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Clustering Analysis

Identify groups and patterns in data using k-means, hierarchical clustering, and DBSCAN for cluster discovery, customer segmentation, and unsupervised learning

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下記のコマンドをコピーしてターミナル(Mac/Linux)または PowerShell(Windows)に貼り付けてください。 ダウンロード → 解凍 → 配置まで全自動。

🍎 Mac / 🐧 Linux 
mkdir -p ~/.claude/skills && cd ~/.claude/skills && curl -L -o clustering-analysis.zip https://jpskill.com/download/21366.zip && unzip -o clustering-analysis.zip && rm clustering-analysis.zip
🪟 Windows (PowerShell) 
$d = "$env:USERPROFILE\.claude\skills"; ni -Force -ItemType Directory $d | Out-Null; iwr https://jpskill.com/download/21366.zip -OutFile "$d\clustering-analysis.zip"; Expand-Archive "$d\clustering-analysis.zip" -DestinationPath $d -Force; ri "$d\clustering-analysis.zip"

完了後、Claude Code を再起動 → 普通に「動画プロンプト作って」のように話しかけるだけで自動発動します。

💾 手動でダウンロードしたい(コマンドが難しい人向け)
  1. 1. 下の青いボタンを押して clustering-analysis.zip をダウンロード
  2. 2. ZIPファイルをダブルクリックで解凍 → clustering-analysis フォルダができる
  3. 3. そのフォルダを C:\Users\あなたの名前\.claude\skills\(Win)または ~/.claude/skills/(Mac)へ移動
  4. 4. Claude Code を再起動
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🎯 このSkillでできること

下記の説明文を読むと、このSkillがあなたに何をしてくれるかが分かります。Claudeにこの分野の依頼をすると、自動で発動します。

📦 インストール方法 (3ステップ)

  1. 1. 上の「ダウンロード」ボタンを押して .skill ファイルを取得
  2. 2. ファイル名の拡張子を .skill から .zip に変えて展開(macは自動展開可)
  3. 3. 展開してできたフォルダを、ホームフォルダの .claude/skills/ に置く
    • · macOS / Linux: ~/.claude/skills/
    • · Windows: %USERPROFILE%\.claude\skills\

Claude Code を再起動すれば完了。「このSkillを使って…」と話しかけなくても、関連する依頼で自動的に呼び出されます。

詳しい使い方ガイドを見る →
最終更新
2026-05-18
取得日時
2026-05-18
同梱ファイル
2

📖 Skill本文(日本語訳)

※ 原文(英語/中国語)を Gemini で日本語化したものです。Claude 自身は原文を読みます。誤訳がある場合は原文をご確認ください。

[Skill 名] クラスタリング分析

クラスタリング分析

概要

クラスタリングは、事前に定義されたラベルなしで、類似した観測値をグループに分割し、データ内の自然なパターンと構造の発見を可能にします。

使用する場面

  • 購買行動やデモグラフィックに基づいて顧客をセグメント化する場合
  • カテゴリに関する事前知識なしにデータ内の自然なグループ分けを発見する場合
  • ターゲットを絞ったマーケティングキャンペーンのために市場セグメントを特定する場合
  • さらなる分析のために大規模なデータセットを意味のあるカテゴリに整理する場合
  • 遺伝子発現データや医用画像データ内のパターンを見つける場合
  • レコメンデーションシステムのためにドキュメント、製品、またはユーザーを類似性によってグループ化する場合

クラスタリングアルゴリズム

  • K-Means: k個のクラスターへの分割
  • Hierarchical: ネストされたクラスターを示すデンドログラム
  • DBSCAN: 密度ベースの任意の形状のクラスター
  • Gaussian Mixture: 確率的クラスタリング
  • Agglomerative: ボトムアップの階層的アプローチ

主要な概念

  • Cluster Validation: クラスターの品質を評価するためのメトリクス
  • Optimal Clusters: 最適なkを決定する方法
  • Inertia: クラスター内平方和
  • Silhouette Score: クラスター分離の尺度
  • Dendrogram: 階層的クラスタリングの可視化

