Title: | Machine Learning Benchmark Problems |
---|---|
Description: | A collection of artificial and real-world machine learning benchmark problems, including, e.g., several data sets from the UCI repository. |
Authors: | Friedrich Leisch [aut] (<https://orcid.org/0000-0001-7278-1983>, maintainer up to 2024), Evgenia Dimitriadou [aut], Kurt Hornik [cre] |
Maintainer: | Kurt Hornik <[email protected]> |
License: | GPL-2 |
Version: | 2.1-5 |
Built: | 2024-12-18 06:53:15 UTC |
Source: | CRAN |
Converts x
(which is basically a list) to a dataframe.
## S3 method for class 'mlbench' as.data.frame(x, row.names=NULL, optional=FALSE, ...)
## S3 method for class 'mlbench' as.data.frame(x, row.names=NULL, optional=FALSE, ...)
x |
Object of class |
row.names , optional , ...
|
currently ignored. |
p <- mlbench.xor(5) p as.data.frame(p)
p <- mlbench.xor(5) p as.data.frame(p)
Returns the decision of the (optimal) Bayes classifier for a given data set. This is a generic function, i.e., there are different methods for the various mlbench problems.
If the classes of the problem do not overlap, then the Bayes
decision is identical to the true classification, which is
implemented as the dummy function bayesclass.noerr
(which
simply returns z$classes
and is used for all problems with
disjunct classes).
bayesclass(z)
bayesclass(z)
z |
An object of class |
# 6 overlapping classes p <- mlbench.2dnormals(500,6) plot(p) plot(p$x, col=as.numeric(bayesclass(p)))
# 6 overlapping classes p <- mlbench.2dnormals(500,6) plot(p) plot(p$x, col=as.numeric(bayesclass(p)))
Housing data for 506 census tracts of Boston from the 1970
census. The dataframe
BostonHousing
contains the original data by Harrison and
Rubinfeld (1979), the dataframe BostonHousing2
the corrected
version with additional spatial information (see references below).
data("BostonHousing", package = "mlbench") data("BostonHousing2", package = "mlbench")
data("BostonHousing", package = "mlbench") data("BostonHousing2", package = "mlbench")
The original data are 506 observations on 14 variables,
medv
being the target variable:
crim | per capita crime rate by town |
zn | proportion of residential land zoned for lots over 25,000 sq.ft |
indus | proportion of non-retail business acres per town |
chas | Charles River dummy variable (= 1 if tract bounds river; 0 otherwise) |
nox | nitric oxides concentration (parts per 10 million) |
rm | average number of rooms per dwelling |
age | proportion of owner-occupied units built prior to 1940 |
dis | weighted distances to five Boston employment centres |
rad | index of accessibility to radial highways |
tax | full-value property-tax rate per USD 10,000 |
ptratio | pupil-teacher ratio by town |
b | where is the proportion of blacks by town |
lstat | percentage of lower status of the population |
medv | median value of owner-occupied homes in USD 1000's |
The corrected data set has the following additional columns:
cmedv | corrected median value of owner-occupied homes in USD 1000's |
town | name of town |
tract | census tract |
lon | longitude of census tract |
lat | latitude of census tract |
The original data were taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and no longer seem to be available from the UC Irvine Machine Learning Repository (now at https://archive.ics.uci.edu/). The corrected data were taken from Statlib at http://lib.stat.cmu.edu/datasets/. See Statlib and references there for details on the corrections. Both were converted to R format by Friedrich Leisch.
Harrison, D. and Rubinfeld, D.L. (1978). Hedonic prices and the demand for clean air. Journal of Environmental Economics and Management, 5, 81–102.
Gilley, O.W., and R. Kelley Pace (1996). On the Harrison and Rubinfeld Data. Journal of Environmental Economics and Management, 31, 403–405. [Provided corrections and examined censoring.]
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
Pace, R. Kelley, and O.W. Gilley (1997). Using the Spatial Configuration of the Data to Improve Estimation. Journal of the Real Estate Finance and Economics, 14, 333–340. [Added georeferencing and spatial estimation.]
data("BostonHousing", package = "mlbench") summary(BostonHousing) data("BostonHousing2", package = "mlbench") summary(BostonHousing2)
data("BostonHousing", package = "mlbench") summary(BostonHousing) data("BostonHousing2", package = "mlbench") summary(BostonHousing2)
The objective is to identify each of a number of benign or malignant classes. Samples arrive periodically as Dr. Wolberg reports his clinical cases. The database therefore reflects this chronological grouping of the data. This grouping information appears immediately below, having been removed from the data itself. Each variable except for the first was converted into 11 primitive numerical attributes with values ranging from 0 through 10. There are 16 missing attribute values. See cited below for more details.
data("BreastCancer", package = "mlbench")
data("BreastCancer", package = "mlbench")
A data frame with 699 observations on 11 variables, one being a character variable, 9 being ordered or nominal, and 1 target class.
[,1] | Id | Sample code number |
[,2] | Cl.thickness | Clump Thickness |
[,3] | Cell.size | Uniformity of Cell Size |
[,4] | Cell.shape | Uniformity of Cell Shape |
[,5] | Marg.adhesion | Marginal Adhesion |
[,6] | Epith.c.size | Single Epithelial Cell Size |
[,7] | Bare.nuclei | Bare Nuclei |
[,8] | Bl.cromatin | Bland Chromatin |
[,9] | Normal.nucleoli | Normal Nucleoli |
[,10] | Mitoses | Mitoses |
[,11] | Class | Class |
Creator: Dr. WIlliam H. Wolberg (physician); University of Wisconsin Hospital ;Madison; Wisconsin; USA
Donor: Olvi Mangasarian ([email protected])
Received: David W. Aha ([email protected])
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Breast Cancer Wisconsin (Original) data set is available from doi:10.24432/C5HP4Z.
1. Wolberg,W.H., and Mangasarian,O.L. (1990). Multisurface method of
pattern separation for medical diagnosis applied to breast cytology. In
Proceedings of the National Academy of Sciences, 87,
9193-9196.
- Size of data set: only 369 instances (at that point in time)
- Collected classification results: 1 trial only
- Two pairs of parallel hyperplanes were found to be consistent with
50% of the data
- Accuracy on remaining 50% of dataset: 93.5%
- Three pairs of parallel hyperplanes were found to be consistent with
67% of data
- Accuracy on remaining 33% of dataset: 95.9%
2. Zhang,J. (1992). Selecting typical instances in instance-based
learning. In Proceedings of the Ninth International Machine
Learning Conference (pp. 470-479). Aberdeen, Scotland: Morgan
Kaufmann.
