Struct QuantumFeatureEncoder

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pub struct QuantumFeatureEncoder { /* private fields */ }

Expand description

Quantum Feature Encoder (sklearn-compatible)

Implementations§

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impl QuantumFeatureEncoder

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pub fn new(encoding_type: &str, normalization: &str) -> Self

Examples found in repository ?

examples/sklearn_pipeline_demo.rs (lines 76-79)

25fn main() -> Result<()> {
26    println!("=== Scikit-learn Compatible Quantum ML Demo ===\n");
27
28    // Step 1: Create sklearn-style dataset
29    println!("1. Creating scikit-learn style dataset...");
30
31    let (X, y) = create_sklearn_dataset()?;
32    println!("   - Dataset shape: {:?}", X.dim());
33    println!(
34        "   - Labels: {} classes",
35        y.iter()
36            .map(|&x| x as i32)
37            .collect::<std::collections::HashSet<_>>()
38            .len()
39    );
40    println!(
41        "   - Feature range: [{:.3}, {:.3}]",
42        X.iter().fold(f64::INFINITY, |a, &b| a.min(b)),
43        X.iter().fold(f64::NEG_INFINITY, |a, &b| a.max(b))
44    );
45
46    // Step 2: Create sklearn-compatible quantum estimators
47    println!("\n2. Creating sklearn-compatible quantum estimators...");
48
49    // Quantum Support Vector Classifier
50    let qsvc = QuantumSVC::new();
51
52    // Quantum Multi-Layer Perceptron Classifier
53    let qmlp = QuantumMLPClassifier::new();
54
55    // Quantum K-Means Clustering
56    let mut qkmeans = QuantumKMeans::new(2); // n_clusters
57
58    println!("   - QuantumSVC: quantum kernel");
59    println!("   - QuantumMLP: multi-layer perceptron");
60    println!("   - QuantumKMeans: 2 clusters");
61
62    // Step 3: Create sklearn-style preprocessing pipeline
63    println!("\n3. Building sklearn-compatible preprocessing pipeline...");
64
65    let preprocessing_pipeline = Pipeline::new(vec![
66        ("scaler", Box::new(StandardScaler::new())),
67        (
68            "feature_selection",
69            Box::new(SelectKBest::new(
70                "quantum_mutual_info", // score_func
71                3,                     // k
72            )),
73        ),
74        (
75            "quantum_encoder",
76            Box::new(QuantumFeatureEncoder::new(
77                "angle", // encoding_type
78                "l2",    // normalization
79            )),
80        ),
81    ])?;
82
83    // Step 4: Create complete quantum ML pipeline
84    println!("\n4. Creating complete quantum ML pipeline...");
85
86    let quantum_pipeline = Pipeline::new(vec![
87        ("preprocessing", Box::new(preprocessing_pipeline)),
88        ("classifier", Box::new(qsvc)),
89    ])?;
90
91    println!("   Pipeline steps:");
92    for (i, step_name) in quantum_pipeline.named_steps().iter().enumerate() {
93        println!("   {}. {}", i + 1, step_name);
94    }
95
96    // Step 5: Train-test split (sklearn style)
97    println!("\n5. Performing train-test split...");
98
99    let (X_train, X_test, y_train, y_test) = model_selection::train_test_split(
100        &X,
101        &y,
102        0.3,      // test_size
103        Some(42), // random_state
104    )?;
105
106    println!("   - Training set: {:?}", X_train.dim());
107    println!("   - Test set: {:?}", X_test.dim());
108
109    // Step 6: Cross-validation with quantum models
110    println!("\n6. Performing cross-validation...");
111
112    let mut pipeline_clone = quantum_pipeline.clone();
113    let cv_scores = model_selection::cross_val_score(
114        &mut pipeline_clone,
115        &X_train,
116        &y_train,
117        5, // cv
118    )?;
119
120    println!("   Cross-validation scores: {cv_scores:?}");
121    println!(
122        "   Mean CV accuracy: {:.3} (+/- {:.3})",
123        cv_scores.mean().unwrap(),
124        cv_scores.std(0.0) * 2.0
125    );
126
127    // Step 7: Hyperparameter grid search
128    println!("\n7. Hyperparameter optimization with GridSearchCV...");
129
130    let param_grid = HashMap::from([
131        (
132            "classifier__C".to_string(),
133            vec!["0.1".to_string(), "1.0".to_string(), "10.0".to_string()],
134        ),
135        (
136            "classifier__feature_map_depth".to_string(),
137            vec!["1".to_string(), "2".to_string(), "3".to_string()],
138        ),
139        (
140            "preprocessing__feature_selection__k".to_string(),
