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source: trunk/sources/HeuristicLab.Algorithms.DataAnalysis/3.4/GaussianProcess/CovarianceFunctions/CovarianceSpectralMixture.cs @ 11128

Last change on this file since 11128 was 10489, checked in by gkronber, 11 years ago

#2125 fixed the bug that covariance functions returned the full gradient vector even when parameters are partially fixed.
changed the calculation of NN covariance and gradient to direct calculation (instead of AutoDiff)

File size: 10.1 KB
Line 
1#region License Information
2/* HeuristicLab
3 * Copyright (C) 2002-2013 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
4 *
5 * This file is part of HeuristicLab.
6 *
7 * HeuristicLab is free software: you can redistribute it and/or modify
8 * it under the terms of the GNU General Public License as published by
9 * the Free Software Foundation, either version 3 of the License, or
10 * (at your option) any later version.
11 *
12 * HeuristicLab is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15 * GNU General Public License for more details.
16 *
17 * You should have received a copy of the GNU General Public License
18 * along with HeuristicLab. If not, see <http://www.gnu.org/licenses/>.
19 */
20#endregion
21
22using System;
23using System.Collections.Generic;
24using System.Linq;
25using System.Linq.Expressions;
26using HeuristicLab.Common;
27using HeuristicLab.Core;
28using HeuristicLab.Data;
29using HeuristicLab.Parameters;
30using HeuristicLab.Persistence.Default.CompositeSerializers.Storable;
31
32namespace HeuristicLab.Algorithms.DataAnalysis {
33  [StorableClass]
34  [Item(Name = "CovarianceSpectralMixture",
35    Description = "The spectral mixture kernel described in Wilson A. G. and Adams R.P., Gaussian Process Kernels for Pattern Discovery and Exptrapolation, ICML 2013.")]
36  public sealed class CovarianceSpectralMixture : ParameterizedNamedItem, ICovarianceFunction {
37    public const string QParameterName = "Number of components (Q)";
38    public const string WeightParameterName = "Weight";
39    public const string FrequencyParameterName = "Component frequency (mu)";
40    public const string LengthScaleParameterName = "Length scale (nu)";
41    public IValueParameter<IntValue> QParameter {
42      get { return (IValueParameter<IntValue>)Parameters[QParameterName]; }
43    }
44
45    public IValueParameter<DoubleArray> WeightParameter {
46      get { return (IValueParameter<DoubleArray>)Parameters[WeightParameterName]; }
47    }
48    public IValueParameter<DoubleArray> FrequencyParameter {
49      get { return (IValueParameter<DoubleArray>)Parameters[FrequencyParameterName]; }
50    }
51
52    public IValueParameter<DoubleArray> LengthScaleParameter {
53      get { return (IValueParameter<DoubleArray>)Parameters[LengthScaleParameterName]; }
54    }
55
56    private bool HasFixedWeightParameter {
57      get { return WeightParameter.Value != null; }
58    }
59    private bool HasFixedFrequencyParameter {
60      get { return FrequencyParameter.Value != null; }
61    }
62    private bool HasFixedLengthScaleParameter {
63      get { return LengthScaleParameter.Value != null; }
64    }
65
66    [StorableConstructor]
67    private CovarianceSpectralMixture(bool deserializing)
68      : base(deserializing) {
69    }
70
71    private CovarianceSpectralMixture(CovarianceSpectralMixture original, Cloner cloner)
72      : base(original, cloner) {
73    }
74
75    public CovarianceSpectralMixture()
76      : base() {
77      Name = ItemName;
78      Description = ItemDescription;
79      Parameters.Add(new ValueParameter<IntValue>(QParameterName, "The number of Gaussians (Q) to use for the spectral mixture.", new IntValue(10)));
80      Parameters.Add(new OptionalValueParameter<DoubleArray>(WeightParameterName, "The weight of the component w (peak height of the Gaussian in spectrum)."));
81      Parameters.Add(new OptionalValueParameter<DoubleArray>(FrequencyParameterName, "The inverse component period parameter mu_q (location of the Gaussian in spectrum)."));
82      Parameters.Add(new OptionalValueParameter<DoubleArray>(LengthScaleParameterName, "The length scale parameter (nu_q) (variance of the Gaussian in the spectrum)."));
83    }
84
85    public override IDeepCloneable Clone(Cloner cloner) {
86      return new CovarianceSpectralMixture(this, cloner);
87    }
88
89    public int GetNumberOfParameters(int numberOfVariables) {
90      var q = QParameter.Value.Value;
91      return
92        (HasFixedWeightParameter ? 0 : q) +
93        (HasFixedFrequencyParameter ? 0 : q * numberOfVariables) +
94        (HasFixedLengthScaleParameter ? 0 : q * numberOfVariables);
95    }
96
97    public void SetParameter(double[] p) {
98      double[] weight, frequency, lengthScale;
99      GetParameterValues(p, out weight, out frequency, out lengthScale);
100      WeightParameter.Value = new DoubleArray(weight);
101      FrequencyParameter.Value = new DoubleArray(frequency);
102      LengthScaleParameter.Value = new DoubleArray(lengthScale);
103    }
104
105
106    private void GetParameterValues(double[] p, out double[] weight, out double[] frequency, out double[] lengthScale) {
107      // gather parameter values
108      int c = 0;
109      int q = QParameter.Value.Value;
110      // guess number of elements for frequency and length (=q * numberOfVariables)
111      int n = WeightParameter.Value == null ? ((p.Length - q) / 2) : (p.Length / 2);
112      if (HasFixedWeightParameter) {
113        weight = WeightParameter.Value.ToArray();
114      } else {
