FAQ.tex

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\begin{flushleft}
  \large
\textbf{\Numberstringnum{58} Questions for Dr.\ Willis}
\end{flushleft}  
\normalsize
%\subsubsection*{FAQ}
\begin{enumerate}

\item \textbf{Question} Did I miss anything in class last week?

\textbf{Answer} Yes.  Please read  the poem “Did I Miss Anything?” by Tom Wayman.  

\item \textbf{Question} Will that be on the test?

\textbf{Answer} Maybe. If you are concerned about a topic that is briefly
mentioned in class that is not in the homework or textbook, please ask me
about its importance. But it is, I think, important for me to 
show you how the topics we are learning are related to other disciplines  
and to understand the historical and human side of the
creative effort involved in creating (or discovering) mathematics. So yes,
not every mathematical morsel we learn in class will be ``on the test.''

\item \textbf{Question} On the test, do you want interval notation, set builder
notation, or a pictorial representation?

\item  \textbf{Answer} Unless the question explicitly says which form,
you are free to express yourself in whatever way you wish.

\item \textbf{Question} Do you want me to write a proof like X or 
like Y?

\item  \textbf{Answer} I like to keep the focus on logical 
correctness, not on adherence to a style template. If your question is about
style, not content, don't be surprised if my answer is ``It doesn't 
matter--either way is OK.'' 

\item \textbf{Question} Is this OK, or do I need to simplify it?

\item  \textbf{Answer} Maybe. Giving guidelines on what it means to 
  simplified is tough. But if you  (a) do all rational arithmetic (b) combine
  all like terms, (c) simplify all ``famous'' values of functions, 
  for example $\cos(0)=1$ and $\sqrt{81} = 9$, and (d) make an effort
  to simplify all vanishing expressions to zero (for example, 
  $\frac{1}{\sqrt{2}} - \frac{\sqrt{2}}{2}$ simplifies to zero), you'll be OK.

\item  \textbf{Question}  Will  we review the entire dead week?

\textbf{Answer} Maybe.  Once we finish all sections in the course 
calendar, we'll review for the remainder of the term.  But it's 
likely that we'll need to use at least part of dead week to cover
new material. 


\item  \textbf{Question}  Will you give us a review before every exam?

\textbf{Answer} Yes. The review will likely not have a complete solution key, 
but yes there will be a review. The review for the final exam will be the union 
of all the other reviews.  We might spend some class time before an exam for review, 
but it's unlikely we'll spend the entire class period reviewing. 

\item  \textbf{Question}  Can I get extra credit?

\textbf{Answer} No. Course grades for all students will be
assigned according to the syllabus. Our grading scheme has 
no provision for extra credit. 

\item  \textbf{Question}  Will you sign my grade check form?

\textbf{Answer} Yes.  Please help me out and look up your course grade on Canvas and 
show it to me.

\item  \textbf{Question}  My major is X and I have to take Calculus II.  I've heard 
that Calculus II is much harder than Calculus I.  Should I switch majors?

 \textbf{Answer}  No, not for that reason. Calculus II is no more intellectually 
 challenging than Calculus I. All science majors have required classes 
 (for example, Physical Chemistry, Quantum Mechanics, etc.) that
are \emph{far} more difficult than Calculus II. 

\item  \textbf{Question} Isn't \(1/0\) \emph{really} equal to infinity?

  \textbf{Answer}  No,  \(1/0 = \infty\)  is rubbish. If we adopted   
   \(1/0 = \infty\) as a rule and kept the other usual rules of arithmetic, we'd 
   be able to derive statements that
are manifestly false (things like \(1 = 2\)).


\item  \textbf{Question} Isn't \(1/\infty \) \emph{really} equal to zero?

 \textbf{Answer}  No,  \(1/\infty = 0\)  is rubbish.  The reason is much the same as 
 for why  \(1/0 = \infty\)  is rubbish.  Possibly the confusion stems from the limit 
 fact that if \(\displaystyle \lim_{x \to a} F(x) = 1\) and  \(\displaystyle  \lim_{x \to a} G(x) =  \infty\), 
 we have \(\displaystyle \lim_{x \to a} \frac{F(x)}{G(x)} = 0\).  Arguably, the 
 calculation \(\displaystyle \lim_{x \to a} \frac{F(x)}{G(x)} =\frac{1}{\infty} = 0\) 
 is a forgivable faux pas, but this limit fact  doesn't imply that  \(1/\infty = 0\).