- Size of data set: only 369 instances (at that point in time)
- Applied 4 instance-based learning algorithms
- Collected classification results averaged over 10 trials
- Best accuracy result:
- 1-nearest neighbor: 93.7%
- trained on 200 instances, tested on the other 169
- Also of interest:
- Using only typical instances: 92.2% (storing only 23.1 instances)
- trained on 200 instances, tested on the other 169
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("BreastCancer", package = "mlbench") summary(BreastCancer)
data("BreastCancer", package = "mlbench") summary(BreastCancer)
It consists of 3,186 data points (splice junctions). The data points are described by 180 indicator binary variables and the problem is to recognize the 3 classes (ei, ie, neither), i.e., the boundaries between exons (the parts of the DNA sequence retained after splicing) and introns (the parts of the DNA sequence that are spliced out).
The StaLog dna dataset is a processed version of the Irvine database described below. The main difference is that the symbolic variables representing the nucleotides (only A,G,T,C) were replaced by 3 binary indicator variables. Thus the original 60 symbolic attributes were changed into 180 binary attributes. The names of the examples were removed. The examples with ambiguities were removed (there was very few of them, 4). The StatLog version of this dataset was produced by Ross King at Strathclyde University. For original details see the Irvine database documentation.
The nucleotides A,C,G,T were given indicator values as follows:
A -> 1 0 0 | |
C -> 0 1 0 | |
G -> 0 0 1 | |
T -> 0 0 0 | |
Hint. Much better performance is generally observed if attributes closest to the junction are used. In the StatLog version, this means using attributes A61 to A120 only.
data("DNA", package = "mlbench")
data("DNA", package = "mlbench")
A data frame with 3,186 observations on 180 variables, all nominal and a target class.
Source:
- all examples taken from Genbank 64.1 (ftp site:
genbank.bio.net)
- categories "ei" and "ie" include every "split-gene"
for primates in Genbank 64.1
- non-splice examples taken from sequences known not to include
a splicing site
Donor: G. Towell, M. Noordewier, and J. Shavlik, towell,[email protected], [email protected]
These data have been taken from:
ftp.stams.strath.ac.uk/pub/Statlog
and were converted to R format by Evgenia Dimitriadou.
machine learning:
– M. O. Noordewier and G. G. Towell and J. W. Shavlik, 1991;
"Training Knowledge-Based Neural Networks to Recognize Genes in
DNA Sequences". Advances in Neural Information Processing Systems,
volume 3, Morgan Kaufmann.
– G. G. Towell and J. W. Shavlik and M. W. Craven, 1991; "Constructive Induction in Knowledge-Based Neural Networks", In Proceedings of the Eighth International Machine Learning Workshop, Morgan Kaufmann.
– G. G. Towell, 1991; "Symbolic Knowledge and Neural Networks: Insertion, Refinement, and Extraction", PhD Thesis, University of Wisconsin - Madison.
– G. G. Towell and J. W. Shavlik, 1992; "Interpretation of Artificial Neural Networks: Mapping Knowledge-based Neural Networks into Rules", In Advances in Neural Information Processing Systems, volume 4, Morgan Kaufmann.
data("DNA", package = "mlbench") summary(DNA)
data("DNA", package = "mlbench") summary(DNA)
A data frame with 214 observation containing examples of the chemical analysis of 7 different types of glass. The problem is to forecast the type of class on basis of the chemical analysis. The study of classification of types of glass was motivated by criminological investigation. At the scene of the crime, the glass left can be used as evidence (if it is correctly identified!).
data("Glass", package = "mlbench")
data("Glass", package = "mlbench")
A data frame with 214 observations on 10 variables:
[,1] | RI | refractive index |
[,2] | Na | Sodium |
[,3] | Mg | Magnesium |
[,4] | Al | Aluminum |
[,5] | Si | Silicon |
[,6] | K | Potassium |
[,7] | Ca | Calcium |
[,8] | Ba | Barium |
[,9] | Fe | Iron |
[,10] | Type | Type of glass (class attribute) |
Creator: B. German, Central Research Establishment, Home Office Forensic Science Service, Aldermaston, Reading, Berkshire RG7 4PN
Donor: Vina Spiehler, Ph.D., DABFT, Diagnostic Products Corporation
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Friedrich Leisch in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Glass Identification data set is available from doi:10.24432/C5WW2P.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Glass", package = "mlbench") summary(Glass)
data("Glass", package = "mlbench") summary(Glass)
This data set includes votes for each of the U.S. House of Representatives Congressmen on the 16 key votes identified by the CQA. The CQA lists nine different types of votes: voted for, paired for, and announced for (these three simplified to yea), voted against, paired against, and announced against (these three simplified to nay), voted present, voted present to avoid conflict of interest, and did not vote or otherwise make a position known (these three simplified to an unknown disposition).
data("HouseVotes84", package = "mlbench")
data("HouseVotes84", package = "mlbench")
A data frame with 435 observations on 17 variables:
1 | Class Name: 2 (democrat, republican) |
2 | handicapped-infants: 2 (y,n) |
3 | water-project-cost-sharing: 2 (y,n) |
4 | adoption-of-the-budget-resolution: 2 (y,n) |
5 | physician-fee-freeze: 2 (y,n) |
6 | el-salvador-aid: 2 (y,n) |
7 | religious-groups-in-schools: 2 (y,n) |
8 | anti-satellite-test-ban: 2 (y,n) |
9 | aid-to-nicaraguan-contras: 2 (y,n) |
10 | mx-missile: 2 (y,n) |
11 | immigration: 2 (y,n) |
12 | synfuels-corporation-cutback: 2 (y,n) |
13 | education-spending: 2 (y,n) |
14 | superfund-right-to-sue: 2 (y,n) |
15 | crime: 2 (y,n) |
16 | duty-free-exports: 2 (y,n) |
17 | export-administration-act-south-africa: 2 (y,n) |
Source: Congressional Quarterly Almanac, 98th Congress, 2nd session 1984, Volume XL: Congressional Quarterly Inc., ington, D.C., 1985
Donor: Jeff Schlimmer ([email protected])
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Friedrich Leisch in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Congressional Voting Records data set is available from doi:10.24432/C5C01P.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("HouseVotes84", package = "mlbench") summary(HouseVotes84)
data("HouseVotes84", package = "mlbench") summary(HouseVotes84)
This radar data was collected by a system in Goose Bay, Labrador. This system consists of a phased array of 16 high-frequency antennas with a total transmitted power on the order of 6.4 kilowatts. See the paper for more details. The targets were free electrons in the ionosphere. "good" radar returns are those showing evidence of some type of structure in the ionosphere. "bad" returns are those that do not; their signals pass through the ionosphere.
Received signals were processed using an autocorrelation function whose arguments are the time of a pulse and the pulse number. There were 17 pulse numbers for the Goose Bay system. Instances in this databse are described by 2 attributes per pulse number, corresponding to the complex values returned by the function resulting from the complex electromagnetic signal. See cited below for more details.
data("Ionosphere", package = "mlbench")
data("Ionosphere", package = "mlbench")
A data frame with 351 observations on 35 independent variables, some numerical and 2 nominal, and one last defining the class.
Source: Space Physics Group; Applied Physics Laboratory; Johns Hopkins University; Johns Hopkins Road; Laurel; MD 20723
Donor: Vince Sigillito ([email protected])
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Ionosphere data set is available from doi:10.24432/C5W01B.
Sigillito, V. G., Wing, S. P., Hutton, L. V., and Baker, K. B. (1989). Classification of radar returns from the ionosphere using neural networks. Johns Hopkins APL Technical Digest, 10, 262-266.
They investigated using backprop and the perceptron training algorithm on this database. Using the first 200 instances for training, which were carefully split almost 50% positive and 50% negative, they found that a "linear" perceptron attained 90.7%, a "non-linear" perceptron attained 92%, and backprop an average of over 96% accuracy on the remaining 150 test instances, consisting of 123 "good" and only 24 "bad" instances. (There was a counting error or some mistake somewhere; there are a total of 351 rather than 350 instances in this domain.) Accuracy on "good" instances was much higher than for "bad" instances. Backprop was tested with several different numbers of hidden units (in [0,15]) and incremental results were also reported (corresponding to how well the different variants of backprop did after a periodic number of epochs).
David Aha ([email protected]) briefly investigated this database. He found that nearest neighbor attains an accuracy of 92.1%, that Ross Quinlan's C4 algorithm attains 94.0% (no windowing), and that IB3 (Aha and Kibler, IJCAI-1989) attained 96.7% (parameter settings: 70% and 80% for acceptance and dropping respectively).
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Ionosphere", package = "mlbench") summary(Ionosphere)
data("Ionosphere", package = "mlbench") summary(Ionosphere)
The objective is to identify each of a large number of black-and-white rectangular pixel displays as one of the 26 capital letters in the English alphabet. The character images were based on 20 different fonts and each letter within these 20 fonts was randomly distorted to produce a file of 20,000 unique stimuli. Each stimulus was converted into 16 primitive numerical attributes (statistical moments and edge counts) which were then scaled to fit into a range of integer values from 0 through 15. We typically train on the first 16000 items and then use the resulting model to predict the letter category for the remaining 4000. See the article cited below for more details.
data("LetterRecognition", package = "mlbench")
data("LetterRecognition", package = "mlbench")
A data frame with 20,000 observations on 17 variables, the first is a factor with levels A-Z, the remaining 16 are numeric.
[,1] | lettr | capital letter |
[,2] | x.box | horizontal position of box |
[,3] | y.box | vertical position of box |
[,4] | width | width of box |
[,5] | high | height of box |
[,6] | onpix | total number of on pixels |
[,7] | x.bar | mean x of on pixels in box |
[,8] | y.bar | mean y of on pixels in box |
[,9] | x2bar | mean x variance |
[,10] | y2bar | mean y variance |
[,11] | xybar | mean x y correlation |
[,12] | x2ybr | mean of |
[,13] | xy2br | mean of |
[,14] | x.ege | mean edge count left to right |
[,15] | xegvy | correlation of x.ege with y |
[,16] | y.ege | mean edge count bottom to top |
[,17] | yegvx | correlation of y.ege with x |
Creator: David J. Slate
Odesta Corporation; 1890 Maple Ave; Suite 115; Evanston, IL 60201
Donor: David J. Slate ([email protected]) (708) 491-3867
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Friedrich Leisch in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Letter Recognition data set is available from doi:10.24432/C5ZP40.
P. W. Frey and D. J. Slate (Machine Learning Vol 6/2 March 91): "Letter Recognition Using Holland-style Adaptive Classifiers".
The research for this article investigated the ability of several variations of Holland-style adaptive classifier systems to learn to correctly guess the letter categories associated with vectors of 16 integer attributes extracted from raster scan images of the letters. The best accuracy obtained was a little over 80%. It would be interesting to see how well other methods do with the same data.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("LetterRecognition", package = "mlbench") summary(LetterRecognition)
data("LetterRecognition", package = "mlbench") summary(LetterRecognition)
Each of the cl
classes consists of a 2-dimensional
Gaussian. The centers are equally spaced on a circle around the
origin with radius r
.
mlbench.2dnormals(n, cl=2, r=sqrt(cl), sd=1)
mlbench.2dnormals(n, cl=2, r=sqrt(cl), sd=1)
n |
number of patterns to create |
cl |
number of classes |
r |
radius at which the centers of the classes are located |
sd |
standard deviation of the Gaussians |
Returns an object of class "bayes.2dnormals"
with components
x |
input values |
classes |
factor vector of length |
# 2 classes p <- mlbench.2dnormals(500,2) plot(p) # 6 classes p <- mlbench.2dnormals(500,6) plot(p)
# 2 classes p <- mlbench.2dnormals(500,2) plot(p) # 6 classes p <- mlbench.2dnormals(500,6) plot(p)
The inputs of the cassini problem are uniformly distributed on
a 2
-dimensional space within 3 structures. The 2 external
structures (classes) are banana-shaped structures and in between them, the
middle structure (class) is a circle.
mlbench.cassini(n, relsize=c(2,2,1))
mlbench.cassini(n, relsize=c(2,2,1))
n |
number of patterns to create |
relsize |
relative size of the classes (vector of length 3) |
Returns an object of class "mlbench.cassini"
with components
x |
input values |
classes |
vector of length |
Evgenia Dimitriadou and Andreas Weingessel
p <- mlbench.cassini(5000) plot(p)
p <- mlbench.cassini(5000) plot(p)
The inputs of the circle problem are uniformly distributed on
the d
-dimensional cube with corners .