141            vec!["2".to_string(), "3".to_string(), "4".to_string()],
142        ),
143    ]);
144
145    let mut grid_search = model_selection::GridSearchCV::new(
146        quantum_pipeline, // estimator
147        param_grid,
148        3, // cv
149    );
150
151    grid_search.fit(&X_train, &y_train)?;
152
153    println!("   Best parameters: {:?}", grid_search.best_params_);
154    println!(
155        "   Best cross-validation score: {:.3}",
156        grid_search.best_score_
157    );
158
159    // Step 8: Train best model and evaluate
160    println!("\n8. Training best model and evaluation...");
161
162    let best_model = grid_search.best_estimator_;
163    let y_pred = best_model.predict(&X_test)?;
164
165    // Calculate metrics using sklearn-style functions
166    let y_test_int = y_test.mapv(|x| x.round() as i32);
167    let accuracy = metrics::accuracy_score(&y_test_int, &y_pred);
168    let precision = metrics::precision_score(&y_test_int, &y_pred, "weighted"); // average
169    let recall = metrics::recall_score(&y_test_int, &y_pred, "weighted"); // average
170    let f1 = metrics::f1_score(&y_test_int, &y_pred, "weighted"); // average
171
172    println!("   Test Results:");
173    println!("   - Accuracy: {accuracy:.3}");
174    println!("   - Precision: {precision:.3}");
175    println!("   - Recall: {recall:.3}");
176    println!("   - F1-score: {f1:.3}");
177
178    // Step 9: Classification report
179    println!("\n9. Detailed classification report...");
180
181    let classification_report = metrics::classification_report(
182        &y_test_int,
183        &y_pred,
184        vec!["Class 0", "Class 1"], // target_names
185        3,                          // digits
186    );
187    println!("{classification_report}");
188
189    // Step 10: Feature importance analysis
190    println!("\n10. Feature importance analysis...");
191
192    if let Some(feature_importances) = best_model.feature_importances() {
193        println!("    Quantum Feature Importances:");
194        for (i, importance) in feature_importances.iter().enumerate() {
195            println!("    - Feature {i}: {importance:.4}");
196        }
197    }
198
199    // Step 11: Model comparison with classical sklearn models
200    println!("\n11. Comparing with classical sklearn models...");
201
202    let classical_models = vec![
203        (
204            "Logistic Regression",
205            Box::new(LogisticRegression::new()) as Box<dyn SklearnClassifier>,
206        ),
207        (
208            "Random Forest",
209            Box::new(RandomForestClassifier::new()) as Box<dyn SklearnClassifier>,
210        ),
211        ("SVM", Box::new(SVC::new()) as Box<dyn SklearnClassifier>),
212    ];
213
214    let mut comparison_results = Vec::new();
215
216    for (name, mut model) in classical_models {
217        model.fit(&X_train, Some(&y_train))?;
218        let y_pred_classical = model.predict(&X_test)?;
219        let classical_accuracy = metrics::accuracy_score(&y_test_int, &y_pred_classical);
220        comparison_results.push((name, classical_accuracy));
221    }
222
223    println!("    Model Comparison:");
224    println!("    - Quantum Pipeline: {accuracy:.3}");
225    for (name, classical_accuracy) in comparison_results {
226        println!("    - {name}: {classical_accuracy:.3}");
227    }
228
229    // Step 12: Clustering with quantum K-means
230    println!("\n12. Quantum clustering analysis...");
231
232    let cluster_labels = qkmeans.fit_predict(&X)?;
233    let silhouette_score = metrics::silhouette_score(&X, &cluster_labels, "euclidean"); // metric
234    let calinski_score = metrics::calinski_harabasz_score(&X, &cluster_labels);
235
236    println!("    Clustering Results:");
237    println!("    - Silhouette Score: {silhouette_score:.3}");
238    println!("    - Calinski-Harabasz Score: {calinski_score:.3}");
239    println!(
240        "    - Unique clusters found: {}",
241        cluster_labels
242            .iter()
243            .collect::<std::collections::HashSet<_>>()
244            .len()
245    );
246
247    // Step 13: Model persistence (sklearn style)
248    println!("\n13. Model persistence (sklearn joblib style)...");
249
250    // Save model
251    best_model.save("quantum_sklearn_model.joblib")?;
252    println!("    - Model saved to: quantum_sklearn_model.joblib");
253
254    // Load model
255    let loaded_model = QuantumSVC::load("quantum_sklearn_model.joblib")?;
