is dependant of the SLAM and Detection part of the code. It consists of a Tremaux algorithm which is provided with a highest succes rate decision maker, a pathplanner and a Dijkstra algorithm to determine the shortest path.

Tremaux describes the placing of landmarks and the (random) order selection of certain choices which can be made by PICO, in this case which path to continue at i.e. an intersection. The highest succes rate decision maker is applied to remove the randomness in the Tremaux algorithm, the direction of the intersection with the least side branches is most preferred (it has the most chance of being successful).

The pathplanner is used to process all the landmarks placed by the Tremaux algorithm into a matrix, describing all possible connections and costs (in this case distance) between nodes. The Dijkstra algorithm will determine the lowest distance of unvisited node, connected to a certain starting node. All possibilities will be stepwise determined, updating the most proferred path from start to end. At the end of the strategy process an array will result, describing all necessary landmarks PICO should move to in order to reach the end.

Change of Plans

As earlier discussed, SLAM is not working robustly as desired, rotation of PICO leads to insufficient results. Since the original plan of Strategy was highly dependant on both the overall Detection as SLAM, a change of tactics is necessary. The alternative plan will not make use of SLAM, and therefore the strategy lacks the presence of certain map. As a result , some issues will occur in specific occasions. These issues will be tackled individually, the main goal in this stage of the project is a PICO actually capable of finishing the Maze challenge.

Due to the absence of SLAM and the map, the Tremaux and Dijkstra algorithms can not be used as initially planned. The strategy will now consist of a " switch", capable of switching between the Homing and the action as decided by the decision maker. Detection will detect a i.e. a deadend or junction, raising their corresponding integer. This integer will trigger a specific decision maker in Strategy based on the situation PICO has recognized. Detection will also determine the open side branches, usefull for the orientation of the T-junction.

If PICO would recognize a junction, a position in which in certain choice has to be made, the decision maker is triggered. The decision is predescribed and depends on the value of the previous " action" of PICO. If PICO would have made a certain decision at a junction, and this choice was unsuccesfull, it will return to the same junction and the " action" is updated. In this way, PICO will analyse every choice in a structured manner. If during a certain choice PICO would again recognize a junction this means that this choice is in some way succesfull, therefore the " action" is resetted. For the T-junction and cross junction to following actions are predescribed:

Cross junction: 1: "go right", 2: "go straight", 3: "go left" and 4: "go straight"
T-junction: 1: "go right" and 2: "go straight"

For the T-junction this will mean that the action is automatically updated if the desired direction as predescribed by the action schedule set is not possible (hence not open). This method us somewhat cumbersome and time demanding, but should make PICO capable of finishing the maze.

Movement

The "movement" part of the software uses data gathered by "detection" to send travel commands to PICO. As already discussed, the part of "strategy" is basically the "decision maker" which commands the "movement" of PICO. An odometry reset has been implemented to make sure that the code functions properly every time PICO starts in real life.

The current non-linear controller has some sort of stiffness, which results in PICO slowing down too soon too much. This “stiffness” can be removed, so it just goes full speed all the time, but this is a bad idea. Due to the sudden maximum acceleration and deceleration which might result in a loss of traction, the odometry data could get corrupted and therefore the movement would not work properly. Instead, a certain linear slowing down is introduced when PICO comes within a certain range of its destination. It also slowly starts moving from standstill and linearly reaches its maximum velocity, based on a velocity difference.

Local coordinates

The main idea is to work with local coordinates. At time t=0, coordinate A is considered the position of PICO in x, y and theta. With use of the coordinates of edges received by "detection" point B can be placed, which decribes the position PICO should travel towards. This point B will then become the new initial coordinate, as the routine is reset. In case of a junction multiple points can be placed, allowing PICO to choose one of these points to travel to.

The initial plan is to first allow PICO to rotate, followed by the translation to the desired coordinates. This idea was scrapped, because this sequence would be time consuming. Instead a non-linear controller was used, that asymptotically stabilizes the robot towards the desired coordinates.

