def sync_to_restore(self): if not hasattr(self, 'ro_version'): self.ro_version = rayoptics.__version__ self.seq_model.sync_to_restore(self) self.ele_model.sync_to_restore(self) self.optical_spec.sync_to_restore(self) if hasattr(self, 'parax_model'): self.parax_model.sync_to_restore(self) else: self.parax_model = ParaxialModel(self) if hasattr(self, 'specsheet'): self.specsheet.sync_to_restore(self) else: self.specsheet = None if hasattr(self, 'part_tree'): self.part_tree.sync_to_restore(self) else: self.part_tree = PartTree(self) self.part_tree.add_element_model_to_tree(self.ele_model) self.map_submodels() self.update_model()
def __init__(self, radius_mode=False, specsheet=None, **kwargs): self.ro_version = rayoptics.__version__ self.radius_mode = radius_mode self.specsheet = specsheet self.system_spec = SystemSpec() self.seq_model = SequentialModel(self, **kwargs) self.optical_spec = OpticalSpecs(self, **kwargs) self.parax_model = ParaxialModel(self, **kwargs) self.ele_model = ElementModel(self, **kwargs) if self.specsheet: self.set_from_specsheet()
def __init__(self, radius_mode=False, specsheet=None, **kwargs): self.ro_version = rayoptics.__version__ self.radius_mode = radius_mode self.specsheet = specsheet self.system_spec = SystemSpec() self.seq_model = SequentialModel(self, **kwargs) self.optical_spec = OpticalSpecs(self, **kwargs) self.parax_model = ParaxialModel(self, **kwargs) self.ele_model = ElementModel(self, **kwargs) if self.specsheet: self.set_from_specsheet() if kwargs.get('do_init', True): # need to do this after OpticalSpec is initialized self.seq_model.update_model()
def sync_to_restore(self): if not hasattr(self, 'ro_version'): self.ro_version = rayoptics.__version__ self.seq_model.sync_to_restore(self) self.ele_model.sync_to_restore(self) self.optical_spec.sync_to_restore(self) if hasattr(self, 'parax_model'): self.parax_model.sync_to_restore(self) else: self.parax_model = ParaxialModel(self) if hasattr(self, 'specsheet'): self.specsheet.sync_to_restore(self) else: self.specsheet = None self.update_model()
class OpticalModel: """ Top level container for optical model. The OpticalModel serves as a top level container of model properties. Key aspects are built-in element and surface based repesentations of the optical surfaces. A sequential optical model is a sequence of surfaces and gaps. Additionally, it includes optical usage information to specify the aperture, field of view, spectrum and focus. Attributes: ro_version: current version of rayoptics radius_mode: if True output radius, else output curvature specsheet: :class:`~rayoptics.parax.specsheet.SpecSheet` system_spec: :class:`.SystemSpec` seq_model: :class:`~rayoptics.seq.sequential.SequentialModel` optical_spec: :class:`~rayoptics.raytr.opticalspec.OpticalSpecs` parax_model: :class:`~rayoptics.parax.paraxialdesign.ParaxialModel` ele_model: :class:`~rayoptics.elem.elements.ElementModel` """ def __init__(self, radius_mode=False, specsheet=None, **kwargs): self.ro_version = rayoptics.__version__ self.radius_mode = radius_mode self.specsheet = specsheet self.system_spec = SystemSpec() self.seq_model = SequentialModel(self, **kwargs) self.optical_spec = OpticalSpecs(self, specsheet=specsheet, **kwargs) self.parax_model = ParaxialModel(self, **kwargs) self.ele_model = ElementModel(self, **kwargs) self.part_tree = PartTree(self, **kwargs) self.map_submodels() if self.specsheet: self.set_from_specsheet() if kwargs.get('do_init', True): # need to do this after OpticalSpec is initialized self.seq_model.update_model() elements_from_sequence(self.ele_model, self.seq_model, self.part_tree) def map_submodels(self): """Setup machinery for model mapping api. """ submodels = {} submodels['specsheet'] = self.specsheet submodels['system_spec'] = self.system_spec submodels['seq_model'] = self.seq_model submodels['optical_spec'] = self.optical_spec submodels['parax_model'] = self.parax_model