IBBT IBCN Universiteit Gent MMLab Universiteit Gent ETRO Vrije Universiteit Brussel ICRI Katholieke Universiteit Leuven COSIC Katholieke Universiteit Leuven.

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IBBT IBCN Universiteit Gent MMLab Universiteit Gent ETRO Vrije Universiteit Brussel ICRI Katholieke Universiteit Leuven COSIC Katholieke Universiteit Leuven PATS Universiteit Antwerpen DESICS IMEC Sets up and maintains the network and takes care of the self-organizing and self-healing characteristics of the network. Exchanged control information in order to determine the forwarding rules, selected channels, transmit power, etc. Tries to optimize the network with intelligent power control and dynamic channel selection, but doesn't take the end-to-end QoS demands of the different running applications into account Each of the networks has its own distributed network control, and resides in each network node. Distributed network control A System Architecture for Wireless Building Automation Forwards data from the BMS to the end devices and vice versa over the different networks of this architecture: The Wireless Mesh Network (WMN). Uses a multi-channel IEEE a MAC. Requires a solid channel assignment algortithm, setting up fixed links with a few selected neighbours, creating a wireless switched ethernet. This allows the introduction of known and well tested ethernet concepts in the WMN domain. The Sensor and Actuator Network (SANET). Uses IEEE technology for the MAC layer. ZigBee doesn't support QoS and is not scalable enough for wireless building automation. Therefore, extra research is needed to solve these issues. The Wireless LAN (WLAN). Requires QoS-supprt, what could be implemented using the new IEEE e standard, or IEEE g extended with some QoS schemes. Network – data plane Monitors data from the end devices and takes the necessary actions. Consists of different applications for the management of heating, ventilation and airconditioning, fire detection, access control, video surveillance, tracking of persons and equipment, etc. For high bit rate data, the BMS - data plane will request connections to the connection management with specific quality parameters such as framerate and resolution. BMS – data plane Typical element management tasks: fault, configuration, performance, security and accounting management Capacity flow management tasks, processing connection requests from the connection management. Uses topology and network status information gathered from the distributed network control to determine the optimal way to route the connection. This optimal route for the connection takes the already established connections into account, thus realising bandwidth reservations. Network management Responsible for the configuration of the device settings, e.g. frame rate and resolution of a camera, polling interval of a temperature sensor, sensitivity of a smoke detector, etc. Typically, the device control isn't intelligent but just executes the commands given by the device management. The Intelligent video control however changes the camera settings in an autonomous way. It can change the resolution and frame rate as a result of intelligent algorithms running on the camera (e.g. taking type of content or energy constraints into account). Device control Low data rate devices such as sensors and actuators, equipped with a low-power RF module (e.g. IEEE ). High data rate devices such as cameras, speakers and video screens, equipped with a high data rate RF module (e.g. IEEE ). The end devices generally send their data to the BMS and vice versa, but some sensors may also send data directly to one or more actuators within the SANET, e.g. when the latency introduced when going through the BMS is too high. End device – data plane be Wim Vandenberghe, Benoît Latré, Filip De Greve, Pieter De Mil, Steven Van den Berghe, Kristof Lamont, Ingrid Moerman, Michiel Mertens, Jeroen Avonts, Chris Blondia, Guido Impens  Aggregates the application-level requirements coming from the BMS, and translates them into reservation requests for the network management and policy settings for the devices.  Keeps a centralized view on the traffic that has to run trough the network  Uses an interative process to find an intersection between the policies (e.g. minimum and maximum bandwidth) requested by the application, the settings of the devices and the connectivity in the network. Connection & device management