Welcome to the Wiki Page for Group 5 in the Embedded Motion Control Course (4SC020) 2019. This page contains the design plans and other details of our work in this course.

Team Members

Name	TU/e Number
Winston Mendonca	1369237
Muliang Du	1279874
Yi Qin	1328441
Shubham Ghatge	1316982
Robert Rompelberg	0905720
Mayukh Samanta	1327720

Initial Design of Escape Room Competition

Design Document

The Initial Design Plan for the Escape Room Competition and the Hospital Competition with PICO could be found here.

Requirements

The following performance requirements are expected to be met for the Escape Room Competition:

1. PICO should leave the room from any initial position.
2. PICO should successfully leave the room when all of its rear wheels are across the finish line at the end of the exit corridor.
3. PICO should not hit the wall of the room and the corridor under any condition.
4. PICO should complete the task within 5 minutes and must not remain idle for more than 30 seconds.

To fulfill the above, and keeping the basic aim of the Hospital Competition as stated in the introduction, the following functional requirements have been identified for the given challenges:

1. For the given start area, PICO could determine the cabinet in each room and face towards all the cabinets in the right region marked previously.
2. When PICO visits a cabinet, it should give a clear sound of which cabinet it is visiting (i.e.,“I have visited the cabinet zero”).
3. PICO should reach all the cabinets with a correct order.
4. PICO could detect the obstacles in this competition not only static objects but also dynamic ones (Such as the walking actor in the hallway).
5. PICO could not hit any walls and objects except for slightly touching.
6. PICO should try to detect the static and dynamic objects and present them in its own world model.
7. PICO should complete the task within 10 minutes and must not remain idle for more than 30 seconds.

Functions

	Function	Description
High-level	Detect Wall	Set a safe distance between wall and PICO. If there are too closer with each other, PICO would execute corresponding movements.
	Detect Corner	Detect the number of corners of the room.
	Startup	Identity the initial angle of PICO in the start position. And then, compute an angle -- θ.
	Scan for Exit	Rotate PICO to detect all the distances between wall and robot in order to find the exact position of the corridor.
	Move to Max	If PICO do not detect enough walls in the room, it will move to the direction of the maximal distance and detect walls again.
	Face Exit	Let PICO face to the exit corridor straightly but not perfectly. PICO would not rotate itself in a defined error range.
	Drive to Exit	PICO moves to the exit.
	Enter Exit Corridor	Enter the exit corridor with a safe range between the walls of the corridor and PICO itself.
	Follow Corridor	Follow the walls of the corridor with a safe range until PICO crosses the finish line.
Low-level	Initialize	Initialize actuators
	Read Data of Sensors	Read the odometer and laser data
	Drive Forward	Move straightly
	Drive Backward	Move back
	Drive Left	Move left
	Drive Right	Move right
	Turn Left	Turn 90°left
	Turn Right	Turn 90°right
	Turn Around	Rotate
	Stop Movement	Stop current movement.

Components

PICO is consisted of many components which are:

• Sensors:

1. Proximity measurement with Laser Range Finder (LRF)
2. Motion measurement with Wheel encoders (Odometer)
3. Control Effort Sensor

• Actuators:

1. Holonomic Base - Omni wheels that facilitate 2D translation and rotation

• Computer:

1. Intel i7 Processor
2. OS: Ubuntu 16.04

Interfaces

Escape Room Challenge Execution

• Introductions about functions of code. Explain each mode more or less in order to let readers know what happened in our PICO. Just like what Winston did in Tuesday evening. -- YI

Startup

This mode involves computing the required angle for PICO to complete a full 360 degree view if needed. Once the angle has been determined the state switches to SCAN_FOR_EXIT.

Scan for exit

This mode searches for an exit in its available field of view which is around 230 degrees. If it does not manage to find an exit in this field of view, it uses the angle computed in the STARTUP to complete to rotate until it manages to find the exit. If it happens to be the case that it still did not manage to find any exit it switches to a state MOVE_TO_MAX. This scenario is generally encountered if PICO is initially put in a corner adjacent to the exit wall.

Move to max

Face exit

Exit undetectable

Orient to exit wall

Drive to exit

Enter exit corridor

Exit corridor follow

Stop

Hospital Competition

The main objective for PICO is to "deliver" the medicines from one cabinet to another which will be defined by the judges just before the challenge starts. The PICO will be operating under an environment amidst static and dynamic obstacles.

here

Software architecture

The main components of our architecture are the world model, the planning, the mapping, the measurement and actuation parts. The world model contains all the data of the environment and data like the position of the robot. The mapping module ensures the world model is updated and a map is provided. The planning ensures a path is planned from the current position of the robot towards a certain goal. The measurement part feeds data and some basic information into the word model and the actuation ensures the robot actually moves. These components will be worked out in more detail below.

World model

Measurment

Planning

To be able to plan a path the A* algorithm is used.

Mapping

Actuation