2. PHYSICS

Subsections

2.12 MEASURE THE HEIGHT OF A BUILDING WITH HELP OF A BAROMETER

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October 15 October 25 For every problem, there are probably a thousand solutions. The trick is to find one you can use. So, if you ever need to measure the height of a building with a barometer, here are some methods you can try.

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From: Donald Simanek <dsimanek#NoSpam.eagle.lhup.edu>
                           THE BAROMETER FABLE

(This seems to be the original story.  If you wish to see many solutions,
you can go to the next item.)

The following essay is frequently referred to, and often reprinted in
textbooks on writing. I recall it was also reprinted in one of the Project
Physics supplementary readers. Few people recall its source, or its author.

As a bit of humor it is nicely constructed. As a parable with a moral, it
falls flat. What is the author's point, one wonders? Is it an argument
against a particular kind of pedantry in teaching? Is it a demonstration
that exam questions can be subject to multiple interpretations? Is it an
example of how a clever student can find ingenious ways to answer a
question?

Just what is the difference between exploring `the deep inner logic of the
subject' and teaching `the structure of the subject'. Calandra doesn't
make that difference clear, yet his student seems not to like the first,
but would rather have the second.

The title (which most people forget) is a clue. Medieval scholastics were
fond of debating such meaningless questions as "How many angels can dance
on the point of a pin," "Did Adam have a navel," and "Do angels defecate."
The emerging sciences replaced such `scholarly' debates with
experimentation and appeals to observable fact. Calandra seems to be
suggesting that "exploring the deep inner logic of a subject in a pedantic
way" is akin to the empty arguments of scholasticism. He compares this to
the `new math', so much in the news in the 60s, which attempted to replace
rote memorization of math with a deeper understanding of the logic and
principles of mathematics, and he seems to be deriding that effort also. So
it still seems to me that we get no clear and useful message from this
essay.

On almost every level, this essay falls apart on critical analysis. I
wonder why it has become such a legend in the physics community?

[The equation, S equals 1/2 a times t-squared, may not come out properly on
your browser or newsreader.]

                              Angels on a Pin

                             A Modern Parable
                          by Alexander Calandra
                      Saturday Review, Dec 21, 1968.

Some time ago I received a call from a colleague who asked if I would
be the referee on the grading of an examination question. He was about
to give a student a zero for his answer to a physics question, while
the student claimed he should receive a perfect score and would if the
system were not set up against the student: The instructor and the
student agreed to submit this to an impartial arbiter, and I was
selected.

I went to my colleague's office and read the examination question:
"Show how it is possible to determine the height of a tall building
with the aid of a barometer."

The student had answered: "Take a barometer to the top of the
building, attach a long rope to it, lower the barometer to the street
and then bring it up, measuring the length of the rope. The length of
the rope is the height of the building."

I pointed out that the student really had a strong case for full
credit since he had answered the question completely and correctly. On
the other hand, if full credit was given, it could well contribute to
a high grade for the student in his physics course. A high grade is
supposed to certify competence in physics, but the answer did not
confirm this. I suggested that the student have another try at
answering the question I was not surprised that my colleague agreed,
but I was surprised that the student did.

I gave the student six minutes to answer the question with the warning
that the answer should show some knowledge of physics. At the end of
five minutes, he had not written anything. I asked if he wished to
give up, but he said no. He had many answers to this problem; he was
just thinking of the best one. I excused myself for interrupting him
and asked him to please go on. In the next minute he dashed off his
answer which read:

"Take the barometer to the top of the building and lean over the edge
of the roof. Drop that barometer, timing its fall with a stopwatch.
Then using the formula S = टatऑ, calculate the height of the building.

At this point I asked my colleague if he would give up. He conceded,
and I gave the student almost full credit.

In leaving my colleague's office, I recalled that the student had said
he had many other answers to the problem, so I asked him what they
were. "Oh yes," said the student. "There are a great many ways of
getting the height of a tall building with a barometer. For example,
you could take the barometer out on a sunny day and measure the height
of the barometer and the length of its shadow, and the length of the
shadow of the building and by the use of a simple proportion,
determine the height of the building."

"Fine," I asked. "And the others?"

"Yes," said the student. "There is a very basic measurement method
that you will like. In this method you take the barometer and begin to
walk up the stairs. As you climb the stairs, you mark off the length
of the barometer along the wa]l. You then count the number of marks,
and this will give you the height of the building in barometer units.
A very direct method."

"Of course, if you want a more sophisticated method, you can tie the
barometer to the end of a string, swing it as a pendulum, and
determine the value of `g' at the street level and at the top of the
building. From the difference of the two values of `g' the height of
the building can be calculated."

Finally, he concluded, there are many other ways of solving the
problem. "Probably the best," he said, "is to take the barometer to
the basement and knock on the superintendent's door. When the
superintendent answers, you speak to him as follows: "Mr.
Superintendent, here I have a fine barometer. If you tell me the
height of this building, I will give you this barometer."

At this point I asked the student if he really did know the
conventional answer to this question. He admitted that he did, said
that he was fed up with high school and college instructors trying to
teach him how to think, using the "scientific method," and to explore
the deep inner logic of the subject in a pedantic way, as is often
done in the new mathematics, rather than teaching him the structure of
the subject. With this in mind, he decided to revive scholasticism as
an academic lark to challenge the Sputnik-panicked classrooms of
America.

The article is by Alexander Calandra and appeared first in
"The Saturday Review" (December 21, 1968, p 60).
It is also in the collection "More Random Walks in Science" by
R.L.Weber, The Institute of Physics, 1982.

Calandra was born in 1911, started at Washington University (St. Louis) in
1950 as Associate Prof. of Physics.  B.S. from Brooklin College and Ph.D.
in statistics from New York Univ.  Consultant, tv teacher and has been AIP
regional counselor for Missouri.

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From: jdm#NoSpam.rheom.demon.co.uk (John Mitchell)

Bob Pease (Nat.Semi.) records the story of the Physics student who
got the following question in an exam:

"You are given an accurate barometer, how would you use it
to determine the height of a skyscraper ?"

1: He answered: "Go to the top floor, tie a long piece of string to the
barometer, let it down 'till it touches the ground and measure the
length of  the string".

The examiner wasn't satisfied, so they decided to interview the guy:

"Can you give us another method, one which demonstrates your knowledge
of Physics ?"

2: "Sure, go to the top floor, drop the barometer off, and measure how
long before it hits the ground......"

"Not, quite what we wanted, care to try again ?"

3: "Make a pendulum of the barometer, measure its period at the bottom,
then measure its period at the top......"

"..another try ?...."

4: "Measure the length of the barometer, then mount it vertically on the
ground on a sunny day and measure its shadow, measure the shadow of the
skyscraper....."

"....and again ?...."

5: "walk up the stairs and use the barometer as a ruler to measure the
height of the walls in the stairwells."

"...One more try ?"

6: "Find where the janitor lives, knock on his door and say 'Please, Mr
Janitor, if I give you this nice Barometer, will you tell me the height
of this building ?"

There are many more ways, for instance:

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From: eaobrien#NoSpam.ebi.ac.uk (Emmet O'Brien)

7: To which the less polite alternative is to threaten to wallop the
caretaker with the barometer unless they tell you how high the building is.

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From: Phil Gustafson <phil#NoSpam.rahul.net>
The just-released book, "Expert C Programming (Deep C Secrets)", Peter
van der Linden, SunSoft/Prentice-Hall, ISBN 0-13-177429-8, lists
twenty-one (21) more or less useful ways to measure the height of a
building with a barometer.

8: Use the barometer as a paperweight while examining the building plans.

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From: Mike <zeus#NoSpam.myth.demon.co.uk>
9: Sell the barometer and buy a tape measure.

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From: gt4495c#NoSpam.prism.gatech.edu (Giannhs)

10: Use a barometer to reflect a laser beam from the top and measure
the travel time.

11: Track the shadow of the building positioning a barometer on the
ground every hour.

12: Create an explosion on the top and measure the time for the pressure
depression indicated on the barometer.

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From: peter#NoSpam.cara.demon.co.uk (Peter Ceresole)

13: For fun, how about using sound; fire a starting pistol at the bottom,
time the difference of arrival at the top. About a second for the
Empire State building, and of course it'd have to be a damn great gun
to carry over the howl and screech of downtown Gotham. Also, the
detonation might get confused with the sounds of routine crack dealing
below.

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From: Adam Jones <Adam#NoSpam.yggdrasl.demon.co.uk>
14: Here's one no-one seems to have thought of :
1) Build a sandpit (full of sand, OK?) at the bottom of the building.
2) Rake the sand flat.
3) Drop the barometer from the top of the building into the sand.
4) Measure the average diameter of the crater thus created.
5) From the answer to (4), the mass of the barometer and the
   properties of the sand (viscosity?) calculate its impact speed
   and thus the height from which it was dropped.

Also has the advantage that you may get your barometer back intact if:
a) The building is small.
b) The sand is soft.
c) The barometer is light and strong.

P.S. Watch out for wind-affected drops hitting pedestrians from tall
     buildings...

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From: jjunging#NoSpam.sciborg.uwaterloo.ca (Yohaun)

15: 1) Borrow one of those fancy two channel digital oscilloscopes from
somebody's lab when they aren't looking.
2) Connect a microphone to each channel. Place one microphone on ground
level. Call it "A".
3) Place other microphone "B" at top of building, directly over the first
microphone. Note that you may need a lot of cable.
4) Place barometer as close to A as possible.
5) Set scope to trigger on channel A.
6) Whack barometer once with hammer or suitable object. The purpose of
this is to make a nice, sharp impulse.
7) Measure the difference in arrival time of the impulse in each channel.
This is how long it took the sound to travel to the top of the building.
The speed of sound is approximately 1 foot per millisecond under most
conditions, so we can find the distance travelled by the pulse and thus
the height of the building.

Now don't even get me started about using a microphone, an oscilloscope
and audible "clicks" to make an acoustical motion detector. :)

Except for the trivial method (2), there are other ways to use dropping
the barometer:

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From: nce#NoSpam.liverpool.ac.uk (Dr N.C. Eastmond)

16: Drop the barometer off the building onto someones head, killing them
outright. Wait for the next day's papers and read the part where is says "A
man (39) was killed yesterday when a scientist (26) dropped a barometer
from the top of an [x] foot building".

17: If it's a _tall_ building, one could drop the barometer, measure how much
its length had changed when it reached the bottom, work out the speed from
the relativistic dilation, and form that nd knwon gravitational acceleration
calculate the height..

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From: Gabriel Krabbe <satan#NoSpam.bofh.studfb.unibw-muenchen.de>
18: Actually, you don't have to drop it to use relativity.just hold it
parallel to your speed vector (as you rotate with the world) and measure
the length.  do this at the top and at the bottom of the building; at the
top, being further from the centre of the world, the speed is greater and
can be determined by the dilatation of the length of the barometer. from
there, it's easy to find out just how much further from the centre you are;
this figure being the height of the building.

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From: Sebastian_Vielhauer#NoSpam.public.uni-hamburg.de (Sebastian Vielhauer)

19:
1) Make sure your barometer contains alcohol[1].
2) Spill the alcohol over a heap of wood, paper and other inflammable
stuff in the cellar of the building in question.
3) Ignite.
4) Get out.
5) Listen to a local station on your radio.
6) If all works fine, you will hear a message like

"A fire broke out in the <actual height of building> feet tall <insert
building name> in <insert adress of building> ..."

7) There you are.
8) "And now the police asks for your cooperation in connection with
the fire in the <insert building name> today:
A young man carrying a broken barometer has been seen leaving the
building right before the fire was detected. Description as
follows:..."

DISCLAIMER: Don't try this at home. It's far too obvious.

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From: thweatt#NoSpam.prairie.NoDak.edu (Superdave the Wonderchemist)

20:
1) Measure the length of the barometer.
2) Borrow the scaffolding from the window washers.
3) Place the bottom of the barometer on the ground and make a
 pencil mark on the building at the top of the barometer.
4) Raise the scaffolding a bit to facilitate barometer and pencil
 manipulation.
5) Place the bottom of the barometer at the pencil mark on the
 building from step 3 and make a mark on the building at the top of the
 barometer.
6) Repeat steps 4 and 5 until you reach the top of the building.
 Be sure to count the pencil marks as you go.  If at the top of the
 building, you end up with the barometer sticking up above the building
 then you must follow the special steps noted later and add that to your
 answer.
7) Multiply the number of barometer lengths by the length of the
 barometer to get the building height.

*****SPECIAL STEPS NOTED HERE*****

        s1) Holding the end of the barometer at the top of the last full
barometer length mark, rotate the other end of the barometer until it is
in line with the top of the building.

        s2) Measure the angle between verticle and the barometer.

        s3) Take the cosine of that angle.

        s4) Take the answer to s4 and add that to the number of full
barometer lengths measured and multiply by the length of the barometer.

**********************************

Note: For best results, always hold the barometer vertically.

21: (Aneroid barometers only) Lie the barometer on its back on the ground.
Bounce a laser off the glass front and time how long that takes. Subtract
the thickness of the barometer.

22: (Mercury barometers only) Drain the mercury out and put it in a bowl.
Bounce a laser off the surface of the mercury, etc. etc. etc. Again,
subtract the height of the surface.

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From: jjhyvone#NoSpam.cc.hut.fi (Jorkki Hyvonen)

23:
1. Take the glass tube out of the barometer.
2. Attach one end of the glass tube to the top of the building,
   so that the other end points directly downwards.
3. Measure the time difference between step 2. and the other end
   of the glass tube touching the ground with a high-precision
   timing device.
4. Calculate the height of the building using the known viscosity
   of glass.

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From: mike#NoSpam.econym.demon.co.uk (Mike Williams)

24: Run a transparent tube up the side of the building. Fill it with water,
seal the top and open the bottom inside a reservoir of water. I.e.
effectively make a water barometer - just like a mercury barometer, but
with water instead of the mercury.

Wait for a day when the water level matches the height of the building, and
read off the atmospheric pressure on your original barometer. Calculate the
height of water that this atmospheric pressure can support.

Unless your building is pretty close to 10 meters high, you may have to wait
a long time.


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From: a.s.haines#NoSpam.davav.demon.co.uk (Tony Haines)

25 :Alternatively you could use fluids with different densities until you
found one which was the height of the building.
Remember you have to seal the top of the tube, and remove all air from it
for an accurate reading.

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From: Adam Price <ami#NoSpam.gladstone.uoregon.edu>
26:
1)  Beat on the foundation o the building, using the barometer, until the
    building comes crashing down.
2)  Any sizeable pieces should be pulverized into pebbles and dust.
3)  The height of the building should be zero.  If not, repeat step 2.

This method may require more than one barometer.  Make sure that you buy
the same kind, for a more scientific study.