submodels['ele_model'] = self.ele_model submodels['part_tree'] = self.part_tree # Add a level of indirection to allow short and long aliases submodel_aliases = { 'ss': 'specsheet', 'specsheet': 'specsheet', 'sys': 'system_spec', 'system_spec': 'system_spec', 'sm': 'seq_model', 'seq_model': 'seq_model', 'osp': 'optical_spec', 'optical_spec': 'optical_spec', 'pm': 'parax_model', 'parax_model': 'parax_model', 'em': 'ele_model', 'ele_model': 'ele_model', 'pt': 'part_tree', 'part_tree': 'part_tree', } self._submodels = submodels, submodel_aliases def __getitem__(self, key): """ Provide mapping interface to submodels. """ submodels, submodel_aliases = self._submodels return submodels[submodel_aliases[key]] def name(self): return self.system_spec.title def reset(self): rdm = self.radius_mode self.__init__() self.radius_mode = rdm def __json_encode__(self): attrs = dict(vars(self)) if hasattr(self, 'app_manager'): del attrs['app_manager'] del attrs['_submodels'] return attrs def listobj_str(self): vs = vars(self) o_str = f"{type(self).__name__}:\n" for k, v in vs.items(): o_str += f"{k}: {v}\n" return o_str def set_from_specsheet(self, specsheet=None): if specsheet: self.specsheet = specsheet else: specsheet = self.specsheet self.optical_spec.set_from_specsheet(specsheet) self.seq_model.set_from_specsheet(specsheet) def save_model(self, file_name, version=None): """Save the optical_model in a ray-optics JSON file. Args: file_name: str or Path version: optional override for rayoptics version number """ file_extension = os.path.splitext(file_name)[1] filename = file_name if len(file_extension) > 0 else file_name+'.roa' # update version number prior to writing file. self.ro_version = rayoptics.__version__ if version is None else version fs_dict = {} fs_dict['optical_model'] = self with open(filename, 'w') as f: json_tricks.dump(fs_dict, f, indent=1, separators=(',', ':'), allow_nan=True) def sync_to_restore(self): if not hasattr(self, 'ro_version'): self.ro_version = rayoptics.__version__ self.seq_model.sync_to_restore(self) self.ele_model.sync_to_restore(self) self.optical_spec.sync_to_restore(self) if hasattr(self, 'parax_model'): self.parax_model.sync_to_restore(self) else: self.parax_model = ParaxialModel(self) if hasattr(self, 'specsheet'): self.specsheet.sync_to_restore(self) else: self.specsheet = None if hasattr(self, 'part_tree'): self.part_tree.sync_to_restore(self) else: self.part_tree = PartTree(self) self.part_tree.add_element_model_to_tree(self.ele_model) self.map_submodels() self.update_model() def update_model(self, **kwargs): self.seq_model.update_model(**kwargs) self.optical_spec.update_model(**kwargs) self.parax_model.update_model(**kwargs) self.ele_model.update_model(**kwargs) self.part_tree.update_model(**kwargs) if self.specsheet is None: self.specsheet = create_specsheet_from_model(self) self.map_submodels() def nm_to_sys_units(self, nm): """ convert nm to system units Args: nm (float): value in nm Returns: float: value converted to system units """ return self.system_spec.nm_to_sys_units(nm) def add_lens(self, **kwargs): descriptor = ele.create_lens(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(*descriptor, **kwargs) def add_mirror(self, **kwargs): descriptor = ele.create_mirror(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(*descriptor, **kwargs) def add_thinlens(self, **kwargs): descriptor = ele.create_thinlens(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(*descriptor, **kwargs) def add_dummy_plane(self, **kwargs): descriptor = ele.create_dummy_plane(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(*descriptor, **kwargs) def add_from_file(self, filename, **kwargs): descriptor = ele.create_from_file(filename, **kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(*descriptor, **kwargs) def insert_ifc_gp_ele(self, *descriptor, **kwargs): """ insert interfaces and gaps into seq_model and eles into ele_model Args: descriptor: a tuple of additions for the sequential, element and part tree models kwargs: keyword arguments including idx: insertion point in the sequential model insert: if True, insert the chunk, otherwise replace it t: the thickness following a chuck when inserting """ sm = self['seq_model'] seq, elm, e_node = descriptor if 'idx' in kwargs: sm.cur_surface = kwargs['idx'] idx = sm.cur_surface e_node.parent = self.part_tree.root_node # distinguish between adding a new chunk, which requires splitting a # gap in two, and replacing a node, which uses the existing gaps. ins_prev_gap = False if 'insert' in kwargs: t_after = kwargs['t'] if 't' in kwargs else 0. if sm.get_num_surfaces() == 2: # only object space gap, add image space gap following this gap_label = "Image space" ins_prev_gap = False else: # we have both object and image space gaps; retain the image # space gap by splitting and inserting the new gap before the # inserted chunk, unless we're inserting before idx=1. gap_label = None if idx > 0: ins_prev_gap = True if ins_prev_gap: t_air, sm.gaps[idx].thi = sm.gaps[idx].thi, t_after else: t_air = t_after g, ag, ag_node = ele.create_air_gap(t=t_air, label=gap_label) if not ins_prev_gap: seq[-1][mc.Gap] = g elm.append(ag) ag_node.parent = self.part_tree.root_node else: # replacing an existing node. need to hook new chunk final # interface to the existing gap and following (air gap) element g = sm.gaps[sm.cur_surface+1] seq[-1][mc.Gap] = g ag, ag_node = self.part_tree.parent_object(g, '#airgap') # ag.idx = seq[-1][mc.Intfc] for sg in seq: if ins_prev_gap: gap, g = g, sg[mc.Gap] else: gap = sg[mc.Gap] sm.insert(sg[mc.Intfc], gap, prev=ins_prev_gap) for e in elm: self.ele_model.add_element(e) self.ele_model.sequence_elements() def remove_ifc_gp_ele(self, *descriptor, **kwargs): """ remove interfaces and gaps from seq_model and eles from ele_model """ seq, elm, e_node = descriptor sg = seq[0] idx = self.seq_model.ifcs.index(sg[mc.Intfc]) # verify that the sequences match seq_match = True for i, sg in enumerate(seq): if sg[0] is not self.seq_model.ifcs[idx+i]: seq_match = False break if seq_match: # remove interfaces in reverse for i in range(idx+len(seq)-1, idx-1, -1): self.seq_model.remove(i) for e in elm: self.ele_model.remove_element(e) e_node.parent = None def remove_node(self, e_node): # remove interfaces from seq_model self.seq_model.remove_node(e_node) # remove elements from ele_model self.ele_model.remove_node(e_node) # unhook node e_node.parent = None def rebuild_from_seq(self): """ Rebuild ele_model and part_tree from seq_model. """ self['em'].elements = [] self['pt'].root_node.children = [] elements_from_sequence(self['em'], self['sm'], self['pt'])
class OpticalModel: """ Top level container for optical model. The OpticalModel serves as a top level container of model properties. Key aspects are built-in element and surface based repesentations of the optical surfaces. A sequential optical model is a sequence of surfaces and gaps. Additionally, it includes optical usage information to specify the aperture, field of view, spectrum and focus. Attributes: ro_version: current version of rayoptics radius_mode: if True output radius, else output curvature specsheet: :class:`~rayoptics.parax.specsheet.SpecSheet` system_spec: :class:`.SystemSpec` seq_model: :class:`~rayoptics.seq.sequential.SequentialModel` optical_spec: :class:`~rayoptics.raytr.opticalspec.OpticalSpecs` parax_model: :class:`~rayoptics.parax.paraxialdesign.ParaxialModel` ele_model: :class:`~rayoptics.elem.elements.ElementModel` """ def __init__(self, radius_mode=False, specsheet=None, **kwargs): self.ro_version = rayoptics.__version__ self.radius_mode = radius_mode self.specsheet = specsheet self.system_spec = SystemSpec() self.seq_model = SequentialModel(self, **kwargs) self.optical_spec = OpticalSpecs(self, **kwargs) self.parax_model = ParaxialModel(self, **kwargs) self.ele_model = ElementModel(self, **kwargs) if self.specsheet: self.set_from_specsheet() def name(self): return self.system_spec.title def reset(self): rdm = self.radius_mode self.