roc.curve: ROC curve
In Jstacs/PRROC: Precision-Recall and ROC Curves for Weighted and Unweighted Data
Description
Usage
Arguments
Details
Value
Author(s)
References
See Also
Examples
Description
Computes the area under the receiver operating characteristics (ROC) curve for weighted and unweighted data.
In addition to the area under the curve, the curve can be obtained by setting argument curve to TRUE.
Usage
1
2
3
4
Arguments
scores.class0
the classification scores of i) all data points or ii) only the data points belonging to the positive class.
In the first case, scores.class1 should not be assigned an explicit value, but left at the default (scores.class1=scores.class0).
In addition, weights.class0 needs to contain the class labels of the data points (1 for positive class, 0 for negative class) or
the soft-labels for the positive class, i.e., the probability for each data point to belong to the positive class.
Accordingly, weights.class1 should be left at the default value (1-weights.class0).
In the second case, the scores for the negative data points need to be provided in scores.class1. In this case, weights.class0 and weights.class1
need to be provided only for soft-labelling and should be of the same length as scores.class0 and scores.class1, respectively.
scores.class1
the scores of the negative class if provided separately (see scores.class0)
weights.class0
the weights for the data points of the positive class in same ordering as scores.class0 (optional)
weights.class1
the weights for the data points of the negative class in same ordering as scores.class1 (optional)
sorted
TRUE if the scores are already sorted
curve
TRUE if the curve should also be returned, FALSE otherwise
max.compute
TRUE if the maximum ROC curve given the supplied weights should be computed
min.compute
TRUE if the minimum ROC curve given the supplied weights should be computed
rand.compute
TRUE if the ROC curve of a random classifier given the supplied weights should be computed
Details
This function computes the area under a receiver-operating characteristic (ROC) curve and, optionally, the curve itself and returns it as a PRROC object (see below).
It can be used under different scenarios:
1. Standard, hard-labeled classification problems:
Each data point is uniquely assigned to one out of two possible classes. In this case, the classification scores may be either provided separately
for the data points of each of the classes, i.e., as scores.class0 for the data points from the positive/foreground class and as scores.class1
for the data points of the negative/background class; or the classification scores for all data points are provided as scores.class0 and the labels
are provided as numerical values (1 for the positive class, 0 for the negative class) as weights.class0.
2. Weighted, hard-labeled classification problems:
Each data point is uniquely assigned to one out of two possible classes, where each data points additionally has a weight assigned, for instance
multiplicities in the original data set. In this case, the classification scores need to be provided separately
for the data points of each of the classes, i.e., as scores.class0 for the data points from the positive/foreground class and as scores.class1
for the data points of the negative/background class. In addition, the weights for the data points must be provided as weights.class0 and weights.class1, respectively.
3. Soft-labeled classification problems:
Each data point belongs to both of the two classes with a certain probability, where for each data point, these two probabilities add up to 1.
In this case, the classification scores for all data points need to be provided only once as scores.class0 and only the positive/foreground weights for each data point need to be provided in weights.class0, while the converse probability for the negative class is automatically set to
weights.class1=1.0-weights.class0.
Value
type
always "ROC"
auc
area under the curve
curve
the ROC curve as a matrix, where the first column contains the false-positive rate, the second contains recall (sensitivity), and the third contains the corresponding threshold on the scores.
max
the maximum ROC curve (if max.compute=TRUE)
min
the minimum ROC curve (if min.compute=TRUE)
rand
the ROC curve of a random classifier (if rand.compute=TRUE)
Author(s)
Jan Grau and Jens Keilwagen
References
J. Keilwagen, I. Grosse, and J. Grau. Area under precision-recall curves for weighted and unweighted data, PLOS ONE (9) 3, 2014.
J. Grau, I. Grosse, and J. Keilwagen. PRROC: computing and visualizing precision-recall and receiver operating characteristic curves in R. Bioinformatics, 31(15):2595-2597, 2015.
