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2016 September 28-30
Ira Edward Aaron, Ph.D., 1919-2016
My great-uncle, Ira Edward Aaron, Professor Emeritus of Reading Education at
the University of Georgia, died on September 27 at age 97 after a long illness.
He was well taken care of by my sister and died in bed at her house.
Thankfully, all the way to the end, his mind was clear when he was awake,
though he was awake less and less of the time.
My middle name, Aaron, was chosen to honor him and his branch of the family.
"Uncle Ed" was an important role model for me. He was the first academic in our
extended family. My first visit to the University of Georgia was when, at age
6, I was brought to his department to be studied. Normally they evaluated children
to find out why they couldn't read — they evaluated me to find out why
I could, and how I had learned it before starting school,
and to make recommendations for my further
education.
He was a co-author of many editions of the Scott, Foresman elementary-school
reading books, including Fun with Dick and Jane,
so a whole generation of Americans grew up reading things he wrote.
He boasted of being
co-author of one of the most notorious sentences in American literature,
"See Dick run."
A sample of "Uncle Ed's" academic work can be seen in
this pamphlet
for teachers published by the State of Georgia.
Notice how clearly he writes.
Almost all his academic work was applied rather than theoretical; his
emphasis was on getting the word out, helping teachers everywhere teach
more effectively.
During the short times our careers overlapped, we never collaborated on anything,
which may have been a lost opportunity.
I did give a talk to his department while I was a Ph.D. candidate; I talked about
the writing systems of other languages and what was involved in learning to read them.
He had the distinction of being listed on page 1 of Who's Who in America
and occasionally getting mail for the baseball player Hank Aaron, whose entry was
right above his.
He is not to be confused with at least two distant relatives also named Ira Edward Aaron,
one of whom was Ira Edward Aaron, M.D., of Lyons, Georgia.
Stack of four 1-minute exposures with the AT65EDQ refractor and Nikon D5300.
Now here's the same image, "solved" (identified) by Astrometry.net:
One of those star clusters is Charles Messier's M103.
But Messier did not give an exact position for it.
Back in 1832, without benefit of modern star maps, W. H. Smyth identified M103
as the cluster later designated NGC 581.
But in Sky and Telescope, February, 2016, p. 8, Tom Reiland argued
that NGC 663 is a better candidate. Both are consistent with Messier's description,
which was a report of an object discovered by his colleague Pierre Méchain with no
exact position given.
But I don't advocate changing the designation now.
Too much confusion would result.
Taking a break from astronomy today, here are a couple of nature photos.
The crape myrtle is encroaching on our driveway and will soon be cut back,
but it has been a pretty sight all summer.
The lizard (Anolis carolinensis) was actually climbing a wall;
the picture has been rotated 90 degrees.
You can't see the Magellanic Clouds from our latitude, but
here is the next best thing.
The Magellanic Clouds are small irregular galaxies that are satellites of our own,
and from Australia, they look like detached pieces of the Milky Way.
Barnard's Galaxy is a similar irregular galaxy, not quite so close.
It's at roughly the same distance as the Andromeda Galaxy (about 2 million
light years), and because it is nearby and not very densely packed, it is one of the first
exterior galaxies in which Edwin Hubble studied variable stars.
Until he found evidence for its distance, he thought it was a large star cluster,
which, in some sense, every galaxy is.
Now look 2/3 of the way from the galaxy to the upper right corner of the picture.
You'll see two bright stars. One of them looks a bit greenish; it is actually
the planetary nebula NGC 6818.
The picture is grainy because of the contrast amplification that I had to perform
in order to bring out this faint object in a picture taken in town, through rather hazy
air. Stack of 20 1-minute exposures with the AT65EDQ and a Nikon D5300 at ISO 400.
I hope to rephotograph Barnard's Galaxy from a dark-sky site.
I know this picture won't fit on your screen all at once, but scroll through it
and enjoy the view...
This is the star cloud, near the galactic center, that Charles Messier dubbed M24.
It is the very bright patch of the Milky Way that you see in the south soon after
darkness falls at this time of year. Within it are star clusters, dark nebulae (clouds
of space dust), and, left of center near the bottom, two reflection nebulae, IC 1283 and 1284,
clouds of gas with stars embedded in them.
I have bought the AT65EDQ refractor (65 mm aperture, f/6.5) from Greg Derda.
This was taken with it; it's a stack of the best 20 out of 30 one-minute exposures
with a Nikon D5300 at ISO 400.
Have 13 years really passed since I took this picture? Yes.
Dated June 22, 2003, it's
the "False Comet" area of Scorpius, including the nebula IC 4628, which,
with surrounding star clusters, looks rather like a comet.
I call it "Melody's Nebula" because she pointed out this field to me
after finding it with binoculars.
The picture was taken with Kodak Elite Chrome (Ektachrome) E200 film and a Nikon 300-mm
f/4 lens on a Nikon F3, piggybacked and autoguided on my Meade LX200.
On the left you see a single 7-minute exposure, more or less the way it
looked on film.
On the right is a stack of three exposures, scanned and processed digitally
with VueScan, DeepSkyStacker, and PixInsight.
Back in 2003 I didn't have a DSLR, but I was starting to experiment with
digital processing of film images.
In fact, you've
seen this example before, but not nearly as well.
I re-did all the scanning and processing last night (September 22).
Details will be in the new edition
of Digital SLR Astrophotography.
When I bought a black 2012 Ford Escape five years ago, I had no idea everybody
in town was doing the same thing.
Today on the way to the University I encountered three of them.
It is very common for me to find myself parked near, or even next to,
another black 2012 Escape.
The 2012 Escape is easy to recognize because it has the body style of the 2008-2011 Escape
with distinctive taillights, which were used only that year.
Black is the most common color.
Most don't have quite as much silver on the lower front grill as the one
in the picture, which shows an option.
I know that 2012 was the end of a body style that was being discontinued; the
Escape was completely re-engineered for 2013. As I understand it, the Kansas
City, Mo., production line was shut down at the end of the 2012 model year.
I also know that I got a good price on my Escape.
Were black 2012 Escapes sold at clearance prices everywhere, or just in
Athens, Georgia?
These pictures were taken with my 8-inch telescope and Canon 60Da camera on September 14.
Each is a stack of the best 75% of several thousand video frames,
stacked with AutoStakkert and sharpened with RegiStax.
Pythagoras:
Grimaldi:
Seleucus (small and prominent, with Eddington beyond it):
Bailly:
Note how well the Canon renders the tonality and subtle coloration of the lunar
surface, especially in the first picture.
Do you need a modified DSLR to photograph nebulae?
It helps, as you can see from the pictures, but it's not vital.
The picture on the left was taken with an unmodified Nikon D5300;
the one on the right, with a Canon 60Da, which has a special filter that
transmits more deep red light (at 656 nm) than an ordinary DSLR.
Thin hydrogen nebulae such as M8, which you see here,
emit about 3/4 of their light at the wavelength of hydrogen-alpha, 656 nm.
The other 1/4 is mostly at hydrogen-beta, 486 nm.
All DSLRs detect hydrogen-beta well, and they detect hydrogen-alpha to some extent,
but not fully. Thus the nebula is purplish, a mix of red and blue, in the Nikon picture.
The Canon camera responds fully to hydrogen-alpha, so the red color predominates and
a bit more of the nebula is visible.
Back in the days of film, Ektachrome responded strongly to hydrogen-alpha, and other
color films didn't, nor did most black-and-white films.
Today, Canon and Nikon both make special DSLRs for photographing nebulae;
Canon's is the 60Da (used here) and Nikon's is the D810A.
But the usual way to get a modified camera is to buy a conventional one
and send it to LifePixel,
Hap Griffin,
or another independent modifier. What they do is replace the camera's
infrared-cutoff filter with one that transmits more of the deep red end
of the spectrum. After the modification, the camera is still good for
other kinds of astrophotography and even daytime photography (with vivid
Ektachrome-like colors).
Do you have to do this? No. As you can see, the unmodified camera performs only
a little worse than the modified one. The difference is that the nebula
isn't red. People who grew up in the Ektachrome era are sometimes very
strident in their insistence that nebulae ought to be red.
Not me... I just want to see the nebula. Seen in the telescope, it is bluish-gray!
This is a stack of twenty 5-second exposures of star cluster NGC 663 through
my 8-inch telescope at f/10, using a Canon 60Da at ISO 3200.
I'm experimenting with short exposures. If I can work with 10-second or
shorter exposures, I won't need an autoguider, because that's how long the
autoguider goes between corrections. Emil Kraaikamp, over in Belgium, has been
photographing galaxies with hundreds of short exposures.
NGC 663 may be what Charles Messier saw when he recorded the object known
as M103. Traditionally, M103 has been identified as NGC 581, but
NGC 663 is more prominent. it's not
clear from Messier's description which cluster he actually saw.
See Tom Reiland's letter in Sky and Telescope, February, 2016, page 8.
My picture isn't great, but it at least shows that the technique works.
Annoying discovery of the day: Some modern "safety" checks don't accept ink from
some pens.
I recently wrote a few checks using a newly-opened batch of checks ordered
from Checks In The Mail several
months ago.
They repelled the ink!
I tried two fountain pens and a typewriter
and got patchy results with all. Ballpoint ink, however, worked.
To be precise, the yellow safety stripes repelled the ink.
Quick experiments with checks from other batches showed me that Checks In The Mail's
blue stripes are less afflicted
than their yellow stripes, and Harland's yellow stripes (from an old batch)
less afflicted yet, though not perfect.
Fortunately, Checks In The Mail graciously gave me a full refund.
Harland, the previous supplier,
no longer seems to be in the retail check-printing business — upon logging into their
web site, I was redirected
to another company with which I was not familiar.
So I ended up going with Vistaprint,
which has much lower prices, and carefully picking a design that didn't have stripes.
If the new checks turn out to be ink-repellent all over, I'm not sure what I'll do, but at
least they don't charge very much (about $18 for 150 wallet checks, delivered).
Before anyone tells me fountain pen ink is an obsolete technology, let me add
that so are paper checks!
More about this: It's not just a fountain pen problem; other types of
pens are converting to water-based ink for environmental reasons,
so I expect other people to
encounter it more and more. The purpose of the yellow stripes is
to keep people from altering checks; they discolor if erased, I'm told.
My checks, what few there are, are to government agencies, charities, and
businesses; there's little risk of anyone altering them.
This Facebook posting was very well received, so I'm preserving it here...
FRIENDS: Please don't let the media (including Facebook) control all your thoughts and feelings.
I have more important things to do today than trade guesses about why Hillary Clinton
stumbled or who tore down the flags at Occidental College.
So do you.
Plenty of journalists and gossips want to keep you angry
with half-baked stories and one-sided accounts of the facts. It's because they want your attention.
Give your attention to things that deserve it. Make the world a better place by doing your job, taking care of your family, helping those around you, and solving problems that only you can solve. Not everything important is on Fox or Facebook.
Now the grand finale from my trip to Deerlick with the 65-mm f/6.5
refractor and Nikon D5300 body. Here you see the
star cluster M21 (at top left),
the Trifid Nebula (M20),
and the Lagoon Nebula (M8, at bottom).
Stack of five 5-minute exposures at ISO 400.
Why are they purple?
Because this Nikon has not been modified for extended red sensitivity,
unlike my Canon 60Da,
so the red hydrogen-alpha wavelength does not dominate the picture
(though it is picked up to a considerable extent).
Also because digital cameras pick up the blue emission of
hydrogen-beta that film did not.
On Ektachrome film, nebulae are red.
To the eye, they are gray, pinkish, or even greenish.
To digital cameras, they are often purplish.
When I test equipment, I see familiar objects with new eyes.
This is with the same telescope and camera as the other pictures I've been
showing you (below); 65-mm f/6.5 refractor, Nikon D5300, three 5-minute
exposures at ISO 400.
This is of course the familiar Andromeda Galaxy, taken at the Deerlick
Astronomy Village.
In the past couple of years, lots of nature photographers have been taking
and publishing pictures like this one. I'm glad, not just because I like
the Milky Way, but more importantly because I want people to appreciate
the starry sky and the fact that excessive city lights keep you from seeing it.
How do you take a picture like this?
You probably need a DSLR or a pro-grade mirrorless camera; miniaturized
cameras with tiny lenses and tiny sensors don't do as well. But try
what you have.
First, find the Milky Way. The bright part of it is not always in the sky.
At north temperate latitudes, look to the south, before midnight, from
August to October.
To get a good view, you'll need to go out in the country.
I took this picture at the Deerlick Astronomy Village.
Then put the camera on a fixed tripod.
Focus on infinity, preferably by focusing on a bright star or very distant light;
autofocusers can't see the stars.
Some cameras have a mountain symbol that you can choose to lock the focus at infinity.
Expose anywhere from 3 to 30 seconds
with a wide-angle lens wide open (f/4 or wider) and a high ISO setting.
The longer the exposure, the more the stars will lengthen into short lines
rather than dots due to the rotation of the earth.
This one was 6 seconds at ISO 12,800 with a Nikon D5300 and a 1990s-vintage Sigma 24-mm lens at f/2.8,
with long-exposure noise reduction.
Brightness and contrast were adjusted in Photoshop, where further noise reduction was done.
A friend asked me today whether the Biblical name Sarah was more correctly
spelled with or without the final h.
The answer is that Sarah is like a lot of Hebrew names — it ends with
an h that was never pronounced but was always written.
The original way of writing Hebrew did not include vowels, but it did use some
consonants as hints of where vowels should be: y for e and i,
w for o and u, and h at the end of the word only, for a.
Later, when vowel symbols were added, these consonants were left in place.
That's how we got Sarah, Deborah, Isaiah, and all those
other names that end in ah.
This led me to another question: Why is Esther written with th when it
has never been pronounced that way? In Hebrew it is written as tav with dagesh, which
is a T sound not softened as it would be between vowels.
The answer, as I finally found out a few years ago, is that because there are two T letters
in Hebrew, tav and tet, it became traditional always to render tav into Greek as theta,
and tet as tau,
even though tav did not sound like a postclassical theta. (Note tav = theta and tet = tau.
They were obviously going by the sounds of the letters at some early date, not the
names of the letters, which are swapped.) We got our English spelling from Latin,
which got it from Greek; theta always goes into Latin as th.
Using the same setup as in the previous entry (below), here's a picture
taken on the previous day, a stack of two 5-minute exposures of the heart
of the constellation Scutum. It shows star clouds, dark nebulae (at the
upper right), and the obscure star cluster Trumpler 34 at the bottom right.
The crescent moon was in the sky.
Can you photograph the moon with an apo refractor? Certainly.
This is not a great photograph because the air was rather unsteady.
On September 5, I took the refractor to Deerlick and got some excellent
pictures, which you'll be seeing in the next few days.
While out there, I snapped this 1/320-second exposure using a Canon 60Da
camera body and "silent shooting" (vibrationless electronic first shutter
curtain, a feature the Nikon D5300 does not have).
Brightness adjustment and unsharp masking with Photoshop.
I'm experimenting with the setup shown below — a borrowed AT65EDQ 65-mm f/6.5
apo refractor, Nikon D5300 body, Celestron AVX mount, and a homemade autoguiding device
similar to the now-discontinued SBIG eFinder riding piggyback on top, connected to an SBIG STV.