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From: a.s.haines#NoSpam.davav.demon.co.uk (Tony Haines)

27: Remove the glass pipe from the barometer. Attach one end to an arrow and
the other to the top of the building. Evenly heat up the middle of the tube
to red heat and fire the arrow at the ground with a bow.
Measure the width of the extended glass tube at several points and average.
Knowing the original width, work out the distance travelled by the arrow.
Measure the distance of the arrow from the base of the building.
Use trigonometry to calculate the height of the building.

28: As a quick check, using the mercury you removed from the barometer:
Measure the temperature of the mercury at the top of the building, and put
it in a perfectly insulating container. Drop it off the building and measure
the temperature of the mercury after it has landed. Calculate the energy
gained and therefore the height of the building.

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From: Frank_Hollis-1#NoSpam.sbphrd.com (Triple Quadrophenic)

29: Sellotape a tuning fork to the barometer and whack it just before you
throw the barometer off the building. Measure the doppler shift at the
moment of impact to get its velocity and, hence, the height of the
building.

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From: borism#NoSpam.interlog.com (Boris Mohar)

30: Wait untill Hell freezes over.  Extrude the mercury into a wire.
Use wire to measure the building.

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From: Michael Warner <warner#NoSpam.wsunix.wsu.edu>
31:
1) Set the barometer a measured distance from the building, ensuring a
clear line-of-sight exists between it and both the top and base of the
building.
2) Buy, borrow or steal a theodolite.
3) Measure the angles (from horizontal) from the base and the top of the
building to the barometer.
4) Diagram the distances and angles at a 1:1 scale on a really big piece
of paper.
5) Lay out the diagram on a convenient empty parking lot.
6) Pace off the distance in question.

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From: Tracy Sweat <sweat#NoSpam.mmc1001.lfwc.lockheed.com>
32: Tie a copper barometer to a copper wire of known diameter.  Lower
barometer from roof until it just rests on the ground.  Apply a
known voltage between the barometer and the end of the wire at root
level.  Measure current flowing between these two points and divide
this number into the voltage, giving you the resistance of the
barometer/wire combination.  Subtract the barometer's resistance and
use the resistance of the wire to determine its length.  Add back in
the height of the barometer.

Also, I'd like to see some answers formulated using a bungee jumping
barometer.  Possibly using the thickness of the bungee cord with the
barometer at ground level, maybe using the barometer weight necessary
to stretch the bungee cord all the way to the ground, etc...

Every meteorological observation site should have at least one
bungee jumping barometer.  At least.

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From: spb#NoSpam.sv1.smb.man.ac.uk (Stephen Bates)

33: Read the inscription on the plaque on the back of the barometer,
which says,
"This barometer is the property of the <number> metres high
<name> building. Please do not remove." [1]

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From: theise#NoSpam.netins.net (Ted Heise)

34: Okay, one more idea which was given to me by my graduate research
advisor.  Suspend the barometer from the top of the building with
a wire.  Remove the barometer and measure the change in length of
the wire.  With the weight of the barometer and Young's modulus
for the wire, one can calculate the length.

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From: fc3a501#NoSpam.AMRISC04.math.uni-hamburg.de (Hauke Reddmann)

35:
1. Look for Godzilla.
2. Wait until he stand before the building.
3. Poke him with the barometer in the,eh,backside.
4. YEOWCH!SLAM!PLOFF!
5. Now that the house is overturned (I think you call
it a "flat" :-) , the task has turned into measuring
the length, which is much more convenient.

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From: dehall#NoSpam.hellcat.ecn.uoknor.edu (David Hall)

And then there is trigonometry, gravity force differentials, laser
rangefinding.....and the list goes on.

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From: zara.baxter#NoSpam.jcu.edu.au (Silky)


36: Heres my silly [1] attempt at answering the question of how tall a
building is, using a barometer. One can easily find the height of a
building, simply by finding its top, and working from there.

Find a person with vertigo. (fear of heights)

Give them the barometer.

Tell them to put it on top of the building.

we have several measurements, which can then be cross referenced to
determine the height of the building.

1. Measure the volume of the sound caused by the persons knees
knocking together. The taller the building, the louder the knocking.
This should be standardised first, by testing  the sound produced for
buildings of known height.

2. attach electrodes to your subject. measure the EEG reading at the
moment immediately after placing the barometer on top of the building.
(ie, the moment they look down) amplitude of waves indicates anxiety.
Again, standardisation should be done to ensure accuracy. [2]

3. Measure the depth of the crater created when they land, after
having seen how high they were when they put the barometer on top of
the building.

Silky...in an attempt to be as perverse as possible. [3]

[1] well everyone else has.
[2] a flat line is the exception to the rule here.
[3] no, not pervert.

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From: "Chester, Justin" <ChesterJ#NoSpam.jntf.osd.mil>
37: Take the barometer to the top of the building.  At the base of the
building put a trigger that when the barometer is dropped onto it, it emits
a loud, high frequency noise.  Start stopwatch once the trigger is
activated.  Put an audiometer at the top of the building to stop the
stopwatch when the audiometer is activated (at least activated higher than
the backround noise already present).  Determine from there the speed of
sound (for that particular day) and therefore determine the top of the
building.

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From: Filip Larsen <filip#NoSpam.post4.tele.dk>
38:I think the best procedure must be:
a) Locate a university where a physics exam or test is about to begin.

b) Locate a student waiting for this test.

b) Impose as a physics professor (wear silly clothes, talk funny,
mess up your hair, etc) and lure the student into a separate room.

c) Show the barameter you brought with you to the student and ask him
the following question: "You are given an accurate barometer, how would
you use it to determine the height of a skyscraper ?". Try to squeeze as
many answer out of him as possible.

d) If you didn't get any useful answers from c), then try to post the
question on Internet, preferably in a news group or on a web-page.

39: Find a barometer with heights of local buildings on it
Go to all the local gift shops. Look for a fancy souvenir barometer,
the kind which shows important local landmarks. Find one which shows
the heights of local buildings and considers this building important
enough to be listed. Use this barometer.

40: Drop the barometer on the roof and on the ground
Hold the barometer straight in front of you and drop it. Measure, very
carefully, how long it takes to hit the ground. Go up on the roof and
hold the barometer in the same position. Drop it and measure, again
very carefully, how long it takes to hit the roof. Since gravity falls
off as the square of the distance from the centre of the planet, you
can use the difference in times to calculate the height of the
building relative to the distance from the base of the building to the
centre of the planet. The local library can provide you with the
distance to the centre of the planet in the required units.

Note: The ratio of the times is the same as the ratio of the distances
from the drop points to the centre of the planet.

41:  Drop (and shatter) the mercury barometer at the base of the buidling
on a windless day. Measure the increase in the mercury vapour
concentration at the top of the building. Solve the diffusion equation
to determine the distance from the shattered barometer to the top of
the building.

42: Place the barometer on the ground floor of the building. Seal all the
building's doors and windows. Fill the building with water. Read the
pressure measurement from the barometer. This gives the weight of a column
of water the same height as the building. Use this and the ratio of the
density of mercury to the density of water to calculate the height of the
building.

Note: It is common courtesy to evacuate the building before using this
technique.

43: If you have access to an airless world, take the building there. Throw
the barometer horizontally off the building. If the barometer hits the
ground, retrieve it and try again, throwing harder. The objective is to
throw it hard enough to achieve a circular orbit. Once the barometer is in
orbit around the planet, you can measure the period of the orbit. Compare
this with the period of the orbit when you throw the barometer from the
base of the building. Use this ratio and Kepler's laws to determine the
height of the building (relative to the radius of the planet).

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From: Andy Johnson <prjohnson#NoSpam.utahlinx.com>
44:
(1) Get a barometer that uses a dial for the reading.
(2) Open the barometer and remove the mechanisim to allow the hand to
    swing freely.
(3) Dig a hole and climb in, hold the barometer at ground level and
    point it at the top of the building.
(4) Use the barometer as a sextant and measure the angle of inclination,
    then pace off the distance to the building and use trig to calculate
    the height of the building.

45:
(1) Get an assistant, two synchronized clocks, some gas and a match.
(2) Assistant remains at the base of the building and you go to the top.
(3) Assistant covers barometer with gas and at a predetermined time,
    lights barometer with match.
(4) You time when you see the flash, and calculate the distance given
    the speed of light.

46:
(1) Go to the top of the building.
(2) Drop barometer off building and start timer.
(3) Stop timer when you hear barometer hit the ground
(4) Solve for height taking into account gravatational acceleration and
    the speed of sound.

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From: Filip Janssen <janssf1#NoSpam.sh.bel.alcatel.be>
47:
Go to the barometers manufacturer and tell him you want a barometer as high
as the building in question.  the manufacturer will say something like:
"what the fuck do you need a XXX feet long barometer for"

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From: "Ali Tayarani" <eldiablo#NoSpam.idt.net>
48:
Tie barometer to a yardstick.  Stack many yardsticks together(head to head).
Measure inches.

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From: CroutonGuy <CroutonGuy#NoSpam.centuryinter.net>
49:
Assume that the barometer has a rectangular shape.  It therefore must have
a corner.  If we also assume that we are finding the height of the building
for a professor on a test, then we must also assume that he has an answer
already prepared to compare to the students answers.  Since the entire
class has to solve this question, every student has a barometer.  Steal
some other students barometers, sell them for a ski mask.  Wear the ski
mask to the professor's house, and threaten him with the pointy corner of
the barometer.  Force him to give the correct answer, then use the correct
answer.

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From: Tom Bach <tbach#NoSpam.cyberus.ca>
50:
1. Weigh the barometer at the ground floor of the building (W).
2. Take the elevator to the roof and weigh the barometer a second time (w).

3. The height of the building H is given by
   H=R*(sqrt(W/w) -1)        R~=6378140 m.

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From: Stuart.Vessey#NoSpam.gstt.sthames.nhs.uk

51:
Take barometer & hammer very flat & thin.
Construct large box from barometer & place over building.
From Schroedingers principle, we can now say that the state of the is unknown (so any answer will be correct!)


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From: "Stan The Man ." <stan_the_man2#NoSpam.hotmail.com>

52:
1)Find mass of the barometer 2)weigh the barometer on the ground 3)weigh the barometer on the roof 4)use F/M=g to find two different gs 5)use g=GMm/r^2 to find two radii 6)subtract


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From: "Dennis Casto" <castovicini#NoSpam.hotmail.com>

53:
Drink the Mercury. When you die you'll go to heaven where all things are revealed including the height of the building.


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From: "Mike Phelan" <krakedhalo#NoSpam.hotmail.com>

54:
Gather 100 friends. Have each of them guess at the height of the building 100 times. This gives a sample size of 10000. Calculate your sample mean Xn and sample variance s^2. Since the sample size is large, s^2 approximates the true variance. Use Xn -Z(s^2)/100 < height < Xn + Z(s^2)/100 to construct a 1-alpha probability interval for the height of the building. Alternatively, have your 100 friends guess at the height n times. Calculate the sample mean each time. As n goes to infinity, the various sample means follow a normal distribution with mu = true height of building. Either way, use the beat your 100 friends over the head with the barometer so your professor cannot claim you had outside help.


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From: Rick <tinkety_tonk#NoSpam.yahoo.com>

55:
A rather advanced solution would be attaching a medium powered transmitter within the barometer. Now measure the received power in a dipole antenna with a micro-voltmeter, when the barometer is on the top of building. Now take the barometer to ground level and then measure the received power. The difference in receiving power will indicate the loss due to attenuation which is proportional to height of the building.


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From: Rick <tinkety_tonk#NoSpam.yahoo.com>

56:
Take the barometer to the wizard of Oz. He will put some courage into it as well as some brains. Now ask the barometer to jump from the top of building. If you give a stop-watch to that barometer it will easity find the height of building.


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From: Rick <tinkety_tonk#NoSpam.yahoo.com>

57:
This solution works in zero gravity conditions, and assuming that the barometer and the building have equal weight. First perform pirouette like action as a ballet dancer without holding anything for 10 sec. and note the number of rotations. Next try it while holding a barometer with outstreched arms, note the rotations in 10 sec. Finally hold the building and perform the same thing. The moment of inertia depends on the radius. I think this much clue is enough, you can solve the rest!


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From: "Matthew Byrne" <mjw_byrne#NoSpam.hotmail.com>

58:
Go to top of building without barometer and with accurate weighing scales. Weigh self. Then place barometer at the base of the building, go back to the top and weigh self again. The increase in weight due to the gravitational attraction of the barometer can be used (knowing the mass of the barometer) to calculate the height of the building.


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From: Forkazoo2#NoSpam.aol.com

59:
Mass the barometer. Ideally, the building has an elevator. If not, you can use the stairs, but it becomes more difficult to be accurate. Use the barometer in a lewd street comedy show, so that you can earn a few dollars to buy a scale, and a video camera. (Or, if you are very good, a stop watch, and just paper and pencil.) Go to the ground floor of the building, and get in the evelator. Start recording the scale with the video camera. If the scale does not read 0, you can use this as a clibration factor. Put the barometer on the scale. Take the elevator to the top floor (stopping at each along the way). (If the top floor is not directly accessible, go outside, look at the building, and determine which floor is half way up to the top. Multiply final answer by two) Since we stopped at each floor along the way, we have a pretty good idea what acceleration due to gravity is at various points along the elevator ride We can interpolate the spaces between sample points. Now, since initial velocity was zero, and we know the acceleration at every point in the trip (displayed weight = m*(acceleration due to gravity + acceleration due to elevator)), we can go frame by frame along the recorded video tape, and numerically integrate the acceleration to get velocity, and then position at each point in time. The resulting position at the end of the tape is the height of the building. Return scale to store to get money back. (Which I actually did for a physics project one time... We kept the scale in the packaging for the entire experiment. My two female lab partners and I then went back to the store, and said it didn't match our bathroom.)


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From: "Stephie Lou"
 

60:
Extract the mercury from the barometer. Take an accurate mass measurement of the mercury sample. Take it to your neighborhood atomic pile. Bombard the mercury with neutrons in the highest flux region of the core for, oh, about a week. The mercury is now quite radioactive. Determine exactly how radioactive using the common activation equation. Remove the mercury from the core, and mount the mercury sample at the top of the building. (You may wish to do this remotely.....) Now use a well-calibrated radiation detector to determine the gamma ray dose rate at the bottom of the building. Use the normal radiation dose equations (with appropriate buildup factors for building material and surroundings) to determine the height of the building. (As we all know, radiation dose from a point source falls off as the inverse square of the distance.) Do not forget to correct for the decay of the radiomercury atoms during the time it takes to perform the experiment.


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From: "Douglas Grimm" <hopehubris#NoSpam.mail.geocities.com>
61: Tie a long piece of string to the barometer. Hold one end of the
string from the top of the building, so that the end of the barometer
barely clears the ground. Give the barometer a small displacement
and time its period as a compound pendulum.

62: Smash the barometer on the roof of the building and time how
long it takes for the mercury to drip down the wall of the building to
the ground. Use the known viscosity of mercury to find the velocity.

63: Throw the barometer horizontally off the building with a known
velocity (calibrate your throwing ability by timing and measuring
barometer throws on the ground). Use projectile motion to find the
height of the building once the distance the barometer lands from
the building is found.

64: Find a small, very efficient, very light electric motor. Weigh the
barometer. Use the motor to carry the barometer up the building.
Using a voltmeter and ammeter, calculate the work done by the
motor, and thus the gravitational potential difference between the top
and bottom of the building. Knowing g, find the height.

65: Go to the basement. Find a part of the basement such that
directly above you is solid brick until you reach the roof. Throw the
barometer at the ceiling of the basement, which is the floor of the
building. The barometer will most likely bounce off the floor. Repeat
n times, where n is a very large number. In a few trials, the
barometer will tunnel through the potential field of the bricks, and
appear on the top of the building. Calculate the percentage of trials
for which the barometer tunnels. Use the quantum tunneling
equation to calculate the length of the barrier, and thus the height of
the building. Note: this effect can be calibrated properly by finding
the likelyhood of the barometer tunneling through one brick.

66: Attach a copper wire to the top of the building, and attach the
other end to the ground. Smash the barometer and use one of the
shards of glass to cut the wire halfway up the building and
place an ammeter in series with the wire. Knowing the current
through the wire and the resistivity of copper, the potential
difference between the top of the building and the bottom of the
building can be found. This will be a gravitational potential
difference, not an electrical one, but the electrons don't know that.
Thus, since g is known, the height of the building can be found.

67: Find a large wooden rod a bit longer than the building is high.
Wrap an insulated copper wire around this rod at a uniform turn
density. Make the coil stop at the top and bottom of the building.
Run alternating current through the coil, measure current and
voltage, and determine the inductance of the coil. Place the
barometer in series with the coil so the resistance of the circuit is
enough to stop the wires from melting. With the inductance of the
coil and its turns per unit length and radius, the length of the
coil, and thus the height of the building, can be found.

68: Drop the barometer off the top of the building and measure the
radius of the resulting puddle of mercury.

69: Using a device that can propel an object at a known velocity
(such as a baseball pitching machine or a rail gun), find the escape
velocity of the barometer from the ground, after first having tied a
string to the barometer so it can be retrieved from deep space.
Repeat on the top of the building. The difference in escape velocity
energies gives the gravitational potential difference between the
ground and the roof, thus yielding the height.

70: Using the aforementioned pitching machine or rail gun, find the
velocity at which the barometer needs to be projected to reach the
roof from the ground.

71: Make a small hole in the barometer through which mercury drips
at a constant rate. Time this rate at the ground. Place the barometer
on the roof and observe the drip rate from the ground with
binoculars. The drip rate will be dilated, by general relativity, by a
factor which will give the difference in the curvature of space at the
bottom and top of the building. Knowing the mass and radius of the
earth and so on, the height of the building can be found.

72: THIS METHOD USES MORE THAN ONE BAROMETER: Pack
as many barometers as possible into the building until it undergoes
gravitational collapse and becomes a black hole. Knowing the
number of barometers used, the mass of this hole can be
calculated, and the Schwarzchild radius of the hole is thus half the
height of the building.

73: Find a barometer that uses a liquid with no surface tension
whatsoever (superfluid helium?). Break the barometer and spread
the liquid evenly over the surface of the building. Measure the depth
of the resulting liquid film. Knowing the volume of the barometer, this
gives the surface area of the building, which will give its height,
if its width and depth are known.

74: Stand on the roof of the building. Throw the barometer to a point
exactly on the horizon. Measure the distance from the bottom of the
building to the barometer. This gives the horizon distance at the top
of the building, thus giving its height above the ground.

75: Make a small hole in the barometer so mercury drips out at a
constant rate. Place the barometer so that it is dripping off the
roof onto the ground. Measure the time between a drop being
released from the barometer and the drop hitting the ground. Repeat
the measurement when moving towards the ground at a known
velocity. The time between a drop being released and a drop hitting
the ground will change. Using the Lorentz transformation equations
and taking the top of the tower as x = 0, the position of the ground
can be found. This will yield the height of the tower.

76: Find a steel cable. Attach it to the barometer and use the
barometer as a physical pendulum to measure g. Then attach the
building to the cable (after having remove it from its foundations
and attaching the cable to a crane of some sort), and using the
building as a physical pendulum, and knowing g, measure its
moment of inertia. This will give the dimensions of the building and
so on.

77: Use a barometer containing sulfuric acid. Break the barometer
on the roof of the building and time how long it takes the acid to eat
its way down to the ground.

78: Measure the volume of the barometer at the bottom and top of
the building. By knowing the coefficient of thermal expansion of
glass, the temperature difference between the top and bottom can
be calculated. Refer this to known data of atmospheric temperature
as a function of height.

79: Every time somebody walks into or out of the building, stab them
with the sharpened end of the barometer (after having sharpened it,
of course). Word of the 'Barometer Murderer' will eventually reach
the building's owner, who will of course be forced to sell the building.
The real estate advertisement should give the height of the building.

80: Knowing the density, width and length of the building, rip the
building from its foundations and place it on top of the barometer,
giving it a pressure equal to the building's weight divided by the
measurement area of the barometer. Thus the weight, and so the
height, of the building can be found.

81: Find the architect who designed the building, crack the
(mercury) barometer over his coffee, watch him die when he drinks
it, then steal the building's specifications, including height.

82: THIS ALSO REQUIRES MORE THAN ONE BAROMETER:
knowing Young's Modulus for brick, place barometers on the roof
until the roof is lowered by one barometer length. This change in the
height of the building under a known stress and Young's Modulus will
give the height of the building.

83: Place a cat on top of the building. Prod it with the barometer so
that it falls off the roof. See whether the cat dies when it hits the
ground. Repeat n times, where n>>{a large number}. Refer to Dr
Karl Kruszelnicki's paper on the probability of a cat dying when
falling from a certain height.

84: AGAIN, MORE THAN ONE BAROMETER: place as many
barometers in the building as will fit. This gives the volume, thus the
height, if other dimensions are known.

85: Use a machine (such as the aforementioned baseball pitching
machine or rail gun) that can hurl the barometer down from the
ground into a hole in the ground at a velocity that is only known to
within a certain tolerance. Find the smallest uncertainty in velocity,
and thus momentum, such that the barometer appears on top of the
building. Use Heisenburg's position-momentum uncertainty
relationship to find the height of the building.

86: Tie a string to the barometer and hang it as a plumb bob. The
string will be slightly deflected from the vertical by the gravitational
effect of the building. This gives the mass of the building, etc.

87: Find at what velocity you must move upwards or downwards past
the building such that the building is contracted to the same length
as the barometer. Find gamma for this velocity, multiply by the
length of the barometer.

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From: Ephram Cohen <ephram#NoSpam.ear.Psych.Berkeley.EDU>
88:
Measure the color of the barometer.
Drop the barometer off the building.
Measure color doppler at the moment of impact.
From there extrapolate the velocity at impact.
Finally use the gravity exuation to figure the height of the building.

89:
Drop barometer
Measure radius of the debris field
This should be a function of velocity hence the height of the building.

90:
Place barometer in such a way that a rock will roll out and push whoever
grabs the barometer off the building.
Wait for newspaper reports about the buildings height.

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From: "Neil Wells" <wells#NoSpam.vision.com>

91: Mount the barometer to top edge of building.  Use a projectile weapon
from a fixed location to shoot it.  Using ballistic curve and weapon specs,
calculate height of building.

92: Using barometer as a pointer, count the number of floors in building,
and calculate the total height using the standard height of a storey of
that type of building.  Or count bricks if you need to.

93: Measure the base of the building in barometer lengths.  Measure the
angle to the base corner to the diagonally opposite top corner.  Use Trig
to calculate unknown height of triangle.

94: Sell the barometer, put the money in an fee-free long term account.
Put yourself in suspended annimation until the compound-interest on your
money makes you the richest man on earth, then use this money to capitalize
your plans for world domination.  Then when you are the Almighty Supreme
Master of the Entire Universe, order one of your lackeys to report back you
with the height of that building.  Or you could have the stupid thing
knocked down if you wanted to ...

95: Get some electronic parts, and a block of plasticine, stick the parts,
and some coiled wires into the plasticine, and mount the barometer to this.
Put a sticker on the plasticine, that has, "C4", or "SEMTEX", written in
clear, signal yellow lettering.
  Go to your local airport and highjack an aircraft, explaining that you
will detonate this device unless the pilot does exactly as told, (you can
embroider this performance any way you wish ...  eg.  Wear a towel on your
head and see if you can start a Middle-Eastern war.  Or maybe you could
have some more selfish demands like $50 000 000 in small unmarked bills, or
maybe demand that Roseanne Barr, be forced to give up acting, you know -
whatever you like).
  Anyway, where was I?  So you instruct the pilot to fly directly past the
building at roof level, and as you pass it, simply look at the altimeter.
Ask the pilot if there are any calibration ajustments and then work out the
building height.
  After this you can tell everybody the truth about the barometer and the
bomb, and you can have a jolly good laugh about it and maybe get together
afterwards for a social drink, or something.

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From: "William Garber" <william.garber#NoSpam.worldnet.att.net>
96: Comedian
Ask a comedian.  apparently comedians are the worlds foremost experts on
using barometers to measure heights.  Actually I would really like to know
how to measure the height of a building with a rectal thermometer.

97: Businessman
Create a small company selling barometers.  Sell stock in the company.
Advertise the many benefits of barometers on daytime TV.  Everybody needs a
barometer.  They are the best thing since sliced bread.  They chop.  They
slice.  They dice.  Get the ginsu barometer.  Now only $19.99.  You get the
added bumper sticker that says "my parents went to Florida and all I got
was this lousy barometer".
Diversify your product by producing a full line of models, the economy
barometer, the standard barometer and the super-duper-extra-deluxe
barometer with vernier caliper and laser scope for high precision
measurements.
Initiate a telemarketing program that calls people late at night asking
them to buy barometers.
Bribe all the physics professors at the university to ask thier students
this stupid question on their exams.  When the stock goes up for sale make
a million dollars profit.  Hire a lobbyist.  Bribe the governor to put
questions about barometers on high school regents exams.  Then create a
contest to see who can find the height of a building using a barometer.
The winner gets a million bucks.  Of course no one really wins, but you get
the answer for free.  Or you could conduct a market survey to measure the
demand for barometers, and use this to measure the approximate height
subject to market fluctuations.

98: Physicist
Get some poor forlorn overworked repressed suffering graduate student to
solve this problem for you.
If he gets the wrong answer threaten to fire him.  Of course you already
know the answer.
This was just for fun.
Then ask your undergraduates the question on an exam.  Somehow none of them
get the right answer.
Initiate a program to measure the height of the building from outer space
somehow mysteriously using the barometer.  Send the experiment on a
space-shuttle research mission.  Put it on your web-site and resume.

99: Engineer
It is perfectly obvious.  Measure the height of the barometer.  Get a
surveying telescope.  Form a triangle such that the top of the building and
the top of the barometer line up as seen in the telescope.  Then measure
the distances along the base of the triangle and compute the ratio.  (Of
course this doesn't work but then ....... back to the drawing board).

100: Anthropologist
Move to a prehistoric jungle society of pygmies who live in grass huts.
They are so short that you can measure the height of thier "scyscraper"
directly.  Barometers did not exist in prehistoric times.

101: Psychiatrist
Thinks to himself:  This patient is extremely frustrated.  I will charge
him extra.
Says to patient:  How long have you been having this recurring fantasy
about the barometer. I believe you are obsessed with it.

102: Anarchist
Dye your hair blue and throw the barometer at the building.
how the fuck can an anarchist measure anything?

103: Doctor
Doctors use manometers all the time.
Find a patient with fear of heights.  Use the barometer to measure the
patient's blood pressure at the bottom of the building.  Stick his head out
of the window at the top of the building and measure his blood pressure
again.  Compute the height from the ratio of blood pressures.

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From: Marco Bernardini <webmaster#NoSpam.taggiasca.com>
104: Dry method
a) buy a lot of dry sand (e.g. the whole Southern Lybia, oil wells excluded)
b) use the barometer as a shovel
c) cover the building with a perfect cone of sand, avoiding windy days
d) measure the area covered by the sand, obtaining diameter of the cone base
e) knowing the natural slope of the sand you can easily obtain the height
of the building

105: Wet method (requires a lot of barometers of many types)
a) use the barometer as a shovel
b) dig a big hole (bigger than the bulding)
c) use a barometer (better the type mounted on a wood tablet) as a trowel
and cover hole walls with concrete until you have a waterproof basin
d) buy as many water barometers as you can
e) remove water from water barometers and put it into the basin
f) seal all doors and windows of the building with duct tape
g) carefully put the building into the basin
h) measure the volume of water moved by the building

106: Amazon (not the bookshop!) method
a) remove the glass pipe from a barometer and open both ends
b) tie a light rope to the tail of an arrow
c) put the arrow into the glass pipe
d) go on the top of building
e) blow the arrow into the nearest tree
f) measure the rope
g) solve the triangle formed by the rope and the building

106b) Another Amazon method - don't require rope but a stopwatch
a) remove the glass pipe from a barometer and open both ends
b) put an arrow into the glass pipe
c) hit a pedestrian
d) start the stopwatch
e) stop the stopwatch when you hear the howl
f) multiply time x sound speed
This must be repeated many times because reaction time of subjects may vary.
In any case the last method has the advantage that you can verify your
results in a easy way: if a M-16 bullet shooted by the police has x energy
when launched, and y energy when it hit you, you can (well, ballistic
experts can) know the distance between the gun and the hole in your head,
thus measures can be compared.

107: Internet method
a) ask everybody on the Net to submit you a solution
b) print every message (remember to number the pages!)
c) put the pile of paper aside the building until you reach the top
d) use the barometer as paperweight
e) multiply the number of pages for the thickness of the paper

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From: kal-el#NoSpam.krypton.rain.com (Leonard Erickson)

108: Remove mercury from barometer. Place drop of mercury so it closes a
circuit between two parallel non-mercury-wettable conductors at a known
potential difference. Measure speed & direction of motion of droplet due
to JxB forces. Rotate setup about a vertical axis until maximum speed is
found. This gives the direction & magnitude of the vertical component of
the local geomagnetic field.

Repeat at top of building.

Compare differences to know characteristics of the geomagnetic field.
This will give height of building.

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From: Ralph Owens <RalphO#NoSpam.concur.com>
109 :Well, if one drilled a small hole in a the bottom of the barometer,
one could establish the rate at which the mercury drips out of the
barometer.  Then one could attach a small electric motor to the top of the
building.  It could raise the barometer at a known rate.  Using the amount
of missing mercury, one could calculate the time it took to raise the
barometer to the roof.  Ergo, the height of the building is now known_

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From: "Anthony Coulter" <c17gmaster#NoSpam.earthlink.net>
110. Drink the mercury. If there's an afterlife, ask God how tall the
building was. If there isn't an afterlife, who cares that you don't know
the height of the building?

111. Set the barometer in the middle of the building. Don't look at it as
its wave function expands. When its wave function encompasses the entire
building, solve Schroedinger's equations.

112. Find a flammable barometer. Burn it and measure the time it takes for
the smoke to reach the top of the building.

113. Give it to an MIT student and tell him to transform it into a robotic
barometer specially designed to measure the height of buildings.

114. Tie the barometer to a string. Swing it in front of the architect of
the building while muttering, "You are getting very sleepy. When I snap my
fingers, you will tell me the height of the building."

115. Find a spot on the ground with a known value for hardness. From the
top of the building, throw the barometer down to this spot. (You could also
throw from the ground, but you would have to throw harder.) Repeat until
the barometer bounces up to the top of the building. Measure the force of
your throw and calculate the height of the building.

116. Find a barometer the size of the building. Measure the barometer.

117. Weld barometers to the top of the building until they reach the
moon. The building is approximately a quarter of a million miles tall.

118. Take the current air pressure and divide by zero. Your barometer (and
your test paper) will burst into flames to prevent a violation of
mathematical law. As the professor finds another copy of the test to give
you, sneak into his desk and find the answer key.

119. Heisenberg's Principle of Aesthetics: Measure the color of the
building so precisely that you cannot measure its size. With that done, any
guess is as good as the real answer.

120. Set the building on the barometer. Knowing the density, length, and
width of the building as well as Young's Modulus for the barometer,
calculate the height.

121. Take the volume of the building and divide by its width and
length. When you're done, hold the barometer in the air to signal to the
professor that you are finished with your test.

122. Create your own system of measurement. The unit of length will be the
"building." The building in question is precisely one building tall. When
asked what the barometer was used for, state that it was around for moral
support.

123. Hold the barometer between the index finger and thumb on your left
hand. Hop twice on each foot before breaking out into disco. This is the
rain dance for a certain Native American tribe. When the rain falls, choose
a drop and measure its velocity at the top of the building and its velocity
when it reaches the bottom of the building. Subtract the former value from
the latter, then apply this into the gravity/acceleration formula.

124. Set a tape measure at the bottom of the building. Tie a rope to one
end, string it (the rope) up around a pulley on the top of the building. At
the other end of the rope, affix the barometer as a counterweight. Let it
loose as the weight of the barometer pulls the tape measure to the top of
the building. Go to the bottom and read the tape measure.

125. Set a laser at the top of the building. Fire the laser to the ground
and have it reflect off the barometer. Then, suddenly rotate the barometer
such that the laser is firing at the building. When the building vaporizes,
its height should be zero. You may wish to set the laser on the ground,
though, so you can use it again when you measure the next building.

126. Briskly rub the barometer with a silk handkerchief. Hammer an iron
spike into the ground at the base of the building. Hold the barometer
directly over the spike for one minute, recording any electric
sparks. Repeat many times, and then use the probability of an electric arc
to calculate the distance between the barometer and the grounding wire,
which is also the height of the building.

127. (Works only for underwater buildings). Find a barometer that uses a
liquid lighter than water. Hold it at the base of the building and let
go. Time it as it floats past the top of the building. Calculate the
height.

128. (Only works for buildings in environments with negligible air and
gravity, i.e. space). Move the barometer at a steady speed along the height
of the building while timing it. As every good student knows, d=rt.

129. Use the barometer to measure the density of a pool of liquid. Weigh
the building and drop it into the liquid. Time the building as it sinks
into the liquid. Calculate the height.

130. Hit the barometer onto a piece of flint. Start a small fire. When the
fire alarms ring, the building is evacuated. Extinguish the fire, pull out
a tape measure, and measure the building without anybody standing around to
see that you didn't really use the barometer.

131. Give the barometer to your younger sibling, who will run outside to
play with it. Now that you have peace and quiet, do some internet research
to find the height of the building.

132. (Omega must be greater than one and the cosmological constant must be
less than one for this next suggestion to work) Allow the barometer to come
into contact with an anti-barometer. The explosion should rip the building
off its foundation and send it into deep space. Wait until the gravity of
the universe causes it to collapse on itself. Since the cosmological
constant is less than one, the universe should curl in on itself. When the
universe's diameter is small enough for the building's top and bottom to
meet, measure the universe's diameter and multiply by pi, assuming that the
space-time continuum is perfectly spherical.

physics
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From: "Guy Raz" <Guyraz#NoSpam.wisemail.weizmann.ac.il>

133: Walk to a comfortable distance from the building. Place the barometer on the ground and sit on it to rest your feet. Now count the number of stories in the building and multiply it by about 3 meters (10 feet).


physics
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From: "Rinaldo Zucca" <rz#NoSpam.cms.tuwien.ac.at>

134: Take a barometer to the top of the building, attach a long rope to it, lower the barometer to the street and then mark the point where it is. Bring it up and drop it. Due to the Coriolis force, the barometer will not fall in the same point as before, but in another one, in westward direction. The distance between these two points is univocally determined by the height of the building (and vice versa). That's it!


physics
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From: "Randall D. Wald" <randy#NoSpam.rwald.com>

135: Here's another way: Tie a string to the barometer. Take the barometer to the four corners of the building's roof, and use it as a plumb bob. Use the difference in angles at the corners to find the distance from the roof to the center of the Earth, based on the Earth's curvature. Subtract the known radius of the Earth to get the building's height.


physics
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From: "Agabi E. Oshiorenoya" <osaagi02#NoSpam.student.umu.se>

136:
Instruments: A barometer, an anemometer, a a lead mass >=40kg(pointed) and
a stop watch, a set of flaps

Just drop this lead mass and mark where this falls. Draw a circle of
infinite radius around this spot. Get a lab-view program and do real time
data acquisition of wind-speed readings from top and bottom of this
building. Drop the Barometer with the set of flaps attached to it to induce
drag and when this barometer falls just measure the deviation form the the
spot. If you tun into problems, remember your lab-view program? A
resolution of a least 0.05mS is fine then you can compute temporally how
much the wind contributes to the deviation. This does not solve the problem
does it? We are just getting warmed up. Remember statistical mechanics? You
will need it now... you will need to standardize the deviation from a known
distance call this quantity x and then we can sum x as a unit of measure of
the building height or alternatively you can measure this with actual
numbers!

physics
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From: "Daniel J.A. van Wassem" <dwassem#NoSpam.sci.kun.nl>
137:
1) Bring the barometer in such a linear motion, that it passes the  
building both at ground level and at it's uppermost level.
2) Be sure not to know anything about the speed of the barometer at ground  
level, you know it's exact location now.
3) Be sure not to know anything about the speed of the barometer at it's  
uppermost level, you now know the exact location of this level as well.
4) The height of the building is given by Height = 3) - 2)

138:
Postulate 1) Assume the building is spherical.
Postulate 2) Assume the building is in a vacuum
Postulate 3) Assume \hbar = 1
Postulate 4) Assume the height of the building is 100 meters.

