t-SNE(t-distribution Stochastic Neighbor Embedding)是目前最为流行的高维数据的降维算法。
t-SNE 成立的前提基于这样的一个假设:我们现实世界观察到的数据集,都在本质上有一种低维的特性(low intrinsic dimensionality),尽管它们嵌入在高维空间中,甚至可以说,高维数据经过降维后,在低维状态下,更能显现其本质特性,这其实也是流形学习(Manifold Learning)的基本思想。
原始论文请见,论文链接(pdf)。
1. sklearn 仿真
import 必要的库;
import numpy as np from numpy import linalg from numpy.linalg import norm from scipy.spatial.distance import squareform, pdist # We import sklearn. import sklearn from sklearn.manifold import TSNE from sklearn.datasets import load_digits from sklearn.preprocessing import scale # We'll hack a bit with the t-SNE code in sklearn 0.15.2. from sklearn.metrics.pairwise import pairwise_distances from sklearn.manifold.t_sne import (_joint_probabilities, _kl_divergence) from sklearn.utils.extmath import _ravel # Random state. RS = 20150101 # We'll use matplotlib for graphics. import matplotlib.pyplot as plt import matplotlib.patheffects as PathEffects import matplotlib %matplotlib inline # We import seaborn to make nice plots. import seaborn as sns sns.set_style('darkgrid') sns.set_palette('muted') sns.set_context("notebook", font_scale=1.5, rc={"lines.linewidth": 2.5}) # We'll generate an animation with matplotlib and moviepy. from moviepy.video.io.bindings import mplfig_to_npimage import moviepy.editor as mpy加载数据集
digits = load_digits() # digits.data.shape ⇒ (1797L, 64L)调用 sklearn 工具箱中的 t-SNE 类
X = np.vstack([digits.data[digits.target==i] for i in range(10)]) y = np.hstack([digits.target[digits.target==i] for i in range(10)]) digits_proj = TSNE(random_state=RS).fit_transform(X) # digits_proj:(1797L, 2L),ndarray 类型可视化
def scatter(x, colors): # We choose a color palette with seaborn. palette = np.array(sns.color_palette("hls", 10)) # We create a scatter plot. f = plt.figure(figsize=(8, 8)) ax = plt.subplot(aspect='equal') sc = ax.scatter(x[:,0], x[:,1], lw=0, s=40, c=palette[colors.astype(np.int)]) plt.xlim(-25, 25) plt.ylim(-25, 25) ax.axis('off') ax.axis('tight') # We add the labels for each digit. txts = [] for i in range(10): # Position of each label. xtext, ytext = np.median(x[colors == i, :], axis=0) txt = ax.text(xtext, ytext, str(i), fontsize=24) txt.set_path_effects([ PathEffects.Stroke(linewidth=5, foreground="w"), PathEffects.Normal()]) txts.append(txt) return f, ax, sc, txts scatter(digits_proj, y) plt.savefig('images/digits_tsne-generated.png', dpi=120)