Example #1
0
def write_in_ava_size():
    avalanche_size = []
    for i in range(len(length)):
        model = RelaxModel(0.5, length[i], time)
        model.start()
        avalanche_size.append(model.ava_size_list.copy())
    with open('avalanche_size.txt', 'wb') as fp:
        pickle.dump(avalanche_size, fp)
Example #2
0
def ave_height_f():
    for i in range(len(length)):
        model = RelaxModel(0.5,length[i],times)
        model.start()
        useful_height = model.heights[cross_over_time[i]+1:]
        ave = sum(useful_height)/len(useful_height)
        ave_height.append(ave)
    print('done 1')
    return ave_height
Example #3
0
def sigma_f():
    for i in range(len(length)):
        model = RelaxModel(0.5, length[i], times)
        model.start()
        useful_height = model.heights[cross_over_time[i] + 1:]
        ave = sum(useful_height) / len(useful_height)
        hh = [x * x for x in useful_height]
        sigma = (sum(hh) / len(useful_height) - ave**2)**(0.5)
        sigma_h.append((sigma))
    print(sigma_h)
    return sigma_h
Example #4
0
def h_tilde(M):
    length = [4, 8]
    times = 100000
    h_tilde = []
    for i in range(len(length)):
        h_data_base = [0] * times
        for j in range(M):
            model = RelaxModel(0.5, length[i], times)
            model.start()
            h_data_base = list(map(add, h_data_base, model.heights))
        h_data_base = [x / M for x in h_data_base]
        h_data_base = [round(i, 3) for i in h_data_base]
        h_tilde.append(h_data_base)
    return h_tilde
Example #5
0
def plot_ave_slop(length,times):
    data_base = []
    fig = plt.figure()
    ax = fig.add_subplot(1, 1, 1)
    for i in range(len(length)):
        model = RelaxModel(0.5, length[i], times)
        model.start()
        data_base.append(model.ave_slop)
    for i in range(len(data_base)):
        ax.plot(range(times), data_base[i], label='L=%a' % (length[i]), linewidth=0.5)
    ax.set_xscale('log')
    plt.legend()
    plt.xlabel('Grains driven into system')
    plt.ylabel('Height of system')
    plt.show()
Example #6
0
def height_prob_f():
    for i in range(len(length)):
        media = []
        model = RelaxModel(0.5, length[i], times)
        model.start()
        useful_height = model.heights[cross_over_time[i]+1:]
        maximum = max(useful_height)+1
        minimum = min(useful_height)
        for j in range(minimum,maximum):
            P = useful_height.count(j)/len(useful_height)
            media.append(P)
        Prob.append(media.copy())
        maxmin.append(range(minimum, maximum))
    print('done all')
    return Prob,maxmin
Example #7
0
def scaling_above():
    critical = []
    for i in range(2, 260):
        model = RelaxModel(0.5, i, i * i + 4000)
        model.start()
        critical.append(model.critical_z())
        print(model.critical_z())
Example #8
0
 def ave_tc(self):
     for i in range(len(self.lengths_of_system)):
         ave_tc = 0.0
         model = RelaxModel(0.5, self.lengths_of_system[i], self.times)
         model.start()
         model.cross_over_time()
         for j in range(len(model.ave_slop)):
             self.ave_tc = self.ave_tc + model.ave_slop[i]*(i+1)
         self.ave_tc_list.append(ave_tc)
Example #9
0
def ave_tc(number_of_piles):
    lengths_of_system = [4, 8, 16, 32, 64, 128, 256]
    all_tc_list = []
    times = 100000
    for i in range(len(lengths_of_system)):
        ave_tc_list = []
        for j in range(number_of_piles):
            model = RelaxModel(0.5, lengths_of_system[i], times)
            model.start()
            model.cross_over_time()
            ave_tc_list.append(model.t_c)
        all_tc_list.append(sum(ave_tc_list) / len(ave_tc_list))
    return all_tc_list
Example #10
0
 def plot_figure_data(self):
     for i in range(len(self.lengths_of_system)):
         model = RelaxModel(0.5,self.lengths_of_system[i],self.times)
         model.start()
         self.data_base_height.append(model.heights)
Example #11
0
from Oslo_model import RelaxModel
'''
# Question 1
-------------------------------------------------------------------------
'''
model_16 = RelaxModel(0.5, 16, 100000)
model_16.start()
print(sum(model_16.heights) / len(model_16.heights))

model_32 = RelaxModel(0.5, 32, 100000)
model_32.start()
print(sum(model_32.heights) / len(model_32.heights))