This is a 2-class problem: The first class is a
d
-dimensional
ball in the middle of the cube, the remainder forms the second
class. The size of the ball is chosen such that both classes have equal
prior probability 0.5.
mlbench.circle(n, d=2)
mlbench.circle(n, d=2)
n |
number of patterns to create |
d |
dimension of the circle problem |
Returns an object of class "mlbench.circle"
with components
x |
input values |
classes |
factor vector of length |
# 2d example p<-mlbench.circle(300,2) plot(p) # # 3d example p<-mlbench.circle(300,3) plot(p)
# 2d example p<-mlbench.circle(300,2) plot(p) # # 3d example p<-mlbench.circle(300,3) plot(p)
The inputs of the cuboids problem are uniformly distributed on
a 3
-dimensional space within 3 cuboids and a small
cube in the middle of them.
mlbench.cuboids(n, relsize=c(2,2,2,1))
mlbench.cuboids(n, relsize=c(2,2,2,1))
n |
number of patterns to create |
relsize |
relative size of the classes (vector of length 4) |
Returns an object of class "mlbench.cuboids"
with components
x |
input values |
classes |
vector of length |
Evgenia Dimitriadou, and Andreas Weingessel
p <- mlbench.cuboids(7000) plot(p) ## Not run: library(Rggobi) g <- ggobi(p$x) g$setColors(p$class) g$setMode("2D Tour") ## End(Not run)
p <- mlbench.cuboids(7000) plot(p) ## Not run: library(Rggobi) g <- ggobi(p$x) g$setColors(p$class) g$setMode("2D Tour") ## End(Not run)
The regression problem Friedman 1 as described in Friedman (1991) and
Breiman (1996). Inputs are 10 independent variables uniformly
distributed on the interval , only 5 out of these 10 are actually
used. Outputs are created according to
the formula
where e is N(0,sd).
mlbench.friedman1(n, sd=1)
mlbench.friedman1(n, sd=1)
n |
number of patterns to create |
sd |
Standard deviation of noise |
Returns a list with components
x |
input values (independent variables) |
y |
output values (dependent variable) |
Breiman, Leo (1996) Bagging predictors. Machine Learning 24, pages 123-140.
Friedman, Jerome H. (1991) Multivariate adaptive regression splines. The Annals of Statistics 19 (1), pages 1-67.
The regression problem Friedman 2 as described in Friedman (1991) and Breiman (1996). Inputs are 4 independent variables uniformly distrtibuted over the ranges
The outputs are created according to the formula
where e is N(0,sd).
mlbench.friedman2(n, sd=125)
mlbench.friedman2(n, sd=125)
n |
number of patterns to create |
sd |
Standard deviation of noise. The default value of 125 gives a signal to noise ratio (i.e., the ratio of the standard deviations) of 3:1. Thus, the variance of the function itself (without noise) accounts for 90% of the total variance. |
Returns a list with components
x |
input values (independent variables) |
y |
output values (dependent variable) |
Breiman, Leo (1996) Bagging predictors. Machine Learning 24, pages 123-140.
Friedman, Jerome H. (1991) Multivariate adaptive regression splines. The Annals of Statistics 19 (1), pages 1-67.
The regression problem Friedman 3 as described in Friedman (1991) and Breiman (1996). Inputs are 4 independent variables uniformly distrtibuted over the ranges
The outputs are created according to the formula
where e is N(0,sd).
mlbench.friedman3(n, sd=0.1)
mlbench.friedman3(n, sd=0.1)
n |
number of patterns to create |
sd |
Standard deviation of noise. The default value of 0.1 gives a signal to noise ratio (i.e., the ratio of the standard deviations) of 3:1. Thus, the variance of the function itself (without noise) accounts for 90% of the total variance. |
Returns a list with components
x |
input values (independent variables) |
y |
output values (dependent variable) |
Breiman, Leo (1996) Bagging predictors. Machine Learning 24, pages 123-140.
Friedman, Jerome H. (1991) Multivariate adaptive regression splines. The Annals of Statistics 19 (1), pages 1-67.
The created data are d
-dimensional spherical Gaussians with standard
deviation sd
and means at the corners of a
d
-dimensional hypercube. The number of classes is .
mlbench.hypercube(n=800, d=3, sides=rep(1,d), sd=0.1) hypercube(d)
mlbench.hypercube(n=800, d=3, sides=rep(1,d), sd=0.1) hypercube(d)
n |
number of patterns to create |
d |
dimensionality of hypercube, default is 3 |
sides |
lengths of the sides of the hypercube, default is to create a unit hypercube |
sd |
standard deviation |
Returns an object of class "mlbench.hypercube"
with components
x |
input values |
classes |
factor of length |
p <- mlbench.hypercube() plot(p) library("lattice") cloud(x.3~x.1+x.2, groups=classes, data=as.data.frame(p))
p <- mlbench.hypercube() plot(p) library("lattice") cloud(x.3~x.1+x.2, groups=classes, data=as.data.frame(p))
Let where u is uniform on
[0,1]. Take x to be uniformly distributed on the d-dimensional
sphere of radius r. Let
. This data set is not a
classification problem but a regression problem where y is the
dependent variable.
mlbench.peak(n, d=20)
mlbench.peak(n, d=20)
n |
number of patterns to create |
d |
dimension of the problem |
Returns a list with components
x |
input values (independent variables) |
y |
output values (dependent variable) |
The inputs of the ringnorm problem are points from two Gaussian
distributions. Class 1 is multivariate normal with mean 0 and
covariance 4 times the identity matrix. Class 2 has unit covariance
and mean ,
.
mlbench.ringnorm(n, d=20)
mlbench.ringnorm(n, d=20)
n |
number of patterns to create |
d |
dimension of the ringnorm problem |
Returns an object of class "mlbench.ringnorm"
with components
x |
input values |
classes |
factor vector of length |
Breiman, L. (1996). Bias, variance, and arcing classifiers. Tech. Rep. 460, Statistics Department, University of California, Berkeley, CA, USA.
p<-mlbench.ringnorm(1000, d=2) plot(p)
p<-mlbench.ringnorm(1000, d=2) plot(p)
A Gaussian, square, triangle and wave in 2 dimensions.
mlbench.shapes(n=500)
mlbench.shapes(n=500)
n |
number of patterns to create |
Returns an object of class "mlbench.shapes"
with components
x |
input values |
classes |
factor of length |
p<-mlbench.shapes() plot(p)
p<-mlbench.shapes() plot(p)
The created data are d
-dimensional spherical Gaussians with standard
deviation sd
and means at the corners of a
d
-dimensional simplex. The number of classes is d+1
.
