Cheetah - SKA - PSS - Prototype Time Domain Search Pipeline
Static Public Member Functions | List of all members
ska::cheetah::pipeline::test::SinglePulseTests< NumericalT > Struct Template Reference
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Static Public Member Functions

static void run ()
 

Detailed Description

template<typename NumericalT>
struct ska::cheetah::pipeline::test::SinglePulseTests< NumericalT >

Definition at line 60 of file SinglePulseTest.cpp.

Member Function Documentation

◆ run()

template<typename NumericalT >
static void ska::cheetah::pipeline::test::SinglePulseTests< NumericalT >::run ( )
inlinestatic

Search ~600 seconds of data at standard resoluton

Configure components

Definition at line 62 of file SinglePulseTest.cpp.

63  {
67  typedef typename data::TimeFrequency<Cpu, NumericalT>::TimePointType TimePointType;
68  typedef typename data::TimeFrequency<Cpu, NumericalT>::DataType DataType;
69 
70 
74  CheetahConfig<NumericalT> config;
75 
76  //Configure high density low DMs
77  ddtr::DedispersionConfig dd_config_low;
78  config.sps_config().dedispersion_config(dd_config_low);
79  dd_config_low.dm_start(ddtr::DedispersionConfig::Dm(0.0 * data::parsecs_per_cube_cm));
80  dd_config_low.dm_end(ddtr::DedispersionConfig::Dm(100.0 * data::parsecs_per_cube_cm));
81  dd_config_low.dm_step(ddtr::DedispersionConfig::Dm(0.1 * data::parsecs_per_cube_cm));
82 
83  //Configure low density high DMs
84  /*
85  ddtr::DedispersionConfig dd_config_high;
86  config.sps_config().dedispersion_config(dd_config_high);
87  dd_config_high.dm_start(ddtr::DedispersionConfig::Dm(200.0 * data::parsecs_per_cube_cm));
88  dd_config_high.dm_end(ddtr::DedispersionConfig::Dm(300.0 * data::parsecs_per_cube_cm));
89  dd_config_high.dm_step(ddtr::DedispersionConfig::Dm(1.0 * data::parsecs_per_cube_cm));
90 */
91 
92  //Set sps priority
93  config.sps_config().set_priority(0);
94 
95  //Set the size of the dedispersion buffer
96  config.sps_config().set_dedispersion_samples(1<<18);
97 
98  //Set up noise parameters for data to be passed through
99  //the pipeline
100  generators::GaussianNoiseConfig noise_config;
101  noise_config.mean(96.0);
102  noise_config.std_deviation(10.0);
103  generators::GaussianNoise<DataType> noise(noise_config);
104  BeamConfig<uint8_t> beam_config;
105 
106  //Start epoch
107  typename utils::ModifiedJulianClock::time_point epoch(utils::julian_day(50000.0));
108  TestSinglePulsePipeline<NumericalT> pipeline(config, beam_config);
109 
110  double tsamp_us = 64.0;
111  double f_low = 1.2;
112  double f_high = 1.8;
113  std::size_t total_nsamps = std::size_t(10.0 / (tsamp_us * 1e-6));
114  data::DimensionSize<data::Time> number_of_samples(1<<15);
115  data::DimensionSize<data::Frequency> number_of_channels(1024);
116  std::size_t loop_count = total_nsamps/number_of_samples + 10;
117  for (std::size_t ii=0; ii<loop_count; ++ii)
118  {
119  std::cout << "Building next time frequency block..." << std::endl;
120  auto tf = std::make_shared<data::TimeFrequency<Cpu, uint8_t>>(number_of_samples, number_of_channels);
121  auto f1 = data::TimeFrequency<Cpu, uint8_t>::FrequencyType(f_high * boost::units::si::giga * boost::units::si::hertz);
122  auto f2 = data::TimeFrequency<Cpu, uint8_t>::FrequencyType(f_low * boost::units::si::giga * boost::units::si::hertz);
123  auto delta = (f2 - f1)/ (double)number_of_channels;
124  tf->set_channel_frequencies_const_width( f1, delta );
125  tf->sample_interval(typename data::TimeFrequency<Cpu, uint8_t>::TimeType(tsamp_us * boost::units::si::micro * data::seconds));
126  tf->start_time(epoch);
127  epoch += std::chrono::duration<double>(tf->sample_interval().value()*number_of_samples);
128  std::cout << "Time frequency block " << ii << " dispatched to pipeline." << std::endl;
129  noise.next(*tf);
130  pipeline(*tf);
131  }
132  }
NumericalT DataType
the underlying data storage type for the amplitude of the signal
Definition: TimeFrequency.h:96
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The documentation for this struct was generated from the following file: