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Sgritta2017.h
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Sgritta2017.h
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/*
* stdp_connection.h
*
* This file is part of NEST.
*
* Copyright (C) 2004 The NEST Initiative
*
* NEST is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 2 of the License, or
* (at your option) any later version.
*
* NEST is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with NEST. If not, see <http://www.gnu.org/licenses/>.
*
*/
#ifndef SGRITTA2017_H
#define SGRITTA2017_H
// Hard-coded frequency limits
#define F_MIN 0.9
#define F_MAX 10.1
/*
Vasco Orza and Alberto Antonietti
Cerebellar MF-GrC Plasticity with STDP + Frequency dependency
*/
// C++ includes:
#include <cmath>
#include <algorithm>
#include <new>
#include <vector>
#include <fstream>
// Includes from nestkernel:
#include "common_synapse_properties.h"
#include "connection.h"
#include "connector_model.h"
#include "event.h"
// Includes from sli:
#include "dictdatum.h"
#include "dictutils.h"
std::ofstream amp_;
std::ofstream window_;
std::ofstream peak_;
std::ofstream stdp_changes_;
namespace mynest
{
// connections are templates of target identifier type (used for pointer /
// target index addressing) derived from generic connection template
template < typename targetidentifierT >
class Sgritta2017 : public nest::Connection< targetidentifierT >
{
public:
typedef nest::CommonSynapseProperties CommonPropertiesType;
typedef nest::Connection< targetidentifierT > ConnectionBase;
/**
* Default Constructor.
* Sets default values for all parameters. Needed by GenericConnectorModel.
*/
Sgritta2017();
/**
* Copy constructor.
* Needs to be defined properly in order for GenericConnector to work.
*/
Sgritta2017( const Sgritta2017& );
// Explicitly declare all methods inherited from the dependent base
// ConnectionBase. This avoids explicit name prefixes in all places these
// functions are used. Since ConnectionBase depends on the template parameter,
// they are not automatically found in the base class.
using ConnectionBase::get_delay_steps;
using ConnectionBase::get_delay;
using ConnectionBase::get_rport;
using ConnectionBase::get_target;
/**
* Get all properties of this connection and put them into a dictionary.
*/
void get_status( DictionaryDatum& d ) const;
/**
* Set properties of this connection from the values given in dictionary.
*/
void set_status( const DictionaryDatum& d, nest::ConnectorModel& cm );
/**
* Send an event to the receiver of this connection.
* \param e The event to send
* \param t_lastspike Point in time of last spike sent.
* \param cp common properties of all synapses (empty).
*/
void send( nest::Event& e,
nest::thread t,
const nest::CommonSynapseProperties& cp );
class ConnTestDummyNode : public nest::ConnTestDummyNodeBase
{
public:
// Ensure proper overriding of overloaded virtual functions.
// Return values from functions are ignored.
