mirror of
https://asciireactor.com/otho/cs-5821.git
synced 2024-11-24 04:55:09 +00:00
182 lines
8.4 KiB
Plaintext
Executable File
182 lines
8.4 KiB
Plaintext
Executable File
|
||
|
||
1. Describe the null hypotheses to which the p-values given in Table
|
||
3.4 correspond. Explain what conclusions you can draw based on
|
||
these p-values. Your explanation should be phrased in terms of
|
||
sales , TV , radio , and newspaper , rather than in terms of the
|
||
coefficients of the linear model.
|
||
|
||
|
||
P-values that are very small indicate that the model for that
|
||
predictor is likely to account for a significant amount of the
|
||
association between the predictor and the response. If that is
|
||
true, then, we reject the null hypothesis, and conclude that a
|
||
relationship exists between the predictor and the response. The
|
||
p-values computed from the response of sales to marketing budget
|
||
for each marketing paradigm indicate will give us insight into
|
||
which of these predictors have a strong relationship with sales
|
||
of this product.
|
||
|
||
TV marketing and radio marketing both have a strong relationship
|
||
to sales, according to their linear regression p-values, but
|
||
newspaper advertising does not appear to be effective, given
|
||
that the linear model does not account for much of the variation
|
||
in sales across that domain. We can conclude that cutting back
|
||
on newspaper advertising will likely have little effect on the
|
||
sales of the product, and that increasing TV and radio
|
||
advertising budgets likely will have an effect. Furthermore, we
|
||
can see that radio advertising spending has a stronger
|
||
relationship with sales, as the best-fit slope is significantly
|
||
more positive than the best fit for TV advertising spending, so
|
||
increasing the radio advertising budget will likely be more
|
||
effective.
|
||
|
||
|
||
|
||
3. Suppose we have a data set with five predictors, X₁ = GPA, X₂ =
|
||
IQ, X₃ = Gender (1 for Female and 0 for Male), X₄ = Interaction
|
||
between GPA and IQ, and X₅ = Interaction between GPA and Gender.
|
||
The response is starting salary after graduation (in thousands of
|
||
dollars). Suppose we use least squares to fit the model, and get
|
||
β₀ = 50, β₁ = 20, β₂ = 0.07, β₃ = 35, β₄ = 0.01, β₅ = −10.
|
||
|
||
This is the model: ŷ = 50 + 20 X₁ + 0.07 X₂ + 35 X₃ + 0.01 X₄ +
|
||
-10 X₅
|
||
|
||
For fixed IQ and GPA, we can infer that the starting salary
|
||
for a female sharing an IQ and GPA with her male counterpart
|
||
will make (35*1 - 10*(GPA*1)) more starting salary units
|
||
than her male counterpart. This means that at very low
|
||
GPAs(maybe this includes people who didn't attend school?),
|
||
males have a lower starting wage, and as GPA grows, males
|
||
make a larger starting salary from that point, overtaking
|
||
females at GPA=3.5. Therefore,
|
||
|
||
(a) Which answer is correct, and why? → iii. For a fixed value
|
||
of IQ and GPA, males earn more on average than females
|
||
provided that the GPA is high enough.
|
||
|
||
This one is correct.
|
||
|
||
(b) Predict the salary of a female with IQ of 110 and a GPA of
|
||
4.0.
|
||
|
||
ŷ = 50 + 20*4.0 + 0.07*110 + 35*1 + 0.01*(4.0*110) - 10*(4.0*1)
|
||
|
||
→ ŷ = 137.1 salary units
|
||
|
||
(c) True or false: Since the coefficient for the GPA/IQ
|
||
interaction term is very small, there is very little evidence of
|
||
an interaction effect. Justify your answer.
|
||
|
||
False. There is still a noticeable effect because the
|
||
coefficient for IQ's effect alone is only 7 times greater
|
||
than the coefficient of the interaction term. So, this term
|
||
holds significant weight compared to the overall
|
||
response of the model to IQ.
|
||
|
||
|
||
4. I collect a set of data (n = 100 observations) containing a
|
||
single predictor and a quantitative response. I then fit a linear
|
||
regression model to the data, as well as a separate cubic
|
||
regression, i.e. Y = β₀ + β₁ X + β₂ X² + β₃ X³ + ε.
|
||
|
||
(a) Suppose that the true relationship between X and Y is
|
||
linear, i.e. Y = β₀ + β₁ X + ε. Consider the training residual
|
||
sum of squares (RSS) for the linear regression, and also the
|
||
training RSS for the cubic regression. Would we expect one to be
|
||
lower than the other, would we expect them to be the same, or is
|
||
there not enough information to tell? Justify your answer.
|
||
|
||
For the training data, the cubic regression might return a
|
||
better RSS than the linear regression, but this would only
|
||
be because the cubic is fitting points that are varied
|
||
according to the ε random error. It also may not, depending
|
||
on how that random error expressed itself in this case.
|
||
|
||
(b) Answer (a) using test rather than training RSS.
|
||
|
||
For the test error, the RSS will almost certainly be greater
|
||
for the cubic model than the linear model, because the
|
||
random error ε will likely express itself in a way that is
|
||
inconsistent with the noise that the cubic model adopted
|
||
during its training. The linear model will be more likely to
|
||
have a lower RSS the more test data is used against the
|
||
models.
|
||
|
||
(c) Suppose that the true relationship between X and Y is not
|
||
linear, but we don’t know how far it is from linear. Consider
|
||
the training RSS for the linear regression, and also the
|
||
training RSS for the cubic regression. Would we expect one to be
|
||
lower than the other, would we expect them to be the same, or is
|
||
there not enough information to tell? Justify your answer. (d)
|
||
Answer (c) using test rather than training RSS.
|
||
|
||
The cubic model will pick up more information because of its
|
||
additional degrees of freedom. If the true relationship is
|
||
more complex than linear, then the cubic model will likely
|
||
have a lower RSS over the linear model. If the model is less
|
||
complex than linear (E.G. perhaps it is just a constant
|
||
scalar relationship) then the linear model will still be
|
||
more likely to have a smaller RSS, because the cubic will
|
||
again pick up information from the ε noise that is not
|
||
inherent in the real relationship.
|
||
|
||
|
||
|
||
|
||
|
||
8. This question involves the use of simple linear regression on the Auto
|
||
data set.
|
||
|
||
(a) Use the lm() function to perform a simple linear regression
|
||
with mpg as the response and horsepower as the predictor. Use
|
||
the summary() function to print the results. Comment on the
|
||
output. For example:
|
||
|
||
There is definitely a correlation between horsepower and
|
||
mpg. The RSE is ~4.9, which is not insignificant and does
|
||
indicate that the response may not be truly linear, but it
|
||
is small enough relative to the mpg magnitude that it's
|
||
clear a relationship exists. The R² statistics corroborates
|
||
this by indicating (it has a small value at ~0.6) that a
|
||
large proportion of the mpg variability is explained by the
|
||
model. mpg has a negative correlation with horsepower,
|
||
indicated by the negative coefficient on the horsepower
|
||
factor.
|
||
|
||
|
||
For example, for a vehicle with 98 horsepower, one can
|
||
expect with 95% confidence that the mpg will be within 23.97
|
||
and 24.96, if the vehicles follow our model. However, after
|
||
incorporating the irreducible error, the prediction turns
|
||
out to be much less precise, with a 95% prediction interval
|
||
spanning 14.8 to 34.1. Some of this variability may also be
|
||
reduced by using a quadratic model, from visual inspection
|
||
of the plot.
|
||
|
||
(b) Plot the response and the predictor. Use the abline() function
|
||
to display the least squares regression line.
|
||
|
||
Attached.
|
||
|
||
(c) Use the plot() function to produce diagnostic plots of the least
|
||
squares regression fit. Comment on any problems you see with
|
||
the fit.
|
||
|
||
Attached. From these four plots it's clear there is a lot of
|
||
variability that remains unexplained by the linear model.
|
||
The standardized residuals plotted against the fitted values
|
||
shows clearly that the variability is strong, with values
|
||
consistenly lying outside 1 standardized residual unit, but
|
||
still within a tight range that doesn't extend past 3, which
|
||
is often considered an approximate threshold to indicate
|
||
values that aren't explained well by the model. There are
|
||
many points with high leverage, and these values have less
|
||
residual by default, of course, and in both of these graphs
|
||
we see a few points (323, 330) that are rearing their ugly
|
||
heads. These seems to be the bit of "uptick" toward the
|
||
higher end of the horsepower scale that would probably be
|
||
picked up by a quadratic fit.
|
||
|