256    let test_subset = X_test.slice(s![..5, ..]).to_owned();
257    let y_pred_loaded = loaded_model.predict(&test_subset)?;
258    println!("    - Model loaded and tested on 5 samples");
259
260    // Step 14: Advanced sklearn utilities
261    println!("\n14. Advanced sklearn utilities...");
262
263    // Learning curves (commented out - function not available)
264    // let (train_sizes, train_scores, val_scores) = model_selection::learning_curve(...)?;
265    println!("    Learning Curve Analysis: (Mock results)");
266    let train_sizes = [0.1, 0.33, 0.55, 0.78, 1.0];
267    let train_scores = [0.65, 0.72, 0.78, 0.82, 0.85];
268    let val_scores = [0.62, 0.70, 0.76, 0.79, 0.81];
269
270    for (i, &size) in train_sizes.iter().enumerate() {
271        println!(
272            "    - {:.0}% data: train={:.3}, val={:.3}",
273            size * 100.0,
274            train_scores[i],
275            val_scores[i]
276        );
277    }
278
279    // Validation curves (commented out - function not available)
280    // let (train_scores_val, test_scores_val) = model_selection::validation_curve(...)?;
281    println!("    Validation Curve (C parameter): (Mock results)");
282    let param_range = [0.1, 0.5, 1.0, 2.0, 5.0];
283    let train_scores_val = [0.70, 0.75, 0.80, 0.78, 0.75];
284    let test_scores_val = [0.68, 0.73, 0.78, 0.76, 0.72];
285
286    for (i, &param_value) in param_range.iter().enumerate() {
287        println!(
288            "    - C={}: train={:.3}, test={:.3}",
289            param_value, train_scores_val[i], test_scores_val[i]
290        );
291    }
292
293    // Step 15: Quantum-specific sklearn extensions
294    println!("\n15. Quantum-specific sklearn extensions...");
295
296    // Quantum feature analysis
297    let quantum_feature_analysis = analyze_quantum_features(&best_model, &X_test)?;
298    println!("    Quantum Feature Analysis:");
299    println!(
300        "    - Quantum advantage score: {:.3}",
301        quantum_feature_analysis.advantage_score
302    );
303    println!(
304        "    - Feature entanglement: {:.3}",
305        quantum_feature_analysis.entanglement_measure
306    );
307    println!(
308        "    - Circuit depth efficiency: {:.3}",
309        quantum_feature_analysis.circuit_efficiency
310    );
311
312    // Quantum model interpretation
313    let sample_row = X_test.row(0).to_owned();
314    let quantum_interpretation = interpret_quantum_model(&best_model, &sample_row)?;
315    println!("    Quantum Model Interpretation (sample 0):");
316    println!(
317        "    - Quantum state fidelity: {:.3}",
318        quantum_interpretation.state_fidelity
319    );
320    println!(
321        "    - Feature contributions: {:?}",
322        quantum_interpretation.feature_contributions
323    );
324
325    println!("\n=== Scikit-learn Integration Demo Complete ===");
326
327    Ok(())
328}

Trait Implementations§

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impl SklearnEstimator for QuantumFeatureEncoder

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fn fit(&mut self, _X: &Array2<f64>, _y: Option<&Array1<f64>>) -> Result<()>

Fit the model to training data

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fn get_params(&self) -> HashMap<String, String>

Get model parameters

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fn set_params(&mut self, params: HashMap<String, String>) -> Result<()>

Set model parameters

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fn is_fitted(&self) -> bool

Check if model is fitted

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fn get_feature_names_out(&self) -> Vec<String>

Get feature names

Auto Trait Implementations§

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impl UnwindSafe for QuantumFeatureEncoder

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impl<T> Any for T
where T: 'static + ?Sized,

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Gets the TypeId of self. Read more

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impl<T> From<T> for T

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fn from(t: T) -> T

Returns the argument unchanged.

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fn into(self) -> U

Calls U::from(self).

That is, this conversion is whatever the implementation of From<T> for U chooses to do.

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where F: FnOnce(&Self) -> bool,

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