air - User contributions [en]

File:ProjetCannonBall-transparents.pdf

2015-04-08T07:47:14Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:ProjetCannonBall-transparents.pdf"

File:ProjetCannonBall-poster.pdf

2015-04-08T07:43:45Z

Ophelie.Pelloux-Prayer:

File:ProjetCannonBall-flyer.pdf

2015-04-08T07:43:04Z

Ophelie.Pelloux-Prayer:

File:ProjetCannonBall-transparents.pdf

2015-04-08T07:42:49Z

Ophelie.Pelloux-Prayer:

File:ProjetCannonBall-Rapport.pdf

2015-04-08T07:42:29Z

Ophelie.Pelloux-Prayer:

Projets 2014-2015

2015-04-08T07:42:09Z

Ophelie.Pelloux-Prayer: /* RICM4 */

<<[[Projets 2013-2014]] [[Projets|^Projets^]] [[Projets 2015-2016]]>>

=RICM=
==RICM3==

==RICM4==

* '''Evaluation à mi-parcours le lundi 2 mars''': Format: 10min (5min de présentation 3 slides au plus, 5min de discussion). Cette évaluation sera prise en compte dans la note finale.

'''Consignes générales:'''

* '''Vous devez être pro-actifs !!!''': Si des points sont pas ou mals spécifiés, vous le faîtes et vous justifiez vos choix. Pour les problèmes techniques éventuels vous pouvez: vous creusez la question, vous contactez l'auteur du code si il y a lieux, vous faites un rapport de bug ('''Attention:''' ca se prépare !), vous soumettez un patch, vous contactez l'enseignant ou la personne suivant le projet.

* '''Vous devez maintenir une fiche de suivi de projet''': elle doit être mise à jour chaque semaine, elle rassemble les élements essentiels du projet, elle
indique les évolutions du projet et présente sa feuille de route. '''Note:''' le nom de la fiche doit être composé du nom du projet et suffixé par ricm4_2014_2015.

* '''Vous devez utiliser un logiciel de gestion de version''' pour vos développements comme [http://en.wikipedia.org/wiki/Git_%28software%29 git ] et nous vous conseillons d'utiliser le site [https://github.com github] pour l'hébergement de votre dépôt public.

* Les document public (exemple sur github) doivent être rédigés en anglais (README, documentation, commentaires de code, nom de variables et de fonctions). Une bonnification sera accordée si le rapport et les transparents sont en anglais (la soutenance sera en francais).

{|class="wikitable alternance"
|+ Affectation des projets RICM4 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
|-

!scope="row"| 1
| [[Projet de monoski intelligent]]
| Blondet, Torck
| Didier Donsez, Pascal Jay, David Eon
| [[Proj-2014-2015-MonoskiIntelligent| '''Fiche''']] [[Proj-2014-2015-MonoskiIntelligent/SRS| '''SRS''']]
[[Proj-2014-2015-MonoskiIntelligent/UML| '''Diagrammes UML''']] [[Proj-2014-2015-MonoskiIntelligent/Scrum| '''Scrum''']] ([https://waffle.io/quentin74/monoski Waffle])
| [https://github.com/quentin74/application-monoski '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]] - [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 2
| [[Smart Classroom]]
| Darrigol, Barthelemy, Damotte, Leonard
| Didier Donsez, Vivien Quema, Jérome Maisonnasse
| [[Proj-2014-2015-SmartClassroom| '''Fiche''']] [[Proj-2014-2015-SmartClassroom/SRS| '''SRS''']] [[Proj-2014-2015-SmartClassroom/UML| '''Diagrammes UML''']] [[Proj-2014-2015-SmartClassroom/Scrum| '''Scrum''']]
| [https://github.com/AlanDamotte/SmartClassroom '''github''']
| [[Media:RapportSmartClassroom2015.pdf|Rapport]] - [[Media:Proj-2014-2015-SmartClassroom-transparents.pdf|Transparents]] - [[Media:Proj-2014-2015-SmartClassroom-flyer.pdf|Flyer]] - [[Media:ProjetXXX-poster.pdf|Poster]] - [http://youtu.be/gX1x9wgypV8 Screencast] - [[Media:SmartClassroom.tar.gz|Sources]]
|-

!scope="row"| 3
| [[RobAIR]] et [[STM32 Nucleo]]
| Hammerer, Michel, Klipffel, Viallet **
| Didier Donsez
| [[Projet-2014-2015-RobAIR| '''Fiche''']] [[Projet-2014-2015-RobAIR/SRS| '''SRS''']] [[Projet-2014-2015-RobAIR/UML| '''Diagrammes UML''']] [[Projet-2014-2015-RobAIR/Scrum| '''Scrum''']]
| [https://github.com/teiroy/RobAIR '''github''']
| [[Media:Projet-2014-2015-RobAIR/Rapport|rapport]] - [[Media:Projet-2014-2015-RobAIR-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]] [[Media:Projet-2014-2015-RobAIR-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 4
| [[IDS|Interactive Digitale Signage]]
| Adam, Zhang
| Didier Donsez
| [[Proj-2014-2015-Interactive_Digitale_Signage| '''Fiche''']] [[Projet-2014-2015-Interactive_Digitale_Signage/SRS| '''SRS''']] [[Projet-2014-2015-Interactive_Digitale_Signage/UML| '''Diagrammes UML''']] [[Projet-2014-2015-Interactive_Digitale_Signage/Scrum| '''Scrum''']]
| [https://github.com/zhangzhengmeng/ProjetIDS2015.git '''github''']
| [[Media:Proj-2014-2015-Interactive_Digitale_Signage/Rapport|rapport]] - [[Media:Proj-2014-2015-Interactive_Digitale_Signage-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-Interactive_Digitale_Signage-flyer.pdf|flyer]] [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 5
| [[Régie vidéo autonome et mobile multi-caméra]]
| Zominy, Bodard, Qian
| Didier Donsez, Thierry C.
| [[Proj-2014-2015-RegieVideoAutonomeEtMobileMulticamera| '''Fiche''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/SRS| '''SRS''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/Scrum| '''Scrum''']]
| [https://github.com/kurisuter/Regie-video-autonome-'''github''']
| [[Media:Rapport_regie.pdf|rapport]] - [[Media:Projet-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera-transparents.pdf|transparents]] - [[Media:Projet-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera-flyer.pdf|flyer]] - [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 6
| OpenHAB Extended GUI ([[IFTTT]] et à la [[Node-RED]] ou [[Flowhub]] pour [[OpenHAB]], Découverte [[UPnP]] des équipements)
| Toussaint, Saussac
| Didier Donsez
| [[Proj-2014-2015-OpenHAB-ExtendedGUI| '''Fiche''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/SRS| '''SRS''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/UML| '''Diagrammes UML''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/Scrum| '''Scrum''']]
| [https://github.com/sebjoe/ProjetExtensionOpenHabRicm4 '''github''']
| [[Media:RapportFranc.pdf|Rapport Francais]]- [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI/Rapport2|Rapport Anglais]] - [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI-transparentsanglais.pdf|transparents anglais]] - [[Media:PProj-2014-2015-OpenHAB-ExtendedGUI-flyer.pdf|flyer]]
|-

!scope="row"| 7
| [[CannonBall de voitures autonomes|CannonBall de voitures autonomes, Edition 2015]]
| Le-Jean, Mammar, Pelloux-Prayer, Rodrigues
| Didier Donsez & Vivien Quema
| [[Project-2014-2015-CannonBall| '''Fiche''']][[Project 2014-2015-CannonBall/SRS| '''SRS''']][[Project 2014-2015-CannonBall/UML| '''UML''']][[Project 2014-2015-CannonBall/Scrum| '''Scrum''']][[Project 2014-2015-CannonBall/DesignPatterns| '''DesignPatterns''']]
| [https://github.com/malek0512/2014_2015_ricm4_cannon_ball '''github''']
| [[Media:ProjetCannonBall-Rapport.pdf|rapport]] - [[Media:ProjetCannonBall-transparents.pdf|transparents]] - [[Media:ProjetCannonBall-flyer.pdf|flyer]]- [[Media:ProjetCannonBall-poster.pdf|poster]] - [http://youtu.be/bkoyAkvbdVI Video]
|-

!scope="row"| 8
| [[Navigation et Montre connectée]]
| Hamdani, Mesnier, Yao
| Jacques Lemordant
| [[Proj-2014-2015-Montreconnectée| '''Fiche''']] [[Proj-2014-2015-Montreconnectée/SRS| '''SRS''']] [[Proj-2014-2015-Montreconnectée/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Montreconnectée/Scrum| '''Scrum''']][[Proj-2014-2015-Montreconnectée/DesignPattern| '''DesignPattern''']]
| [https://github.com/vince0508/OrientateWatch.git '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 9
| [[Python sur ESP8266]]
| Libralesso, Soldano
| Olivier Richard
| [[Project-2014-2015-ESP8266| '''Fiche''']] - [[Proj-2014-2015-ESP8266/SRS| '''SRS''']] - [[Proj-2014-2015-ESP8266/UML| '''UML diagrams''']] - [[Proj-2014-2015-ESP8266/Scrum| '''Scrum''']]
| [https://github.com/librallu/RICM4Projet/ '''github''']
| [https://github.com/librallu/RICM4Projet/blob/master/reports/Final_report/final.rst '''rapport'''] - [https://github.com/librallu/RICM4Projet/tree/master/reports/presentation/ '''transparents'''] - [[Media:Projet9-ESP8266-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast] - [http://librallu.github.io/RICM4Projet/ '''website''']
|-

!scope="row"| 10
| [[Serious Game: Handicap, parole et geste v2]]
| Aissanou, Codazzi, Guo
| Olivier Richard
| [[Proj-2014-2015-SeriousGamev2| '''Fiche''']][[Proj-2014-2015-SeriousGamev2/SRS| '''SRS''']][[Proj-2014-2015-SeriousGamev2/Scrum| '''Scrum''']] [[Projet-2014-2015-SeriousGamev2/Diagrammes| '''Diagrammes UML''']]
| [https://github.com/wizardkeven/SeriousGameV2 '''github''']
| [http://air.imag.fr/images/a/ad/Rapport2.pdf '''rapport'''] - [http://air.imag.fr/images/e/e0/Projetseriousgame-transparents.pdf '''transparents'''] - [http://air.imag.fr/images/2/2a/Projetseriousgame-flyer.pdf '''flyer''']- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 11
| [[Plateforme d'expérimentation mini-datacentre]] Système
| Fotsing, Morison
| Olivier Richard
| [[Proj-2014-2015-Mini_DataCenter_Systeme| '''Fiche''']][[Proj-2014-2015-Mini_datacenter_Systeme_SRS| '''SRS''']] [[Proj-2014-2015-Mini_datacenter_Systeme_scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:ProjetMini_DataCenter_Systeme/Rapport|rapport]] - [[Media:ProjetMini_DataCenter_Systeme-transparents.pdf|transparents]] - [[Media:ProjetMini_DataCenter_Systeme-flyer.pdf|flyer]]- [[Media:ProjetMini_DataCenter_Systeme-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 12
| [[Plateforme d'expérimentation mini-datacentre]] Portail
| Rossi, [[User:Robin.Eudes|Eudes]]
| Olivier Richard
| [[Proj-2014-2015-Mini_datacenter_portail| '''Fiche''']] [[Proj-2014-2015-Mini_datacenter_portail_SRS| '''SRS''']] [[Proj-2014-2015-Mini_datacenter_portail_scrum| '''Scrum''']] [[Proj-2014-2015-Mini_datacenter_portail_uml| '''UML''']]
| [https://github.com/EudesRobin/webui-oardocker '''github''']
| [[Media:Projet_webui-oardocker-rapport.pdf|rapport]] - [[Media:Projet_webui-oardocker-transparents.pdf|transparents]] - [[Media:Projet_webui-oardocker-flyer.pdf|flyer]]- [[Media:Projet-webui-oardocker-poster.pdf|poster]] - [https://www.youtube.com/watch?v=OXnNJ0PsN_g Screencast]
|-

