def test_ndaisies(n_daisies):
P = 1
gamma = 0.3
a_vec = np.array([1 / (n_daisies + 1) for i in range(n_daisies)])
#A_vec = np.random.uniform(0, 0.5, size=n_daisies)
A_vec = np.linspace(0.05, 0.75, n_daisies)
T_vec = np.random.normal(295., 10., size=n_daisies)
#T_vec = 295 * np.ones(n_daisies)
#tube = Tube(P=1, gamma=0.3,
#a_vec=np.array([1/(n_daisies + 1) for i in range(n_daisies)]),
#A_vec=np.random.uniform(size=n_daisies),
#T_vec=np.random.normal(295., 10., size=n_daisies))
#tube.setupGrid(40, 40, 80)
#tube._updategrid()
#phis = [0, 1.57, 3.14, 4.71]
phis = np.linspace(-0.39, 0.39, 9)
phis = [0.]
for phi in phis:
tube = Tube(P=P,
gamma=gamma,
a_vec=a_vec,
A_vec=A_vec,
phi=phi,
T_vec=T_vec)
tube.setupGrid(0, 0, 80, oceans=True, inputfile='test.world')
#tube.plot(r'Daisyworld init', ptype='albedo')
for i in range(100):
print(f"{i}")
tube._updategrid()
tube.plot(f"Daisyworld w/ {n_daisies} daisies")
tube.plot(f"Daisyworld w/ {n_daisies} daisies", ptype='albedo')
gamma=gamma,
a_vec=a_vec,
A_vec=A_vec,
phi=phi,
T_vec=T_vec)
tube.setupGrid(0, 0, 80, oceans=True, inputfile='harrison.world')
tube.plot(r'Daisyworld init', savefig="temps_init.png")
tube.plot(r'Daisyworld init albedos',
ptype='albedo',
savefig='albedos_init.png')
#tube.plot(r'Daisyworld init', ptype='albedo')
for i in range(100):
print(f"{i}", end="\r")
tube._updategrid()
tube.plot(f'Daisyworld at {i} iterations',
savefig=f'figures/frame_{i:03d}.png',
ptype='temperature')
tube.plot(f'Daisyworld at {i} iterations',
savefig=f'figures/pop_frame_{i:03d}.png',
ptype='pops')
tube.plot(f'Daisyworld at {i} iterations',
savefig=f'figures/pop_frame_{i:03d}.png',
ptype='albedo')
for ndaisy in range(n_daisies):
tube.plot(f'Daisyworld at {i} iterations',
savefig=f'figures/pop_frame_{ndaisy}_{i:03d}.png',
ptype=f'{ndaisy}')
#if i % 10 == 0 and i > 1: