d4/d6f/_m_s_c_f_model___smart_s_k_8cpp_source.html

 /****************************************************************************/

 // Eclipse SUMO, Simulation of Urban MObility; see https://eclipse.dev/sumo

 // Copyright (C) 2012-2024 German Aerospace Center (DLR) and others.

 // This program and the accompanying materials are made available under the

 // terms of the Eclipse Public License 2.0 which is available at

 // https://www.eclipse.org/legal/epl-2.0/

 // This Source Code may also be made available under the following Secondary

 // Licenses when the conditions for such availability set forth in the Eclipse

 // Public License 2.0 are satisfied: GNU General Public License, version 2

 // or later which is available at

 // https://www.gnu.org/licenses/old-licenses/gpl-2.0-standalone.html

 // SPDX-License-Identifier: EPL-2.0 OR GPL-2.0-or-later

 /****************************************************************************/

 // A smarter SK

 /****************************************************************************/

 #include <config.h>


 #include <map>

 #include <microsim/MSVehicle.h>

 #include <microsim/MSLane.h>

 #include "MSCFModel_SmartSK.h"

 #include <microsim/lcmodels/MSAbstractLaneChangeModel.h>

 #include <utils/common/RandHelper.h>


 //#define SmartSK_DEBUG


 // ===========================================================================

 // method definitions

 // ===========================================================================

 MSCFModel_SmartSK::MSCFModel_SmartSK(const MSVehicleType* vtype) :

 // check whether setting these variables here with default values is ''good'' SUMO design

 //        double tmp1=0.0, double tmp2=5.0, double tmp3=0.0, double tmp4, double tmp5)

     MSCFModel(vtype),

     myDawdle(vtype->getParameter().getCFParam(SUMO_ATTR_SIGMA, SUMOVTypeParameter::getDefaultImperfection(vtype->getParameter().vehicleClass))),

     myTauDecel(myDecel * myHeadwayTime),

     myTmp1(vtype->getParameter().getCFParam(SUMO_ATTR_TMP1, 1.0)),

     myTmp2(vtype->getParameter().getCFParam(SUMO_ATTR_TMP2, 1.0)),

     myTmp3(vtype->getParameter().getCFParam(SUMO_ATTR_TMP3, 1.0)),

     myTmp4(vtype->getParameter().getCFParam(SUMO_ATTR_TMP4, 1.0)),

     myTmp5(vtype->getParameter().getCFParam(SUMO_ATTR_TMP5, 1.0)) {

     // the variable tmp1 is the acceleration delay time, e.g. two seconds (or something like this).

     // for use in the upate process, a rule like if (v<myTmp1) vsafe = 0; is needed.

     // To have this, we have to transform myTmp1 (which is a time) into an equivalent speed. This is done by the

     // using the vsafe formula and computing:

     // v(t=myTmp1) = -myTauDecel + sqrt(myTauDecel*myTauDecel + accel*(accel + decel)*t*t + accel*decel*t*TS);

     double t = myTmp1;

     myS2Sspeed = -myTauDecel + sqrt(myTauDecel * myTauDecel + myAccel * (myAccel + myDecel) * t * t + myAccel * myDecel * t * TS);

 #ifdef SmartSK_DEBUG

     std::cout << "# s2s-speed: " << myS2Sspeed << std::endl;

 #endif

     if (myS2Sspeed > 5.0) {

         myS2Sspeed = 5.0;

     }

 // double maxDeltaGap = -0.5*ACCEL2DIST(myDecel + myAccel);

     maxDeltaGap = -0.5 * (myDecel + myAccel) * TS * TS;

 #ifdef SmartSK_DEBUG

     std::cout << "# maxDeltaGap = " << maxDeltaGap << std::endl;

 #endif

     myTmp2 = TS / myTmp2;

     myTmp3 = sqrt(TS) * myTmp3;