|}

* [[Projet de monoski intelligent]] (RICM4 et 3I4 et Matériaux) pour le [http://www.defi-foly-laclusaz.com/ défi Foly 2015] : Didier Donsez, Pascal Jay, David Eon (2 élèves)
* [[Smart Classroom]] (avec ENSIMAG) Didier Donsez, Vivien Quema, Jérome Maisonnasse (4 élèves)
* Robot [[RobAIR]] à base de [[STM32 Nucleo]] (+ cartes additionnelles MEMS BLE4) et de téléphones [[Firefox OS]]. Didier Donsez (4 élèves)
* [[StartAIR]] (Fabrice Dubost) (2 élèves)
* [[IDS|Interactive Digitale Signage]] avec [[Reveal.js]], [[Kinect]], [[WebRTC]], [[Node.js]], [[Open Data]], [[NFC]], [[Miracast]] [http://blueimp.github.io/Bootstrap-Image-Gallery/ Bootstrap Gallery]... (Didier Donsez) (2 élèves)
* [[Régie vidéo autonome et mobile multi-caméra]] (Didier Donsez, Thierry C.) (2 élèves)
* Interface HTML5 à la [[IFTTT]] et à la [[Node-RED]] ou [[Flowhub]] pour [[OpenHAB]] (2 élèves)
* [[Intégration d'Espruino à RIOT OS]] sur [[STM32 Nucleo]]: Application à la robotique [[RobAIR]] (Didier Donsez) (2 élèves)
* [[Inventaire Forestier]] sous Android (3I4 ou 5, RICM4) Emmanuel Promayon (2 élèves)
* [[Navigation indoor basé iBeacons]], Jacques Lemordant (2 élèves)
* [[Navigation et Montre connectée]], Jacques Lemordant (2 élèves)
* [[Projets Sitra avec la région Rhône-Alpes]], Jacques Lemordant (2 élèves)
* [[CannonBall de voitures autonomes|CannonBall de voitures autonomes, Edition 2015]] Didier Donsez & Vivien Quema (piste [[Star War Drone Race]]) (2 élèves)
* [[Python sur ESP8266]] Olivier Richard (2 élèves)
* [[Serious Game: Handicap, parole et geste v2]], edition 2015, Olivier Richard (3 élèves)
* [[Plateforme d'expérimentation mini-datacentre]] édition 2015, Olivier Richard (2 élèves)

==RICM5==
===Projet Semestre S10===
Démarrage : Lundi 26/01 à 8H00-12H00, P257 (Rendez-vous devant la salle AIR)

Soutenance : Mercredi 25/03 à 9H00-12H00, Salle à confirmer

{|class="wikitable alternance"
|+ Affectation des projets RICM5 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
|-

!scope="row"| 1
| [[iRock]] :Plateforme Ubilitics pour la surveillance des risques naturelles (déploiement grande échelle de capteurs [[LoRa]] sur le terrain pour l'observation de glissement de terrain) .
| Peyre, Guo, Ginoux, Boey
| Didier Donsez & Denis Jongmans & Georges-Pierre Bonneau
| [[Proj-2014-2015-iRock| '''Fiche''']] [[Proj-2014-2015-iRock/SRS| '''SRS''']] [[Proj-2014-2015-iRock/UML| '''Diagrammes UML''']] [[Proj-2014-2015-iRock/Scrum| '''Scrum''']]
| [https://github.com/fpeyre/IRock_2015'''github''']
| [[Media:Proj-2014-2015-iRock-Rapport|rapport]] - [[Media:Proj-2014-2015-iRock-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-iRock-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-iRock-poster.pdf|poster]] - [[Proj-2014-2015-iRock-media.pdf|Video ou Screencast]]
|-

!scope="row"| 2
| Plateforme Ubilitics pour [[SmartCampus 2015]] : (déploiement grande échelle de capteurs [[LoRa]]) (voir [[OpenBAS]]).
| Sambe, Husson, Labat, Fréby, Barbier
| Didier Donsez & Vivien Quema
| [[Proj-2014-2015-SmartCampus2015| '''Fiche''']] [[Proj-2014-2015-SmartCampus2015/SRS| '''SRS''']] [[Proj-2014-2015-SmartCampus2015#G.C3.A9nie_Logiciel| '''Diagrammes UML''']] [[Proj-2014-2015-SmartCampus2015#Organisation_du_projet| '''Scrum''']]
| [https://github.com/nexucis/SmartCampus '''github''']
| [[Media:Proj-2014-2015-SmartCampus2015-Rapport|rapport]] - [[Media:Proj-2014-2015-SmartCampus2015-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartCampus2015-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-SmartCampus2015-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 3
| [[Extensions XBMC Sujet 2015]]
| Valentin, Bobo, Legros, Gabin Teulon (DUT1 R&T)
| Nicolas Palix
| [[Extensions_XBMC_2015| '''Fiche''']] [[Proj-2014-2015-Ext_XBMC/SRS| '''SRS''']] [[Proj-2014-2015-Ext_XBMC/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Ext_XBMC/Scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:Proj-2014-2015-xbmc-rapport.pdf|rapport]] - [[Media:Proj-2014-2015-Ext_XBMC2015-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-xbmc-flyer.png|flyer]] - [[Media:Proj-2014-2015-xbmc-poster.png|poster]]
|-

!scope="row"| 4
| [[Smart Classroom]] : tables tactiles en mode [[Tiled Display]], Murs interactifs, Robots de Téléprésence, ...
| Benyounes, Fall, Tiamiou, Perruche, Quentin Fombaron (DUT1 R&T), Lucas Reygrobellet (DUT1 R&T)
| Didier Donsez & Vivien Quema & Jérome Maisonnasse
| [[Proj-2014-2015-SmartClassRoom| '''Fiche''']] [[Proj-2014-2015-SmartClassRoom/SRS| '''SRS''']] [[Proj-2014-2015-SmartClassRoom/UML| '''Diagrammes UML''']] [[Proj-2014-2015-SmartClassRoom/Scrum| '''Scrum''']]
| [https://github.com/falle38/SmartClassroom-TiledDisplayPart '''github''']
| [[Media:Proj-2014-2015-SmartClassRoom-Rapport|rapport]] - [[Media:Proj-2014-2015-SmartClassRoom-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassRoom-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-SmartClassRoom-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 5
| Défi H 2015 : Rééducation de la main
| Mariage, Perea, Clerc-Ghérardi, Arredondo (TIS5)
| Didier Donsez & Alessandro Semere & Nicolas Vuillerme + Pierre-Yves Thomas (tuteur Sogeti)
| '''Sur DropBox''' : [[HandTrainer| '''Fiche''']] [[HandTrainer-SRS| '''SRS''']] [[Proj-2014-2015-ReducMain/UML| '''Diagrammes UML''']] [[Proj-2014-2015-ReducMain/Scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:Proj-2014-2015-ReducMain-Rapport|rapport]] - [[Media:Proj-2014-2015-ReducMain-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassRoom-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-ReducMain-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

|}

Rappel: les séances de MPI (Management de Projet Innovant) auront lieu les jours suivants (salles sur ADE) :
* Mardi 27/01 après-midi (Stéphanie Diligent)
* Lundi 2/02 matin (Emmanuelle Tréhoust)
* Lundi 9/02 matin (Emmanuelle Tréhoust)
* Lundi 23/02 matin (Stéphanie Diligent)
* Mardi 17/03 matin (Stéphanie Diligent+Emmanuelle Tréhoust)

Remarque: il y à 3 étudiants PEIP D de l'IUT 1 R&T qui participeront aux projets.

===Projet Biométrie===
Démarrage : Lundi 26/01 à 8H00-9H45

Voir Laurent Besacier & François Portet

=3I=
==3I3==

==3I4==

==3I5==
* Carte d'extension Semtech [[LoRa]] pour [[Arduino]] et [[STM32 Nucleo]] (Didier Donsez)

===Projet Semestre 10===
Démarrage : 26/01/2015
Soutenance: 26/03/2015

{|class="wikitable alternance"
|+ Affectation des projets 3I5 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
!scope="col"| Docs.
|-

!scope="row"| 1
| [[Projet Cannonball - Intégration d'une caméra auto-directive| '''Projet Cannonball''']] : Intégration d'une caméra auto-directive.
| Alwan, Laurent, Cottin Bizonne
| Alina Voda & Ahmad Farhat
| [[Fiche de suivi Projet Cannonball 2015| '''Fiche de suivi''']]
| [https://github.com/Jerome-Laurent/CannonBall-Nucleo-STM32F401 '''github''']
| [[Media:Rapport_Cannonball2015.pdf‎|Rapport]] - [[Media:Poster_Project_Cannonball.pdf|Poster]] - [https://www.youtube.com/watch?v=44PW_EM8MZ0| Vidéo ]

|}

=M2PGI=
* Extensions à [[SmartCampus]]

=Bachelor Summer Program=

=Année A définir=
* [[GeoDiff]] Production, visualisation, fusion de variations (diff) sur de l'information géocodée : Nicolas Palix
* [[Smart campus augmenté et contributif]]
* [[Intégration OpenHAB / OpenTele]]
* [[Client MQTT pour OBD]] sur Android
* [[Sommeilomètre]] (Michael Perin, Didier Donsez)
* [[Open DynDNS]]
* [[IllumiRoom]]
* [[Emergency mobile app]] Nicolas Palix pour TIS, PRI et RICM
* [[OwnPOI]] ownCloud plugin and osmand plugin to share POI and favorite positions. Nicolas Palix.
* [[OwnList]] ownCloud plugin and Android app to share a TODO list. Nicolas Palix.
* [[floatingimage UPnP feed]] Nicolas Palix
* [[XBMC Reflexive Remote]] Dynamic remote control for XBMC. Nicolas Palix.
* [http://intgat.tigress.co.uk/rmy/uml/index.html Zerofree] Portage de zerofree pour d'autres systèmes de fichiers que ext2/3/4 (notamment Unix FS). Voir également la page [http://packages.qa.debian.org/z/zerofree.html QA de Debian]. Nicolas Palix.
* [[Bracelet électronique de monitoriing de l'alcoolémie]]
* [[Oxymètre DIY]]
* [[PinSound]]
* [[Extension du support STM32Fx-Discovery dans libopencm3]] : Olivier Richard
* [[Arduino et libopencm3]] : Olivier Richard
* [[Data Acquisition System et Stm32f4-Discovery]] : Olivier Richard
* [[Distributed Data Storage System]] : Olivier Richard
* [[Dashboard based on w2ui]]
* [[Environnement logiciel pour FabLab]] : Olivier Richard
* [[Environnement logiciel pour le Live Programming]] : Olivier Richard
* [[VirtualPinball]]
* Tondeuse dessinatrice
* [[ImmersiveDog]] Nicolas Glade, Didier Donsez
* Projet avec [[OpenROV]] ???? : Didier Donsez
* [[Sphero]] malin (Michael Périn) (2 etudiants)
* [[Drone paramoteur]] ???
* [[IRock : Surveillance Géotechnique LoRa|iRock]]: Plateforme Ubilitics pour la surveillance des risques naturelles (déploiement grande échelle de capteurs [[LoRa]] sur le terrain pour l'observation de glissement de terrain) en commun avec Geotech (à confirmer) : Didier Donsez & Denis Jongmans
* [[Optimisation de l'énergie pour cyclotouriste électrique]]
* [[SmartSelfService|Smart Self-Service 2015]] Didier Donsez & Vivien Quema
* [[Station Météo LoRa]] : contribution au projet [[LoRA-Fabian]] (Didier Donsez)

