Difference between revisions of "Math equation demo"

Latest revision as of 09:01, 10 January 2022

The following shows an angled degree symbol: $\angle {90}^{\circ }$

 $P_{wave}={\frac {\rho g^{2}h^{2}T_{e}}{6400\pi }}$ 
 ${\frac {{\vec {X}}_{0}}{P({\vec {X}}_{0})}}\nabla _{\{H,T,B,\eta \}}P({\vec {X}}_{0})=(2,1,1,1)$

In more explicit terms, the equaliser consists of an object E and a morphism eq : E → X satisfying $f\circ eq=g\circ eq$ , and such that, given any object O and morphism m : O → X, if $f\circ m=g\circ m$ , then there exists a unique morphism u : O → E such that $eq\circ u=m$ .

The following equation shows how to use square root: $c={\sqrt {a^{2}+b^{2}}}$

A morphism $m:O\rightarrow X$ is said to equalise $f$ and $g$ if $f\circ m=g\circ m$ .

@@ Line 1: / Line 1: @@
+The following shows an angled '''degree''' symbol: <math>\ang{90}^{\circ}</math>
+ <math>P_{wave} = \frac{\rho g^2 h^2 T_e}{6400 \pi} </math>
+ <math>\frac{\vec{X}_0}{P(\vec{X}_0)} \nabla_{\{H,T,B,\eta \}} P (\vec{X}_0) = (2, 1, 1, 1) </math>
 In more explicit terms, the equaliser consists of an object ''E'' and a morphism ''eq'' : ''E'' → ''X'' satisfying <math>f \circ eq = g \circ eq</math>,
 and such that, given any object ''O'' and morphism ''m'' : ''O'' → ''X'', if <math>f \circ m = g \circ m</math>, then there exists a [[unique (mathematics)|unique]] morphism ''u'' : ''O'' → ''E'' such that <math>eq \circ u = m</math>.
+The following equation shows how to use square root:
+<math> c = \sqrt{a^2 + b^2} </math>
+A morphism <math>m:O \rightarrow X</math> is said to '''equalise''' <math>f</math> and <math>g</math> if <math>f \circ m = g \circ m</math>.

Difference between revisions of "Math equation demo"

Latest revision as of 09:01, 10 January 2022

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