mirror of https://github.com/m-labs/artiq.git
doc: update overview slides
This commit is contained in:
parent
15d09c0b94
commit
6062b42117
|
@ -1,92 +1,177 @@
|
|||
\documentclass{beamer}
|
||||
\usepackage{marvosym}
|
||||
\usepackage{wasysym}
|
||||
\usepackage{siunitx}
|
||||
\usepackage{moreverb}
|
||||
\usepackage{lato}
|
||||
\documentclass[final,presentation,compress]{beamer}
|
||||
\usepackage[mathcal]{euler}
|
||||
\usepackage{amsmath, amssymb, amsopn} %amssymb,amstext
|
||||
\usepackage[cm-default]{fontspec}
|
||||
\usepackage{xltxtra}
|
||||
\usepackage[english]{babel}
|
||||
\usepackage{multicol}
|
||||
\usepackage{multimedia}
|
||||
\usepackage{tikz}
|
||||
\usetikzlibrary{arrows,shapes,snakes,positioning,backgrounds,decorations,graphs}
|
||||
\definecolor{ethblue}{rgb}{0, 0.2, 0.3568}
|
||||
\usepackage{minted}
|
||||
|
||||
\definecolor{UniBlue}{RGB}{43,61,81}
|
||||
\definecolor{UniBlueHL}{RGB}{67,98,129}
|
||||
\definecolor{UniGreen}{RGB}{54,188,123}
|
||||
\mode<presentation>
|
||||
{
|
||||
\useoutertheme{default} % simplistic
|
||||
\setbeamertemplate{headline}[default] % kill the headline
|
||||
\setbeamertemplate{navigation symbols}{} % no navigaton stuff in lr corner
|
||||
\useinnertheme{circles}
|
||||
\setbeamercolor*{palette primary}{use=structure,fg=white,bg=ethblue!70}
|
||||
\setbeamercolor*{palette secondary}{use=structure,fg=white,bg=ethblue!80}
|
||||
\setbeamercolor*{palette tertiary}{use=structure,fg=white,bg=ethblue!90}
|
||||
\setbeamercolor*{palette quaternary}{use=structure,fg=white,bg=ethblue!100}
|
||||
\setbeamercolor*{structure}{fg=ethblue!70}
|
||||
\hypersetup{
|
||||
}
|
||||
\setbeamercovered{invisible}
|
||||
}
|
||||
|
||||
\renewcommand*{\familydefault}{fla}
|
||||
\renewcommand*{\sfdefault}{fla}
|
||||
\graphicspath{{fig//}}
|
||||
|
||||
\setbeamercolor{title}{fg=white}
|
||||
\setbeamercolor{frametitle}{fg=UniGreen}
|
||||
\setbeamercolor{structure}{fg=white}
|
||||
\setbeamercolor{normal text}{fg=white}
|
||||
\setbeamercolor{background canvas}{bg=UniBlue}
|
||||
\title{The ARTIQ experiment control system}
|
||||
\author[S]{{\bf S\'ebastien~Bourdeauducq}}
|
||||
\institute[S]{
|
||||
M-Labs Ltd, Hong Kong -- \url{http://m-labs.hk}
|
||||
}
|
||||
|
||||
\begin{document}
|
||||
\fontseries{l}\selectfont
|
||||
|
||||
\title{ARTIQ}
|
||||
\subtitle{A new control system for trapped ion experiments}
|
||||
\author{\fontseries{el}\selectfont S\'ebastien Bourdeauducq}
|
||||
\date{\fontseries{el}\selectfont july 2014}
|
||||
|
||||
\frame{\titlepage}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{\fontseries{l}\selectfont Key points}
|
||||
\begin{itemize}
|
||||
\item High performance --- nanosecond resolution, hundreds of ns latency
|
||||
\item Expressive --- describe algorithms with few lines of code
|
||||
\item Portable --- treat FPGA boards as commodity
|
||||
\item Modular --- separate components as much as possible
|
||||
\item Flexible --- hard-code as little as possible
|
||||
\end{itemize}
|
||||
\begin{frame}[plain]
|
||||
\titlepage
|
||||
\tikz[overlay,remember picture]\node[anchor=south,above=-.5cm] at (current page.south)
|
||||
{\includegraphics[width=\paperwidth]{hong_kong}};
|
||||
\tikz[overlay,remember picture]\node[anchor=south east, fill=white,
|
||||
inner sep=.3mm] at (current page.south east) {%
|
||||
\tiny David Iliff, CC-BY-SA};
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{\fontseries{l}\selectfont Kernels}
|
||||
\begin{itemize}
|
||||
\item The real-time parts of the experiments
|
||||
\item Written in a subset of Python
|
||||
\item Executed on a CPU embedded in a FPGA (\textit{core device})
|
||||
\item Special constructs to specify timing
|
||||
\end{itemize}
|
||||
\includegraphics[width=\columnwidth]{jost_trap-3}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Quantum gate sequences (NIST)}
|
||||
\includegraphics[width=\columnwidth]{gate_sequence}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\begin{tikzpicture}[box/.style={rectangle,fill=white}]
|
||||
\node[inner sep=0] {\includegraphics[width=\columnwidth]{lab}};\pause
|
||||
%\draw[help lines,white] (-4, -3) grid (4, 3);
|
||||
\node[box] at (-4, -2) {FPGA};
|
||||
\node[box] at (3.5, 0) {ion trap};
|
||||
\node[box] at (-3, 3) {$\sim$10 attenuators};
|
||||
\node[box] at (2, 2) {$\sim$50 DAC};
|
||||
\node[box] at (-4, 0) {$\sim$20 DDS};
|
||||
\node[box] at (-2, 1) {$\sim$50 GPIO};
|
||||
\node[box] at (.5, 0) {$\sim$10 motors};
|
||||
\node[box] at (2, -2) {$\sim$10 power supplies};
|
||||
\node[box] at (4, -3) {$\sim$10 lasers};
|
||||
\end{tikzpicture}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Enter ARTIQ}
|
||||
\alert{A}dvanced \alert{R}eal-\alert{T}ime \alert{I}nfrastructure for \alert{Q}uantum physics
|
||||
|
||||
\footnotesize
|
||||
\begin{itemize}
|
||||
\item High performance --- nanosecond resolution, hundreds of ns latency
|
||||
\item Expressive --- describe algorithms with few lines of code
|
||||
\item Portable --- treat hardware, especially FPGA boards, as commodity
|
||||
\item Modular --- separate components as much as possible
|
||||
\item Flexible --- hard-code as little as possible
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{\fontseries{l}\selectfont Timing}
|
||||
\begin{itemize}
|
||||
\item Exact time of interactions with the outside world is kept in an internal variable
|
||||
\item That variable only loosely tracks the execution time of CPU instructions
|
||||
\item The value of that variable is exchanged with the \textit{RTIO core} that does precise timing
|
||||
\end{itemize}
|
||||
\begin{verbatimtab}
|
||||
self.mains_sync.wait_edge()
|
||||
for i in range(10):
|
||||
delay(10*us)
|
||||
self.X.pulse(100*MHz, 100*us)
|
||||
\end{verbatimtab}
|
||||
\center First X pulse is emitted exactly \SI{10}{\micro\second} after mains edge
|
||||
\frametitle{Define a simple timing language}
|
||||
\footnotesize
|
||||
|
||||
\begin{minted}[frame=leftline]{python}
|
||||
trigger.sync() # wait for trigger input
|
||||
start = now() # capture trigger time
|
||||
for i in range(3):
|
||||
delay(5*us)
|
||||
dds.pulse(900*MHz, 7*us) # first pulse 5 µs after trigger
|
||||
at(start + 1*ms) # re-reference time-line
|
||||
dds.pulse(200*MHz, 11*us) # exactly 1 ms after trigger
|
||||
\end{minted}
|
||||
|
||||
\begin{itemize}
|
||||
\item Written in a subset of Python
|
||||
\item Executed on a CPU embedded on a FPGA (the \emph{core device})
|
||||
\item \verb!now(), at(), delay()! describe time-line of an experiment
|
||||
\item Exact time is kept in an internal variable
|
||||
\item That variable only loosely tracks the execution time of CPU instructions
|
||||
\item The value of that variable is exchanged with the RTIO fabric that
|
||||
does precise timing
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{\fontseries{l}\selectfont Parallel and sequential blocks}
|
||||
\begin{itemize}
|
||||
\item All statements in a \verb!parallel! block are executed at the same exact time
|
||||
\item A \verb!parallel! block can spawn a \verb!sequential! block, where exact time increases
|
||||
\item \verb!Parallel! and \verb!sequential! blocks can be arbitrarily nested
|
||||
\end{itemize}
|
||||
\begin{verbatimtab}
|
||||
with parallel:
|
||||
with sequential:
|
||||
self.a.pulse(100*MHz, 20*us)
|
||||
self.b.pulse(200*MHz, 20*us)
|
||||
with sequential:
|
||||
self.c.pulse(300*MHz, 10*us)
|
||||
self.d.pulse(400*MHz, 20*us)
|
||||
\end{verbatimtab}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{\fontseries{l}\selectfont Object orientation and code reuse}
|
||||
\begin{verbatimtab}
|
||||
class Main(AutoDB):
|
||||
\frametitle{Convenient syntax additions}
|
||||
\footnotesize
|
||||
\begin{minted}[frame=leftline]{python}
|
||||
with sequential:
|
||||
with parallel:
|
||||
a.pulse(100*MHz, 10*us)
|
||||
b.pulse(200*MHz, 20*us)
|
||||
with parallel:
|
||||
c.pulse(300*MHz, 30*us)
|
||||
d.pulse(400*MHz, 20*us)
|
||||
\end{minted}
|
||||
|
||||
\begin{itemize}
|
||||
\item Experiments are inherently parallel:
|
||||
simultaneous laser pulses, parallel cooling of ions in different trap zones
|
||||
\item \verb!parallel! and \verb!sequential! contexts with arbitrary nesting
|
||||
\item \verb!a! and \verb!b! pulses both start at the same time
|
||||
\item \verb!c! and \verb!d! pulses both start when \verb!a! and \verb!b! are both done
|
||||
(after 20\,µs)
|
||||
\item Implemented by inlining, loop-unrolling, and interleaving
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{Physical quantities, hardware granularity}
|
||||
\footnotesize
|
||||
\begin{minted}[frame=leftline]{python}
|
||||
n = 1000
|
||||
dt = 1.2345*ns
|
||||
f = 345*MHz
|
||||
|
||||
dds.on(f, phase=0) # must round to integer tuning word
|
||||
for i in range(n):
|
||||
delay(dt) # must round to native cycles
|
||||
|
||||
dt_raw = time_to_cycles(dt) # integer number of cycles
|
||||
f_raw = dds.frequency_to_ftw(f) # integer frequency tuning word
|
||||
|
||||
# determine correct phase despite accumulation of rounding errors
|
||||
phi = n*cycles_to_time(dt_raw)*dds.ftw_to_frequency(f_raw)
|
||||
\end{minted}
|
||||
|
||||
\begin{itemize}
|
||||
\item Need well defined conversion and rounding of physical quantities
|
||||
(time, frequency, phase, etc.) to hardware granularity and back
|
||||
\item Complicated because of calibration, offsets, cable delays,
|
||||
non-linearities
|
||||
\item No generic way to do it automatically and correctly
|
||||
\item $\rightarrow$ need to do it explicitly where it matters
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{Invite organizing experiment components and code reuse}
|
||||
\footnotesize
|
||||
|
||||
\begin{minted}[frame=leftline]{python}
|
||||
class Experiment:
|
||||
def build(self):
|
||||
self.ion1 = Ion(...)
|
||||
self.ion2 = Ion(...)
|
||||
|
@ -94,48 +179,104 @@ class Main(AutoDB):
|
|||
|
||||
@kernel
|
||||
def run(self):
|
||||
self.ion1.cool(duration=10*us)
|
||||
self.ion2.cool(frequency=...)
|
||||
with parallel:
|
||||
self.ion1.cool(duration=10*us)
|
||||
self.ion2.cool(frequency=...)
|
||||
self.transporter.move(speed=...)
|
||||
delay(100*ms)
|
||||
self.ion1.detect(duration=...)
|
||||
\end{verbatimtab}
|
||||
\end{minted}
|
||||
\end{frame}
|
||||
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{\fontseries{l}\selectfont Communication with the kernel}
|
||||
\begin{itemize}
|
||||
\item When the kernel function calls a non-kernel function, it generates a RPC
|
||||
\item The callee is executed on the host
|
||||
\item The callee may receive parameters from the kernel and may return a value to the kernel
|
||||
\item The kernel must have a loose real-time constraint (a long \verb!delay!) to cover communication and host delays
|
||||
\item Mechanism to report results and control slow devices
|
||||
\end{itemize}
|
||||
\frametitle{RPC to handle distributed non-RT hardware}
|
||||
\footnotesize
|
||||
|
||||
\begin{minted}[frame=leftline]{python}
|
||||
class Experiment:
|
||||
def prepare(self): # runs on the host
|
||||
self.motor.move_to(20*mm) # slow RS232 motor controller
|
||||
|
||||
@kernel
|
||||
def run(self): # runs on the RT core device
|
||||
self.prepare() # converted into an RPC
|
||||
\end{minted}
|
||||
|
||||
\begin{itemize}
|
||||
\item When a kernel function calls a non-kernel function, it generates a RPC
|
||||
\item The callee is executed on the host
|
||||
\item Mechanism to report results and control slow devices
|
||||
\item The kernel must have a loose real-time constraint (a long \verb!delay!)
|
||||
or means of re-synchronization to cover communication, host, and device delays
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{\fontseries{l}\selectfont Kernel deployment process}
|
||||
\begin{enumerate}
|
||||
\item Constants and called kernels are inlined
|
||||
\item Loops are unrolled
|
||||
\item Statements from concurrent sequential blocks are interleaved. Threads are currently unsupported.
|
||||
\item Time is converted to RTIO clock units
|
||||
\item The Python AST is converted to LLVM IR
|
||||
\item The LLVM IR is compiled to OpenRISC machine code
|
||||
\item The OpenRISC binary is sent to the core device
|
||||
\item The runtime in the core device links and run the kernel
|
||||
\item The kernel calls the runtime for communication (RPC) and access to core device peripherals (RTIO, DDS)
|
||||
\end{enumerate}
|
||||
\frametitle{Kernel deployment to the core device}
|
||||
\footnotesize
|
||||
\begin{itemize}
|
||||
\item RPC and exception mappings are generated
|
||||
\item Constants and small kernels are inlined
|
||||
\item Small loops are unrolled
|
||||
\item Statements in parallel blocks are interleaved
|
||||
\item Time is converted to RTIO clock cycles
|
||||
\item The Python AST is converted to LLVM IR
|
||||
\item The LLVM IR is compiled to OpenRISC machine code
|
||||
\item The OpenRISC binary is sent to the core device
|
||||
\item The runtime in the core device links and runs the kernel
|
||||
\item The kernel calls the runtime for communication (RPC) and interfacing
|
||||
with core device peripherals (RTIO, DDS)
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}[fragile]
|
||||
\frametitle{\fontseries{l}\selectfont Channels and parameters}
|
||||
\begin{itemize}
|
||||
\item A kernel is a method of a class
|
||||
\item The entry point for an experiment is called \verb!run! --- may or may not be a kernel
|
||||
\item The \verb!AutoDB! class manages channels and parameters
|
||||
\item If channels/parameters are passed as constructor arguments, those are used
|
||||
\item Otherwise, they are looked up in the device and parameter databases
|
||||
\end{itemize}
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Higher level features}
|
||||
\footnotesize
|
||||
\begin{itemize}
|
||||
\item Device management: drivers, remote devices, device database
|
||||
\item Parameter database \\
|
||||
e.g.\ ion properties such as qubit flopping frequency
|
||||
\item Scheduling of experiments \\
|
||||
e.g.\ calibrations, queue
|
||||
\item Archival of results (HDF5 format)
|
||||
\item Graphical user interface \\
|
||||
run with arguments, schedule, real-time plotting
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
|
||||
\begin{frame}
|
||||
\frametitle{Short-term hardware support}
|
||||
\footnotesize
|
||||
\begin{itemize}
|
||||
\item Core device: Papilio Pro, Pipistrello, KC705
|
||||
\item High speed DDS with AD9858 and AD9914 \\
|
||||
(direct core device, $ < 25$ channels)
|
||||
\item Waveform generation: PDQ (NIST), PXI6733
|
||||
\item Lab Brick Digital Attenuators
|
||||
\item Novatech 409B DDS
|
||||
\item Thorlabs motor controllers
|
||||
\end{itemize}
|
||||
\end{frame}
|
||||
|
||||
\begin{frame}
|
||||
\begin{center}
|
||||
\includegraphics[width=3cm]{../../logo/artiq.pdf} \\
|
||||
\url{http://m-labs.hk/artiq}
|
||||
\end{center}
|
||||
|
||||
\footnotesize
|
||||
\begin{itemize}
|
||||
\item Public mailing list (with archives)
|
||||
\item Full source code, BSD licensed
|
||||
\item Design applicable beyond ion trapping (superconducting qubits,
|
||||
neutral atoms...)
|
||||
\end{itemize}
|
||||
\textit{Thanks to Robert J\"ordens, Joe Britton, Daniel Slichter and other members of the NIST Ion Storage Group for their support in developing ARTIQ.}
|
||||
|
||||
\end{frame}
|
||||
|
||||
\end{document}
|
||||
|
|
Binary file not shown.
After Width: | Height: | Size: 208 KiB |
Loading…
Reference in New Issue