def plot_correlation_demo2():
    np.random.seed(0)  # to reproduce the data later on
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x**2 + norm.rvs(1, scale=.01, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x**2 + norm.rvs(1, scale=.1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x**2 + norm.rvs(1, scale=1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x**2 + norm.rvs(1, scale=10, size=len(x))
    _plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "corr_demo_2.png"
Beispiel #2
0
def plot_p_leading_order(frame):
    mat = scipy.io.loadmat('sound-speed_2D-wave.mat')
    T = 5
    nt = T / 0.5
    pp = mat['U'][nt, :, :]
    xx = mat['xx']
    yy = mat['yy']

    fig = pl.figure(figsize=(8, 3.5))
    #pl.title("t= "+str(sol.state.t),fontsize=20)
    pl.xticks(size=20)
    pl.yticks(size=20)
    pl.xlabel('x', fontsize=20)
    pl.ylabel('y', fontsize=20)
    #pl.pcolormesh(xx,yy,p_subxy,cmap=cm.OrRd)
    pl.pcolormesh(xx, yy, pp, cmap='RdBu_r')
    pl.autoscale(tight=True)
    cb = pl.colorbar(ticks=[0.5, 1, 1.5, 2])

    #pl.clim(ticks=[0.5,1,1.5,2])
    imaxes = pl.gca()
    pl.axes(cb.ax)
    pl.yticks(fontsize=20)
    pl.axes(imaxes)
    #pl.xticks(fontsize=20); pl.axes(imaxes)
    #pl.axis('equal')
    pl.axis('tight')
    fig.tight_layout()
    pl.savefig('./_plots_to_paper/sound-speed_LO_t' + str(frame) +
               '_pcolor.png')
    pl.close()
Beispiel #3
0
def plot_mi_demo():
    np.random.seed(0)  # to reproduce the data later on
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=.01, size=len(x))
    _plot_mi_func(x, y)

    # pylab.subplot(222)
    # y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    # _plot_mi_func(x, y)

    # pylab.subplot(223)
    # y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    # _plot_mi_func(x, y)

    # pylab.subplot(224)
    # y = norm.rvs(1, scale=10, size=len(x))
    # _plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "mi_demo_1.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
def plot_mi_demo2():
    np.random.seed(0)
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x**2 + norm.rvs(1, scale=.01, size=len(x))
    _plot_mi_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x**2 + norm.rvs(1, scale=.1, size=len(x))
    _plot_mi_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x**2 + norm.rvs(1, scale=1, size=len(x))
    _plot_mi_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x**2 + norm.rvs(1, scale=10, size=len(x))
    _plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "mi_demo_2.png"
def plot_p(frame):
    sol=Solution(frame,file_format='petsc',read_aux=False,path='./_output/_p/',file_prefix='claw_p')
    x=sol.state.grid.x.centers; y=sol.state.grid.y.centers
    mx=len(x); my=len(y)
    
    mp=sol.state.num_eqn    
    yy,xx = np.meshgrid(y,x)

    p=sol.state.q[0,:,:]
    fig = pl.figure(figsize=(8, 3.5))
    #pl.title("t= "+str(sol.state.t),fontsize=20)
    pl.xticks(size=20); pl.yticks(size=20)
    pl.xlabel('x',fontsize=20); pl.ylabel('y',fontsize=20)
    #pl.pcolormesh(xx,yy,p_subxy,cmap=cm.OrRd)
    pl.pcolormesh(xx,yy,p,cmap='RdBu_r')
    pl.autoscale(tight=True)
    cb = pl.colorbar(ticks=[0.5,1,1.5,2]);
    
    #pl.clim(ticks=[0.5,1,1.5,2])
    imaxes = pl.gca(); pl.axes(cb.ax)
    pl.yticks(fontsize=20); pl.axes(imaxes)
    #pl.xticks(fontsize=20); pl.axes(imaxes)
    #pl.axis('equal')
    pl.axis('tight')
    fig.tight_layout()
    pl.savefig('./_plots_to_paper/sound-speed_FV_t'+str(frame)+'_pcolor.png')
    pl.close()
def plot_p_leading_order(frame):
    mat = scipy.io.loadmat('sound-speed_2D-wave.mat')
    T=5; nt=T/0.5
    pp=mat['U'][nt,:,:]
    xx=mat['xx']
    yy=mat['yy']

    fig=pl.figure(figsize=(8, 3.5))
    #pl.title("t= "+str(sol.state.t),fontsize=20)
    pl.xticks(size=20); pl.yticks(size=20)
    pl.xlabel('x',fontsize=20); pl.ylabel('y',fontsize=20)
    #pl.pcolormesh(xx,yy,p_subxy,cmap=cm.OrRd)
    pl.pcolormesh(xx,yy,pp,cmap='RdBu_r')
    pl.autoscale(tight=True)
    cb = pl.colorbar(ticks=[0.5,1,1.5,2]);
    
    #pl.clim(ticks=[0.5,1,1.5,2])
    imaxes = pl.gca(); pl.axes(cb.ax)
    pl.yticks(fontsize=20); pl.axes(imaxes)
    #pl.xticks(fontsize=20); pl.axes(imaxes)
    #pl.axis('equal')
    pl.axis('tight')
    fig.tight_layout()
    pl.savefig('./_plots_to_paper/sound-speed_LO_t'+str(frame)+'_pcolor.png')
    pl.close()
def plot_mi_demo1():
    np.random.seed(0)  # to reproduce the data later on
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=.01, size=len(x))
    _plot_mi_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    _plot_mi_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    _plot_mi_func(x, y)

    pylab.subplot(224)
    y = norm.rvs(1, scale=10, size=len(x))
    _plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "mi_demo_1.png"
Beispiel #8
0
def plot_simple_demo_2():
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(10, 4))
    pylab.subplot(121)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    np.random.seed(3)
    x1 = np.arange(0, 10, .2)
    x2 = x1 + np.random.normal(loc=0, scale=1, size=len(x1))

    good = x1 > x2
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(122)

    X = np.c_[(x1, x2)]

    pca = decomposition.PCA(n_components=1)
    Xtrans = pca.fit_transform(X)

    Xg = Xtrans[good]
    Xb = Xtrans[bad]

    pylab.scatter(Xg[:, 0],
                  np.zeros(len(Xg)),
                  edgecolor="blue",
                  facecolor="blue")
    pylab.scatter(Xb[:, 0],
                  np.zeros(len(Xb)),
                  edgecolor="red",
                  facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(False)

    print("======系统pca 数据2==========")
    print("特征重要度:", pca.explained_variance_ratio_)

    pylab.grid(True)

    pylab.autoscale(tight=True)
    filename = "pca_demo_2.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
def plot_correlation_demo():
    np.random.seed(0)  # to reproduce the data later on
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, loc=0, scale=.01, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, loc=0, scale=.1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, loc=0, scale=1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(224)
    y = norm.rvs(1, loc=0, scale=10, size=len(x))
    _plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "corr_demo_1.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")

    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x ** 2 + norm.rvs(1, loc=0, scale=.01, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x ** 2 + norm.rvs(1, loc=0, scale=.1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x ** 2 + norm.rvs(1, loc=0, scale=1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x ** 2 + norm.rvs(1, loc=0, scale=10, size=len(x))
    _plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "corr_demo_2.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #10
0
def plot_simple_demo_lda():
    #from sklearn import lda
    # 与demo2不同的是,lda会利用(即有监督的标签信息,而pca并不会利用此信息)类别信息进行降维
    from sklearn.discriminant_analysis import LinearDiscriminantAnalysis
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(10, 4))
    pylab.subplot(121)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    good = x1 > x2
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(122)

    X = np.c_[(x1, x2)]

    #lda_inst = lda.LDA(n_components=1)
    lda_inst = LinearDiscriminantAnalysis(n_components=1)
    Xtrans = lda_inst.fit_transform(X, good)

    Xg = Xtrans[good]
    Xb = Xtrans[bad]

    pylab.scatter(Xg[:, 0],
                  np.zeros(len(Xg)),
                  edgecolor="blue",
                  facecolor="blue")
    pylab.scatter(Xb[:, 0],
                  np.zeros(len(Xb)),
                  edgecolor="red",
                  facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(False)

    pylab.grid(True)

    pylab.autoscale(tight=True)
    filename = "lda_demo.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #11
0
def plot_correlation_demo():
    np.random.seed(0)
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=.01, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(224)
    y = norm.rvs(1, scale=10, size=len(x))
    _plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "corr_demo_1.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")

    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x**2 + norm.rvs(1, scale=.01, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x**2 + norm.rvs(1, scale=.1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x**2 + norm.rvs(1, scale=1, size=len(x))
    _plot_correlation_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x**2 + norm.rvs(1, scale=10, size=len(x))
    _plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "corr_demo_2.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
def plot_simple_demo_2():
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(10, 4))
    pylab.subplot(121)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    x1 = np.arange(0, 10, .2)
    x2 = x1 + np.random.normal(loc=0, scale=1, size=len(x1))

    good = x1 > x2
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(122)

    X = np.c_[(x1, x2)]

    pca = decomposition.PCA(n_components=1)
    Xtrans = pca.fit_transform(X)

    Xg = Xtrans[good]
    Xb = Xtrans[bad]

    pylab.scatter(
        Xg[:, 0], np.zeros(len(Xg)), edgecolor="blue", facecolor="blue")
    pylab.scatter(
        Xb[:, 0], np.zeros(len(Xb)), edgecolor="red", facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(False)

    print(pca.explained_variance_ratio_)

    pylab.grid(True)

    pylab.autoscale(tight=True)
    filename = "pca_demo_2.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #13
0
def Plot():
    u = Calculator()
    u = u[::-1]*4.47058
    x = condition[:, 1]*1000000.
    plt.plot(x, u)
    plt.xlabel('micrometers depth')
    plt.ylabel('argon concentration ppm')
    plt.title('1D system state')
    plt.grid(True)
    #plt.savefig("F1D_result.png")
    plt.autoscale(enable=True, axis='y')
    plt.show()
    return 'sucessfully plotted'
Beispiel #14
0
def plot_simple_demo_lda():
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(10, 4))
    pylab.subplot(121)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    good = x1 > x2
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(122)

    X = np.c_[(x1, x2)]

    lda_inst = lda(n_components=1)
    Xtrans = lda_inst.fit_transform(X, good)

    Xg = Xtrans[good]
    Xb = Xtrans[bad]

    pylab.scatter(Xg[:, 0],
                  np.zeros(len(Xg)),
                  edgecolor="blue",
                  facecolor="blue")
    pylab.scatter(Xb[:, 0],
                  np.zeros(len(Xb)),
                  edgecolor="red",
                  facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(False)

    pylab.grid(True)

    pylab.autoscale(tight=True)
    filename = "lda_demo.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #15
0
def plot_clusters(x, y, title, mx=None, ymax=None, xmin=None, km=None):
    pylab.figure(num=None, figsize=(8, 6))
    if km:
        pylab.scatter(x, y, s=50, c=km.predict(list(zip(x, y))))
    else:
        pylab.scatter(x, y, s=50)
    pylab.title(title)
    pylab.xlabel("Occurance of Word1")
    pylab.ylabel("Occurance of Word2")
    pylab.autoscale(tight=True)
    pylab.ylim(ymin=0, ymax=1)
    pylab.xlim(xmin=0, xmax=1)
    pylab.grid(True, linestyle='-', color='0.75')
    return pylab
Beispiel #16
0
def Plot():
    u, u_sec = Calculator()
    u = u[::-1]*4.47058
    u_sec = u_sec[::-1]*2.17143
    x = condition[:, 1]*1000000.
    plt.plot(x, u)
    plt.plot(x, u_sec)
    plt.xlabel('micrometers depth')
    plt.ylabel('argon concentration ppm')
    plt.title('Zhang and measured D ranges')
    plt.grid(True)
    plt.savefig("F1D_result.png")
    plt.autoscale(enable=True, axis='y')
    plt.show()
def plot_simple_demo_lda():
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(10, 4))
    pylab.subplot(121)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    good = x1 > x2
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(122)

    X = np.c_[(x1, x2)]

    lda_inst = lda.LDA(n_components=1)
    Xtrans = lda_inst.fit_transform(X, good)

    Xg = Xtrans[good]
    Xb = Xtrans[bad]

    pylab.scatter(
        Xg[:, 0], np.zeros(len(Xg)), edgecolor="blue", facecolor="blue")
    pylab.scatter(
        Xb[:, 0], np.zeros(len(Xb)), edgecolor="red", facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(False)

    pylab.grid(True)

    pylab.autoscale(tight=True)
    filename = "lda_demo.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
def plot_clustering(x, y, title, mx=None, ymax=None, xmin=None, km=None):
    pylab.figure(num=None, figsize=(8, 6))
    if km:
        pylab.scatter(x, y, s=50, c=km.predict(list(zip(x, y))))
    else:
        pylab.scatter(x, y, s=50)

    pylab.title(title)
    pylab.xlabel("Occurrence word 1")
    pylab.ylabel("Occurrence word 2")

    pylab.autoscale(tight=True)
    pylab.ylim(ymin=0, ymax=1)
    pylab.xlim(xmin=0, xmax=1)
    pylab.grid(True, linestyle='-', color='0.75')

    return pylab
def plot_results(benchmark_series, 
                 target_series, 
                 target_balances, 
                 n_assets,
                 columns,
                 name2plot = '',
                 path2save = './',
                 base_name_series = 'series'):
    
#     N = len(np.array(benchmark_series).cumsum())
    N = len(np.array([item for sublist in benchmark_series for item in sublist]).cumsum()) 
    
    if not os.path.exists(path2save):
        os.makedirs(path2save)

    for i in range(0, len(target_balances)):

        current_range = np.arange(0, N)
        current_ts = np.zeros(N)
        current_ts2 = np.zeros(N)

        ts_benchmark = np.array([item for sublist in benchmark_series[:i+1] for item in sublist]).cumsum()
        ts_target = np.array([item for sublist in target_series[:i+1] for item in sublist]).cumsum()

        t = len(ts_benchmark)
        current_ts[:t] = ts_benchmark
        current_ts2[:t] = ts_target

        current_ts[current_ts == 0] = ts_benchmark[-1]
        current_ts2[current_ts2 == 0] = ts_target[-1]

        plt.figure(figsize = (12, 10))
        
        plt.subplot(2, 1, 1)
        plt.bar(np.arange(n_assets), target_balances[i], color = 'grey')
        plt.xticks(np.arange(n_assets), columns, rotation='vertical')

        plt.subplot(2, 1, 2)
        plt.colormaps = current_cmap
        plt.plot(current_range[:t], current_ts[:t], color = 'black', label = 'Benchmark')
        plt.plot(current_range[:t], current_ts2[:t], color = 'red', label = name2plot)
        plt.plot(current_range[t:], current_ts[t:], ls = '--', lw = .1, color = 'black')
        plt.autoscale(False)
        plt.ylim([-1, 1])
        plt.legend()
Beispiel #20
0
def plot_entropy():
    pylab.clf()
    pylab.figure(num=None, figsize=(5, 4))

    title = "Entropy $H(X)$"
    pylab.title(title)
    pylab.xlabel("$P(X=$coin will show heads up$)$")
    pylab.ylabel("$H(X)$")

    pylab.xlim(xmin=0, xmax=1.1)
    x = np.arange(0.001, 1, 0.001)
    y = -x * np.log2(x) - (1-x) * np.log2(1-x)
    pylab.plot(x, y)
    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "entropy_demo.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #21
0
def plot_clustering(x, y, title, mx=None, ymax=None, xmin=None, km=None):
    pylab.figure(num=None, figsize=(8, 6))
    if km:
        pylab.scatter(x, y, s=50, c=km.predict(list(zip(x, y))))
    else:
        pylab.scatter(x, y, s=50)

    pylab.title(title)
    pylab.xlabel("Occurrence word 1")
    pylab.ylabel("Occurrence word 2")
    # pylab.xticks([w*7*24 for w in range(10)], ['week %i'%w for w in range(10)])

    pylab.autoscale(tight=True)
    pylab.ylim(ymin=0, ymax=1)
    pylab.xlim(xmin=0, xmax=1)
    pylab.grid(True, linestyle='-', color='0.75')

    return pylab
Beispiel #22
0
def show_image(img, messages=None, fig=None, ax=None, cmap='Gray'):

    if not ax or not fig:
        w, h = plt.figaspect(img.shape[0] / img.shape[1])
        fig = plt.figure(figsize=(w, h))
        ax = fig.add_axes([0.1, 0.1, 0.8, 0.8])

    bbox_opts = dict(ec='k', fc='k')
    ax.clear()
    img_axes = ax.imshow(img, cmap=cmaps[cmap])
    ax.axis('off')
    ax.text(0.03, 0.97, messages['filename'], fontsize=8, color='w', ha='left', va='top', transform=ax.transAxes,
            bbox=bbox_opts)
    ax.text(0.03, 0.03, messages['text_bottom'], fontsize=8, color='w', ha='left', va='bottom',
            transform=ax.transAxes, bbox=bbox_opts)
    fig.canvas.draw()
    plt.autoscale(tight=True)
    fig.show()

    return fig, ax, img_axes
Beispiel #23
0
def periodogram(pipe):
    """Create a plot of the periodogram with nice labels.

    Highlights highest SNR point and also overplots harmonics
    """
    pgram = pipe.pgram

    # Nicely formatted periodogram ticks
    xt = [ 
        0.1,  0.2,  0.3,  0.4,  0.5,  0.6,  0.7,  0.8,  0.9,
        1, 2, 3, 4, 5, 6, 7, 8, 9,
        10, 20, 30, 40, 50, 60, 70, 80, 90,
        100, 200, 300, 400, 500, 600, 700, 800, 900,
    ]
    
    grid_P = pipe.header.ix['grid_P'].value
    grid_s2n = pipe.header.ix['grid_s2n'].value

    plt.semilogx()
    peak = pgram.sort_values('s2n').iloc[-1]

    # Plot periogram, peak, and harmonics
    plt.plot(pgram.P, pgram.s2n)
    plt.plot(grid_P, grid_s2n, 'ro')
    harm = np.array([2,4]).astype(float)
    harm = np.hstack([1,1/harm,harm]) 
    harm *= grid_P
    for h in harm:
        plt.axvline(h,lw=6,alpha=0.2,color='r',zorder=0)

    # Label plot
    ax = plt.gca()
    plt.autoscale(axis='x',tight=True)
    xl = plt.xlim() # Save away the tight-fitting limits
    plt.xticks(xt, xt) # Add the nicely formatted ticks
    ax.xaxis.set_ticks_position('top')
    ax.xaxis.set_label_position('top') 
    plt.xlim(*xl) # Reset the plot limits.
    plt.xlabel('Period [days]')
    plt.ylabel('SNR')
    plt.draw()
Beispiel #24
0
def plot_entropy():
    pylab.clf()
    pylab.figure(num=None, figsize=(5, 4))

    title = "Entropy $H(X)$"
    pylab.title(title)
    pylab.xlabel("$P(X=$coin will show heads up$)$")
    pylab.ylabel("$H(X)$")

    pylab.xlim(xmin=0, xmax=1.1)
    x = np.arange(0.001, 1, 0.001)
    y = -x * np.log2(x) - (1 - x) * np.log2(1 - x)
    pylab.plot(x, y)
    # pylab.xticks([w*7*24 for w in [0,1,2,3,4]], ['week %i'%(w+1) for w in
    # [0,1,2,3,4]])

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "entropy_demo.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #25
0
    def __init__(self,
                 x,
                 y,
                 title,
                 mx=None,
                 y_max=None,
                 x_min=None,
                 kmeans=None):
        pylab.figure(num=None, figsize=(8, 6))
        if kmeans:
            pylab.scatter(x, y, s=50, c=kmeans.predict(list(zip(x, y))))
        else:
            pylab.scatter(x, y, s=50)

        pylab.title(title)
        pylab.xlabel("Occurrence of first word")
        pylab.ylabel("Occurrence of second word")

        pylab.autoscale(tight=True)
        pylab.ylim(bottom=0, top=1)
        pylab.xlim(left=0, right=1)
        self._pylab = pylab
Beispiel #26
0
def plot_p(frame):
    sol = Solution(frame,
                   file_format='petsc',
                   read_aux=False,
                   path='./_output/_p/',
                   file_prefix='claw_p')
    x = sol.state.grid.x.centers
    y = sol.state.grid.y.centers
    mx = len(x)
    my = len(y)

    mp = sol.state.num_eqn
    yy, xx = np.meshgrid(y, x)

    p = sol.state.q[0, :, :]
    fig = pl.figure(figsize=(8, 3.5))
    #pl.title("t= "+str(sol.state.t),fontsize=20)
    pl.xticks(size=20)
    pl.yticks(size=20)
    pl.xlabel('x', fontsize=20)
    pl.ylabel('y', fontsize=20)
    #pl.pcolormesh(xx,yy,p_subxy,cmap=cm.OrRd)
    pl.pcolormesh(xx, yy, p, cmap='RdBu_r')
    pl.autoscale(tight=True)
    cb = pl.colorbar(ticks=[0.5, 1, 1.5, 2])