\item \textbf{Question} Is \(0^0\) undefined?

 \textbf{Answer} Sometimes, but not always.  In the context of a summation, such 
 as \(\sum_{k=0}^{n} x^k\),  the first term is \(x^0\). If \(0^0\) is undefined, 
 the first term of the sum is
undefined when \(x=0\). But in the context of a sum of powers of a variable, we 
almost always want \(x^0 = 1\) for all \(x\).  In other contexts,  \(0^0\) is 
undefined. Mathematical notation, like all natural languages, is context dependent.

\item  \textbf{Question} What is  \(\infty - \infty\)?

\textbf{Answer} It is rubbish.


\item  \textbf{Question}  Is infinity a number?

\textbf{Answer} Yes, infinity is a number.  It's not a \emph{real} number, but it 
is a number.

\item  \textbf{Question}  Can a function be infinity?

 \textbf{Answer} No. Functions and numbers are distinct objects, so a function 
 can \emph{never} be a number. It is possible for infinity to be in the range of a 
 function, for example, \(x \in \reals \mapsto \begin{cases}  x & \mbox{ if } x \neq 2 \\ \infty &  \mbox{ if } x = 2 \end{cases} \).  Although infinity is in the range of this function, the function certainly isn't infinity. Failing to distinguish a function from a number is an example of \emph{conflating}.

 \item \textbf{Question} What do you mean by an identity?

\textbf{Answer} An equation is an identity provided its solution set is
``everything.'' For equations involving one real variable, ``everything'' generally 
means the set of all real numbers. For example, the solution set to 
\( 0 x= 0 \) is \(\reals\), so \(0 x = 0 \)
is an identity. But the solution set to \(\displaystyle \frac{x}{x} = 1\)
is the set of all real numbers \emph{except} for zero, so \(\displaystyle \frac{x}{x} = 1\)
isn't an identity. 

\quad A relaxed notion of an identity is an equation whose
solution set is the same as its natural domain. For that meaning, \(\displaystyle \frac{x}{x} = 1\)
is an identity because both its solution set and its natural domain are \(\reals_{\neq 0}\).

\item \textbf{Question} To prove that an equation is an identity, I was
 told to ``only work with one side at a time.'' Why is that?

 \textbf{Answer} First, to prove that an equation is an identity,
 we need to (i) solve the equation and (ii) show that its solution
 set is the same as its natural domain. During the process of solving,
 we can't do anything that enlarges the solution set, but doing anything
 that maintains the solution set is allowed.
 
 \quad The requirement to ``only work with one side at a time''
 is an effort to disallow doing things that enlarge the solution set of
 the given equation. One  such example is multiplying both sides of an equation by zero. Another
 example is squaring both sides of an equation. Indeed, multiplying
 both sides of \(x = 1\) by zero enlarges the solution set from \(\{1\}\)
to \(\reals\). And that's a huge enlargement.  Another example is squaring both sides of 
\(x=1\) enlarges the solution set from \(\{1\}\) to \(\{-1,1\}\).

\quad Instead of the adage to ``only work with one side at a time,'' 
students would be much better served if we gave them guidance that was firmly
rooted in logic than to ``only work with one side at a time.'' 

\item  \textbf{Question} Why is \(0! = 1\)?

 \textbf{Answer} Because it's useful and it extends the validity of a useful identity. For positive integers \(n\) greater than two, we 
 have the identity \(n! = n (n-1)!\). If we replace \(n\) by one in this identity, 
 we get \(0! = 1\). 

\item  \textbf{Question} I saw a proof that \(0=1\).  Is it correct?

  \textbf{Answer}  No, it is rubbish. Most likely the so-called proof involved a hidden divide by zero.



\item  \textbf{Question} My cousin told me about a strategy for playing Keno that is guaranteed to win. Does it work?

 \textbf{Answer} No. Many such methods involve doubling your bet repeatedly. This doubling scheme is 
an effective way to convert  a large fortune into a small fortune. Actually, there is a sure-fire 
way to earn a small fortune playing Keno--the trick is to start with a 
large fortune.

\item  \textbf{Question}  If a sentence ends with a factorial function, should a period 
follow the exclamation point?

  \textbf{Answer}  Yes. But the sentence should be re-written to not 
  end that way.  Writing ``\(x = 0!\).''  is nerd humor for the 
  equivalent statement ``\(x = 1.\)''
\
\item \textbf{Question}   Shouldn't the abbreviated name for the natural logarithm function be $\mathrm{nl}$
      not $\ln$?
      
\textbf{Answer} Ha! That's funny! I've never thought of this before. In computer science
  this might be described as a  little endian versus a big endian problem.

\item  \textbf{Question} Does \(\ln x + y\) mean \((\ln x) + y \) or   \(\ln  (x + y)\)?

 \textbf{Answer} The standard is that is \(\ln x + y = (\ln x) + y \). But \( \ln x y = \ln(xy)\).  All this is too confusing, so I suggest using parentheses. 

\item  \textbf{Question}  Is it true that \(a \cdot b  + c\) means \(a (b+c)\), but \(a  b  + c\) means \((ab) + c\)?

 \textbf{Answer} No.  Both  \(a \cdot b  + c\) and \(a b + c\) mean  \((ab) + c\).  Possibly before about 1940 or so, using a centered dot for multiplication had a lower precedence than for addition. But at least in the United States, this is no longer true.



\item  \textbf{Question}  Is time the fourth dimension?

\textbf{Answer} No, not really.  For many physical theories, it's convenient to lump the three spatial dimensions together with the time, forming a vector with four components. But in mathematics, 
vectors can have any number of components and we don't impose any particular meaning on the components. So I wouldn't say that time is \emph{the} fourth dimension.

\item  \textbf{Question}  Can you see the fourth dimension?

\textbf{Answer} No, absolutely not.

\item  \textbf{Question}  Is mathematics \emph{invented} or \emph{discovered}?

 \textbf{Answer} I don't know. Meta-mathematical questions don't interest me all that much. 
It isn't, I think, a question that is worth pondering.

\item  \textbf{Question} Do numbers exist?

  \textbf{Answer} I don't know. Again, it isn't, I think, a question worth pondering.

\item  \textbf{Question} Do Fibonacci numbers frequently appear in nature?

\textbf{Answer}  No, not really.  For an explanation, read the article ``Fibonacci Flim-Flam,'' by Donald E. Simanek.

\item  \textbf{Question} Are there deep connections between mathematics and music? 

  \textbf{Answer}  No, not really. The connections that are known aren't, I would say, particularly deep.

\item  \textbf{Question}  Billy had 53 socks.  Eleven of them were brown.  The rest were navy blue.  He never sorts them, and he keeps them all in his drawer.  In the morning, what's the greatest number of socks that he has to pull out before he gets a matching pair?

  \textbf{Answer} It depends. Is Billy color-blind?  Are the lights on? What does matching mean? Does a wool sock match a cotton sock? It matters.

\item  \textbf{Question} What's the next number in the sequence  \(2,5,8,11, \dots \)?

  \textbf{Answer}  It's a silly problem that deserves a silly answer--any number is just as logical as any other. 
The formula for the sequence might be \(k \in \mathbf{Z}_{\geq 0} \mapsto \begin{cases} 3 k +2 & \mbox{ if } k \leq 3
 \\ \sqrt{2} & \mbox{ if } k >  3 \end{cases} \). That would make the next term \(\sqrt{2} \). 
 Arguably, the formula  \(k \in \mathbf{Z}_{\geq 0}  \mapsto 3 k +2 \) is in some 
 sense the most simple, so by the law of parsimony 
 (the simplest explanation is most likely the right one), the next 
 term is 14. But ``most likely'' isn't always correct.

\item  \textbf{Question} Is it true that \(1 + 2 + 3 + \cdots = -1/12\)?

  \textbf{Answer}  Maybe. For one meaning of the concept of convergence, the answer is yes; for other meanings, including the meaning that you will learn (or learned)  in calculus, the answer is no.  Some physical theories use the notion of convergence for which it is true that \(1 + 2 + 3 + \cdots = -1/12\).

\item  \textbf{Question} Is \(\sqrt{9} = \pm 3\)?

  \textbf{Answer}  Maybe.  But for this class, it's best to stick with the so-called 
  principal square root--that means \(\sqrt{9} = 3\), not  \(\sqrt{9} = \pm 3\).

\item  \textbf{Question} Why does my graphing calculator not show the left side of the graph of \(y = x^{2/3}\)?

\textbf{Answer} It's because your calculator is using what is usually known as the principal branch for the \(2/3\) power and not the so-called real-branch rule.  Using the real branch rule,
we have \((-1)^{2/3} = ((-1)^2)^3 = 1^3 = 1\). But using principal branch, we have \((-1)^{2/3} = \frac{\sqrt{3}}{2}  \mathrm{i}  -\frac{1}{2}\) If you would like to understand this, please enroll in MATH 365.

