%description: This is a test for ideal radio interference handling. The first signal is stronger than the reception threshold. The second signal is weaker than the reception threshold. The second signal is too weak to cause bit errors. The first signal is expected to be received correctly. %file: test.ned import inet.networklayer.configurator.ipv4.IPv4NetworkConfigurator; import inet.node.inet.WirelessHost; import inet.physicallayer.idealradio.IdealRadioMedium; network Test { submodules: radioMedium: IdealRadioMedium; configurator: IPv4NetworkConfigurator; hostSender1: WirelessHost; hostSender2: WirelessHost; hostReceiver: WirelessHost; } %inifile: omnetpp.ini [General] network = Test sim-time-limit = 500us record-eventlog = true ned-path = .;../../../../src #omnetpp 5.0 - 5.1 compatibility: eventlog-file = "${resultdir}/${configname}-${runnumber}.elog" output-scalar-file = "${resultdir}/${configname}-${runnumber}.sca" output-vector-file = "${resultdir}/${configname}-${runnumber}.vec" snapshot-file = "${resultdir}/${configname}-${runnumber}.sna" **.arpType = "GlobalARP" **.mobility.constraintAreaMinZ = 0m **.mobility.constraintAreaMinX = 0m **.mobility.constraintAreaMinY = 0m **.mobility.constraintAreaMaxX = 1000m **.mobility.constraintAreaMaxY = 1000m **.mobility.constraintAreaMaxZ = 0m **.mobility.initFromDisplayString = false **.mobility.initialY = 500m **.mobility.initialZ = 0m *.host*.mobilityType = "StationaryMobility" *.hostSender1.mobility.initialX = 200m *.hostSender2.mobility.initialX = 800m *.hostReceiver.mobility.initialX = 400m # nic *.host*.wlan[*].typename = "IdealWirelessNic" *.host*.wlan[*].bitrate = 2Mbps *.host*.wlan[*].mac.headerLength = 10B *.host*.wlan[*].mac.fullDuplex = false *.host*.wlan[*].radioType = "IdealRadio" *.host*.wlan[*].radio.transmitter.bitrate = 2Mbps *.host*.wlan[*].radio.transmitter.preambleDuration = 0s *.host*.wlan[*].radio.transmitter.headerBitLength = 100b *.host*.wlan[*].radio.receiver.ignoreInterference = false *.hostSender1.wlan[*].radio.transmitter.communicationRange = 300m *.hostSender1.wlan[*].radio.transmitter.interferenceRange = 600m *.hostSender1.wlan[*].radio.transmitter.detectionRange = 1.2km *.hostSender2.wlan[*].radio.transmitter.communicationRange = 150m *.hostSender2.wlan[*].radio.transmitter.interferenceRange = 300m *.hostSender2.wlan[*].radio.transmitter.detectionRange = 600m *.hostReceiver.wlan[*].radio.transmitter.communicationRange = 0m *.hostReceiver.wlan[*].radio.transmitter.interferenceRange = 0m *.hostReceiver.wlan[*].radio.transmitter.detectionRange = 0m # ping app *.hostSender*.numPingApps = 1 *.hostSender*.pingApp[0].count = 1 *.hostSender*.pingApp[0].printPing = true *.hostSender*.pingApp[0].destAddr = "hostReceiver" *.hostSender*.pingApp[0].startTime = 0s %contains: results/General-0.elog Changing radio reception state from IDLE to RECEIVING. %contains: results/General-0.elog Passing up contained packet `ping0' to higher layer %contains: results/General-0.elog Sending datagram (inet::IPv4Datagram)ping0-reply with destination = 10.0.0.1 %#-------------------------------------------------------------------------------------------------------------- %not-contains: stdout undisposed object: %not-contains: stdout -- check module destructor %#--------------------------------------------------------------------------------------------------------------