    #pl.clim(ticks=[0.5,1,1.5,2])
    imaxes = pl.gca()
    pl.axes(cb.ax)
    pl.yticks(fontsize=20)
    pl.axes(imaxes)
    #pl.xticks(fontsize=20); pl.axes(imaxes)
    #pl.axis('equal')
    pl.axis('tight')
    fig.tight_layout()
    pl.savefig('./_plots_to_paper/sound-speed_FV_t' + str(frame) +
               '_pcolor.png')
    pl.close()
Beispiel #27
0
def main():
    #mat_dir = 'Annotations_Part/'
    #origimage_dir = 'JPEGImages/'
    mat_dir = 'Annotations_Part/'
    origimage_dir = 'JPEGImages/'

    label_dir = 'yolabel/'
    personimage_dir = 'yoimage/'

    os.mkdir(label_dir)
    os.mkdir(personimage_dir)

    list_mats = os.listdir(mat_dir)

    for mat in list_mats:
        imname = mat[:-4] + '.jpg'
        image_size, part_mask = make_label(origimage_dir + imname, mat_dir + mat)

        if image_size == 0:
            continue

        copy_cmd = 'cp ' + origimage_dir  + imname + ' ' + personimage_dir
        os.system(copy_cmd)

        mpl.rcParams['savefig.pad_inches'] = 0
        figsize = (image_size[1]*1.0/100, image_size[0]*1.0/100)
        fig = plt.figure(figsize=figsize)
        ax = plt.axes([0,0,1,1], frameon=False)
        ax.get_xaxis().set_visible(False)
        ax.get_yaxis().set_visible(False)
        plt.autoscale(tight=True)
        if np.max(part_mask) == 0:
            ax.imshow(part_mask, cmap='gray')
        else:
            ax.imshow(part_mask, cmap=color_map(N=np.max(part_mask) + 1))
        #plt.savefig(label_dir + imname)
        cv2.imwrite(label_dir + imname, part_mask)
        plt.close()
def ImageViewer(im, cmap=None, interpolation='nearest', **kwargs):
    import matplotlib.pyplot as plt
    import matplotlib.cm as cm

    if type(im) is str: im = open_image(im, rgb2gray=False)

    if cmap is None: cmap = cm.gray
    fig = plt.figure()
    ax = fig.add_subplot(111)
    ax.imshow(im, interpolation=interpolation, cmap=cmap, **kwargs)

    h = im.shape[0]
    w = im.shape[1]
    if im.ndim == 2:
        def format_coord(x, y):
            col = int(x + 0.5)
            row = int(y + 0.5)
            if col >= 0 and col < w and row >= 0 and row < h:
                z = im[row, col]
                return '%1.3f (y=%1.1f, x=%1.1f)' % (z, y, x)
            else:
                return 'x=%1.1f, y=%1.1f' % (x, y)
    else:
        def format_coord(x, y):
            col = int(x + 0.5)
            row = int(y + 0.5)
            if col >= 0 and col < w and row >= 0 and row < h:
                r = im[row, col, 0]
                g = im[row, col, 1]
                b = im[row, col, 2]
                return 'y=%1.1f, x=%1.1f, R=%d, G=%d, B=%d' % (y, x, r, g, b)
            else:
                return 'x=%1.1f, y=%1.1f' % (x, y)

    ax.format_coord = format_coord
    plt.autoscale(tight=True)

    return plt
def plot_entropy():
    pylab.clf()
    pylab.figure(num=None, figsize=(5, 4))

    title = "Entropy $H(X)$"
    pylab.title(title)
    pylab.xlabel("$P(X=$coin will show heads up$)$")
    pylab.ylabel("$H(X)$")

    pylab.xlim(xmin=0, xmax=1.1)
    x = np.arange(0.001, 1, 0.001)
    
    # Claude Shannon's information entropy
    # H(X) = - Sum_i( p(Xi) * log(p(Xi)))
    
    y = -x * np.log2(x) - (1 - x) * np.log2(1 - x)
    
    pylab.plot(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "b_entropy_coin.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #30
0
def t_tms_from_Xc(M, savefig=None, plot_fig=None, ttms_true=None, Xc=None):
    '''
    Calculates the t(tms) for a given Xc and mass
    Xc: float
    M: float
    '''
# ------------------------------------------------------------------------------
    # Parameters from the models
    mass = np.array([14.6, 12.5, 10.8, 9.6, 8.6, 7.7, 6.4, 5.5, 4.8,
                    4.2, 3.8, 3.4])

    nm = len(mass)
    str_mass = ['M14p60', 'M12p50', 'M10p80', 'M9p600', 'M8p600', 'M7p700',
                'M6p400', 'M5p500', 'M4p800', 'M4p200', 'M3p800', 'M3p400']
    st = ['B0.5', 'B1', 'B1.5', 'B2', 'B2.5', 'B3', 'B4', 'B5', 'B6', 'B7',
          'B8', 'B9']
    zsun = 'Z01400'
    str_vel = ['V60000', 'V70000', 'V80000', 'V90000', 'V95000']
    Hfracf = 0.  # end of main sequence

    # ****
    folder_data = 'tables/models/models_bes/'

    if plot_fig is True:
        plt.xlabel(r'$t/t_{MS}$')
        plt.ylabel(r'$X_c$')
        plt.ylim([0.0, 0.8])
        plt.xlim([0.0, 1.0])

# ------------------------------------------------------------------------------
    # Loop (reading the models)
    typ = (1, 3, 16, 21)  # Age, Lum versus Teff versus Hfrac
    arr_age = []
    arr_Hfr = []
    arr_t_tc = []
    cor = phc.gradColor(np.arange(len(st)), cmapn='inferno')
    iv = 2  # O que eh isto?
    arr_Xc = []
    for i in range(nm):
        file_data = folder_data + str_mass[i] + zsun + str_vel[iv] + '.dat'
        age, lum, Teff, Hfrac = np.loadtxt(file_data, usecols=typ,
                                           unpack=True, skiprows=2)
        arr_age.append(age)
        arr_Hfr.append(Hfrac)

        iMS = np.where(abs(Hfrac - Hfracf) == min(abs(Hfrac - Hfracf)))
        X_c = Hfrac[0:iMS[0][0]]
        arr_Xc.append(X_c)

        t_tc = age[0:iMS[0][0]] / max(age[0:iMS[0][0]])
        arr_t_tc.append(t_tc)
    if plot_fig is True:
        plt.plot(t_tc, X_c, color=cor[i], label=('%s' % st[i]))

# ------------------------------------------------------------------------------
# Interpolation
    k = find_nearest(mass, M)[1]

    if plot_fig is True:
        plt.plot(ttms_true, Xc, 'o')
        plt.autoscale()
        plt.minorticks_on()
        plt.legend(fontsize=10, ncol=2, fancybox=False, frameon=False)

# ------------------------------------------------------------------------------

    if savefig is True:
        pdfname = 'Xc_vs_Tsp.png'
        plt.savefig(pdfname)

    return k, arr_t_tc, arr_Xc
Beispiel #31
0
def setup(
    subplt=None,
    figsize=None,
    ax=None,
    xr=None,
    xmin=None,
    xmax=None,
    yr=None,
    ymin=None,
    ymax=None,
    xlog=False,
    ylog=False,
    xoffset=None,
    yoffset=None,
    xlabel=None,
    ylabel=None,
    xtickv=None,
    xticknames=None,
    xtickrotate=None,
    ytickv=None,
    yticknames=None,
    ytickrotate=None,
    halfxlog=False,
    suptitle=None,
    suptitle_prop=None,
    subtitle=None,
    subtitle_prop=None,
    subtitleloc=1,
    title=None,
    xticks=None,
    yticks=None,
    autoticks=False,
    embiggenx=None,
    embiggeny=None,
    secondx=False,
    secondx_prop=None,
    secondy=False,
    secondy_prop=None,
    grid=True,
    tickmarks=True,
    font=True,
    adjust=True,
    hspace=0.1,
    wspace=0.1,
    aspect=None,
    rasterized=False,
):
    '''Setup some nice defaults so that we are all fancy like
    
    xr,yr -- xrange and yrange.  by setting this it turns off the autoscale feature in that axis
    xlog,ylog -- T/F I do love me my log log plots
    
    xlabel,ylabel,title -- Set some nice text for the different axis
    
    xticks, yticks -- set to False if you want to hide the tickmarks and labels
    
    grid -- Turn on the grid in a nice way
    
    tickmarks -- make me some nick minor and major ticks
    
    you can pass in a gridspec
    '''

    # if notebook:
    #   # http://matplotlib.org/users/customizing.html
    #   # http://damon-is-a-geek.com/publication-ready-the-first-time-beautiful-reproducible-plots-with-matplotlib.html
    #   matplotlib.rcParams['savefig.dpi'] = 144
    #   matplotlib.rcParams.update({'font.size': 12})
    #   # matplotlib.rcParams['font.family'] = 'serif'
    #   # matplotlib.rcParams['font.serif'] = ['Computer Modern Roman']
    #   # matplotlib.rcParams['text.usetex'] = True

    if figsize is not None:
        fig = pylab.figure(figsize=figsize)

    ## Handle subplot being an int `223`, tuple `(2,2,3)` or gridspec
    try:
        if subplt is None:
            if ax is None:
                ax = pylab.gca()
        elif isinstance(subplt,
                        (int, gridspec.GridSpec, gridspec.SubplotSpec)):
            ax = pylab.subplot(subplt)
        else:
            ax = pylab.subplot(*subplt)
    except Exception as e:
        raise ValueError(
            'Failed to setup subplt:[{}] -- probably indexing error'.format(
                subplt))

    # Ranges -- Setting either xr,yr stops the auto ranging
    if xr is not None:
        ax.set_xlim(xr)
        pylab.autoscale(False, 'x', True)
    if yr is not None:
        ax.set_ylim(yr)
        pylab.autoscale(False, 'y', True)

    # Log stuff -- do this afterwards to ensure the minor tick marks are updated
    # can set the specific ticks using subsx, subsy --
    #   ax.set_xscale('log', subsx=[2, 3, 4, 5, 6, 7, 8, 9])
    # Look here: http://www.ianhuston.net/2011/02/minor-tick-labels-in-matplotlib
    # clip ensures that lines that go off the edge of the plot are shown but clipped
    if xlog:
        ax.set_xscale('log', nonposx='clip')
    if ylog:
        ax.set_yscale('log', nonposy='clip')