mlbench.simplex(n = 800, d = 3, sides = 1, sd = 0.1, center=TRUE) simplex(d, sides, center=TRUE)
mlbench.simplex(n = 800, d = 3, sides = 1, sd = 0.1, center=TRUE) simplex(d, sides, center=TRUE)
n |
number of patterns to create |
d |
dimensionality of simplex, default is 3 |
sides |
lengths of the sides of the simplex, default is to create a unit simplex |
sd |
standard deviation |
center |
If |
Returns an object of class "mlbench.simplex"
with components
x |
input values |
classes |
factor of length |
Manuel Eugster and Sebastian Kaiser
p <- mlbench.simplex() plot(p) library("lattice") cloud(x.3~x.1+x.2, groups=classes, data=as.data.frame(p))
p <- mlbench.simplex() plot(p) library("lattice") cloud(x.3~x.1+x.2, groups=classes, data=as.data.frame(p))
The smiley consists of 2 Gaussian eyes, a trapezoid nose and a parabula mouth (with vertical Gaussian noise).
mlbench.smiley(n=500, sd1 = 0.1, sd2 = 0.05)
mlbench.smiley(n=500, sd1 = 0.1, sd2 = 0.05)
n |
number of patterns to create |
sd1 |
standard deviation for eyes |
sd2 |
standard deviation for mouth |
Returns an object of class "mlbench.smiley"
with components
x |
input values |
classes |
factor vector of length |
p<-mlbench.smiley() plot(p)
p<-mlbench.smiley() plot(p)
The inputs of the spirals problem are points on two entangled spirals. If
sd>0
, then Gaussian noise is added to each data
point. mlbench.1spiral
creates a single spiral.
mlbench.spirals(n, cycles=1, sd=0) mlbench.1spiral(n, cycles=1, sd=0)
mlbench.spirals(n, cycles=1, sd=0) mlbench.1spiral(n, cycles=1, sd=0)
n |
number of patterns to create |
cycles |
the number of cycles each spiral makes |
sd |
standard deviation of data points around the spirals |
Returns an object of class "mlbench.spirals"
with components
x |
input values |
classes |
factor vector of length |
# 1 cycle each, no noise p<-mlbench.spirals(300) plot(p) # # 1.5 cycles each, with noise p<-mlbench.spirals(300,1.5,0.05) plot(p)
# 1 cycle each, no noise p<-mlbench.spirals(300) plot(p) # # 1.5 cycles each, with noise p<-mlbench.spirals(300,1.5,0.05) plot(p)
The inputs of the threenorm problem are points from two Gaussian
distributions with unit covariance matrix. Class 1 is drawn with
equal probability from a unit multivariate normal with mean
and from a unit multivariate normal with mean
. Class 2 is drawn from a multivariate normal
with mean at
,
.
mlbench.threenorm(n, d=20)
mlbench.threenorm(n, d=20)
n |
number of patterns to create |
d |
dimension of the threenorm problem |
Returns an object of class "mlbench.threenorm"
with components
x |
input values |
classes |
factor vector of length |
Breiman, L. (1996). Bias, variance, and arcing classifiers. Tech. Rep. 460, Statistics Department, University of California, Berkeley, CA, USA.
p<-mlbench.threenorm(1000, d=2) plot(p)
p<-mlbench.threenorm(1000, d=2) plot(p)
The inputs of the twonorm problem are points from two Gaussian
distributions with unit covariance matrix. Class 1 is multivariate
normal with mean and class 2 with mean
,
.
mlbench.twonorm(n, d=20)
mlbench.twonorm(n, d=20)
n |
number of patterns to create |
d |
dimension of the twonorm problem |
Returns an object of class "mlbench.twonorm"
with components
x |
input values |
classes |
factor vector of length |
Breiman, L. (1996). Bias, variance, and arcing classifiers. Tech. Rep. 460, Statistics Department, University of California, Berkeley, CA, USA.
p<-mlbench.twonorm(1000, d=2) plot(p)
p<-mlbench.twonorm(1000, d=2) plot(p)
The generated data set consists of 21 attributes with continuous values and a variable showing the 3 classes (33% for each of 3 classes). Each class is generated from a combination of 2 of 3 "base" waves.
mlbench.waveform(n)
mlbench.waveform(n)
n |
number of patterns to create |
Returns an object of class "mlbench.waveform"
with components
x |
input values |
classes |
factor vector of length |
The original C code for the waveform generator was taken from the UCI Repository of Machine Learning Databases (Blake & Merz 1998). The C code was modified to use R's random number generator by Friedrich Leisch, who also wrote the R interface.
Breiman, L. (1996). Bias, variance, and arcing classifiers. Tech. Rep. 460, Statistics Department, University of California, Berkeley, CA, USA.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
p <- mlbench.waveform(100) plot(p)
p <- mlbench.waveform(100) plot(p)
The inputs of the XOR problem are uniformly distributed on
the d
-dimensional cube with corners . Each pair of
opposite corners form one class, hence the total number of classes is
mlbench.xor(n, d=2)
mlbench.xor(n, d=2)
n |
number of patterns to create |
d |
dimension of the XOR problem |
Returns an object of class "mlbench.xor"
with components
x |
input values |
classes |
factor vector of length |
# 2d example p<-mlbench.xor(300,2) plot(p) # # 3d example p<-mlbench.xor(300,3) plot(p)
# 2d example p<-mlbench.xor(300,2) plot(p) # # 3d example p<-mlbench.xor(300,3) plot(p)
A data frame with 366 observations on 13 variables, each observation is one day
data("Ozone", package = "mlbench")
data("Ozone", package = "mlbench")
1 | Month: 1 = January, ..., 12 = December |
2 | Day of month |
3 | Day of week: 1 = Monday, ..., 7 = Sunday |
4 | Daily maximum one-hour-average ozone reading |
5 | 500 millibar pressure height (m) measured at Vandenberg AFB |
6 | Wind speed (mph) at Los Angeles International Airport (LAX) |
7 | Humidity (%) at LAX |
8 | Temperature (degrees F) measured at Sandburg, CA |
9 | Temperature (degrees F) measured at El Monte, CA |
10 | Inversion base height (feet) at LAX |
11 | Pressure gradient (mm Hg) from LAX to Daggett, CA |
12 | Inversion base temperature (degrees F) at LAX |
13 | Visibility (miles) measured at LAX |
The problem is to predict the daily maximum one-hour-average ozone reading (V4).
