Ejemplo n.º 1
0
 /// <summary>
 /// Constructor for the Electronegativity object.
 /// </summary>
 /// <param name="maxIterations">The maximal number of Iteration</param>
 /// <param name="maxResonStruc">The maximal number of Resonance Structures</param>
 public PiElectronegativity(int maxIterations, int maxResonStruc)
 {
     peoe                   = new GasteigerMarsiliPartialCharges();
     pepe                   = new GasteigerPEPEPartialCharges();
     MaxIterations          = maxIterations;
     MaxResonanceStructures = maxResonStruc;
 }
        public void TestSetStepSize()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();
            int StepSize = 22;

            peoe.StepSize = StepSize;
            Assert.AreEqual(StepSize, peoe.StepSize);
        }
        public void TestSetChiCatHydrogen_Double()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();
            double DEOC_HYDROGEN = 22;

            peoe.ChiCatHydrogen = DEOC_HYDROGEN;
            Assert.AreEqual(DEOC_HYDROGEN, peoe.ChiCatHydrogen, 0.01);
        }
        public void TestSetMaxGasteigerDamp_Double()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();
            double MX_DAMP = 1;

            peoe.MaxGasteigerDamp = MX_DAMP;
            Assert.AreEqual(MX_DAMP, peoe.MaxGasteigerDamp, 0.01);
        }
        public void TestSetMaxGasteigerIters_Double()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();
            double MX_ITERATIONS = 10;

            peoe.MaxGasteigerIterations = MX_ITERATIONS;
            Assert.AreEqual(MX_ITERATIONS, peoe.MaxGasteigerIterations, 0.01);
        }
Ejemplo n.º 6
0
        /// <summary>
        /// Calculate the electronegativity of orbitals pi.
        /// </summary>
        /// <param name="ac"></param>
        /// <param name="atom">atom for which effective atom electronegativity should be calculated</param>
        /// <param name="maxIterations">The maximal number of Iteration</param>
        /// <param name="maxResonStruc">The maximal number of Resonance Structures</param>
        /// <returns>Electronegativity of orbitals pi.</returns>
        public double CalculatePiElectronegativity(IAtomContainer ac, IAtom atom, int maxIterations, int maxResonStruc)
        {
            MaxIterations          = maxIterations;
            MaxResonanceStructures = maxResonStruc;

            double electronegativity = 0;

            try
            {
                if (!ac.Equals(acOldP))
                {
                    molPi = ac.Builder.NewAtomContainer(ac);

                    peoe = new GasteigerMarsiliPartialCharges();
                    peoe.AssignGasteigerMarsiliSigmaPartialCharges(molPi, true);
                    var iSet = ac.Builder.NewAtomContainerSet();
                    iSet.Add(molPi);
                    iSet.Add(molPi);

                    gasteigerFactors = pepe.AssignrPiMarsilliFactors(iSet);

                    acOldP = ac;
                }
                IAtom  atomi        = molPi.Atoms[ac.Atoms.IndexOf(atom)];
                int    atomPosition = molPi.Atoms.IndexOf(atomi);
                int    stepSize     = pepe.StepSize;
                int    start        = (stepSize * (atomPosition) + atomPosition);
                double q            = atomi.Charge.Value;
                if (molPi.GetConnectedLonePairs(molPi.Atoms[atomPosition]).Any() ||
                    molPi.GetMaximumBondOrder(atomi) != BondOrder.Single || atomi.FormalCharge != 0)
                {
                    return((gasteigerFactors[1][start]) + (q * gasteigerFactors[1][start + 1]) + (gasteigerFactors[1][start + 2] * (q * q)));
                }
            }
            catch (Exception e)
            {
                Trace.TraceError(e.StackTrace);
            }

            return(electronegativity);
        }
        public void TestAssignGasteigerSigmaMarsiliFactors_IAtomContainer()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();

            IAtomContainer molecule = builder.NewAtomContainer();

            molecule.Atoms.Add(builder.NewAtom("C"));
            molecule.Atoms[0].Charge = 0.0;
            molecule.Atoms.Add(builder.NewAtom("F"));
            molecule.Atoms[1].Charge = 0.0;
            molecule.AddBond(molecule.Atoms[0], molecule.Atoms[1], BondOrder.Single);

            AddExplicitHydrogens(molecule);
            AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(molecule);
            CDK.LonePairElectronChecker.Saturate(molecule);
            foreach (var atom in molecule.Atoms)
            {
                atom.Charge = 0.0;
            }

            Assert.IsNotNull(peoe.AssignGasteigerSigmaMarsiliFactors(molecule).Length);
        }
Ejemplo n.º 8
0
        public void TestCalculateCharges_IAtomContainer()
        {
            double[] testResult = { 0.07915, -0.25264, 0.05783, 0.05783, 0.05783 };

            var peoe = new GasteigerMarsiliPartialCharges();

            var molecule = builder.NewAtomContainer();

            molecule.Atoms.Add(builder.NewAtom("C"));
            molecule.Atoms.Add(builder.NewAtom("F"));
            molecule.AddBond(molecule.Atoms[0], molecule.Atoms[1], BondOrder.Single);

            AddExplicitHydrogens(molecule);
            AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(molecule);
            CDK.LonePairElectronChecker.Saturate(molecule);

            peoe.CalculateCharges(molecule);
            for (int i = 0; i < molecule.Atoms.Count; i++)
            {
                Assert.AreEqual(testResult[i], molecule.Atoms[i].Charge.Value, 0.01);
            }
        }
        public void TestAssignGasteigerMarsiliSigmaPartialCharges_IAtomContainer_Boolean()
        {
            double[] testResult = { 0.07915, -0.25264, 0.05783, 0.05783, 0.05783 };

            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();

            IAtomContainer molecule = builder.NewAtomContainer();

            molecule.Atoms.Add(builder.NewAtom("C"));
            molecule.Atoms.Add(builder.NewAtom("F"));
            molecule.AddBond(molecule.Atoms[0], molecule.Atoms[1], BondOrder.Single);

            AddExplicitHydrogens(molecule);
            AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(molecule);
            CDK.LonePairElectronChecker.Saturate(molecule);

            peoe.AssignGasteigerMarsiliSigmaPartialCharges(molecule, true);
            for (int i = 0; i < molecule.Atoms.Count; i++)
            {
                //Debug.WriteLine("Charge for atom:"+i+" S:"+mol.GetAtomAt(i).Symbol+" Charge:"+mol.GetAtomAt(i).Charge);
                Assert.AreEqual(testResult[i], molecule.Atoms[i].Charge.Value, 0.01);
            }
        }
        public void TestUndefinedPartialCharge()
        {
            var filename = "NCDK.Data.MDL.burden_undefined.sdf";
            var ins      = ResourceLoader.GetAsStream(filename);
            var reader   = new MDLV2000Reader(ins);
            var content  = reader.Read(builder.NewChemFile());

            reader.Close();
            var cList = ChemFileManipulator.GetAllAtomContainers(content);
            var ac    = cList.First();

            Assert.IsNotNull(ac);
            AddExplicitHydrogens(ac);
            AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(ac);
            Aromaticity.CDKLegacy.Apply(ac);

            AddExplicitHydrogens(ac);
            AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(ac);
            CDK.LonePairElectronChecker.Saturate(ac);

            var peoe = new GasteigerMarsiliPartialCharges();

            peoe.CalculateCharges(ac);
        }
        public void TestGetStepSize()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();

            Assert.AreEqual(5, peoe.StepSize);
        }
        public void TestGetChiCatHydrogen()
        {
            GasteigerMarsiliPartialCharges peoe = new GasteigerMarsiliPartialCharges();

            Assert.AreEqual(20, peoe.MaxGasteigerIterations, 0.01);
        }
Ejemplo n.º 13
0
        /// <summary>
        /// Main method which assigns Gasteiger partial pi charges.
        /// </summary>
        /// <param name="ac">AtomContainer</param>
        /// <param name="setCharge">currently unused</param>
        /// <returns>AtomContainer with partial charges</returns>
        public IAtomContainer AssignGasteigerPiPartialCharges(IAtomContainer ac, bool setCharge)
        {
            // we save the aromaticity flags for the input molecule so that
            // we can add them back before we return
            var oldBondAromaticity = new bool[ac.Bonds.Count];
            var oldAtomAromaticity = new bool[ac.Atoms.Count];

            for (int i = 0; i < ac.Atoms.Count; i++)
            {
                oldAtomAromaticity[i] = ac.Atoms[i].IsAromatic;
            }
            for (int i = 0; i < ac.Bonds.Count; i++)
            {
                oldBondAromaticity[i] = ac.Bonds[i].IsAromatic;
            }

