| T.R | Title | User | Personal
Name | Date | Lines |
|---|
| 490.1 | And Turing machines | PLDVAX::JANZEN | Tom LMO2-0/E5 2795421 | Fri May 16 1986 12:19 | 12 |
| It could be your favorite Mathematician,
Fourier (I am a musician)
or your favorite Math function, Integration
or your favorite Math formula, y = sin omega t
or your favorite Math constant (not just pi), log (e) 2
or your favorite Math operant (not just +, -, *, ^, /), !
or your favorite Math teacher or professor, never had a good one
or anything that is your favorite which is Math related.
I love my program that draws the pattern emulating
two swinging pendula, one with a pen, one with a table.
Tom
|
| 490.2 | | LATOUR::JMUNZER | | Thu May 22 1986 11:28 | 14 |
| Some favorites: theorem -- Pythagorean
n!
formula -- --------
k! (n-k)!
(x + delta)^2 - x^2
proof -- ------------------- ----> 2x
delta
professor -- Robert Heineman (Cornell)
note -- British soldiers/hora synchronization
game -- Mastermind
...and Turing machines, and the Science Museum's
sand pendulum
John
|
| 490.3 | let's rank the top 40 | TAV02::NITSAN | Nitsan Duvdevani, Digital Israel | Fri May 23 1986 07:38 | 13 |
| Hmmm... this begins to sound like the MUSIC conference.
Some more favorites: theorems -- Fermat's last, Pspace=NPspace
n n+k-1
formula -- CC = ( )
k n
math operator -- binary exclusive or
games -- chess, othello, k-Welter (from my thesis)
Nitsan
|
| 490.4 | magic | CACHE::MARSHALL | beware the fractal dragon | Wed Jul 02 1986 17:36 | 9 |
| my favorite math relationship is:
1 = e^(2*pi*i)
there just seems to be something magical about that combination
of irrationals, and imaginary combining to make "one".
sm
|
| 490.5 | Favorite Taylor series | NOBUGS::AMARTIN | Alan H. Martin | Thu Oct 30 1986 18:40 | 14 |
| My favorite Taylor (MacLaurin?) series is the one for the area under
the bell curve from -inf to x. This is because the terms in the series
contain factors of 2n+1, something squared, 2 raised to the nth power,
and n factorial.
Not that I know all that many such series.
BTW, I never could directly derive a closed-form expression for the
nth term of the series, because each time you take the derivitive of the
last term to get the next one, the number of terms in the expression
doubles. So I could never get far enough to notice a pattern. Someone
pointed me at a probability book which had the series written down without
derivation.
/AHM
|
| 490.6 | Complex Variables and Fractals. | STAR::HEERMANCE | Martin, Bugs 5 - Martin 0 | Mon Jan 18 1988 14:12 | 14 |
| This topics a bit old but I see no reason to start a new note.
I have two favorite topics. The first is complex variables and
functions. The second is fractal geometry.
I like complex variables because of the merger of algebra and
geometry. Also, finding a mapping to solve electrostatics or fluid
flow problems has a similar feel to programming. Complex variables
also gave me a better grasp of Linear Systems and stability.
I became interested in fractals because of complex variables.
At first I was interested in the Mandelbrot set but later I became
interested in dragon curves and tree stuctures.
Are there any other people interested in fractals in this con-
ference?
Martin H.
|
| 490.7 | have also been interested in complex... | CTCADM::ROTH | If you plant ice you'll harvest wind | Mon Jan 18 1988 17:42 | 21 |
| I'm not really too good at math, and am a typical engineer/physics
type at heart, but do find it very interesting.
I have also been fascinated by complex variables, probably ever since
encountering 'phasors' in a high school electicity course. In a sense
it can be a gateway to advanced mathematics. My own experiences in
trying to demystify and really understand it has shown how unified
mathematics really is. Complex lies at the intersection of so many
things - topology (Riemann surfaces), analysis, partial differential
equations, differential geometry, and on and on.
The math I like is more visual than the areas most computer science
people are into; algebra, combinatorial stuff and probability doesn't
hold a great interest. In college, I essentialy 'cheated' my way thru
math courses by making up pictures of physical situations to understand
things rather than proceeding by logic, and it rarely failed me.
My parents were both commercial artists, so that's probably what the
problem is.
- Jim
|
| 490.8 | Another Fractalizer | TEACH::ART | Art Baker, DC Training Center (EKO) | Thu Jan 21 1988 15:08 | 8 |
|
I'm real fond of fractals and complex num's as well; my main
area of interest is chaotic dynamics, with an emphasis on
modelling complicated natural systems. Related to this is
my interest in self-organizing and adaptive systems.
-Art
"Bounded chaotic mixing produces strange stabilities..."
|
| 490.9 | Tell me more about chaotic dynamics | STAR::HEERMANCE | Martin, Bugs 5 - Martin 0 | Thu Jan 21 1988 16:56 | 5 |
| Re. -1
I've heard of chaotic dynamics but don't know to much about
it. Can you recommend any good books?
Martin H.
|
| 490.10 | Chaotic Dynamics, etc. | CADM::ROTH | If you plant ice you'll harvest wind | Fri Jan 22 1988 06:32 | 11 |
| I've seen a number of books at the university bookstores in Boston
and Cambridge. The subject probably has its roots in classical
mechanics, where questions of the stability of the solar system and
the like were asked. You can get amazingly complex behaviour with
some rather simple coupled differential equations; a good example
is the Lorenz equations - a set equations in 3 variables that leads
to nonperiodic behaviour, and came about from studying atmospheric
turbulance. I'll post a copy of a simple program to play with the
Lorenz attractor separately.
- Jim
|
| 490.11 | Chaos ? What Chaos ? | TEACH::ART | Art Baker, DC Training Center (EKO) | Fri Jan 22 1988 14:49 | 22 |
|
> The subject probably has its roots in classical
> mechanics, where questions of the stability of the solar system and
> the like were asked.
Actually, a lot of the work dealing with chaotic systems
grew out of questions arising from fluid dynamics and
turbulence, and the impossibility of describing/predicting
the onset of turbulence using the methods of traditional
physics (i.e. mechanics).
Also, a lot of interesting chaotic behavior shows up in
discrete-time systems (in the form of difference equations)
as well as in systems of DifEq's. Even the old logistic
equation will pop itself into a chaotic regime when it's
pushed far enough.
I'll get a short booklist together this weekend and attach
it to this note.
-Art
|
| 490.12 | I collect puzzles | 63669::HAINSWORTH | My fingers never leave my hands! | Thu Mar 22 1990 18:34 | 10 |
| Favorite math proof (great for kids):
a = b
a^2 = ab
a^2 - b^2 = ab - b^2
(a + b)(a - b) = b(a - b)
a + b = b
b + b = b
2b = b
2 = 1
|
| 490.13 | x�-a� | ELIS::BUREMA | In the middle of life is if... | Mon Oct 29 1990 10:23 | 11 |
| My favorite equation is:
2 2
x - a = (x - a).(x + a)
because when I first was thaught algebra it made me realize *why*
the primary school trick of 52*48 worked the way it did (e.g. the
equations had a real life meaning!). It also foxed in my mind the
difference between variables and constants.
Wildrik 8-))
|