Ah! I read it as \(\lim_{n \rightarrow \infty } \left(2-\ln (n) \right)\) It makes sense when you're sober!
TEX tags documentation: ftp://mirror.switch.ch/mirror/tex/documentation help: ftp://mirror.switch.ch/mirror/tex/help macros: ftp://mirror.switch.ch/mirror/tex/macros parent directory: ftp://mirror.switch.ch/mirror/tex/ hope this info helps.
As I understand (Infinity)a -(Infinity)b = o or any other number positive or negetive no. depending on the value of (Infinity)a and (Infinity)b. P.J.LAKHAPATE plakhapate@rediffmail.com
Just testing. I will delete this if I can: \(f = \sqrt(1 - \frac{2GM}{c^2 r}) \) \(\frac{\partial f}{\partial r} = \frac{GM}{c^2 r^2 f}\)
How about this, as a simple way to display matrices: enclose in tex tags the following \begin{pmatrix}1 & 0\\ 0 & 1 \end{pmatrix} yielding \(\begin{pmatrix}1 & 0\\ 0 & 1 \end{pmatrix} \). If you want more space between the rows, just chuck in a few more \\, like \begin{pmatrix}1 & 0\\ \\ \\ \\ 0 & 1 \end{pmatrix} which delivers \(\begin{pmatrix}1 & 0\\ \\ \\ \\ 0 & 1 \end{pmatrix}\)
Here are a couple of bugs/omissions I detected with this implementation of LaTex. The congruence glyph "\cong" is not supported; the proper subset glyph "\subsetne" is not supported; Lower case fraktur font is not supported; enclosed text "\text{blah blah}" is not supported; In-line math, as "[itex]", "\textstyle{blah}" is not supported, neither is the command "\tfrac" for in-line fractions the package xy-pic is not included (agreed, this would be a great luxury, but great, nonetheless, and not too hard to implement, I believe)
To prove Absane's relation, a clever use of power series does the trick. Please Register or Log in to view the hidden image!
\(\pi=3+\frac{1}{6+\frac{9}{6+\frac{25}{6+\frac{49}{6+\frac{81}{6+\frac{121}{6+\frac{169}{6+\frac{225}{\ddots}}}}}}}}\) Is there a simple way to make the size not reduce as the fractions go on?
Try this: \( \pi = 3+\frac{1}{ \large 6+\frac{9}{ \large 6+\frac{25}{ \large 6+\frac{49}{ \large 6+\frac{81}{ \large 6+\frac{121}{ \large 6+\frac{169}{ \large 6+\frac{225}{ \large \ddots } } } } } } } } \) Code: [tex-] \large \pi = 3+\frac{1}{\large 6+\frac{9}{\large 6+\frac{25}{\large 6+\frac{49}{\large 6+\frac{81}{\large 6+\frac{121}{\large 6+\frac{169}{\large 6+\frac{225}{\large \ddots } } } } } } } } [/tex]
Thanks. I see it makes no difference how you lay out your code, only the \large function makes a difference. \(\large1+\frac{1}{\large1+\frac{2}{\large1+\frac{3}{\large1+\frac{4}{\large\ddots}}}}\) Code: \large1+\frac{1}{\large1+\frac{2}{\large1+\frac{3}{\large1+\frac{4}{\large\ddots}}}}