 }


 MSCFModel_SmartSK::~MSCFModel_SmartSK() {}


 double

 MSCFModel_SmartSK::finalizeSpeed(MSVehicle* const veh, double vPos) const {

     const double vNext = MSCFModel::finalizeSpeed(veh, vPos);

     updateMyHeadway(veh);

     SSKVehicleVariables* vars = (SSKVehicleVariables*)veh->getCarFollowVariables();

 #ifdef SmartSK_DEBUG

     if (vars->ggOld.size() > 1) {

         std::cout << "# more than one entry in ggOld list. Speed is " << vPos << ", corresponding dist is " << vars->ggOld[(int) vPos] << "\n";

         for (std::map<int, double>::iterator I = vars->ggOld.begin(); I != vars->ggOld.end(); I++) {

             std::cout << "# " << (*I).first << ' ' << (*I).second << std::endl;

         }

     }

 #endif

     vars->gOld = vars->ggOld[(int) vPos];

     vars->ggOld.clear();

     return vNext;

 }


 double

 MSCFModel_SmartSK::followSpeed(const MSVehicle* const veh, double speed, double gap, double predSpeed, double /*predMaxDecel*/, const MSVehicle* const /*pred*/, const CalcReason /*usage*/) const {

     SSKVehicleVariables* vars = (SSKVehicleVariables*)veh->getCarFollowVariables();


 // if (((gap - vars->gOld) < maxDeltaGap) && (speed>=5.0) && gap>=5.0) {

     if ((gap - vars->gOld) < maxDeltaGap) {

         double tTauTest = gap / speed;

 // allow  headway only to decrease only, never to increase. Increase is handled automatically by the headway dynamics in finalizeSpeed()!!!

         if ((tTauTest < vars->myHeadway) && (tTauTest > TS)) {

             vars->myHeadway = tTauTest;

         }

     }


     double vsafe = _vsafe(veh, gap, predSpeed);

     if ((speed <= 0.0) && (vsafe < myS2Sspeed)) {

         vsafe = 0;

     }


     double vNew = MAX2(getSpeedAfterMaxDecel(speed), MIN2(vsafe, maxNextSpeed(speed, veh)));

     // there must be a better place to do the following assignment!!!

     vars->gOld = gap;

     vars->ggOld[(int)vNew] = gap;

     return vNew;

 }


 double

 MSCFModel_SmartSK::stopSpeed(const MSVehicle* const veh, const double speed, double gap, double /*decel*/, const CalcReason /*usage*/) const {

     SSKVehicleVariables* vars = (SSKVehicleVariables*)veh->getCarFollowVariables();


 // if (((gap - vars->gOld) < maxDeltaGap) && (speed>=5.0) && gap>=5.0) {

     if ((gap - vars->gOld) < maxDeltaGap) {

         double tTauTest = gap / speed;

 // allow  headway only to decrease only, never to increase. Increase is handled automatically by the headway dynamics in finalizeSpeed()!!!

         if ((tTauTest < vars->myHeadway) && (tTauTest > TS)) {

             vars->myHeadway = tTauTest;

         }

     }


     return MAX2(getSpeedAfterMaxDecel(speed), MIN2(_vsafe(veh, gap, 0), maxNextSpeed(speed, veh)));

 }


 double

 MSCFModel_SmartSK::patchSpeedBeforeLC(const MSVehicle* veh, double /*vMin*/, double /*vMax*/) const {

     return dawdle(veh->getSpeed(), veh->getRNG());

 }


 double

 MSCFModel_SmartSK::dawdle(double speed, SumoRNG* rng) const {

     return MAX2(0., speed - ACCEL2SPEED(myDawdle * myAccel * RandHelper::rand(rng)));

 }


 double MSCFModel_SmartSK::_vsafe(const MSVehicle* const veh, double gap, double predSpeed) const {

     if (predSpeed == 0 && gap < 0.01) {

         return 0;

     }

     SSKVehicleVariables* vars = (SSKVehicleVariables*)veh->getCarFollowVariables();

     // this is the most obvious change to the normal SK: the model uses the variable vars->myHeadway instead of the constant