**The height of the building is 100 meters**

proof:
1) Write the height H as H = 0.5H + 0.5H
2) According to postulate 4 the height of the building is 100 meters ->  
0.5H = 50 meters
3) Combining 1) and 2) we get: H = 50 + 50 = 100, so the height of the  
building is 100 meters
Q.E.D.

physics
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From: Rishi Deshpande <vonrishi#NoSpam.gmail.com>
139:
Put a glass cap at the open end of the barometer and turn it over so
that it acts like a mirror. Place the barometer facing down from the
room. Now with a laser pointer direct the beam at an angle from the
ground and see where you get the light dot reflected from the
barometer. You know the angle and know the horizontal distance between
two dots. Its simple trigonometry after this.

physics
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From: "David Brodeur" <dbrodeur#NoSpam.astro-cycles.com>
140:
Attach two copper cables to the metal case of the barometer. Position the
barometer at the edge of the roof, so it can be seen from the sidewalk
below.  Tap into the electrical system to get enough current to heat the
case to incandescence. Measure the flux one meter from the barometer, and
again from the sidewalk.  The height of the building in meters is the square
root of the ratio of the one meter measurement and the sidewalk measurement.

physics
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From: "David Brodeur" <dbrodeur#NoSpam.astro-cycles.com>
141:
Alternatively, you could fashion a cavity radiator from the case. This saves
you the trouble of hauling your measuring equipment up and down the stairs
(in case you knocked out power to the elevators while hacking into the
building power), as you just need to measure the flux at several
wavelengths. Knowing the radiating area, you can now calculate the
luminosity, and from that and the apparent brightness, the distance to the
roof.

physics
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From: Baldur Gislason <baldur#NoSpam.foo.is>

142:
Detonate a charge of TNT on the roof of the building. Measure the pressure
of the shockwave on the ground using the barometer. Knowing
the amount of tnt detonated one can work out the shockwave strength
and knowing the decay rate of the shockwave one can work out the distance
from the blast knowing the pressure.

physics
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From: komrul alam <komrul_alam#NoSpam.yahoo.com>
143:
Assumptions:
1. Let the building and the barometer in the question be only one
  dimensional.
2. If they are 3D objects, make them run at near light speed in any
  direction followed by another run with 90 degree angle to the previous
  direction. After the dual run the barometer and the building will become
  1D objects.

Now take a digital photo of the barometer and the building separately using
your web cam and save them as BAROMETER.JPG and BUILDING.JPG.( Don't
Capture background photo for accurate calculation.)
Now compare the size of the pictures. You've now got to know the height of
the building in barometer unit.

physics
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From: Paul Lyons <p.lyons#NoSpam.paradise.net.nz>

1. Measure PT, the air pressure at the top of the building.
2. Measure PB, the air pressure at the bottom of the building.
3. Calculate DeltaP = PB - PT.
4. Using the barometer as a spade, while taking care to preserve its ability
 to indicate air pressure, dig a pit beside the building until the barometer
 indicates a pit pressure, PP = PB + DeltaP.
5. The depth to which you have dug is the height of the building.

PalmiePaul 

New after last time posted (December 21, 2013) physics
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From: Leigh Lundin <leigh_lundin#NoSpam.yahoo.com>

Your article credits an article in 1968, but I first encountered it in 1966 at Rose Polytechnic Institute (Terre Haute, Indiana), now Rose-Hulman Technical Institute.

The professor challenged every incoming freshman class to come up with solutions, which gave the impression the joke was quite old, possibly from the early 1900s.

Following are a few of my contributions:

* Break open the barometer vial. Use the contents to create a mercury oxide battery to power any number of electronic measuring instruments, e.g, sonar, laser, etc.

* If the day isn’t sunny enough to allow measuring of shadows, drill an angled hole through the barometer and, using it as a sight-line with a fence post or light pole of known height, use basic trigonometry to calculate the height of the building.

* Use the barometer’s mercury to create a reflective lens to bounce a coherent beam onto the top edge of the building, using the angle to determine the height.

My bent mind further suggests the following:

* Have a grad student hold the barometer in his hand while standing on the top ledge of the building. Push him off and measure the doppler effect of his screams.

* Collect sufficient mercury barometers to create a massive amount of C2N2O2Hg to fill the building (or less if sufficient nitro-glycerine is available). Ignite the mercury fulminate. The height of the building should be zero.


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Of course, you could use the barometer to measure the pressure at the top and the bottom of the building and use the air density...

IF YOU READ ALL THE ABOVE, YOU PROBABLY HAVE THOUGHT OF A NEW WAY YOURSELF. SEND IT TO ME. - Joachim Verhagen.


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And now for something slightly different:

DETERMINE THE HEIGHT OF A BUILDING WITH HELP OF A SEXTANT.

From: David Lark 

I sent this into cartalk.com for use in their weekly puzzler. But it's 
too heady for them to use, so I'm sending it to you.

A candidate for a doctorate in mathematics was taking one of his final 
examinations. He was given this problem: "Given a sextant, how would you 
determine the height of a tall building?" He started to write "from a 
known distance away, measure the angle subtended by the building, and 
multiply the known distance by the tangent of the measured angle", which 
was probably the answer the professor was looking for, but he started 
thinking: 'eight years of college and hard work and sacrifice and all 
this jerk can come up with is a simple high school trig problem!" So he 
crafted the following answer:

Method 1: Go to the top of the building. Tie the sextant to a long rope. 
Lower the sextant until it touches the ground. Mark the rope at that 
point and measure it.

Method 2: Go to the top of the building. Drop the sextant off the 
building. Count off the seconds until it hits the ground. Integrate the 
gravitational constant twice over the time interval to get the distance.

Method 3: Go to to the basement of the building. Find the "maintenance 
engineer". Tell him "I'll give you this kewl sextant if you tell me how 
high this building is."

When the professor graded his paper, his first reaction was to flunk him 
out and send him back to Akron where his family would disown him and 
he'd become a destitute alcoholic and die an early death of liver 
disease if he didn't jump off a tall building first, counting the 
seconds until he hit the ground. But then he thought: "perhaps the 
answer I had in mind wasn't the best answer after all". Which of the 
four answers, or combination of them, would provide the best measurement 
of the building?

ANSWER: The problem, as given, did not presuppose any way to measure 
distance. This would seemingly eliminate the trigonometric method, as 
well as the rope method. Dropping the sextant off the building would 
give a wildly inaccurate answer, as counting off seconds is rather 
subjective, a small timing error would become a large distance error, 
who knows what the wind resistance of a sextant is, it might be hard to 
even see when the sextant hit the ground (and listening for the sound 
when it hits is an even dumber idea), and the sextant might become 
imbedded in someone's head before it even gets there. The "maintenance 
engineer" would likely be able to give you an accurate answer, but how 
do you tell if he's putting you on?

I would pace off a distance from the building, and use the sextant in 
its intended manner. This would render an answer in paces (which, being 
a kind of unit, provides a technically correct answer). Since I know 
that one of my paces is approximately a yard (or perhaps a meter), I 
would have an answer in accepted units. Then I would go to the basement, 
trade the sextant to the "engineer", and use my measurement to verify 
that he isn't playing a perverse joke on me.

Anyway, the other day I went into the local Mal-Wart. I told the first 
employee I encountered that I was looking for a sextant. She took me 
back to sporting goods and said: "All our tents are on this aisle, and 
most of them would work quite well for that".


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