# Introduction

Here is some sample LaTeX notation. By associativity, if $$\zeta$$ is combinatorially closed then $$\delta = \Psi$$. Since ${S^{(F)}} \left( 2, \dots,-\mathbf{{i}} \right) \to \frac{-\infty^{-6}}{\overline{\alpha}},$ $$l < \cos \left( \hat{\xi} \cup P \right)$$. Thus every functor is Green and hyper-unconditionally stable. Obviously, every injective homeomorphism is embedded and Clifford. Because $$\mathcal{{A}} > S$$, $$\tilde{i}$$ is not dominated by $$b$$. Thus $${T_{t}} > | A |$$.

Subsection text here. Let’s show some more LaTeX: Obviously, $${W_{\Xi}}$$ is composite. Trivially, there exists an ultra-convex and arithmetic independent, multiply associative equation. So $$\infty^{1} > \overline{0}$$. It is easy to see that if $${v^{(W)}}$$ is not isomorphic to $$\mathfrak{{l}}$$ then there exists a reversible and integral convex, bounded, hyper-Lobachevsky point. One can easily see that $$\hat{\mathscr{{Q}}} \le 0$$. Now if $$\bar{\mathbf{{w}}} > h' ( \alpha )$$ then $${z_{\sigma,T}} = \nu$$. Clearly, if $$\| Q \| \sim \emptyset$$ then every dependent graph is pseudo-compactly parabolic, complex, quasi-measurable and parabolic. This completes the proof.

Subsubsection text here. This is how you can cite other articles. Just type \cite{DOI} where DOI is a Digital Object Identifier. For example cite this article published in IEEE INFOCOM 2001 (Aad 2001)

# Figures

Note that \label must occur AFTER (or within) \caption . For figures, \caption should occur after the \includegraphics . Note that IEEEtran v1.7 and later has special internal code that is designed to preserve the operation of \label within \caption even when the captionsoff option is in effect. However, because of issues like this, it may be the safest practice to put all your \label just after \caption rather than within \caption{} .

# Table

An example of a floating table. Note that, for IEEE style tables, the \caption command should come BEFORE the table. Table text will default to \footnotesize as IEEE normally uses this smaller font for tables. The \label must come after \caption as always.

\label{tab:1} An Example of a Table
One Two
Three Four

Note that IEEE does not put floats in the very first column - or typically anywhere on the first page for that matter. Also, in-text middle (“here”) positioning is not used. Most IEEE journals/conferences use top floats exclusively. Note that, LaTeX2e, unlike IEEE journals/conferences, places footnotes above bottom floats. This can be corrected via the \fnbelowfloat command of the stfloats package.

# Conclusion

The conclusion goes here.

# Acknowledgment

The authors would like to thank...

# Introduction

Here is some sample LaTeX notation. By associativity, if $$\zeta$$ is combinatorially closed then $$\delta = \Psi$$. Since ${S^{(F)}} \left( 2, \dots,-\mathbf{{i}} \right) \to \frac{-\infty^{-6}}{\overline{\alpha}},$ $$l < \cos \left( \hat{\xi} \cup P \right)$$. Thus every functor is Green and hyper-unconditionally stable. Obviously, every injective homeomorphism is embedded and Clifford. Because $$\mathcal{{A}} > S$$, $$\tilde{i}$$ is not dominated by $$b$$. Thus $${T_{t}} > | A |$$.

Subsection text here. Let’s show some more LaTeX: Obviously, $${W_{\Xi}}$$ is composite. Trivially, there exists an ultra-convex and arithmetic independent, multiply associative equation. So $$\infty^{1} > \overline{0}$$. It is easy to see that if $${v^{(W)}}$$ is not isomorphic to $$\mathfrak{{l}}$$ then there exists a reversible and integral convex, bounded, hyper-Lobachevsky point. One can easily see that $$\hat{\mathscr{{Q}}} \le 0$$. Now if $$\bar{\mathbf{{w}}} > h' ( \alpha )$$ then $${z_{\sigma,T}} = \nu$$. Clearly, if $$\| Q \| \sim \emptyset$$ then every dependent graph is pseudo-compactly parabolic, complex, quasi-measurable and parabolic. This completes the proof.

Subsubsection text here. This is how you can cite other articles. Just type \cite{DOI} where DOI is a Digital Object Identifier. For example cite this article published in IEEE INFOCOM 2001 (Aad 2001)

# Figures

Note that must occur AFTER (or within) . For figures, should occur after the . Note that IEEEtran v1.7 and later has special internal code that is designed to preserve the operation of within even when the captionsoff option is in effect. However, because of issues like this, it may be the safest practice to put all your just after rather than within .

# Table

An example of a floating table. Note that, for IEEE style tables, the command should come BEFORE the table. Table text will default to as IEEE normally uses this smaller font for tables. The must come after as always.

\label{tab:1} An Example of a Table
One Two
Three Four

Note that IEEE does not put floats in the very first column - or typically anywhere on the first page for that matter. Also, in-text middle (“here”) positioning is not used. Most IEEE journals/conferences use top floats exclusively. Note that, LaTeX2e, unlike IEEE journals/conferences, places footnotes above bottom floats. This can be corrected via the command of the stfloats package.

# Conclusion

The conclusion goes here.

# Acknowledgment

The authors would like to thank...

# Introduction

Here is some sample LaTeX notation. By associativity, if $$\zeta$$ is combinatorially closed then $$\delta = \Psi$$. Since ${S^{(F)}} \left( 2, \dots,-\mathbf{{i}} \right) \to \frac{-\infty^{-6}}{\overline{\alpha}},$ $$l < \cos \left( \hat{\xi} \cup P \right)$$. Thus every functor is Green and hyper-unconditionally stable. Obviously, every injective homeomorphism is embedded and Clifford. Because $$\mathcal{{A}} > S$$, $$\tilde{i}$$ is not dominated by $$b$$. Thus $${T_{t}} > | A |$$.

Subsection text here. Let’s show some more LaTeX: Obviously, $${W_{\Xi}}$$ is composite. Trivially, there exists an ultra-convex and arithmetic independent, multiply associative equation. So $$\infty^{1} > \overline{0}$$. It is easy to see that if $${v^{(W)}}$$ is not isomorphic to $$\mathfrak{{l}}$$ then there exists a reversible and integral convex, bounded, hyper-Lobachevsky point. One can easily see that $$\hat{\mathscr{{Q}}} \le 0$$. Now if $$\bar{\mathbf{{w}}} > h' ( \alpha )$$ then $${z_{\sigma,T}} = \nu$$. Clearly, if $$\| Q \| \sim \emptyset$$ then every dependent graph is pseudo-compactly parabolic, complex, quasi-measurable and parabolic. This completes the proof.
Subsubsection text here. This is how you can cite other articles. Just type \cite{DOI} where DOI is a Digital Object Identifier. For example cite this article published in IEEE INFOCOM 2001 (Aad 2001)