using nest::ConnTestDummyNodeBase::handles_test_event;
nest::port
handles_test_event( nest::SpikeEvent&, nest::rport )
{
return nest::invalid_port_;
}
};
void
check_connection( nest::Node& s,
nest::Node& t,
nest::rport receptor_type,
const CommonPropertiesType& )
{
ConnTestDummyNode dummy_target;
ConnectionBase::check_connection_( dummy_target, s, t, receptor_type );
t.register_stdp_connection( t_lastspike_ - get_delay(), get_delay() );
}
void
set_weight( double w )
{
weight_ = w;
}
private:
double
CalculateMultiplier( double Fpeak )
{
double multiplier;
if ( Fpeak < F_MIN || Fpeak > F_MAX )
{
multiplier = 0;
}
if ( Fpeak <= 6 && Fpeak >= 1 )
{
multiplier = 0.308*Fpeak - 0.848;
}
if ( Fpeak > 6 && Fpeak <= 10 )
{
multiplier = -0.115 * Fpeak + 1.69;
}
return multiplier;
}
double
FindPeaks( double perc )
{
std::vector<double> DummyAmp;
std::vector<double>::iterator found;
std::vector<double>::iterator max;
double m;
int index_m;
int i = 0;
while ( Frequencies[ i ] < F_MAX )
{
DummyAmp.push_back( Amplitudes[ i ] );
i++;
}
max = std::max_element( DummyAmp.begin(), DummyAmp.end() );
m = *max;
found = std::find( DummyAmp.begin(), DummyAmp.end(), m );
index_m = distance( DummyAmp.begin(), found );
return Frequencies[ index_m ];
}
void
four1( void )
{
unsigned long n = 0, mmax = 0, m = 0, j = 0, istep = 0, i = 0;
double wtemp = 0.0, wr = 0.0, wpr = 0.0, wpi = 0.0, wi = 0.0, theta = 0.0;
double tempr = 0.0, tempi = 0.0;
// reverse-binary reindexing
n = W_int << 1;
j = 1;
for ( i = 1; i < n; i += 2 )
{
if ( j > i )
{
std::swap( Doppio[ j-1 ], Doppio[ i-1 ] );
std::swap( Doppio[ j ], Doppio[ i ] );
}
m = W_int;
while ( m >= 2 && j > m )
{
j -= m;
m >>= 1;
}
j += m;
}
// here begins the Danielson-Lanczos section
mmax=2;
while( n/2 > mmax )
{
istep = mmax << 1;
theta = -( 2 * M_PI / mmax );
wtemp = sin( 0.5 * theta );
wpr = -2.0 * wtemp * wtemp;
wpi = sin( theta );
wr = 1.0;
wi = 0.0;
for ( m = 1; m < mmax; m += 2 )
{
for ( i = m; i <= n; i += istep)
{
j = i + mmax;
tempr = wr * Doppio[ j-1 ] - wi * Doppio[ j ];
tempi = wr * Doppio[ j ] + wi * Doppio[ j-1 ];
Doppio[ j-1 ] = Doppio[ i-1 ] - tempr;
Doppio[ j ] = Doppio[ i ] - tempi;
Doppio[ i-1 ] += tempr;
Doppio[ i ] += tempi;
}
wtemp = wr;
wr += wr * wpr - wi * wpi;
wi += wi * wpr + wtemp * wpi;
}
mmax = istep;
}
}
void
CalculateA( void )
{
double sq_sum;
double sq_root;
int j = 0;
for ( int i = 0; i < W_int; i++ )
{
Amplitudes[ i ] = 0;
}
for ( int i = 0; i < W_int * 2; i = i + 2 )
{
sq_sum = std::pow( Doppio[ i ], 2) + std::pow(Doppio[ i + 1 ], 2 );
sq_root = std::sqrt(sq_sum);
Amplitudes[ j ] = sq_root;
j++;
}
for ( int i = 0; i < W_int; i++ )
{
if (Frequencies[ i ] < F_MIN || Frequencies[ i ] > F_MAX)
{
Amplitudes[ i ] = 0;
}
if ( p_ != 0.0 )
{
amp_ << Amplitudes [ i ] << " ";
}
}
if ( p_ != 0.0 )
{
amp_ << std::endl;
}
}
void
InstantFreq( double t2, double t1, int P, double A )
{
double b = resolution / 1000.0;
double dT = (t2 - t1) / 1000.0;
double div = resolution / 1000.0;
int len = (int)( dT/div + 0.5 );