Let me start with one of the less spectacular pictures; better ones are coming in the next few days.
The star cluster that you see above is M26, in Scutum, notable for appearing to have an
empty space in the center. As I understand it, astronomers are still debating whether
the "hole" is a dark nebula (common in the area) or an actual lack of stars.
This is a stack of five 5-minute exposures at ISO 400, taken in town (Athens, Georgia).
Finally, Peanuts readers will remember Charlie Brown's tree that ate kites.
While completing the M26 exposure sequence, I caught a tree eating a star cluster:
I haven't been able to get a Java system completely working under it,
with either OpenJDK 7 (which installs if you ask for "default-jdk")
or Oracle JDK 8.
The usual symptom is that a Java program hangs, completely occupying one CPU core.
Depending on the circumstances, java -version may hang,
or javac hello.java may hang.
But according to what I hear on the Web, even if you can compile and run
simple single-threaded Java applications, you're not out of the woods.
More complicated Java-based packages such as Bazel still have problems.
Why do I want Java under WSL when I can already run Java under Windows?
Because some other Linux-based tools, such as the Bazel utility from Google,
require it.
As best I and others can determine, the problem has to do with process creation.
The biggest difference between Linux and Windows is that creating a process
in Windows is a much bigger deal, taking more work and time.
For WSL, Microsoft introduced a new type of lightweight process.
It apparently still doesn't quite satisfy Java's expectations.
Very late the other night, Melody's glasses broke. To be precise, one of
the temples (earpieces) broke in two near the hinge.
Most people would have resorted to Scotch tape and an emergency trip to
the optician the next morning, but we were more resourceful.
Rummaging among Melody's old glasses, we found one whose temples were
almost the same. Then I got out my jeweler's screwdrivers and made
the swap. Success! A perfect fit; it didn't even need adjusting.
But the repair job was non-trivial because the spring kept retracting
the hinge where I couldn't get to the hole.
A very close observer may notice a slight difference in
style between the left temple and the right temple of Melody's glasses.
But, really, if you're going to stand that close to my wife, you
might need to ask my permission!
A while back I wrote about code-signing certificates
and how I was getting ready to start digitally signing my software products.
Other things came up, and I didn't implement everything I wanted to until
today. Now, EXIFLOG reaches you
code-signed, and so does CoVec, or it will
when I start selling it.
Recall that I got an Authenticode certificate from Digicert
and installed it on my main desktop computer. I also got a Windows Software Development Kit
(which comes with Visual Studio) in order to have the signtool command.
But there were tactical questions.
Sha256 or Sha1? Newer versions of Windows expect Sha256 encryption, which is more
secure, but prior to Windows XP SP3 (or so I'm told), only Sha1 is acceptable.
One certificate or two? Executable exe files accept multiple digital certificates, but
an msi file (Microsoft Installer) can only have one.
Access to signtool? It's available in the Visual Studio developer command prompt,
but in an ordinary command prompt, it's not on the path and doesn't work.
My solution? First I used the command where signtool.exe
(from a Visual Studio Developer command prompt, not an ordinary one)
to find out
where signtool resides.
In my case, it was in C:\Program Files (x86)\Windows Kits\10\bin\x64\
and I added it to the path.
Then wrote a script that includes the following three commands:
to affix an Sha256 signature, affix an Sha1 signature too (failing harmlessly if the file
won't accept one), and then verify them.
Now then: Workflow with Visual Studio.
I'm well aware that I could call signtool as a post-build event and get my code signed
automatically. I don't want to do that! I only sign code when, in my considered opinion,
it is ready to distribute.
So here's what I do.
(1) Build the project (the executable).
(2) Sign the exe file. With Visual
Studio installer projects, you have to sign the copy that is in
obj\Release, not bin\Release.
This threw me for a while. Installshield, however, uses the latter.
OK, hang on to your hats, this Notebook entry is going to be about
linguistics, on a rather technical level.
But I'll do my best to make it understandable by non-specialists.
An article in the September 2015 issue of Language caught my
eye. (Yes, I'm a whole year behind reading them.)
Yusuke Kubota and Jungmee Lee argue that the Coordinate Structure Constraint
is not what we thought it was.
The Coordinate Structure Constraint is an unusual, but strict, rule or principle of grammar
that wasn't discovered until 1967 (by J. R. Ross). It will take me a moment to
explain what it is.
First look at how the English language forms yes-no questions.
We put do, does, or did at the beginning of the sentence
and change the verb to the plain form (in this case see rather than saw):
You saw a duck.
Did you see a duck?
Now consider what questions. To form a what question, we make the changes
that I just described, and we also put what at the beginning of the sentence
and omit the noun phrase that is being questioned, thus:
You saw a duck.
What did you see _ ?
Here I'm using _ to mark the position of the omitted noun phrase.
Much of the early appeal of Chomsky's transformational grammar was that it enabled us
to state recipes like this for making one kind of sentence from another.
If you could account for the grammar of one set of sentences, you could make another
set of sentences from them easily, by transformation, without having to describe
everything from scratch.
Now note a crucial fact about what questions: The questioned (omitted) noun phrase
can be almost anywhere in the sentence. Exactly one noun phrase can be questioned, but it
can be almost anywhere.
You saw a duck carrying a stick. What did you see _ carrying a stick? (A duck.) What did you see a duck carrying _ ? (A stick.)
You saw a duck sitting next to a goose. What did you see _ sitting next to a goose? (A duck.) What did you see a duck sitting next to _ ? (A goose.)
You saw a duck carrying a stick shaped like a baseball bat. What did you see a duck carrying a stick shaped like _ ?
The last one is a bit wordy, but you had no trouble understanding it.
It may be clumsy style, but it's not ungrammatical.
(By the way, the example with sitting next to violates the artificial
rule, imported from Latin, that prepositions should never come at the ends of
sentences — but, again, it's perfectly natural English as the language is
actually spoken. We're analyzing real English here, not the language found in
grammar books.)
Now for the Coordinate Structure Constraint. Ross discovered that when the
questioned noun phrase is one of a pair joined by and, the process that
we've been describing does not take place.
You saw a duck and a goose.
What did you see a duck and _ ? (ungrammatical)
What did you see _ and a goose? (ungrammatical)
Not only is the Coordinate Structure Constraint quite strict, it appears to
apply to all languages (at least, all languages in which we can identify a
question-forming process like ours), not just English.
It seems to be more than just a rule of grammar — not something children
acquire as they're learning to speak English, but rather, something deeper having
to do with the mechanisms by which sentences are constructed.
A long line of research ensued from that discovery. But now Kubota and Lee have
a completely different proposal.
They argue, based on evidence from Korean and Japanese, that
the Coordinate Structure Constraint is not a rule or principle of grammar at all.
Instead, it is a rule of discourse structure: phrases joined by and have to
be parallel. That is, they have to play the same role in communication, as alternatives
or a pair.
Old-fashioned English teachers will be nodding and saying, "Parallelism!"
Yes; that's exactly it. The Coordinate Structure Constraint is not a rule of grammar;
it is a rule of how to express your ideas in an orderly way (the area of linguistics
that is now called pragmatics).
Here's an example (based on Kubota and Lee) showing that parallel communicative intent
is what matters.
We sometimes use and to indicate logical succession rather than pairing.
When we do, it's OK to question the second noun phrase:
I went to the store and bought milk.
What did you go to the store and buy _ ?
Here there is no violation of parallelism because go to the store and
buy milk were not a matched pair in the first place; one of them was a
consequence of the other.
Their evidence from Korean and Japanese is along the same lines but more extensive.
Now you know what linguists spend their time thinking about!
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