add: task 3 and 4,
cleanup: moved non task specific code to seperate file
This commit is contained in:
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cdf9e3104f
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#!/usr/bin/env python
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import numpy as np
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from jax import numpy as jnp, jit, grad
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# toy moleculat dynamic system parameters (constants)
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De = 1.6 # [eV (electronvolt)]
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alpha = 3.028 # [A^-1]
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re = 1.411 # [A]
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mass = 18.998403 # atomic mass of a single particle
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def dump(file, position, velocity, box_size, mode = "w", comment = ""):
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"""
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Dumps `position` and `velocity` to `file` with meta data.
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First writes a header to `file` in `mode` file write mode defines as three
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lines.
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`<nr of particles [int]>`
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`<comment (ignored)>`
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`<box side lenght [float]>`
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then each line (nr of particles many) have the form `x y z vx vy vx`.
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"""
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header = [str(position.shape[0]), comment, str(box_size)]
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data = np.hstack((position, velocity))
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np.savetxt(file, data, comments = "", header = "\n".join(header))
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def load(file):
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"""
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Loads a state from `file` and returns the `position` and `velocity` system
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states as two `numpy` arrays.
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As a side effect the config object as agumented with `file` header info.
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"""
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if isinstance(file, str):
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with open(file) as handle:
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return load(handle)
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# read header
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nr_particles = int(file.readline().strip())
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file.readline() # ignore comment line
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box_size = float(file.readline().strip())
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# read the state data, each line constains `x y z vx vy vz`
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data = np.loadtxt(file, max_rows = nr_particles)
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return np.hsplit(data, 2), box_size
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def iter_load(file):
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"""
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Iterator yielding similar to `load` entries from `file` in the same format.
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"""
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if isinstance(file, str):
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with open(file) as handle:
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yield from iter_load(handle)
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else:
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while True:
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# read header
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line = file.readline().strip()
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if not line:
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return
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nr_particles = int(line)
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file.readline() # ignore comment line
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line = file.readline().strip()
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if not line:
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return
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box_size = float(line)
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# read the state data, each line constains `x y z vx vy vz`
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data = np.loadtxt(file, max_rows = nr_particles)
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if not data.shape[0] == nr_particles:
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return
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yield np.hsplit(data, 2), box_size
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def print_prog_bar(index, max_index):
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"""
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Simple progress bar. Just for convenience.
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"""
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if (index % 100) and (max_index != index + 1):
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return
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progress = (30 * (index + 1)) // max_index
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print(f"\r{(index + 1)}/{max_index} - " \
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f"[{'':=>{(progress)}}{'': >{(30 - progress)}}]",
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end = "\n" if max_index == index + 1 else "",
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flush = True)
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@jit
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def energy(position, box_size):
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"""
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Computes the potential energy of a system of particles with `position` using
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Morses potential.
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"""
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# enforce expected shape
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# (`scipy.optimize.minimize` drops shape information)
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if len(position.shape) == 1:
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position = position.reshape((position.shape[0] // 3, 3))
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# compute all pairwise position differences (all!)
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diff = position[:, jnp.newaxis, :] - position
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# extract only one of two distance combinations of non-equal particles
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lower_tri = jnp.tril_indices(position.shape[0], k = -1)
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diff = diff[lower_tri[0], lower_tri[1], :]
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# fold space in all directions. The `max_dist` is the maximum distance
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# in the folded space untill the distance through the folded space
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# border is smaller than inside the box. 3-axis parallel fold
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max_dist = box_size / 2.0
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diff = jnp.mod(diff + max_dist, box_size) - max_dist
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# Compute distances
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dist = jnp.linalg.norm(diff, axis = 1)
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# calc inbetween exp(.) expression
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ex = jnp.exp(-alpha * (dist - re))
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# evaluate Morse potential
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return De * jnp.sum(ex * (ex - 2.0))
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@jit
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def force(position, box_size):
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"""
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Computes the forces acting on each particle in `position` as the negative
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gradient of the potential energy.
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"""
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return -grad(energy)(position, box_size)
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@jit
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def kinetic(velocity):
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"""
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Computes the kenetic energy given a systems `velocity` state.
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"""
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return (mass / 2.0) * jnp.linalg.norm(velocity, axis = 1).sum()
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@jit
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def step(position, velocity, acceleration, box_size, step_size):
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"""
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Performs a single Newton time step with `step_size` given system state
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through the current particle `position`, `velocity` and `acceleration`.
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"""
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# update position with a second order Taylor expantion
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position += step_size * velocity + (0.5 * step_size**2) * acceleration
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# compute new particle acceleration through Newton’s second law of motion
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acceleration_next = force(position, box_size) / mass
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# update velocity with a finite mean approximation
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velocity += (0.5 * step_size) * (acceleration + acceleration_next)
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# updated state
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return position, velocity, acceleration_next
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@ -1,130 +1,113 @@
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#!/usr/bin/env python
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from optparse import OptionParser # to parse script parameters
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import scipy
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import numpy as np # static objects like constants (and outside functions)
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from jax import numpy as jnp # tracable objects like particle positions
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from jax import jit, grad, vmap
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################################################################################
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### parse script parameters ###
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################################################################################
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from optparse import OptionParser
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# Parte script parameters
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arg_parser = OptionParser()
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usage = "usage: %prog [options] [<NR_PARTICLES>] [<BOX_SIZE>] [<TEMPERATURE>]"
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arg_parser = OptionParser(usage = usage)
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arg_parser.add_option("-M", "--particles", action = "store", type = int,
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dest = "nr_particles", help = "Nr. of particles", default = 1000)
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dest = "nr_particles", default = -1,
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help = "Nr. of particles (required!)")
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arg_parser.add_option("-L", "--box_size", action = "store", type = float,
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dest = "box_size", help = "side box_size [A (angstrom)] of the simulation cube",
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default = 15.0)
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arg_parser.add_option("-T", "--temp", action = "store", type = float,
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dest = "temp", help = "temperature [K] to generate initial conditions",
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default = 300.0)
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arg_parser.add_option("-f", "--file", action = "store", type = str,
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dest = "path", help = "output file path",
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default = "task02.xyz")
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arg_parser.add_option("-p", "--plot", action = "store", type = str,
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dest = "plot", help = "output file path for a plot of the configuration " \
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"(default: no plot generated)",
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default = None)
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arg_parser.add_option("-v", action = "store_true", dest = "verbose",
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default = False, help = "turn verbosity mode on (default: off a.k.a. silent)")
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dest = "box_size", default = -1.0,
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help = "side box_size [A (angstrom)] of the simulation cube (required!)")
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arg_parser.add_option("-T", "--temperature", action = "store", type = float,
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dest = "temperature", default = -1.0,
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help = "temperature [K] to generate initial conditions (required!)")
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arg_parser.add_option("-o", "--output", action = "store", type = str,
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dest = "output", default = "task02.xyz",
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help = "output file path (default: 'task02.xyz')")
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arg_parser.add_option("-v", action = "store_true",
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dest = "verbose", default = False,
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help = "turn verbosity mode on (default: off a.k.a. silent)")
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# Parse command line arguments (as def. above) or store defaults to `config`
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config, args = arg_parser.parse_args()
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# overwrite options with positional arguments if supplied
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try:
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if len(args) > 0:
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config.nr_particles = int(args[0])
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if len(args) > 1:
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config.box_size = float(args[1])
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if len(args) > 2:
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config.temperature = float(args[2])
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except ValueError as expression:
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arg_parser.print_help()
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print(f"Error: {expression}")
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exit(-1)
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else:
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# quick and dirty validation
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if not config.nr_particles > 0 \
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or not config.box_size > 0.0 \
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or not config.temperature > 0.0:
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arg_parser.print_help()
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print("Error: missing or illegal argument")
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exit(-1)
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# toy moleculat dynamic system parameters
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De = 1.6 # [eV (electronvolt)]
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alpha = 3.028 # [A^-1]
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re = 1.411 # [A]
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mass = 18.998403 # atomic mass of a single particle
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def dump(position, velocity, box_size = config.box_size, \
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path = config.path, mode = "w", comment = ""):
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"""
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Dumps `position` and `velocity` to `path` with meta data.
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First writes a header to `path` in `mode` file write mode defines as three
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lines.
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`<nr of particles [int]>`
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`<comment (ignored)>`
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`<box side lenght [float]>`
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then each line (nr of particles many) have the form `x y z vx vy vx`.
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"""
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with open(path, mode) as file:
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# write headers
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print(position.shape[0], comment, box_size, sep = "\n", file = file)
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# store position and velocity for with `x y z vx vy vz` entries per line`
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for (x, y, z), (vx, vy, vz) in zip(position, velocity):
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print(x, y, z, vx, vy, vz, file = file)
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@jit
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def energy(position):
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"""
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Computes the potential energy of a system of particles with `position` using
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Morses potential.
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"""
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# enforce expected shape
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# (`scipy.optimize.minimize` drops shape information)
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position = position.reshape((config.nr_particles, 3))
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# compute all pairwise position differences (all!)
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diff = position[:, jnp.newaxis, :] - position
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# extract only one of two distance combinations of non-equal particles
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lower_tri = jnp.tril_indices(config.nr_particles, k = -1)
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diff = diff[lower_tri[0], lower_tri[1], :]
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# fold space in all directions. The `max_dist` is the maximum distance
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# in the folded space untill the distance through the folded space
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# border is smaller than inside the box. 3-axis parallel fold
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max_dist = config.box_size / 2
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diff = jnp.mod(diff + max_dist, 2 * max_dist) - max_dist
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# Compute distances
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dist = jnp.linalg.norm(diff, axis = 1)
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# calc inbetween exp(.) expression
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ex = jnp.exp(-alpha * (dist - re))
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# evaluate Morse potential
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return De * jnp.sum(ex * (ex - 2.0))
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@jit
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def force(position):
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"""
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Computes the forces acting on each particle in `position` as the gradient of
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the potential energy. (a.k.a. the derivative (gradient) of `energy`)
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"""
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return grad(energy)(position)
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################################################################################
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### task 2 / generation of initial conditions ###
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################################################################################
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# note, load module _after_ processing script parameters (no need to load all
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# of the heavy numeric modules if only usage or alike is needed)
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import numpy as np
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import scipy
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from jax import jit, grad
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from molecular_dynamics import dump, energy, force, mass
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# Sample random positions in a 3D cube (TODO: make this not just uniform :-})
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position = np.random.uniform(0.0, config.box_size, (config.nr_particles, 3))
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# Sample particle velocities
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sd = np.sqrt(scipy.constants.Boltzmann * config.temp / mass)
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sd = np.sqrt(scipy.constants.Boltzmann * config.temperature / mass)
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velocity = np.random.normal(0.0, sd, (config.nr_particles, 3))
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# center velocities
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velocity -= velocity.mean(axis = 0)
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# remember energy before optimizing for a low energy state
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initial_energy = energy(position)
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initial_energy = energy(position, config.box_size)
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forces = force(position, config.box_size)
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initial_mean_forces = forces.mean(axis = 0)
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initial_mean_fnorm = np.linalg.norm(forces, axis = 1).mean()
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# optimize energy to find low energy system state using Conjugate-Gradients
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optim = scipy.optimize.minimize(energy, x0 = position, jac = force, method = "CG")
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optim = scipy.optimize.minimize(energy, # objective func.
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jac = jit(grad(energy)), # jacobian
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x0 = position, # initial position
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args = (config.box_size, ), # further args
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method = "CG")
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# extract (and reshape) optimization result
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position = optim.x.reshape((config.nr_particles, 3))
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# ensure all particles are in the box
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position = np.mod(position, config.box_size)
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# recompute stats after optimizing for low energy state
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final_energy = energy(position)
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mean_forces = force(position).mean(axis = 0)
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final_energy = energy(position, config.box_size)
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forces = force(position, config.box_size)
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final_mean_forces = forces.mean(axis = 0)
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final_mean_fnorm = np.linalg.norm(forces, axis = 1).mean()
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# store state snapshot to file (default target file defined by script args)
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dump(position, velocity)
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dump(config.output, position, velocity, config.box_size)
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# report stats (if requested by `-v` script argument)
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if config.verbose:
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print("Initial Energy: {:.4e}".format(initial_energy))
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print("Final Energy: {:.4e}".format(final_energy))
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print("Mean Forces: {:.4e} {:.4e} {:.4e}".format(*mean_forces))
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print(f"Initial Energy: {initial_energy:.4e}")
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print( "Initial Mean Forces: {:.4e} {:.4e} {:.4e}".format(*initial_mean_forces))
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print(f"Initial Mean ||Forces||: {initial_mean_fnorm:.4e}")
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print(f"Final Energy: {final_energy:.4e}")
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print( "Final Mean Forces: {:.4e} {:.4e} {:.4e}".format(*final_mean_forces))
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print(f"Final Mean ||Forces||: {final_mean_fnorm:.4e}")
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print(f"Done: saved inital state to '{config.output}'")
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# if a plot path is provided
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if not config.plot is None:
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from mpl_toolkits import mplot3d
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import matplotlib.pyplot as plt
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# new plot with 3D axis
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plt.figure()
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ax = plt.axes(projection = "3d")
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# create 3D position scatter plot
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ax.scatter(position[:, 0], position[:, 1], position[:, 2])
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# and save to file
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plt.savefig(config.plot)
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# # if a plot path is provided
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# if not config.plot is None:
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# from mpl_toolkits import mplot3d
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# import matplotlib.pyplot as plt
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# # new plot with 3D axis
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# plt.figure()
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# ax = plt.axes(projection = "3d")
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# # create 3D position scatter plot
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# ax.scatter(position[:, 0], position[:, 1], position[:, 2])
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# # and save to file
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# plt.savefig(config.plot)
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#!/usr/bin/env python
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################################################################################
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### parse script parameters ###
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################################################################################
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from optparse import OptionParser
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usage = "usage: %prog [options] [<INPUT>] [<STEP_SIZE>] [<ITERATIONS>]"
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arg_parser = OptionParser(usage = usage)
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arg_parser.add_option("-i", "--input", action = "store", type = str,
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dest = "input", default = None,
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help = "input file path (required!)")
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arg_parser.add_option("-t", "--step_size", action = "store", type = float,
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dest = "step_size", default = -1.0,
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help = "time step size (Delta t) for integration (required!)")
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arg_parser.add_option("-N", "--iterations", action = "store", type = int,
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dest = "iterations", default = -1,
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help = "Number of time steps used for Newton's equation integration (required!)")