See Also
Examples
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# create artificial scores as random numbers
x <- rnorm( 1000 );
y <- rnorm( 1000, -1 );
# compute area under ROC curve for the hard-labeled case
roc <- roc.curve( x, y );
print( roc );
# compute ROC curve and area under curve
roc <- roc.curve( x, y, curve = TRUE );
# plot curve
plot(roc);
# create artificial weights
x.weights <- runif( 1000 );
y.weights <- runif( 1000 );
# compute ROC curve and area under curve for weighted, hard-labeled data
roc <- roc.curve( x, y, x.weights, y.weights, curve = TRUE );
# and plot the curve
plot(roc);
# compute ROC curve and area under curve,
# and maximum, minimum, and random ROC curve for weighted, hard-labeled data
roc <- roc.curve(x, y, x.weights, y.weights, curve = TRUE, max.compute = TRUE,
min.compute = TRUE, rand.compute = TRUE);
# plot all three curves
plot(roc, max.plot = TRUE, min.plot = TRUE, rand.plot = TRUE, fill.area = TRUE)
# concatenate the drawn scores
scores<-c(x,y);
# and create artificial soft-labels
weights<-c(runif(1000, min = 0.5, max = 1), runif(1000, min = 0, max = 0.5))
# compute ROC curve and area under curve,
# and maximum, minimum, and random ROC curve for soft-labeled data
roc<-roc.curve(scores.class0 = scores, weights.class0 = weights, curve = TRUE,
max.compute = TRUE, min.compute = TRUE, rand.compute = TRUE);
# plot all three curves
plot(roc, max.plot = TRUE, min.plot = TRUE, rand.plot = TRUE, fill.area = TRUE)
# print the areas under the curves
print(roc);
# generate classification scores of a second classifier
scores.2<-c(rnorm( 1000 ),rnorm( 1000, -2 ));
# and compute the ROC curve
roc.2<-roc.curve(scores.class0 = scores.2, weights.class0 = weights, curve = TRUE)
# plot all three curves for the first classifier in red
plot(roc, max.plot = TRUE, min.plot = TRUE, rand.plot = TRUE, fill.area = TRUE,
color="red", auc.main=FALSE)
# and add the curve for the second classifier
plot(roc.2, add=TRUE, color="green")
Jstacs/PRROC documentation built on May 14, 2019, 11 p.m.
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Description Usage Arguments Details Value Author(s) References See Also Examples
Description
Computes the area under the receiver operating characteristics (ROC) curve for weighted and unweighted data.
In addition to the area under the curve, the curve can be obtained by setting argument curve to TRUE.
Usage
1 2 3 4 |
Arguments
scores.class0 |
the classification scores of i) all data points or ii) only the data points belonging to the positive class. In the first case, scores.class1 should not be assigned an explicit value, but left at the default (scores.class1=scores.class0). In addition, weights.class0 needs to contain the class labels of the data points (1 for positive class, 0 for negative class) or the soft-labels for the positive class, i.e., the probability for each data point to belong to the positive class. Accordingly, weights.class1 should be left at the default value (1-weights.class0). In the second case, the scores for the negative data points need to be provided in scores.class1. In this case, weights.class0 and weights.class1 need to be provided only for soft-labelling and should be of the same length as scores.class0 and scores.class1, respectively. |
scores.class1 |
the scores of the negative class if provided separately (see scores.class0) |
weights.class0 |
the weights for the data points of the positive class in same ordering as |
weights.class1 |
the weights for the data points of the negative class in same ordering as |
sorted |
|
curve |
|
max.compute |
|
min.compute |
|
rand.compute |
|
Details
This function computes the area under a receiver-operating characteristic (ROC) curve and, optionally, the curve itself and returns it as a PRROC object (see below).
It can be used under different scenarios:
1. Standard, hard-labeled classification problems:
Each data point is uniquely assigned to one out of two possible classes. In this case, the classification scores may be either provided separately
for the data points of each of the classes, i.e., as scores.class0 for the data points from the positive/foreground class and as scores.class1
for the data points of the negative/background class; or the classification scores for all data points are provided as scores.class0 and the labels
are provided as numerical values (1 for the positive class, 0 for the negative class) as weights.class0.
