update texed notes

tex/energy_transfer/src/index.tex

@@ -400,7 +400,7 @@ stochastic process.
 \label{sec:multibath}
 
 For the models we consider in \fixme{citation,reference}, we have
-\([H_\inter^{(i)}, H_\inter^{(j)}] = 0\), where \(i,j\) are the bath
+\([H_\bath^{(i)}, H_\bath^{(j)}] = 0\), where \(i,j\) are the bath
 indices. Therefore, we can apply the formalism of the previous
 sections almost unchanged, by just taking care that all quantities
 involved in the expression of \(J_n=-\dv{\ev{H_B^{(n)}}}{t}\) refer to

tex/gaussian_model/src/index.tex

@@ -373,10 +373,10 @@ and
   ∑_{m,n}\frac{A_nG_m}{C_n+W_m}\qty(1-\eu^{-(C_n+W_m)t}) - ∑_{m,n}\frac{A_nU_m}{C_n+Q_m}\qty(1-\eu^{-(C_n+Q_m)t}).
 \end{multline}
 
-This concludes the calculation. A possible measure would be to write
-\cref{eq:bathderiv_1} as a sum of exponentials and give explicit
-expressions for the coefficients and exponents. This is not required
-for now. Code implementing this can be found under
+This concludes the calculation. A possible measure of simplification
+would be to write \cref{eq:bathderiv_1} as a sum of exponentials and
+give explicit expressions for the coefficients and exponents. This is
+not required for now. Code implementing this can be found under
 \url{https://github.com/vale981/hopsflow}.
 
 \section{Two Oscillators, Two Baths}%
@@ -526,7 +526,7 @@ of the two harmonic oscillators.
 We find
 \begin{equation}
   \label{eq:generalcorr}
-  C_{ij}(t, s) = G_{ik}(t)G_{jl}(s) C(0,0)_{ij} +
+  C_{ij}(t, s) = G_{ik}(t)G_{jl}(s) C(0,0)_{kl} +
   \underbrace{∫_0^t\dd{l}∫_0^s\dd{r}G_{ik}(t-l)G_{jl}(s-r) \ev{W_k(l)W_l(r)}}_{=Θ_{ij}}.
 \end{equation}
 

tex/hiromacros.sty

@@ -0,0 +1,100 @@
+\ProvidesPackage{hiromacros}
+
+% Macros
+
+%% qqgg
+\newcommand{\qqgg}[0]{q\bar{q}\rightarrow\gamma\gamma}
+
+%% ppgg
+\newcommand{\ppgg}[0]{pp\rightarrow\gamma\gamma}
+
+%% Momenta and Polarization Vectors convenience
+\DeclareMathOperator{\ps}{\slashed{p}}
+
+\DeclareMathOperator{\pe}{\varepsilon}
+\DeclareMathOperator{\pes}{\slashed{\pe}}
+
+\DeclareMathOperator{\pse}{\varepsilon^{*}}
+\DeclareMathOperator{\pses}{\slashed{\pe}^{*}}
+
+%% Spinor convenience
+\DeclareMathOperator{\us}{u}
+\DeclareMathOperator{\usb}{\bar{u}}
+
+\DeclareMathOperator{\vs}{v}
+\DeclareMathOperator*{\vsb}{\overline{v}}
+
+%% Center of Mass energy
+\DeclareMathOperator{\ecm}{E_{\text{CM}}}
+
+%% area hyperbolicus
+\DeclareMathOperator{\artanh}{artanh}
+\DeclareMathOperator{\arcosh}{arcosh}
+
+%% Fast Slash
+\let\sl\slashed
+
+%% hermitian/complex conjugate
+\DeclareMathOperator{\hc}{h.c.}
+\DeclareMathOperator{\cc}{c.c.}
+
+%% eulers number
+\def\eu{\ensuremath{\mathrm{e}}}
+
+%% Notes on Equations
+\newcommand{\shorteqnote}[1]{ &  & \text{\small\llap{#1}}}
+
+%% Typewriter Macros
+\newcommand{\sherpa}{\texttt{Sherpa}}
+\newcommand{\rivet}{\texttt{Rivet}}
+\newcommand{\vegas}{\texttt{VEGAS}}
+\newcommand{\lhapdf}{\texttt{LHAPDF6}}
+\newcommand{\scipy}{\texttt{scipy}}
+
+%% Sherpa Versions
+\newcommand{\oldsherpa}{\texttt{2.2.10}}
+\newcommand{\newsherpa}{\texttt{3.0.0} (unreleased)}
+
+%% Special Names
+\newcommand{\lhc}{\emph{LHC}}
+
+%% Expected Value and Variance
+\newcommand{\EX}[1]{\operatorname{E}\qty[#1]}
+\newcommand{\VAR}[1]{\operatorname{VAR}\qty[#1]}
+
+%% Uppercase Rho
+\newcommand{\Rho}{P}
+
+%% Transverse Momentum
+\newcommand{\pt}[0]{p_\mathrm{T}}
+
+%% Sign Function
+\DeclareMathOperator{\sign}{sgn}
+
+%% Stages
+\newcommand{\stone}{\texttt{LO}}
+\newcommand{\sttwo}{\texttt{LO+PS}}
+\newcommand{\stthree}{\texttt{LO+PS+pT}}
+\newcommand{\stfour}{\texttt{LO+PS+pT+Hadr.}}
+\newcommand{\stfive}{\texttt{LO+PS+pT+Hadr.+MI}}
+
+%% GeV
+\newcommand{\gev}[1]{\SI{#1}{\giga\electronvolt}}
+
+\def\iu{\ensuremath{\mathrm{i}}}
+\def\i{\iu}
+\def\id{\ensuremath{\mathbb{1}}}
+\def\RR{\ensuremath{\mathbb{R}}}
+\def\CC{\ensuremath{\mathbb{C}}}
+
+% fixme
+\newcommand{\fixme}[1]{\textbf{\textcolor{red}{FIXME:~#1}}}
+
+% HOPS/NMQSD
+\def\sys{\ensuremath{\mathrm{S}}}
+\def\bath{\ensuremath{\mathrm{B}}}
+\def\inter{\ensuremath{\mathrm{I}}}
+\def\nth{\ensuremath{^{(n)}}}
+
+\newcommand{\mat}[1]{\ensuremath{{\underline{\vb{#1}}}}}
+\def\kmat{{\mat{k}}}

tex/hirostyle.sty

@@ -79,99 +79,3 @@ labelformat=brace, position=top]{subcaption}
 
 %% Minus Sign for Matplotlib
 \newunicodechar{−}{-}
-
-% Macros
-
-%% qqgg
-\newcommand{\qqgg}[0]{q\bar{q}\rightarrow\gamma\gamma}
-
-%% ppgg
-\newcommand{\ppgg}[0]{pp\rightarrow\gamma\gamma}
-
-%% Momenta and Polarization Vectors convenience
-\DeclareMathOperator{\ps}{\slashed{p}}
-
-\DeclareMathOperator{\pe}{\varepsilon}
-\DeclareMathOperator{\pes}{\slashed{\pe}}
-
-\DeclareMathOperator{\pse}{\varepsilon^{*}}
-\DeclareMathOperator{\pses}{\slashed{\pe}^{*}}
-
-%% Spinor convenience
-\DeclareMathOperator{\us}{u}
-\DeclareMathOperator{\usb}{\bar{u}}
-
-\DeclareMathOperator{\vs}{v}
-\DeclareMathOperator*{\vsb}{\overline{v}}
-
-%% Center of Mass energy
-\DeclareMathOperator{\ecm}{E_{\text{CM}}}
-
-%% area hyperbolicus
-\DeclareMathOperator{\artanh}{artanh}
-\DeclareMathOperator{\arcosh}{arcosh}
-
-%% Fast Slash
-\let\sl\slashed
-
-%% hermitian/complex conjugate
-\DeclareMathOperator{\hc}{h.c.}
-\DeclareMathOperator{\cc}{c.c.}
-
-%% eulers number
-\def\eu{\ensuremath{\mathrm{e}}}
-
-%% Notes on Equations
-\newcommand{\shorteqnote}[1]{ &  & \text{\small\llap{#1}}}
-
-%% Typewriter Macros
-\newcommand{\sherpa}{\texttt{Sherpa}}
-\newcommand{\rivet}{\texttt{Rivet}}
-\newcommand{\vegas}{\texttt{VEGAS}}
-\newcommand{\lhapdf}{\texttt{LHAPDF6}}
-\newcommand{\scipy}{\texttt{scipy}}
-
-%% Sherpa Versions
-\newcommand{\oldsherpa}{\texttt{2.2.10}}
-\newcommand{\newsherpa}{\texttt{3.0.0} (unreleased)}
-
-%% Special Names
-\newcommand{\lhc}{\emph{LHC}}
-
-%% Expected Value and Variance
-\newcommand{\EX}[1]{\operatorname{E}\qty[#1]}
-\newcommand{\VAR}[1]{\operatorname{VAR}\qty[#1]}
-
-%% Uppercase Rho
-\newcommand{\Rho}{P}
-
-%% Transverse Momentum
-\newcommand{\pt}[0]{p_\mathrm{T}}
-
-%% Sign Function
-\DeclareMathOperator{\sign}{sgn}
-
-%% Stages
-\newcommand{\stone}{\texttt{LO}}
-\newcommand{\sttwo}{\texttt{LO+PS}}
-\newcommand{\stthree}{\texttt{LO+PS+pT}}
-\newcommand{\stfour}{\texttt{LO+PS+pT+Hadr.}}
-\newcommand{\stfive}{\texttt{LO+PS+pT+Hadr.+MI}}
-
-%% GeV
-\newcommand{\gev}[1]{\SI{#1}{\giga\electronvolt}}
-
-\def\iu{\ensuremath{\mathrm{i}}}
-\def\i{\iu}
-\def\id{\ensuremath{\mathbb{1}}}
-\def\RR{\ensuremath{\mathbb{R}}}
-\def\CC{\ensuremath{\mathbb{C}}}
-
-% fixme
-\newcommand{\fixme}[1]{\textbf{\textcolor{red}{FIXME:~#1}}}
-
-% HOPS/NMQSD
-\def\sys{\ensuremath{\mathrm{S}}}
-\def\bath{\ensuremath{\mathrm{B}}}
-\def\inter{\ensuremath{\mathrm{I}}}
-\def\nth{\ensuremath{^{(n)}}}

