FBA1018 - Introductory Econometrics Autumn 2024 PDF

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This document provides an introduction to econometrics, focusing on OLS, regression techniques, and related concepts. It appears to be lecture notes.

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FBA1018 – Introductory
Econometrics

Autumn 2024
Regression (1/3)
Agenda
The basics of regression (Week 4)

Getting fancier with regression (Week 5)

Issues with standard errors (Week 6)

Additional regression concerns (Week 6)
The Basics of Regression
Error terms
Regression assumptions and sampling variation
Hypothesis testing in OLS
Regression tables and model-fit statistics
Subscripts in regression equations
Turning a causal diagram into a regression
Coding examples
 Recall from Week 2 – Describing Relationships

We can use the values of one variable () to predict the values of another (). We call this
explaining using.

While there are many ways to do this, one is to fit a line or shape that describes the
relationship. For example,.

Estimating this line using ordinary least squares (standard, linear regression) will select the line
that minimizes the sum of squared residuals, which is what you get if you take the prediction
errors from the line, square them, and add them up. Linear regression, for example, gives us
the best linear approximation of the relationship between and. The quality of that
approximation depends in part on how linear the true model is.
 Recall from Week 2 – Describing Relationships (Cont.)

Pro: Uses variation efficiently
Pro: A shape is easy to explain

Con: We lose some interesting variation
Con: If we pick a shape that’s wrong for the relationship, our results will be bad
 Recall from Week 2 – Describing Relationships (Cont.)

We can interpret the coefficient that multiples a variable () as a slope. So, a one-unit increase in
is associated with a increase in.

With only one predictor, the estimate of the slope is the covariance of and divided by the
variance of. With more than one, the result is sort of similar, but also accounts for the way the
different predictors are correlated.

If we plug an observation’s predictor variables into an estimated regression, we get a prediction.
This is the part of that is explained by the regression. The difference between and is the
unexplained part, which is also called the “residual.”
 Recall from Week 2 – Describing Relationships (Cont.)

If we add another variable to the regression equation, such as , then the the coefficient on each
variable will be estimated using the variation that remains after removing what is explained by
the other variable. So our estimate of would not give the best-fit line between and , but rather
between the part of not explained by and the part of not explained by. This “controls for.”

If we think the relationship between and isn’t well-explained by a straight line, we can use a
curvy one instead. OLS can handle things like that are “linear in parameters” (notice that the
parameters and are just plain multiplied by a variable, then added up), or we can use nonlinear
regression like probit, logit, or a zillion other options.
 What we’re going to add

The error term

Sampling variation

The statistical properties of OLS

Interpreting regression results

Interpreting coefficients on binary and transformed variables
 Error Terms

Fitting a straight line is not sufficient. It will rarely predict any observation perfectly, much
less all of the observations. There’s going to be a difference between the line that we fit and the
observation we get.

We can add this difference to our actual equation as an “error term”.

That difference goes by two names: the residual, which we’ve talked about, is the difference
between the prediction we make with our fitted line and the actual value, and the error is the
difference between the true best fit-line and the actual value. Why the distinction? Well…
sampling variation.
Error Terms

The Difference Between the Residual and the
Error
 Error Terms

That includes both stuff we can see and stuff we can’t. So, for example, if the true model is given
by the Figure, and we are using the OLS model , then is made up of some combination of , ,
and. We know that since we can determine from the graph that , , and all cause , but aren’t in
the model.
 Regression Assumptions & Sampling Variation

Exogeneity assumption: If we want to say that our OLS estimates of will, on average, give us
the population , then it must be the case that is uncorrelated with.

If we do have that endogeneity problem, then on average our estimate of won’t give us the
population value. When that happens - when our estimate on average gives us the wrong
answer, we call that a bias in our estimate. In particular, this form of bias, where we are biased
because a variable correlated with is in the error term, is known as omitted variable bias, since
it happens because we omitted an important variable from the regression equation.
 Regression Assumptions & Sampling Variation

Regression coefficients also follow a normal distribution, and we know what the mean and
standard deviation of that normal distribution is. Or, at least we do if we make a few more
assumptions about the error term.

In a regression model with one predictor, like , an OLS estimate of the true-model
population follows a normal distribution with a mean of and a standard deviation of ,
where is the number of observations in the data, is the standard deviation of the error term ,
and is the variance of.

The standard deviation of a sampling distribution is often referred to as a standard error.
 Hypothesis Testing in OLS

Step 1: We pick a theoretical distribution, specifically a normal distribution centred around a
particular value of

Step 2: Estimate using OLS in our observed data, getting

Step 3: Use that theoretical distribution to see how unlikely it would be to get if indeed the true
population value is what we picked in the first step

Step 4: If it’s super unlikely, that initial value we picked is probably wrong!
 Hypothesis Testing in OLS – Example

Assume the true model is , where is normally distributed with mean 0 and variance 1. We
generated 200 random observations from the true model.