=Réserve (boite à idées)=

# [[Tag et Paint Ball en réalité augmentée]] (Michaël Périn)
# [[Passe moi ton fichier]] (Michaël Périn)
# [[Extensions à Fab Server]] (Jean-Michel Molenaar) sous reserve (CM ou SR)
# [[Table multijeux de café 2.0]]
# [[ GPIO_Qemu_RasPI| Emulation des GPIO dans QEMU pour le carte Raspberry Pi]] (Olivier Richard)
# [[ Qemu et STM32F0-Discovery ]] (Olivier Richard)
# [[Serrure à clé MIDI multifactorielle]] (Didier Donsez)
# [[Table interactive musicale]] (Didier Donsez)
# [[iMailbox]] (Didier Donsez)
# [[AmILight]] (eclairage d'ambience intelligent) (Didier Donsez)
# [[PDAmeetPDA]] (synchronisation d'agenda) (Michaël Périn)
# [[1 000 000 VMs]] (expérimentation d'application distribuée à très grande échelle) (Olivier Richard) (2-3 RICM4)
# [[Multiple Kinect]] (utilisation simultanée de plusieurs Kinect) (Olivier Richard) (RICM ou 3I)
# [[Kinect musicale]] (Didier Donsez) (RICM)
# [[Ktechlab Simavr Arduino | Ktechlab et integration de Simavr(Arduino)]] (Olivier Richard) (2-3 RICM4-SR)
# Ocaml on AVR (Arduino)
# Ocaml on Cortex-M3
# [[Arduino on STM32 Discovery]]
# [[Reverse Geocache Puzzle Box]]
# [[OSGi ME]] (Didier Donsez)
# [[Affichage Etudiant à Polytech]]
# Synthèse 3D + motion capture Kinect
# Logiciel d'[[apprentissage du calcul]] sur tablette Android (reconnaissance de chiffres manuscrits)
# Plancher de verre (saint gobain) à la [http://www.wat.tv/video/mickael-jackson-billie-jean-oewj_2ey2h_.html Mickael Jackson dans Billie Jean] ! woo
# [[Ktechlab Simavr Arduino | Ktechlab et integration de Simavr(Arduino)]] (Olivier Richard) (2-3 RICM4-SR)
# [[CNC]]
# [[Idées en Vrac]]
# Scheme Everywhere (Olivier Richard) (2-3 RICM4-SR)
# [[Projet Station Météo]]
# Ocaml on AVR (Arduino)
# [[Table interactive musicale]] (Didier Donsez)
# [[AmILight]] (eclairage d'amnbience intelligent) (Didier Donsez)
# [[Cube pointeur]] d'activité ingénieur
# [http://www.instructables.com/id/Puppeteer-Motion-Capture-Costume/ Puppeteer Motion-Capture Costume]
# [[Musical Staircase]] @ Polytech (Didier Donsez, 1 RICM4 + 1 3I4)
# [[Total Recall]] (Didier Donsez)
# [[SoundMachine]]
# [[IGN-OSM|Importation de données IGN publiques dans OSM]]
# [[Speed-limit-OSM|Analyse de traces GPX pour déterminer les limitations de vitesse]]
# [[Multi perceptual cameras]] (Didier Donsez)
# [[Photomaton 3D]] (Didier Donsez)
# [[ArduCopter]]
# [[Parking Intelligent]]

Projets 2014-2015

2015-04-08T07:39:01Z

Ophelie.Pelloux-Prayer: /* RICM4 */

<<[[Projets 2013-2014]] [[Projets|^Projets^]] [[Projets 2015-2016]]>>

=RICM=
==RICM3==

==RICM4==

* '''Evaluation à mi-parcours le lundi 2 mars''': Format: 10min (5min de présentation 3 slides au plus, 5min de discussion). Cette évaluation sera prise en compte dans la note finale.

'''Consignes générales:'''

* '''Vous devez être pro-actifs !!!''': Si des points sont pas ou mals spécifiés, vous le faîtes et vous justifiez vos choix. Pour les problèmes techniques éventuels vous pouvez: vous creusez la question, vous contactez l'auteur du code si il y a lieux, vous faites un rapport de bug ('''Attention:''' ca se prépare !), vous soumettez un patch, vous contactez l'enseignant ou la personne suivant le projet.

* '''Vous devez maintenir une fiche de suivi de projet''': elle doit être mise à jour chaque semaine, elle rassemble les élements essentiels du projet, elle
indique les évolutions du projet et présente sa feuille de route. '''Note:''' le nom de la fiche doit être composé du nom du projet et suffixé par ricm4_2014_2015.

* '''Vous devez utiliser un logiciel de gestion de version''' pour vos développements comme [http://en.wikipedia.org/wiki/Git_%28software%29 git ] et nous vous conseillons d'utiliser le site [https://github.com github] pour l'hébergement de votre dépôt public.

* Les document public (exemple sur github) doivent être rédigés en anglais (README, documentation, commentaires de code, nom de variables et de fonctions). Une bonnification sera accordée si le rapport et les transparents sont en anglais (la soutenance sera en francais).

{|class="wikitable alternance"
|+ Affectation des projets RICM4 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
|-

!scope="row"| 1
| [[Projet de monoski intelligent]]
| Blondet, Torck
| Didier Donsez, Pascal Jay, David Eon
| [[Proj-2014-2015-MonoskiIntelligent| '''Fiche''']] [[Proj-2014-2015-MonoskiIntelligent/SRS| '''SRS''']]
[[Proj-2014-2015-MonoskiIntelligent/UML| '''Diagrammes UML''']] [[Proj-2014-2015-MonoskiIntelligent/Scrum| '''Scrum''']] ([https://waffle.io/quentin74/monoski Waffle])
| [https://github.com/quentin74/application-monoski '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]] - [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 2
| [[Smart Classroom]]
| Darrigol, Barthelemy, Damotte, Leonard
| Didier Donsez, Vivien Quema, Jérome Maisonnasse
| [[Proj-2014-2015-SmartClassroom| '''Fiche''']] [[Proj-2014-2015-SmartClassroom/SRS| '''SRS''']] [[Proj-2014-2015-SmartClassroom/UML| '''Diagrammes UML''']] [[Proj-2014-2015-SmartClassroom/Scrum| '''Scrum''']]
| [https://github.com/AlanDamotte/SmartClassroom '''github''']
| [[Media:RapportSmartClassroom2015.pdf|Rapport]] - [[Media:Proj-2014-2015-SmartClassroom-transparents.pdf|Transparents]] - [[Media:Proj-2014-2015-SmartClassroom-flyer.pdf|Flyer]] - [[Media:ProjetXXX-poster.pdf|Poster]] - [http://youtu.be/gX1x9wgypV8 Screencast] - [[Media:SmartClassroom.tar.gz|Sources]]
|-

!scope="row"| 3
| [[RobAIR]] et [[STM32 Nucleo]]
| Hammerer, Michel, Klipffel, Viallet **
| Didier Donsez
| [[Projet-2014-2015-RobAIR| '''Fiche''']] [[Projet-2014-2015-RobAIR/SRS| '''SRS''']] [[Projet-2014-2015-RobAIR/UML| '''Diagrammes UML''']] [[Projet-2014-2015-RobAIR/Scrum| '''Scrum''']]
| [https://github.com/teiroy/RobAIR '''github''']
| [[Media:Projet-2014-2015-RobAIR/Rapport|rapport]] - [[Media:Projet-2014-2015-RobAIR-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]] [[Media:Projet-2014-2015-RobAIR-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 4
| [[IDS|Interactive Digitale Signage]]
| Adam, Zhang
| Didier Donsez
| [[Proj-2014-2015-Interactive_Digitale_Signage| '''Fiche''']] [[Projet-2014-2015-Interactive_Digitale_Signage/SRS| '''SRS''']] [[Projet-2014-2015-Interactive_Digitale_Signage/UML| '''Diagrammes UML''']] [[Projet-2014-2015-Interactive_Digitale_Signage/Scrum| '''Scrum''']]
| [https://github.com/zhangzhengmeng/ProjetIDS2015.git '''github''']
| [[Media:Proj-2014-2015-Interactive_Digitale_Signage/Rapport|rapport]] - [[Media:Proj-2014-2015-Interactive_Digitale_Signage-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-Interactive_Digitale_Signage-flyer.pdf|flyer]] [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 5
| [[Régie vidéo autonome et mobile multi-caméra]]
| Zominy, Bodard, Qian
| Didier Donsez, Thierry C.
| [[Proj-2014-2015-RegieVideoAutonomeEtMobileMulticamera| '''Fiche''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/SRS| '''SRS''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/Scrum| '''Scrum''']]
| [https://github.com/kurisuter/Regie-video-autonome-'''github''']
| [[Media:Rapport_regie.pdf|rapport]] - [[Media:Projet-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera-transparents.pdf|transparents]] - [[Media:Projet-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera-flyer.pdf|flyer]] - [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 6
| OpenHAB Extended GUI ([[IFTTT]] et à la [[Node-RED]] ou [[Flowhub]] pour [[OpenHAB]], Découverte [[UPnP]] des équipements)
| Toussaint, Saussac
| Didier Donsez
| [[Proj-2014-2015-OpenHAB-ExtendedGUI| '''Fiche''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/SRS| '''SRS''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/UML| '''Diagrammes UML''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/Scrum| '''Scrum''']]
| [https://github.com/sebjoe/ProjetExtensionOpenHabRicm4 '''github''']
| [[Media:RapportFranc.pdf|Rapport Francais]]- [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI/Rapport2|Rapport Anglais]] - [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI-transparentsanglais.pdf|transparents anglais]] - [[Media:PProj-2014-2015-OpenHAB-ExtendedGUI-flyer.pdf|flyer]]
|-

