Mobile Robot Control 2020 Group 7: Difference between revisions

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[[Image:Req_Group7.png | frame | 20px | left | Requirements of the Escape Room Challenge ]]
[[Image:Req_Group7.png | frame | 20px | centre | Requirements of the Escape Room Challenge ]]
[[Image:Specs_Group7.png | frame | 20px | right | Specifications of the Escape Room Challenge ]]
[[Image:Specs_Group7.png | frame | 20px | centre | Specifications of the Escape Room Challenge ]]


The requirements and specifications for the challenge are shown in figure.  The primary requirement is safety that we need to fulfill by avoiding collision. All other requirements shall be treated equally.
The requirements and specifications for the challenge are shown in figure.  The primary requirement is safety that we need to fulfill by avoiding collision. All other requirements shall be treated equally.

Revision as of 19:10, 15 May 2020

Group Members

Name Student Number
1 Mick Decates 0957870
2 Steven Eisinger 1449273
3 Gerben Erens 0997906
4 Roohi Jain 1475061
5 Mengqi Wang 1449435
6 Goos Wetzer 0902160

ESCAPE ROOM CHALLENGE

Requirements & Specifications

Requirements of the Escape Room Challenge
Specifications of the Escape Room Challenge

The requirements and specifications for the challenge are shown in figure. The primary requirement is safety that we need to fulfill by avoiding collision. All other requirements shall be treated equally.

Functions

Functions for Escape Room Challenge

Once the robot is deployed in the room, it should sense around the room and try to find the exit corridor. If it cannot find the corridor, it should move around the room in an attempt to find it. Once the corridor is found it should position itself in front of the corridor and proceed through it until crossing the finish line.The functions that the robot needs to perform these tasks are described in Figure 2.1. These functions are divided into three main components: Sense, which allows the robot to perceive and quantify its world; Reasoning, where the robot makes a decision based on its perception; and Act, which determines what action the robot performs based on its reasoning information.

Hardware Components

Sensors - Laser Range Finder

The laser range finder measures the distance from the robot to the closest obstacle for a range of angles aroundthe direction the robot is facing. The sensor data is stored in a structure called LaserData, which is described intable 3.1. There are 1000 measurements in total.

Property Description
range_max The maximum range that can be measured is 10 meters
range_min The minimum range that can be measured is 0.01 meters
angle_max 2 radians from the direction straight ahead
angle_min -2 radians from the direction straight ahead
angle_increment Each angle is 0.004004 radians away from the next one
timestamp Timestamp of the measurement in UNIX

Sensors - Odometry

The odometry data measures the distance the robot has traveled in all 3 degrees of freedom in the horizontal plane.This data is obtained through encoders on the wheels of the holonomic base, which are stored in a structure calledOdometryData, described in table 3.2. Small errors could accumulate over time due to measurement errors andwheel slip. To combat this, the positional data of the robot will be updated using the difference between the currentand previous odometry measurement. This data is then corrected with the use of the world model and the dataobtained from the laser range finder.

Property Description
x distance travelled in horizonal direction since start of measurement
y distance travelled in vertical direction since start of measurement
a angle rotation since start of measurement
timestamp Timestamp of the measurement in UNIX

Actuators

The robot is built on a holonomic base, which means that it has three degrees of freedom in its horizontal plane: twotranslational, and one rotational. The robot is able to move in these ways using its omni-directional wheels, which are placed in a triangular formation on the base. Besides being able to provide a force in the driving direction,unlike normal wheels, the omni-directional wheels also do not constrain movement in the direction orthogonal tothe driving direction. Because of this, the robot is able to move with a given max velocity in all possible directions of the horizontal plane.

Software Infrastructure

Software components and interfaces of the Escape Room Challenge

The software will be divided into components, which are connected through certain interfaces. Major components are seen in Figure 5.1, and their interfaces are specified with the arrows. Perception is the component where the PICO uses sensor data from LaserData and OdometryData to get an idea of it’s current location. This data isinterfaced with the World Model, which stores map and localization data, including the exit location once found.The Planning component takes care of decision making and control planning, including path finding and obstacle avoidance. The actuation component will actuate the holonomic base in order to carry out the movement plan.

Important links

GitLab repo

Deliverables

Escape Room Challenge Design Document