//Methods
/// <summary>
/// See the base.
/// </summary>
public override bool Equals(object obj)
{
if (obj == null)
{
return(false);
}
ISRUSettings cmpSettings = obj as ISRUSettings;
if (!Equals(Alpha, cmpSettings.Alpha))
{
return(false);
}
return(true);
}
/// <summary>
/// Creates an instance of the activation function according to given settings.
/// </summary>
/// <param name="settings">Specific activation function settings </param>
/// <param name="rand">Random object to be used for randomly generated parameters</param>
public static IActivationFunction Create(RCNetBaseSettings settings, Random rand)
{
IActivationFunction af;
Type settingsType = settings.GetType();
if (settingsType == typeof(AdExpIFSettings))
{
AdExpIFSettings afs = (AdExpIFSettings)settings;
af = new AdExpIF(rand.NextDouble(afs.TimeScale),
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.RheobaseV),
rand.NextDouble(afs.FiringThresholdV),
rand.NextDouble(afs.SharpnessDeltaT),
rand.NextDouble(afs.AdaptationVoltageCoupling),
rand.NextDouble(afs.AdaptationTimeConstant),
rand.NextDouble(afs.AdaptationSpikeTriggeredIncrement),
afs.SolverMethod,
afs.SolverCompSteps,
afs.StimuliDuration
);
}
else if (settingsType == typeof(BentIdentitySettings))
{
af = new BentIdentity();
}
else if (settingsType == typeof(ElliotSettings))
{
ElliotSettings afs = (ElliotSettings)settings;
af = new Elliot(rand.NextDouble(afs.Slope));
}
else if (settingsType == typeof(ExpIFSettings))
{
ExpIFSettings afs = (ExpIFSettings)settings;
af = new ExpIF(rand.NextDouble(afs.TimeScale),
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.RheobaseV),
rand.NextDouble(afs.FiringThresholdV),
rand.NextDouble(afs.SharpnessDeltaT),
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps,
afs.StimuliDuration
);
}
else if (settingsType == typeof(GaussianSettings))
{
af = new Gaussian();
}
else if (settingsType == typeof(IdentitySettings))
{
af = new Identity();
}
else if (settingsType == typeof(ISRUSettings))
{
ISRUSettings afs = (ISRUSettings)settings;
af = new ISRU(rand.NextDouble(afs.Alpha));
}
else if (settingsType == typeof(IzhikevichIFSettings))
{
IzhikevichIFSettings afs = (IzhikevichIFSettings)settings;
af = new IzhikevichIF(rand.NextDouble(afs.RecoveryTimeScale),
rand.NextDouble(afs.RecoverySensitivity),
rand.NextDouble(afs.RecoveryReset),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.FiringThresholdV),
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps,
afs.StimuliDuration
);
}
else if (settingsType == typeof(AutoIzhikevichIFSettings))
{
double randomValue = rand.NextDouble().Power(2);
AutoIzhikevichIFSettings afs = (AutoIzhikevichIFSettings)settings;
//Ranges
af = new IzhikevichIF(0.02,
0.2,
8 + (-6 * randomValue),
-70,
-65 + (15 * randomValue),
30,
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps,
afs.StimuliDuration
);
}
else if (settingsType == typeof(LeakyIFSettings))
{
LeakyIFSettings afs = (LeakyIFSettings)settings;
af = new LeakyIF(rand.NextDouble(afs.TimeScale),
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.FiringThresholdV),
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps,
afs.StimuliDuration
);
}
else if (settingsType == typeof(LeakyReLUSettings))
{
LeakyReLUSettings afs = (LeakyReLUSettings)settings;
af = new LeakyReLU(rand.NextDouble(afs.NegSlope));
}
else if (settingsType == typeof(SigmoidSettings))
{
af = new Sigmoid();
}
else if (settingsType == typeof(SimpleIFSettings))
{
SimpleIFSettings afs = (SimpleIFSettings)settings;
af = new SimpleIF(rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.DecayRate),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.FiringThresholdV),
afs.RefractoryPeriods
);
}
else if (settingsType == typeof(SincSettings))
{
af = new Sinc();
}
else if (settingsType == typeof(SinusoidSettings))
{
af = new Sinusoid();
}
else if (settingsType == typeof(SoftExponentialSettings))
{
SoftExponentialSettings afs = (SoftExponentialSettings)settings;
af = new SoftExponential(rand.NextDouble(afs.Alpha));
}
else if (settingsType == typeof(SoftPlusSettings))
{
af = new SoftPlus();
}
else if (settingsType == typeof(SQNLSettings))
{
af = new SQNL();
}
else if (settingsType == typeof(TanHSettings))
{
af = new TanH();
}
else
{
throw new ArgumentException($"Unsupported activation function settings: {settingsType.Name}");
}
//*
//Set random initial membrane potential for spiking activation
if (!af.Stateless && af.TypeOfActivation == ActivationType.Spiking)
{
af.SetInitialInternalState(rand.NextRangedUniformDouble(0.05, 0.95));
}
//*/
return(af);
}
/// <summary>
/// Copy constructor
/// </summary>
/// <param name="source">Source instance</param>
public ISRUSettings(ISRUSettings source)
{
Alpha = source.Alpha.DeepClone();
return;
}
/// <summary>
/// Creates the deep copy instance of this instance
/// </summary>
public ISRUSettings DeepClone()
{
ISRUSettings clone = new ISRUSettings(this);
return(clone);
}
/// <summary>
/// Creates an instance of the activation function according to given settings.
