from ca.nengo.util import MU
from java.io import File
import math
nInput = range(200, 2001, 400)
nDiff = 1000;
networks = [interneuron, dualTC, adapting, depressing, butterworth, interneuronFeedback]
exporter = MatlabExporter()
for network in networks:
network.setInputFunction(ConstantFunction(1, 0));
network.setStepSize(.0001)
network.setMode(SimulationMode.DIRECT);
inputVariance = [];
outputVariance = [];
for n in nInput:
network.setNoise(n, nDiff);
#network.setDistortion(n, nDiff);
network.reset(0)
network.run(0, 10);
inputVariance.append(MU.variance(MU.prod(network.getInputEnsembleData().getValues(), [1]), 0))
outputVariance.append(MU.variance(MU.prod(network.getOutputData().getValues(), [1]), 0))
network.clearErrors();
Plotter.plot(nInput, outputVariance, "output")
exporter.write(File("noise.mat"));
componentRMS = math.sqrt(1.0 / len(frequencies)); signal = FourierFunction(frequencies, MU.uniform(1, len(frequencies), componentRMS/.707)[0], MU.random(1, len(frequencies), IndicatorPDF(-.5, .5))[0]) noiseBandwidth = 500 for network in networks: network.setMode(SimulationMode.DIRECT); network.setStepSize(.0005); signalPower = [] noisePower = [] for t in tau: network.setTau(t) network.setInputFunction(signal); network.clearErrors(); network.reset(0) network.run(0, 10) signalPower.append(MU.variance(MU.prod(network.getOutputData().getValues(), [1]), 0)) network.setInputFunction(ConstantFunction(1, 0)); network.setNoise(1000, 1000); network.reset(0) network.run(0, 10); network.clearErrors(); noisePower.append(MU.variance(MU.prod(network.getOutputData().getValues(), [1]), 0)) Plotter.plot(tau, signalPower, "%s signal power" %network.getName()); Plotter.plot(tau, noisePower, "%s noise power" %network.getName()); network.setStepSize(.001);
