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- import numpy as np
- from sklearn.gaussian_process import GaussianProcessRegressor
- # Different kernels available in sklearn:
- from sklearn.gaussian_process.kernels import RBF, ConstantKernel, Matern, WhiteKernel, ExpSineSquared, RationalQuadratic
- from matplotlib import pyplot as plt
- # Set random seed for same results
- np.random.seed(12345)
- # Load data
- inFileName = "DATA/original_histograms/mass_mm_higgs_Background.npz"
- with np.load(inFileName) as data:
- bin_edges = data['bin_edges']
- bin_centers = data['bin_centers']
- bin_values = data['bin_values']
- bin_errors = data['bin_errors']
- # Set hyper-parameter bounds for ConstantKernel
- nEvts = np.sum(bin_values)
- const0 = 1
- const_low = 10.0**-5
- const_hi = nEvts * 10.0
- # Set hyper-parameter bounds for RBF kernel
- RBF0 = 1
- RBF_low = 1e-2
- RBF_high = 1e2
- # A) Define kernel: ConstantKernel * RBF:
- kernel_RBF = ConstantKernel(const0, constant_value_bounds=(const_low, const_hi)) * RBF(RBF0, length_scale_bounds=(RBF_low, RBF_high))
- # B) Define kernel: ConstantKernel * Matern:
- kernel_Matern = ConstantKernel(const0, constant_value_bounds=(const_low, const_hi)) * Matern(RBF0, length_scale_bounds=(RBF_low, RBF_high), nu=1.5)
- # Transform x data into 2d vector!
- X = np.atleast_2d(bin_centers).T # true datapoints
- X_to_predict = np.atleast_2d(np.linspace(110, 160, 1000)).T # what to predict
- y = bin_values
- # Initialize Gaussian Process Regressor: !!! alpha = bin_errors, 2*bin_errors or bin_errors**2? Your task to figure out. !!!
- gp = GaussianProcessRegressor(kernel=kernel_RBF, n_restarts_optimizer=1, alpha=bin_errors**2)
- # Fit on X with values y
- gp.fit(X, y)
- # Predict
- y_pred, sigma = gp.predict(X_to_predict, return_std=True)
- plt.title("Example GPR with RBF kernel", fontsize=14, fontweight='bold')
- plt.xlabel(r"$m_{\mu\mu}$ [GeV]", fontsize=12)
- plt.ylabel("Events/Bin", fontsize=12)
- plt.scatter(bin_centers, bin_values, color='r', linewidth=0.5, marker='o', s=10)
- plt.plot(X_to_predict, y_pred, color='k')
- plt.fill_between(X_to_predict.ravel(), y_pred - sigma, y_pred + sigma)
- plt.show()
- plt.savefig("GPR_simple.pdf")
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