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CONGRATULATIONS:to the following students who have emerged as champion on the recently concluded 7th Physics Brain Tournament at the MSU-IIT Iligan City last February 16 2006. JOB well DONE GUYS!

Anthony Cordova---------BSEE
Patricklyn Antimano-----BSECE
Glaiza Cansadra Laurete-BSAPS
Coach: MR Ruelson S Solidum

From the Physics Faculty and Staff of MPSC
---------------------------------------------

How To Catch A Lion


1. Mathematical Methods

1. The Hilbert (axiomatic) method

We place a locked cage onto a given point in the desert. After that we introduce the following logical system:

Axiom 1: The set of lions in the Sahara is not empty.
Axiom 2: If there exists a lion in the Sahara, then there exists a lion in the cage.
Procedure: If P is a theorem, and if the following is holds: "P implies Q", then Q is a theorem.
Theorem 1: There exists a lion in the cage.

2. The geometrical inversion method

We place a spherical cage in the desert, enter it and lock it from inside. We then performe an inversion with respect to the cage. Then the lion is inside the cage, and we are outside.

3. The projective geometry method

Without loss of generality, we can view the desert as a plane surface. We project the surface onto a line and afterwards the line onto an interiour point of the cage. Thereby the lion is mapped onto that same point.

4. The Bolzano-Weierstraß method

Divide the desert by a line running from north to south. The lion is then either in the eastern or in the western part. Let's assume it is in the eastern part. Divide this part by a line running from east to west. The lion is either in the northern or in the southern part. Let's assume it is in the northern part. We can continue this process arbitrarily and thereby constructing with each step an increasingly narrow fence around the selected area. The diameter of the chosen partitions converges to zero so that the lion is caged into a fence of arbitrarily small diameter.

5. The set theoretical method

We observe that the desert is a separable space. It therefore contains an enumerable dense set of points which constitutes a sequence with the lion as its limit. We silently approach the lion in this sequence, carrying the proper equipment with us.

6. The Peano method

In the usual way construct a curve containing every point in the desert. It has been proven [1] that such a curve can be traversed in arbitrarily short time. Now we traverse the curve, carrying a spear, in a time less than what it takes the lion to move a distance equal to its own length.

7. A topological method

We observe that the lion possesses the topological gender of a torus. We embed the desert in a four dimensional space. Then it is possible to apply a deformation [2] of such a kind that the lion when returning to the three dimensional space is all tied up in itself. It is then completely helpless.

8. The Cauchy method

We examine a lion-valued function f(z). Be \zeta the cage. Consider the integral

1 [ f(z)
------- | --------- dz
2 \pi i ] z - \zeta

C

where C represents the boundary of the desert. Its value is f(zeta), i.e. there is a lion in the cage [3].

9. The Wiener-Tauber method

We obtain a tame lion, L_0, from the class L(-\infinity,\infinity), whose fourier transform vanishes nowhere. We put this lion somewhere in the desert. L_0 then converges toward our cage. According to the general Wiener-Tauber theorem [4] every other lion L will converge toward the same cage. (Alternatively we can approximate L arbitrarily close by translating L_0 through the desert [5].)

2. Theoretical Physics Methods

1. The Dirac method

We assert that wild lions can ipso facto not be observed in the Sahara desert. Therefore, if there are any lions at all in the desert, they are tame. We leave catching a tame lion as an exercise to the reader.

2. The Schrödinger method

At every instant there is a non-zero probability of the lion being in the cage. Sit and wait.

3. The nuclear physics method

Insert a tame lion into the cage and apply a Majorana exchange operator [6] on it and a wild lion.

As a variant let us assume that we would like to catch (for argument's sake) a male lion. We insert a tame female lion into the cage and apply the Heisenberg exchange operator [7], exchanging spins.

4. A relativistic method

All over the desert we distribute lion bait containing large amounts of the companion star of Sirius. After enough of the bait has been eaten we send a beam of light through the desert. This will curl around the lion so it gets all confused and can be approached without danger.

3. Experimental Physics Methods

1. The thermodynamics method

We construct a semi-permeable membrane which lets everything but lions pass through. This we drag across the desert.

2. The atomic fission method

We irradiate the desert with slow neutrons. The lion becomes radioactive and starts to disintegrate. Once the disintegration process is progressed far enough the lion will be unable to resist.

3. The magneto-optical method

We plant a large, lense shaped field with cat mint (nepeta cataria) such that its axis is parallel to the direction of the horizontal component of the earth's magnetic field. We put the cage in one of the field's foci. Throughout the desert we distribute large amounts of magnetized spinach (spinacia oleracea) which has, as everybody knows, a high iron content. The spinach is eaten by vegetarian desert inhabitants which in turn are eaten by the lions. Afterwards the lions are oriented parallel to the earth's magnetic field and the resulting lion beam is focussed on the cage by the cat mint lense.

4. Contributions from Computer Science

1. The search method

We assume that the lion is most likely to be found in the direction to the north of the point where we are standing. Therefore the REAL problem we have is that of speed, since we are only using a PC to solve the problem.

2. The parallel search method

By using parallelism we will be able to search in the direction to the north much faster than earlier.

