def process(self, order = 0.998, solution=solve_type.FAST, collect_dynamic=True):
"""!
@brief Peforms cluster analysis using simulation of the oscillatory network.
@param[in] order (double): Order of synchronization that is used as indication for stopping processing.
@param[in] solution (solve_type): Specified type of solving diff. equation.
@param[in] collect_dynamic (bool): Specified requirement to collect whole dynamic of the network.
@return (syncnet_analyser) Returns analyser of results of clustering.
"""
if self._ccore_network_pointer is not None:
pointer_output_dynamic = syncnet_process(self._ccore_network_pointer, order, solution, collect_dynamic)
return syncnet_analyser(None, None, pointer_output_dynamic)
else:
output_sync_dynamic = self.simulate_dynamic(order, solution, collect_dynamic)
return syncnet_analyser(output_sync_dynamic.output, output_sync_dynamic.time, None)
def process(self, order = 0.998, solution = solve_type.FAST, collect_dynamic = True):
"""!
@brief Peforms cluster analysis using simulation of the oscillatory network.
@param[in] order (double): Order of synchronization that is used as indication for stopping processing.
@param[in] solution (solve_type): Specified type of solving diff. equation.
@param[in] collect_dynamic (bool): Specified requirement to collect whole dynamic of the network.
@return (syncnet_analyser) Returns analyser of results of clustering.
"""
if (self.__ccore_network_pointer is not None):
pointer_output_dynamic = syncnet_process(self.__ccore_network_pointer, order, solution, collect_dynamic);
return syncnet_analyser(None, None, pointer_output_dynamic);
else:
output_sync_dynamic = self.simulate_dynamic(order, solution, collect_dynamic);
return syncnet_analyser(output_sync_dynamic.output, output_sync_dynamic.time, None);