DrudeNoseHooverIntegrator¶
- class openmm.openmm.DrudeNoseHooverIntegrator(*args)¶
This Integrator simulates systems that include Drude particles. It applies two different Nose-Hoover chain thermostats to the different parts of the system. The first is applied to ordinary particles (ones that are not part of a Drude particle pair), as well as to the center of mass of each Drude particle pair. A second thermostat, typically with a much lower temperature, is applied to the relative internal displacement of each pair.
This Integrator requires the System to include a DrudeForce, which it uses to identify the Drude particles.
- __init__(self, temperature, collisionFrequency, drudeTemperature, drudeCollisionFrequency, stepSize, chainLength=3, numMTS=3, numYoshidaSuzuki=7) → DrudeNoseHooverIntegrator¶
- __init__(self, other) → DrudeNoseHooverIntegrator
Create a DrudeNoseHooverIntegrator.
- Parameters
temperature (double) – the target temperature for the system (in Kelvin).
collisionFrequency (double) – the frequency of the system’s interaction with the heat bath (in inverse picoseconds).
drudeTemperature (double) – the target temperature for the Drude particles, relative to their parent atom (in Kelvin).
drudeCollisionFrequency (double) – the frequency of the drude particles’ interaction with the heat bath (in inverse picoseconds).
stepSize (double) – the step size with which to integrator the system (in picoseconds)
chainLength (int) – the number of beads in the Nose-Hoover chain.
numMTS (int) – the number of step in the multiple time step chain propagation algorithm.
numYoshidaSuzuki (int) – the number of terms in the Yoshida-Suzuki multi time step decomposition used in the chain propagation algorithm (must be 1, 3, or 5).
Methods
__init__
(-> DrudeNoseHooverIntegrator)Create a DrudeNoseHooverIntegrator.
addSubsystemThermostat
(self, …[, …])Add a Nose-Hoover Chain thermostat to control the temperature of a collection of atoms and/or pairs of connected atoms within the full system.
addThermostat
(self, temperature, …)Add a simple Nose-Hoover Chain thermostat to control the temperature of the full system
Compute the kinetic energy of the drude particles at the current time.
computeHeatBathEnergy
(self)Compute the total (potential + kinetic) heat bath energy for all heat baths associated with this integrator, at the current time.
Compute the kinetic energy of all (real and drude) particles at the current time.
getCollisionFrequency
(self[, chainID])Get the collision frequency for absolute motion of the i-th chain (in 1/picosecond).
getConstraintTolerance
(self)Get the distance tolerance within which constraints are maintained, as a fraction of the constrained distance.
Get which force groups to use for integration.
getMaxDrudeDistance
(self)Get the maximum distance a Drude particle can ever move from its parent particle, measured in nm.
getMaximumPairDistance
(self)Gets the maximum distance (in nm) that a connected pair may stray from each other.
getNumThermostats
(self)Get the number of Nose-Hoover chains registered with this integrator.
getRelativeCollisionFrequency
(self[, chainID])Get the collision frequency for pairs’ relative motion of the i-th chain (in 1/picosecond).
getRelativeTemperature
(self[, chainID])Get the temperature of the i-th chain for controling pairs’ relative particle motion (in Kelvin).
getStepSize
(self)Get the size of each time step, in picoseconds.
getTemperature
(self[, chainID])Get the temperature of the i-th chain for controling absolute particle motion (in Kelvin).
getThermostat
(self[, chainID])Get the NoseHooverChain thermostat
getVelocitiesForTemperature
(self, system, …)Return a list of velocities normally distributed around a target temperature, with the Drude temperatures assigned according to the Drude temperature assigned to the integrator.
hasSubsystemThermostats
(self)Return false, if this integrator was set up with the ‘default constructor’ that thermostats the whole system, true otherwise.
initialize
(self, context)This will be called by the Context when it is created.
setCollisionFrequency
(self, frequency[, chainID])Set the collision frequency for absolute motion of the i-th chain.
setConstraintTolerance
(self, tol)Set the distance tolerance within which constraints are maintained, as a fraction of the constrained distance.
setIntegrationForceGroups
(groups)Set which force groups to use for integration.
setMaxDrudeDistance
(self, distance)Set the maximum distance a Drude particle can ever move from its parent particle, measured in nm.
setMaximumPairDistance
(self, distance)Sets the maximum distance (in nm) that a connected pair may stray from each other, implemented using a hard wall.
setRelativeCollisionFrequency
(self, frequency)Set the collision frequency for pairs’ relative motion of the i-th chain.
setRelativeTemperature
(self, temperature[, …])set the (relative pair motion) temperature of the i-th chain.
setStepSize
(self, size)Set the size of each time step, in picoseconds.
setTemperature
(self, temperature[, chainID])set the (absolute motion) temperature of the i-th chain.
step
(self, steps)Advance a simulation through time by taking a series of time steps.
Attributes
The membership flag
- property thisown¶
The membership flag
- initialize(self, context)¶
This will be called by the Context when it is created. It informs the Integrator of what context it will be integrating, and gives it a chance to do any necessary initialization. It will also get called again if the application calls reinitialize() on the Context.
- getMaxDrudeDistance(self) → double¶
Get the maximum distance a Drude particle can ever move from its parent particle, measured in nm. This is implemented with a hard wall constraint. If this distance is set to 0 (the default), the hard wall constraint is omitted.
- setMaxDrudeDistance(self, distance)¶
Set the maximum distance a Drude particle can ever move from its parent particle, measured in nm. This is implemented with a hard wall constraint. If this distance is set to 0 (the default), the hard wall constraint is omitted.
- computeDrudeKineticEnergy(self) → double¶
Compute the kinetic energy of the drude particles at the current time.
- computeTotalKineticEnergy(self) → double¶
Compute the kinetic energy of all (real and drude) particles at the current time.
- getVelocitiesForTemperature(self, system, temperature, randomSeed) → std::vector< Vec3,std::allocator< Vec3 > >¶
Return a list of velocities normally distributed around a target temperature, with the Drude temperatures assigned according to the Drude temperature assigned to the integrator.
- Parameters
system (System) – the system whose velocities are to be initialized.
temperature (double) – the target temperature in Kelvin.
randomSeed (int) – the random number seed to use when selecting velocities
- __copy__(self) → Integrator¶
- addSubsystemThermostat(self, thermostatedParticles, thermostatedPairs, temperature, collisionFrequency, relativeTemperature, relativeCollisionFrequency, chainLength=3, numMTS=3, numYoshidaSuzuki=7) → int¶
Add a Nose-Hoover Chain thermostat to control the temperature of a collection of atoms and/or pairs of connected atoms within the full system. A list of atoms defining the atoms to be thermostated is provided and the thermostat will only control members of that list. Additionally a list of pairs of connected atoms may be provided; in this case both the center of mass absolute motion of each pair is controlled as well as their motion relative to each other, which is independently thermostated. If both the list of thermostated particles and thermostated pairs are empty all particles will be thermostated.
- Parameters
thermostatedParticles (vector< int >) – list of particle ids to be thermostated.
thermostatedPairs (vector< std::pair< int, int > >) – a list of pairs of connected atoms whose absolute center of mass motion and motion relative to one another will be independently thermostated.
temperature (double) – the target temperature for each pair’s absolute of center of mass motion.
collisionFrequency (double) – the frequency of the interaction with the heat bath for the pairs’ center of mass motion (in 1/ps).
relativeTemperature (double) – the target temperature for each pair’s relative motion.
relativeCollisionFrequency (double) – the frequency of the interaction with the heat bath for the pairs’ relative motion (in 1/ps).
chainLength (int) – the number of beads in the Nose-Hoover chain.
numMTS (int) – the number of step in the multiple time step chain propagation algorithm.
numYoshidaSuzuki (int) – the number of terms in the Yoshida-Suzuki multi time step decomposition used in the chain propagation algorithm (must be 1, 3, 5, or 7).
- addThermostat(self, temperature, collisionFrequency, chainLength, numMTS, numYoshidaSuzuki) → int¶
Add a simple Nose-Hoover Chain thermostat to control the temperature of the full system
- Parameters
temperature (double) – the target temperature for the system.
collisionFrequency (double) – the frequency of the interaction with the heat bath (in 1/ps).
chainLength (int) – the number of beads in the Nose-Hoover chain
numMTS (int) – the number of step in the multiple time step chain propagation algorithm.
numYoshidaSuzuki (int) – the number of terms in the Yoshida-Suzuki multi time step decomposition used in the chain propagation algorithm (must be 1, 3, 5, or 7).
- computeHeatBathEnergy(self) → double¶
Compute the total (potential + kinetic) heat bath energy for all heat baths associated with this integrator, at the current time.
- getCollisionFrequency(self, chainID=0) → double¶
Get the collision frequency for absolute motion of the i-th chain (in 1/picosecond).
- Parameters
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- Returns
the collision frequency.
- Return type
double
- getConstraintTolerance(self) → double¶
Get the distance tolerance within which constraints are maintained, as a fraction of the constrained distance.
- getIntegrationForceGroups(self) → int¶
Get which force groups to use for integration. By default, all force groups are included. This is interpreted as a set of bit flags: the forces from group i will be included if (groups&(1<<i)) != 0.
- getMaximumPairDistance(self) → double¶
Gets the maximum distance (in nm) that a connected pair may stray from each other. If zero, there are no constraints on the intra-pair separation.
- getNumThermostats(self) → int¶
Get the number of Nose-Hoover chains registered with this integrator.
- getRelativeCollisionFrequency(self, chainID=0) → double¶
Get the collision frequency for pairs’ relative motion of the i-th chain (in 1/picosecond).
- Parameters
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- Returns
the collision frequency.
- Return type
double
- getRelativeTemperature(self, chainID=0) → double¶
Get the temperature of the i-th chain for controling pairs’ relative particle motion (in Kelvin).
- Parameters
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- Returns
the temperature.
- Return type
double
- getStepSize(self) → double¶
Get the size of each time step, in picoseconds. If this integrator uses variable time steps, the size of the most recent step is returned.
- Returns
the step size, measured in ps
- Return type
double
- getTemperature(self, chainID=0) → double¶
Get the temperature of the i-th chain for controling absolute particle motion (in Kelvin).
- Parameters
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- Returns
the temperature.
- Return type
double
- getThermostat(self, chainID=0) → NoseHooverChain¶
Get the NoseHooverChain thermostat
- Parameters
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- hasSubsystemThermostats(self) → bool¶
Return false, if this integrator was set up with the ‘default constructor’ that thermostats the whole system, true otherwise. Required for serialization.
- setCollisionFrequency(self, frequency, chainID=0)¶
Set the collision frequency for absolute motion of the i-th chain.
- Parameters
frequency (double) – the collision frequency in picosecond.
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- setConstraintTolerance(self, tol)¶
Set the distance tolerance within which constraints are maintained, as a fraction of the constrained distance.
- setIntegrationForceGroups(groups)¶
Set which force groups to use for integration. By default, all force groups are included.
- Parameters
groups (set or int) – a set of indices for which force groups to include when integrating the equations of motion. Alternatively, the groups can be passed as a single unsigned integer interpreted as a bitmask, in which case group i will be included if (groups&(1<<i)) != 0.
- setMaximumPairDistance(self, distance)¶
Sets the maximum distance (in nm) that a connected pair may stray from each other, implemented using a hard wall. If set to zero, the hard wall constraint is omited and the pairs are free to be separated by any distance.
- setRelativeCollisionFrequency(self, frequency, chainID=0)¶
Set the collision frequency for pairs’ relative motion of the i-th chain.
- Parameters
frequency (double) – the collision frequency in picosecond.
chainID (int) – the index of the Nose-Hoover chain thermostat (default=0).
- setRelativeTemperature(self, temperature, chainID=0)¶
set the (relative pair motion) temperature of the i-th chain.
- Parameters
temperature (double) – the temperature for the Nose-Hoover chain thermostat (in Kelvin).
chainID (int) – The id of the Nose-Hoover chain thermostat for which the temperature is set (default=0).
- setStepSize(self, size)¶
Set the size of each time step, in picoseconds. If this integrator uses variable time steps, the effect of calling this method is undefined, and it may simply be ignored.
- Parameters
size (double) – the step size, measured in ps
- setTemperature(self, temperature, chainID=0)¶
set the (absolute motion) temperature of the i-th chain.
- Parameters
temperature (double) – the temperature for the Nose-Hoover chain thermostat (in Kelvin).
chainID (int) – The id of the Nose-Hoover chain thermostat for which the temperature is set (default=0).
- step(self, steps)¶
Advance a simulation through time by taking a series of time steps.
- Parameters
steps (int) – the number of time steps to take