__init__() self.radius_mode = rdm def __json_encode__(self): # update version number prior to writing file. self.ro_version = rayoptics.__version__ attrs = dict(vars(self)) if hasattr(self, 'app_manager'): del attrs['app_manager'] return attrs def set_from_specsheet(self, specsheet=None): if specsheet: self.specsheet = specsheet else: specsheet = self.specsheet self.seq_model.set_from_specsheet(specsheet) self.optical_spec.set_from_specsheet(specsheet) def save_model(self, file_name): file_extension = os.path.splitext(file_name)[1] filename = file_name if len(file_extension) > 0 else file_name + '.roa' fs_dict = {} fs_dict['optical_model'] = self with open(filename, 'w') as f: json_tricks.dump(fs_dict, f, indent=1, separators=(',', ':'), allow_nan=True) def sync_to_restore(self): if not hasattr(self, 'ro_version'): self.ro_version = rayoptics.__version__ self.seq_model.sync_to_restore(self) self.ele_model.sync_to_restore(self) self.optical_spec.sync_to_restore(self) if hasattr(self, 'parax_model'): self.parax_model.sync_to_restore(self) else: self.parax_model = ParaxialModel(self) if hasattr(self, 'specsheet'): self.specsheet.sync_to_restore(self) else: self.specsheet = None self.update_model() def update_model(self): self.seq_model.update_model() self.optical_spec.update_model() self.parax_model.update_model() self.ele_model.update_model() if self.specsheet is None: self.specsheet = create_specsheet_from_model(self) def nm_to_sys_units(self, nm): """ convert nm to system units Args: nm (float): value in nm Returns: float: value converted to system units """ return self.system_spec.nm_to_sys_units(nm) def add_lens(self, **kwargs): seq, elm = ele.create_lens(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(seq, elm, **kwargs) def add_mirror(self, **kwargs): seq, elm = ele.create_mirror(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(seq, elm, **kwargs) def add_thinlens(self, **kwargs): seq, elm = ele.create_thinlens(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(seq, elm, **kwargs) def add_dummy_plane(self, **kwargs): seq, elm = ele.create_dummy_plane(**kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(seq, elm, **kwargs) def add_from_file(self, filename, **kwargs): seq, elm = ele.create_from_file(filename, **kwargs) kwargs['insert'] = True self.insert_ifc_gp_ele(seq, elm, **kwargs) def insert_ifc_gp_ele(self, *args, **kwargs): """ insert interfaces and gaps into seq_model and eles into ele_model """ seq, elm = args if 'idx' in kwargs: self.seq_model.cur_surface = kwargs['idx'] # distinguish between adding a new chunk, which requires splitting a # gap in two, and replacing a node, which uses the existing gaps. if 'insert' in kwargs: t = kwargs['t'] if 't' in kwargs else 0. g, ag = ele.create_air_gap(t=t, ref_ifc=seq[-1][mc.Intfc]) seq[-1][mc.Gap] = g elm.append(ag) else: # replacing an existing node. need to hook new chunk final # interface to the existing gap and following (air gap) element g = self.seq_model.gaps[self.seq_model.cur_surface + 1] seq[-1][mc.Gap] = g ag = self.ele_model.gap_dict[g] ag.ref_ifc = seq[-1][mc.Intfc] # tacit assumption is ag == AirGap for sg in seq: self.seq_model.insert(sg[mc.Intfc], sg[mc.Gap]) for e in elm: self.ele_model.add_element(e) self.ele_model.sequence_elements() def remove_ifc_gp_ele(self, *args, **kwargs): """ remove interfaces and gaps from seq_model and eles from ele_model """ seq, elm = args sg = seq[0] idx = self.seq_model.ifcs.index(sg[mc.Intfc]) # verify that the sequences match seq_match = True for i, sg in enumerate(seq): if sg[0] is not self.seq_model.ifcs[idx + i]: seq_match = False break if seq_match: # remove interfaces in reverse for i in range(idx + len(seq) - 1, idx - 1, -1): self.seq_model.remove(i) for e in elm: self.ele_model.remove_element(e)