Preparation
Goals
Explanations of overfitting in machine learning tend to be
frustratingly vague. We for instance hear “An overfitted model predicts
poorly on new examples,” which is a definition, not an explanation. Or
we hear that overfitting results from “fitting the training data too
well” or that we are “fitting the noise,” again rather unsatisfying.
Somewhat better–but only somewhat–are the explanations based on the
famous Bias-Variance Tradeoff. The latter is the mathematical
relationship,
mean squared prediction error (MSPE) = squared bias + variance
The narrative is then:
Bias and variance are at odds with each other. The lower the bias,
the more the variance. As we move through a sequence of models of
increasing complexity, eventually the reduction in bias is overwhlemed
by the increase in variance, a net loss. Somewhere in that sequence of
models is a best one, i.e. one with minimum MSPE.
OK, but the bias and variance of WHAT? Our treatment here is based on
that notion, with emphasis on what it is that we are really
talking about in discussing bias and variance.
Required Background
Only very basic statistical concepts are needed, plus patience
(document is a bit long).
Setting and Notation
Let Y denote our outcome variable, and X represent the vector of our
predictors/features. We are predicting Y from X. For instance, Y might
be human weight, with X being (height, age). We include binary
classification problems, with Y = 1 or 0, coding the “yes” class and
“no” class.
In multiclass settings with c classes, Y is a vector of c 1s and 0s,
with only one component being equal to 1 at a time.
We denote by n and p the number of rows and columns in our training
data.
Overfitting is often described as arising when we go too far towards
the low-bias end of the Bias-Variance Tradeoff. Yes, but what does that
really mean in the prediction context?
The “True” Relation between Y and X
The regression function of Y on X, ρ(t), is defined to be
the mean Y for the given X values t. In the weight/height/age example,
ρ(68.2,32.9) is the mean weight of all people of height 68.2 and age
32.9.
Though some books use the term “regression” to mean a linear model, the
actual definition is unrestricted; it applies just as much to, say,
random forests as to linear models.
The ρ function is the best (i.e. minimum MSPE) predictor of weight
based on height and age, the ideal. Note the phrase “based on,” though.
If we had a third predictor variable/feature available, say waist size,
there would be another ρ function for that 3-predictor setting, possibly
better than the 2-predictor one.
Note too that the ρ function is a population entity, which we
estimate from our sample data. Denote the estimated ρ(t) by r(t). Say we
are studying diabetic people. ρ(t) gives us the relation of weight
vs. height and age in the entire population of diabetics; if our study
involves 100 patients, that is considered a sample from that population,
and our estimate r(t) is based on that sample. Note: “Sample” will mean
our entire dataset; we will say, “A sample of 100 people,” as in
statistics courses, not “We have 100 samples,” the machine learning
term.
The term population is used in the statistics community.
Those who come to ML from the computer science world tend to use terms
like probabilistic generating process. Either way, it is
crucial to keep in mind that we treat our data as randomly generated. If
our data consists of 100 diabetes patients, we treat them as being
randomly drawn from the conceptual population of all diabetics.
For those with some background in probability theory: We are modeling
the conditional distribution of Y given X, so we can regard the X
columns in our dataset as fixed but the Y column as random.
In a binary classification problem, the regression function reduces
to the probability of class 1, since the mean of a 0,1 variable is the
probability of a 1.
Example: estimating the ρ function via a linear model
Say we use a linear model to predict weight from height, i.e. our
model for ρ(height) is
ρ(weight) = mean weight = β0 + β1 height
This is called a “parametric” model, in that it expresses ρ(t) in
terms of some parameters, in this case the βi.
Our sample-based estimate of the function ρ(t) is a function r(t),
with
r(height) = mean weight = b0 + b1 height
The bi, say computed using the familiar least-squares
method, are the sample estimates of the βi.
Example: estimating the ρ function via a k-NN model
It will be convenient here to use as our nonparametric method the
classic k-Nearest Neighbors approach. To estimate ρ(t), we find the k
closest rows in our dataset to t, and average the Y values of those data
points. Of course, k is a hyperparameter, chosen by the analyst.
