Difference between revisions of "WCPS: Wireless Cyber-Physical Simulator"
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The following tutorial introduces in detail how to configure general MATLAB, TinyOS, and PYTHON environments, as well as the WCPS framework. The tutorial herein is an end-user version specifically for end-users that do not do much development but instead trying to do wireless control simulations with Simulink, TOSSIM and WCPS. An advanced tutorial on in-depth TinyOS development (e.g., routing protoocls, MAC layer development) with WCPS can be found [here]. | The following tutorial introduces in detail how to configure general MATLAB, TinyOS, and PYTHON environments, as well as the WCPS framework. The tutorial herein is an end-user version specifically for end-users that do not do much development but instead trying to do wireless control simulations with Simulink, TOSSIM and WCPS. An advanced tutorial on in-depth TinyOS development (e.g., routing protoocls, MAC layer development) with WCPS can be found [here]. | ||
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+ | == Live Demonstration == | ||
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+ | == Get Support == | ||
==Software Environment Setup== | ==Software Environment Setup== |
Revision as of 15:31, 14 March 2013
This page is under construction and thus incomplete, please contact boli@seas.wustl.edu before using materials below.
End-user's Tutorial on using WCPS: Wireless Cyber-Physical Simulator
Normal User Tutorial on the Wireless Cyber-Physical Simulator(WCPS) WCPS is design for, but not limited to, realistic Wireless Structural Control simulations. The layered infrastructure and efficient integration of state-of-the-art control and wireless networking tools, i.e., Simulink and TOSSIM, have made WCPS an ideal choice for general wireless control simulations with Simulink and TOSSIM.
The following tutorial introduces in detail how to configure general MATLAB, TinyOS, and PYTHON environments, as well as the WCPS framework. The tutorial herein is an end-user version specifically for end-users that do not do much development but instead trying to do wireless control simulations with Simulink, TOSSIM and WCPS. An advanced tutorial on in-depth TinyOS development (e.g., routing protoocls, MAC layer development) with WCPS can be found [here].
Contents
Live Demonstration
Change Log
Get Support
Software Environment Setup
Install TinyOS
WCPS is implemented and tested on MacOS X (snowleopard), Windows XP, and Windows 7.
Current release of WCPS is under TinyOS 2.1.1, which can be installed following the three methods.
- (1) Follow the TinyOS official tutorial on installation of TinyOS for your specific platform: Link
- (2) Directly download the pre-tested TinyOS 2.1.1 image from here: [under construction Cygwin] [under construction Mac OS X]
Install Mac Layer Architecture(MLA)
Follow the instructions here: Install MLA.
Install MATLAB and Simulink
If you already have MATLAB MATLAB 7.11.0.584 (2010b) or later version, skip this step. Otherwise, follow the tutorial here: install MATLAB
Install Python
If you already have Python 2.7.2 or later version installed, skip this step. Otherwise, follow the manual here: install Python
Environment Setup Testing
To test if TinyOS, Python and WCPS were configured correctly, pleas read ahead and do the following example.
Building a 5-node Network in TOSSIM
Makefile
"Makefile" takes advantage of the fact that it's not necessary to recompile all the project files that has not been changed. To have the "Makefile" for our project, copy the code below into a txt file and save as "Makefile" without any suffix.
# target file COMPONENT=TestNetworkAppC # dependencies of the target include $(UPMA_DIR)/Makefile.include BUILD_EXTRA_DEPS = TestNetworkMsg.py CFLAGS += -DTOSH_DATA_LENGTH=156 CFLAGS += -I$(TOSDIR)/lib/T2Hack PFLAGS += -I../../../pure-tdma CFLAGS += -I$(TOSDIR)/lib/printf CFLAGS += -DFOOTER_SIZE=0 -DTDMA -DUPMA #TDMA mac layer UPMA_MAC = pure-tdma #mig information for python TestNetworkMsg.py: TestNetwork.h mig python -target=$(PLATFORM) $(CFLAGS) -python-classname=TestNetworkMsg TestNetwork.h TestNetworkMsg -o $@ CLEAN_EXTRA = TestNetworkMsg.py TestNetworkMsg.class TestNetworkMsg.java TestNetworkMsg.pyc include $(MAKERULES) migclean: rm -rf $(MIGFILES)
TestNetwork.h
"TestNetwork.h" defines necessary message structures for the wireless communication. Copy the code below into a txt file and save as "TestNetwork.h".