Leo Breiman, Department of Statistics, UC Berkeley. Data used in Leo Breiman and Jerome H. Friedman (1985), Estimating optimal transformations for multiple regression and correlation, JASA, 80, pp. 580-598.
data("Ozone", package = "mlbench") summary(Ozone)
data("Ozone", package = "mlbench") summary(Ozone)
A data frame with 768 observations on 9 variables.
data("PimaIndiansDiabetes", package = "mlbench") data("PimaIndiansDiabetes2", package = "mlbench")
data("PimaIndiansDiabetes", package = "mlbench") data("PimaIndiansDiabetes2", package = "mlbench")
pregnant | Number of times pregnant |
glucose | Plasma glucose concentration (glucose tolerance test) |
pressure | Diastolic blood pressure (mm Hg) |
triceps | Triceps skin fold thickness (mm) |
insulin | 2-Hour serum insulin (mu U/ml) |
mass | Body mass index |
pedigree | Diabetes pedigree function |
age | Age (years) |
diabetes | Class variable (test for diabetes) |
The data set PimaIndiansDiabetes2
contains a corrected
version of the original data set. While the UCI repository index
claims that there are no missing values, closer inspection of the data
shows several physical impossibilities, e.g., blood pressure or body
mass index of 0. In PimaIndiansDiabetes2
, all zero values of
glucose
, pressure
, triceps
, insulin
and
mass
have been set to NA
, see also Wahba et al (1995)
and Ripley (1996).
Original owners: National Institute of Diabetes and Digestive and Kidney Diseases
Donor of database: Vincent Sigillito ([email protected])
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Friedrich Leisch in the late 1990s.
The data no longer seems to be available from the UC Irvine Machine Learning Repository (now at https://archive.ics.uci.edu/).
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
Brian D. Ripley (1996), Pattern Recognition and Neural Networks, Cambridge University Press, Cambridge.
Grace Whaba, Chong Gu, Yuedong Wang, and Richard Chappell (1995), Soft Classification a.k.a. Risk Estimation via Penalized Log Likelihood and Smoothing Spline Analysis of Variance, in D. H. Wolpert (1995), The Mathematics of Generalization, 331-359, Addison-Wesley, Reading, MA.
data("PimaIndiansDiabetes", package = "mlbench") summary(PimaIndiansDiabetes) data("PimaIndiansDiabetes2", package = "mlbench") summary(PimaIndiansDiabetes2)
data("PimaIndiansDiabetes", package = "mlbench") summary(PimaIndiansDiabetes) data("PimaIndiansDiabetes2", package = "mlbench") summary(PimaIndiansDiabetes2)
Plots the data of an mlbench object using different colors for each class. If the dimension of the input space is larger that 2, a scatter plot matrix is used.
## S3 method for class 'mlbench' plot(x, xlab="", ylab="", ...)
## S3 method for class 'mlbench' plot(x, xlab="", ylab="", ...)
x |
Object of class |
xlab |
Label for x-axis. |
ylab |
Label for y-axis. |
... |
Further plotting options. |
# 6 normal classes p <- mlbench.2dnormals(500,6) plot(p) # 4-dimensiona XOR p <- mlbench.xor(500,4) plot(p)
# 6 normal classes p <- mlbench.2dnormals(500,6) plot(p) # 4-dimensiona XOR p <- mlbench.xor(500,4) plot(p)
The database consists of the multi-spectral values of pixels in 3x3 neighbourhoods in a satellite image, and the classification associated with the central pixel in each neighbourhood. The aim is to predict this classification, given the multi-spectral values.
data("Satellite", package = "mlbench")
data("Satellite", package = "mlbench")
A data frame with 36 inputs (x.1 ... x.36
) and one target
(classes
).
One frame of Landsat MSS imagery consists of four digital images of the same scene in different spectral bands. Two of these are in the visible region (corresponding approximately to green and red regions of the visible spectrum) and two are in the (near) infra-red. Each pixel is a 8-bit binary word, with 0 corresponding to black and 255 to white. The spatial resolution of a pixel is about 80m x 80m. Each image contains 2340 x 3380 such pixels.
The database is a (tiny) sub-area of a scene, consisting of 82 x 100 pixels. Each line of data corresponds to a 3x3 square neighbourhood of pixels completely contained within the 82x100 sub-area. Each line contains the pixel values in the four spectral bands (converted to ASCII) of each of the 9 pixels in the 3x3 neighbourhood and a number indicating the classification label of the central pixel.
The classes are
red soil |
cotton crop |
grey soil |
damp grey soil |
soil with vegetation stubble |
very damp grey soil |
The data is given in random order and certain lines of data have been removed so you cannot reconstruct the original image from this dataset.
In each line of data the four spectral values for the top-left pixel are given first followed by the four spectral values for the top-middle pixel and then those for the top-right pixel, and so on with the pixels read out in sequence left-to-right and top-to-bottom. Thus, the four spectral values for the central pixel are given by attributes 17,18,19 and 20. If you like you can use only these four attributes, while ignoring the others. This avoids the problem which arises when a 3x3 neighbourhood straddles a boundary.
The original Landsat data for this database was generated from data purchased from NASA by the Australian Centre for Remote Sensing, and used for research at: The Centre for Remote Sensing, University of New South Wales, Kensington, PO Box 1, NSW 2033, Australia.
The sample database was generated taking a small section (82 rows and 100 columns) from the original data. The binary values were converted to their present ASCII form by Ashwin Srinivasan. The classification for each pixel was performed on the basis of an actual site visit by Ms. Karen Hall, when working for Professor John A. Richards, at the Centre for Remote Sensing at the University of New South Wales, Australia. Conversion to 3x3 neighbourhoods and splitting into test and training sets was done by Alistair Sutherland.
The Landsat satellite data is one of the many sources of information available for a scene. The interpretation of a scene by integrating spatial data of diverse types and resolutions including multispectral and radar data, maps indicating topography, land use etc. is expected to assume significant importance with the onset of an era characterised by integrative approaches to remote sensing (for example, NASA's Earth Observing System commencing this decade). Existing statistical methods are ill-equipped for handling such diverse data types. Note that this is not true for Landsat MSS data considered in isolation (as in this sample database). This data satisfies the important requirements of being numerical and at a single resolution, and standard maximum-likelihood classification performs very well. Consequently, for this data, it should be interesting to compare the performance of other methods against the statistical approach.
Ashwin Srinivasan, Department of Statistics and Data Modeling, University of Strathclyde, Glasgow, Scotland, UK, [email protected]
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Friedrich Leisch in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Statlog Landsat Satellite data set is available from doi:10.24432/C55887.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Satellite", package = "mlbench") summary(Satellite)
data("Satellite", package = "mlbench") summary(Satellite)
This data set is from a simulation of a servo system involving a servo amplifier, a motor, a lead screw/nut, and a sliding carriage of some sort. It may have been on of the translational axes of a robot on the 9th floor of the AI lab. In any case, the output value is almost certainly a rise time, or the time required for the system to respond to a step change in a position set point. The variables that describe the data set and their values are the following:
[,1] | Motor | A,B,C,D,E |
[,2] | Screw | A,B,C,D,E |
[,3] | Pgain | 3,4,5,6 |
[,4] | Vgain | 1,2,3,4,5 |
[,5] | Class | 0.13 to 7.10 |
data("Servo", package = "mlbench")
data("Servo", package = "mlbench")
A data frame with 167 observations on 5 variables, 4 nominal and 1 as the target class.
