示例#1
0
	def __init__(self, name = "baserfgap"):
		"""
		Constructor for the simplest RF gap. 
		E0L and E0TL parameters are in GeV. Phases are in radians.
		"""
		AbstractRF_Gap.__init__(self,name)		
		self.addParam("E0TL",0.)
		self.addParam("mode",0.)		
		self.addParam("gap_phase",0.)
		self.addParam("rfCavity", None)
		#----- TTF model params ------
		self.addParam("E0L",0.)	
		self.polyT = Polynomial(0)
		self.polyT.coefficient(0,1.0)
		self.polyS = Polynomial(0)
		self.polyS.coefficient(0,0.0)
		self.polyTp = Polynomial(0)
		self.polyTp.coefficient(0,0.0)
		self.polySp = Polynomial(0)
		self.polySp.coefficient(0,0.0)
		self.addParam("beta_min",0.)
		self.addParam("beta_max",1.)
		#-----------------------------
		self.addParam("rfCavity",None)
		self.addParam("EzFile","no_file")
		self.setType("baserfgap")	
		self.__isFirstGap = False
		#---- by default we use the TTF model 
		#---- which is a Transit-Time-Factor model from Parmila
		#self.cppGapModel = MatrixRfGap()
		#self.cppGapModel = BaseRfGap()
		self.cppGapModel = RfGapTTF()
示例#2
0
	def __init__(self, baserf_gap):
		"""
		Constructor for the axis field RF gap. 
		E0L parameter is in GeV. Phases are in radians.
		"""
		AbstractRF_Gap.__init__(self,baserf_gap.getName())
		self.setAsFirstRFGap(baserf_gap.isFirstRFGap())
		self.baserf_gap = baserf_gap
		self.setType("axis_field_rfgap")			
		self.addParam("E0TL",self.baserf_gap.getParam("E0TL"))
		self.addParam("mode",self.baserf_gap.getParam("mode"))
		self.addParam("gap_phase",self.baserf_gap.getParam("gap_phase"))
		self.addParam("rfCavity",self.baserf_gap.getParam("rfCavity"))
		self.addParam("E0L",self.baserf_gap.getParam("E0L"))
		self.addParam("EzFile",self.baserf_gap.getParam("EzFile"))
		self.setPosition(self.baserf_gap.getPosition())
		#---- aperture parameters
		if(baserf_gap.hasParam("aperture") and baserf_gap.hasParam("aprt_type")):
			self.addParam("aperture",baserf_gap.getParam("aperture"))
			self.addParam("aprt_type",baserf_gap.getParam("aprt_type"))
		#---- axis field related parameters
		self.axis_field_func = None
		self.z_step = 0.01
		self.z_min = 0.
		self.z_max = 0.
		self.z_tolerance = 0.000001    # in meters
		self.phase_tolerance = 0.001   # in degrees
		#---- gap_phase_vs_z_arr keeps [pos,phase] pairs after the tracking
		self.gap_phase_vs_z_arr = []
		#---- The position of the particle during the run. 
		#---- It is used for the path length accounting.
		self.part_pos = 0.
		#---- The RF gap model - three points model
		self.cppGapModel = RfGapThreePointTTF()
	def __init__(self, name = "baserfgap"):
		"""
		Constructor for the simplest RF gap. 
		E0L and E0TL parameters are in GeV. Phases are in radians.
		"""
		AbstractRF_Gap.__init__(self,name)
		self.addParam("E0TL",0.)
		self.addParam("mode",0.)		
		self.addParam("gap_phase",0.)
		self.addParam("rfCavity", None)
		#----- TTF model params ------
		self.addParam("E0L",0.)	
		self.polyT = Polynomial(0)
		self.polyT.coefficient(0,1.0)
		self.polyS = Polynomial(0)
		self.polyS.coefficient(0,0.0)
		self.polyTp = Polynomial(0)
		self.polyTp.coefficient(0,0.0)
		self.polySp = Polynomial(0)
		self.polySp.coefficient(0,0.0)
		self.addParam("beta_min",0.)
		self.addParam("beta_max",1.)
		#-----------------------------
		self.addParam("rfCavity",None)
		self.addParam("EzFile","no_file")
		self.setType("baserfgap")	
		self.__isFirstGap = False
		self.cppGapModel = MatrixRfGap()
		self.cppGapModel = BaseRfGap()
		self.cppGapModel = RfGapTTF()
示例#4
0
    def __init__(self, axis_field_rf_gap):
        """
		Constructor for the axis field RF gap. 
		The axis_field_rf_gap is the instance of the AbstractRF_Gap class.
		E0L parameter is in GeV. Phases are in radians.
		"""
        AbstractRF_Gap.__init__(self, axis_field_rf_gap.getName())
        self.setType("GAP&Q")
        self.axis_field_rf_gap = axis_field_rf_gap
        self.addParam("E0TL", self.axis_field_rf_gap.getParam("E0TL"))
        self.addParam("mode", self.axis_field_rf_gap.getParam("mode"))
        self.addParam("gap_phase",
                      self.axis_field_rf_gap.getParam("gap_phase"))
        self.addParam("rfCavity", self.axis_field_rf_gap.getParam("rfCavity"))
        self.addParam("E0L", self.axis_field_rf_gap.getParam("E0L"))
        self.addParam("EzFile", self.axis_field_rf_gap.getParam("EzFile"))
        self.setPosition(self.axis_field_rf_gap.getPosition())
        #---- aperture parameters
        if (axis_field_rf_gap.hasParam("aperture")
                and axis_field_rf_gap.hasParam("aprt_type")):
            self.addParam("aperture", axis_field_rf_gap.getParam("aperture"))
            self.addParam("aprt_type", axis_field_rf_gap.getParam("aprt_type"))
        #---- axis field related parameters
        self.z_step = 0.01
        self.z_min = 0.
        self.z_max = 0.
        #---- gap_phase_vs_z_arr keeps [pos,phase] pairs after the tracking
        self.gap_phase_vs_z_arr = []
        #---- The position of the particle during the run.
        #---- It is used for the path length accounting.
        self.part_pos = 0.
        #---- The RF gap model - three points model
        self.cppGapModel = RfGapThreePointTTF()
        #---- If we going to use the longitudinal magnetic field component of quad
        self.useLongField = False
        #---- quadrupole field sources
        #----quads_fields_arr is an array of [quad, fieldFunc, z_center_of_field]
        self.quads_fields_arr = []
        #---- If it is true then the this tracking will be in the reversed lattice
        self.reversed_lattice = False