sponge.control.integrator.leapfrog 源代码

# Copyright 2021-2023 @ Shenzhen Bay Laboratory &
#                       Peking University &
#                       Huawei Technologies Co., Ltd
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# This code is a part of MindSPONGE:
# MindSpore Simulation Package tOwards Next Generation molecular modelling.
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"""
Leap-frog integrator
"""

from typing import Tuple

from mindspore import Tensor

from .integrator import Integrator, _integrator_register
from ..thermostat import Thermostat
from ..barostat import Barostat
from ..constraint import Constraint
from ...system import Molecule
from ...function import get_arguments


[文档]@_integrator_register('leap_frog') class LeapFrog(Integrator): r""" A leap-frog integrator based on "middle scheme" developed by Jian Liu, et al. It is a subclass of :class:`sponge.control.Integrator`. Reference Zhang, Z.; Yan, K; Liu, X.; Liu, J. A Leap-Frog Algorithm-based Efficient Unified Thermostat Scheme for Molecular Dynamics [J]. Chinese Science Bulletin, 2018, 63(33). Args: system (:class:`sponge.system.Molecule`): Simulation system. thermostat (:class:`sponge.control.Thermostat`, optional): Thermostat for temperature coupling. Default: ``None``. barostat (:class:`sponge.control.Barostat`, optional): Barostat for pressure coupling. Default: ``None``. constraint (:class:`sponge.control.Constraint`, optional): Constraint algorithm. Default: ``None``. Inputs: - **coordinate** (Tensor) - Coordinate. Tensor of shape :math:`(B, A, D)`. Data type is float. Here :math:`B` is the number of walkers in simulation, :math:`A` is the number of atoms and :math:`D` is the spatial dimension of the simulation system, which is usually 3. - **velocity** (Tensor) - Velocity. Tensor of shape :math:`(B, A, D)`. Data type is float. - **force** (Tensor) - Force. Tensor of shape :math:`(B, A, D)`. Data type is float. - **energy** (Tensor) - Energy. Tensor of shape :math:`(B, 1)`. Data type is float. - **kinetics** (Tensor) - Kinetics. Tensor of shape :math:`(B, D)`. Data type is float. - **virial** (Tensor) - Virial. Tensor of shape :math:`(B, D)`. Data type is float. - **pbc_box** (Tensor) - Pressure boundary condition box. Tensor of shape :math:`(B, D)`. Data type is float. - **step** (int) - Simulation step. Default: ``0``. Outputs: - coordinate, Tensor of shape :math:`(B, A, D)`. Coordinate. Data type is float. - velocity, Tensor of shape :math:`(B, A, D)`. Velocity. Data type is float. - force, Tensor of shape :math:`(B, A, D)`. Force. Data type is float. - energy, Tensor of shape :math:`(B, 1)`. Energy. Data type is float. - kinetics, Tensor of shape :math:`(B, D)`. Kinetics. Data type is float. - virial, Tensor of shape :math:`(B, D)`. Virial. Data type is float. - pbc_box, Tensor of shape :math:`(B, D)`. Periodic boundary condition box. Data type is float. Supported Platforms: ``Ascend`` ``GPU`` Examples: >>> from sponge import Molecule >>> from sponge.control import LeapFrog >>> system = Molecule(template='water.tip3p.yaml') >>> controller = LeapFrog(system) """ def __init__(self, system: Molecule, thermostat: Thermostat = None, barostat: Barostat = None, constraint: Constraint = None, **kwargs ): super().__init__( system=system, thermostat=thermostat, barostat=barostat, constraint=constraint, ) self._kwargs = get_arguments(locals(), kwargs) def construct(self, coordinate: Tensor, velocity: Tensor, force: Tensor, energy: Tensor, kinetics: Tensor, virial: Tensor = None, pbc_box: Tensor = None, step: int = 0, ) -> Tuple[Tensor, Tensor, Tensor, Tensor, Tensor, Tensor, Tensor]: r""" Update simulation step. Args: coordinate (Tensor): Tensor of shape :math:`(B, A, D)`. Data type is float. velocity (Tensor): Tensor of shape :math:`(B, A, D)`. Data type is float. force (Tensor): Tensor of shape :math:`(B, A, D)`. Data type is float. energy (Tensor): Tensor of shape :math:`(B, 1)`. Data type is float. kinetics (Tensor): Tensor of shape :math:`(B, D)`. Data type is float. virial (Tensor): Tensor of shape :math:`(B, D)`. Data type is float. pbc_box (Tensor): Tensor of shape :math:`(B, D)`. Data type is float. step (int): Simulation step. Default: ``0``. Returns: - **coordinate** (Tensor) - Tensor of shape :math:`(B, A, D)`. Data type is float. - **velocity** (Tensor) - Tensor of shape :math:`(B, A, D)`. Data type is float. - **force** (Tensor) - Tensor of shape :math:`(B, A, D)`. Data type is float. - **energy** (Tensor) - Tensor of shape :math:`(B, 1)`. Data type is float. - **kinetics** (Tensor) - Tensor of shape :math:`(B, D)`. Data type is float. - **virial** (Tensor) - Tensor of shape :math:`(B, D)`. Data type is float. - **pbc_box** (Tensor) - Tensor of shape :math:`(B, D)`. Data type is float. Note: :math:`B` is the number of walkers in simulation. :math:`A` is the number of atoms. :math:`D` is the spatial dimension of the simulation system. Usually is 3. """ # (B,A,D) = (B,A,D) * (B,A,1) acceleration = self.acc_unit_scale * force * self._inv_mass # v(t+0.5) = v(t-0.5) + a(t) * dt velocity_half = velocity + acceleration * self.time_step # (B,A,D) = (B,A,D) - (B,1,D) velocity_half -= self.get_com_velocity(velocity_half) kinetics = self.get_kinetics(velocity_half) # R(t+0.5) = R(t) + v(t+0.5) * dt coordinate_half = coordinate + velocity_half * self.time_step * 0.5 if self.thermostat is not None: # v'(t+0.5) = f_T[v(t+0.5)] coordinate_half, velocity_half, force, energy, kinetics, virial, pbc_box = \ self.thermostat(coordinate_half, velocity_half, force, energy, kinetics, virial, pbc_box, step) # R(t+1) = R(t+0.5) + v'(t+0.5) * dt coordinate_new = coordinate_half + velocity_half * self.time_step * 0.5 if self.constraint is not None: for i in range(self.num_constraint_controller): coordinate_new, velocity_half, force, energy, kinetics, virial, pbc_box = \ self.constraint[i](coordinate_new, velocity_half, force, energy, kinetics, virial, pbc_box, step) if self.barostat is not None: coordinate_new, velocity_half, force, energy, kinetics, virial, pbc_box = \ self.barostat(coordinate_new, velocity_half, force, energy, kinetics, virial, pbc_box, step) return coordinate_new, velocity_half, force, energy, kinetics, virial, pbc_box