General Homework Tips, Suggestions, and Strategies
Chris Mihos, CWRU Astronomy
Start Early, Work Regularly
Many of the problems involve multiple steps that build off one
another. If you start the HW set late, find you're stuck on step
1, you'll be in deep trouble for the rest of the problem. Also, I
don't always define every single thing you need to solve the
problem -- that's by design, to get you used to the idea that
sometimes you need to do a bit of your own digging for
information. Again, if you can't find that information the night
before the due date, you'll be in trouble. I'm always
happy to help you find information or work through sticking
points, but you need to know where those sticking points are well
ahead of the deadline so that you can ask for help. So start the
problem sets early, and work a little bit on them every few days
so that you know where you might need help well in advance of the
due date.
Show Your Work
Explain each step of your calculation of analysis, included a
description of any assumptions or data/numbers used. Show
intermediate steps. Don't just write down an answer with no other
explanation -- that won't get full credit, even if it's correct.
Two reasons for showing your work: First, a good answer is much
more than a calculation, its an explanation. A truly excellent
A-level homework writeup should double as the solution set that I
can just hand to other students so that they can understand the
concepts behind the solution, as well as the quantitative answer.
Second, if you show your work, I can tell the difference between a
simple calculation error (which don't get penalized much) and a
completely wrong approach. If all I have to grade is a final
answer, and it's wrong, it's a zero, whereas if I can see steps
showing that you did 90% of problem correctly, but stumbled on the
last step, you'll get much more credit.
Use Words
This goes hand-in-hand with the previous comment. A scientific
writeup is an explanation, not a calculation. Don't just hand me a
piece of paper with numbers and plots. I expect your writeups to
be well written, using verbal explanations, complete sentences,
good grammar, etc -- no different from the standards and
expectations we scientists have in writing up our research in
scientific journals. I don't demand that you typeset or use a word
processor to write up your HW (writing out mathematical
expressions on word processors is a much bigger pain than it's
worth), but your writeups should be neat and readable -- if I
can't read your handwriting (or if I can but it gives me a
splitting headache), or if I can't follow your logical steps, it
will be hard to give full credit on your answers.
Use the units of astronomy; try and limit conversions.
We're doing astronomy, so in general you should use units
natural to astronomy-- parsecs, solar masses, years, and
variations of those units. Certainly there are times when SI/cgs
units are appropriate -- if you were calculating the mass of a
comet, for example, expressing it in solar masses would be kind of
silly. So you'll have to make decisions about the best units to
use. But you're used to mixed units that are situationally
dependent. In your physics class, if asked to do a calculation of
time, you'll probably work out an answer with units of seconds,
but if asked your age, you'll give it in years. Or if asked "how
far is Toledo", you might even answer in units of time ("its a two
hour drive"), not distance. These are "situational units". And in
this class, the situation is astronomy, and more specifically,
galactic and extragalactic astronomy. So use the units of
astronomy. Converting back and forth from astronomy units to
SI/cgs is bound to lead to silly mistakes, and is one of the
biggest sources of error I see on HW sets.
And finally, yes, we use magnitudes. We're astronomers. Learn
to be comfortable with them.
Here are some tips and shortcuts to make your life
easier:
- if you measure distances in parsecs (pc), time in
millions of years (Myr), masses in solar masses (Msun), and
speeds in km/s, G=4.43x10-3 pc3 Msun-1
Myr-2. Don't convert everything to SI, plug in
G=6.67x10-11 N m2 kg-2, then
convert back -- you're apt to make a silly conversion error.
- Similarly if you are a planetary scientist working with
distances in AU, time in years, and masses in solar masses,
G=4 AU3
Msun-1 yr-2.
- 1 km/s ~ 1 pc/Myr (which means I could just as easily
have said G=4.43x10-3 pc (km/s)2
Msun-1)
- 1 year ~
x 107
seconds
- For small magnitude errors (< few tenths), the
relative flux uncertainty is roughly equal to the magnitude
uncertainty. So a magnitude uncertainty of 0.1 mag is roughly
a 10% uncertainty in flux.