Pythonによる実装

import pandas as pd
import numpy as np
import matplotlib.pyplot as plt
from sklearn.cluster import KMeans, DBSCAN, AgglomerativeClustering
from sklearn.mixture import GaussianMixture
from sklearn.preprocessing import StandardScaler
from sklearn.metrics import (
    silhouette_score, silhouette_samples, davies_bouldin_score,
    calinski_harabasz_score
)
from scipy.cluster.hierarchy import dendrogram, linkage
import seaborn as sns

# Generate sample data
np.random.seed(42)
n_samples = 300
centers = [[0, 0], [5, 5], [-3, 4]]
X = np.vstack([
    np.random.randn(100, 2) + centers[0],
    np.random.randn(100, 2) + centers[1],
    np.random.randn(100, 2) + centers[2],
])

# Standardize
scaler = StandardScaler()
X_scaled = scaler.fit_transform(X)

# K-Means with Elbow method
inertias = []
silhouette_scores = []
k_range = range(2, 11)

for k in k_range:
    kmeans = KMeans(n_clusters=k, random_state=42, n_init=10)
    kmeans.fit(X_scaled)
    inertias.append(kmeans.inertia_)
    silhouette_scores.append(silhouette_score(X_scaled, kmeans.labels_))

fig, axes = plt.subplots(1, 2, figsize=(14, 4))

axes[0].plot(k_range, inertias, 'bo-')
axes[0].set_xlabel('Number of Clusters (k)')
axes[0].set_ylabel('Inertia')
axes[0].set_title('Elbow Method')
axes[0].grid(True, alpha=0.3)

axes[1].plot(k_range, silhouette_scores, 'go-')
axes[1].set_xlabel('Number of Clusters (k)')
axes[1].set_ylabel('Silhouette Score')
axes[1].set_title('Silhouette Analysis')
axes[1].grid(True, alpha=0.3)

plt.tight_layout()
plt.show()

# Optimal k = 3
optimal_k = 3
kmeans = KMeans(n_clusters=optimal_k, random_state=42, n_init=10)
kmeans_labels = kmeans.fit_predict(X_scaled)

# K-Means visualization
fig, axes = plt.subplots(1, 3, figsize=(15, 4))

# K-Means clusters
axes[0].scatter(X[:, 0], X[:, 1], c=kmeans_labels, cmap='viridis', alpha=0.6)
axes[0].scatter(
    kmeans.cluster_centers_[:, 0], kmeans.cluster_centers_[:, 1],
    c='red', marker='X', s=200, edgecolors='black', linewidths=2
)
axes[0].set_title(f'K-Means (k={optimal_k})')
axes[0].set_xlabel('Feature 1')
axes[0].set_ylabel('Feature 2')

# Silhouette plot
ax = axes[1]
y_lower = 10
silhouette_vals = silhouette_samples(X_scaled, kmeans_labels)

for i in range(optimal_k):
    cluster_silhouette_vals = silhouette_vals[kmeans_labels == i]
    cluster_silhouette_vals.sort()

    size_cluster_i = cluster_silhouette_vals.shape[0]
    y_upper = y_lower + size_cluster_i

    ax.fill_betweenx(np.arange(y_lower, y_upper),
                      0, cluster_silhouette_vals,
                      alpha=0.7, label=f'Cluster {i}')
    y_lower = y_upper + 10

ax.axvline(x=silhouette_score(X_scaled, kmeans_labels), color="red", linestyle="--")
ax.set_xlabel('Silhouette Coefficient')
ax.set_ylabel('Cluster Label')
ax.set_title('Silhouette Plot')

# Hierarchical clustering
linkage_matrix = linkage(X_scaled, method='ward')
dendrogram(linkage_matrix, ax=axes[2], truncate_mode='lastp', p=10)
axes[2].set_title('Dendrogram (Ward)')
axes[2].set_xlabel('Sample Index')

plt.tight_layout()
plt.show()

# Hierarchical clustering
hierarchical = AgglomerativeClustering(n_clusters=optimal_k, linkage='ward')
hier_labels = hierarchical.fit_predict(X_scaled)

# DBSCAN clustering
dbscan = DBSCAN(eps=0.4, min_samples=5)
dbscan_labels = dbscan.fit_predict(X_scaled)
n_clusters_dbscan = len(set(dbscan_labels)) - (1 if -1 in dbscan_labels else 0)
n_noise = list(dbscan_labels).count(-1)