            /* 0: remove charge, and possible flag ac */
            for (int j = 0; j < ac.Atoms.Count; j++)
            {
                ac.Atoms[j].Charge   = 0.0;
                ac.Atoms[j].IsPlaced = false;
            }
            for (int j = 0; j < ac.Bonds.Count; j++)
            {
                ac.Bonds[j].IsPlaced = false;
            }

            /* 1: detect resonance structure */
            var gR1           = new StructureResonanceGenerator(); // according G. should be integrated the breaking bonding
            var reactionList1 = gR1.Reactions.ToList();
            var paramList1    = new List <IParameterReaction>();
            var param         = new SetReactionCenter {
                IsSetParameter = true
            };

            paramList1.Add(param);
            var reactionHCPB = new HeterolyticCleavagePBReaction {
                ParameterList = paramList1
            };

            reactionList1.Add(new SharingAnionReaction());
            foreach (var reaction in reactionList1)
            {
                reaction.ParameterList = paramList1;
            }
            gR1.Reactions = reactionList1;

            // according G. should be integrated the breaking bonding
            var gR2 = new StructureResonanceGenerator {
                MaximalStructures = MaxResonanceStructures
            };
            var reactionList2 = gR2.Reactions.ToList();
            var paramList     = new List <IParameterReaction>();
            var paramA        = new SetReactionCenter {
                IsSetParameter = true
            };

            paramList.Add(paramA);
            reactionList2.Add(new HeterolyticCleavagePBReaction());
            reactionList2.Add(new SharingAnionReaction());
            foreach (var reaction in reactionList2)
            {
                reaction.ParameterList = paramList;
            }
            gR2.Reactions = reactionList2;

            /* find resonance containers, which eliminates the repetitions */
            StructureResonanceGenerator gRN = new StructureResonanceGenerator(); // according G. should be integrated the breaking bonding
            var acSet = gRN.GetContainers(RemovingFlagsAromaticity(ac));

            var iSet = ac.Builder.NewAtomContainerSet();

            iSet.Add(ac);

            if (acSet != null)
            {
                foreach (var container in acSet)
                {
                    ac = SetFlags(container, ac, true);

                    // Aromatic don't break its double bond homolytically
                    if (Aromaticity.CDKLegacy.Apply(ac))
                    {
                        reactionList1.Remove(reactionHCPB);
                    }
                    else
                    {
                        reactionList1.Add(reactionHCPB);
                    }

                    var a = gR1.GetStructures(RemovingFlagsAromaticity(ac));
                    if (a.Count > 1)
                    {
                        for (int j = 1; j < a.Count; j++)
                        { // the first is already added
                            iSet.Add(a[j]);
                        }
                    }
                    ac = SetFlags(container, ac, false);

                    /* processing for bonds which are not in resonance */
                    for (int number = 0; number < ac.Bonds.Count; number++)
                    {
                        IAtomContainer aa = SetAntiFlags(container, ac, number, true);
                        if (aa != null)
                        {
                            var ab = gR2.GetStructures(aa);
                            if (ab.Count > 1)
                            {
                                for (int j = 1; j < ab.Count; j++)
                                { // the first is already added
                                    iSet.Add(ab[j]);
                                }
                            }
                            ac = SetAntiFlags(container, aa, number, false);
                        }
                    }
                }
            }

            /* detect hyperconjugation interactions */
            var setHI = GetHyperconjugationInteractions(ac, iSet);

            if (setHI != null)
            {
                if (setHI.Count != 0)
                {
                    iSet.AddRange(setHI);
                }
                Debug.WriteLine($"setHI: {iSet.Count}");
            }
            if (iSet.Count < 2)
            {
                for (int i = 0; i < ac.Atoms.Count; i++)
                {
                    ac.Atoms[i].IsAromatic = oldAtomAromaticity[i];
                }
                for (int i = 0; i < ac.Bonds.Count; i++)
                {
                    ac.Bonds[i].IsAromatic = oldBondAromaticity[i];
                }
                return(ac);
            }