- For small errors in distance modulus, the relative
distance uncertainty is about half the distance modulus
uncertainty. So a distance modulus uncertainty of 0.1 mag is a
distance uncertainty of 5%.
Unit analysis can help you track down a problem
Remember that you can do math on units as well. Let's say you
were doing a problem using the speed of the Sun's orbit around the
Galaxy to work out the Galaxy's mass. OK, so the Sun is about 8
kpc from the galactic center, and the orbital speed is about 220
km/s. So you say
M = rv/G = 8000*220/4.43x10-3 = 4x107
Msun. Hmm that seems really small if the Galaxy really has
billions of stars in it, what went wrong? So let's
check the units:
M = rv/G = [pc] * [km/s] / [pc (km/s)2 Msun-1]
- the pc on top and bottom cancel out
- Msun-1 on the bottom becomes Msun on the top
- one power of km/s on top divided by two powers of km/s on
the bottom leaves a km/s on the bottom
- so my final unit on my answer is Msun / (km/s) -- that's
not a mass! So my answer can't be right, I've messed up the
velocity part!
and yes, that's the problem -- it's not M = rv/G, it's M=rv2/G.
If you plug the numbers into that correct expression, you get a
much more reasonable mass: 8.7x109 Msun. (Although
remember that's only the mass inside the Sun's orbital radius!)
So if you're numbers aren't working out, use unit analysis to
help track down a problem.
Answers have units, plots have labels
Numerical answers always have units -- make sure you give them.
Working out a distance to a globular cluster of "7600" is not
correct, it ought to be "7600 pc" or, better yet, "7.6 kpc". When
you make a plot, axes should be labeled both with what they are
showing and what the units are. For example, a color magnitude
diagram would have an x-axis label that says "B-V [mags]" and a
y-axis that says "mV [mags]", and bright blue stars
would be at the upper left of the plot!
And while we are on the subject of plots, if you are making an x-y
plot
and y spans more than an order of magnitude, don't plot it on a
linear
plot! Either plot log(y), or use a plot with a logarithmic y-axis.
(The
same goes for x, of course!)
Don't write out every digit your calculator displays!
Think about significant digits, not necessarily in the strict
sense, but in terms of common sense. If I said to you that
Columbus was 140 miles away and you were driving 75 mph, I hope
you wouldn't tell me it would take 1.86666666667 hours to get
there, right? (Plus, why would you want to go to Clodumbus?) Stop
quoting digits where they stop being meaningful. Sometimes
"meaningful" will have a quantitative definition -- for example,
how the answer compares to the uncertainty -- other times it will
have a common sense answer based on the quality of the
assumptions.
Comment on Wrong Answers
If you work out an answer that you know to be wrong, please say
so! For example, if you work out the distance to a star and get a
number like 3.31234x106 meters, please
tell me you know that's a wrong answer, otherwise I'll worry that
you think that star really is located in Los Angeles! (Plus,
shouldn't you have worked it out in parsecs, anyway?). Tell me
that it's wrong, give me some idea of where you think your error
might have happened. Don't just write down an answer that you know
to be wrong and leave it there without comment.
Think about the Results
Arriving at a quantitative answer or making a plot is never the
end of an exercise. After you've done the analysis, you need to
comment on what it means! Again, just about every scientific paper
has a "Discussion" section after the "Results" section (even if
they are not formally labelled like that), and you should take the
same approach. Don't just attach a plot and walk off stage --
instead, talk about how your result fits in with the bigger
picture of whatever the problem is talking about.
Also, often times I will ask you to comment on sources of
uncertainty or error. Don't just say "the data could be bad" --
that's kind of a "duh" comment. Of course, the data can always be
bad. Instead, I'm asking you to comment on sources of systematic
uncertainty -- problems with any assumptions that were made, or
with how the data might have been collected, etc -- and how that
uncertainty affects your answer/result. For example, if I gave you
a color-magnitude diagram and asked you why the spread in the main
sequnce got worse for low mass stars, saying "the apparent
magnitudes of the stars might be wrong" is a duh answer, but
saying "low mass stars are intrinsically low luminosity, and
measuring accurate colors and magnitudes becomes harder as you go
fainter, so there is just more measurement error for low mass
stars" is a much more thoughtful answer.