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stdp_connection_sinexp.h
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stdp_connection_sinexp.h
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/*
* stdp_connection_sinexp.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/>.
*
*/
/*
Alberto Antonietti
Cerebellar PF-PC Plasticity with an exp. sin. Kernel LTP and LTD
*/
#ifndef STDP_CONNECTION_SINEXP_H
#define STDP_CONNECTION_SINEXP_H
/* BeginDocumentation
Name:
Description:
Examples:
Parameters:
vt long - ID of volume_transmitter collecting the spikes from the pool of
dopamine releasing neurons and transmitting the spikes
to the synapse. A value of -1 indicates that no volume
transmitter has been assigned.
Common properties:
A_plus double - Amplitude of weight change for facilitation
A_minus double - Amplitude of weight change for depression
Wmin double - Minimal synaptic weight
Wmax double - Maximal synaptic weight
*/
#include "connection.h"
#include "spikecounter.h"
#include "volume_transmitter_alberto.h"
#include "numerics.h"
#include <math.h>
#include "mynames.h"
namespace mynest
{
/**
* Class containing the common properties for all synapses of type dopamine connection.
*/
class STDPSinExpCommonProperties : public nest::CommonSynapseProperties
{
public:
/**
* Default constructor.
* Sets all property values to defaults.
*/
STDPSinExpCommonProperties();
void get_status( DictionaryDatum& d ) const;
void set_status( const DictionaryDatum& d, nest::ConnectorModel& cm );
long get_vt_gid() const;
double A_plus_;
double A_minus_;
double Wmin_;
double Wmax_;
volume_transmitter_alberto* vtC_;
};
inline long
STDPSinExpCommonProperties::get_vt_gid() const
{
if ( vtC_ != 0 )
{
return vtC_->get_gid();
}
else
{
return -1;
}
}
/**
* Class representing an STDPSinExpConnection with homogeneous parameters,
* i.e. parameters are the same for all synapses.
*/
template < typename targetidentifierT >
class STDPSinExpConnection : public nest::Connection< targetidentifierT >
{
public:
nest::Node* get_node();
long get_vt_gid() const;
volume_transmitter_alberto* vt_;
std::vector<double> SpikeBuffer_;
typedef STDPSinExpCommonProperties CommonPropertiesType;
typedef nest::Connection< targetidentifierT > ConnectionBase;
STDPSinExpConnection();
STDPSinExpConnection( const STDPSinExpConnection& );
// 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;
using ConnectionBase::get_delay_steps;
using ConnectionBase::get_rport;
using ConnectionBase::get_target;
void get_status( DictionaryDatum& d ) const;
void set_status( const DictionaryDatum& d, nest::ConnectorModel& cm );
void send( nest::Event& e, nest::thread t, const STDPSinExpCommonProperties& cp );
void trigger_update_weight( nest::thread t,
const std::vector< nest::spikecounter >& dopa_spikes, double t_trig, const STDPSinExpCommonProperties& 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_;
}
};
/*
* This function calls check_connection on the sender and checks if the receiver
* accepts the event type and receptor type requested by the sender.
* Node::check_connection() will either confirm the receiver port by returning
* true or false if the connection should be ignored.
* We have to override the base class' implementation, since for STDP
* connections we have to call register_stdp_pl_connection on the target neuron
* to inform the Archiver to collect spikes for this connection.
* Further, the STDP dopamine synapse requires a volume transmitter to be set before
* any simulation is performed. Checking this satisfies ticket #926.
*
* \param s The source node
* \param r The target node
* \param receptor_type The ID of the requested receptor type
* \param t_lastspike_ last spike produced by presynaptic neuron (in ms)
*/
void
check_connection( nest::Node& s,
nest::Node& t,
nest::rport receptor_type,
const CommonPropertiesType& cp )
{
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;
}
void set_vt_num( double n ){
vt_num_ = n;
}
void set_meta_l( double l ){
meta_l_ = l;
}
private:
// update dopamine trace from last to current dopamine spike and increment index
void update_dopamine_( const std::vector< nest::spikecounter >& dopa_spikes,const STDPSinExpCommonProperties& cp );
void update_weight_(double weight_change, const STDPSinExpCommonProperties& cp );
void process_dopa_spikes_( const std::vector< nest::spikecounter >& dopa_spikes, double t0, double t1, const STDPSinExpCommonProperties& cp );
// data members of each connection
double weight_;
// dopa_spikes_idx_ refers to the dopamine spike that has just been processes
// after trigger_update_weight a pseudo dopamine spike at t_trig is stored at index 0 and
// dopa_spike_idx_ = 0
nest::index dopa_spikes_idx_;
// time of last update, which is either time of last presyn. spike or time-driven update
double t_last_update_;
double vt_num_;
double meta_l_;
double t_lastspike_;
};
//
// Implementation of class STDPSinExpConnection.