     // myHeadwayTime as the "desired headway" tau

     double bTau = myDecel * (vars->myHeadway);

     double vsafe = (double)(-1. * bTau

                             + sqrt(

                                 bTau * bTau

                                 + (predSpeed * predSpeed)

                                 + (2. * myDecel * gap)

                             ));

     assert(vsafe >= 0);

     return vsafe;

 }


 MSCFModel*

 MSCFModel_SmartSK::duplicate(const MSVehicleType* vtype) const {

     return new MSCFModel_SmartSK(vtype);

 }

MSAbstractLaneChangeModel.h

MSCFModel_SmartSK.h

MSLane.h

MSVehicle.h

RandHelper.h

ACCEL2SPEED
#define ACCEL2SPEED(x)
Definition: SUMOTime.h:51

TS
#define TS
Definition: SUMOTime.h:42

SUMO_ATTR_TMP4
@ SUMO_ATTR_TMP4
Definition: SUMOXMLDefinitions.h:914

SUMO_ATTR_TMP3
@ SUMO_ATTR_TMP3
Definition: SUMOXMLDefinitions.h:913

SUMO_ATTR_TMP2
@ SUMO_ATTR_TMP2
Definition: SUMOXMLDefinitions.h:912

SUMO_ATTR_SIGMA
@ SUMO_ATTR_SIGMA
Definition: SUMOXMLDefinitions.h:907

SUMO_ATTR_TMP1
@ SUMO_ATTR_TMP1
Definition: SUMOXMLDefinitions.h:911

SUMO_ATTR_TMP5
@ SUMO_ATTR_TMP5
Definition: SUMOXMLDefinitions.h:915

MIN2
T MIN2(T a, T b)
Definition: StdDefs.h:76

MAX2
T MAX2(T a, T b)
Definition: StdDefs.h:82

MSBaseVehicle::getRNG
SumoRNG * getRNG() const
Definition: MSBaseVehicle.cpp:2305

MSCFModel_SmartSK::SSKVehicleVariables
Definition: MSCFModel_SmartSK.h:173

MSCFModel_SmartSK::SSKVehicleVariables::gOld
double gOld
Definition: MSCFModel_SmartSK.h:175

MSCFModel_SmartSK::SSKVehicleVariables::ggOld
std::map< int, double > ggOld
Definition: MSCFModel_SmartSK.h:176

MSCFModel_SmartSK::SSKVehicleVariables::myHeadway
double myHeadway
Definition: MSCFModel_SmartSK.h:175

MSCFModel_SmartSK::patchSpeedBeforeLC
double patchSpeedBeforeLC(const MSVehicle *veh, double vMin, double vMax) const
apply dawdling
Definition: MSCFModel_SmartSK.cpp:134

MSCFModel_SmartSK::myTauDecel
double myTauDecel
The precomputed value for myDecel*myTau.
Definition: MSCFModel_SmartSK.h:184

MSCFModel_SmartSK::myDawdle
double myDawdle
The vehicle's dawdle-parameter. 0 for no dawdling, 1 for max.
Definition: MSCFModel_SmartSK.h:181

MSCFModel_SmartSK::maxDeltaGap
double maxDeltaGap
Definition: MSCFModel_SmartSK.h:192

MSCFModel_SmartSK::_vsafe
virtual double _vsafe(const MSVehicle *const veh, double gap, double predSpeed) const
Returns the "safe" velocity.
Definition: MSCFModel_SmartSK.cpp:145

MSCFModel_SmartSK::duplicate
virtual MSCFModel * duplicate(const MSVehicleType *vtype) const
Duplicates the car-following model.
Definition: MSCFModel_SmartSK.cpp:165

MSCFModel_SmartSK::myTmp3
double myTmp3
Definition: MSCFModel_SmartSK.h:187

MSCFModel_SmartSK::followSpeed
virtual double followSpeed(const MSVehicle *const veh, double speed, double gap2pred, double predSpeed, double predMaxDecel, const MSVehicle *const pred=0, const CalcReason usage=CalcReason::CURRENT) const
Computes the vehicle's safe speed (no dawdling)
Definition: MSCFModel_SmartSK.cpp:93