    # Labels
    if xlabel is not None:
        pylab.xlabel(xlabel)
    if ylabel is not None:
        pylab.ylabel(ylabel)
    if title is not None:
        pylab.title(title)
    if suptitle is not None:
        if suptitle_prop is None:
            suptitle_prop = {}
        pylab.suptitle(suptitle, **suptitle_prop)
    if subtitle is not None:
        prop = dict(transform=ax.transAxes)
        if subtitleloc == 1:
            prop.update({
                'location': (0.95, 0.95),
                'horizontalalignment': 'right',
                'verticalalignment': 'top'
            })
        elif subtitleloc == 3:
            prop.update({
                'location': (0.05, 0.05),
                'horizontalalignment': 'left',
                'verticalalignment': 'bottom'
            })
        else:
            raise NotImplementedError(
                'Get to work adding the following subtitle location: %d' %
                (subtitleloc))
        if subtitle_prop is not None:
            prop.update(subtitle_prop)
        loc = prop.pop('location')
        outline = prop.pop('outline', True)
        outlinewidth = prop.pop('linewidth', 3.5)
        txt = pylab.text(loc[0], loc[1], subtitle, **prop)
        if outline:
            # pylab.setp(txt,path_effects=[PathEffects.Stroke(linewidth=outlinewidth, foreground="w")]) # Broken
            txt.set_path_effects([
                PathEffects.Stroke(linewidth=outlinewidth, foreground="w"),
                PathEffects.Normal()
            ])
            # raise ValueError()

    if xtickv is not None:
        ax.xaxis.set_major_locator(matplotlib.ticker.FixedLocator(xtickv))
        if xticknames is not None:
            ax.xaxis.set_major_formatter(
                matplotlib.ticker.FixedFormatter(xticknames))
    if xtickrotate is not None:
        if xtickrotate == 'vertical':
            pylab.xticks(xtickv, xticknames, rotation='vertical')
        else:
            tmp = dict(rotation=30, ha='right')
            if isinstance(xtickrotate, dict):
                tmp.update(xtickrotate)
            else:
                tmp['rotation'] = xtickrotate
            pylab.setp(pylab.xticks()[1], **tmp)

    if ytickv is not None:
        ax.yaxis.set_major_locator(matplotlib.ticker.FixedLocator(ytickv))
        if yticknames is not None:
            ax.yaxis.set_major_formatter(
                matplotlib.ticker.FixedFormatter(yticknames))
    if ytickrotate is not None:
        pylab.setp(pylab.yticks()[1], rotation=ytickrotate, ha='right')

    # Axis hiding
    if autoticks:
        if not (((isinstance(subplt, tuple) and len(subplt) == 3)) or
                ((isinstance(subplt, gridspec.SubplotSpec)))):
            splog('Cannot setup auto ticks without a proper subplot')
        else:
            if isinstance(subplt, gridspec.SubplotSpec):
                rows, cols, i, _ = subplt.get_geometry()
                i += 1  # i is 0 indexed.
            else:
                rows, cols, i = subplt

            if ((i % cols) != 1) and (not yticks):
                yticks = False
            # if ( i < (cols*(rows-1) + 1) ) and (not xticks):
            #     xticks = False
            xticks = not ((i < (cols * (rows - 1) + 1)) and (not xticks))

    # Tickmark hiding -- used by autoticks as well.
    if xticks is False:
        # ax.set_xticklabels([])
        ax.set_xlabel('')
        pylab.setp(ax.get_xticklabels(), visible=False)

    if yticks is False:
        # ax.set_yticklabels([])
        ax.set_ylabel('')
        pylab.setp(ax.get_yticklabels(), visible=False)

    # some nice defaults
    if grid is True:
        pylab.grid(b=True,
                   which='major',
                   linestyle='solid',
                   color='0.3',
                   alpha=0.5)
        ax.set_axisbelow(True)
    if grid is False:
        pylab.grid('off')

    if tickmarks:
        ax.tick_params('both', which='major', length=5, width=2)
        ax.tick_params('both', which='minor', length=3, width=1)
        ax.minorticks_on()
    else:
        ax.minorticks_off()
        pylab.tick_params(axis='both',
                          which='both',
                          bottom='off',
                          top='off',
                          left='off',
                          right='off')

    if adjust:
        pylab.subplots_adjust(hspace=hspace, wspace=wspace)

    if font:
        # this in theory should work, but fails becuase of the stupidify known as `_`
        # pylab.rc('font', **{'family':'sans-serif', 'sans-serif':['Helvetica']})
        # prop = {'family' : 'normal', 'weight' : 'bold', 'size'   : 22}
        # pylab.rc('font', **{'family':'serif', 'serif':['Computer Modern Roman']})
        # pylab.rc('text', usetex=True)
        pass

    if aspect is not None:
        # 'auto', 'equal'
        ax.set_aspect(aspect)

    if embiggenx:
        setup(xr=math.embiggen(ax.axis()[:2], embiggenx))
    if embiggeny:
        setup(yr=math.embiggen(ax.axis()[2:], embiggeny))

    if (xticks) and (halfxlog):
        xax = ax.xaxis
        xax.set_minor_formatter(matplotlib.ticker.FormatStrFormatter('%g'))

        tmp = (10.0**(np.arange(-1, 5, 1))) * 5.0
        for x, label in zip(xax.get_minorticklocs(),
                            xax.get_minorticklabels()):
            if x in tmp:
                label.set_fontsize(8)
            else:
                label.set_fontsize(0)
                pylab.setp(label, visible=False)

    if secondx:
        # second x axis
        tmp = dict(
            xlabel=None,
            fcn=lambda arr: arr,
            fmt='{}',
            xr=ax.axis()[:2],
            xlog=('log' in ax.get_xscale()),
            # yr=ax.axis()[2:]
            xtickv=ax.get_xticks(),
        )  # defaults
        if secondx_prop:
            tmp.update(secondx_prop)

        # adjust some nice things
        f = tmp.pop('fcn')
        fcn = lambda arr: [f(x) for x in arr]
        fmt = tmp.pop('fmt')
        if isinstance(fmt, str): fmt = (fmt, fmt)

        if 'xtickv' in tmp:
            tmp['xtickv'] = np.array(tmp['xtickv'])

        if 'xticknames' not in tmp:
            arr = np.array(fcn(tmp['xtickv']))
            tmp['xticknames'] = np.array([fmt[0].format(x) for x in arr])
            if tmp['xlog'] and tmp['nicelog']:
                ii = np.where((arr >= 1e1) & (arr < 1e4))[0]
                tmp['xticknames'][ii] = [fmt[1].format(x) for x in arr[ii]]
                ii = np.where(arr >= 1e4)
                tmp['xticknames'][ii] = [
                    fmt[2].format(np.log10(x)) for x in arr[ii]
                ]

        ax2 = ax.twiny()  # I have never understood this
        ax2.set_xlabel(tmp['xlabel'])
        ax2.set_xlim(tmp['xr'])
        if tmp['xlog']:
            ax2.set_xscale('log', nonposx='clip')
        if 'xtickv' in tmp:
            ax2.xaxis.set_major_locator(
                matplotlib.ticker.FixedLocator(tmp['xtickv']))
        if 'xticknames' in tmp:
            ax2.xaxis.set_major_formatter(
                matplotlib.ticker.FixedFormatter(tmp['xticknames']))

        ax.secondx = ax2
        pylab.sca(ax)

    if secondy:
        # second x axis
        tmp = dict(
            ylabel=None,
            fcn=lambda arr: arr,
            fmt='{}',
            yr=ax.axis()[2:],
            ylog=('log' in ax.get_yscale()),
            ytickv=ax.get_yticks(),
        )
        if secondy_prop:
            tmp.update(secondy_prop)

        # adjust some nice things
        f = tmp.pop('fcn')
        fcn = lambda arr: [f(x) for x in arr]
        fmt = tmp.pop('fmt')
        if isinstance(fmt, str): fmt = (fmt, fmt)

        if 'ytickv' in tmp:
            tmp['ytickv'] = np.array(tmp['ytickv'])

        if 'yticknames' not in tmp:
            arr = np.array(fcn(tmp['ytickv']))
            tmp['yticknames'] = np.array([fmt[0].format(x) for x in arr])
            if tmp['ylog'] and tmp['nicelog']:
                ii = np.where((arr >= 1e1) & (arr < 1e4))[0]
                tmp['yticknames'][ii] = [fmt[1].format(x) for x in arr[ii]]
                ii = np.where(arr >= 1e4)
                tmp['yticknames'][ii] = [
                    fmt[2].format(np.log10(x)) for x in arr[ii]
                ]

        print(tmp)

        ax2 = ax.twinx()  # I have never understood this
        ax2.set_ylabel(tmp['ylabel'])
        ax2.set_ylim(tmp['yr'])
        if tmp['ylog']:
            ax2.set_yscale('log', nonposx='clip')
        if 'ytickv' in tmp:
            ax2.yaxis.set_major_locator(
                matplotlib.ticker.FixedLocator(tmp['ytickv']))
        if 'yticknames' in tmp:
            ax2.yaxis.set_major_formatter(
                matplotlib.ticker.FixedFormatter(tmp['yticknames']))

        ax.secondy = ax2
        pylab.sca(ax)

    if xoffset is False:
        tmp = matplotlib.ticker.ScalarFormatter(useOffset=False)
        tmp.set_scientific(False)
        ax.xaxis.set_major_formatter(tmp)
    if yoffset is False:
        tmp = matplotlib.ticker.ScalarFormatter(useOffset=False)
        tmp.set_scientific(False)
        ax.yaxis.set_major_formatter(tmp)

    if rasterized:
        ax.set_rasterized(True)
    # temp
    return ax
def plot_mi_demo():

    # determinism!
    np.random.seed(0)
    
    # plot1
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=.01, size=len(x))
    plot_mi_func(x, y)
    
    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(224)
    y = norm.rvs(1, scale=10, size=len(x))
    plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "c_mutual_information_1_ok.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")

    ##############
    # plot 2
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=.01, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=.1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=10, size=len(x))
    plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "c_mutual_information_2_ok.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #33
0
forecast = model_fit.forecast(forecast_len)
#forecast = np.exp(forecast)                          # for log correction

# eval metrics
rmse = np.sqrt(((forecast - df_test)**2).mean())
p_rmse = (rmse / df_test.mean()) * 100

# plot it again
plt.figure(figsize=(20, 10))
plt.plot(series, 'b')
plt.plot(forecast, 'r')

plt.title('RMSE: %.2f     Percent Avg Error: %.2f' % (rmse, p_rmse))
plt.xlabel('Weeks')
plt.ylabel('Weekly Rates')
plt.autoscale(enable=True, axis='x', tight=True)
plt.axvline(x=series.index[len(df_train)], color='black')

# write out for testing
df_test.to_csv('../../data/processed/test_actuals.csv')

forecast.to_csv('../../data/processed/test_forecasted.csv')

##############
# prediction #
##############
# predict out for 52
model = SARIMAX(series,
                order=(1, 1, 2),
                seasonal_order=(1, 0, 1, 52),
                enforce_stationarity=False,
Beispiel #34
0
def plot_MDS(x, y=None, data_set_ids=None):
    if data_set_ids is None:
        data_set_ids = np.ones(x.shape[0])
    pl.close()

    fig = pl.figure()
    #axes = fig.add_subplot(111)
    axes = pl.subplot(111)
    to_use = false(x.shape[0])
    max_to_use = 200
    for i in np.unique(data_set_ids):
        I = (data_set_ids == i).nonzero()[0]
        if len(I) <= max_to_use:
            to_use[I] = True
        else:
            choice = np.random.choice(I, max_to_use, replace=False)
            to_use[choice] = True
    x = x[to_use, :]
    data_set_ids = data_set_ids[to_use]
    if y is not None:
        y = y[to_use]
    x = try_toarray(x)
    I_nonzero = x.sum(1).nonzero()[0]
    x = x[I_nonzero, :]
    data_set_ids = data_set_ids[I_nonzero]
    y = y[I_nonzero]
    '''
    x = np.zeros(x.shape)
    x[data_set_ids==0,0] = 1
    x[data_set_ids==1,1] = 1
    x[data_set_ids==2,2] = 1
    '''
    W = pairwise.pairwise_distances(x, x, 'cosine')
    #W = pairwise.pairwise_distances(x,x,'euclidean')
    W = make_rbf(x, sigma=10, metric='cosine')
    W = 1 - W

    #mds = sklearn.manifold.MDS(dissimilarity='precomputed',max_iter=1000,verbose=1,metric=False)
    mds = sklearn.manifold.MDS(dissimilarity='precomputed',
                               max_iter=1000,
                               verbose=1,
                               n_init=4)
    x_mds = mds.fit_transform(W)
    #mds = sklearn.manifold.MDS()
    #x_mds = mds.fit_transform(x)
    colors = ['r', 'g', 'b']
    labels = ['s', 'o']
    for ind, i in enumerate(np.unique(data_set_ids)):
        if ind == 0 and False:
            continue
        if ind == 2 and False:
            continue
        I = data_set_ids == i
        alpha = 1 / float(I.sum())
        alpha = alpha * 50
        alpha = .3
        if i == 0:
            alpha = 1
        y_curr = y[I]
        x_curr = x_mds[I, :]
        for ind2, j in enumerate(np.unique(y_curr)):
            I2 = y_curr == j
            axes.scatter(x_curr[I2, 0],
                         x_mds[I2, 1],
                         alpha=alpha,
                         c=colors[ind],
                         s=100,
                         marker=labels[ind2])
        #axes.scatter(x_mds[I,0],x_mds[I,1], alpha=alpha,c=colors[ind],s=60)
    move_fig(fig)
    pl.autoscale()
    pl.show(block=True)
    pass
def plot_MDS(x, y=None, data_set_ids=None):
    if data_set_ids is None:
        data_set_ids = np.ones(x.shape[0])
    pl.close()

    fig = pl.figure()
    #axes = fig.add_subplot(111)
    axes = pl.subplot(111)
    to_use = false(x.shape[0])
    max_to_use = 200
    for i in np.unique(data_set_ids):
        I = (data_set_ids == i).nonzero()[0]
        if len(I) <= max_to_use:
            to_use[I] = True
        else:
            choice = np.random.choice(I, max_to_use, replace=False)
            to_use[choice] = True
    x = x[to_use,:]
    data_set_ids = data_set_ids[to_use]
    if y is not None:
        y = y[to_use]
    x = try_toarray(x)
    I_nonzero = x.sum(1).nonzero()[0]
    x = x[I_nonzero,:]
    data_set_ids = data_set_ids[I_nonzero]
    y = y[I_nonzero]


    '''
    x = np.zeros(x.shape)
    x[data_set_ids==0,0] = 1
    x[data_set_ids==1,1] = 1
    x[data_set_ids==2,2] = 1
    '''
    W = pairwise.pairwise_distances(x,x,'cosine')
    #W = pairwise.pairwise_distances(x,x,'euclidean')
    W = make_rbf(x,sigma=10,metric='cosine')
    W = 1 - W

    #mds = sklearn.manifold.MDS(dissimilarity='precomputed',max_iter=1000,verbose=1,metric=False)
    mds = sklearn.manifold.MDS(dissimilarity='precomputed',max_iter=1000,verbose=1,n_init=4)
    x_mds = mds.fit_transform(W)
    #mds = sklearn.manifold.MDS()
    #x_mds = mds.fit_transform(x)
    colors = ['r','g','b']
    labels = ['s','o']
    for ind,i in enumerate(np.unique(data_set_ids)):
        if ind == 0 and False:
            continue
        if ind == 2 and False:
            continue
        I = data_set_ids == i
        alpha = 1 / float(I.sum())
        alpha = alpha*50
        alpha = .3
        if i == 0:
            alpha = 1
        y_curr = y[I]
        x_curr = x_mds[I,:]
        for ind2, j in enumerate(np.unique(y_curr)):
            I2 = y_curr == j
            axes.scatter(x_curr[I2,0],x_mds[I2,1], alpha=alpha,c=colors[ind],s=100,marker = labels[ind2])
        #axes.scatter(x_mds[I,0],x_mds[I,1], alpha=alpha,c=colors[ind],s=60)
    move_fig(fig)
    pl.autoscale()
    pl.show(block=True)
    pass
Beispiel #36
0
def setup(subplt=None, figsize=None, ax=None,
          xr=None, xmin=None, xmax=None,
          yr=None, ymin=None, ymax=None,
          xlog=False, ylog=False,
          xoffset=None, yoffset=None,
          xlabel=None, ylabel=None, 
          xtickv=None, xticknames=None, xtickrotate=None,
          ytickv=None, yticknames=None, ytickrotate=None,
          halfxlog=False,
          suptitle=None, suptitle_prop=None, 
          subtitle=None, subtitle_prop=None, subtitleloc=1, 
          title=None,
          xticks=None, yticks=None, autoticks=False,
          embiggenx=None, embiggeny=None,
          secondx=False, secondx_prop=None,
          secondy=False, secondy_prop=None,
          grid=True, tickmarks=True, font=True,
          adjust=True, hspace=0.1, wspace=0.1, aspect=None,
          rasterized=False,
          ):
    '''Setup some nice defaults so that we are all fancy like
    
    xr,yr -- xrange and yrange.  by setting this it turns off the autoscale feature in that axis
    xlog,ylog -- T/F I do love me my log log plots
    
    xlabel,ylabel,title -- Set some nice text for the different axis
    
    xticks, yticks -- set to False if you want to hide the tickmarks and labels
    
    grid -- Turn on the grid in a nice way
    
    tickmarks -- make me some nick minor and major ticks
    
    you can pass in a gridspec
    '''
    
    # if notebook:
    #   # http://matplotlib.org/users/customizing.html
    #   # http://damon-is-a-geek.com/publication-ready-the-first-time-beautiful-reproducible-plots-with-matplotlib.html
    #   matplotlib.rcParams['savefig.dpi'] = 144
    #   matplotlib.rcParams.update({'font.size': 12})
    #   # matplotlib.rcParams['font.family'] = 'serif'
    #   # matplotlib.rcParams['font.serif'] = ['Computer Modern Roman']
    #   # matplotlib.rcParams['text.usetex'] = True
    
    
    if figsize is not None:
        fig = pylab.figure(figsize=figsize)
    
    ## Handle subplot being an int `223`, tuple `(2,2,3)` or gridspec 
    try:
        if subplt is None:
            if ax is None:
                ax = pylab.gca()
        elif isinstance(subplt, (int, gridspec.GridSpec, gridspec.SubplotSpec) ):
            ax = pylab.subplot(subplt)
        else:
            ax = pylab.subplot(*subplt)
    except Exception as e:
        raise ValueError('Failed to setup subplt:[{}] -- probably indexing error'.format(subplt))
    
    
    
    # Ranges -- Setting either xr,yr stops the auto ranging
    if xr is not None:
        ax.set_xlim(xr)
        pylab.autoscale(False, 'x', True)
    if yr is not None:
        ax.set_ylim(yr)
        pylab.autoscale(False, 'y', True)
    
    # Log stuff -- do this afterwards to ensure the minor tick marks are updated
    # can set the specific ticks using subsx, subsy -- 
    #   ax.set_xscale('log', subsx=[2, 3, 4, 5, 6, 7, 8, 9])
    # Look here: http://www.ianhuston.net/2011/02/minor-tick-labels-in-matplotlib
    # clip ensures that lines that go off the edge of the plot are shown but clipped
    if xlog:
        ax.set_xscale('log', nonposx='clip')
    if ylog:
        ax.set_yscale('log', nonposy='clip')

    
    # Labels
    if xlabel is not None:
        pylab.xlabel(xlabel)
    if ylabel is not None:
        pylab.ylabel(ylabel)
    if title is not None:
        pylab.title(title)
    if suptitle is not None:
        if suptitle_prop is None:
            suptitle_prop = {}
        pylab.suptitle(suptitle, **suptitle_prop)
    if subtitle is not None:
        prop = dict(transform=ax.transAxes)
        if subtitleloc == 1:
            prop.update({'location':(0.95,0.95),
                         'horizontalalignment':'right',
                         'verticalalignment':'top'})
        elif subtitleloc == 3:
            prop.update({'location':(0.05,0.05),
                         'horizontalalignment':'left',
                         'verticalalignment':'bottom'})
        else: 
            raise NotImplementedError('Get to work adding the following subtitle location: %d'%(subtitleloc))
        if subtitle_prop is not None:
            prop.update(subtitle_prop)
        loc = prop.pop('location')
        outline = prop.pop('outline',True)
        outlinewidth = prop.pop('linewidth',3.5)
        txt = pylab.text(loc[0], loc[1], subtitle, **prop)
        if outline:
            # pylab.setp(txt,path_effects=[PathEffects.Stroke(linewidth=outlinewidth, foreground="w")]) # Broken
            txt.set_path_effects(
                [PathEffects.Stroke(linewidth=outlinewidth, foreground="w"),
                 PathEffects.Normal()])
            # raise ValueError()
    
    
    if xtickv is not None:
        ax.xaxis.set_major_locator(matplotlib.ticker.FixedLocator(xtickv))
        if xticknames is not None:
            ax.xaxis.set_major_formatter(matplotlib.ticker.FixedFormatter(xticknames))
    if xtickrotate is not None:
        if xtickrotate == 'vertical':
            pylab.xticks(xtickv, xticknames, rotation='vertical')
        else:
            tmp = dict(rotation=30, ha='right')
            if isinstance(xtickrotate, dict):
                tmp.update(xtickrotate)
            else:
                tmp['rotation'] = xtickrotate
            pylab.setp(pylab.xticks()[1], **tmp)
    
    if ytickv is not None:
        ax.yaxis.set_major_locator(matplotlib.ticker.FixedLocator(ytickv))
        if yticknames is not None:
            ax.yaxis.set_major_formatter(matplotlib.ticker.FixedFormatter(yticknames))
    if ytickrotate is not None:
        pylab.setp(pylab.yticks()[1], rotation=ytickrotate, ha='right')
        