115        weight = p.Skip(c).Select(Math.Exp).Take(q).ToArray();
116        c += q;
117      }
118      if (HasFixedFrequencyParameter) {
119        frequency = FrequencyParameter.Value.ToArray();
120      } else {
121        frequency = p.Skip(c).Select(Math.Exp).Take(n).ToArray();
122        c += n;
123      }
124      if (HasFixedLengthScaleParameter) {
125        lengthScale = LengthScaleParameter.Value.ToArray();
126      } else {
127        lengthScale = p.Skip(c).Select(Math.Exp).Take(n).ToArray();
128        c += n;
129      }
130      if (p.Length != c) throw new ArgumentException("The length of the parameter vector does not match the number of free parameters for CovarianceSpectralMixture", "p");
131    }
132
133    public ParameterizedCovarianceFunction GetParameterizedCovarianceFunction(double[] p, IEnumerable<int> columnIndices) {
134      double[] weight, frequency, lengthScale;
135      GetParameterValues(p, out weight, out frequency, out lengthScale);
136      var fixedWeight = HasFixedWeightParameter;
137      var fixedFrequency = HasFixedFrequencyParameter;
138      var fixedLengthScale = HasFixedLengthScaleParameter;
139      // create functions
140      var cov = new ParameterizedCovarianceFunction();
141      cov.Covariance = (x, i, j) => {
142        return GetCovariance(x, x, i, j, QParameter.Value.Value, weight, frequency,
143                             lengthScale, columnIndices);
144      };
145      cov.CrossCovariance = (x, xt, i, j) => {
146        return GetCovariance(x, xt, i, j, QParameter.Value.Value, weight, frequency,
147                             lengthScale, columnIndices);
148      };
149      cov.CovarianceGradient = (x, i, j) => GetGradient(x, i, j, QParameter.Value.Value, weight, frequency,
150                             lengthScale, columnIndices, fixedWeight, fixedFrequency, fixedLengthScale);
151      return cov;
152    }
153
154    private static double GetCovariance(double[,] x, double[,] xt, int i, int j, int maxQ, double[] weight, double[] frequency, double[] lengthScale, IEnumerable<int> columnIndices) {
155      // tau = x - x' (only for selected variables)
156      double[] tau =
157        Util.GetRow(x, i, columnIndices).Zip(Util.GetRow(xt, j, columnIndices), (xi, xj) => xi - xj).ToArray();
158      int numberOfVariables = lengthScale.Length / maxQ;
159      double k = 0;
160      // for each component
161      for (int q = 0; q < maxQ; q++) {
162        double kc = weight[q]; // weighted kernel component
163
164        int idx = 0; // helper index for tau
165        // for each selected variable
166        foreach (var c in columnIndices) {
167          kc *= f1(tau[idx], lengthScale[q * numberOfVariables + c]) * f2(tau[idx], frequency[q * numberOfVariables + c]);
168          idx++;
169        }
170        k += kc;
171      }
172      return k;
173    }
174
175    public static double f1(double tau, double lengthScale) {
176      return Math.Exp(-2 * Math.PI * Math.PI * tau * tau * lengthScale);
177    }
178    public static double f2(double tau, double frequency) {
179      return Math.Cos(2 * Math.PI * tau * frequency);
180    }
181
182    // order of returned gradients must match the order in GetParameterValues!
183    private static IEnumerable<double> GetGradient(double[,] x, int i, int j, int maxQ, double[] weight, double[] frequency, double[] lengthScale, IEnumerable<int> columnIndices,
184      bool fixedWeight, bool fixedFrequency, bool fixedLengthScale) {
185      double[] tau = Util.GetRow(x, i, columnIndices).Zip(Util.GetRow(x, j, columnIndices), (xi, xj) => xi - xj).ToArray();
186      int numberOfVariables = lengthScale.Length / maxQ;
187
188      if (!fixedWeight) {
189        // weight
190        // for each component
191        for (int q = 0; q < maxQ; q++) {
192          double k = weight[q];
193          int idx = 0; // helper index for tau
194          // for each selected variable
195          foreach (var c in columnIndices) {
196            k *= f1(tau[idx], lengthScale[q * numberOfVariables + c]) * f2(tau[idx], frequency[q * numberOfVariables + c]);
197            idx++;
198          }
199          yield return k;
200        }
201      }
202
203      if (!fixedFrequency) {
204        // frequency
205        // for each component
206        for (int q = 0; q < maxQ; q++) {
207          int idx = 0; // helper index for tau
208          // for each selected variable
209          foreach (var c in columnIndices) {
210            double k = f1(tau[idx], lengthScale[q * numberOfVariables + c]) *
211                       -2 * Math.PI * tau[idx] * frequency[q * numberOfVariables + c] *
212                       Math.Sin(2 * Math.PI * tau[idx] * frequency[q * numberOfVariables + c]);
213            idx++;
214            yield return weight[q] * k;
215          }
216        }
217      }
218
219      if (!fixedLengthScale) {
220        // length scale
221        // for each component
222        for (int q = 0; q < maxQ; q++) {
223          int idx = 0; // helper index for tau
224          // for each selected variable
225          foreach (var c in columnIndices) {
226            double k = -2 * Math.PI * Math.PI * tau[idx] * tau[idx] * lengthScale[q * numberOfVariables + c] *
227                       f1(tau[idx], lengthScale[q * numberOfVariables + c]) *
228                       f2(tau[idx], frequency[q * numberOfVariables + c]);
229            idx++;
230            yield return weight[q] * k;
231          }
232        }
233      }
234    }
235  }
236}
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