2. Weighted, hard-labeled classification problems:
Each data point is uniquely assigned to one out of two possible classes, where each data points additionally has a weight assigned, for instance
multiplicities in the original data set. In this case, the classification scores need to be provided separately
for the data points of each of the classes, i.e., as scores.class0 for the data points from the positive/foreground class and as scores.class1
for the data points of the negative/background class. In addition, the weights for the data points must be provided as weights.class0 and weights.class1, respectively.
3. Soft-labeled classification problems:
Each data point belongs to both of the two classes with a certain probability, where for each data point, these two probabilities add up to 1.
In this case, the classification scores for all data points need to be provided only once as scores.class0 and only the positive/foreground weights for each data point need to be provided in weights.class0, while the converse probability for the negative class is automatically set to
weights.class1=1.0-weights.class0.
Value
type |
always |
auc |
area under the curve |
curve |
the ROC curve as a matrix, where the first column contains the false-positive rate, the second contains recall (sensitivity), and the third contains the corresponding threshold on the scores. |
max |
the maximum ROC curve (if |
min |
the minimum ROC curve (if |
rand |
the ROC curve of a random classifier (if |
Author(s)
Jan Grau and Jens Keilwagen
References
J. Keilwagen, I. Grosse, and J. Grau. Area under precision-recall curves for weighted and unweighted data, PLOS ONE (9) 3, 2014.
J. Grau, I. Grosse, and J. Keilwagen. PRROC: computing and visualizing precision-recall and receiver operating characteristic curves in R. Bioinformatics, 31(15):2595-2597, 2015.
See Also
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 | # create artificial scores as random numbers
x <- rnorm( 1000 );
y <- rnorm( 1000, -1 );
# compute area under ROC curve for the hard-labeled case
roc <- roc.curve( x, y );
print( roc );
# compute ROC curve and area under curve
roc <- roc.curve( x, y, curve = TRUE );
# plot curve
plot(roc);
# create artificial weights
x.weights <- runif( 1000 );
y.weights <- runif( 1000 );
# compute ROC curve and area under curve for weighted, hard-labeled data
roc <- roc.curve( x, y, x.weights, y.weights, curve = TRUE );
# and plot the curve
plot(roc);
# compute ROC curve and area under curve,
# and maximum, minimum, and random ROC curve for weighted, hard-labeled data
roc <- roc.curve(x, y, x.weights, y.weights, curve = TRUE, max.compute = TRUE,
min.compute = TRUE, rand.compute = TRUE);
# plot all three curves
plot(roc, max.plot = TRUE, min.plot = TRUE, rand.plot = TRUE, fill.area = TRUE)
# concatenate the drawn scores
scores<-c(x,y);
# and create artificial soft-labels
weights<-c(runif(1000, min = 0.5, max = 1), runif(1000, min = 0, max = 0.5))
# compute ROC curve and area under curve,
# and maximum, minimum, and random ROC curve for soft-labeled data
roc<-roc.curve(scores.class0 = scores, weights.class0 = weights, curve = TRUE,
max.compute = TRUE, min.compute = TRUE, rand.compute = TRUE);
# plot all three curves
plot(roc, max.plot = TRUE, min.plot = TRUE, rand.plot = TRUE, fill.area = TRUE)
# print the areas under the curves
print(roc);
# generate classification scores of a second classifier
scores.2<-c(rnorm( 1000 ),rnorm( 1000, -2 ));
# and compute the ROC curve
roc.2<-roc.curve(scores.class0 = scores.2, weights.class0 = weights, curve = TRUE)
# plot all three curves for the first classifier in red
plot(roc, max.plot = TRUE, min.plot = TRUE, rand.plot = TRUE, fill.area = TRUE,
color="red", auc.main=FALSE)
# and add the curve for the second classifier
plot(roc.2, add=TRUE, color="green")
|
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