if ( P + 1 < 0 || P + len >= W_int )
{
std::cout << " CHECK7 FAIL " << std::endl;
}
for ( int i = P + 1; i <= P + len; i++ )
{
Window[ i ] = A * std::exp( -1.0 * b / 0.25 );
b = b + div;
}
Window[ P+len ] = Window[ P+len ] + 4.0;
if (p_ != 0 )
{
for (int i = 0; i < W_int; i++ )
{
window_ << Window[ i ] << " ";
}
window_ << std::endl;
}
}
void
MoveWindow( double dT, double posOld, int flagM )
{
if ( flagM == 1 || posOld >= W_int )
{
posOld = W_int - 1;
}
int step = dT - ( ( W_int - 1 ) - posOld );
if (step<0 || posOld>=W_int)
{
std::cout << " CHECK6 FAIL " << " " << step << " " << posOld <<std::endl;
}
for ( int i = step; i <= posOld; i++ )
{
Window[ i - step ] = Window[ i ];
}
}
void
Inizializza(void)
{
double b = 0.0;
double stepFreq;
stepFreq = ( 1000.0 / resolution ) / W_int;
for ( int i = 0; i < W_int; i++ )
{
Window.push_back( 0.0 );
Amplitudes.push_back( 0.0 );
Frequencies.push_back( b );
b = b + stepFreq;
}
}
void
Duplica( int flag )
{
int j = 0;
if ( flag == 0 )
{
for ( int i = 0; i < W_int * 2; i++ )
{
if ( i % 2 == 0 )
{
Doppio.push_back( Window[ j ] );
j++;
}
else if ( i % 2 != 0 )
{
Doppio.push_back(0.0);
}
}
}
if ( flag != 0 )
{
for (int i = 0; i < W_int * 2; i++ )
{
if ( i % 2 == 0 )
{
Doppio[ i ] = Window[ j ];
j++;
}
else if ( i % 2 != 0 )
{
Doppio[ i ] = 0.0;
}
}
}
}
double
calculate_k_( double dt )
{
double k = 2.0 * std::pow( sin( 2 * M_PI * dt * 0.01 ), 5 ) *
std::exp( -1 * std::abs( 0.0587701241739 *dt ) );
return k;
}
double
facilitate_( double w, double kplus, double scaleFactor, double Peak )
{
double norm_w = 0.0;
if ( Peak >= 1.0 && Peak <= 2.75 ) // Only LTD if Peak between 1 and 2.75 Hz
{
if ( w < 0 )
{
norm_w = -1*( std::abs( w ) - std::abs( w * alpha_ * kplus * scaleFactor ) );
}
else if ( w >= 0 )
{
norm_w = w - std::abs( w * alpha_ * kplus * scaleFactor );
}
}
else if ( Peak > 2.75 ) // Both LTP and LTD
{
if ( w < 0 )
{
norm_w = -1*( std::abs( w ) + ( w * alpha_ * kplus * scaleFactor ) );
}
else if ( w >= 0 )
{
norm_w = w + ( w * alpha_ * kplus * scaleFactor );
}
}
else
{
return w;
}
return norm_w;
}
// data members of each connection
double weight_;
double tau_plus_;
double lambda_;
double alpha_;
long mu_plus_; // Size of the moving windows (in seconds)
double mu_minus_;
double Wmax_;
double Kplus_;
double Wmin_;
int p;
double dtp_;
double dtn_;
double t_old;
double alpha = 0;
int flag = 0;
int flagMove = 0;
int move;
int posF;
int pos;
int pos_old = 0;
double deltaT;
int W;
int W_int;
double resolution = nest::Time::get_resolution().get_ms();
std::vector<double> Window;
std::vector<double> Frequencies;
std::vector<double> Doppio;
std::vector<double> Amplitudes;
double t_lastspike_;
double p_; // flag, set to 1.0 only for debugging
};
/**
* Send an event to the receiver of this connection.
* \param e The event to send
* \param t The thread on which this connection is stored.
* \param t_lastspike_ Time point of last spike emitted
* \param cp Common properties object, containing the stdp parameters.