!scope="row"| 7
| [[CannonBall de voitures autonomes|CannonBall de voitures autonomes, Edition 2015]]
| Le-Jean, Mammar, Pelloux-Prayer, Rodrigues
| Didier Donsez & Vivien Quema
| [[Project-2014-2015-CannonBall| '''Fiche''']][[Project 2014-2015-CannonBall/SRS| '''SRS''']][[Project 2014-2015-CannonBall/UML| '''UML''']][[Project 2014-2015-CannonBall/Scrum| '''Scrum''']][[Project 2014-2015-CannonBall/DesignPatterns| '''DesignPatterns''']]
| [https://github.com/malek0512/2014_2015_ricm4_cannon_ball '''github''']
| [[Media:ProjetCannonBall.pdf|rapport]] - [[Media:ProjetCannonBall-transparents.pdf|transparents]] - [[Media:ProjetCannon-flyer.pdf|flyer]]- [[Media:ProjetCannonBall-poster.pdf|poster]] - [http://youtu.be/bkoyAkvbdVI Video]
|-

!scope="row"| 8
| [[Navigation et Montre connectée]]
| Hamdani, Mesnier, Yao
| Jacques Lemordant
| [[Proj-2014-2015-Montreconnectée| '''Fiche''']] [[Proj-2014-2015-Montreconnectée/SRS| '''SRS''']] [[Proj-2014-2015-Montreconnectée/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Montreconnectée/Scrum| '''Scrum''']][[Proj-2014-2015-Montreconnectée/DesignPattern| '''DesignPattern''']]
| [https://github.com/vince0508/OrientateWatch.git '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 9
| [[Python sur ESP8266]]
| Libralesso, Soldano
| Olivier Richard
| [[Project-2014-2015-ESP8266| '''Fiche''']] - [[Proj-2014-2015-ESP8266/SRS| '''SRS''']] - [[Proj-2014-2015-ESP8266/UML| '''UML diagrams''']] - [[Proj-2014-2015-ESP8266/Scrum| '''Scrum''']]
| [https://github.com/librallu/RICM4Projet/ '''github''']
| [https://github.com/librallu/RICM4Projet/blob/master/reports/Final_report/final.rst '''rapport'''] - [https://github.com/librallu/RICM4Projet/tree/master/reports/presentation/ '''transparents'''] - [[Media:Projet9-ESP8266-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast] - [http://librallu.github.io/RICM4Projet/ '''website''']
|-

!scope="row"| 10
| [[Serious Game: Handicap, parole et geste v2]]
| Aissanou, Codazzi, Guo
| Olivier Richard
| [[Proj-2014-2015-SeriousGamev2| '''Fiche''']][[Proj-2014-2015-SeriousGamev2/SRS| '''SRS''']][[Proj-2014-2015-SeriousGamev2/Scrum| '''Scrum''']] [[Projet-2014-2015-SeriousGamev2/Diagrammes| '''Diagrammes UML''']]
| [https://github.com/wizardkeven/SeriousGameV2 '''github''']
| [http://air.imag.fr/images/a/ad/Rapport2.pdf '''rapport'''] - [http://air.imag.fr/images/e/e0/Projetseriousgame-transparents.pdf '''transparents'''] - [http://air.imag.fr/images/2/2a/Projetseriousgame-flyer.pdf '''flyer''']- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 11
| [[Plateforme d'expérimentation mini-datacentre]] Système
| Fotsing, Morison
| Olivier Richard
| [[Proj-2014-2015-Mini_DataCenter_Systeme| '''Fiche''']][[Proj-2014-2015-Mini_datacenter_Systeme_SRS| '''SRS''']] [[Proj-2014-2015-Mini_datacenter_Systeme_scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:ProjetMini_DataCenter_Systeme/Rapport|rapport]] - [[Media:ProjetMini_DataCenter_Systeme-transparents.pdf|transparents]] - [[Media:ProjetMini_DataCenter_Systeme-flyer.pdf|flyer]]- [[Media:ProjetMini_DataCenter_Systeme-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 12
| [[Plateforme d'expérimentation mini-datacentre]] Portail
| Rossi, [[User:Robin.Eudes|Eudes]]
| Olivier Richard
| [[Proj-2014-2015-Mini_datacenter_portail| '''Fiche''']] [[Proj-2014-2015-Mini_datacenter_portail_SRS| '''SRS''']] [[Proj-2014-2015-Mini_datacenter_portail_scrum| '''Scrum''']] [[Proj-2014-2015-Mini_datacenter_portail_uml| '''UML''']]
| [https://github.com/EudesRobin/webui-oardocker '''github''']
| [[Media:Projet_webui-oardocker-rapport.pdf|rapport]] - [[Media:Projet_webui-oardocker-transparents.pdf|transparents]] - [[Media:Projet_webui-oardocker-flyer.pdf|flyer]]- [[Media:Projet-webui-oardocker-poster.pdf|poster]] - [https://www.youtube.com/watch?v=OXnNJ0PsN_g Screencast]
|-

|}

* [[Projet de monoski intelligent]] (RICM4 et 3I4 et Matériaux) pour le [http://www.defi-foly-laclusaz.com/ défi Foly 2015] : Didier Donsez, Pascal Jay, David Eon (2 élèves)
* [[Smart Classroom]] (avec ENSIMAG) Didier Donsez, Vivien Quema, Jérome Maisonnasse (4 élèves)
* Robot [[RobAIR]] à base de [[STM32 Nucleo]] (+ cartes additionnelles MEMS BLE4) et de téléphones [[Firefox OS]]. Didier Donsez (4 élèves)
* [[StartAIR]] (Fabrice Dubost) (2 élèves)
* [[IDS|Interactive Digitale Signage]] avec [[Reveal.js]], [[Kinect]], [[WebRTC]], [[Node.js]], [[Open Data]], [[NFC]], [[Miracast]] [http://blueimp.github.io/Bootstrap-Image-Gallery/ Bootstrap Gallery]... (Didier Donsez) (2 élèves)
* [[Régie vidéo autonome et mobile multi-caméra]] (Didier Donsez, Thierry C.) (2 élèves)
* Interface HTML5 à la [[IFTTT]] et à la [[Node-RED]] ou [[Flowhub]] pour [[OpenHAB]] (2 élèves)
* [[Intégration d'Espruino à RIOT OS]] sur [[STM32 Nucleo]]: Application à la robotique [[RobAIR]] (Didier Donsez) (2 élèves)
* [[Inventaire Forestier]] sous Android (3I4 ou 5, RICM4) Emmanuel Promayon (2 élèves)
* [[Navigation indoor basé iBeacons]], Jacques Lemordant (2 élèves)
* [[Navigation et Montre connectée]], Jacques Lemordant (2 élèves)
* [[Projets Sitra avec la région Rhône-Alpes]], Jacques Lemordant (2 élèves)
* [[CannonBall de voitures autonomes|CannonBall de voitures autonomes, Edition 2015]] Didier Donsez & Vivien Quema (piste [[Star War Drone Race]]) (2 élèves)
* [[Python sur ESP8266]] Olivier Richard (2 élèves)
* [[Serious Game: Handicap, parole et geste v2]], edition 2015, Olivier Richard (3 élèves)
* [[Plateforme d'expérimentation mini-datacentre]] édition 2015, Olivier Richard (2 élèves)

==RICM5==
===Projet Semestre S10===
Démarrage : Lundi 26/01 à 8H00-12H00, P257 (Rendez-vous devant la salle AIR)

Soutenance : Mercredi 25/03 à 9H00-12H00, Salle à confirmer

{|class="wikitable alternance"
|+ Affectation des projets RICM5 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
|-

!scope="row"| 1
| [[iRock]] :Plateforme Ubilitics pour la surveillance des risques naturelles (déploiement grande échelle de capteurs [[LoRa]] sur le terrain pour l'observation de glissement de terrain) .
| Peyre, Guo, Ginoux, Boey
| Didier Donsez & Denis Jongmans & Georges-Pierre Bonneau
| [[Proj-2014-2015-iRock| '''Fiche''']] [[Proj-2014-2015-iRock/SRS| '''SRS''']] [[Proj-2014-2015-iRock/UML| '''Diagrammes UML''']] [[Proj-2014-2015-iRock/Scrum| '''Scrum''']]
| [https://github.com/fpeyre/IRock_2015'''github''']
| [[Media:Proj-2014-2015-iRock-Rapport|rapport]] - [[Media:Proj-2014-2015-iRock-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-iRock-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-iRock-poster.pdf|poster]] - [[Proj-2014-2015-iRock-media.pdf|Video ou Screencast]]
|-

!scope="row"| 2
| Plateforme Ubilitics pour [[SmartCampus 2015]] : (déploiement grande échelle de capteurs [[LoRa]]) (voir [[OpenBAS]]).
| Sambe, Husson, Labat, Fréby, Barbier
| Didier Donsez & Vivien Quema
| [[Proj-2014-2015-SmartCampus2015| '''Fiche''']] [[Proj-2014-2015-SmartCampus2015/SRS| '''SRS''']] [[Proj-2014-2015-SmartCampus2015#G.C3.A9nie_Logiciel| '''Diagrammes UML''']] [[Proj-2014-2015-SmartCampus2015#Organisation_du_projet| '''Scrum''']]
| [https://github.com/nexucis/SmartCampus '''github''']
| [[Media:Proj-2014-2015-SmartCampus2015-Rapport|rapport]] - [[Media:Proj-2014-2015-SmartCampus2015-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartCampus2015-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-SmartCampus2015-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 3
| [[Extensions XBMC Sujet 2015]]
| Valentin, Bobo, Legros, Gabin Teulon (DUT1 R&T)
| Nicolas Palix
| [[Extensions_XBMC_2015| '''Fiche''']] [[Proj-2014-2015-Ext_XBMC/SRS| '''SRS''']] [[Proj-2014-2015-Ext_XBMC/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Ext_XBMC/Scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:Proj-2014-2015-xbmc-rapport.pdf|rapport]] - [[Media:Proj-2014-2015-Ext_XBMC2015-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-xbmc-flyer.png|flyer]] - [[Media:Proj-2014-2015-xbmc-poster.png|poster]]
|-

!scope="row"| 4
| [[Smart Classroom]] : tables tactiles en mode [[Tiled Display]], Murs interactifs, Robots de Téléprésence, ...
| Benyounes, Fall, Tiamiou, Perruche, Quentin Fombaron (DUT1 R&T), Lucas Reygrobellet (DUT1 R&T)
| Didier Donsez & Vivien Quema & Jérome Maisonnasse
| [[Proj-2014-2015-SmartClassRoom| '''Fiche''']] [[Proj-2014-2015-SmartClassRoom/SRS| '''SRS''']] [[Proj-2014-2015-SmartClassRoom/UML| '''Diagrammes UML''']] [[Proj-2014-2015-SmartClassRoom/Scrum| '''Scrum''']]
| [https://github.com/falle38/SmartClassroom-TiledDisplayPart '''github''']
| [[Media:Proj-2014-2015-SmartClassRoom-Rapport|rapport]] - [[Media:Proj-2014-2015-SmartClassRoom-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassRoom-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-SmartClassRoom-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 5
| Défi H 2015 : Rééducation de la main
| Mariage, Perea, Clerc-Ghérardi, Arredondo (TIS5)
| Didier Donsez & Alessandro Semere & Nicolas Vuillerme + Pierre-Yves Thomas (tuteur Sogeti)
| '''Sur DropBox''' : [[HandTrainer| '''Fiche''']] [[HandTrainer-SRS| '''SRS''']] [[Proj-2014-2015-ReducMain/UML| '''Diagrammes UML''']] [[Proj-2014-2015-ReducMain/Scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:Proj-2014-2015-ReducMain-Rapport|rapport]] - [[Media:Proj-2014-2015-ReducMain-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassRoom-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-ReducMain-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

|}

Rappel: les séances de MPI (Management de Projet Innovant) auront lieu les jours suivants (salles sur ADE) :
* Mardi 27/01 après-midi (Stéphanie Diligent)
* Lundi 2/02 matin (Emmanuelle Tréhoust)
* Lundi 9/02 matin (Emmanuelle Tréhoust)
* Lundi 23/02 matin (Stéphanie Diligent)
* Mardi 17/03 matin (Stéphanie Diligent+Emmanuelle Tréhoust)

Remarque: il y à 3 étudiants PEIP D de l'IUT 1 R&T qui participeront aux projets.

