def test_histogram_along_axis_observable(self):
fname = os.path.join(self.dir, "test_observables_hist_along_axis.h5")
simulation = Simulation("SingleCPU")
box_size = [10.,10.,10.]
simulation.context.kbt = 2
simulation.context.pbc = [True, True, True]
simulation.context.box_size = box_size
simulation.context.particle_types.add("A", .2)
simulation.context.particle_types.add("B", .2)
simulation.context.potentials.add_harmonic_repulsion("A", "B", 10, 2.)
simulation.add_particle("A", common.Vec(-2.5, 0, 0))
simulation.add_particle("B", common.Vec(0, 0, 0))
bin_borders = np.arange(0, 5, .01)
n_time_steps = 50
callback_hist = []
def hist_callback(hist):
callback_hist.append(hist)
handle = simulation.register_observable_histogram_along_axis(2, bin_borders, 0, ["A", "B"], hist_callback)
with closing(io.File.create(fname)) as f:
handle.enable_write_to_file(f, u"hist_along_x_axis", int(3))
simulation.run(n_time_steps, 0.02)
handle.flush()
with h5py.File(fname, "r") as f2:
histogram = f2["readdy/observables/hist_along_x_axis/data"][:]
time_series = f2["readdy/observables/hist_along_x_axis/time"]
np.testing.assert_equal(time_series, np.array(range(0, n_time_steps+1))[::2])
for t in range(n_time_steps // 2):
np.testing.assert_equal(histogram[t], np.array(callback_hist[t]))
def test_histogram_along_axis_observable(self):
common.set_logging_level("warn")
fname = os.path.join(self.dir, "test_observables_hist_along_axis.h5")
simulation = Simulation()
simulation.set_kernel("SingleCPU")
box_size = common.Vec(10, 10, 10)
simulation.kbt = 2
simulation.periodic_boundary = [True, True, True]
simulation.box_size = box_size
simulation.register_particle_type("A", .2, 1.)
simulation.register_particle_type("B", .2, 1.)
simulation.register_potential_harmonic_repulsion("A", "B", 10)
simulation.add_particle("A", common.Vec(-2.5, 0, 0))
simulation.add_particle("B", common.Vec(0, 0, 0))
bin_borders = np.arange(0, 5, .01)
n_time_steps = 50
callback_hist = []
def hist_callback(hist):
callback_hist.append(hist)
handle = simulation.register_observable_histogram_along_axis(
2, bin_borders, 0, ["A", "B"], hist_callback)
with closing(
io.File(fname, io.FileAction.CREATE,
io.FileFlag.OVERWRITE)) as f:
handle.enable_write_to_file(f, u"hist_along_x_axis", int(3))
simulation.run(n_time_steps, 0.02)
handle.flush()
with h5py.File(fname, "r") as f2:
histogram = f2["readdy/observables/hist_along_x_axis/data"][:]
time_series = f2["readdy/observables/hist_along_x_axis/time"]
np.testing.assert_equal(time_series,
np.array(range(0, n_time_steps + 1))[::2])
for t in range(n_time_steps // 2):
np.testing.assert_equal(histogram[t],
np.array(callback_hist[t]))
def execute(self):
###################################
#
# Units:
# - [x] = µm
# - [t] = s
# - [E] = kJ/mol
#
###################################
kernel_provider = KernelProvider.get()
kernel_provider.load_from_dir(platform_utils.get_readdy_plugin_dir())
simulation = Simulation()
simulation.set_kernel("CPU")
###################################
#
# set up simulation box
#
###################################
box_size = Vec(2, 7, 12)
simulation.box_size = box_size
simulation.kbt = 2.437 # room temperature
simulation.periodic_boundary = [False, False, False]
###################################
#
# register particle types
#
###################################
# particle size, see: http://bmccellbiol.biomedcentral.com/articles/10.1186/1471-2121-5-29
# "The size of the V-ATPase complex is about 15 nm (diameter) x 25 nm (length from lumen side to tip of head)"
membrane_particle_size = .05
diffusion_factor = .5
simulation.register_particle_type("D", 2.5 * diffusion_factor,
.01) # MinD-ADP (without phosphor)
simulation.register_particle_type("D_P", 2.5 * diffusion_factor,
.01) # MinD-ATP (with phosphor)
simulation.register_particle_type("E", 2.5 * diffusion_factor,
.01) # MinE
simulation.register_particle_type("D_PB", .01 * diffusion_factor,
.01) # MinD-ATP bound
simulation.register_particle_type("DE", .01 * diffusion_factor,
.01) # MinDE
###################################
#
# register reaction types
#
###################################
reaction_radius = 4 * (
0.01 + 0.01
) # = sum of the particle radii * 5 (5 - magic number such that k_fusion makes sense, sort of) 5 *
# k_fusion = brentq(lambda x: self.erban_chapman(.093, 2.5 + .01, reaction_radius, x), 1, 5000000)
k_fusion = 1.0
print("k_fusion=%s" % k_fusion)
simulation.register_reaction_conversion("Phosphorylation", "D", "D_P",
.5)
simulation.register_reaction_fusion("bound MinD+MinE->MinDE", "D_PB",
"E", "DE", k_fusion,
reaction_radius * 3.5, .5, .5)
simulation.register_reaction_fission("MinDE to MinD and MinE, detach",
"DE", "D", "E", .25,
reaction_radius, .5, .5)
###################################
#
# register potentials
#
###################################
membrane_size = Vec(.5, 5, 10)
layer = Vec(.08, .08, .08)
extent = membrane_size + 2 * layer
origin = -.5 * membrane_size - layer
simulation.register_potential_box(
"D", 10., origin, extent,
False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box(
"D_P", 10., origin, extent,
False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box(
"D_PB", 10., origin, extent,
False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box(
"E", 10., origin, extent,
False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box(
"DE", 10., origin, extent,
False) # (force constant, origin, extent, considerParticleRadius)
# simulation.register_potential_piecewise_weak_interaction("D_P", "D_PB", 3, .02, 2, .05) # (force constant, desired dist, depth, no interaction dist)
###################################
#
# membrane particles
#
###################################
using_membrane_particles = False
if using_membrane_particles:
simulation.register_particle_type(
"M", 0, membrane_particle_size) # membrane particle
simulation.register_reaction_enzymatic(
"Attach to membrane", "M", "D_P", "D_PB", .5,
.01 + membrane_particle_size) # .01 + .025 # todo: rate?
dx = np.linspace(
origin[0] + layer[0],
-1 * origin[0] - layer[0],
int(float(membrane_size[0]) / membrane_particle_size),
endpoint=True)
dy = np.linspace(
origin[1] + layer[1],
-1 * origin[1] - layer[1],
int(float(membrane_size[1]) / membrane_particle_size),
endpoint=True)
dz = np.linspace(
origin[2] + layer[2],
-1 * origin[2] - layer[2],
int(float(membrane_size[2]) / membrane_particle_size),
endpoint=True)
for y in dy:
for z in dz:
simulation.add_particle(
"M", Vec(-1 * origin[0] - layer[0], y, z))
print("done adding membrane particles")
else:
simulation.register_reaction_conversion("Phosphorylation", "D_P",
"D_PB", .5)
simulation.register_reaction_enzymatic(
"Enzymatic DP+DPB->DPB + DPB", "D_PB", "D_P", "D_PB", .5, .02)
using_uniform_distribution = True
n_minE_particles = 3120
n_minD_particles = n_minE_particles * 4
mine_x = np.random.uniform(origin[0] + layer[0],
-1 * origin[0] - layer[0], n_minE_particles)
mine_y = np.random.uniform(origin[1] + layer[1],
-1 * origin[1] - layer[1], n_minE_particles)
if using_uniform_distribution:
mine_z = np.random.uniform(origin[2] + layer[2],
-1 * origin[2] - layer[2],
n_minE_particles)
else:
mine_z = np.random.uniform(origin[2] + layer[2],
.5 * (-1 * origin[2] - layer[2]),
n_minE_particles)
mind_x = np.random.uniform(origin[0] + layer[0],
-1 * origin[0] - layer[0], n_minD_particles)
mind_y = np.random.uniform(origin[1] + layer[1],
-1 * origin[1] - layer[1], n_minD_particles)
if using_uniform_distribution:
mind_z = np.random.uniform(origin[2] + layer[2],
-1 * origin[2] - layer[2],
n_minD_particles)
else:
mind_z = np.random.uniform(.5 * (-1 * origin[2] - layer[2]),
-1 * origin[2] - layer[2],
n_minD_particles)
for i in range(n_minE_particles):
simulation.add_particle("E", Vec(mine_x[i], mine_y[i], mine_z[i]))
for i in range(int(.5 * n_minD_particles)):
simulation.add_particle("D", Vec(mind_x[i], mind_y[i], mind_z[i]))
for i in range(int(.5 * n_minD_particles), n_minD_particles):
simulation.add_particle("D_P", Vec(mind_x[i], mind_y[i],
mind_z[i]))
self.timestep = simulation.get_recommended_time_step(2)
###################################
#
# register observables
#
###################################
# simulation.register_observable_center_of_mass(1, self.com_callback_mind, ["D", "D_P", "D_PB"])
# simulation.register_observable_center_of_mass(1, self.com_callback_mine, ["E"])
# simulation.register_observable_center_of_mass(1, self.com_callback_minde, ["DE", "D_PB"])
print("histogram start")
# simulation.register_observable_histogram_along_axis(100, self.histrogram_callback_minD, np.arange(-3, 3, .1), ["D", "D_P", "D_PB"], 2)
# simulation.register_observable_histogram_along_axis(100, self.histrogram_callback_minE, np.arange(-3, 3, .1), ["D_PB", "DE"], 2)
stride = int(.01 / self.timestep)
self.stride = stride
print("using stride=%s" % stride)
bins = np.linspace(-7, 7, 80)
simulation.register_observable_histogram_along_axis(
stride, bins, 2, ["D"], self.histogram_callback_minD)
simulation.register_observable_histogram_along_axis(
stride, bins, 2, ["D_P"], self.histogram_callback_minDP)
simulation.register_observable_histogram_along_axis(
stride, bins, 2, ["D_PB"], self.histogram_callback_minDPB)
simulation.register_observable_histogram_along_axis(
stride, bins, 2, ["E"], self.histogram_callback_minE)
simulation.register_observable_histogram_along_axis(
stride, bins, 2, ["DE"], self.histogram_callback_minDE)
simulation.register_observable_histogram_along_axis(
stride, bins, 2, ["D", "D_P", "D_PB", "DE"],
self.histogram_callback_M)
simulation.register_observable_n_particles(
stride, ["D", "D_P", "D_PB", "E", "DE"], self.n_particles_callback)
print("histogram end")
self.n_timesteps = int(1200. / self.timestep)
print("starting simulation for effectively %s sec" %
(self.timestep * self.n_timesteps))
simulation.run_scheme_readdy(True).with_reaction_scheduler(
"GillespieParallel").configure(self.timestep).run(self.n_timesteps)
if self._result_fname is not None:
with open(self._result_fname, 'w') as f:
np.save(f, np.array(self._hist_data))
def execute(self):
###################################
#
# Units:
# - [x] = µm
# - [t] = s
# - [E] = kJ/mol
#
###################################
kernel_provider = KernelProvider.get()
kernel_provider.load_from_dir(platform_utils.get_readdy_plugin_dir())
simulation = Simulation()
simulation.set_kernel("CPU")
###################################
#
# set up simulation box
#
###################################
box_size = Vec(2, 7, 12)
simulation.box_size = box_size
simulation.kbt = 2.437 # room temperature
simulation.periodic_boundary = [False, False, False]
###################################
#
# register particle types
#
###################################
# particle size, see: http://bmccellbiol.biomedcentral.com/articles/10.1186/1471-2121-5-29
# "The size of the V-ATPase complex is about 15 nm (diameter) x 25 nm (length from lumen side to tip of head)"
membrane_particle_size = .05
diffusion_factor = .5
simulation.register_particle_type("D", 2.5 * diffusion_factor, .01) # MinD-ADP (without phosphor)
simulation.register_particle_type("D_P", 2.5 * diffusion_factor, .01) # MinD-ATP (with phosphor)
simulation.register_particle_type("E", 2.5 * diffusion_factor, .01) # MinE
simulation.register_particle_type("D_PB", .01 * diffusion_factor, .01) # MinD-ATP bound
simulation.register_particle_type("DE", .01 * diffusion_factor, .01) # MinDE
###################################
#
# register reaction types
#
###################################
reaction_radius = 4*(0.01 + 0.01) # = sum of the particle radii * 5 (5 - magic number such that k_fusion makes sense, sort of) 5 *
# k_fusion = brentq(lambda x: self.erban_chapman(.093, 2.5 + .01, reaction_radius, x), 1, 5000000)
k_fusion = 1.0
print("k_fusion=%s" % k_fusion)
simulation.register_reaction_conversion("Phosphorylation", "D", "D_P", .5)
simulation.register_reaction_fusion("bound MinD+MinE->MinDE", "D_PB", "E", "DE", k_fusion, reaction_radius*3.5, .5, .5)
simulation.register_reaction_fission("MinDE to MinD and MinE, detach", "DE", "D", "E", .25, reaction_radius, .5, .5)
###################################
#
# register potentials
#
###################################
membrane_size = Vec(.5, 5, 10)
layer = Vec(.08, .08, .08)
extent = membrane_size + 2 * layer
origin = -.5 * membrane_size - layer
simulation.register_potential_box("D", 10., origin, extent, False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box("D_P", 10., origin, extent, False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box("D_PB", 10., origin, extent, False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box("E", 10., origin, extent, False) # (force constant, origin, extent, considerParticleRadius)
simulation.register_potential_box("DE", 10., origin, extent, False) # (force constant, origin, extent, considerParticleRadius)
# simulation.register_potential_piecewise_weak_interaction("D_P", "D_PB", 3, .02, 2, .05) # (force constant, desired dist, depth, no interaction dist)
###################################
#
# membrane particles
#
###################################
using_membrane_particles = False
if using_membrane_particles:
simulation.register_particle_type("M", 0, membrane_particle_size) # membrane particle
simulation.register_reaction_enzymatic("Attach to membrane", "M", "D_P", "D_PB", .5, .01 + membrane_particle_size) # .01 + .025 # todo: rate?