//
template < typename targetidentifierT > STDPSinExpConnection< targetidentifierT >::STDPSinExpConnection()
: ConnectionBase()
, vt_ ( 0 )
, weight_( 1.0 )
, dopa_spikes_idx_( 0 )
, t_last_update_( 0.0 )
, vt_num_ ( 0.0 )
, meta_l_ ( 0.0 )
, t_lastspike_( 0.0 )
{
}
template < typename targetidentifierT > STDPSinExpConnection< targetidentifierT >::STDPSinExpConnection( const STDPSinExpConnection& rhs )
: ConnectionBase( rhs )
, vt_ ( rhs.vt_ )
, weight_( rhs.weight_ )
, dopa_spikes_idx_( rhs.dopa_spikes_idx_ )
, t_last_update_( rhs.t_last_update_ )
, vt_num_ ( rhs.vt_num_ )
, meta_l_ ( rhs.meta_l_ )
, t_lastspike_( rhs.t_lastspike_ )
{
}
template < typename targetidentifierT > void STDPSinExpConnection< targetidentifierT >::get_status( DictionaryDatum& d ) const{
// base class properties, different for individual synapse
ConnectionBase::get_status( d );
def< double >( d, nest::names::weight, weight_ );
def< double >( d, "vt_num", vt_num_ );
def< double >( d, "meta_l", meta_l_ );
if ( vt_ != 0 )
{
def< long >( d, "modulator", vt_->get_gid() );
}
else
{
def< long >( d, "modulator", -1 );
}
}
template < typename targetidentifierT >
long
STDPSinExpConnection< targetidentifierT >::get_vt_gid( ) const
{
if ( vt_ != 0 )
{
return vt_->get_gid();
}
else
{
return -1;
}
}
template < typename targetidentifierT >
void
STDPSinExpConnection< targetidentifierT >::set_status( const DictionaryDatum& d,
nest::ConnectorModel& cm )
{
// base class properties
ConnectionBase::set_status( d, cm );
updateValue< double >( d, nest::names::weight, weight_ );
updateValue< double >( d, "vt_num", vt_num_ );
updateValue< double >( d, "meta_l", meta_l_ );
long vtgid;
if ( updateValue< long >( d, nest::names::vt, vtgid ) )
{
vt_ = dynamic_cast< volume_transmitter_alberto* >( nest::kernel().node_manager.get_node( vtgid ) );
if ( vt_ == 0 )
{
throw nest::BadProperty( "vt needs to be a Volume Transmitter" );
}
}
}
template < typename targetidentifierT >
inline void
STDPSinExpConnection< targetidentifierT >::update_dopamine_(
const std::vector< nest::spikecounter >& dopa_spikes,
const STDPSinExpCommonProperties& cp )
{
// We enter here when there is a spike of the Volume Transmitter
double minus_dt = dopa_spikes[ dopa_spikes_idx_+1].spike_time_-1;
if ( SpikeBuffer_.size() > 0 )
{
double LTD_amount = 0.0;
for ( unsigned int GR = 0; GR < SpikeBuffer_.size(); GR++ )
{
double sd= SpikeBuffer_[ GR ] - minus_dt;
if ( sd < 0 && sd >= -200 )
{
LTD_amount += cp.A_minus_ * meta_l_ *
exp( -( sd - 150.0 ) / 1000.0 ) *
pow( ( sin( 2 * 3.1415 * ( sd - 150.0 ) / 1000.0 ) ), 20 ) / 1.2848;
}
}
update_weight_( LTD_amount, cp );
}
++dopa_spikes_idx_;
}
template < typename targetidentifierT >
inline void
STDPSinExpConnection< targetidentifierT >::update_weight_(double weight_change,
const STDPSinExpCommonProperties& cp )
{
// LTP or LTD, depending on who calls this function
weight_ = weight_+weight_change;
if ( weight_ < cp.Wmin_ )
{
weight_ = cp.Wmin_;
}
if ( weight_ > cp.Wmax_ )
{
weight_ = cp.Wmax_;
}
}
template < typename targetidentifierT >
inline void