            /* 2: search whose atoms which don't keep their formal charge and set flags */
            var sumCharges = Arrays.CreateJagged <double>(iSet.Count, ac.Atoms.Count);

            for (int i = 1; i < iSet.Count; i++)
            {
                var iac = iSet[i];
                for (int j = 0; j < iac.Atoms.Count; j++)
                {
                    sumCharges[i][j] = iac.Atoms[j].FormalCharge.Value;
                }
            }

            for (int i = 1; i < iSet.Count; i++)
            {
                var iac   = iSet[i];
                int count = 0;
                for (int j = 0; j < ac.Atoms.Count; j++)
                {
                    if (count < 2)
                    {
                        if (sumCharges[i][j] != ac.Atoms[j].FormalCharge)
                        {
                            ac.Atoms[j].IsPlaced  = true;
                            iac.Atoms[j].IsPlaced = true;
                            count++; /* TODO- error */
                        }
                    }
                }
            }

            /* 3: set sigma charge (PEOE). Initial start point */
            var peoe = new GasteigerMarsiliPartialCharges();;

            peoe.MaxGasteigerIterations = 6;
            IAtomContainer acCloned;

            var gasteigerFactors = AssignPiFactors(iSet);//a,b,c,deoc,chi,q

            /* 4: calculate topological weight factors Wt=fQ*fB*fA */
            var Wt = new double[iSet.Count - 1];

            for (int i = 1; i < iSet.Count; i++)
            {
                Wt[i - 1] = GetTopologicalFactors(iSet[i], ac);
                Debug.WriteLine($", W:{Wt[i - 1]}");
                acCloned = (IAtomContainer)iSet[i].Clone();

                acCloned = peoe.AssignGasteigerMarsiliSigmaPartialCharges(acCloned, true);
                for (int j = 0; j < acCloned.Atoms.Count; j++)
                {
                    if (iSet[i].Atoms[j].IsPlaced)
                    {
                        gasteigerFactors[i][StepSize * j + j + 5] = acCloned.Atoms[j].Charge.Value;
                    }
                }
            }

            // calculate electronegativity for changed atoms and make the difference
            // between whose atoms which change their formal charge
            for (int iter = 0; iter < MaxGasteigerIterations; iter++)
            {
                for (int k = 1; k < iSet.Count; k++)
                {
                    IAtomContainer iac = iSet[k];
                    double[]       electronegativity = new double[2];
                    int            count             = 0;
                    int            atom1             = 0;
                    int            atom2             = 0;
                    for (int j = 0; j < iac.Atoms.Count; j++)
                    {
                        if (count == 2) // The change of sign is product of only two atoms, is not true
                        {
                            break;
                        }
                        if (iac.Atoms[j].IsPlaced)
                        {
                            Debug.WriteLine("Atom: " + j + ", S:" + iac.Atoms[j].Symbol + ", C:"
                                            + iac.Atoms[j].FormalCharge);
                            if (count == 0)
                            {
                                atom1 = j;
                            }
                            else
                            {
                                atom2 = j;
                            }

                            double q1 = gasteigerFactors[k][StepSize * j + j + 5];
                            electronegativity[count] =
                                gasteigerFactors[k][StepSize * j + j + 2] * q1 * q1
                                + gasteigerFactors[k][StepSize * j + j + 1] * q1
                                + gasteigerFactors[k][StepSize * j + j];
                            Debug.WriteLine("e:" + electronegativity[count] + ",q1: " + q1 + ", c:"
                                            + gasteigerFactors[k][StepSize * j + j + 2] + ", b:"
                                            + gasteigerFactors[k][StepSize * j + j + 1] + ", a:"
                                            + gasteigerFactors[k][StepSize * j + j]);
                            count++;
                        }
                    }
                    Debug.WriteLine("Atom1:" + atom1 + ",Atom2:" + atom2);
                    /* difference of electronegativity 1 lower */
                    var    max1 = Math.Max(electronegativity[0], electronegativity[1]);
                    var    min1 = Math.Min(electronegativity[0], electronegativity[1]);
                    double DX   = 1.0;
                    if (electronegativity[0] < electronegativity[1])
                    {
                        DX = gasteigerFactors[k][StepSize * atom1 + atom1 + 3];
                    }
                    else
                    {
                        DX = gasteigerFactors[k][StepSize * atom2 + atom2 + 3];
                    }

