Proj-2013-2014-BrasRobotique-1/SRS
The document provides a template of the Software Requirements Specification (SRS). It is inspired of the IEEE/ANSI 830-1998 Standard.
Version | Date | Authors | Description | Validator | Validation Date | |
---|---|---|---|---|---|---|
0.1.0 | Février 2014 | El Hadji Malick Fall
Adji Ndèye Ndaté Sambe |
TBC | TBC | TBC |
1. Introduction
1.1 Purpose of the requirements document
The main goals of this document which describes the robotic arm project are :
- allow people to discover the technology we will develop
- provide a working basis for future improvements
1.2 Scope of the product
The long-term goal of this project is to develop a control software manipulator arm for support of persons with disabilities. There are commercial products of arms which are unfortunately too expensive and does not have control system high levels. An example is the robotic arm Jaco.
1.3 Definitions, acronyms and abbreviations
Aruco
- It is a library for augmented reality applications based on OpenCV
Marker
- The library relies on the use of coded markers. Each marker has an unique code indicated by the black and white colors in it. The libary detect borders, and analyzes into the rectangular regions which of them are likely to be markers. Then, a decoding is performed and if the code is valid, it is considered that the rectangle is a marker.
OpenCV
- OpenCv ( Open Computer Vision) is a free graphic library mainly designed for real-time image processing.
SPADE
- SPADE (Smart Python multi-Agent Devepment Environment) is multiagent and organizations platform based on the XMPP technology and written in the Python programming language. The SPADE Agent Library is a module for the Python programming language for building SPADE agents.XMPP is the Extensible Messaging and Presence Protocol, used for instant messaging, presence, multi-party chat, voice and video calls, etc.
1.4 References
General :
This project is a school project, located in Polytech Grenoble, and supported by AIR The project page on air wiki is available through this link [1]
Technical :
2011-2012 Project page on the AIR wiki : - http://air.imag.fr/index.php/Proj-2011-2012-BrasRobotiqueHandicap
Librairies:
Aruco - http://www.uco.es/investiga/grupos/ava/node/26
OpenCV - http://opencv.org/
SPADE - https://github.com/javipalanca/spade
1.5 Overview of the remainder of the document
The remainder of this document will present the technical characteristics of the project such as requirements and constraints, and user characteristics. Section three outlines the detailed, specific and functional requirements, performance, system and other related requirements of the project. Supporting information about appendices is also provided in this same section.
2. General description
2.1 Product perspective
2.2 Product functions
2.3 User characteristics
This project is intended to disabled people. The robotic arm will allow them to grab distant objects. The arm can be remote-controlled. Therefore, users can be developers who can create new sequences of instructions given to the robot.
2.4 General constraints
Unlike existing technologies, our robotic arm must have the feature of being able to detect an object with a marker and get it back. It must also be able to interpret a series of instructions that will be given to him.
2.5 Assumptions and dependencies
3.Specific requirements, covering functional, non-functional and interface requirements
- document external interfaces,
- describe system functionality and performance
- specify logical database requirements,
- design constraints,
- emergent system properties and quality characteristics.
3.1 Requirement X.Y.Z (in Structured Natural Language)
Function:
Description:
Inputs:
Source:
Outputs:
Destination:
Action:
- Natural language sentences (with MUST, MAY, SHALL)
- Graphical Notations : UML Sequence w/o collaboration diagrams, Process maps, Task Analysis (HTA, CTT)
- Mathematical Notations
- Tabular notations for several (condition --> action) tuples
Non functional requirements:
Pre-condition:
Post-condition:
Side-effects:
4. Product evolution
- Remote-control
- Use several types of markers
- Send coordinates in real time on an interface
- Giving to the robot type of markers to detect as parameters
- Automatic recalibration of the position of the robot if the detected marker position is not optimal
5. Appendices
5.1 Specification
- The global project's page can be found here
- An other RICM4 group is working on this project. Their wiki page can be found there: