Exemplo n.º 1
0
import numpy as np
import sys, os
import math

cwd = os.getcwd()
sys.path.append(cwd + '/..')
import spaths
from spaths.reactions import intermediate, Reaction

# seed setting
seed = 3579
rng = np.random.default_rng(seed)
rng.integers(10**3, size=10**3)  # warm up of RNG

# solver
em = spaths.EulerMaruyama(rng)

# simulation parameters
dt = 1e-4
nsam = 10
tspan = (0.0, 10.0)

# initial conditions
x0, y0 = [100.0] * nsam, [100.0] * nsam

Y = intermediate(1)
X = intermediate(0)
X2 = intermediate(0, 2)

c1 = 1.0
c2 = 100.0
Exemplo n.º 2
0
def dispersion_rqp(t, x, dx):
    dx[0, 1] = np.sqrt(2 * temp / tsep)
    dx[1, 0] = np.sqrt(2 * temp)
    dx[1, 1] = 2 * x[0] * np.sqrt(2 * temp / tsep)


# corresponding sde
sde_rqp = spaths.ItoSDE(drift_rqp, dispersion_rqp, noise_mixing_dim=2)

# seed setting and solvers
seed = 3579
rng_Fou = np.random.default_rng(seed)
rng_rqp = np.random.default_rng(seed)
rng_Fou.integers(10**4), rng_rqp.integers(10**4)  # warm up of RNG
em_Fou = spaths.EulerMaruyama(rng_Fou)
em_rqp = spaths.EulerMaruyama(rng_rqp)

# simulation params
dt = .1 * tsep
nsam = 4000
x0, y0 = 0.0, 0.0
tspan = (0.0, 5)
tsteps = (0.0, 10)

ens0 = np.array([[x0, y0] * nsam], dtype=np.float32).reshape(-1, 2)
x0 = ens0.T

print(np.allclose(sde_Fou.drif(0, x0), sde_rqp.drif(0, x0)))
print(np.allclose(sde_Fou.disp(0, x0), sde_rqp.disp(0, x0)))