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arg_parser.add_option("-o", "--output", action = "store", type = str,
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dest = "output", default = "task03.xyz",
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help = "output file path (default: 'task03.xyz')")
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arg_parser.add_option("-v", action = "store_true",
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dest = "verbose", default = False,
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help = "turn verbosity mode on (default: off a.k.a. silent)")
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# Parse command line arguments (as def. above) or store defaults to `config`
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config, args = arg_parser.parse_args()
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# overwrite options with positional arguments if supplied
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try:
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if len(args) > 0:
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config.input = args[0]
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if len(args) > 1:
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config.step_size = float(args[1])
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if len(args) > 2:
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config.iterations = int(args[2])
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except ValueError as expression:
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arg_parser.print_help()
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print(f"Error: {expression}")
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exit(-1)
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else:
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# quick and dirty validation
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if not config.step_size > 0.0 \
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or not config.iterations > 0 \
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or config.input is None:
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arg_parser.print_help()
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print("Error: missing or illegal argument")
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exit(-1)
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################################################################################
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### task 3 / trajectory generation ###
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################################################################################
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# note, load module _after_ processing script parameters (no need to load all
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# of the heavy numeric modules if only usage or alike is needed)
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from molecular_dynamics import load, dump, force, mass, step, print_prog_bar
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# load initial state from file
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(position, velocity), box_size = load(config.input)
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# compute initial acceleration using Newton’s second law of motion
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acceleration = force(position, box_size) / mass
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# iterate time steps for system time evolution
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with open(config.output, "w") as output:
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# store initial state to file
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dump(output, position, velocity, box_size)
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# perform iterations many time steps
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for iteration in range(1, config.iterations):
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# perform a single time step
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position, velocity, acceleration = step(position, velocity, acceleration,
|
||||
box_size, config.step_size)
|
||||
# dump current state to file
|
||||
dump(output, position, velocity, box_size)
|
||||
# if verbosity turned on, print a progress bar
|
||||
if config.verbose:
|
||||
print_prog_bar(iteration, config.iterations)
|
||||
|
||||
# report output file path
|
||||
print(f"Done: trajectories saved to '{config.output}'")
|
|
@ -0,0 +1,66 @@
|
|||
#!/usr/bin/env python
|
||||
|
||||
################################################################################
|
||||
### parse script parameters ###
|
||||
################################################################################
|
||||
from optparse import OptionParser
|
||||
|
||||
usage = "usage: %prog [options] [<INPUT>]"
|
||||
arg_parser = OptionParser(usage = usage)
|
||||
arg_parser.add_option("-i", "--input", action = "store", type = str,
|
||||
dest = "input", default = None,
|
||||
help = "input file path (required!)")
|
||||
arg_parser.add_option("-a", "--animate", action = "store_true",
|
||||
dest = "animate", default = False,
|
||||
help = "creates an trajectory animation of the states in the input file")
|
||||
# Parse command line arguments (as def. above) or store defaults to `config`
|
||||
config, args = arg_parser.parse_args()
|
||||
# overwrite options with positional arguments if supplied
|
||||
try:
|
||||
if len(args) > 0:
|
||||
config.input = args[0]
|
||||
except ValueError as expression:
|
||||
arg_parser.print_help()
|
||||
print(f"Error: {expression}")
|
||||
exit(-1)
|
||||
else:
|
||||
# quick and dirty validation
|
||||
if config.input is None:
|
||||
arg_parser.print_help()
|
||||
print("Error: missing or illegal argument")
|
||||
exit(-1)
|
||||
|
||||
################################################################################
|
||||
### task 3 / trajectory generation ###
|
||||
################################################################################
|
||||
# note, load module _after_ processing script parameters (no need to load all
|
||||
# of the heavy numeric modules if only usage or alike is needed)
|
||||
import numpy as np
|
||||
import matplotlib.pyplot as plt
|
||||
from mpl_toolkits import mplot3d
|
||||
from molecular_dynamics import iter_load, energy, kinetic
|
||||
|
||||
if config.animate:
|
||||
# new plot with 3D axis
|
||||
fig = plt.figure()
|
||||
ax = fig.add_subplot(111, projection = "3d")
|
||||
|
||||
count = 0
|
||||
for (position, velocity), box_size in iter_load(config.input):
|
||||
count += 1
|
||||
e_pot = energy(position, box_size)
|
||||
e_kin = kinetic(velocity)
|
||||
print(f"{count: >3} - {e_pot:10.5e} {e_kin:10.5e} {(e_pot + e_kin):10.5e}")
|
||||
|
||||
if config.animate:
|
||||
ax.cla()
|
||||
plt.title(f"time step {count}")
|
||||
plt.xlim([0, box_size])
|
||||
plt.ylim([0, box_size])
|
||||
ax.set_zlim([0, box_size])
|
||||
# create 3D position scatter plot
|
||||
position = np.mod(position, box_size)
|
||||
ax.scatter(position[:, 0], position[:, 1], position[:, 2])
|
||||
# # and save to file
|
||||
# plt.savefig(config.plot)
|
||||
plt.pause(0.01)
|
Loading…
Reference in New Issue