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Cupcarbon user guide CupCarbon User Guide Version U-One www cupcarbon com contact cupcarbon com Document version C C Introduction CupCarbon is a Smart City and Internet of Things Wireless Sensor Network SCI-WSN simulator Its objective is to design visuali

CupCarbon User Guide Version U-One www cupcarbon com contact cupcarbon com Document version C C Introduction CupCarbon is a Smart City and Internet of Things Wireless Sensor Network SCI-WSN simulator Its objective is to design visualize debug and validate distributed algorithms for monitoring environmental data collection etc and to create environmental scenarios such as ?res gas mobiles and generally within educational and scienti ?c projects Not only it can help to visually explain the basic concepts of sensor networks and how they work it may also support scientists to test their wireless topologies protocols etc CupCarbon o ?ers two simulation environments The ?rst simulation environment enables the design of mobility scenarios and the generation of natural events such as ?res and gas as well as the simulation of mobiles such as vehicles and ying objects e g UAVs insects etc The second simulation environment represents a discrete event simulation of wireless sensor networks which takes into account the scenario designed on the basis of the ?rst environment Networks can be designed and prototyped by an ergonomic and easy to use interface using the OpenStreetMap OSM framework to deploy sensors directly on the map It includes a script called SenScript which allows to program and to con ?gure each sensor node individually From this script it is also possible to generate codes for hardware platforms such as Arduino XBee This part is not fully implemented in CupCarbon it allows to generate codes for simple networks and algorithms CupCarbon simulation is based on the application layer of the nodes This makes it a real complement to existing simulators It does not simulate all protocol layers due to the complex nature of urban networks which need to incorporate other complex and resource consuming information such as buildings roads mobility signals etc CupCarbon o ?ers the possibility to simulate algorithms and scenarios in several steps For example there could be a step for determining the nodes of interest followed by a step related to the nature of the communication between these nodes to perform a given task such as the detection of an event and ?nally a step describing the nature of the routing to the base station in case that an event is detected The current version of CupCarbon allows to con ?gure the nodes dynamically in order to be able to split nodes into separate networks or to join di ?erent networks a task which is based on the network addresses and the channel The energy consumption can be calculated and displayed as a function of the simulated time This allows to clarify the structure feasibility and realistic implementation of a network before its real deployment The propagation visibility and the interference models are integrated and includes the ZigBee LoRa and WiFi protocols CupCarbon represents the main kernel of the ANR project PERSEPTEUR that aims to develop algorithms for an accurate simulation of the propagation and interference of signals in a D urban environment What ? s new Intelligent mobility which can