# Gaussian Mixture Model
gmm = GaussianMixture(n_components=optimal_k, random_state=42)
gmm_labels = gmm.fit_predict(X_scaled)
gmm_proba = gmm.predict_proba(X_scaled)

# Clustering algorithm comparison
fig, axes = plt.subplots(2, 2, figsize=(12, 10))

algorithms = [
    (kmeans_labels, 'K-Means'),
    (hier_labels, 'Hierarchical'),
    (dbscan_labels, 'DBSCAN'),
    (gmm_labels, 'Gaussian Mixture'),
]

for idx, (labels, title) in enumerate(algorithms):
    ax = axes[idx // 2, idx % 2]

    # Skip noise points for DBSCAN
    mask = labels != -1
    scatter = ax.scatter(
        X[mask, 0], X[mask, 1], c=labels[mask], cmap='viridis', alpha=0.6
    )

    if title == 'DBSCAN' and n_noise > 0:
        noise_mask = labels == -1
        ax.scatter(X[noise_mask, 0], X[noise_mask, 1], c='red', marker='x', s=100, label='Noise')
        ax.legend()

    ax.set_title(f'{title} (n_clusters={len(set(labels[mask]))})')
    ax.set_xlabel('Feature 1')
    ax.set_ylabel('Feature 2')

plt.tight_layout()
plt.show()

# Cluster validation metrics
validation_metrics = {
    'Algorithm': ['K-Means', 'Hierarchical', 'DBSCAN', 'GMM'],
    'Silhouette Score': [
        silhouette_score(X_scaled, kmeans_labels),
        silhouette_score(X_scaled, hier_labels),
        silhouette_score(X_scaled[dbscan_labels != -1], dbscan_labels[dbsca
📜 原文 SKILL.md(Claudeが読む英語/中国語)を展開

Clustering Analysis

Overview

Clustering partitions data into groups of similar observations without pre-defined labels, enabling discovery of natural patterns and structures in data.

When to Use

  • Segmenting customers based on purchasing behavior or demographics
  • Discovering natural groupings in data without prior knowledge of categories
  • Identifying market segments for targeted marketing campaigns
  • Organizing large datasets into meaningful categories for further analysis
  • Finding patterns in gene expression data or medical imaging
  • Grouping documents, products, or users by similarity for recommendation systems

Clustering Algorithms

  • K-Means: Partitioning into k clusters
  • Hierarchical: Dendrograms showing nested clusters
  • DBSCAN: Density-based arbitrary-shaped clusters
  • Gaussian Mixture: Probabilistic clustering
  • Agglomerative: Bottom-up hierarchical approach

Key Concepts

  • Cluster Validation: Metrics to evaluate cluster quality
  • Optimal Clusters: Methods to determine best k
  • Inertia: Within-cluster sum of squares
  • Silhouette Score: Measure of cluster separation
  • Dendrogram: Hierarchical clustering visualization

Implementation with Python

import pandas as pd
import numpy as np
import matplotlib.pyplot as plt
from sklearn.cluster import KMeans, DBSCAN, AgglomerativeClustering
from sklearn.mixture import GaussianMixture
from sklearn.preprocessing import StandardScaler
from sklearn.metrics import (
    silhouette_score, silhouette_samples, davies_bouldin_score,
    calinski_harabasz_score
)
from scipy.cluster.hierarchy import dendrogram, linkage
import seaborn as sns

# Generate sample data
np.random.seed(42)
n_samples = 300
centers = [[0, 0], [5, 5], [-3, 4]]
X = np.vstack([
    np.random.randn(100, 2) + centers[0],
    np.random.randn(100, 2) + centers[1],
    np.random.randn(100, 2) + centers[2],
])

