1.  a) Which star is eclipsed (i.e., which star is behind the other) at time = 0?  star A or star B?  The answer is contained entirely in the radial velocity graphs of RW Mon at the top of page 18!  Explain how you knew (of course!). 

   2.  a) The eclipses of RW Mon (one of which is a total eclipse and the other of which is an annular eclipse) both have flat bottoms (see the light curve -- the plot of apparent magnitude of time in the Astro green book page 18).  Some eclipsing binaries, however, have light curves that have pointy bottoms (like the letter V or like an upside down teepee)  what are the TWO situations that would produce a light curve with pointy bottoms as opposed to flat bottoms?

b) Suppose that you have a binary like RW Mon, where both stars' spectral lines are visible in a single superimposed spectrum (the stars are so close together that we can't see the star separately or therefore get separate spectra for the two star). 

And clearly both sets of spectral lines are seen, otherwise we wouldn't have the wavelength shifts of each star and thus wouldn't have the radial velocities of each star as a function of time.  So how do astronomers (in general) know which star (the bigger or the smaller) is in front at each of the two eclipses (e.g., at phase = 0.0 and phase = 0.5 for RW Mon) that occur during one orbit period?

   3. a) The real question here is:  The deeper eclipse in an eclipsing binary system's light curve (for example, the one for RW Mon on p. 18 of the green book) is always the eclipse of the ________________ star.  (Fill in the blank !) and explain of course!

                b) However, to make the answer to the above almost obvious, answer this question first:   In which eclipse (the deeper or the shallower) is more star area covered?

                  (and of course to make this really really obvious, cut out some star shapes {= circles!} with scissors and paper and try it!!  and I almost guarantee if you *refuse* to do this, you will get this question wrong and be really embarrassed!)