Other machine learning methods, such as random forests, SVM and
neural nets, have similar problems to what we discuss below, so k-NN
will be our main nonparametric example.
Bias and Variance of WHAT
It’s very easy to drop terms like “Bias-Variance Tradeoff” into a
discussion, but what does it really mean? We’ll explain here, mainly
with linear model examples, but bring in k-NN later.
Bias in prediction
Though the reader may have seen the concept of statistical bias in
terms of simple estimators, our context here is different. Let’s take as
our example prediction of house prices, say using the predictor
variables Square Feet and Location. Prediction methods are often used in
real estate contexts, such as in assessing market value.
Generally, the larger a home is, the greater its value. But the
same-sized home will have a higher value in some places than others. In
other words,
If we predict the price of a house based only on size and decline to
use (or do not know) its location, we induce a bias. If say the house is
in an expensive neighborhood, our prediction based only on Square Feet
will likely be too low.
We can write this as, for a specific case,
average(actual value -
predicted value from size alone,
given size=2125, location='Seaside') > 0
That average discrepancy is called the bias. Here the bias
will be positive for the houses in expensive neighborhoods, and negative
for those in inexpensive areas. Note that, negative or positive, the
impact on MSPE is the same, since the latter involves squared
bias.
Note that “average” here means the mean over all possible houses of
the given size and place. In some cases, we may not underpredict, but on
average we will do so.
Variance in prediction
This refers to sampling variance, which measures the degree of
instability of one’s estimated r(t) from one training dataset to
another. E.g. in the above linear model, there will the variation of the
bi from one sample to another, thus causing variation in r(t)
among samples.
The key point is:
The more complex our model, the higher the variance of its fit to the
data.
Let’s illustrate this with the pef dataset, included
with the qeML package:
> data(pef)
> head(pef)
age educ occ sex wageinc wkswrkd
1 50.30082 zzzOther 102 2 75000 52
2 41.10139 zzzOther 101 1 12300 20
3 24.67374 zzzOther 102 2 15400 52
4 50.19951 zzzOther 100 1 0 52
5 51.18112 zzzOther 100 2 160 1
6 57.70413 zzzOther 100 1 0 0
Let’s start with a very simple model, predicting wage income from
number of weeks worked:
> zWeeks <- lm(wageinc ~ wkswrkd,pef))
> coef(zWeeks)
(Intercept) wkswrkd
-2315.625 1387.481
So, our predicted income of someone who works 45 weeks would be
-2315.625 + 1387.481 x 45
But again, the predicted value varies from one training dataset to
another. One can show that its estimated variance is as follows:
> c(1,45) %*% vcov(zWeeks) %*% c(1,45)
[,1]
[1,] 98016.11
Now let’s fit a somewhat more complex model, including age:
zWeeksAge <- lm(wageinc ~ wkswrkd+age,pef)
> coef(zWeeksAge)
(Intercept) wkswrkd age
-22097.8721 1388.9398 498.5047
Say we predict the income of a worker who worked 45 weeks and is age
26. The estimated variance of our prediction is now
> c(1,45,26) %*% vcov(zWeeksAge) %*% c(1,45,26)
[,1]
[1,] 237114.2
So, adding just one more feature led to a dramatic increase in
variance. Again, note that this reflects the sampling variation in the
bi from one dataset to another.
This may be difficult to accept for some, who may ask, “Why does
sampling variation matter? We have only one sample.” The point is that
if sampling variance is low, say, then most samples produce
bi that are near the true βi, giving us confidence
that our particular sample is of that nature. It’s just like playing a
game in a casino; we may play the game just once, but we will still want
to know the probability of winning–i.e. the proportion of wins among
many plays–before deciding to gamble.
Roughly speaking:
For a fixed number of rows in our data, a prediction using more
columns will have smaller bias but larger variance. This is the
Bias-Variance Tradeoff.
What about k-NN?