#ifndef TEST_NETWORK_C_H #define TEST_NETWORK_C_H enum { AM_TESTNETWORKMSG = 0x05, AM_TESTNETWORKMSGG = 0x06, SAMPLE_RATE_KEY = 0x1, CL_TEST = 0xee, TEST_NETWORK_QUEUE_SIZE = 8, }; #endif
TestNetworkAppC.nc
"TestNetworkAppC.nc" connects claimed application interfaces to interfaces that are defined in the hardware librare. Copy the code below into a txt file and save as "TestNetworkAppC.nc".
#include "TestNetwork.h" configuration TestNetworkAppC { } implementation { components TestNetworkC, MainC, ActiveMessageC; components new AMSenderC(AM_TESTNETWORKMSG) as Sender; components new AMReceiverC(AM_TESTNETWORKMSG) as Receiver; components new AMReceiverC(AM_TESTNETWORKMSG) as AMReceiver; components new TimerMilliC() as InjectionTimer; components SerialActiveMessageC as SerialAM; TestNetworkC.RadioControl -> SerialAM; TestNetworkC.SerialReceive -> SerialAM.Receive[AM_TESTNETWORKMSG]; TestNetworkC.SerialSend -> SerialAM.AMSend[AM_TESTNETWORKMSG]; TestNetworkC.Boot -> MainC; TestNetworkC.RadioControl -> ActiveMessageC; TestNetworkC.Send -> Sender; TestNetworkC.Receive -> Receiver; TestNetworkC.AMReceive -> AMReceiver; TestNetworkC.InjectionTimer -> InjectionTimer; }
TestNetworkC.nc
"TestNetworkC.nc" Implements send/receive functionality of a wireless node. Copy the code below into a txt file and save as "TestNetworkC.nc".
#include <Timer.h> #include "TestNetwork.h" module TestNetworkC { uses interface Boot; uses interface SplitControl as RadioControl; uses interface StdControl as RoutingControl; uses interface AMSend as Send; uses interface Receive; uses interface Receive as AMReceive; uses interface Timer<TMilli> as InjectionTimer; uses interface Receive as SerialReceive; uses interface AMSend as SerialSend; } implementation { message_t packet; TestNetworkMsg* rcm; TestNetworkMsg* msgamr; uint8_t msglen; enum { RECEIVER=0, }; event void Boot.booted() { call RadioControl.start(); } event void RadioControl.startDone(error_t err) { if (err != SUCCESS) { call RadioControl.start(); } else { } } void failedSend() { dbg("App", "%s: Send failed.\n", __FUNCTION__); } event void Send.sendDone(message_t* m, error_t err) { if (err != SUCCESS) { } dbg("TestNetworkC", "Send completed.\n"); } uint8_t prevSeq = 0; uint8_t firstMsg = 0; event message_t* Receive.receive(message_t* msg, void* payload, uint8_t len) { rcmr = (TestNetworkMsg*)payload; if (TOS_NODE_ID % 500 == 0){ if (rcmr->data1==1) { printf("%u %u %u \n", rcmr->data2, 2, rcmr->data1); } else{ //printf("This is sensor %d\n", TOS_NODE_ID); } } if (TOS_NODE_ID % 500 == 3){ call Send.send(0, rcm, sizeof(TestNetworkMsg)); } return msg; } event message_t* AMReceive.receive(message_t* bufPtr, void* payload, uint8_t len) { rcm = (TestNetworkMsg*)payload; msgamr = (TestNetworkMsg*)call Send.getPayload(&packet, sizeof(TestNetworkMsg)); if (msgamr == NULL) { return; } memcpy(msgamr, rcm, sizeof(TestNetworkMsg)); if (len != sizeof(TestNetworkMsg)) { return bufPtr; } if (TOS_NODE_ID!=0){ if (TOS_NODE_ID % 500 == 1){ if (call Send.send(3, &packet, sizeof(TestNetworkMsg)) != SUCCESS) { failedSend(); }else { } }else if (TOS_NODE_ID % 500 !=0 && TOS_NODE_ID % 500 != 1){ if (call Send.send(0, &packet, sizeof(TestNetworkMsg)) != SUCCESS) { failedSend(); }else { } } } return bufPtr; } event void InjectionTimer.fired(){} event void RadioControl.stopDone(error_t err) {} void sendMessage() {} event void SerialSend.sendDone(message_t* m, error_t err) {} event message_t* SerialReceive.receive(message_t* msg, void* payload, uint8_t len) { return msg; } }
tossim-call.py
"tossim-call.py" configures TOSSIM network and does packet injection into the Tossim network. Copy the code below into a txt file and save as "tossim-call.py".