dx = np.linspace(origin[0] + layer[0], -1 * origin[0] - layer[0], int(float(membrane_size[0]) / membrane_particle_size), endpoint=True)
dy = np.linspace(origin[1] + layer[1], -1 * origin[1] - layer[1], int(float(membrane_size[1]) / membrane_particle_size), endpoint=True)
dz = np.linspace(origin[2] + layer[2], -1 * origin[2] - layer[2], int(float(membrane_size[2]) / membrane_particle_size), endpoint=True)
for y in dy:
for z in dz:
simulation.add_particle("M", Vec(-1 * origin[0] - layer[0], y, z))
print("done adding membrane particles")
else:
simulation.register_reaction_conversion("Phosphorylation", "D_P", "D_PB", .5)
simulation.register_reaction_enzymatic("Enzymatic DP+DPB->DPB + DPB", "D_PB", "D_P", "D_PB", .5, .02)
using_uniform_distribution = True
n_minE_particles = 3120
n_minD_particles = n_minE_particles * 4
mine_x = np.random.uniform(origin[0] + layer[0], -1 * origin[0] - layer[0], n_minE_particles)
mine_y = np.random.uniform(origin[1] + layer[1], -1 * origin[1] - layer[1], n_minE_particles)
if using_uniform_distribution:
mine_z = np.random.uniform(origin[2] + layer[2], -1 * origin[2] - layer[2], n_minE_particles)
else:
mine_z = np.random.uniform(origin[2] + layer[2], .5 * (-1 * origin[2] - layer[2]), n_minE_particles)
mind_x = np.random.uniform(origin[0] + layer[0], -1 * origin[0] - layer[0], n_minD_particles)
mind_y = np.random.uniform(origin[1] + layer[1], -1 * origin[1] - layer[1], n_minD_particles)
if using_uniform_distribution:
mind_z = np.random.uniform(origin[2] + layer[2], -1 * origin[2] - layer[2], n_minD_particles)
else:
mind_z = np.random.uniform(.5 * (-1 * origin[2] - layer[2]), -1 * origin[2] - layer[2], n_minD_particles)
for i in range(n_minE_particles):
simulation.add_particle("E", Vec(mine_x[i], mine_y[i], mine_z[i]))
for i in range(int(.5 * n_minD_particles)):
simulation.add_particle("D", Vec(mind_x[i], mind_y[i], mind_z[i]))
for i in range(int(.5 * n_minD_particles), n_minD_particles):
simulation.add_particle("D_P", Vec(mind_x[i], mind_y[i], mind_z[i]))
self.timestep = simulation.get_recommended_time_step(2)
###################################
#
# register observables
#
###################################
# simulation.register_observable_center_of_mass(1, self.com_callback_mind, ["D", "D_P", "D_PB"])
# simulation.register_observable_center_of_mass(1, self.com_callback_mine, ["E"])
# simulation.register_observable_center_of_mass(1, self.com_callback_minde, ["DE", "D_PB"])
print("histogram start")
# simulation.register_observable_histogram_along_axis(100, self.histrogram_callback_minD, np.arange(-3, 3, .1), ["D", "D_P", "D_PB"], 2)
# simulation.register_observable_histogram_along_axis(100, self.histrogram_callback_minE, np.arange(-3, 3, .1), ["D_PB", "DE"], 2)
stride = int(.01/self.timestep)
self.stride = stride
print("using stride=%s" % stride)
bins = np.linspace(-7, 7, 80)
simulation.register_observable_histogram_along_axis(stride, bins, 2, ["D"], self.histogram_callback_minD)
simulation.register_observable_histogram_along_axis(stride, bins, 2, ["D_P"], self.histogram_callback_minDP)
simulation.register_observable_histogram_along_axis(stride, bins, 2, ["D_PB"], self.histogram_callback_minDPB)
simulation.register_observable_histogram_along_axis(stride, bins, 2, ["E"], self.histogram_callback_minE)
simulation.register_observable_histogram_along_axis(stride, bins, 2, ["DE"], self.histogram_callback_minDE)
simulation.register_observable_histogram_along_axis(stride, bins, 2, ["D", "D_P", "D_PB", "DE"], self.histogram_callback_M)
simulation.register_observable_n_particles(stride, ["D", "D_P", "D_PB", "E", "DE"], self.n_particles_callback)
print("histogram end")
self.n_timesteps = int(1200./self.timestep)
print("starting simulation for effectively %s sec" % (self.timestep * self.n_timesteps))
simulation.run_scheme_readdy(True).with_reaction_scheduler("GillespieParallel").configure(self.timestep).run(self.n_timesteps)
if self._result_fname is not None:
with open(self._result_fname, 'w') as f:
np.save(f, np.array(self._hist_data))