*/
template < typename targetidentifierT >
inline void
Sgritta2017< targetidentifierT >::send( nest::Event& e,
nest::thread t,
const nest::CommonSynapseProperties& )
{
double t_spike = e.get_stamp().get_ms();
// use accessor functions (inherited from Connection< >) to obtain delay and
// target
nest::Node* target = get_target( t );
double dendritic_delay = get_delay();
// get spike history in relevant range (t1, t2 ] from post-synaptic neuron
std::deque< nest::histentry >::iterator start;
std::deque< nest::histentry >::iterator finish;
target->get_history(
t_lastspike_ - dendritic_delay, t_spike - dendritic_delay, &start, &finish );
W = mu_plus_;
W_int = (int) ( ( W * 1000 ) / resolution + 0.5 );
posF = (int) ( t_spike / resolution + 0.5 );
deltaT = (int)( ( t_spike - t_old ) / resolution + 0.5 );
// After the first pre-synaptic spike
if (flag == 0)
{
Inizializza();
posF = posF % W_int;
if (posF < 0 || posF >= W_int )
{
std::cout << " CHECK1 FAIL " << std::endl;
}
Window[ posF ] = 4.0;
flag = 1;
}
// The instantaneous frequency buffer is being filled
else if ( pos_old + deltaT < W_int && flag != 0 )
{
if ( pos_old < 0 || pos_old >= W_int )
{
std::cout << " CHECK4 FAIL " << std::endl;
}
InstantFreq( t_spike, t_old, pos_old, Window[ pos_old ] );
}
else if ( pos_old + deltaT >= W_int && flag != 0 && deltaT < W_int )
{
MoveWindow(deltaT, pos_old, flagMove);
if ( flagMove != 0 )
{
pos = W_int - 1 - deltaT;
if ( pos < 0 || pos >= W_int )
{
std::cout << " CHECK2 FAIL " << std::endl;
}
InstantFreq( t_spike, t_old, pos, Window[ pos ] );
Duplica( flagMove );
four1();
CalculateA();
if ( t == 0 && p_ != 0.0 )
{
peak_ << FindPeaks( mu_minus_ ) << "\t";
}
}
else if ( flagMove == 0 )
{
p = deltaT - ( ( W_int - 1 ) - pos_old );
pos = pos_old - p;
if ( pos < 0 || pos >= W_int )
{
std::cout << " CHECK3 FAIL " << pos << std::endl;
}
InstantFreq( t_spike, t_old, pos, Window[ pos ]);
Duplica( flagMove );
four1();
CalculateA();
flagMove = 1;
if ( t == 0 && p_ != 0.0 )
{
peak_ << FindPeaks( mu_minus_ ) << "\t";
}
}
}
t_old = t_spike;
pos_old = posF;
while ( start != finish )
{
// Delta_t > 0 - causal spikes (pre-synaptic spike -> post-synaptic spike)
double peak = FindPeaks( mu_minus_ );
dtp_ = ( start ->t_ ) - t_lastspike_; // DeltaT = T_post - T_pre
Kplus_ = calculate_k_( dtp_ );
alpha = CalculateMultiplier( peak );
double weight_pre = weight_;
weight_ = facilitate_( weight_, Kplus_, alpha, peak );
if ( p_ != 0.0 )
{
stdp_changes_ << ( start ->t_ ) << " " << dtp_ << " " << Kplus_ << " " << alpha << " " << peak << " " << weight_-weight_pre << std::endl;
}
// Delta_t < 0 anti-causal spikes (post-synaptic spike -> pre-synaptic spike)
dtn_ = ( start ->t_ ) - t_spike; // DeltaT = T_post - T_pre
Kplus_ = calculate_k_( dtn_ );
weight_pre = weight_;
weight_ = facilitate_( weight_, Kplus_, alpha, peak );
if ( p_ != 0.0 )
{
stdp_changes_ << ( start ->t_ ) << " " << dtn_ << " " << Kplus_ << " " << alpha << " " << peak << " " << weight_-weight_pre << std::endl;
}
++start;
}
e.set_receiver( *target );
if ( weight_ < Wmin_ )
{
weight_ = Wmin_;
}
if ( weight_ > Wmax_ )
{
weight_ = Wmax_;
}
e.set_weight( weight_ );
// use accessor functions (inherited from Connection< >) to obtain delay in
// steps and rport
e.set_delay_steps( get_delay_steps() );
e.set_rport( get_rport() );
e();
t_lastspike_ = t_spike;
}
template < typename targetidentifierT >
Sgritta2017< targetidentifierT >::Sgritta2017()
: ConnectionBase()
, weight_( 1.0 )
, tau_plus_( 20.0 )
, lambda_( 0.01 )
, alpha_( 1.0 )
, mu_plus_( 1 )
, mu_minus_( 1.0 )
, Wmax_( 100.0 )
, Kplus_( 0.0 )
, Wmin_(-100.0)
, t_lastspike_( 0.0 )
, p_( 0.0 )
{
}
template < typename targetidentifierT >
Sgritta2017< targetidentifierT >::Sgritta2017(
const Sgritta2017< targetidentifierT >& rhs )
: ConnectionBase( rhs )
, weight_( rhs.weight_ )
, tau_plus_( rhs.tau_plus_ )
, lambda_( rhs.lambda_ )
, alpha_( rhs.alpha_ )
, mu_plus_( rhs.mu_plus_ )
, mu_minus_( rhs.mu_minus_ )
, Wmax_( rhs.Wmax_ )
, Kplus_( rhs.Kplus_ )
, Wmin_( rhs.Wmin_ )
, t_lastspike_( rhs.t_lastspike_ )
, p_( rhs.p_ )
{
}
template < typename targetidentifierT >
void
Sgritta2017< targetidentifierT >::get_status( DictionaryDatum& d ) const
{
ConnectionBase::get_status( d );
def< double >( d, nest::names::weight, weight_ );
def< double >( d, nest::names::tau_plus, tau_plus_ );
def< double >( d, nest::names::lambda, lambda_ );
def< double >( d, nest::names::alpha, alpha_ );
def< long >( d, nest::names::mu_plus, mu_plus_ );
def< double >( d, nest::names::mu_minus, mu_minus_ );
def< double >( d, nest::names::Wmax, Wmax_ );
def< double >( d, nest::names::Wmin, Wmin_ );
def< long >( d, nest::names::size_of, sizeof( *this ) );
def< double >( d, nest::names::P, p_ );
}
template < typename targetidentifierT >
void
Sgritta2017< targetidentifierT >::set_status( const DictionaryDatum& d,
nest::ConnectorModel& cm )
{
ConnectionBase::set_status( d, cm );
updateValue< double >( d, nest::names::weight, weight_ );
updateValue< double >( d, nest::names::tau_plus, tau_plus_ );
updateValue< double >( d, nest::names::lambda, lambda_ );
updateValue< double >( d, nest::names::alpha, alpha_ );
updateValue< long >( d, nest::names::mu_plus, mu_plus_ );
updateValue< double >( d, nest::names::mu_minus, mu_minus_ );
updateValue< double >( d, nest::names::Wmax, Wmax_ );
updateValue< double >( d, nest::names::Wmin, Wmin_ );
updateValue< double >( d, nest::names::P, p_ );
// only one synapse can write to file
if ( p_ != 0.0 )
{
std::cout << "WARNING! Sgritta synapse is writing to a file! " << std::endl;
window_.open( "window.dat" );
amp_.open( "amp.dat" );
peak_.open( "peak.dat" );
stdp_changes_.open( "stdp_changes.dat" );
}
// check if weight_ and Wmax_ has the same sign
if ( not( ( ( weight_ >= 0 ) - ( weight_ < 0 ) )
== ( ( Wmax_ >= 0 ) - ( Wmax_ < 0 ) ) ) )
{
throw nest::BadProperty( "Weight and Wmax must have the same sign." );
}
}
} // of namespace nest
#endif // of #ifndef SGRITTA2017_