                    var Dq = (max1 - min1) / DX;
                    Debug.WriteLine("Dq : " + Dq + " = (" + max1 + "-" + min1 + ")/" + DX);
                    var epN1  = GetElectrostaticPotentialN(iac, atom1, gasteigerFactors[k]);
                    var epN2  = GetElectrostaticPotentialN(iac, atom2, gasteigerFactors[k]);
                    var SumQN = Math.Abs(epN1 - epN2);
                    Debug.WriteLine("sum(" + SumQN + ") = (" + epN1 + ") - (" + epN2 + ")");

                    /* electronic weight */
                    var WE = Dq + fE * SumQN;
                    Debug.WriteLine("WE : " + WE + " = Dq(" + Dq + ")+FE(" + fE + ")*SumQN(" + SumQN);
                    var iTE = iter + 1;

                    /* total topological */
                    var W = WE * Wt[k - 1] * fS / (iTE);
                    Debug.WriteLine("W : " + W + " = WE(" + WE + ")*Wt(" + Wt[k - 1] + ")*FS(" + fS + ")/iter(" + iTE
                                    + "), atoms: " + atom1 + ", " + atom2);

                    /* iac == new structure, ac == old structure */
                    /* atom1 */
                    if (iac.Atoms[atom1].FormalCharge == 0)
                    {
                        if (ac.Atoms[atom1].FormalCharge < 0)
                        {
                            gasteigerFactors[k][StepSize * atom1 + atom1 + 5] = -1 * W;
                        }
                        else
                        {
                            gasteigerFactors[k][StepSize * atom1 + atom1 + 5] = W;
                        }
                    }
                    else if (iac.Atoms[atom1].FormalCharge > 0)
                    {
                        gasteigerFactors[k][StepSize * atom1 + atom1 + 5] = W;
                    }
                    else
                    {
                        gasteigerFactors[k][StepSize * atom1 + atom1 + 5] = -1 * W;
                    }
                    /* atom2 */
                    if (iac.Atoms[atom2].FormalCharge == 0)
                    {
                        if (ac.Atoms[atom2].FormalCharge < 0)
                        {
                            gasteigerFactors[k][StepSize * atom2 + atom2 + 5] = -1 * W;
                        }
                        else
                        {
                            gasteigerFactors[k][StepSize * atom2 + atom2 + 5] = W;
                        }
                    }
                    else if (iac.Atoms[atom2].FormalCharge > 0)
                    {
                        gasteigerFactors[k][StepSize * atom2 + atom2 + 5] = W;
                    }
                    else
                    {
                        gasteigerFactors[k][StepSize * atom2 + atom2 + 5] = -1 * W;
                    }
                }
                for (int k = 1; k < iSet.Count; k++)
                {
                    for (int i = 0; i < ac.Atoms.Count; i++)
                    {
                        if (iSet[k].Atoms[i].IsPlaced)
                        {
                            var    charge  = ac.Atoms[i].Charge.Value;
                            double chargeT = 0.0;
                            chargeT = charge + gasteigerFactors[k][StepSize * i + i + 5];
                            Debug.WriteLine("i<|" + ac.Atoms[i].Symbol + ", " + chargeT + "=c:" + charge + "+g: "
                                            + gasteigerFactors[k][StepSize * i + i + 5]);
                            ac.Atoms[i].Charge = chargeT;
                        }
                    }
                }
            }// iterations
            Debug.WriteLine("final");

            // before getting back we should set back the aromatic flags
            for (int i = 0; i < ac.Atoms.Count; i++)
            {
                ac.Atoms[i].IsAromatic = oldAtomAromaticity[i];
            }
            for (int i = 0; i < ac.Bonds.Count; i++)
            {
                ac.Bonds[i].IsAromatic = oldBondAromaticity[i];
            }

            return(ac);
        }
Ejemplo n.º 14
0
        public void TestGetMaxGasteigerDamp()
        {
            var peoe = new GasteigerMarsiliPartialCharges();

            Assert.AreEqual(20, peoe.MaxGasteigerIterations, 0.01);
        }