    
    # Axis hiding
    if autoticks:
        if not ( ( (isinstance(subplt, tuple) and len(subplt) == 3) ) or 
                 ( (isinstance(subplt, gridspec.SubplotSpec)) ) ):
            splog('Cannot setup auto ticks without a proper subplot')
        else:
            if isinstance(subplt, gridspec.SubplotSpec):
                rows,cols,i, _ = subplt.get_geometry()
                i += 1 # i is 0 indexed.
            else:
                rows,cols,i = subplt
            
            if ( (i%cols) != 1 ) and (not yticks):
                yticks = False
            # if ( i < (cols*(rows-1) + 1) ) and (not xticks):
            #     xticks = False
            xticks = not ( ( i < (cols*(rows-1) + 1) ) and (not xticks) )
    
    
    
    
    # Tickmark hiding -- used by autoticks as well.
    if xticks is False:
        # ax.set_xticklabels([])
        ax.set_xlabel('') 
        pylab.setp(ax.get_xticklabels(), visible=False)
        
    if yticks is False:
        # ax.set_yticklabels([])
        ax.set_ylabel('')
        pylab.setp(ax.get_yticklabels(), visible=False)
    
    
    # some nice defaults
    if grid is True:
        pylab.grid(b=True, which='major', linestyle='solid', color='0.3', alpha=0.5)
        ax.set_axisbelow(True)
    if grid is False:
        pylab.grid('off')
    
    
    if tickmarks:
        ax.tick_params('both', which='major', length=5, width=2)
        ax.tick_params('both', which='minor', length=3, width=1)
        ax.minorticks_on()
    else:
        ax.minorticks_off()
        pylab.tick_params(axis='both',which='both',
                          bottom='off', top='off',
                          left='off', right='off')
        
    
    if adjust:
        pylab.subplots_adjust(hspace=hspace, wspace=wspace)
    
    if font:
        # this in theory should work, but fails becuase of the stupidify known as `_`
        # pylab.rc('font', **{'family':'sans-serif', 'sans-serif':['Helvetica']})
        # prop = {'family' : 'normal', 'weight' : 'bold', 'size'   : 22}
        # pylab.rc('font', **{'family':'serif', 'serif':['Computer Modern Roman']})
        # pylab.rc('text', usetex=True)
        pass
    
    if aspect is not None:
        # 'auto', 'equal'
        ax.set_aspect(aspect)
    
    if embiggenx:
        setup(xr=math.embiggen(ax.axis()[:2],embiggenx))
    if embiggeny:
        setup(yr=math.embiggen(ax.axis()[2:],embiggeny))
    
    if (xticks) and (halfxlog):
        xax = ax.xaxis
        xax.set_minor_formatter(matplotlib.ticker.FormatStrFormatter('%g'))
        
        tmp = (10.0**(np.arange(-1,5,1)))*5.0
        for x,label in zip(xax.get_minorticklocs(), xax.get_minorticklabels()):
            if x in tmp:
                label.set_fontsize(8)
            else:
                label.set_fontsize(0)
                pylab.setp(label, visible=False)
    

    if secondx:
        # second x axis
        tmp = dict(xlabel=None,
                   fcn=lambda arr: arr,
                   fmt='{}',
                   xr=ax.axis()[:2],
                   xlog=('log' in ax.get_xscale()),
                   # yr=ax.axis()[2:]
                   xtickv=ax.get_xticks(),
                   ) # defaults
        if secondx_prop:
            tmp.update(secondx_prop)
            
        # adjust some nice things
        f = tmp.pop('fcn')
        fcn = lambda arr: [f(x) for x in arr]
        fmt = tmp.pop('fmt')
        if isinstance(fmt, str): fmt = (fmt,fmt)
        
        if 'xtickv' in tmp:
            tmp['xtickv'] = np.array(tmp['xtickv'])
        
        if 'xticknames' not in tmp:
            arr = np.array(fcn(tmp['xtickv']))
            tmp['xticknames'] = np.array([fmt[0].format(x) for x in arr])
            if tmp['xlog'] and tmp['nicelog']:
                ii = np.where((arr >= 1e1)&
                              (arr < 1e4) )[0]
                tmp['xticknames'][ii] = [fmt[1].format(x) for x in arr[ii]]
                ii = np.where(arr >= 1e4)
                tmp['xticknames'][ii] = [fmt[2].format(np.log10(x)) for x in arr[ii]]
        
        ax2 = ax.twiny() # I have never understood this
        ax2.set_xlabel(tmp['xlabel'])
        ax2.set_xlim(tmp['xr'])
        if tmp['xlog']:
            ax2.set_xscale('log', nonposx='clip')
        if 'xtickv' in tmp:
            ax2.xaxis.set_major_locator(matplotlib.ticker.FixedLocator(tmp['xtickv']))
        if 'xticknames' in tmp:
            ax2.xaxis.set_major_formatter(matplotlib.ticker.FixedFormatter(tmp['xticknames']))
        
        ax.secondx = ax2
        pylab.sca(ax)

    if secondy:
        # second x axis
        tmp = dict(ylabel=None,
                   fcn=lambda arr: arr,
                   fmt='{}',
                   yr=ax.axis()[2:],
                   ylog=('log' in ax.get_yscale()),
                   ytickv=ax.get_yticks(), )
        if secondy_prop:
            tmp.update(secondy_prop)
            
        # adjust some nice things
        f = tmp.pop('fcn')
        fcn = lambda arr: [f(x) for x in arr]
        fmt = tmp.pop('fmt')
        if isinstance(fmt, str): fmt = (fmt,fmt)
        
        if 'ytickv' in tmp:
            tmp['ytickv'] = np.array(tmp['ytickv'])
        
        if 'yticknames' not in tmp:
            arr = np.array(fcn(tmp['ytickv']))
            tmp['yticknames'] = np.array([fmt[0].format(x) for x in arr])
            if tmp['ylog'] and tmp['nicelog']:
                ii = np.where((arr >= 1e1)&
                              (arr < 1e4) )[0]
                tmp['yticknames'][ii] = [fmt[1].format(x) for x in arr[ii]]
                ii = np.where(arr >= 1e4)
                tmp['yticknames'][ii] = [fmt[2].format(np.log10(x)) for x in arr[ii]]
            
        print(tmp)
        
        ax2 = ax.twinx() # I have never understood this
        ax2.set_ylabel(tmp['ylabel'])
        ax2.set_ylim(tmp['yr'])
        if tmp['ylog']:
            ax2.set_yscale('log', nonposx='clip')
        if 'ytickv' in tmp:
            ax2.yaxis.set_major_locator(matplotlib.ticker.FixedLocator(tmp['ytickv']))
        if 'yticknames' in tmp:
            ax2.yaxis.set_major_formatter(matplotlib.ticker.FixedFormatter(tmp['yticknames']))
            
        ax.secondy = ax2
        pylab.sca(ax)

    if xoffset is False:
        tmp = matplotlib.ticker.ScalarFormatter(useOffset=False)
        tmp.set_scientific(False)
        ax.xaxis.set_major_formatter(tmp)
    if yoffset is False:
        tmp = matplotlib.ticker.ScalarFormatter(useOffset=False)
        tmp.set_scientific(False)
        ax.yaxis.set_major_formatter(tmp)
        
    
    if rasterized:
        ax.set_rasterized(True)
    # temp
    return ax
Beispiel #37
0
def plot_simple_demo_1():
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(10, 4))
    pylab.subplot(131)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    np.random.seed(3)
    x1 = np.arange(0, 10, .2)
    x2 = x1 + np.random.normal(loc=0, scale=1, size=len(x1))

    good = (x1 > 5) | (x2 > 5)
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(132)

    X = np.c_[(x1, x2)]  # X:[N, 2]

    pca = decomposition.PCA(n_components=2)
    Xtrans = pca.fit_transform(X)  # Xtrans:[N, 1], 只有一个主成份
    #Xtrans *=-1

    Xg = Xtrans[good]
    Xb = Xtrans[bad]
    """
    pylab.scatter( Xg[:, 0], np.zeros(len(Xg)), edgecolor="blue", facecolor="blue")
    pylab.scatter( Xb[:, 0], np.zeros(len(Xb)), edgecolor="red", facecolor="white")
    """
    pylab.scatter(Xg[:, 0], Xg[:, 1], edgecolor="blue", facecolor="blue")
    pylab.scatter(Xb[:, 0], Xb[:, 1], edgecolor="red", facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(False)

    title = "Transformed feature space(1-d)"
    pylab.subplot(133)
    pylab.scatter(Xg[:, 0],
                  np.zeros(len(Xg)),
                  edgecolor="blue",
                  facecolor="blue")
    pylab.scatter(Xb[:, 0],
                  np.zeros(len(Xb)),
                  edgecolor="red",
                  facecolor="white")

    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[2].get_yaxis().set_visible(False)

    print("======系统pca 数据1==========")
    print("特征值:", pca.explained_variance_)
    print("特征重要度比率:", pca.explained_variance_ratio_)
    # 可以看出, 手工pca与系统pca数据有个符号相反,并不影响分解,
    # 比如 X=U*S*(V^T) = (-U) S*(-V^T)
    # 对于二维数据, 其物理意义对应是按照顺时针旋转还是逆时针旋转,并不影响保持最大分量这一物理意义
    print("系统Xg:", Xg)
    pylab.grid(True)

    pylab.autoscale(tight=True)
    filename = "pca_demo_1.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #38
0
        callback = (odl.solvers.CallbackPrintIteration())