STDPSinExpConnection< targetidentifierT >::process_dopa_spikes_(
const std::vector< nest::spikecounter >& dopa_spikes,
double t0,
double t1,
const STDPSinExpCommonProperties& cp )
{
// process dopa spikes in (t0, t1]
// propagate weight from t0 to t1
if ( ( dopa_spikes.size() > dopa_spikes_idx_ ) &&
( dopa_spikes[ dopa_spikes_idx_ ].spike_time_ <= t1 && dopa_spikes[ dopa_spikes_idx_+1 ].multiplicity_ == int (vt_num_ ) ) )
{
// A IO SPIKE IS DETECTED AT TIME T0, LTD happens with a different amplitude, it depends on the distance between IO SPIKE and PF spikes
update_dopamine_( dopa_spikes, cp );
}
}
/**
* Send an event to the receiver of this connection.
* \param e The event to send
* \param p The port under which this connection is stored in the Connector.
* \param t_lastspike Time point of last spike emitted
*/
template < typename targetidentifierT >
inline void
STDPSinExpConnection< targetidentifierT >::send( nest::Event& e,
nest::thread t,
const STDPSinExpCommonProperties& cp )
{
nest::Node* target = get_target( t );
double t_spike = e.get_stamp().get_ms();
// LTP (of a factor A_plus) due to new pre-synaptic spike
double t_spike_d = t_spike;
SpikeBuffer_.push_back( t_spike_d );
// vt_num control for NO-related enabling
if (int(vt_num_) > 0){
update_weight_( cp.A_plus_ * meta_l_, cp );
}
while( SpikeBuffer_[ 0 ] < t_spike - 200.0 )
{
SpikeBuffer_.erase( SpikeBuffer_.begin() );
}
e.set_receiver( *target );
e.set_weight( weight_ );
e.set_delay_steps( get_delay_steps() );
e.set_rport( get_rport() );
e();
t_last_update_ = t_spike;
t_lastspike_ = t_spike;
}
template < typename targetidentifierT >
inline void
STDPSinExpConnection< targetidentifierT >::trigger_update_weight(
nest::thread t,
const std::vector< nest::spikecounter >& dopa_spikes,
const double t_trig,
const STDPSinExpCommonProperties& cp )
{
int Vid_Check = cp.get_vt_gid();
if ( Vid_Check != get_vt_gid() )
{
return;
}
std::vector< nest::spikecounter > dopa_temp = dopa_spikes;
const std::vector< nest::spikecounter > dopa_temp2 = dopa_temp;
// purely dendritic delay
double dendritic_delay = get_delay();
// get spike history in relevant range (t_last_update, t_trig] from postsyn. neuron
std::deque< nest::histentry >::iterator start;
std::deque< nest::histentry >::iterator finish;
get_target( t )->get_history(t_last_update_ - dendritic_delay, t_trig - dendritic_delay, &start, &finish );
// facilitation due to postsyn. spikes since last update
double t0 = t_last_update_;
// propagate weight, eligibility trace c, dopamine trace n and facilitation trace K_plus to time
// t_trig
// but do not increment/decrement as there are no spikes to be handled at t_trig
process_dopa_spikes_( dopa_temp2, t0, t_trig, cp );
t_last_update_ = t_trig;
dopa_spikes_idx_ = 0;
}
template < typename targetidentifierT >
inline nest::Node*
STDPSinExpConnection< targetidentifierT >::get_node()
{
if ( vt_ == 0 )
{
throw nest::BadProperty( "No neuron has been assigned as the modulator of the synapse." );
}
else
{
return vt_;
}
}
} // of namespace mynest
#endif // of #ifndef STDP_CONNECTION_SINEXP_H