damaris-backends/machines/PFGcore.cpp

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2014-06-26 11:10:51 +00:00
/* **************************************************************************
Author: Achim Gaedke
Created: June 2004
****************************************************************************/
#include "machines/hardware.h"
#include "core/core.h"
#include "drivers/Tecmag-DAC20/DAC20.h"
#include "drivers/PTS-Synthesizer/PTS.h"
#include "drivers/Spectrum-MI40xxSeries/Spectrum-MI40xxSeries.h"
#include "drivers/SpinCore-PulseBlaster24Bit/SpinCore-PulseBlaster24Bit.h"
/**
\defgroup pfgmachine PFG NMR Spectrometer
\ingroup machines
Uses Spincore Pulseblaster 24 Bit, Spectrum MI4021, one DAC20 and a synchronization board.
\li line 0 for gate
\li line 1 for pulse
\li line 22 for trigger
\li line 23 for synchronization
\par Starting the hardware
This procedure should assure the correct initialisation of the hardware:
\li Switch off main switches of SpinCore Pulseblaster and Computer (the main switch of the computer is at the rear)
\li Switch on Computer and start Windows or linux
@{
*/
class PFG_hardware: public hardware
{
SpinCorePulseBlaster24Bit* my_pulseblaster;
SpectrumMI40xxSeries* my_adc;
public:
PFG_hardware()
{
ttlout trigger;
trigger.id = 0;
/* trigger on line 22 */
trigger.ttls = 1 << 22;
my_adc = new SpectrumMI40xxSeries(trigger);
/* device_id = 0, clock = 100 MHz, sync_mask = Bit 23 */
my_pulseblaster = new SpinCorePulseBlaster24Bit(0, 1e8, 1 << 23);
/* PTS has analog id = 0 */
PTS* my_pts = new PTS_latched(0);
the_fg = my_pts;
the_pg = my_pulseblaster;
the_adc = my_adc;
/* DAC has analog id = 1 */
DAC20* my_pfg = new DAC20(1);
list_dacs.push_back(my_pfg);
}
result* experiment(const state& exp)
{
result* r = NULL;
for (size_t tries = 0; r == NULL && core::term_signal == 0 && tries < 102; ++tries)
{
state* work_copy = exp.copy_flat();
if (work_copy == NULL)
return new error_result(1, "could create work copy of experiment sequence");
try
{
if (the_fg != NULL)
the_fg->set_frequency(*work_copy);
if (the_adc != NULL)
the_adc->set_daq(*work_copy);
experiment_prepare_dacs(work_copy);
// the pulse generator is necessary
my_pulseblaster->run_pulse_program_w_sync(*work_copy, my_adc->get_sample_clock_frequency());
// wait for pulse generator
the_pg->wait_till_end();
// after that, the result must be available
if (the_adc != NULL)
r = the_adc->get_samples();
else
r = new adc_result(1, 0, NULL);
}
catch (const RecoverableException &e)
{
r = new error_result(1, e.what());
}
delete work_copy;
if (core::quit_signal != 0)
break;
}
return r;
}
virtual ~PFG_hardware()
{
if (the_adc != NULL)
delete the_adc;
if (the_pg != NULL)
delete the_pg;
if (the_fg != NULL)
delete the_fg;
}
};
/**
\brief brings standard core together with the Mobile NMR hardware
*/
class PFG_core: public core
{
std::string the_name;
public:
PFG_core(const core_config& conf) :
core(conf)
{
the_hardware = new PFG_hardware();
the_name = "PFG core";
}
virtual const std::string& core_name() const
{
return the_name;
}
};
/**
@}
*/
int main(int argc, const char** argv)
{
int return_result = 0;
try
{
core_config my_conf(argv, argc);
// setup input and output
PFG_core my_core(my_conf);
// start core application
my_core.run();
}
catch (const DamarisException& e)
{
fprintf(stderr, "%s\n", e.what());
return_result = 1;
}
return return_result;
}