AmoebaMultipoleForce

class OpenMM::AmoebaMultipoleForce : public OpenMM::Force

This class implements the Amoeba multipole interaction.

To use it, create an AmoebaMultipoleForce object then call addMultipole() once for each atom. After an entry has been added, you can modify its force field parameters by calling setMultipoleParameters(). This will have no effect on Contexts that already exist unless you call updateParametersInContext().

Public Functions

AmoebaMultipoleForce()

Create an AmoebaMultipoleForce.

inline int getNumMultipoles() const

Get the number of particles in the potential function

NonbondedMethod getNonbondedMethod() const

Get the method used for handling long-range nonbonded interactions.

void setNonbondedMethod(NonbondedMethod method)

Set the method used for handling long-range nonbonded interactions.

PolarizationType getPolarizationType() const

Get polarization type

void setPolarizationType(PolarizationType type)

Set the polarization type

double getCutoffDistance() const

Get the cutoff distance (in nm) being used for nonbonded interactions. If the NonbondedMethod in use is NoCutoff, this value will have no effect.

Returns

the cutoff distance, measured in nm

void setCutoffDistance(double distance)

Set the cutoff distance (in nm) being used for nonbonded interactions. If the NonbondedMethod in use is NoCutoff, this value will have no effect.

Parameters

distance – the cutoff distance, measured in nm

void getPMEParameters(double &alpha, int &nx, int &ny, int &nz) const

Get the parameters to use for PME calculations. If alpha is 0 (the default), these parameters are ignored and instead their values are chosen based on the Ewald error tolerance.

Parameters
  • alpha[out] the separation parameter

  • nx[out] the number of grid points along the X axis

  • ny[out] the number of grid points along the Y axis

  • nz[out] the number of grid points along the Z axis

void setPMEParameters(double alpha, int nx, int ny, int nz)

Set the parameters to use for PME calculations. If alpha is 0 (the default), these parameters are ignored and instead their values are chosen based on the Ewald error tolerance.

Parameters
  • alpha – the separation parameter

  • nx – the number of grid points along the X axis

  • ny – the number of grid points along the Y axis

  • nz – the number of grid points along the Z axis

double getAEwald() const

Get the Ewald alpha parameter. If this is 0 (the default), a value is chosen automatically based on the Ewald error tolerance.

Deprecated:

This method exists only for backward compatibility. Use getPMEParameters() instead.

Returns

the Ewald alpha parameter

void setAEwald(double aewald)

Set the Ewald alpha parameter. If this is 0 (the default), a value is chosen automatically based on the Ewald error tolerance.

Deprecated:

This method exists only for backward compatibility. Use setPMEParameters() instead.

Parameters

aewald – alpha parameter

int getPmeBSplineOrder() const

Get the B-spline order to use for PME charge spreading

Returns

the B-spline order

void getPmeGridDimensions(std::vector<int> &gridDimension) const

Get the PME grid dimensions. If Ewald alpha is 0 (the default), this is ignored and grid dimensions are chosen automatically based on the Ewald error tolerance.

Deprecated:

This method exists only for backward compatibility. Use getPMEParameters() instead.

Returns

the PME grid dimensions

void setPmeGridDimensions(const std::vector<int> &gridDimension)

Set the PME grid dimensions. If Ewald alpha is 0 (the default), this is ignored and grid dimensions are chosen automatically based on the Ewald error tolerance.

Deprecated:

This method exists only for backward compatibility. Use setPMEParameters() instead.

Parameters

gridDimension – the PME grid dimensions

void getPMEParametersInContext(const Context &context, double &alpha, int &nx, int &ny, int &nz) const

Get the parameters being used for PME in a particular Context. Because some platforms have restrictions on the allowed grid sizes, the values that are actually used may be slightly different from those specified with setPmeGridDimensions(), or the standard values calculated based on the Ewald error tolerance. See the manual for details.