from TOSSIM import Tossim from random import * from TestNetworkMsg import * import sys def main(): sensor_num_mn=sys.argv[1] sensor_data_mn=sys.argv[2] cm_code=sys.argv[3] return {'y0':sensor_num_mn,'y1':sensor_data_mn,'y2':cm_code} sensor_num=int(main()['y0']) sensor_data=main()['y1'] cmmd_code=main()['y2'] t = Tossim([]) r = t.radio() L_topo=[0, 1, 2, 3, 4]; L=list() lines=sensor_data #channel 26 f = open("topo_building_all_channel_26-1000.txt", "r") lines = f.readlines() for line in lines: s = line.split() if (len(s) > 0): r.add(int(s[0]), int(s[1]), float(s[2])) for i in L_topo: i_int=int(i) m = t.getNode(i_int); if (i_int==1): noise_flr = open("Noise-floor-channel26-1-1000.txt", "r") elif(i_int==2): noise_flr = open("Noise-floor-channel26-2-1000.txt", "r") elif(i_int==3): noise_flr = open("Noise-floor-channel26-3-1000.txt", "r") elif(i_int==4): noise_flr = open("Noise-floor-channel26-4-1000.txt", "r") elif(i_int==0): noise_flr = open("Noise-floor-channel26-4-1000.txt", "r") lines_noise = noise_flr.readlines() for line_noise in lines_noise: strrr = line_noise.strip() if (strrr != ""): val = int(strrr) m = t.getNode(i_int); m.addNoiseTraceReading(val) m.createNoiseModel(); m.turnOn() m.bootAtTime(0) msg = TestNetworkMsg() ii=1; for i in range(4, 0, -1): #for k in range(1,round_remainder/sensor_num+1): # mycode = "msg.set_data"+str(k)+"("+str(L[(i-1)*(round_remainder/sensor_num)+k-1])+")" # print mycode # exec mycode node=i msg.set_data1(node) msg.set_data2(1) pkt = t.newPacket(); pkt.setData(msg.data) pkt.setType(msg.get_amType()) pkt.setSource(node); pkt.setDestination(node) tm=2000000000+(ii)*100000000 pkt.deliver(node, t.time()+tm) #print "At injectTime: "+str(float((float)(t.time()+tm)/10000000000.0))+" we inject packet to "+str(node); ii=ii+1; t.addChannel('printf', sys.stdout) t.addChannel("DataFeedback", sys.stdout) while (t.time() < 10000000000): t.runNextEvent() #print "Completed simulation at" +str(float(t.time())/10000000000)
=== Make ===
Put all the above files into the same folder, prompt a terminal (or a Cygwin window), and: 1. In the terminal, Make micaz sim and hit return 2. In the terminal ./tossim-call.py
Wireless traces
To run the network simulation above, we need wireless RSSI (strength of the wireless communication signal) and wireless Noise for Tossim to build Signal to Noise Ratio (SNR) model. Two options to do are:
1) Use the provided RSSI and noise traces for test purposes.
2) Use the code [rssi.zip] to collect the RSSI values and use code [noise.zip] to collect the wireless noise traces.
Test run
And you are ready to go for the wireless network setup.
WCPS Principles
Integrated Simulation with WCPS
Realistic Case Studies of Wireless Structural Control WCPS Software Version 0.1. WSC Examples from a structural perspective.
References
- B. Li, Z. Sun, K. Mechitov, G. Hackmann, C. Lu, S. Dyke, G. Agha and B. Spencer, "Realistic Case Studies of Wireless Structural Control," ACM/IEEE International Conference on Cyber-Physical Systems (ICCPS'13), April 2013.
- Z. Sun, B. Li, D. Dyke, and C. Lu. "A novel data utilization and control strategy for wireless structural control systems with tdma network," In Proc. ASCE IWCCE 2013.
- Z. Sun, B. Li, S.J. Dyke and C. Lu, "Evaluation of Performances of Structural Control Benchmark Problem with Time Delays from Wireless Sensor Network," Joint Conference of the Engineering Mechanics Institute and ASCE Joint Specialty Conference on Probabilistic Mechanics and Structural Reliability (EMI/PMC'12), June 2012.
- H. Lee, A. Cerpa, and P. Levis. Improving wireless simulation through noise modeling. In IPSN, 2007.
- P. Levis, N. Lee, M. Welsh, and D. Culler. Tossim: Accurate and scalable simulation of entire tinyos applications. In Sensys, 2003.
Contact us
- TinyOS and TOSSIM: Bo Li: boli@seas.wustl.edu
- Simulink Models: Zhuoxiong Sun: SUN152@purdue.edu