        # Solve with initial guess x = 0.
        # Step size parameters are selected to ensure convergence.
        # See douglas_rachford_pd doc for more information.
        x = ray_trafo.domain.zero()
        odl.solvers.douglas_rachford_pd(x,
                                        f,
                                        g,
                                        lin_ops,
                                        tau=0.1,
                                        sigma=[0.1, 0.1, 0.02],
                                        lam=1.5,
                                        niter=100,
                                        callback=callback)

        name = 'reco_l2TV_datafunc__lam_' + lam_str + '__l2reg_' + l2_reg_param_str
        np.savetxt(path_load_result + name, x)

        fig = x.show(clim=[-1, 1])
        plt.axis('off')
        fig.delaxes(fig.axes[1])
        plt.autoscale(False)
        typefig = 'png'
        plt.savefig(path_load_result + name + '.' + typefig,
                    transparent=True,
                    bbox_inches='tight',
                    pad_inches=0,
                    format=typefig)
        plt.close('all')
def plot_correlation():
    
    # rerun
    
    # plot 1
    np.random.seed(66)
    
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))
    
    x = np.arange(0, 10, 0.2)
    # print x
    
    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=0.01, size=len(x))
    # print y
    plot_correlation_func(x, y)
    
    
    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    plot_correlation_func(x, y)
    

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    plot_correlation_func(x, y)

    
    pylab.subplot(224)
    y = norm.rvs(1, scale=10, size=len(x))
    plot_correlation_func(x, y)
    
   
    
    # pylab.autoscale(tight=True)
    pylab.grid(True)
    
    filename = "a_correlation_pearsonr_1_linear_ok.png"
    CHART_DIR = os.path.join(os.path.dirname(os.path.realpath(__file__)), "charts")
    
    if not os.path.exists(CHART_DIR):
        os.mkdir(CHART_DIR)
        
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
    
    #########
    
    # plot 2
    
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))
    
    x = np.arange(-5, 5, 0.2)
    
    pylab.subplot(221)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=.01, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=.1, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=1, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=10, size=len(x))
    plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)
    
    filename = "a_correlation_pearsonr_2_quad_bad.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #40
0
def plot_correlation():

    # rerun

    # plot 1
    np.random.seed(66)

    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)
    # print x

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=0.01, size=len(x))
    # print y
    plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(224)
    y = norm.rvs(1, scale=10, size=len(x))
    plot_correlation_func(x, y)

    # pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "a_correlation_pearsonr_1_linear_ok.png"
    CHART_DIR = os.path.join(os.path.dirname(os.path.realpath(__file__)),
                             "charts")

    if not os.path.exists(CHART_DIR):
        os.mkdir(CHART_DIR)

    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")

    #########

    # plot 2

    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x**2 + norm.rvs(1, scale=.01, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x**2 + norm.rvs(1, scale=.1, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x**2 + norm.rvs(1, scale=1, size=len(x))
    plot_correlation_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x**2 + norm.rvs(1, scale=10, size=len(x))
    plot_correlation_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "a_correlation_pearsonr_2_quad_bad.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #41
0
#pylab.grid(True)
#pylab.autoscale(tight=True)

##case 2 LDA
good = x1 > x2
bad = ~good
lda_inst = lda.LDA(n_components=1)
Xtrans = lda_inst.fit_transform(X, good)

pylab.clf()
fig = pylab.figure(num=None, figsize=(10, 4))
pylab.subplot(121)
pylab.xlabel("$X_1$")
pylab.ylabel("$X_2$")
pylab.scatter(x1[good], x2[good], edgecolors="blue", facecolor="blue")
pylab.scatter(x1[bad], x2[bad], edgecolors="red", facecolor="white")
pylab.grid(True)

pylab.subplot(122)
pylab.xlabel("$X'$")
pylab.scatter(Xtrans[good],
              np.zeros(len(Xtrans[good])),
              edgecolors="blue",
              facecolor="blue")
pylab.scatter(Xtrans[bad],
              np.zeros(len(Xtrans[bad])),
              edgecolors="red",
              facecolor="white")
pylab.grid(True)
pylab.autoscale(tight=True)
Beispiel #42
0
    def density_along_orbit(self, ax=None, annotate=True, min_fp_local_length=0, bg_color='dimgrey', cmap=None, vmin=1., vmax=3.):
        if cmap is None:
            cmap = plt.cm.autumn
            cmap.set_bad('dimgrey',0.)
            cmap.set_under('dimgrey',0.)

        if ax is None:
            ax = plt.gca()

        fp_local_list = [d for d in self.digitization_list if np.isfinite(d.fp_local)]

        plt.sca(ax)
        mex.plot_planet(lw=3.)
        mex.plot_bs(lw=1., ls='dashed', color='k')
        mex.plot_mpb(lw=1., ls='dotted', color='k')
        ax.set_aspect('equal', 'box')
        plt.xlim(2,-2)
        plt.autoscale(False,tight=True)
        plt.ylim(0,1.9999)

        if annotate:
            plt.annotate('%d' % self.orbit, (0.05, 0.85), xycoords='axes fraction', va='top')

        def f_x(pos):
            return pos[0] / mex.mars_mean_radius_km
        def f_y(pos):
            return np.sqrt(pos[1]**2. + pos[2]**2.) / mex.mars_mean_radius_km
        # def f_y(pos):
        #     return pos[2] / mex.mars_mean_radius_km

        plt.plot( f_x(self.mso_pos), f_y(self.mso_pos),
                color=bg_color, lw=1., zorder=-10)

        inx = np.interp(np.array([d.time for d in self.ionogram_list]), self.t, np.arange(self.t.shape[0]))
        inx = inx.astype(int)

        plt.plot( f_x(self.mso_pos[:,inx]), f_y(self.mso_pos[:,inx]),
                color=bg_color, ls='None',marker='o', ms=8.,mew=0., mec=bg_color, zorder=-9)

        if fp_local_list:
            val = np.empty_like(self.t) + np.nan
            # for t, v in [(float(f.time), np.log10(ais_code.fp_to_ne(f.maximum_fp_local))) for f in fp_local_list]:
            #     val[np.abs(self.t - t) < ais_code.ais_spacing_seconds] = v

            for f in fp_local_list:
                t = float(f.time)
                # if (f.fp_local_error / f.fp_local) > 0.3:
                #     v = np.log10(20.)
                # else:
                v = np.log10(ais_code.fp_to_ne(f.fp_local))
                # print t, ais_code.fp_to_ne(f.fp_local), f.fp_local_error/f.fp_local > 0.3
                val[np.abs(self.t - t) < ais_code.ais_spacing_seconds] = v

            points = np.array([f_x(self.mso_pos), f_y(self.mso_pos)]).T.reshape(-1, 1, 2)
            segments = np.concatenate([points[:-1], points[1:]], axis=1)
            lc = LineCollection(segments, cmap=cmap, norm=plt.Normalize(vmin=vmin, vmax=vmax, clip=True))
            lc.set_array(val)
            lc.set_linewidth(5)
            plt.gca().add_collection(lc)
        else:
            lc = None

        plt.ylabel(r'$\rho / R_M$')
        # plt.ylabel(r'$z / R_M$')
        plt.xlabel(r'$x / R_M$')
        if lc:
            ticks = [i for i in range(10) if ((float(i)+0.1) > vmin) & ((float(i)-0.1) < vmax)]
            old_ax = plt.gca()
            plt.colorbar(lc, cax = celsius.make_colorbar_cax(offset=0.001, height=0.8),
                            ticks=ticks).set_label(r'$log_{10}\;n_e / cm^{-3}$')
            plt.sca(old_ax)
Beispiel #43
0
    def modb_along_orbit(self, ax=None, annotate=True, bg_color='dimgrey', cmap=None, vmin=0., vmax=20.):
        if ax is None:
            ax = plt.gca()

        if cmap is None:
            cmap = plt.cm.autumn
            cmap.set_bad('dimgrey',0.)
            cmap.set_under('dimgrey',0.)

        td_cyclotron_list = [d for d in self.digitization_list if np.isfinite(d.td_cyclotron)]

        plt.sca(ax)
        mex.plot_planet(lw=3.)
        mex.plot_bs(lw=1., ls='dashed', color='k')
        mex.plot_mpb(lw=1., ls='dotted', color='k')
        ax.set_aspect('equal','box')
        plt.xlim(2,-2)
        plt.autoscale(False,tight=True)
        plt.ylim(0., 1.999)

        if annotate:
            plt.annotate('%d' % self.orbit, (0.05, 0.85),
                        xycoords='axes fraction', va='top')

        def f_x(pos):
            return pos[0] / mex.mars_mean_radius_km
        def f_y(pos):
            return np.sqrt(pos[1]**2. + pos[2]**2.) / mex.mars_mean_radius_km
        # def f_y(pos):
        #     return pos[2] / mex.mars_mean_radius_km

        plt.plot( f_x(self.mso_pos), f_y(self.mso_pos),
                color=bg_color, lw=2., zorder=-10)

        inx = np.interp(np.array([d.time for d in self.ionogram_list]),
                                        self.t, np.arange(self.t.shape[0]))
        inx = inx.astype(int)
        plt.plot(f_x(self.mso_pos[:,inx]), f_y(self.mso_pos[:,inx]),
                color=bg_color, ls='None',marker='o', ms=8., mew=0., mec=bg_color, zorder=-9)

        if td_cyclotron_list:
            val = np.empty_like(self.t) + np.nan
            for t, v in [(float(f.time), 1E9 * ais_code.td_to_modb(f.td_cyclotron))
                                                        for f in td_cyclotron_list]:
                val[np.abs(self.t - t) < ais_code.ais_spacing_seconds] = v

            points = np.array([f_x(self.mso_pos), f_y(self.mso_pos)]).T.reshape(-1, 1, 2)
            segments = np.concatenate([points[:-1], points[1:]], axis=1)
            lc = LineCollection(segments, cmap=cmap,
                    norm=plt.Normalize(vmin=vmin, vmax=vmax, clip=True))

            lc.set_array(val)
            lc.set_linewidth(5)
            plt.gca().add_collection(lc)
        else:
            lc = None
        plt.ylabel(r'$\rho / R_M$')
        # plt.ylabel(r'$z / R_M$')
        plt.xlabel(r'$x / R_M$')
        if lc:
            old_ax = plt.gca()
            plt.colorbar(lc, cax = celsius.make_colorbar_cax(offset=0.001, height=0.8)
                        ).set_label(r'$|B| / nT$')
            plt.sca(old_ax)
Beispiel #44
0
def plot_simple_demo_my_pca():
    pylab.clf()
    fig = pylab.figure(num=None, figsize=(25, 4))
    pylab.subplot(151)

    title = "Original feature space"
    pylab.title(title)
    pylab.xlabel("$X_1$")
    pylab.ylabel("$X_2$")

    np.random.seed(3)
    x1 = np.arange(0, 10, .2)
    x2 = x1 + np.random.normal(loc=0, scale=1, size=len(x1))