Opposing effects on bias and variance definitely arise here (and in
any other ML method). The above analysis involving the number of
predictors has a similar effect here, but let’s look at the effect of k
instead:
Bias: Say Y = weight, X = height, and k is
rather large. Suppose we need to predict the weight of a very tall
person. A problem arises in that most of the training data points in the
k-neighborhood of this tall person will be shorter than him/her–thus
lighter. So, when we average the weights of the neighborhs to get our
predicted weight for the new person, we are likely to be too low, a
positive bias. A negative basis can occur analogously. Smaller k values
are thus desirable.
Variance: As we know from statistics, the
variance of a sample mean is the population variance divided by the
number of terms being averaged. In other words, variance will be
proportional to 1/k. Larger k values are thus desirable.
So, again, we see bias and variance at odds with each other.
Where Is the “Goldilocks” Level of Complexity?
For any dataset and predictive algorithm, there is some optimal level
of complexity–optimal feature set, optimal k etc.–which achieves minimum
MSPE. Let’s take a look. First, a very important principle.
Other measures than MSPE might be used. An analog of the neat
bias2+variance formulation would not exist, but the same
general principles would hold.
Dependency on n
The larger n is, the higher level of complexity is optimal
A U-shaped curve
Mean squared error is the sum of a decreasing quantity, squared bias,
and an increasing quantity, variance. This typically produces a U-shape,
but there is no inherent reason that it must come out this way. A
double-U can occur (see below), or for that matter, multiple-U.
Cross-validation
Again, MSPE is a population quantity, but we can estimate it via
cross-validation. For instance, for each value of k in a range, we can
fit k-NN on our training data and the estimate the corresponding MSPE
value by predicting our test set.
Overfitting with Impunity–and Even Gain?
Research in machine learning has, among other things, produced two
major mysteries, which we discuss now.
Baffling behavior–drastic overfitting
In many ML applications, especially those in which neural networks
are used, there may be far more hyperparameters than data points. Yet
excellent prediction accuracy on new data has often been reported in
spite of such extreme overfitting.
How could it be possible?
Much speculation has been made as to why this phenomenon can occur.
My own speculation is as follows.
These phenomena occur in classification problems in which
there is a very low error rate, 1 or 2% or even under
1%.
In other words, the classes are widely separated, i.e. there is a
large margin in the SVM sense. Thus a large amount of variance
can be tolerated in the fitted model, and there is room for myriad
high-complexity functions that separate the classes perfectly or nearly
so, even for test data.
Thus there are myriad fits that will achieve 0 training error,
and the iterative solution method used by ML methods such as neural
networks is often of a nature that the minimum norm solution is
arrived at. In other words, of the ocean of possible 0-training error
solutions, this one is smallest, which intuitively suggests that it is
of small variance. This may produce very good test error.
Here is an example, using a famous image recognition dataset
(generated by code available here:
UMAP plot
There are 10 classes, each shown in a different color. Here the UMAP
method (think of it as a nonlinear PCA) was applied for dimension
reduction, shown to dimension 2 here. There are some isolated points
here and there, but almost all the data is separated into 10 “islands.”
Between any two islands, there are tons of high-dimensonal curves, say
high-degree polynomials, that one can fit to separate them. So we see
that overfitting is just not an issue, even with high-degree
polynomials.
Baffling behavior–“double descent”
The phenomenon of double descent is sometimes observed, in
which the familiar graph of test set accuracy vs. model complexity
consists of two U shapes rather than one. The most intriguing
cases are those in which the first U ends at a point where the model
fully interpolates the training data, i.e. 0 training error–and yet
even further complexity actually reduces test set error, with
the minimum of the second U being smaller than the first..
How could it be possible?
The argument explaining double descent generally made by researchers
in this field is actually similar to the argument I made for the
“overfitting with impunity” analysis above, regarding minimum-norm
estimators.
By the way, the function penroseLM() in the regtools
package (on top of which qeML is built) does find the minimum-norm b in
the case of overfitting a linear model. As mentioned, this has been
observed empirically, and some theoretical work has proved it under
certain circumstances.