Although the PICO has an omni-wheel drive platform, it is considered that the robot has an uni-cylce like platform whose control signals are the linear and angular velocity ( $[math]\displaystyle{ u }[/math]$ and $[math]\displaystyle{ \omega }[/math]$ ). The mathematical model in polar coordinates describing the navigation of PICO in free space is as follow:

[math]\displaystyle{ \dot{r}=-u \, \text{cos}(\theta)\! }[/math]

[math]\displaystyle{ \dot{\theta}=-\omega + u\, \frac{\text{sin}(\theta)}{r},\! }[/math]

where are $[math]\displaystyle{ r }[/math]$ is the distance between the robot and the goal, and $[math]\displaystyle{ \theta }[/math]$ is the orientation error. Thus, the objective of the control is to make the variables $[math]\displaystyle{ r }[/math]$ and $[math]\displaystyle{ \theta }[/math]$ to asymptotically go to zeros. For checking such condition, one can consider the following Lyapunov function candidate: $[math]\displaystyle{ V(r,\theta) = 0.5 \, r^2 + 0.5 \, \theta^2 }[/math]$ . The time derivative of $[math]\displaystyle{ V(r,\theta) }[/math]$ should be negative definite to guarantee asymptotic stability; therefore the state feedback for the variables $[math]\displaystyle{ u }[/math]$ and $[math]\displaystyle{ \omega }[/math]$ are defined as,

[math]\displaystyle{ u = u_{max}\, \text{tanh}(r)\, \text{cos}(\theta) \! }[/math]

[math]\displaystyle{ \omega = k_{\omega} \, \theta + u_{max} \frac{\text{tanh}(r)}{r} \, \text{sin}( \theta) \, \text{cos}( \theta),\! }[/math]

where $[math]\displaystyle{ u_{max} }[/math]$ and $[math]\displaystyle{ k_{\omega} }[/math]$ both are postive constants.

Potential field

If PICO would be located at position A and would directly travel towards point C, this will result in a collision with the walls. To avoid collision with the walls and other objects, a potential field around the robot will be created using the laser. This can be interpreted as a repulsive force $[math]\displaystyle{ \vec{U} }[/math]$ given by:

[math]\displaystyle{ \vec{U}(d_l) = \begin{cases} K_0 \left(\frac{1}{d_{pt}}- \frac{1}{d_l} \right) \frac{1}{{d_l}^2} & \text{if } d_l \lt d_{pt}, \\ ~~\, 0 & \text{otherwise}, \end{cases} }[/math]

where $[math]\displaystyle{ K_0 }[/math]$ is the virtual stiffness for repulsion, $[math]\displaystyle{ d_{pt} }[/math]$ the range of the potential field, and $[math]\displaystyle{ d_l }[/math]$ the distance picked up from the laser. Moreover, the same trick can be applied in order for an attractive force

[math]\displaystyle{ \vec{V}(d_l) = \begin{cases} 0 & \text{if } d_l \lt d_{pt}, \\ ~~\,K_1 d_{l}^2 & \text{otherwise}, \end{cases} }[/math]

where $[math]\displaystyle{ K_1 }[/math]$ is virtual spring for attraction. Summing these repulsive force $[math]\displaystyle{ \vec{U} }[/math]$ results into a netto force,

[math]\displaystyle{ \vec{F}_n = \sum_{i=1}^N \vec{U}(d_{l,i}) + w_i\vec{V}(d_{l,i}), }[/math]

where $[math]\displaystyle{ N }[/math]$ is the number of laser data, and $[math]\displaystyle{ w }[/math]$ a weight filter used to make turns. Assume that the PICO has an initial velocity $[math]\displaystyle{ \vec{v_0} }[/math]$ . Once a force is introduced, this velocity vector is influenced. This influence is modeled as an impulse reaction; therefore the new velocity vector $[math]\displaystyle{ \vec{v}_r }[/math]$ becomes,

[math]\displaystyle{ \vec{v}_r = \vec{v_0} + \frac{\vec{F}_n \,}{m_0} \, \Delta t, }[/math]

where $[math]\displaystyle{ m_0 }[/math]$ is a virtual mass of PICO, and $[math]\displaystyle{ \Delta t }[/math]$ the specific time frame. The closer PICO moves to an object, the greater the repulsive force becomes. Some examples of the earlier implementation are included:

Maze challenge

During the maze challenge, the performance of PICO was not satisfactory as it wasn't able to reach the door or solve the maze. During the final test, the day before the challenge, it was already clear that the detection part of the code did not give the desired results in real life, which is in contrary to the simulation where it worked fine. This is caused by the fact that in real life, the incoming laserdata is not so nicely received by PICO due to diffuse reflectance of the walls, opposed to in the simulation where the walls are 'smooth', and due to noise present in the data. Although prior testdata was saved to optimize the detection afterwards with the simulation, it did not give the same results as in real life. Apparently these tests were not representative for the actual maze. The robot did not recognize situations properly because the detection part, which should have distinguished the situations that could appear in a maze, was not robust enough. To try to make it work, some tolerances were changed. However, during the first try of the maze challenge, PICO started rotating too early or kept rotating because the detection was still not good enough. This made PICO think it was at a junction all the time and that it had to take action, i.e. make a turn.

For the second try, a different code was used with other detection parameters. This time, PICO did a better job at recognizing the situations, but still not satisfactory. It failed to recognize the T-junction of the door, after which it came to a halt at a corner. Stuck in its place, it did not move anymore and that concluded the second try. The fact that it did not move anymore might be because of the used potential field which was used to drive. The input command for driving was very low when it got stuck. The potential field did not have an integrator action to give it a high value when standing still. With the low drive input, the motors did not get enough power to overcome the static friction, resulting in PICO being stuck in one place.

An improvement therefore would be to add an extra check to verify if the drive input is high enough and, if necessary, increase this input. The detection part of the code should be made more robust as well to make sure the situations that are present in a maze will be detected properly. This could be done by for instance adding filters to the incoming laserdata or by changing the detection tolerances which are used to determine whether something is a cross- or T-junction.

Overall conclusion

We learned a lot during the course of this project, i.e. programming in C++ in a clear and structured way by making use of a composition pattern. How to set requirements, functions, components, specifications, and interfaces while designing software to reach a certain goal and the big advantages of designing in this way have become clear. Working with Git and Ubuntu, of which no member had experience with, is something that has improved our overall programming efficiency and will be useful in the future. Furthermore, the communication of the hardware and software of a robot has become clear thanks to the hands on tests with PICO and the lectures of Herman Bruyninckx.

It is unfortunate that PICO did not solve the maze in the end. Up to the final test, the day before the maze challenge, it could detect situations in the maze and move nicely through our small test-mazes. However, when we put everything together it did not do what we intended it to do. In the end, we think we bit off more than we could chew. At the start of the project we decided to use SLAM to create a world model and based on that we would use Tremaux's alghorithm to solve the maze. We wanted to make everything ourselves and not just simply implement already existing methods from OpenCV or ROS, so we would understand what is happening. However, it proved that SLAM was hard to realize and that creating our own Hough-lines algorithm was no easy task either. Furthermore, the overall code structure kept changing during the project to match the composition pattern, which step after step kept improving. These improvements were a combination of new code/tactics and the lack of experience at the beginning of the project. After it had been decided that it would be too risky to rely on SLAM, as it might or might not work, a simpler strategy was used and there would be no mapping of where the robot has been. The main focus was shifted to creating a clear code structure, in which we succeeded if we do say so ourselves.

Regarding SLAM, we were very close to successfully creating it on our own as can be seen in SLAM. With more time, this would be a success as well. A thing which was a success, was the way PICO moved using Point2Point and Collision Avoidance. It moved nicely towards a set point in space while it avoided obstacles in its way. Due to the change of strategy without SLAM, we did not implement it as it would rely on SLAM. In the end, with the changed strategy PICO was able to move nicely through the maze in the simulator, but unfortunately not in real life.

A challenge during the entire project was our group size. We noticed it was important to maintain good communication with everyone, something which was difficult and not always achieved. We experienced that the reality is different from the simulation and if we had more testing time, we might have altered the code such that the results were satisfactory. We also learned that first determining a good overall code structure and sticking to it is key. We did change the structure a lot, but we are proud of it now. Another thing we are proud of, is the fact that we wrote everything ourselves, even if it was not used eventually, like SLAM.

Embedded Motion Control 2015 Group 7

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