# Standardize
scaler = StandardScaler()
X_scaled = scaler.fit_transform(X)

# K-Means with Elbow method
inertias = []
silhouette_scores = []
k_range = range(2, 11)

for k in k_range:
    kmeans = KMeans(n_clusters=k, random_state=42, n_init=10)
    kmeans.fit(X_scaled)
    inertias.append(kmeans.inertia_)
    silhouette_scores.append(silhouette_score(X_scaled, kmeans.labels_))

fig, axes = plt.subplots(1, 2, figsize=(14, 4))

axes[0].plot(k_range, inertias, 'bo-')
axes[0].set_xlabel('Number of Clusters (k)')
axes[0].set_ylabel('Inertia')
axes[0].set_title('Elbow Method')
axes[0].grid(True, alpha=0.3)

axes[1].plot(k_range, silhouette_scores, 'go-')
axes[1].set_xlabel('Number of Clusters (k)')
axes[1].set_ylabel('Silhouette Score')
axes[1].set_title('Silhouette Analysis')
axes[1].grid(True, alpha=0.3)

plt.tight_layout()
plt.show()

# Optimal k = 3
optimal_k = 3
kmeans = KMeans(n_clusters=optimal_k, random_state=42, n_init=10)
kmeans_labels = kmeans.fit_predict(X_scaled)

# K-Means visualization
fig, axes = plt.subplots(1, 3, figsize=(15, 4))

# K-Means clusters
axes[0].scatter(X[:, 0], X[:, 1], c=kmeans_labels, cmap='viridis', alpha=0.6)
axes[0].scatter(
    kmeans.cluster_centers_[:, 0], kmeans.cluster_centers_[:, 1],
    c='red', marker='X', s=200, edgecolors='black', linewidths=2
)
axes[0].set_title(f'K-Means (k={optimal_k})')
axes[0].set_xlabel('Feature 1')
axes[0].set_ylabel('Feature 2')

# Silhouette plot
ax = axes[1]
y_lower = 10
silhouette_vals = silhouette_samples(X_scaled, kmeans_labels)

for i in range(optimal_k):
    cluster_silhouette_vals = silhouette_vals[kmeans_labels == i]
    cluster_silhouette_vals.sort()

    size_cluster_i = cluster_silhouette_vals.shape[0]
    y_upper = y_lower + size_cluster_i

    ax.fill_betweenx(np.arange(y_lower, y_upper),
                      0, cluster_silhouette_vals,
                      alpha=0.7, label=f'Cluster {i}')
    y_lower = y_upper + 10

ax.axvline(x=silhouette_score(X_scaled, kmeans_labels), color="red", linestyle="--")
ax.set_xlabel('Silhouette Coefficient')
ax.set_ylabel('Cluster Label')
ax.set_title('Silhouette Plot')

# Hierarchical clustering
linkage_matrix = linkage(X_scaled, method='ward')
dendrogram(linkage_matrix, ax=axes[2], truncate_mode='lastp', p=10)
axes[2].set_title('Dendrogram (Ward)')
axes[2].set_xlabel('Sample Index')

plt.tight_layout()
plt.show()

# Hierarchical clustering
hierarchical = AgglomerativeClustering(n_clusters=optimal_k, linkage='ward')
hier_labels = hierarchical.fit_predict(X_scaled)

# DBSCAN clustering
dbscan = DBSCAN(eps=0.4, min_samples=5)
dbscan_labels = dbscan.fit_predict(X_scaled)
n_clusters_dbscan = len(set(dbscan_labels)) - (1 if -1 in dbscan_labels else 0)
n_noise = list(dbscan_labels).count(-1)

# Gaussian Mixture Model
gmm = GaussianMixture(n_components=optimal_k, random_state=42)
gmm_labels = gmm.fit_predict(X_scaled)
gmm_proba = gmm.predict_proba(X_scaled)

# Clustering algorithm comparison
fig, axes = plt.subplots(2, 2, figsize=(12, 10))

algorithms = [
    (kmeans_labels, 'K-Means'),
    (hier_labels, 'Hierarchical'),
    (dbscan_labels, 'DBSCAN'),
    (gmm_labels, 'Gaussian Mixture'),
]

for idx, (labels, title) in enumerate(algorithms):
    ax = axes[idx // 2, idx % 2]

    # Skip noise points for DBSCAN
    mask = labels != -1
    scatter = ax.scatter(
        X[mask, 0], X[mask, 1], c=labels[mask], cmap='viridis', alpha=0.6
    )

    if title == 'DBSCAN' and n_noise > 0:
        noise_mask = labels == -1
        ax.scatter(X[noise_mask, 0], X[noise_mask, 1], c='red', marker='x', s=100, label='Noise')
        ax.legend()

    ax.set_title(f'{title} (n_clusters={len(set(labels[mask]))})')
    ax.set_xlabel('Feature 1')
    ax.set_ylabel('Feature 2')

plt.tight_layout()
plt.show()

# Cluster validation metrics
validation_metrics = {
    'Algorithm': ['K-Means', 'Hierarchical', 'DBSCAN', 'GMM'],
    'Silhouette Score': [
        silhouette_score(X_scaled, kmeans_labels),
        silhouette_score(X_scaled, hier_labels),
        silhouette_score(X_scaled[dbscan_labels != -1], dbscan_labels[dbscan_labels != -1]) if n_noise < len(X_scaled) else np.nan,
        silhouette_score(X_scaled, gmm_labels),
    ],
    'Davies-Bouldin Index': [
        davies_bouldin_score(X_scaled, kmeans_labels),
        davies_bouldin_score(X_scaled, hier_labels),
        davies_bouldin_score(X_scaled[dbscan_labels != -1], dbscan_labels[dbscan_labels != -1]) if n_noise < len(X_scaled) else np.nan,
        davies_bouldin_score(X_scaled, gmm_labels),
    ],
    'Calinski-Harabasz Index': [
        calinski_harabasz_score(X_scaled, kmeans_labels),
        calinski_harabasz_score(X_scaled, hier_labels),
        calinski_harabasz_score(X_scaled[dbscan_labels != -1], dbscan_labels[dbscan_labels != -1]) if n_noise < len(X_scaled) else np.nan,
        calinski_harabasz_score(X_scaled, gmm_labels),
    ],
}

metrics_df = pd.DataFrame(validation_metrics)
print("Clustering Validation Metrics:")
print(metrics_df)

# Cluster size analysis
sizes_df = pd.DataFrame({
    'K-Means': pd.Series(kmeans_labels).value_counts().sort_index(),
    'Hierarchical': pd.Series(hier_labels).value_counts().sort_index(),
    'GMM': pd.Series(gmm_labels).value_counts().sort_index(),
})

print("\nCluster Sizes:")
print(sizes_df)

# Membership probability (GMM)
fig, ax = plt.subplots(figsize=(10, 6))
membership = gmm_proba.max(axis=1)
scatter = ax.scatter(X[:, 0], X[:, 1], c=membership, cmap='RdYlGn', alpha=0.6, s=50)
ax.set_title('Cluster Membership Confidence (GMM)')
ax.set_xlabel('Feature 1')
ax.set_ylabel('Feature 2')
plt.colorbar(scatter, ax=ax, label='Membership Probability')
plt.show()

# Cluster characteristics
kmeans_centers_original = scaler.inverse_transform(kmeans.cluster_centers_)
cluster_df = pd.DataFrame(X, columns=['Feature 1', 'Feature 2'])
cluster_df['Cluster'] = kmeans_labels

for cluster_id in range(optimal_k):
    cluster_data = cluster_df[cluster_df['Cluster'] == cluster_id]
    print(f"\nCluster {cluster_id} Characteristics:")
    print(cluster_data[['Feature 1', 'Feature 2']].describe())

Cluster Quality Metrics

  • Silhouette Score: -1 to 1 (higher is better)
  • Davies-Bouldin Index: Lower is better
  • Calinski-Harabasz Index: Higher is better
  • Inertia: Lower is better (KMeans only)

Algorithm Selection

  • K-Means: Fast, spherical clusters, k needs specification
  • Hierarchical: Produces dendrogram, interpretable
  • DBSCAN: Arbitrary shapes, handles noise
  • GMM: Probabilistic, soft assignments

Deliverables

  • Optimal cluster count analysis
  • Cluster visualizations
  • Validation metrics comparison
  • Cluster characteristics summary
  • Silhouette plots
  • Dendrogram for hierarchical clustering
  • Membership assignments

同梱ファイル

※ ZIPに含まれるファイル一覧。`SKILL.md` 本体に加え、参考資料・サンプル・スクリプトが入っている場合があります。