|0.1.0||february 2013||Jean-François Bianco
|First description||TBC||february 2013|
Purpose of the requirements document
Scope of the product
The goal of the “Trodometre” project is to provide a system to make accurate measurements during a journey. This system is able to calculate both indoor and outdoor measurements. In fact, it doesn’t use a localization system for its position in real time. Moreover, GPS is not available indoor and consumes a lot of energy which reduces the battery life of a system. Information collected by the program can be exported in XML format and used in OpenStreetMap. We can trace an itinerary everywhere precisely on the map. So, every circuit can be shared with everybody. The system is separated into two parts. The first part is the hardware. It is made up of sensors, based on ANT + technology (or BTLE), and moving means (scooter). Then, there is a second part with software which is based on Android an adaptability on every smartphone and mobile system. This system will be used by another project, Navigation of Visually Impaired People (http://autonomie.minalogic.net/index.en.html). This project is intended to facilitate mobility and independence of people with visual impairments. It works both indoors and outdoors, and facilitates access to public transport. Our system enables new itineraries to be created quickly and speeds up completion of those available.
Definitions, acronyms and abbreviations
Android: Android is a Linux-based operating system designed primarily for touchscreen mobile devices such as smartphones and tablet computers. Initially developed by Android, Inc.
ANT + : ANT is a proprietary wireless sensor network technology featuring a wireless communications protocol stack that enables semiconductor radios operating in the 2.4 GHz Industrial, Scientific and Medical allocation of the RF spectrum ("ISM band") to communicate by establishing standard rules for co-existence, data representation, signalling, authentication and error detection.
Bluetooth low energy : BLTE is a feature of Bluetooth 4.0 wireless radio technology, aimed at new, principally low-power and low-latency, applications for wireless devices within a short range (up to 50 metres / 160 feet -see table below). This facilitates a wide range of applications and smaller form factor devices in the healthcare, fitness, security, and home entertainment industries.
Android - https://developers.google.com/android/
ANT+ - http://www.thisisant.com/
Wahoo Fitness sensors - http://www.wahoofitness.com/Products/Wahoo-Fitness-Wahoo-Cycling-SpeedCadence-Sensor.asp
Bluetooh Low Energy - http://www.bluetooth.com/Pages/Low-Energy.aspx
Today, itineraries are planned with GPS (outdoor) or done by hand with suitable map software (indoor). However, the first solution requires lot of energy, and the second is theoretical and takes a lot of time. Our project improves data creation in both cases.
This system will be used by another project, Navigation of Visually Impaired People (http://autonomie.minalogic.net/index.en.html). This project is intended to facilitate mobility and independence of people with visual impairments. It works both indoors and outdoors, and facilitates access to public transport. Our system enables new itineraries to be created quickly and speeds up completion of those available.
The system must provide solutions for the requirement stated below:
- Provide a way to create an itinerary from a departure point.
- The itinerary should be accurate (-50 cm / 20 inch)
- Show the current orientation and modification
- Record the user’s information, such as points of interest. These records are audio and textual.
- Backup the itineraries.
- Export data in XML file compatible with OpenStreetMap for other uses, such as Navigation of Visually Impaired People.
- Display itinerary on map.
We have an actor class, the user. The user represents the person who wants to interact with the system. This interaction is divided into different tasks that the user can carry out.
Support of the project must be mobile, discrete and lightweight. We are able to travel long and short distances easily. In addition, it must provide for attachment points for the sensors, and cheerful smartphone software. Our system should be work even without connection to Internet. We can imagine it being used everywhere in the world. Thanks to this, it is possible to save measurements in a XML file in the smartphone.
Assumptions and dependencies
Our system has one dependency with XML format where are save the itinerary. It must respect this format for be read by other project.
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.
In Figure 1 all the basic features we will make can be seen. We have an actor class, the user. The user represents the person who wants to interact with the system. This interaction is divided into different tasks that the user can carry out:
- Define a departure point :
Description: This case corresponds to the definition of the starting point. Three different methods are possible: the first is to obtain the current position of the user, with a tracking system. The second method is to ask the user. The third method asks the user for latitude and longitude.
Inputs: GPS / USER (Map or manual input)
Outputs: Latitude/Longitude saved on the system.
Action: Select a departure point.
Non functional requirements:
GPS : That needs to be outdoors and have a tracking module on the smartphone. USER Map : An access map (online or local) USER Manual : The User know the coordinates