/// </summary>
/// <param name="settings">Specific activation function settings </param>
/// <param name="rand">Random object to be used for randomly generated parameters</param>
public static IActivationFunction Create(Object settings, Random rand)
{
Type settingsType = settings.GetType();
if (settingsType == typeof(AdExpIFSettings))
{
AdExpIFSettings afs = (AdExpIFSettings)settings;
return(new AdExpIF(afs.StimuliCoeff,
rand.NextDouble(afs.TimeScale),
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.RheobaseV),
rand.NextDouble(afs.FiringThresholdV),
rand.NextDouble(afs.SharpnessDeltaT),
rand.NextDouble(afs.AdaptationVoltageCoupling),
rand.NextDouble(afs.AdaptationTimeConstant),
rand.NextDouble(afs.AdaptationSpikeTriggeredIncrement),
afs.SolverMethod,
afs.SolverCompSteps
));
}
else if (settingsType == typeof(BentIdentitySettings))
{
return(new BentIdentity());
}
else if (settingsType == typeof(ElliotSettings))
{
ElliotSettings afs = (ElliotSettings)settings;
return(new Elliot(rand.NextDouble(afs.Slope)));
}
else if (settingsType == typeof(ExpIFSettings))
{
//return new ExpIF((ExpIFSettings)settings, rand);
ExpIFSettings afs = (ExpIFSettings)settings;
return(new ExpIF(afs.StimuliCoeff,
rand.NextDouble(afs.TimeScale),
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.RheobaseV),
rand.NextDouble(afs.FiringThresholdV),
rand.NextDouble(afs.SharpnessDeltaT),
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps
));
}
else if (settingsType == typeof(GaussianSettings))
{
return(new Gaussian());
}
else if (settingsType == typeof(IdentitySettings))
{
return(new Identity());
}
else if (settingsType == typeof(ISRUSettings))
{
ISRUSettings afs = (ISRUSettings)settings;
return(new ISRU(rand.NextDouble(afs.Alpha)));
}
else if (settingsType == typeof(IzhikevichIFSettings))
{
IzhikevichIFSettings afs = (IzhikevichIFSettings)settings;
return(new IzhikevichIF(afs.StimuliCoeff,
rand.NextDouble(afs.RecoveryTimeScale),
rand.NextDouble(afs.RecoverySensitivity),
rand.NextDouble(afs.RecoveryReset),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.FiringThresholdV),
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps
));
}
else if (settingsType == typeof(AutoIzhikevichIFSettings))
{
double randomValue = rand.NextBoundedUniformDouble(0, 1);
AutoIzhikevichIFSettings afs = (AutoIzhikevichIFSettings)settings;
if (afs.Role == CommonEnums.NeuronRole.Excitatory)
{
//Excitatory ranges
return(new IzhikevichIF(afs.StimuliCoeff,
0.02,
0.2,
8 + (-6 * randomValue.Power(2)),
-70,
-65 + (15 * randomValue.Power(2)),
30,
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps
));
}
else
{
//Inhibitory ranges
return(new IzhikevichIF(afs.StimuliCoeff,
0.02 + 0.08 * randomValue,
0.25 - 0.05 * randomValue,
2,
-70,
-65,
30,
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps
));
}
}
else if (settingsType == typeof(LeakyIFSettings))
{
LeakyIFSettings afs = (LeakyIFSettings)settings;
return(new LeakyIF(afs.StimuliCoeff,
rand.NextDouble(afs.TimeScale),
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.RestV),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.FiringThresholdV),
afs.RefractoryPeriods,
afs.SolverMethod,
afs.SolverCompSteps
));
}
else if (settingsType == typeof(LeakyReLUSettings))
{
LeakyReLUSettings afs = (LeakyReLUSettings)settings;
return(new LeakyReLU(rand.NextDouble(afs.NegSlope)));
}
else if (settingsType == typeof(SigmoidSettings))
{
return(new Sigmoid());
}
else if (settingsType == typeof(SimpleIFSettings))
{
SimpleIFSettings afs = (SimpleIFSettings)settings;
return(new SimpleIF(afs.StimuliCoeff,
rand.NextDouble(afs.Resistance),
rand.NextDouble(afs.DecayRate),
rand.NextDouble(afs.ResetV),
rand.NextDouble(afs.FiringThresholdV),
afs.RefractoryPeriods
));
}
else if (settingsType == typeof(SincSettings))
{
return(new Sinc());
}
else if (settingsType == typeof(SinusoidSettings))
{
return(new Sinusoid());
}
else if (settingsType == typeof(SoftExponentialSettings))
{
SoftExponentialSettings afs = (SoftExponentialSettings)settings;
return(new SoftExponential(rand.NextDouble(afs.Alpha)));
}
else if (settingsType == typeof(SoftPlusSettings))
{
return(new SoftPlus());
}
else if (settingsType == typeof(TanHSettings))
{
return(new TanH());
}
else
{
throw new ArgumentException($"Unsupported activation function settings: {settingsType.Name}");
}
}
/// <summary>
/// Copy constructor
/// </summary>
/// <param name="source">Source instance</param>
public ISRUSettings(ISRUSettings source)
{
Alpha = (URandomValueSettings)source.Alpha.DeepClone();
return;
}