3. The Monte-Carlo method

We pick a random number indexing the space we search. By excluding neighboring points in the search, we can drastically reduce the number of points we need to consider. The lion will according to probability appear sooner or later.

4. The practical approach

We see a rabbit very close to us. Since it is already dead, it is particularly easy to catch. We therefore catch it and call it a lion.

5. The common language approach

If only everyone used ADA/Common Lisp/Prolog, this problem would be trivial to solve.

6. The standard approach

We know what a Lion is from ISO 4711/X.123. Since CCITT have specified a Lion to be a particular option of a cat we will have to wait for a harmonized standard to appear. $20,000,000 have been funded for initial investigations into this standard development.

7. Linear search

Stand in the top left hand corner of the Sahara Desert. Take one step east. Repeat until you have found the lion, or you reach the right hand edge. If you reach the right hand edge, take one step southwards, and proceed towards the left hand edge. When you finally reach the lion, put it the cage. If the lion should happen to eat you before you manage to get it in the cage, press the reset button, and try again.

8. The Dijkstra approach

The way the problem reached me was: catch a wild lion in the Sahara Desert. Another way of stating the problem is:

Axiom 1: Sahara elem deserts
Axiom 2: Lion elem Sahara
Axiom 3: NOT(Lion elem cage)

We observe the following invariant:

P1: C(L) v not(C(L))

where C(L) means: the value of "L" is in the cage.

Establishing C initially is trivially accomplished with the statement

;cage := {}

Note 0:
This is easily implemented by opening the door to the cage and shaking out any lions that happen to be there initially.
(End of note 0.)

The obvious program structure is then:

;cage := {}
;do NOT (C(L)) ->
;"approach lion under invariance of P1"
;if P(L) ->
;"insert lion in cage"
[] not P(L) ->
;skip
;fi
;od

where P(L) means: the value of L is within arm's reach.

Note 1:
Axiom 2 ensures that the loop terminates.
(End of note 1.)

Exercise 0:
Refine the step "Approach lion under invariance of P1".
(End of exercise 0.)

Note 2:
The program is robust in the sense that it will lead to abortion if the value of L is "lioness".
(End of note 2.)

Remark 0:
This may be a new sense of the word "robust" for you.
(End of remark 0.)

Note 3:
From observation we can see that the above program leads to the desired goal. It goes without saying that we therefore do not have to run it.
(End of note 3.)

(End of approach.)

[1] After Hilbert, cf. E. W. Hobson, "The Theory of Functions of a Real Variable and the Theory of Fourier's Series" (1927), vol. 1, pp 456-457
[2] H. Seifert and W. Threlfall, "Lehrbuch der Topologie" (1934), pp 2-3
[3] According to the Picard theorem (W. F. Osgood, "Lehrbuch der Funktionentheorie", vol 1 (1928), p 178) it is possible to catch every lion except for at most one.
[4] N. Wiener, "The Fourier Integral and Certain of its Applications" (1933), pp 73-74
[5] N. Wiener, ibid, p 89
[6] cf e.g. H. A. Bethe and R. F. Bacher, "Reviews of Modern Physics", 8 (1936), pp 82-229, esp. pp 106-107
[7] ibid




RUELSON SOLIDUM

DAte: August 22, 2008.
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Ruelson Solidum
Physics Instructor

I am Currently Teaching Basic undergraduate courses:

Physics 11 Electricity and Magnetism: BSAPS-2, BSMS-2, BSIC-2
Physics 20 Acoustics and Optcs: BSAPS-3
Physics 60 Modern Phsyics: BSAPS-4
Physics 501: Mechanics and Heat to MST-APS
--------------------------------------------
A Party of Famous Physicists

One day, all of the world's famous physicists decided to get together for a tea luncheon. Fortunately, the doorman was a grad student, and able to observe some of the guests...

* Everyone gravitated toward Newton, but he just kept moving around at a constant velocity and showed no reaction.
* Einstein thought it was a relatively good time.
* Coulomb got a real charge out of the whole thing.
* Cavendish wasn't invited, but he had the balls to show up anyway.
* Cauchy, being the only mathematician there, still managed to integrate well with everyone.
* Thompson enjoyed the plum pudding.
* Pauli came late, but was mostly excluded from things, so he split.
* Pascal was under too much pressure to enjoy himself.
* Ohm spent most of the time resisting Ampere's opinions on current events.
* Hamilton went to the buffet tables exactly once.
* Volt thought the social had a lot of potential.
* Hilbert was pretty spaced out for most of it.
* Heisenberg may or may not have been there.
* The Curies were there and just glowed the whole time.
* van der Waals forced himeself to mingle.
* Wien radiated a colourful personality.
* Millikan dropped his Italian oil dressing.
* de Broglie mostly just stood in the corner and waved.
* Hollerith liked the hole idea.
* Stefan and Boltzman got into some hot debates.
* Everyone was attracted to Tesla's magnetic personality.
* Compton was a little scatter-brained at times.
* Bohr ate too much and got atomic ache.
* Watt turned out to be a powerful speaker.
* Hertz went back to the buffet table several times a minute.
* Faraday had quite a capacity for food.
* Oppenheimer got bombed.