Creator: Karl Ulrich (MIT) in 1986
Donor: Ross Quinlan
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Servo data set is available from doi:10.24432/C5Q30F.
1. Quinlan, J.R., "Learning with continuous classes", Proc. 5th Australian Joint Conference on AI (eds A. Adams and L. Sterling), Singapore: World Scientific, 1992 2. Quinlan, J.R., "Combining instance-based and model-based learning", Proc. ML'93 (ed P.E. Utgoff), San Mateo: Morgan Kaufmann 1993
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Servo", package = "mlbench") summary(Servo)
data("Servo", package = "mlbench") summary(Servo)
The shuttle dataset contains 9 attributes all of which are numerical with the first one being time. The last column is the class with the following 7 levels: Rad.Flow, Fpv.Close, Fpv.Open, High, Bypass, Bpv.Close, Bpv.Open.
Approximately 80% of the data belongs to class 1. Therefore the default accuracy is about 80%. The aim here is to obtain an accuracy of 99 - 99.9%.
data("Shuttle", package = "mlbench")
data("Shuttle", package = "mlbench")
A data frame with 58,000 observations on 9 numerical independent variables and 1 target class.
Source: Jason Catlett of Basser Department of Computer Science; University of Sydney; N.S.W.; Australia.
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Statlog Shuttle data set is available from doi:10.24432/C5WS31.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Shuttle", package = "mlbench") summary(Shuttle)
data("Shuttle", package = "mlbench") summary(Shuttle)
This is the data set used by Gorman and Sejnowski in their study of the classification of sonar signals using a neural network [1]. The task is to train a network to discriminate between sonar signals bounced off a metal cylinder and those bounced off a roughly cylindrical rock.
Each pattern is a set of 60 numbers in the range 0.0 to 1.0. Each number represents the energy within a particular frequency band, integrated over a certain period of time. The integration aperture for higher frequencies occur later in time, since these frequencies are transmitted later during the chirp.
The label associated with each record contains the letter "R" if the object is a rock and "M" if it is a mine (metal cylinder). The numbers in the labels are in increasing order of aspect angle, but they do not encode the angle directly.
data("Sonar", package = "mlbench")
data("Sonar", package = "mlbench")
A data frame with 208 observations on 61 variables, all numerical and one (the Class) nominal.
Contribution: Terry Sejnowski, Salk Institute and University of California, San Deigo.
Development: R. Paul Gorman, Allied-Signal Aerospace Technology Center.
Maintainer: Scott E. Fahlman
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Connectionist Bench Sonar, Mines vs. Rocks data set is available from doi:10.24432/C5T01Q.
Gorman, R. P., and Sejnowski, T. J. (1988). "Analysis of Hidden Units in a Layered Network Trained to Classify Sonar Targets" in Neural Networks, Vol. 1, pp. 75-89.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Sonar", package = "mlbench") summary(Sonar)
data("Sonar", package = "mlbench") summary(Sonar)
There are 19 classes, only the first 15 of which have been used in prior work. The folklore seems to be that the last four classes are unjustified by the data since they have so few examples. There are 35 categorical attributes, some nominal and some ordered. The value “dna” means does not apply. The values for attributes are encoded numerically, with the first value encoded as “0,” the second as “1,” and so forth.
data("Soybean", package = "mlbench")
data("Soybean", package = "mlbench")
A data frame with 683 observations on 36 variables. There are 35 categorical attributes, all numerical and a nominal denoting the class.
[,1] | Class | the 19 classes |
[,2] | date | apr(0),may(1),june(2),july(3),aug(4),sept(5),oct(6). |
[,3] | plant.stand | normal(0),lt-normal(1). |
[,4] | precip | lt-norm(0),norm(1),gt-norm(2). |
[,5] | temp | lt-norm(0),norm(1),gt-norm(2). |
[,6] | hail | yes(0),no(1). |
[,7] | crop.hist | dif-lst-yr(0),s-l-y(1),s-l-2-y(2), s-l-7-y(3). |
[,8] | area.dam | scatter(0),low-area(1),upper-ar(2),whole-field(3). |
[,9] | sever | minor(0),pot-severe(1),severe(2). |
[,10] | seed.tmt | none(0),fungicide(1),other(2). |
[,11] | germ | 90-100%(0),80-89%(1),lt-80%(2). |
[,12] | plant.growth | norm(0),abnorm(1). |
[,13] | leaves | norm(0),abnorm(1). |
[,14] | leaf.halo | absent(0),yellow-halos(1),no-yellow-halos(2). |
[,15] | leaf.marg | w-s-marg(0),no-w-s-marg(1),dna(2). |
[,16] | leaf.size | lt-1/8(0),gt-1/8(1),dna(2). |
[,17] | leaf.shread | absent(0),present(1). |
[,18] | leaf.malf | absent(0),present(1). |
[,19] | leaf.mild | absent(0),upper-surf(1),lower-surf(2). |
[,20] | stem | norm(0),abnorm(1). |
[,21] | lodging | yes(0),no(1). |
[,22] | stem.cankers | absent(0),below-soil(1),above-s(2),ab-sec-nde(3). |
[,23] | canker.lesion | dna(0),brown(1),dk-brown-blk(2),tan(3). |
[,24] | fruiting.bodies | absent(0),present(1). |
[,25] | ext.decay | absent(0),firm-and-dry(1),watery(2). |
[,26] | mycelium | absent(0),present(1). |
[,27] | int.discolor | none(0),brown(1),black(2). |
[,28] | sclerotia | absent(0),present(1). |
[,29] | fruit.pods | norm(0),diseased(1),few-present(2),dna(3). |
[,30] | fruit.spots | absent(0),col(1),br-w/blk-speck(2),distort(3),dna(4). |
[,31] | seed | norm(0),abnorm(1). |
[,32] | mold.growth | absent(0),present(1). |
[,33] | seed.discolor | absent(0),present(1). |
[,34] | seed.size | norm(0),lt-norm(1). |
[,35] | shriveling | absent(0),present(1). |
[,36] | roots | norm(0),rotted(1),galls-cysts(2). |
Source: R.S. Michalski and R.L. Chilausky "Learning by Being Told and Learning from Examples: An Experimental Comparison of the Two Methods of Knowledge Acquisition in the Context of Developing an Expert System for Soybean Disease Diagnosis", International Journal of Policy Analysis and Information Systems, Vol. 4, No. 2, 1980.
Donor: Ming Tan & Jeff Schlimmer (Jeff.Schlimmer%cs.cmu.edu)
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Soybean (Large) data set is available from doi:10.24432/C5JG6Z.
Tan, M., & Eshelman, L. (1988). Using weighted networks to represent classification knowledge in noisy domains. Proceedings of the Fifth International Conference on Machine Learning (pp. 121-134). Ann Arbor, Michigan: Morgan Kaufmann. – IWN recorded a 97.1% classification accuracy – 290 training and 340 test instances
Fisher,D.H. & Schlimmer,J.C. (1988). Concept Simplification and Predictive Accuracy. Proceedings of the Fifth International Conference on Machine Learning (pp. 22-28). Ann Arbor, Michigan: Morgan Kaufmann. – Notes why this database is highly predictable
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Soybean", package = "mlbench") summary(Soybean)
data("Soybean", package = "mlbench") summary(Soybean)
The purpose is to classify a given silhouette as one of four types of vehicle, using a set of features extracted from the silhouette. The vehicle may be viewed from one of many different angles. The features were extracted from the silhouettes by the HIPS (Hierarchical Image Processing System) extension BINATTS, which extracts a combination of scale independent features utilising both classical moments based measures such as scaled variance, skewness and kurtosis about the major/minor axes and heuristic measures such as hollows, circularity, rectangularity and compactness.
Four "Corgie" model vehicles were used for the experiment: a double decker bus, Cheverolet van, Saab 9000 and an Opel Manta 400. This particular combination of vehicles was chosen with the expectation that the bus, van and either one of the cars would be readily distinguishable, but it would be more difficult to distinguish between the cars.
data("Vehicle", package = "mlbench")
data("Vehicle", package = "mlbench")
A data frame with 846 observations on 19 variables, all numerical and one nominal defining the class of the objects.
[,1] | Comp | Compactness |
[,2] | Circ | Circularity |
[,3] | D.Circ | Distance Circularity |
[,4] | Rad.Ra | Radius ratio |
[,5] | Pr.Axis.Ra | pr.axis aspect ratio |
[,6] | Max.L.Ra | max.length aspect ratio |
[,7] | Scat.Ra | scatter ratio |
[,8] | Elong | elongatedness |
[,9] | Pr.Axis.Rect | pr.axis rectangularity |
[,10] | Max.L.Rect | max.length rectangularity |
[,11] | Sc.Var.Maxis | scaled variance along major axis |
[,12] | Sc.Var.maxis | scaled variance along minor axis |
[,13] | Ra.Gyr | scaled radius of gyration |
[,14] | Skew.Maxis | skewness about major axis |
[,15] | Skew.maxis | skewness about minor axis |
[,16] | Kurt.maxis | kurtosis about minor axis |
[,17] | Kurt.Maxis | kurtosis about major axis |
[,18] | Holl.Ra | hollows ratio |
[,19] | Class | type |
Creator: Drs.Pete Mowforth and Barry Shepherd, Turing Institute, Glasgow, Scotland.
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Statlog Vehicle Silhouettes data set is available from doi:10.24432/C5HG6N.
Turing Institute Research Memorandum TIRM-87-018 "Vehicle Recognition Using Rule Based Methods" by Siebert,JP (March 1987)
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Vehicle", package = "mlbench") summary(Vehicle)
data("Vehicle", package = "mlbench") summary(Vehicle)
Speaker independent recognition of the eleven steady state vowels of British English using a specified training set of lpc derived log area ratios. The vowels are indexed by integers 0-10. For each utterance, there are ten floating-point input values, with array indices 0-9. The vowels are the following: hid, hId, hEd, hAd, hYd, had, hOd, hod, hUd, hud, hed.
data("Vowel", package = "mlbench")
data("Vowel", package = "mlbench")
A data frame with 990 observations on 10 independent variables, one nominal and the other numerical, and 1 as the target class.
Creator: Tony Robinson
Maintainer: Scott E. Fahlman, CMU
These data have been taken from the UCI Repository Of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Connectionist Bench Vowel Recognition Deterding Data data set is available from doi:10.24432/C58P4S.
D. H. Deterding, 1989, University of Cambridge, "Speaker Normalisation for Automatic Speech Recognition", submitted for PhD.
M. Niranjan and F. Fallside, 1988, Cambridge University Engineering Department, "Neural Networks and Radial Basis Functions in Classifying Static Speech Patterns", CUED/F-INFENG/TR.22.
Steve Renals and Richard Rohwer, "Phoneme Classification Experiments Using Radial Basis Functions", Submitted to the International Joint Conference on Neural Networks, Washington, 1989.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Vowel", package = "mlbench") summary(Vowel)
data("Vowel", package = "mlbench") summary(Vowel)
A simple dataset containing 17 (mostly logical) variables on 101 animals.
data("Zoo", package = "mlbench")
data("Zoo", package = "mlbench")
A data frame with 17 columns: hair, feathers, eggs, milk, airborne, aquatic, predator, toothed, backbone, breathes, venomous, fins, legs, tail, domestic, catsize, type.
Most variables are logical and indicate whether the corresponding
animal has the corresponsing characteristic or not. The only 2
exceptions are: legs
takes
values 0, 2, 4, 5, 6, and 8. type
is a grouping of the animals
into 7 groups, see the example section for the detailed list.
Ask the original donor of the data why girl is an animal.
The original data have been donated by Richard S. Forsyth to the UCI Repository of Machine Learning Databases (Blake & Merz 1998) and were converted to R format by Friedrich Leisch and Evgenia Dimitriadou in the late 1990s.
The current version of the UC Irvine Machine Learning Repository Zoo data set is available from doi:10.24432/C5R59V.
Blake, C.L. & Merz, C.J. (1998). UCI Repository of Machine Learning Databases. Irvine, CA: University of California, Irvine, Department of Information and Computer Science. Formerly available from ‘http://www.ics.uci.edu/~mlearn/MLRepository.html’.
data("Zoo", package = "mlbench") summary(Zoo) ## see the annimals grouped by type split(rownames(Zoo), Zoo$type) ## which animals have fins? rownames(Zoo)[Zoo$fins]
data("Zoo", package = "mlbench") summary(Zoo) ## see the annimals grouped by type split(rownames(Zoo), Zoo$type) ## which animals have fins? rownames(Zoo)[Zoo$fins]