MSCFModel_SmartSK::myS2Sspeed
double myS2Sspeed
new variables needed in this model; myS2Sspeed is the speed below which the vehicle does not move whe...
Definition: MSCFModel_SmartSK.h:192

MSCFModel_SmartSK::myTmp1
double myTmp1
temporary (testing) parameter
Definition: MSCFModel_SmartSK.h:187

MSCFModel_SmartSK::updateMyHeadway
virtual void updateMyHeadway(const MSVehicle *const veh) const
Definition: MSCFModel_SmartSK.h:152

MSCFModel_SmartSK::~MSCFModel_SmartSK
~MSCFModel_SmartSK()
Destructor.
Definition: MSCFModel_SmartSK.cpp:71

MSCFModel_SmartSK::MSCFModel_SmartSK
MSCFModel_SmartSK(const MSVehicleType *vtype)
Constructor.
Definition: MSCFModel_SmartSK.cpp:37

MSCFModel_SmartSK::myTmp2
double myTmp2
Definition: MSCFModel_SmartSK.h:187

MSCFModel_SmartSK::dawdle
virtual double dawdle(double speed, SumoRNG *rng) const
Applies driver imperfection (dawdling / sigma)
Definition: MSCFModel_SmartSK.cpp:139

MSCFModel_SmartSK::finalizeSpeed
double finalizeSpeed(MSVehicle *const veh, double vPos) const
Applies interaction with stops and lane changing model influences.
Definition: MSCFModel_SmartSK.cpp:75

MSCFModel_SmartSK::stopSpeed
virtual double stopSpeed(const MSVehicle *const veh, const double speed, double gap2pred, double decel, const CalcReason usage=CalcReason::CURRENT) const
Computes the vehicle's safe speed for approaching a non-moving obstacle (no dawdling)
Definition: MSCFModel_SmartSK.cpp:118

MSCFModel
The car-following model abstraction.
Definition: MSCFModel.h:55

MSCFModel::maxNextSpeed
virtual double maxNextSpeed(double speed, const MSVehicle *const veh) const
Returns the maximum speed given the current speed.
Definition: MSCFModel.cpp:292

MSCFModel::finalizeSpeed
virtual double finalizeSpeed(MSVehicle *const veh, double vPos) const
Applies interaction with stops and lane changing model influences. Called at most once per simulation...
Definition: MSCFModel.cpp:187

MSCFModel::CalcReason
CalcReason
What the return value of stop/follow/free-Speed is used for.
Definition: MSCFModel.h:77

MSCFModel::myDecel
double myDecel
The vehicle's maximum deceleration [m/s^2].
Definition: MSCFModel.h:701

MSCFModel::myAccel
double myAccel
The vehicle's maximum acceleration [m/s^2].
Definition: MSCFModel.h:698

MSCFModel::getSpeedAfterMaxDecel
virtual double getSpeedAfterMaxDecel(double v) const
Returns the velocity after maximum deceleration.
Definition: MSCFModel.h:403

MSVehicle
Representation of a vehicle in the micro simulation.
Definition: MSVehicle.h:77

MSVehicle::getCarFollowVariables
MSCFModel::VehicleVariables * getCarFollowVariables() const
Returns the vehicle's car following model variables.
Definition: MSVehicle.h:995

MSVehicle::getSpeed
double getSpeed() const
Returns the vehicle's current speed.
Definition: MSVehicle.h:493

MSVehicleType
The car-following model and parameter.
Definition: MSVehicleType.h:63

RandHelper::rand
static double rand(SumoRNG *rng=nullptr)
Returns a random real number in [0, 1)
Definition: RandHelper.cpp:94

SUMOVTypeParameter
Structure representing possible vehicle parameter.
Definition: SUMOVTypeParameter.h:121

SumoRNG
Definition: RandHelper.h:103