mirror of https://github.com/m-labs/artiq.git
doc: update slides with new API
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@ -91,18 +91,19 @@ inner sep=.3mm] at (current page.south east) {%
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\begin{minted}[frame=leftline]{python}
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trigger.sync() # wait for trigger input
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start = now() # capture trigger time
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start = now_mu() # capture trigger time
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for i in range(3):
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delay(5*us)
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dds.pulse(900*MHz, 7*us) # first pulse 5 µs after trigger
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at(start + 1*ms) # re-reference time-line
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# re-reference time-line
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at(start + seconds_to_mu(1*ms))
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dds.pulse(200*MHz, 11*us) # exactly 1 ms after trigger
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\end{minted}
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\begin{itemize}
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\item Written in a subset of Python
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\item Executed on a CPU embedded on a FPGA (the \emph{core device})
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\item \verb!now(), at(), delay()! describe time-line of an experiment
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\item \verb!now_mu(), at_mu(), delay_mu(), delay()! describe time-line of an experiment
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\item Exact time is kept in an internal variable
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\item That variable only loosely tracks the execution time of CPU instructions
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\item The value of that variable is exchanged with the RTIO fabric that
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@ -148,11 +149,12 @@ dds.on(f, phase=0) # must round to integer tuning word
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for i in range(n):
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delay(dt) # must round to native cycles
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dt_raw = time_to_cycles(dt) # integer number of cycles
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dt_raw = seconds_to_mu(dt) # integer number of cycles
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f_raw = dds.frequency_to_ftw(f) # integer frequency tuning word
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# determine correct phase despite accumulation of rounding errors
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phi = n*cycles_to_time(dt_raw)*dds.ftw_to_frequency(f_raw)
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# determine correct (to FP precision) phase
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# despite accumulation of rounding errors
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phi = mu_to_seconds(n*dt_raw)*dds.ftw_to_frequency(f_raw)
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\end{minted}
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\begin{itemize}
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@ -105,18 +105,19 @@ inner sep=.3mm] at (current page.south east) {%
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\begin{minted}[frame=leftline]{python}
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trigger.sync() # wait for trigger input
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start = now() # capture trigger time
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start = now_mu() # capture trigger time
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for i in range(3):
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delay(5*us)
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dds.pulse(900*MHz, 7*us) # first pulse 5 µs after trigger
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at(start + 1*ms) # re-reference time-line
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# re-reference time-line
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at_mu(start + seconds_to_mu(1*ms))
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dds.pulse(200*MHz, 11*us) # exactly 1 ms after trigger
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\end{minted}
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\begin{itemize}
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\item Written in a subset of Python
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\item Executed on a CPU embedded on a FPGA (the \emph{core device})
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\item \verb!now(), at(), delay()! describe time-line of an experiment
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\item \verb!now_mu(), at_mu(), delay_mu(), delay()! describe time-line of an experiment
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\item Exact time is kept in an internal variable
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\item That variable only loosely tracks the execution time of CPU instructions
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\item The value of that variable is exchanged with the RTIO fabric that
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@ -162,11 +163,12 @@ dds.on(f, phase=0) # must round to integer tuning word
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for i in range(n):
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delay(dt) # must round to native cycles
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dt_raw = time_to_cycles(dt) # integer number of cycles
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dt_raw = seconds_to_mu(dt) # integer number of cycles
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f_raw = dds.frequency_to_ftw(f) # integer frequency tuning word
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# determine correct phase despite accumulation of rounding errors
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phi = n*cycles_to_time(dt_raw)*dds.ftw_to_frequency(f_raw)
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# determine correct (to FP precision) phase
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# despite accumulation of rounding errors
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phi = n*mu_to_seconds(dt_raw)*dds.ftw_to_frequency(f_raw)
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\end{minted}
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\begin{itemize}
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