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| author | wolffd |
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| date | Tue, 10 Feb 2015 15:05:51 +0000 |
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Metric Learning to Rank (mlr-1.0) http://www-cse.ucsd.edu/~bmcfee/code/mlr/ Brian McFee <bmcfee@cs.ucsd.edu>, 2010. This code is distributed under the GNU GPL license. See LICENSE for details, or http://www.gnu.org/licenses/gpl-3.0.txt . INTRODUCTION ------------ This package contains the MATLAB code for Metric Learning to Rank (MLR). The latest version of this software can be found at the URL above. The software included here implements the algorithm described in [1] Mcfee, Brian and Lanckriet, G.R.G. Metric learning to rank. Proceedings of the 27th annual International Conference on Machine Learning (ICML), 2010. Please cite this paper if you use this code. INSTALLATION ------------ 1. Requirements This software requires MATLAB R2007a or later. Because it makes extensive use of the "bsxfun" function, earlier versions of Matlab will not work. If you have an older Matlab installation, you can install an alternative bsxfun implementation by going to http://www.mathworks.com/matlabcentral/fileexchange/23005 , however, this may not work, and it will certainly be slower than the native bsxfun implementation. 2. Compiling MEX functions MLR includes two auxiliary functions "cummax" and "binarysearch" to accelerate certain steps of the optimization procedure. The source code for these functions is located in the "util" subdirectory. A makefile is provided, so that (on Unix systems), you can simply type cd util make cd .. 3. Running the demo To test the installation, run mlr_demo from within Matlab. The demo generates a random training/test split of the Wine data set http://archive.ics.uci.edu/ml/datasets/Wine and learns a metric with MLR. Both native and learned metrics are displayed in a figure with a scatter plot. TRAINING -------- There are several modes of operation for training metrics with MLR. In the simplest mode, training data is contained in a matrix X (each column is a training vector), and Y contains the labels/relevance for the training data (see below). [W, Xi, D] = mlr_train(X, Y, C,...) X = d*n data matrix Y = either n-by-1 label of vectors OR n-by-2 cell array where Y{q,1} contains relevant indices for q, and Y{q,2} contains irrelevant indices for q C >= 0 slack trade-off parameter (default=1) W = the learned metric, i.e., the inner product matrix of the learned space can be computed by X' * W * X Xi = slack value on the learned metric (see [1]) D = diagnostics By default, MLR optimizes for Area Under the ROC Curve (AUC). This can be changed by setting the "LOSS" parameter to one of several ranking loss measures: [W, Xi, D] = mlr_train(X, Y, C, LOSS) where LOSS is one of: 'AUC': Area under ROC curve (default) 'KNN': KNN accuracy* 'Prec@k': Precision-at-k 'MAP': Mean Average Precision 'MRR': Mean Reciprocal Rank 'NDCG': Normalized Discounted Cumulative Gain *Note: KNN is correct only for binary classification problems; in practice, Prec@k is usually a better alternative. For KNN/Prec@k/NDCG, a threshold k may be set to determine the truncation of the ranked list. Thiscan be done by setting the k parameter: [W, Xi, D] = mlr_train(X, Y, C, LOSS, k) where k is the number of neighbors for Prec@k or NDCG (default=3) By default, MLR regularizes the metric W by the trace, i.e., the 1-norm of the eigenvalues. This can be changed to one of several alternatives: [W, Xi, D] = mlr_train(X, Y, C, LOSS, k, REG) where REG defines the regularization on W, and is one of: 0: no regularization 1: 1-norm: trace(W) (default) 2: 2-norm: trace(W' * W) 3: Kernel: trace(W * X), assumes X is square and positive-definite The last setting, "kernel", is appropriate for regularizing metrics learned from kernel matrices. W corresponds to a linear projection matrix (rotation and scaling). To learn a restricted model which may only scale, but not rotate the data, W can be constrained to diagonal matrices by setting the "Diagonal" parameter to 1: [W, Xi, D] = mlr_train(X, Y, C, LOSS, k, REG, Diagonal) Diagonal = 0: learn a full d-by-d W (default) Diagonal = 1: learn diagonally-constrained W (d-by-1) Note: the W returned in this case will be the d-by-1 vector corresponding to the main diagonal of a full metric, not the full d-by-d matrix. Finally, we provide a stochastic gradient descent implementation to handle large-scale problems. Rather than estimating gradients from the entire training set, this variant uses a random subset of size B (see below) at each call to the cutting plane subroutine. This results in faster, but less accurate, optimization: [W, Xi, D] = mlr_train(X, Y, C, LOSS, k, REG, Diagonal, B) where B > 0 enables stochastic optimization with batch size B TESTING ------- Once a metric has been trained by "mlr_train", you can evaluate performance across all measures by using the "mlr_test" function: Perf = mlr_test(W, test_k, Xtrain, Ytrain, Xtest, Ytest) W = d-by-d positive semi-definite matrix test_k = vector of k-values to use for KNN/Prec@k/NDCG Xtrain = d-by-n matrix of training data Ytrain = n-by-1 vector of training labels OR n-by-2 cell array where Y{q,1} contains relevant indices (in 1..n) for point q Y{q,2} contains irrelevant indices (in 1..n) for point q Xtest = d-by-m matrix of testing data Ytest = m-by-1 vector of training labels, or m-by-2 cell array If using the cell version, indices correspond to the training set, and must lie in the range (1..n) The output structure Perf contains the mean score for: AUC, KNN, Prec@k, MAP, MRR, NDCG, as well as the effective dimensionality of W, and the best-performing k-value for KNN, Prec@k, and NDCG. For information retrieval settings, consider Xtrain/Ytrain as the corpus and Xtest/Ytest as the queries. By testing with Wnative = eye(size(X,1)) you can quickly evaluate the performance of the native (Euclidean) metric. FEEDBACK -------- Please send any bug reports, source code contributions, etc. to Brian McFee <bmcfee@cs.ucsd.edu>