===Projet Biométrie===
Démarrage : Lundi 26/01 à 8H00-9H45

Voir Laurent Besacier & François Portet

=3I=
==3I3==

==3I4==

==3I5==
* Carte d'extension Semtech [[LoRa]] pour [[Arduino]] et [[STM32 Nucleo]] (Didier Donsez)

===Projet Semestre 10===
Démarrage : 26/01/2015
Soutenance: 26/03/2015

{|class="wikitable alternance"
|+ Affectation des projets 3I5 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
!scope="col"| Docs.
|-

!scope="row"| 1
| [[Projet Cannonball - Intégration d'une caméra auto-directive| '''Projet Cannonball''']] : Intégration d'une caméra auto-directive.
| Alwan, Laurent, Cottin Bizonne
| Alina Voda & Ahmad Farhat
| [[Fiche de suivi Projet Cannonball 2015| '''Fiche de suivi''']]
| [https://github.com/Jerome-Laurent/CannonBall-Nucleo-STM32F401 '''github''']
| [[Media:Rapport_Cannonball2015.pdf‎|Rapport]] - [[Media:Poster_Project_Cannonball.pdf|Poster]] - [https://www.youtube.com/watch?v=44PW_EM8MZ0| Vidéo ]

|}

=M2PGI=
* Extensions à [[SmartCampus]]

=Bachelor Summer Program=

=Année A définir=
* [[GeoDiff]] Production, visualisation, fusion de variations (diff) sur de l'information géocodée : Nicolas Palix
* [[Smart campus augmenté et contributif]]
* [[Intégration OpenHAB / OpenTele]]
* [[Client MQTT pour OBD]] sur Android
* [[Sommeilomètre]] (Michael Perin, Didier Donsez)
* [[Open DynDNS]]
* [[IllumiRoom]]
* [[Emergency mobile app]] Nicolas Palix pour TIS, PRI et RICM
* [[OwnPOI]] ownCloud plugin and osmand plugin to share POI and favorite positions. Nicolas Palix.
* [[OwnList]] ownCloud plugin and Android app to share a TODO list. Nicolas Palix.
* [[floatingimage UPnP feed]] Nicolas Palix
* [[XBMC Reflexive Remote]] Dynamic remote control for XBMC. Nicolas Palix.
* [http://intgat.tigress.co.uk/rmy/uml/index.html Zerofree] Portage de zerofree pour d'autres systèmes de fichiers que ext2/3/4 (notamment Unix FS). Voir également la page [http://packages.qa.debian.org/z/zerofree.html QA de Debian]. Nicolas Palix.
* [[Bracelet électronique de monitoriing de l'alcoolémie]]
* [[Oxymètre DIY]]
* [[PinSound]]
* [[Extension du support STM32Fx-Discovery dans libopencm3]] : Olivier Richard
* [[Arduino et libopencm3]] : Olivier Richard
* [[Data Acquisition System et Stm32f4-Discovery]] : Olivier Richard
* [[Distributed Data Storage System]] : Olivier Richard
* [[Dashboard based on w2ui]]
* [[Environnement logiciel pour FabLab]] : Olivier Richard
* [[Environnement logiciel pour le Live Programming]] : Olivier Richard
* [[VirtualPinball]]
* Tondeuse dessinatrice
* [[ImmersiveDog]] Nicolas Glade, Didier Donsez
* Projet avec [[OpenROV]] ???? : Didier Donsez
* [[Sphero]] malin (Michael Périn) (2 etudiants)
* [[Drone paramoteur]] ???
* [[IRock : Surveillance Géotechnique LoRa|iRock]]: Plateforme Ubilitics pour la surveillance des risques naturelles (déploiement grande échelle de capteurs [[LoRa]] sur le terrain pour l'observation de glissement de terrain) en commun avec Geotech (à confirmer) : Didier Donsez & Denis Jongmans
* [[Optimisation de l'énergie pour cyclotouriste électrique]]
* [[SmartSelfService|Smart Self-Service 2015]] Didier Donsez & Vivien Quema
* [[Station Météo LoRa]] : contribution au projet [[LoRA-Fabian]] (Didier Donsez)

=Réserve (boite à idées)=

# [[Tag et Paint Ball en réalité augmentée]] (Michaël Périn)
# [[Passe moi ton fichier]] (Michaël Périn)
# [[Extensions à Fab Server]] (Jean-Michel Molenaar) sous reserve (CM ou SR)
# [[Table multijeux de café 2.0]]
# [[ GPIO_Qemu_RasPI| Emulation des GPIO dans QEMU pour le carte Raspberry Pi]] (Olivier Richard)
# [[ Qemu et STM32F0-Discovery ]] (Olivier Richard)
# [[Serrure à clé MIDI multifactorielle]] (Didier Donsez)
# [[Table interactive musicale]] (Didier Donsez)
# [[iMailbox]] (Didier Donsez)
# [[AmILight]] (eclairage d'ambience intelligent) (Didier Donsez)
# [[PDAmeetPDA]] (synchronisation d'agenda) (Michaël Périn)
# [[1 000 000 VMs]] (expérimentation d'application distribuée à très grande échelle) (Olivier Richard) (2-3 RICM4)
# [[Multiple Kinect]] (utilisation simultanée de plusieurs Kinect) (Olivier Richard) (RICM ou 3I)
# [[Kinect musicale]] (Didier Donsez) (RICM)
# [[Ktechlab Simavr Arduino | Ktechlab et integration de Simavr(Arduino)]] (Olivier Richard) (2-3 RICM4-SR)
# Ocaml on AVR (Arduino)
# Ocaml on Cortex-M3
# [[Arduino on STM32 Discovery]]
# [[Reverse Geocache Puzzle Box]]
# [[OSGi ME]] (Didier Donsez)
# [[Affichage Etudiant à Polytech]]
# Synthèse 3D + motion capture Kinect
# Logiciel d'[[apprentissage du calcul]] sur tablette Android (reconnaissance de chiffres manuscrits)
# Plancher de verre (saint gobain) à la [http://www.wat.tv/video/mickael-jackson-billie-jean-oewj_2ey2h_.html Mickael Jackson dans Billie Jean] ! woo
# [[Ktechlab Simavr Arduino | Ktechlab et integration de Simavr(Arduino)]] (Olivier Richard) (2-3 RICM4-SR)
# [[CNC]]
# [[Idées en Vrac]]
# Scheme Everywhere (Olivier Richard) (2-3 RICM4-SR)
# [[Projet Station Météo]]
# Ocaml on AVR (Arduino)
# [[Table interactive musicale]] (Didier Donsez)
# [[AmILight]] (eclairage d'amnbience intelligent) (Didier Donsez)
# [[Cube pointeur]] d'activité ingénieur
# [http://www.instructables.com/id/Puppeteer-Motion-Capture-Costume/ Puppeteer Motion-Capture Costume]
# [[Musical Staircase]] @ Polytech (Didier Donsez, 1 RICM4 + 1 3I4)
# [[Total Recall]] (Didier Donsez)
# [[SoundMachine]]
# [[IGN-OSM|Importation de données IGN publiques dans OSM]]
# [[Speed-limit-OSM|Analyse de traces GPX pour déterminer les limitations de vitesse]]
# [[Multi perceptual cameras]] (Didier Donsez)
# [[Photomaton 3D]] (Didier Donsez)
# [[ArduCopter]]
# [[Parking Intelligent]]

Projets 2014-2015

2015-04-07T21:48:11Z

Ophelie.Pelloux-Prayer: /* RICM4 */

<<[[Projets 2013-2014]] [[Projets|^Projets^]] [[Projets 2015-2016]]>>

=RICM=
==RICM3==

==RICM4==

* '''Evaluation à mi-parcours le lundi 2 mars''': Format: 10min (5min de présentation 3 slides au plus, 5min de discussion). Cette évaluation sera prise en compte dans la note finale.

'''Consignes générales:'''

* '''Vous devez être pro-actifs !!!''': Si des points sont pas ou mals spécifiés, vous le faîtes et vous justifiez vos choix. Pour les problèmes techniques éventuels vous pouvez: vous creusez la question, vous contactez l'auteur du code si il y a lieux, vous faites un rapport de bug ('''Attention:''' ca se prépare !), vous soumettez un patch, vous contactez l'enseignant ou la personne suivant le projet.

* '''Vous devez maintenir une fiche de suivi de projet''': elle doit être mise à jour chaque semaine, elle rassemble les élements essentiels du projet, elle
indique les évolutions du projet et présente sa feuille de route. '''Note:''' le nom de la fiche doit être composé du nom du projet et suffixé par ricm4_2014_2015.

* '''Vous devez utiliser un logiciel de gestion de version''' pour vos développements comme [http://en.wikipedia.org/wiki/Git_%28software%29 git ] et nous vous conseillons d'utiliser le site [https://github.com github] pour l'hébergement de votre dépôt public.

* Les document public (exemple sur github) doivent être rédigés en anglais (README, documentation, commentaires de code, nom de variables et de fonctions). Une bonnification sera accordée si le rapport et les transparents sont en anglais (la soutenance sera en francais).