\item \textbf{Question} Do I need a graphing calculator for this class?

\textbf{Answer} No. When we need a computer drawn graph, we'll use an online tool.

\item \textbf{Question} What other classes do you teach?

\textbf{Answer} At UNK I have taught College Algebra, 
   Plane Trigonometry, Calculus I, II, and III, Applied Calculus I,
   Foundations of Math, Differential Equations, Discrete Mathematics, Abstract Algebra, Complex Analysis,
   Numerical Analysis, Linear Algebra, Theory of Numbers, and Advanced Calculus I. Additionally, I've
   taught the final third of Math for Elementary Teachers I as well as  Probability and Statistics.
   Additionally, at another university, I taught classes in partial differential equations and a
   year long applied mathematics course for graduate students in engineering.

\item  \textbf{Question} Is it true that four current UNK faculty took a math class from you?

 \textbf{Answer}  This was likely true at one time, but currently I only know of two who 
 took a class from me. And no--without violating Federal law, I cannot reveal the identities of
 these faculty members.

\item  \textbf{Question} Why did you choose to be a math teacher?

\textbf{Answer} It was a combination of having something close to 
love for the discipline, growing up in a scientifically based 
family, and learning from some strong science and mathematics 
teachers in high school and college.


\item \textbf{Question} Why do you like math so much?
\item 
\textbf{Answer} I have no idea. I was  a dopey kid who
grew up in rural Kansas with two loves: girls and trigonometry. I wasn't
all that successful with girls, so there you go.

\item  \textbf{Question} What is your favorite comfort food?

  \textbf{Answer}  For cool weather, it's cornbread (with butter and honey), chili, collard greens, chow-chow, and peach cobbler; for warm weather, it's coleslaw, baked beans, sliced tomatoes, buttered corn on the cob, and peach cobbler.

  \item  \textbf{Question}  What is your favorite bird?
  
  \textbf{Answer} Goldfinches--I grow sunflowers for them and in late summer
  they visit my garden and gobble up the crop. Watching goldfinches feed on my 
  sunflower
  crop gives me a 
  ridiculous amount of joy.

  \item  \textbf{Question}  Do bees visit your gardens?
  
  \textbf{Answer} Yes--my pollinator garden attracts lots of bees. I love
  watching them and I wish I could learn all the different
  species that visit my flowers. I don't have hives for honey bees, but
  I'd like to try that someday.

 \item   \textbf{Question} Is kale easy to grow? Do you make kale chips?
 
 \textbf{Answer} No, to both. To grow kale successfully  you must
 control the cabbage worms. And that takes some effort that is 
 beyond easy.  Kale chips are too trendy for me--I eat 
 kale either raw, sautéed, or boiled.

\item   \textbf{Question}  What is your favorite programming language?

 \textbf{Answer}  Common Lisp. And this is fortunate because I'm a developer for a computer algebra system that is written in Common Lisp. My second favorite language is Julia.

\item   \textbf{Question} Is it true that you hit your head on a TV in class and 
passed out?

  \textbf{Answer} Mostly true---I bled profusely, but I didn't pass out.

\item   \textbf{Question} Will you tell the story about the time you chased a turkey?

 \textbf{Answer} No, the turkey story has been retired.


\item   \textbf{Question} Is there anything that totally creeps you out?

\textbf{Answer} Bats (the flying mammal kind) come pretty close.

\item \textbf{Question} Do you speak any languages other than English?

\textbf{Answer} Regrettably no. I studied a semester of German as an 
undergraduate and two quarters of German grammar in graduate school. 
Sadly, \emph{Mein Deutsch ist sehr schlecht} (My German is very bad).

\item \textbf{Question} Why is 107 your favorite number?

 \textbf{Answer} It's a secret and only my sister knows the reason.

\item \textbf{Question} Why do class handouts sometimes have unusable 
two hole punches instead of the useable three hole punches?

\textbf{Answer} It's due to my abject sloth and laziness. 
On the printer options, the two hole punch is the first, and 
laziness prevails and I choose the first option.

\item \textbf{Question} Where do you get the unusual names and places you
use on exams?
 
\textbf{Answer} Some of them come from British television serials
that I enjoy and some from old tombstones in the Kearney cemetery.
Some other names are from my hobbyist humor writing efforts.

\item  \textbf{Question} Has somebody really asked all these questions?
 
\textbf{Answer} Except for this question, yes.
\end{enumerate}

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