    # 两者中,有一个>5就是good
    good = (x1 > 5) | (x2 > 5)
    bad = ~good

    x1g = x1[good]
    x2g = x2[good]
    pylab.scatter(x1g, x2g, edgecolor="blue", facecolor="blue")

    x1b = x1[bad]
    x2b = x2[bad]
    pylab.scatter(x1b, x2b, edgecolor="red", facecolor="white")

    pylab.grid(True)

    pylab.subplot(152)

    X = np.c_[(x1, x2)]  # X:[N, 2]

    Xtrans, eigen_values, V, x_mean = my_pca(X, k_components=2, whiten=False)
    Xtrans_whiten, _, _, _ = my_pca(np.copy(X), k_components=2, whiten=True)

    Xg = Xtrans[good]
    Xb = Xtrans[bad]

    print("======手工pca==========")
    print("原始特征值 eigen_values:", eigen_values)
    print("手工Xg:", Xg)
    print("手工Xg(whiten):", Xtrans_whiten[good])

    pylab.scatter(Xg[:, 0], Xg[:, 1], edgecolor="blue", facecolor="blue")
    pylab.scatter(Xb[:, 0], Xb[:, 1], edgecolor="red", facecolor="white")
    #Xb[:, 0], np.zeros(len(Xb)), edgecolor="red", facecolor="white")
    title = "Transformed feature space"
    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[1].get_yaxis().set_visible(True)
    fig.axes[1].set_xlim(-6, 6)
    fig.axes[1].set_ylim(-6, 6)
    #fig.axes.set_ylim(-6,6)

    # 白化
    Xg = Xtrans_whiten[good]
    Xb = Xtrans_whiten[bad]
    title = "Transformed feature space(whiten)"
    pylab.subplot(153)
    pylab.scatter(Xg[:, 0], Xg[:, 1], edgecolor="blue", facecolor="blue")
    pylab.scatter(Xb[:, 0], Xb[:, 1], edgecolor="red", facecolor="white")

    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[2].get_yaxis().set_visible(True)
    fig.axes[2].set_xlim(-6, 6)
    fig.axes[2].set_ylim(-6, 6)

    # X_new_1d = X*V[:,0:1]
    title = "Transformed feature space(1-d)"
    pylab.subplot(154)
    pylab.scatter(Xg[:, 0],
                  np.zeros(len(Xg)),
                  edgecolor="blue",
                  facecolor="blue")
    pylab.scatter(Xb[:, 0],
                  np.zeros(len(Xb)),
                  edgecolor="red",
                  facecolor="white")

    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[3].get_yaxis().set_visible(True)
    fig.axes[3].set_xlim(-6, 6)
    fig.axes[3].set_ylim(-6, 6)

    # X_new_1d = X*V[:,0:1]
    # 重构信号
    X_reconstruct = Xtrans[:, 0:1] * (V[:, 0:1].T) + x_mean
    Xg = X_reconstruct[good]
    Xb = X_reconstruct[bad]
    title = "reconstruct from transformed feature space(1-d)"
    pylab.xlabel("$X'$")
    pylab.subplot(155)
    pylab.scatter(Xg[:, 0], Xg[:, 1], edgecolor="blue", facecolor="blue")
    pylab.scatter(Xb[:, 0], Xb[:, 1], edgecolor="red", facecolor="white")

    pylab.title(title)
    pylab.xlabel("$X'$")
    fig.axes[4].get_yaxis().set_visible(True)
    fig.axes[4].set_xlim(-6, 10)
    fig.axes[4].set_ylim(-6, 10)

    #pylab.grid(True)
    pylab.autoscale(tight=True)
    filename = "my_pca_demo.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #45
0
def plot_mi_demo():

    # determinism!
    np.random.seed(0)

    # plot1
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(0, 10, 0.2)

    pylab.subplot(221)
    y = 0.5 * x + norm.rvs(1, scale=.01, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(224)
    y = norm.rvs(1, scale=10, size=len(x))
    plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "c_mutual_information_1_ok.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")

    ##############
    # plot 2
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)

    pylab.subplot(221)
    y = 0.5 * x**2 + norm.rvs(1, scale=.01, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(222)
    y = 0.5 * x**2 + norm.rvs(1, scale=.1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(223)
    y = 0.5 * x**2 + norm.rvs(1, scale=1, size=len(x))
    plot_mi_func(x, y)

    pylab.subplot(224)
    y = 0.5 * x**2 + norm.rvs(1, scale=10, size=len(x))
    plot_mi_func(x, y)

    pylab.autoscale(tight=True)
    pylab.grid(True)

    filename = "c_mutual_information_2_ok.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")
Beispiel #46
0
def diagnostic(pipe):
    """
    Print a 1-page diagnostic plot of a given pipeline object

    Args:
        pipe (terra.pipeline.Pipeline) : pipeline object
    """
    fig = plt.figure(figsize=(20,12))
    
    gs_kw = dict(left=0.04,right=0.99)

    # Provision the upper plots
    gs1 = GridSpec(3,10)
    gs1.update(hspace=0.2, wspace=0.6,bottom=0.65,top=0.95, **gs_kw)
    axPeriodogram  = fig.add_subplot(gs1[0,0:8])
    axACF = fig.add_subplot(gs1[0,8])
    
    # These 4 plots all share an xaxis
    ax_transit = fig.add_subplot(gs1[1,0:2])
    ax_transit_zoom = fig.add_subplot(gs1[2,0:2],sharex=ax_transit)
    ax_phasefold_180 = fig.add_subplot(gs1[1,2:4],sharex=ax_transit)
    ax_phasefold_secondary = fig.add_subplot(gs1[2,2:4],sharex=ax_transit)

    ax_phasefold = fig.add_subplot(gs1[1:,4:8])
    axTransitTimes = fig.add_subplot(gs1[1,8])
    axTransitRp = fig.add_subplot(gs1[2,8])

    # Provision the lower plots
    gs2 = GridSpec(1,5)
    gs2.update(hspace=0.05,wspace=0.2,bottom=0.05,top=0.6,**gs_kw)
    axSES = fig.add_subplot(gs2[0 ,0:4])
    axTransitStack = fig.add_subplot(gs2[0 ,4])

    # Periodogram
    plt.sca(axPeriodogram)
    periodogram(pipe)
    ax = plt.gca()
    at = AnchoredText('Periodogram',prop=tprop, frameon=True,loc=2)
    ax.add_artist(at)

    # Auto correlation plot, and header text, defined to the right
    plt.sca(axACF)
    ax = plt.gca()
    autocorr(pipe)
    AddAnchored("ACF",prop=tprop,frameon=True,loc=2)    

    # Transit times, holding depth constant
    plt.sca(axTransitTimes)
    transits(pipe,mode='transit-times')

    # Transit radius ratio
    plt.sca(axTransitRp)
    transits(pipe,mode='transit-rp')

    # Phasefolded photometry 
    plt.sca(ax_transit)
    phasefold_transit(pipe,mode='transit')
    plt.ylabel('Flux')

    # Zoomed phase folded photometry
    plt.sca(ax_transit_zoom)
    phasefold_transit(pipe,mode='transit-zoom')

    # Light curve 180 degrees out of phase
    plt.sca(ax_phasefold_180)
    phasefold_shifted(pipe, 0.5)

    # Phase-folded light curve at the most significant secondary eclipse
    plt.sca(ax_phasefold_secondary)
    phasefold_shifted(pipe, pipe.se_phase)

    # Phase-folded all phases
    plt.sca(ax_phasefold)
    lc, lcbin = phasefold_shifted(pipe, 0, xdata='phase')
    yl = [lcbin.fmed.min(),lcbin.fmed.max()]
    span = lcbin.fmed.ptp()
    yl[0] -= 0.25 * span
    yl[1] += 0.25 * span
    plt.ylim(*yl)
    plt.autoscale(axis='x',tight=True)
    plt.xlabel('Phase')
    plt.ylabel('Flux')

    # Single Event Statistic Stack
    plt.sca(axSES)
    mad = pipe.lc.f.abs().median()
    ystep = 3 * 1.6 * mad
    ystep = max(pipe.fit_rp**2 * 1.0, ystep)

    single_event_statistic_stack(pipe, ystep=ystep)
    pipe.se_phase 
    plt.axvline(0, alpha=.1,lw=10,color='m',zorder=1)

    # Single Event Statistic Stack
    plt.sca(axTransitStack)
    transit_stack(pipe,ystep=ystep)

    axL = [
        ax_transit, ax_transit_zoom, ax_phasefold_180, ax_phasefold_secondary,
        ax_phasefold, axTransitTimes, axTransitRp
    ]
    for ax in axL:
        ax.yaxis.set_major_locator(MaxNLocator(4))

    axL = [
        ax_transit, ax_transit_zoom, ax_phasefold_180, ax_phasefold, 
        axTransitTimes, axTransitRp, axSES, axTransitStack,
    ]
    for ax in fig.get_axes():
        ax.grid()

    plt.sca(axACF)
    text = header_text(pipe)
    plt.text(
        1.1, 1.0, text, family='monospace', size='large', 
        transform=axACF.transAxes, va='top',
    )
Beispiel #47
0
    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))
    x = np.arange(0, 10, 0.2)
    y = 0.5 * x + norm.rvs(1, scale=.01, size=len(x))
    obj.set_data_set(x, y)
    obj.plot_correlation_func(221)
    y = 0.5 * x + norm.rvs(1, scale=.1, size=len(x))
    obj.set_data_set(x, y)
    obj.plot_correlation_func(222)
    y = 0.5 * x + norm.rvs(1, scale=1, size=len(x))
    obj.set_data_set(x, y)
    obj.plot_correlation_func(223)
    y = norm.rvs(1, scale=10, size=len(x))
    obj.set_data_set(x, y)
    obj.plot_correlation_func(224)
    pylab.autoscale(tight=True)
    pylab.grid(True)
    filename = "corr_demo_1.png"
    pylab.savefig(os.path.join(CHART_DIR, filename), bbox_inches="tight")

    pylab.clf()
    pylab.figure(num=None, figsize=(8, 8))

    x = np.arange(-5, 5, 0.2)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=.01, size=len(x))
    obj.set_data_set(x, y)
    obj.plot_correlation_func(221)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=.1, size=len(x))
    obj.set_data_set(x, y)
    obj.plot_correlation_func(222)
    y = 0.5 * x ** 2 + norm.rvs(1, scale=1, size=len(x))