Parameters
  • context – the Context for which to get the parameters

  • alpha[out] the separation parameter

  • nx[out] the number of grid points along the X axis

  • ny[out] the number of grid points along the Y axis

  • nz[out] the number of grid points along the Z axis

int addMultipole(double charge, const std::vector<double> &molecularDipole, const std::vector<double> &molecularQuadrupole, int axisType, int multipoleAtomZ, int multipoleAtomX, int multipoleAtomY, double thole, double dampingFactor, double polarity)

Add multipole-related info for a particle

Parameters
  • charge – the particle’s charge

  • molecularDipole – the particle’s molecular dipole (vector of size 3)

  • molecularQuadrupole – the particle’s molecular quadrupole (vector of size 9)

  • axisType – the particle’s axis type

  • multipoleAtomZ – index of first atom used in constructing lab<->molecular frames

  • multipoleAtomX – index of second atom used in constructing lab<->molecular frames

  • multipoleAtomY – index of second atom used in constructing lab<->molecular frames

  • thole – Thole parameter

  • dampingFactor – dampingFactor parameter

  • polarity – polarity parameter

Returns

the index of the particle that was added

void getMultipoleParameters(int index, double &charge, std::vector<double> &molecularDipole, std::vector<double> &molecularQuadrupole, int &axisType, int &multipoleAtomZ, int &multipoleAtomX, int &multipoleAtomY, double &thole, double &dampingFactor, double &polarity) const

Get the multipole parameters for a particle.

Parameters
  • index – the index of the atom for which to get parameters

  • charge[out] the particle’s charge

  • molecularDipole[out] the particle’s molecular dipole (vector of size 3)

  • molecularQuadrupole[out] the particle’s molecular quadrupole (vector of size 9)

  • axisType[out] the particle’s axis type

  • multipoleAtomZ[out] index of first atom used in constructing lab<->molecular frames

  • multipoleAtomX[out] index of second atom used in constructing lab<->molecular frames

  • multipoleAtomY[out] index of second atom used in constructing lab<->molecular frames

  • thole[out] Thole parameter

  • dampingFactor[out] dampingFactor parameter

  • polarity[out] polarity parameter

void setMultipoleParameters(int index, double charge, const std::vector<double> &molecularDipole, const std::vector<double> &molecularQuadrupole, int axisType, int multipoleAtomZ, int multipoleAtomX, int multipoleAtomY, double thole, double dampingFactor, double polarity)

Set the multipole parameters for a particle.

Parameters
  • index – the index of the atom for which to set parameters

  • charge – the particle’s charge

  • molecularDipole – the particle’s molecular dipole (vector of size 3)

  • molecularQuadrupole – the particle’s molecular quadrupole (vector of size 9)

  • axisType – the particle’s axis type

  • multipoleAtomZ – index of first atom used in constructing lab<->molecular frames

  • multipoleAtomX – index of second atom used in constructing lab<->molecular frames

  • multipoleAtomY – index of second atom used in constructing lab<->molecular frames

  • thole – thole parameter

  • dampingFactor – damping factor parameter

  • polarity – polarity parameter

void setCovalentMap(int index, CovalentType typeId, const std::vector<int> &covalentAtoms)

Set the CovalentMap for an atom

Parameters
  • index – the index of the atom for which to set parameters

  • typeId – CovalentTypes type

  • covalentAtoms – vector of covalent atoms associated w/ the specfied CovalentType

void getCovalentMap(int index, CovalentType typeId, std::vector<int> &covalentAtoms) const

Get the CovalentMap for an atom

Parameters
  • index – the index of the atom for which to set parameters

  • typeId – CovalentTypes type

  • covalentAtoms[out] output vector of covalent atoms associated w/ the specfied CovalentType

void getCovalentMaps(int index, std::vector<std::vector<int>> &covalentLists) const

Get the CovalentMap for an atom

Parameters
  • index – the index of the atom for which to set parameters

  • covalentLists[out] output vector of covalent lists of atoms

int getMutualInducedMaxIterations(void) const

Get the max number of iterations to be used in calculating the mutual induced dipoles

Returns

max number of iterations

void setMutualInducedMaxIterations(int inputMutualInducedMaxIterations)

Set the max number of iterations to be used in calculating the mutual induced dipoles

Parameters

inputMutualInducedMaxIterations – number of iterations

double getMutualInducedTargetEpsilon(void) const

Get the target epsilon to be used to test for convergence of iterative method used in calculating the mutual induced dipoles

Returns

target epsilon

void setMutualInducedTargetEpsilon(double inputMutualInducedTargetEpsilon)

Set the target epsilon to be used to test for convergence of iterative method used in calculating the mutual induced dipoles

Parameters

inputMutualInducedTargetEpsilon – target epsilon

void setExtrapolationCoefficients(const std::vector<double> &coefficients)

Set the coefficients for the mu_0, mu_1, mu_2, …, mu_n terms in the extrapolation algorithm for induced dipoles.

Parameters

coefficients – a vector whose mth entry specifies the coefficient for mu_m. The length of this vector determines how many iterations are performed.

const std::vector<double> &getExtrapolationCoefficients() const

Get the coefficients for the mu_0, mu_1, mu_2, …, mu_n terms in the extrapolation algorithm for induced dipoles. In this release, the default values for the coefficients are [-0.154, 0.017, 0.658, 0.474], but be aware that those may change in a future release.

double getEwaldErrorTolerance() const

Get the error tolerance for Ewald summation. This corresponds to the fractional error in the forces which is acceptable. This value is used to select the grid dimensions and separation (alpha) parameter so that the average error level will be less than the tolerance. There is not a rigorous guarantee that all forces on all atoms will be less than the tolerance, however.

This can be overridden by explicitly setting an alpha parameter and grid dimensions to use.

void setEwaldErrorTolerance(double tol)

Get the error tolerance for Ewald summation. This corresponds to the fractional error in the forces which is acceptable. This value is used to select the grid dimensions and separation (alpha) parameter so that the average error level will be less than the tolerance. There is not a rigorous guarantee that all forces on all atoms will be less than the tolerance, however.

This can be overridden by explicitly setting an alpha parameter and grid dimensions to use.

void getLabFramePermanentDipoles(Context &context, std::vector<Vec3> &dipoles)

Get the fixed dipole moments of all particles in the global reference frame.

Parameters
  • context – the Context for which to get the fixed dipoles

  • dipoles[out] the fixed dipole moment of particle i is stored into the i’th element

void getInducedDipoles(Context &context, std::vector<Vec3> &dipoles)

Get the induced dipole moments of all particles.

Parameters
  • context – the Context for which to get the induced dipoles

  • dipoles[out] the induced dipole moment of particle i is stored into the i’th element

void getTotalDipoles(Context &context, std::vector<Vec3> &dipoles)

Get the total dipole moments (fixed plus induced) of all particles.

Parameters
  • context – the Context for which to get the total dipoles

  • dipoles[out] the total dipole moment of particle i is stored into the i’th element

void getElectrostaticPotential(const std::vector<Vec3> &inputGrid, Context &context, std::vector<double> &outputElectrostaticPotential)

Get the electrostatic potential.

Parameters
  • inputGrid – input grid points over which the potential is to be evaluated

  • context – context

  • outputElectrostaticPotential[out] output potential

void getSystemMultipoleMoments(Context &context, std::vector<double> &outputMultipoleMoments)

Get the system multipole moments.

This method is most useful for non-periodic systems. When called for a periodic system, only the lowest nonvanishing moment has a well defined value. This means that if the system has a net nonzero charge, the dipole and quadrupole moments are not well defined and should be ignored. If the net charge is zero, the dipole moment is well defined (and really represents a dipole density), but the quadrupole moment is still undefined and should be ignored.

Parameters
  • context – context

  • outputMultipoleMoments[out] (charge, dipole_x, dipole_y, dipole_z, quadrupole_xx, quadrupole_xy, quadrupole_xz, quadrupole_yx, quadrupole_yy, quadrupole_yz, quadrupole_zx, quadrupole_zy, quadrupole_zz)

void updateParametersInContext(Context &context)

Update the multipole parameters in a Context to match those stored in this Force object. This method provides an efficient method to update certain parameters in an existing Context without needing to reinitialize it. Simply call setMultipoleParameters() to modify this object’s parameters, then call updateParametersInContext() to copy them over to the Context.

This method has several limitations. The only information it updates is the parameters of multipoles. All other aspects of the Force (the nonbonded method, the cutoff distance, etc.) are unaffected and can only be changed by reinitializing the Context. Furthermore, this method cannot be used to add new multipoles, only to change the parameters of existing ones.

inline virtual bool usesPeriodicBoundaryConditions() const

Returns whether or not this force makes use of periodic boundary conditions.

Returns

true if nonbondedMethod uses PBC and false otherwise