tex/hops_tweaks/src/_preamble.tex

@@ -3,14 +3,13 @@
 captions=nooneline,captions=tableabove,english,DIV=16,numbers=noenddot,final]{scrartcl}
 
 \usepackage{../../hirostyle}
+\usepackage{../../hiromacros}
 \usepackage{stackengine}
 \synctex=1
 \title{HOPS Tweaks}
 \author{Valentin Link, Kai Mueller, Valentin Boettcher}
 \date{\today}
 
-\newcommand{\mat}[1]{\ensuremath{{\underline{\vb{#1}}}}}
-\def\kmat{{\mat{k}}}
 \begin{document}
 \maketitle
 \tableofcontents

tex/hops_tweaks/src/index.tex

@@ -68,7 +68,7 @@ the form
 \end{equation}
 where \(H_\sys\) is the (possibly time dependent) system Hamiltonian,
 \(H_B\nth = ∑_λω_λ\nth a_λ^{(n),†}a_λ\nth\),
-\(B_n=∑_{λ}L_n^† g_λ\nth a_λ\nth\) and the \(L_n={(\vb{L})}_n\) are
+\(B_n=∑_{λ} g_λ\nth a_λ\nth\) and the \(L_n={(\vb{L})}_n\) are
 arbitrary operators in the system Hilbert space. This models a
 situation where each bath couples with the system through exactly one
 spectral density and is therefore not fully general.
@@ -218,9 +218,9 @@ Using
 where \({\qty(\mat{e}_{n,μ})}_{ij}=δ_{ni}δ_{μj}\) we find after some algebra
 \begin{multline}
   \label{eq:multihops}
-  \dot{ψ}^\kmat = \qty[-i H_\sys + \vb{L}\cdot\vb{η}^\ast -
+  \dot{ψ}^\kmat = \qty[-\iu H_\sys + \vb{L}\cdot\vb{η}^\ast -
   ∑_{n=1}^N∑_{μ=1}^{M_n}\kmat_{n,μ}W\nth_μ]ψ^\kmat \\+
-  i∑_{n=1}^N∑_{μ=1}^{M_n}\sqrt{G\nth_μ}\qty[\sqrt{\kmat_{n,μ}}  L_nψ^{\kmat -
+  \iu ∑_{n=1}^N∑_{μ=1}^{M_n}\sqrt{G\nth_μ}\qty[\sqrt{\kmat_{n,μ}}  L_nψ^{\kmat -
     \mat{e}_{n,μ}} + \sqrt{\qty(\kmat_{n,μ} + 1)}  L^†_nψ^{\kmat +
     \mat{e}_{n,μ}} ].
 \end{multline}
@@ -239,7 +239,7 @@ are bosonic Fock-states.
 Now \cref{eq:multihops} becomes
 \begin{equation}
   \label{eq:fockhops}
-  ∂_t\ket{Ψ} = \qty[-i H_\sys + \vb{L}\cdot\vb{η}^\ast -
+  ∂_t\ket{Ψ} = \qty[-\iu H_\sys + \vb{L}\cdot\vb{η}^\ast -
   ∑_{n=1}^N∑_{μ=1}^{M_n}b_{n,μ}^\dag b_{n,μ} W\nth_μ +
-  i∑_{n=1}^N∑_{μ=1}^{M_n} \sqrt{G_{n,μ}} \qty(b^†_{n,μ}L_n + b_{n,μ}L^†_n)] \ket{Ψ}.
+  \iu ∑_{n=1}^N∑_{μ=1}^{M_n} \sqrt{G_{n,μ}} \qty(b^†_{n,μ}L_n + b_{n,μ}L^†_n)] \ket{Ψ}.
 \end{equation}