Pretend that we don’t know the truth is =0.2, we estimated the OLS model using the regression

The first estimate we get is 0.142. We can use the formula from the last section to also calculate
that the standard error of is. So the theoretical distribution we’re looking at is a normal
distribution with mean 0 and standard deviation 0.077.
 Hypothesis Testing in OLS – Example

Under that distribution, the 0.142 estimate we got is at the 96.7th percentile of the theoretical distribution, as
shown in the Figure below. That means that something as far from 0 as 0.142 is (or farther) happens (100 –
96.7) x 2 = 3.3 x 2 = 6.6% of the time.

If we started with , then we would not reject the null hypothesis, since 6.6% is higher than 5%, even though
we happen to know for a fact that the null is quite wrong.
 Hypothesis Testing in OLS – Key points

An estimate not being statistically significant doesn’t mean it’s wrong. It just means it’s not statistically
significant.

Never, ever, ever, ever, ever, ever, ever give in to the thought “oh no, my results aren’t significant, I’d better
change the analysis to get something significant.” Bad. I’m pretty sure professors always say to never do this,
but students somehow remember the opposite.

A lot of stuff goes into significance besides just “is the true relationship nonzero or not.” - sampling variation,
of course, and also the sample size, the way you’re doing your analysis, your choice of , and so on. A
significance test isn’t the last word on a result.

Statistical significance only provides information about whether a particular null value is unlikely. It doesn’t
say anything about whether the effect you’ve found matters. In other words, “statistical significance” isn’t the
same thing as “significant.” A result showing that your treatment improves IQ by.000000001 points is not
a meaningful effect, whether it’s statistically significant or not.
 Regression Tables and Model-Fit Statistics

We’re going to run some regressions using data on restaurant and food inspections. We might be
curious whether chain restaurants get better health inspections than restaurants with fewer (or
only one) location.

Summary Statistics for Restaurant Inspection Data
 Regression Tables and Model-Fit Statistics

We run 2 regressions. The first just regresses inspection score on the number of locations the
chain has:

The second adds year of inspection as a control:
Regression Tables and Model-Fit Statistics

Two Regressions of Restaurant Health
Inspection Scores on Number of Locations
 Regression Tables and Model-Fit Statistics

Intercept/ Constant; Coefficient

Standard errors of the coefficients

“Significance stars”: whether the coefficient is statistically significantly different from a null-
hypothesis value of 0. To be really precise, these aren’t exactly significance tests. Instead, they’re
a representation of the p-value.
 Regression Tables and Model-Fit Statistics

The number of observations

and : These are measures of the share of the dependent variable’s variance that is predicted by the model. In the
first model is 0.065, telling us that 6.5% of the variation in Inspection Score is predicted by the Number of
Locations.

is the same idea, except that it makes an adjustment for the number of variables you’re using in the model, so it
only counts the variance explained above and beyond what you’d get by just adding a random variable to the
model.

“F-statistic.” This is a statistic used to do a hypothesis test. Specifically, it uses a null that all the coefficients in the
model (except the intercept/constant) are all zero at once, and tests how unlikely your results are given that null.
 Regression Tables and Model-Fit Statistics

The interpretation of an OLS coefficient on a variable is “controlling for the other variables in the model, a
one-unit change in is linearly associated with a -unit change in ”.

If we want to get even more precise, we can say “If two observations have the same values of the other
variables in the model, but one has a value of that is one unit higher, the observation with the one unit higher
will on average have a that is units higher”.

We can say “comparing two inspections in the same year, the one for a restaurant that’s a part of a chain
with one more location than the other will on average have an inspection score -0.019 lower.” After all, that’s
the idea of controlling for variables. We want to compare like-with-like and close back doors, and so we’re
trying to remove the part of the Number of Locations/Inspector Score relationship that is driven by Year of
Inspection.
 Subscripts in Regression Equations

: Thehere tells us what index the data varies across. In this regression, and differ across
individuals.

: The here would be shorthand for time period. This is describing a regression where each
observation is a different time period. The tells us that we are relating from a given period to
the from the period before.

: This is describing a regression in which and vary across a set of individuals and across
time (a panel data set).
Turning a Causal Diagram into a Regression
 Coding examples & Regressions in papers

BOLTON, P. and KACPERCZYK, M. (2023), Global Pricing of Carbon-Transition Risk. J Finance, 78: 3677-
3754. https://doi.org/10.1111/jofi.13272