{|class="wikitable alternance"
|+ Affectation des projets RICM4 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
|-

!scope="row"| 1
| [[Projet de monoski intelligent]]
| Blondet, Torck
| Didier Donsez, Pascal Jay, David Eon
| [[Proj-2014-2015-MonoskiIntelligent| '''Fiche''']] [[Proj-2014-2015-MonoskiIntelligent/SRS| '''SRS''']]
[[Proj-2014-2015-MonoskiIntelligent/UML| '''Diagrammes UML''']] [[Proj-2014-2015-MonoskiIntelligent/Scrum| '''Scrum''']] ([https://waffle.io/quentin74/monoski Waffle])
| [https://github.com/quentin74/application-monoski '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]] - [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 2
| [[Smart Classroom]]
| Darrigol, Badamo, Damotte, Leonard
| Didier Donsez, Vivien Quema, Jérome Maisonnasse
| [[Proj-2014-2015-SmartClassroom| '''Fiche''']] [[Proj-2014-2015-SmartClassroom/SRS| '''SRS''']] [[Proj-2014-2015-SmartClassroom/UML| '''Diagrammes UML''']] [[Proj-2014-2015-SmartClassroom/Scrum| '''Scrum''']]
| [https://github.com/AlanDamotte/SmartClassroom '''github''']
| [[Media:RapportSmartClassroom2015.pdf|Rapport]] - [[Media:Proj-2014-2015-SmartClassroom-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassroom-flyer.pdf|flyer]] [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtu.be/gX1x9wgypV8 Screencast]
|-

!scope="row"| 3
| [[RobAIR]] et [[STM32 Nucleo]]
| Hammerer, Michel, Klipffel, Viallet **
| Didier Donsez
| [[Projet-2014-2015-RobAIR| '''Fiche''']] [[Projet-2014-2015-RobAIR/SRS| '''SRS''']] [[Projet-2014-2015-RobAIR/UML| '''Diagrammes UML''']] [[Projet-2014-2015-RobAIR/Scrum| '''Scrum''']]
| [https://github.com/teiroy/RobAIR '''github''']
| [[Media:Projet-2014-2015-RobAIR/Rapport|rapport]] - [[Media:Projet-2014-2015-RobAIR-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]] [[Media:Projet-2014-2015-RobAIR-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 4
| [[IDS|Interactive Digitale Signage]]
| Adam, Zhang
| Didier Donsez
| [[Proj-2014-2015-Interactive_Digitale_Signage| '''Fiche''']] [[Projet-2014-2015-Interactive_Digitale_Signage/SRS| '''SRS''']] [[Projet-2014-2015-Interactive_Digitale_Signage/UML| '''Diagrammes UML''']] [[Projet-2014-2015-Interactive_Digitale_Signage/Scrum| '''Scrum''']]
| [https://github.com/zhangzhengmeng/ProjetIDS2015.git '''github''']
| [[Media:Proj-2014-2015-Interactive_Digitale_Signage/Rapport|rapport]] - [[Media:Proj-2014-2015-Interactive_Digitale_Signage-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-Interactive_Digitale_Signage-flyer.pdf|flyer]] [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 5
| [[Régie vidéo autonome et mobile multi-caméra]]
| Zominy, Bodard, Qian
| Didier Donsez, Thierry C.
| [[Proj-2014-2015-RegieVideoAutonomeEtMobileMulticamera| '''Fiche''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/SRS| '''SRS''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera/Scrum| '''Scrum''']]
| [https://github.com/kurisuter/Regie-video-autonome-'''github''']
| [[Media:Rapport_regie.pdf|rapport]] - [[Media:Projet-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera-transparents.pdf|transparents]] - [[Media:Projet-2014-2015-Regie_Video_Autonome_Et_Mobile_Multicamera-flyer.pdf|flyer]] - [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 6
| OpenHAB Extended GUI ([[IFTTT]] et à la [[Node-RED]] ou [[Flowhub]] pour [[OpenHAB]], Découverte [[UPnP]] des équipements)
| Toussaint, Saussac
| Didier Donsez
| [[Proj-2014-2015-OpenHAB-ExtendedGUI| '''Fiche''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/SRS| '''SRS''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/UML| '''Diagrammes UML''']] [[Projet-2014-2015-OpenHAB-ExtendedGUI/Scrum| '''Scrum''']]
| [https://github.com/sebjoe/ProjetExtensionOpenHabRicm4 '''github''']
| [[Media:RapportFranc.pdf|Rapport Francais]]- [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI/Rapport2|Rapport Anglais]] - [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-OpenHAB-ExtendedGUI-transparentsanglais.pdf|transparents anglais]] - [[Media:PProj-2014-2015-OpenHAB-ExtendedGUI-flyer.pdf|flyer]]
|-

!scope="row"| 7
| [[CannonBall de voitures autonomes|CannonBall de voitures autonomes, Edition 2015]]
| Le-Jean, Mammar, Pelloux-Prayer, Rodrigues
| Didier Donsez & Vivien Quema
| [[Project-2014-2015-CannonBall| '''Fiche''']][[Project 2014-2015-CannonBall/SRS| '''SRS''']][[Project 2014-2015-CannonBall/UML| '''UML''']][[Project 2014-2015-CannonBall/Scrum| '''Scrum''']][[Project 2014-2015-CannonBall/DesignPatterns| '''DesignPatterns''']]
| [https://github.com/malek0512/2014_2015_ricm4_cannon_ball '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtu.be/bkoyAkvbdVI Video]
|-

!scope="row"| 8
| [[Navigation et Montre connectée]]
| Hamdani, Mesnier, Yao
| Jacques Lemordant
| [[Proj-2014-2015-Montreconnectée| '''Fiche''']] [[Proj-2014-2015-Montreconnectée/SRS| '''SRS''']] [[Proj-2014-2015-Montreconnectée/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Montreconnectée/Scrum| '''Scrum''']][[Proj-2014-2015-Montreconnectée/DesignPattern| '''DesignPattern''']]
| [https://github.com/vince0508/OrientateWatch.git '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 9
| [[Python sur ESP8266]]
| Libralesso, Soldano
| Olivier Richard
| [[Project-2014-2015-ESP8266| '''Fiche''']] - [[Proj-2014-2015-ESP8266/SRS| '''SRS''']] - [[Proj-2014-2015-ESP8266/UML| '''UML diagrams''']] - [[Proj-2014-2015-ESP8266/Scrum| '''Scrum''']]
| [https://github.com/librallu/RICM4Projet/ '''github''']
| [https://github.com/librallu/RICM4Projet/blob/master/reports/Final_report/final.rst '''rapport'''] - [https://github.com/librallu/RICM4Projet/tree/master/reports/presentation/ '''transparents'''] - [[Media:Projet9-ESP8266-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast] - [http://librallu.github.io/RICM4Projet/ '''website''']
|-

!scope="row"| 10
| [[Serious Game: Handicap, parole et geste v2]]
| Aissanou, Codazzi, Guo
| Olivier Richard
| [[Proj-2014-2015-SeriousGamev2| '''Fiche''']][[Proj-2014-2015-SeriousGamev2/SRS| '''SRS''']][[Proj-2014-2015-SeriousGamev2/Scrum| '''Scrum''']] [[Projet-2014-2015-SeriousGamev2/Diagrammes| '''Diagrammes UML''']]
| [https://github.com/wizardkeven/SeriousGameV2 '''github''']
| [[Media:ProjetXYZ/Rapport|rapport]] - [[Media:ProjetXXX-transparents.pdf|transparents]] - [[Media:ProjetXXX-flyer.pdf|flyer]]- [[Media:ProjetXXX-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 11
| [[Plateforme d'expérimentation mini-datacentre]] Système
| Fotsing, Morison
| Olivier Richard
| [[Proj-2014-2015-Mini_DataCenter_Systeme| '''Fiche''']][[Proj-2014-2015-Mini_datacenter_Systeme_SRS| '''SRS''']] [[Proj-2014-2015-Mini_datacenter_Systeme_scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:ProjetMini_DataCenter_Systeme/Rapport|rapport]] - [[Media:ProjetMini_DataCenter_Systeme-transparents.pdf|transparents]] - [[Media:ProjetMini_DataCenter_Systeme-flyer.pdf|flyer]]- [[Media:ProjetMini_DataCenter_Systeme-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 12
| [[Plateforme d'expérimentation mini-datacentre]] Portail
| Rossi, [[User:Robin.Eudes|Eudes]]
| Olivier Richard
| [[Proj-2014-2015-Mini_datacenter_portail| '''Fiche''']] [[Proj-2014-2015-Mini_datacenter_portail_SRS| '''SRS''']] [[Proj-2014-2015-Mini_datacenter_portail_scrum| '''Scrum''']] [[Proj-2014-2015-Mini_datacenter_portail_uml| '''UML''']]
| [https://github.com/EudesRobin/webui-oardocker '''github''']
| [[Media:Projet_webui-oardocker-rapport.pdf|rapport]] - [[Media:Projet_webui-oardocker-transparents.pdf|transparents]] - [[Media:Projet_webui-oardocker-flyer.pdf|flyer]]- [[Media:Projet-webui-oardocker-poster.pdf|poster]] - [https://www.youtube.com/watch?v=OXnNJ0PsN_g Screencast]
|-

|}

* [[Projet de monoski intelligent]] (RICM4 et 3I4 et Matériaux) pour le [http://www.defi-foly-laclusaz.com/ défi Foly 2015] : Didier Donsez, Pascal Jay, David Eon (2 élèves)
* [[Smart Classroom]] (avec ENSIMAG) Didier Donsez, Vivien Quema, Jérome Maisonnasse (4 élèves)
* Robot [[RobAIR]] à base de [[STM32 Nucleo]] (+ cartes additionnelles MEMS BLE4) et de téléphones [[Firefox OS]]. Didier Donsez (4 élèves)
* [[StartAIR]] (Fabrice Dubost) (2 élèves)
* [[IDS|Interactive Digitale Signage]] avec [[Reveal.js]], [[Kinect]], [[WebRTC]], [[Node.js]], [[Open Data]], [[NFC]], [[Miracast]] [http://blueimp.github.io/Bootstrap-Image-Gallery/ Bootstrap Gallery]... (Didier Donsez) (2 élèves)
* [[Régie vidéo autonome et mobile multi-caméra]] (Didier Donsez, Thierry C.) (2 élèves)
* Interface HTML5 à la [[IFTTT]] et à la [[Node-RED]] ou [[Flowhub]] pour [[OpenHAB]] (2 élèves)
* [[Intégration d'Espruino à RIOT OS]] sur [[STM32 Nucleo]]: Application à la robotique [[RobAIR]] (Didier Donsez) (2 élèves)
* [[Inventaire Forestier]] sous Android (3I4 ou 5, RICM4) Emmanuel Promayon (2 élèves)
* [[Navigation indoor basé iBeacons]], Jacques Lemordant (2 élèves)
* [[Navigation et Montre connectée]], Jacques Lemordant (2 élèves)
* [[Projets Sitra avec la région Rhône-Alpes]], Jacques Lemordant (2 élèves)
* [[CannonBall de voitures autonomes|CannonBall de voitures autonomes, Edition 2015]] Didier Donsez & Vivien Quema (piste [[Star War Drone Race]]) (2 élèves)
* [[Python sur ESP8266]] Olivier Richard (2 élèves)
* [[Serious Game: Handicap, parole et geste v2]], edition 2015, Olivier Richard (2 élèves)
* [[Plateforme d'expérimentation mini-datacentre]] édition 2015, Olivier Richard (2 élèves)

==RICM5==
===Projet Semestre S10===
Démarrage : Lundi 26/01 à 8H00-12H00, P257 (Rendez-vous devant la salle AIR)

Soutenance : Mercredi 25/03 à 9H00-12H00, Salle à confirmer

{|class="wikitable alternance"
|+ Affectation des projets RICM5 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
|-

!scope="row"| 1
| [[iRock]] :Plateforme Ubilitics pour la surveillance des risques naturelles (déploiement grande échelle de capteurs [[LoRa]] sur le terrain pour l'observation de glissement de terrain) .
| Peyre, Guo, Ginoux, Boey
| Didier Donsez & Denis Jongmans & Georges-Pierre Bonneau
| [[Proj-2014-2015-iRock| '''Fiche''']] [[Proj-2014-2015-iRock/SRS| '''SRS''']] [[Proj-2014-2015-iRock/UML| '''Diagrammes UML''']] [[Proj-2014-2015-iRock/Scrum| '''Scrum''']]
| [https://github.com/fpeyre/IRock_2015'''github''']
| [[Media:Proj-2014-2015-iRock-Rapport|rapport]] - [[Media:Proj-2014-2015-iRock-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-iRock-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-iRock-poster.pdf|poster]] - [[Proj-2014-2015-iRock-media.pdf|Video ou Screencast]]
|-

!scope="row"| 2
| Plateforme Ubilitics pour [[SmartCampus 2015]] : (déploiement grande échelle de capteurs [[LoRa]]) (voir [[OpenBAS]]).
| Sambe, Husson, Labat, Fréby, Barbier
| Didier Donsez & Vivien Quema
| [[Proj-2014-2015-SmartCampus2015| '''Fiche''']] [[Proj-2014-2015-SmartCampus2015/SRS| '''SRS''']] [[Proj-2014-2015-SmartCampus2015#G.C3.A9nie_Logiciel| '''Diagrammes UML''']] [[Proj-2014-2015-SmartCampus2015#Organisation_du_projet| '''Scrum''']]
| [https://github.com/nexucis/SmartCampus '''github''']
| [[Media:Proj-2014-2015-SmartCampus2015-Rapport|rapport]] - [[Media:Proj-2014-2015-SmartCampus2015-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartCampus2015-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-SmartCampus2015-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 3
| [[Extensions XBMC Sujet 2015]]
| Valentin, Bobo, Legros, Gabin Teulon (DUT1 R&T)
| Nicolas Palix
| [[Extensions_XBMC_2015| '''Fiche''']] [[Proj-2014-2015-Ext_XBMC/SRS| '''SRS''']] [[Proj-2014-2015-Ext_XBMC/UML| '''Diagrammes UML''']] [[Proj-2014-2015-Ext_XBMC/Scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:Proj-2014-2015-xbmc-rapport.pdf|rapport]] - [[Media:Proj-2014-2015-Ext_XBMC2015-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-xbmc-flyer.png|flyer]] - [[Media:Proj-2014-2015-xbmc-poster.png|poster]]
|-

!scope="row"| 4
| [[Smart Classroom]] : tables tactiles en mode [[Tiled Display]], Murs interactifs, Robots de Téléprésence, ...
| Benyounes, Fall, Tiamiou, Perruche, Quentin Fombaron (DUT1 R&T), Lucas Reygrobellet (DUT1 R&T)
| Didier Donsez & Vivien Quema & Jérome Maisonnasse
| [[Proj-2014-2015-SmartClassRoom| '''Fiche''']] [[Proj-2014-2015-SmartClassRoom/SRS| '''SRS''']] [[Proj-2014-2015-SmartClassRoom/UML| '''Diagrammes UML''']] [[Proj-2014-2015-SmartClassRoom/Scrum| '''Scrum''']]
| [https://github.com/falle38/SmartClassroom-TiledDisplayPart '''github''']
| [[Media:Proj-2014-2015-SmartClassRoom-Rapport|rapport]] - [[Media:Proj-2014-2015-SmartClassRoom-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassRoom-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-SmartClassRoom-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

!scope="row"| 5
| Défi H 2015 : Rééducation de la main
| Mariage, Perea, Clerc-Ghérardi, Arredondo (TIS5)
| Didier Donsez & Alessandro Semere & Nicolas Vuillerme + Pierre-Yves Thomas (tuteur Sogeti)
| '''Sur DropBox''' : [[HandTrainer| '''Fiche''']] [[HandTrainer-SRS| '''SRS''']] [[Proj-2014-2015-ReducMain/UML| '''Diagrammes UML''']] [[Proj-2014-2015-ReducMain/Scrum| '''Scrum''']]
| [https://github.com/ '''github''']
| [[Media:Proj-2014-2015-ReducMain-Rapport|rapport]] - [[Media:Proj-2014-2015-ReducMain-transparents.pdf|transparents]] - [[Media:Proj-2014-2015-SmartClassRoom-flyer.pdf|flyer]] - [[Media:Proj-2014-2015-ReducMain-poster.pdf|poster]] - [http://youtube.com Video ou Screencast]
|-

|}

Rappel: les séances de MPI (Management de Projet Innovant) auront lieu les jours suivants (salles sur ADE) :
* Mardi 27/01 après-midi (Stéphanie Diligent)
* Lundi 2/02 matin (Emmanuelle Tréhoust)
* Lundi 9/02 matin (Emmanuelle Tréhoust)
* Lundi 23/02 matin (Stéphanie Diligent)
* Mardi 17/03 matin (Stéphanie Diligent+Emmanuelle Tréhoust)

Remarque: il y à 3 étudiants PEIP D de l'IUT 1 R&T qui participeront aux projets.

===Projet Biométrie===
Démarrage : Lundi 26/01 à 8H00-9H45

Voir Laurent Besacier & François Portet

=3I=
==3I3==

==3I4==

==3I5==
* Carte d'extension Semtech [[LoRa]] pour [[Arduino]] et [[STM32 Nucleo]] (Didier Donsez)

===Projet Semestre 10===
Démarrage : 26/01/2015
Soutenance: 26/03/2015

{|class="wikitable alternance"
|+ Affectation des projets 3I5 2014-2015
|-
|
!scope="col"| Sujet
!scope="col"| Etudiants
!scope="col"| Enseignant(s)
!scope="col"| Fiche de suivi
!scope="col"| Dépot git
!scope="col"| Docs.
|-

!scope="row"| 1
| [[Projet Cannonball - Intégration d'une caméra auto-directive| '''Projet Cannonball''']] : Intégration d'une caméra auto-directive.
| Alwan, Laurent, Cottin Bizonne
| Alina Voda & Ahmad Farhat
| [[Fiche de suivi Projet Cannonball 2015| '''Fiche de suivi''']]
| [https://github.com/Jerome-Laurent/CannonBall-Nucleo-STM32F401 '''github''']
| [[Media:Rapport_Cannonball2015.pdf‎|Rapport]] - [[Media:Poster_Project_Cannonball.pdf|Poster]] - [https://www.youtube.com/watch?v=44PW_EM8MZ0| Vidéo ]

|}

=M2PGI=
* Extensions à [[SmartCampus]]

=Bachelor Summer Program=

=Année A définir=
* [[GeoDiff]] Production, visualisation, fusion de variations (diff) sur de l'information géocodée : Nicolas Palix
* [[Smart campus augmenté et contributif]]
* [[Intégration OpenHAB / OpenTele]]
* [[Client MQTT pour OBD]] sur Android
* [[Sommeilomètre]] (Michael Perin, Didier Donsez)
* [[Open DynDNS]]
* [[IllumiRoom]]
* [[Emergency mobile app]] Nicolas Palix pour TIS, PRI et RICM
* [[OwnPOI]] ownCloud plugin and osmand plugin to share POI and favorite positions. Nicolas Palix.
* [[OwnList]] ownCloud plugin and Android app to share a TODO list. Nicolas Palix.
* [[floatingimage UPnP feed]] Nicolas Palix
* [[XBMC Reflexive Remote]] Dynamic remote control for XBMC. Nicolas Palix.
* [http://intgat.tigress.co.uk/rmy/uml/index.html Zerofree] Portage de zerofree pour d'autres systèmes de fichiers que ext2/3/4 (notamment Unix FS). Voir également la page [http://packages.qa.debian.org/z/zerofree.html QA de Debian]. Nicolas Palix.
* [[Bracelet électronique de monitoriing de l'alcoolémie]]
* [[Oxymètre DIY]]
* [[PinSound]]
* [[Extension du support STM32Fx-Discovery dans libopencm3]] : Olivier Richard
* [[Arduino et libopencm3]] : Olivier Richard
* [[Data Acquisition System et Stm32f4-Discovery]] : Olivier Richard
* [[Distributed Data Storage System]] : Olivier Richard
* [[Dashboard based on w2ui]]
* [[Environnement logiciel pour FabLab]] : Olivier Richard
* [[Environnement logiciel pour le Live Programming]] : Olivier Richard
* [[VirtualPinball]]
* Tondeuse dessinatrice
* [[ImmersiveDog]] Nicolas Glade, Didier Donsez
* Projet avec [[OpenROV]] ???? : Didier Donsez
* [[Sphero]] malin (Michael Périn) (2 etudiants)
* [[Drone paramoteur]] ???
* [[IRock : Surveillance Géotechnique LoRa|iRock]]: Plateforme Ubilitics pour la surveillance des risques naturelles (déploiement grande échelle de capteurs [[LoRa]] sur le terrain pour l'observation de glissement de terrain) en commun avec Geotech (à confirmer) : Didier Donsez & Denis Jongmans
* [[Optimisation de l'énergie pour cyclotouriste électrique]]
* [[SmartSelfService|Smart Self-Service 2015]] Didier Donsez & Vivien Quema
* [[Station Météo LoRa]] : contribution au projet [[LoRA-Fabian]] (Didier Donsez)

=Réserve (boite à idées)=

# [[Tag et Paint Ball en réalité augmentée]] (Michaël Périn)
# [[Passe moi ton fichier]] (Michaël Périn)
# [[Extensions à Fab Server]] (Jean-Michel Molenaar) sous reserve (CM ou SR)
# [[Table multijeux de café 2.0]]
# [[ GPIO_Qemu_RasPI| Emulation des GPIO dans QEMU pour le carte Raspberry Pi]] (Olivier Richard)
# [[ Qemu et STM32F0-Discovery ]] (Olivier Richard)
# [[Serrure à clé MIDI multifactorielle]] (Didier Donsez)
# [[Table interactive musicale]] (Didier Donsez)
# [[iMailbox]] (Didier Donsez)
# [[AmILight]] (eclairage d'ambience intelligent) (Didier Donsez)
# [[PDAmeetPDA]] (synchronisation d'agenda) (Michaël Périn)
# [[1 000 000 VMs]] (expérimentation d'application distribuée à très grande échelle) (Olivier Richard) (2-3 RICM4)
# [[Multiple Kinect]] (utilisation simultanée de plusieurs Kinect) (Olivier Richard) (RICM ou 3I)
# [[Kinect musicale]] (Didier Donsez) (RICM)
# [[Ktechlab Simavr Arduino | Ktechlab et integration de Simavr(Arduino)]] (Olivier Richard) (2-3 RICM4-SR)
# Ocaml on AVR (Arduino)
# Ocaml on Cortex-M3
# [[Arduino on STM32 Discovery]]
# [[Reverse Geocache Puzzle Box]]
# [[OSGi ME]] (Didier Donsez)
# [[Affichage Etudiant à Polytech]]
# Synthèse 3D + motion capture Kinect
# Logiciel d'[[apprentissage du calcul]] sur tablette Android (reconnaissance de chiffres manuscrits)
# Plancher de verre (saint gobain) à la [http://www.wat.tv/video/mickael-jackson-billie-jean-oewj_2ey2h_.html Mickael Jackson dans Billie Jean] ! woo
# [[Ktechlab Simavr Arduino | Ktechlab et integration de Simavr(Arduino)]] (Olivier Richard) (2-3 RICM4-SR)
# [[CNC]]
# [[Idées en Vrac]]
# Scheme Everywhere (Olivier Richard) (2-3 RICM4-SR)
# [[Projet Station Météo]]
# Ocaml on AVR (Arduino)
# [[Table interactive musicale]] (Didier Donsez)
# [[AmILight]] (eclairage d'amnbience intelligent) (Didier Donsez)
# [[Cube pointeur]] d'activité ingénieur
# [http://www.instructables.com/id/Puppeteer-Motion-Capture-Costume/ Puppeteer Motion-Capture Costume]
# [[Musical Staircase]] @ Polytech (Didier Donsez, 1 RICM4 + 1 3I4)
# [[Total Recall]] (Didier Donsez)
# [[SoundMachine]]
# [[IGN-OSM|Importation de données IGN publiques dans OSM]]
# [[Speed-limit-OSM|Analyse de traces GPX pour déterminer les limitations de vitesse]]
# [[Multi perceptual cameras]] (Didier Donsez)
# [[Photomaton 3D]] (Didier Donsez)
# [[ArduCopter]]
# [[Parking Intelligent]]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:15:50Z

Ophelie.Pelloux-Prayer: /* Sprint 3 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

=End Sprint 1=
User Story done : 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2 (The researchers needs several game mode to verify the good behavior of the car).

