pcdsdevices.mirror.XOffsetMirror2D4PState

class pcdsdevices.mirror.XOffsetMirror2D4PState(*args, x_ranges: list[list[int]] = [], y_ranges: list[list[int]] = [], pitch_ranges: list[list[list[int]]] = [], **kwargs)

X-ray Offset Mirror with coating states that have 4 positions.

The coating states use 2 dimensional state movers with PMPS.

Currently services MR1L0.

Ophyd Device Components
Attribute	Class	Suffix	Docs	Kind	Notes
lightpath_summary	`SummarySignal`			omitted	Inherited from `XOffsetMirrorStateCool`
coating	`MirrorStripe2D4P`	`:COATING:STATE`	Control of the coating states via saved positions.	hinted	Inherited from `XOffsetMirrorStateCool`
y_up	`BeckhoffAxisNoOffset`	`:MMS:YUP`	Yupstream master axis [um]	hinted	Inherited from `XOffsetMirrorStateCool`
x_up	`BeckhoffAxisNoOffset`	`:MMS:XUP`	Xupstream master [um]	hinted	Inherited from `XOffsetMirrorStateCool`
pitch	`BeckhoffAxisNoOffset`	`:MMS:PITCH`	Pitch stepper and piezo axes [urad]	hinted	Inherited from `XOffsetMirrorStateCool`
bender	`BeckhoffAxisNoOffset`	`:MMS:BENDER`	Bender motor [um]	normal	Inherited from `XOffsetMirrorStateCool`
y_dwn	`BeckhoffAxisNoOffset`	`:MMS:YDWN`	Ydwnstream slave axis [um]	config	Inherited from `XOffsetMirrorStateCool`
x_dwn	`BeckhoffAxisNoOffset`	`:MMS:XDWN`	Xdwnstream slave axis [um]	config	Inherited from `XOffsetMirrorStateCool`
gantry_x	`PytmcSignal`	`:GANTRY_X`	X gantry difference [um]	normal	Inherited from `XOffsetMirrorStateCool`
gantry_y	`PytmcSignal`	`:GANTRY_Y`	Y gantry difference [um]	normal	Inherited from `XOffsetMirrorStateCool`
couple_y	`PytmcSignal`	`:COUPLE_Y`	Couple Y motors [bool]	config	Inherited from `XOffsetMirrorStateCool`
couple_x	`PytmcSignal`	`:COUPLE_X`	Couple X motors [bool]	config	Inherited from `XOffsetMirrorStateCool`
decouple_y	`PytmcSignal`	`:DECOUPLE_Y`	Decouple Y motors [bool]	config	Inherited from `XOffsetMirrorStateCool`
decouple_x	`PytmcSignal`	`:DECOUPLE_X`	Decouple X motors [bool]	config	Inherited from `XOffsetMirrorStateCool`
couple_status_y	`PytmcSignal`	`:ALREADY_COUPLED_Y`		normal	Inherited from `XOffsetMirrorStateCool`
couple_status_x	`PytmcSignal`	`:ALREADY_COUPLED_X`		normal	Inherited from `XOffsetMirrorStateCool`
y_enc_rms	`PytmcSignal`	`:ENC:Y:RMS`	Yup encoder RMS deviation [um]	normal	Inherited from `XOffsetMirrorStateCool`
x_enc_rms	`PytmcSignal`	`:ENC:X:RMS`	Xup encoder RMS deviation [um]	normal	Inherited from `XOffsetMirrorStateCool`
pitch_enc_rms	`PytmcSignal`	`:ENC:PITCH:RMS`	Pitch encoder RMS deviation [urad]	normal	Inherited from `XOffsetMirrorStateCool`
bender_enc_rms	`PytmcSignal`	`:ENC:BENDER:RMS`	Bender encoder RMS deviation [um]	normal	Inherited from `XOffsetMirrorStateCool`
cool_flow1	`EpicsSignalRO`	`:FWM:1_RBV`	Mirror cooling panel loop flow sensor	normal	Inherited from `XOffsetMirrorStateCool`
cool_flow2	`EpicsSignalRO`	`:FWM:2_RBV`	Mirror cooling panel loop flow sensor	normal	Inherited from `XOffsetMirrorStateCool`
cool_press	`EpicsSignalRO`	`:PRSM:1_RBV`	Mirror cooling panel loop pressure sensor	normal	Inherited from `XOffsetMirrorStateCool`
variable_cool	`PytmcSignal`	`:VCV`	Activates variable cooling valve	normal	Inherited from `XOffsetMirrorStateCool`

Methods

calc_lightpath_state(x_up: float, coating_state: int, pitch: float) → LightpathState

Create and return a LightpathState object containing information needed for lightpath, given a set of signal values

kwargs should be the same as the signal names provided in lightpath_cpts

Device logic goes here.

Returns:: LightpathState – a dataclass containing the Lightpath state

configure(d: Dict[str, Any]) → Tuple[Dict[str, Any], Dict[str, Any]]

Configure the device for something during a run

This default implementation allows the user to change any of the configuration_attrs. Subclasses might override this to perform additional input validation, cleanup, etc.

Parameters:

d (dict) – The configuration dictionary. To specify the order that the changes should be made, use an OrderedDict.

Returns:

(old, new) tuple of dictionaries
Where old and new are pre- and post-configure configuration states.

describe() → OrderedDictType[str, Dict[str, Any]]

Provide schema and meta-data for read().

This keys in the OrderedDict this method returns must match the keys in the OrderedDict return by read().

This provides schema related information, (ex shape, dtype), the source (ex PV name), and if available, units, limits, precision etc.

Returns:: data_keys (OrderedDict) – The keys must be strings and the values must be dict-like with the event_model.event_descriptor.data_key schema.

get(**kwargs)

Get the value of all components in the device

Keyword arguments are passed onto each signal.get(). Components beginning with an underscore will not be included.

get_lightpath_state(use_cache: bool = True) → LightpathState

Return the current LightpathState

Returns:: LightpathState – a dataclass containing the Lightpath state

post_elog_status(): Post device status to the primary elog, if possible.

read() → OrderedDictType[str, Dict[str, Any]]

Read data from the device.

This method is expected to be as instantaneous as possible, with any substantial acquisition time taken care of in trigger().

The OrderedDict returned by this method must have identical keys (in the same order) as the OrderedDict returned by describe().

By convention, the first key in the return is the ‘primary’ key and maybe used by heuristics in bluesky.

The values in the ordered dictionary must be dict (-likes) with the keys {'value', 'timestamp'}. The 'value' may have any type, the timestamp must be a float UNIX epoch timestamp in UTC.

Returns:: data (OrderedDict) – The keys must be strings and the values must be dict-like with the keys {'value', 'timestamp'}

read_configuration() → OrderedDictType[str, Dict[str, Any]]

Dictionary mapping names to value dicts with keys: value, timestamp

To control which fields are included, change the Component kinds on the device, or modify the configuration_attrs list.

screen()

Open a screen for controlling the device.

Default behavior is the typhos screen, but this method can be overridden for more specialized screens.

stage_group_instances() → Iterator[OphydObject]: Yields an iterator of subdevices that should be staged.

status() → str: Returns a str with the current pv values for the device.

stop(*, success=False): Stop the Device and all (instantiated) subdevices

summary()

trigger() → StatusBase

Trigger the device and return status object.

This method is responsible for implementing ‘trigger’ or ‘acquire’ functionality of this device.

If there is an appreciable time between triggering the device and it being able to be read (via the read() method) then this method is also responsible for arranging that the StatusBase object returned by this method is notified when the device is ready to be read.

If there is no delay between triggering and being readable, then this method must return a StatusBase object which is already completed.

Returns:: status (StatusBase) – StatusBase object which will be marked as complete when the device is ready to be read.

Attributes

configuration_attrs

connected

hints

kind

lightpath_cpts = ['x_up.user_readback', 'coating.state', 'pitch.user_readback']

md

needs_parent: list[type[OphydObject]] = [<class 'ophyd.signal.AttributeSignal'>, <class 'ophyd.signal.DerivedSignal'>, <class 'ophyd.areadetector.plugins.PluginBase'>, <class 'ophyd.pseudopos.PseudoSingle'>, <class 'pcdsdevices.signal.PVStateSignal'>, <class 'pcdsdevices.signal.AggregateSignal'>]

stage_group: list[Component] = None

subscriptions: ClassVar[FrozenSet[str]] = frozenset({'acq_done'})