Projects tagged ‘network’ and ‘sensor’

The Make Controller is an open source network-enabled microcontroller platform, based on the Atmel 32-bit SAM7X, sponsored by MakingThings. It provides easy to use development tools, a rich set of ... [More] libraries to get you started quickly and a variety of integrations to desktop environments. The main support site, with forums, documentation and store can be found at http://www.makingthings.com. There are a variety of software components to the Make Controller project: FirmwareThe firmware for the Make Controller is written in C/C++ and provides a variety of libraries for easily controlling the board's peripherals, communicating on the network, via USB and much more. Docs are available at http://www.makingthings.com/ref/firmware/html. mchelperMake Controller Helper is a configuration program that makes it easy to communicate with the default firmware build for the Make Controller, called Heavy. Heavy communicates with mchelper via OSC (Open Sound Control) and exposes most of the functionality on the board to external control. mchelper also provides an XML server that can manage communication between the Make Controller and other desktop applications if those applications can't or don't want to communicate directly via USB or the network interface. mchelper is written in C++/Qt4. mcbuilderMake Controller Builder is an easy to use, all in one development environment for the Make Controller. It provides a pre-configured toolchain for cross compilation, simple code editor and project management for Make Controller firmware development. mcbuilder is written in C++/Qt4. Flash / ActionScriptThe Make Controller can communicate with Flash & ActionScript projects via the XMLSocket API. This requires running mchelper since Flash can't communicate directly via USB, for example. Docs are available at http://www.makingthings.com/ref/flash. Max/MSPThe Make Controller can communicate via USB with Max/MSP using the mc.usb external. If you don't need to communicate via USB, you can use the built-in udpsend and udpreceive objects along with the OpenSoundControl object from CNMAT. [Less]

A wildlife tracking project using Sun SPOTs. Network uses FPS reservation-based routing. Ongoing work in power management.

CRANES (Context- & Resource-Adaptive Network-Embedded Sensors) is an extension framework for the JiST/SWANS (Java in Simulation Time / Scalable Wireless Ad hoc Network Simulator) discrete event ... [More] simulator and aims to provide a simulation framework for wireless sensor networks. It is based on the SIDnet-SWANS (Simulator and Integrated Development Platform for Sensor Networks Applications) and provides a flexible and adaptive communication architecture optimized for wireless sensor network applications. [Less]

Intelligent Wireless Sensor Networks Browser

SensoBygThe purpose of The SensoByg Project is to develop low-cost, reliable surveillance systems for the construction sector using embedded, wireless sensor technology and intelligent decision ... [More] support systems. The focus is on surveillance of moisture and temperature in the construction sector via wireless sensors. The CodeThis code is a contribution from the F1 sub-project where the goal is to develop a network/software-architecture supporting the SensoByg scenarios and their derived demands. It should also scale to general sensor-based surveillance systems used in the building industry. The result of the work done by F1 will be a state-of-the-art network and software architecture of sensors, databases, and interfaces to other systems, implemented in a generic SensoByg framework. [Less]

SimMobil is a wireless network simulator that has been developped for 2 years at INSA Rennes, France as a student project. Our goal is to implement several kind of wireless networks : infrastructured ... [More] , ad hoc, hybrid, sensor networks along route and sleeping algorithms in a simulator. The application is developped using the Java programming language and Swing. [Less]

Armazd is a software system designed to monitoring of the network components. We can distinguish two kind of network components: physical and logical. By the physical network components we mean ... [More] some network devices (i.e. routers, switches, etc), hosts (i.e. servers, work stations, etc). The logical, consists of some services (i.e. SOA). Based on the multi-agents architecture, Armazd can deliver us all information we need about each of the network components. [Less]

The Re-Mote Testbed Framework is a collection of modules for providing remote access to wireless sensor network testbeds with a main focus on modularity, abstraction levels, and responsiveness. The ... [More] components of the framework fall into three categories: Client software, server software and host/gateway software. The client is a Java based GUI featuring mote console windows useful for debugging applications. The server software consists of a mote server daemon written in C++, a relational database based on MySQL, and a mote information server based on Apache Tomcat and Axis. The host software is a mote host daemon written in C++ with site specific configuration in shell scripts. Getting StartedIf you are using the Re-Mote client basic information is available in the UserManual. If you are deploying a testbed see the AdministratorManual and read the SecurityConsiderations. If you want to contribute read the DeveloperManual and take a look at the RoadMap to get an idea of what needs work. Questions and Bug ReportingQuestions can be mailed to the mailing list. All discussions related to testbeds and sensor networks are welcome. Note, first time posters are moderated to prevent spam. If you found a bug in the client or one of the other components, please enter it into the issue tracker. If the bug has already been reported you are encouraged to add extra information as a comment. This will help to confirm that it is reproducible and raise the attention of developers. CreditThe project is being developed in collaboration between DIKU and CIT and headed by Jonas Fonseca and Rostislav Špinar. The initial work was done by Jan Flora and Esben Zeuthen at DIKU under the supervision of Philippe Bonnet. The Re-Mote Testbed Framework has been developed in the context of Embedded WiSeNts and has further been developed in the context of the CRUISE IST. [Less]