=Sprint 3=
We need to do the user story 3 (The researcher needs a car simulator to avoid material constraint).

We also need to correct the problem of low frame rate.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:15:20Z

Ophelie.Pelloux-Prayer: /* Sprint 3 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

=End Sprint 1=
User Story done : 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2 (The researchers needs several game mode to verify the good behavior of the car).

=Sprint 3=
We need to do the user story 3 (The researcher needs a car simulator to avoid material constraint).
We also need to correct the problem of low fps.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:14:26Z

Ophelie.Pelloux-Prayer: /* Sprint 3 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

=End Sprint 1=
User Story done : 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2 (The researchers needs several game mode to verify the good behavior of the car).

=Sprint 3=
We need to do the user story 3 (The researcher needs a car simulator to avoid material constraint).

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:13:54Z

Ophelie.Pelloux-Prayer: /* End Sprint 1 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

=End Sprint 1=
User Story done : 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2 (The researchers needs several game mode to verify the good behavior of the car).

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:13:32Z

Ophelie.Pelloux-Prayer: /* Sprint 1 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1 (The researcher must be able to consult in real time the car's information to make changes if needed).

=End Sprint 1=
User Story done : 1

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2 (The researchers needs several game mode to verify the good behavior of the car).

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:13:11Z

Ophelie.Pelloux-Prayer: /* Sprint 2 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1.

=End Sprint 1=
User Story done : 1

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2 (The researchers needs several game mode to verify the good behavior of the car).

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:12:49Z

Ophelie.Pelloux-Prayer: /* Sprint 2 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1.

=End Sprint 1=
User Story done : 1

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the user story 2.

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:12:08Z

Ophelie.Pelloux-Prayer: /* End Sprint 1 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1.

=End Sprint 1=
User Story done : 1

Problems :

Problem with the speed of processing the images. The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the tasks 1, 3 and 7.

We add also the task 2 because this one was not finished in the last sprint.

Task 3 is already working, so we add some changes on this task :
The developper can add specific orders to the car with the help of qrCode to realize different tests.

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:11:45Z

Ophelie.Pelloux-Prayer: /* End Sprint 1 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1.

=End Sprint 1=
User Story done : 1

Problems :

Problem with the speed of processing the images.

The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the tasks 1, 3 and 7.

We add also the task 2 because this one was not finished in the last sprint.

Task 3 is already working, so we add some changes on this task :
The developper can add specific orders to the car with the help of qrCode to realize different tests.

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:10:06Z

Ophelie.Pelloux-Prayer: /* Sprint 1 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the user story 1.

=End Sprint 1=
Tasks done :
6 and 5

Problems :

Task 2 : problem with the speed of processing the images.

The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the tasks 1, 3 and 7.

We add also the task 2 because this one was not finished in the last sprint.

Task 3 is already working, so we add some changes on this task :
The developper can add specific orders to the car with the help of qrCode to realize different tests.

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/Scrum

2015-04-07T07:09:46Z

Ophelie.Pelloux-Prayer: /* Sprint 1 */

=Project Presentation=
[http://air.imag.fr/index.php/CannonBall_de_voitures_autonomes CannonBall]

=User stories=

1. The researcher must be able to consult in real time the car's information to make changes if needed.

* Broadcast the messages with a publish/subscribe protocol
* Create a Node.js server that will serve the html page to the client
* Store the car's data in a database
* Car's data are showed on the html page

2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).

* AISheep : facilitates the QRCode-Action matching :
** Make generic actions for car mouvements
** Make a grammar syntax for the user and a its parser

* AIRabbit : the car follow a specific QRcode :
** QRcode recognition
** Localize the marker in space
** Move in the marker direction

* AICannonBall : the car moves in a QRcode circuit :
** QRcode recognition and interpretation
** Avoid the QRcode

3. The researcher needs a car simulator to avoid material constraint
* Make a simulator
* Give instructions to the simulator
* The simulator reproduce exactly the comportment of the car (real interpretation)
* Choose a wise graphic library
* Get the data from the mosquitto broker

* Documentation : facilitate the comprehension and use of the piece of software
** make a documentation of all the actions that are programmed

The developer have to optimize the processing speed to provide a better product experience.
The RICM must master the different technologies to be able to do the project.
The RICM want the car works in order to start the project.
The RICM need to change the Arduino board with a STM32 (more equipped with sensors) to improve the precision of movement
The user should access the web interface through a Rasberry pi Wifi router
The RICM need to develop a car simulator for algorithms testing purposes

=Product backlog=
{|class="wikitable alternance"
|-
!scope="col" width="40%"| User story
!scope="col"| Tasks
!scope="col"| Priority
!scope="col"| Time
!scope="col"| Actors
|-
! scope="row" | 1. The researcher must be able to consult in real time the car's information to make changes if needed.
|
|
|
|
|-

|
| Broadcast the messages with a publish/subscribe protocol
| 13
| 1 week
|
|-

|
| Create a Node.js server that will serve the html page to the client
| 21
| 1 week
|
|-

|
| Store the car's data in a database
| 13
| 1 week
|
|-

|
| Car's data are showed on the html page
| 21
| 1 week
|
|-

! scope="row" | 2. The researchers needs several game mode to verify the good behavior of the car (Control Algorithm).
|
|
|
|
|-

| '''AISheep : facilitates the QRCode-Action matching'''
| Make generic actions for car mouvements
| 21
| 1 week
|
|-

|
| Make a grammar syntax for the user and a its parser
| 13
| 1 week
|
|-

| '''AIRabbit : the car follow a specific QRcode'''
| QRcode recognition
| 34
| 1 week
|
|-

|
| Localize the marker in space
| 21
| 2 weeks
|
|-

|
| Move in the marker direction
| 21
| 2 weeks
|
|-

| '''AICannonBall : the car moves in a QRcode circuit'''
| QRcode recognition and interpretation
| 34
| 2 weeks
|
|-

|
| Avoid the QRcode
| 21
| 2 weeks
|
|-

! scope="row" | 3. The researcher needs a car simulator to avoid material constraint
|
|
|
|
|-

|
| Make a simulator
| 21
| 2 weeks
|
|-

|
| Give instructions to the simulator
| 21
| 2 weeks
|
|-

|
| The simulator reproduce exactly the comportment of the car (real interpretation)
| 21
| 1 week
|
|-

|
| Choose a wise graphic library
| 13
| 1 week
|
|-

|
| Get the data from the mosquitto broker
| 13
| 1 week
|
|-

|}

=Sprint 1=
We need to do the tasks 1.

=End Sprint 1=
Tasks done :
6 and 5

Problems :

Task 2 : problem with the speed of processing the images.

The frame rate is very slow. The car is moving slowly.

=Sprint 2=
We need to do the tasks 1, 3 and 7.

We add also the task 2 because this one was not finished in the last sprint.

Task 3 is already working, so we add some changes on this task :
The developper can add specific orders to the car with the help of qrCode to realize different tests.

=Sprint 3=
We need to do the tasks 8 and 9.

=Waffle=
[https://waffle.io/malek0512/2014_2015_ricm4_cannon_ball here]

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T14:35:03Z

Ophelie.Pelloux-Prayer: /* MVC */

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T14:34:52Z

Ophelie.Pelloux-Prayer: /* MVC : Simulateur */

File:Mvc.png

2015-04-06T14:34:26Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T14:33:50Z

Ophelie.Pelloux-Prayer:

File:Sequence.png

2015-04-06T13:52:53Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:Sequence.png"

File:Sequence.png

2015-04-06T13:50:33Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:Sequence.png"

Project 2014-2015-CannonBall/UML

2015-04-06T13:43:57Z

Ophelie.Pelloux-Prayer: /* Sequence Diagrams */

Project 2014-2015-CannonBall/UML

2015-04-06T13:43:52Z

Ophelie.Pelloux-Prayer: /* Sequence Diagrams */

Project 2014-2015-CannonBall/UML

2015-04-06T13:43:45Z

Ophelie.Pelloux-Prayer: /* Sequence Diagrams */

File:Sequence.png

2015-04-06T13:42:59Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/UML

2015-04-06T13:42:27Z

Ophelie.Pelloux-Prayer: /* Class Diagrams */

Project 2014-2015-CannonBall/UML

2015-04-06T13:42:18Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/UML

2015-04-06T13:07:03Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/UML

2015-04-06T13:06:53Z

Ophelie.Pelloux-Prayer: /* Sequence */

Project 2014-2015-CannonBall/UML

2015-04-06T13:06:43Z

Ophelie.Pelloux-Prayer:

File:EAI Pub Sub Simulateur.png

2015-04-06T12:24:43Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:EAI Pub Sub Simulateur.png"

File:Mvp.png

2015-04-06T12:21:55Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T12:21:45Z

Ophelie.Pelloux-Prayer: /* MVP */

File:EAI Pub Sub Simulateur.png

2015-04-06T12:07:50Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:EAI Pub Sub Simulateur.png"

File:EAI Publish Subscribe.png

2015-04-06T12:07:16Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:EAI Publish Subscribe.png"

File:MVC Simul.png

2015-04-06T12:06:35Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:MVC Simul.png": Reverted to version as of 11:55, 6 April 2015

File:MVC Simul.png

2015-04-06T12:05:05Z

Ophelie.Pelloux-Prayer: Ophelie.Pelloux-Prayer uploaded a new version of "File:MVC Simul.png"

File:MVC Simul.png

2015-04-06T11:55:53Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T11:55:44Z

Ophelie.Pelloux-Prayer: /* MVC : Simulateur */

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T11:55:36Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T11:54:24Z

Ophelie.Pelloux-Prayer: /* MVP */

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T11:54:13Z

Ophelie.Pelloux-Prayer:

File:Mvp.jpg

2015-04-06T11:53:07Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T11:52:55Z

Ophelie.Pelloux-Prayer: /* MVP */

File:Mvp.pdf

2015-04-06T11:51:27Z

Ophelie.Pelloux-Prayer:

Project 2014-2015-CannonBall/DesignPatterns

2015-04-06T11:51:11Z

Ophelie.Pelloux-Prayer: