def __init__(self): self.log = logging.getLogger("schedulerDriver") self.params = DriverParameters() self.location = ObservatoryLocation() self.observatoryModel = ObservatoryModel(self.location, WORDY) self.observatoryModel2 = ObservatoryModel(self.location, WORDY) self.observatoryState = ObservatoryState() self.sky = AstronomicalSkyModel(self.location) self.db = FieldsDatabase() self.build_fields_dict() self.propid_counter = 0 self.science_proposal_list = [] self.start_time = 0.0 self.time = 0.0 self.targetid = 0 self.survey_started = False self.isnight = False self.sunset_timestamp = 0.0 self.sunrise_timestamp = 0.0 self.survey_duration_DAYS = 0.0 self.survey_duration_SECS = self.survey_duration_DAYS * 24 * 60 * 60.0 self.darktime = False self.mounted_filter = "" self.unmounted_filter = "" self.midnight_moonphase = 0.0 self.nulltarget = Target() self.nulltarget.targetid = -1 self.nulltarget.num_exp = 1 self.nulltarget.exp_times = [0.0] self.nulltarget.num_props = 1 self.nulltarget.propid_list = [0] self.nulltarget.need_list = [0.0] self.nulltarget.bonus_list = [0.0] self.nulltarget.value_list = [0.0] self.nulltarget.propboost_list = [1.0] self.last_winner_target = self.nulltarget.get_copy() self.deep_drilling_target = None self.need_filter_swap = False self.filter_to_unmount = "" self.filter_to_mount = "" self.cloud = 0.0 self.seeing = 0.0
def __init__(self, obs_site_config, idle_delay): """Initialize the class. Parameters ---------- obs_site_config : :class:`.ObservingSite` The instance of the observing site configuration. idle_delay : float The delay time (seconds) to skip forward when no target is received. """ self.targets_received = 0 self.targets_missed = 0 self.observation = None self.observatory_model = MainObservatory(obs_site_config) self.observatory_location = ObservatoryLocation( obs_site_config.latitude_rad, obs_site_config.longitude_rad, obs_site_config.height) self.observatory_state = None self.log = logging.getLogger("kernel.Sequencer") self.idle_delay = (idle_delay, "seconds") self.sky_model = AstronomicalSkyModel(self.observatory_location)
def setUp(self): # Need to set current time to something the sky brightness files # available for testing have available (MJD: 59853.-59856.). self.start_time = Time(59853.983, format="mjd", scale="tai") # Step in time when there is no target (in seconds). self.no_target_time_step = 120.0 self.raw_telemetry = dict() self.raw_telemetry["timeHandler"] = None self.raw_telemetry["scheduled_targets"] = [] self.raw_telemetry["observing_queue"] = [] self.raw_telemetry["observatoryState"] = None self.raw_telemetry["bulkCloud"] = 0.0 self.raw_telemetry["seeing"] = 1.19 self.models = dict() self.models["location"] = ObservatoryLocation() self.models["location"].for_lsst() self.models["observatory_model"] = ObservatoryModel(self.models["location"]) self.models["observatory_model"].configure_from_module() self.models["observatory_model"].update_state(self.start_time.unix) self.models["observatory_state"] = ObservatoryState() self.models["observatory_state"].set( self.models["observatory_model"].current_state ) self.models["sky"] = AstronomicalSkyModel(self.models["location"]) self.models["seeing"] = SeeingModel() self.models["cloud"] = CloudModel() self.models["downtime"] = DowntimeModel() self.driver = FeatureScheduler( models=self.models, raw_telemetry=self.raw_telemetry ) self.config = types.SimpleNamespace( driver_configuration=dict( scheduler_config="", force=True, default_observing_script_name="standard_visit.py", default_observing_script_is_standard=True, stop_tracking_observing_script_name="stop_tracking.py", stop_tracking_observing_script_is_standard=True, ) ) self.files_to_delete = []
def setUp(self): self.raw_telemetry = dict() self.raw_telemetry["timeHandler"] = None self.raw_telemetry["scheduled_targets"] = [] self.raw_telemetry["observing_queue"] = [] self.raw_telemetry["observatoryState"] = None self.raw_telemetry["bulkCloud"] = 0.0 self.raw_telemetry["seeing"] = 1.0 self.models = dict() self.models["location"] = ObservatoryLocation() self.models["location"].for_lsst() self.models["observatory_model"] = ObservatoryModel(self.models["location"]) self.models["observatory_model"].configure_from_module() self.models["observatory_model"].update_state(current_tai()) self.models["observatory_state"] = ObservatoryState() self.models["observatory_state"].set( self.models["observatory_model"].current_state ) self.models["sky"] = AstronomicalSkyModel(self.models["location"]) self.models["seeing"] = SeeingModel() self.models["cloud"] = CloudModel() self.models["downtime"] = DowntimeModel() self.driver = SequentialScheduler( models=self.models, raw_telemetry=self.raw_telemetry, ) self.config = types.SimpleNamespace( driver_configuration=dict( observing_list=pathlib.Path(__file__) .parents[1] .joinpath("tests", "data", "test_observing_list.yaml"), general_propos=["Test"], default_observing_script_name="standard_visit.py", default_observing_script_is_standard=True, stop_tracking_observing_script_name="stop_tracking.py", stop_tracking_observing_script_is_standard=True, ) ) self.files_to_delete = []
def __init__(self): self.log = logging.getLogger("schedulerDriver") self.params = DriverParameters() self.location = ObservatoryLocation() self.observatoryModel = ObservatoryModel(self.location, WORDY) self.observatoryModel2 = ObservatoryModel(self.location, WORDY) self.observatoryState = ObservatoryState() self.sky = AstronomicalSkyModel(self.location) self.propid_counter = 0 self.night = 0 self.start_time = 0.0 self.time = 0.0 self.targetid = 0 self.survey_started = False self.isnight = False self.sunset_timestamp = 0.0 self.sunrise_timestamp = 0.0 self.survey_duration_DAYS = 0.0 self.survey_duration_SECS = self.survey_duration_DAYS * 24 * 60 * 60.0 self.darktime = False self.mounted_filter = "" self.unmounted_filter = "" self.midnight_moonphase = 0.0 self.nulltarget = Target() self.nulltarget.targetid = -1 self.nulltarget.num_exp = 1 self.nulltarget.exp_times = [0.0] self.nulltarget.num_props = 1 self.nulltarget.propid_list = [0] self.nulltarget.need_list = [0.0] self.nulltarget.bonus_list = [0.0] self.nulltarget.value_list = [0.0] self.nulltarget.propboost_list = [1.0] self.last_winner_target = self.nulltarget.get_copy() self.deep_drilling_target = None self.need_filter_swap = False self.filter_to_unmount = "" self.filter_to_mount = "" self.cloud = 0.0 self.seeing = 0.0
class Sequencer(object): """Handle the observation of a target. This class is responsible for taking a target from the Scheduler and performing the necessary steps to make an astronomical observation. It is then responsible for handing that observation back. Attributes ---------- targets_received : int Counter for the number of targets received by the sequencer. targets_missed : int Counter for the number of targets that were actually observed due to scheduler rejection. observations_made : int Counter for the number of observations made by the sequencer. observation : SALPY_scheduler.observationC DDS topic instance for the observation information. observatory_model : :class:`.MainObservatory` Instance of the SOCS observatory model. observatory_state : SALPY_scheduler.observatoryStateC DDS topic instance for the observatory state information. idle_delay : float Time (units=seconds) to wait when a missed target is received. log : logging.Logger The logging instance. """ def __init__(self, obs_site_config, idle_delay): """Initialize the class. Parameters ---------- obs_site_config : :class:`.ObservingSite` The instance of the observing site configuration. idle_delay : float The delay time (seconds) to skip forward when no target is received. """ self.targets_received = 0 self.targets_missed = 0 self.observation = None self.observatory_model = MainObservatory(obs_site_config) self.observatory_location = ObservatoryLocation( obs_site_config.latitude_rad, obs_site_config.longitude_rad, obs_site_config.height) self.observatory_state = None self.log = logging.getLogger("kernel.Sequencer") self.idle_delay = (idle_delay, "seconds") self.sky_model = AstronomicalSkyModel(self.observatory_location) @property def observations_made(self): """Get the number of observations made. Returns ------- int """ return self.observatory_model.observations_made def end_night(self): """Perform end of night functions. """ # Park the telescope for the day. self.observatory_model.park() def get_observatory_state(self, timestamp): """Return the observatory state in a DDS topic instance. Parameters ---------- timestamp : float The current timestamp at the state retrieval request. Return ------ SALPY_scheduler.observatoryStateC """ self.observatory_model.update_state(timestamp) obs_current_state = self.observatory_model.current_state self.observatory_state.timestamp = timestamp self.observatory_state.pointing_ra = obs_current_state.ra self.observatory_state.pointing_dec = obs_current_state.dec self.observatory_state.pointing_angle = obs_current_state.ang self.observatory_state.pointing_altitude = obs_current_state.alt self.observatory_state.pointing_azimuth = obs_current_state.az self.observatory_state.pointing_pa = obs_current_state.pa self.observatory_state.pointing_rot = obs_current_state.rot self.observatory_state.tracking = obs_current_state.tracking self.observatory_state.telescope_altitude = obs_current_state.telalt self.observatory_state.telescope_azimuth = obs_current_state.telaz self.observatory_state.telescope_rotator = obs_current_state.telrot self.observatory_state.dome_altitude = obs_current_state.domalt self.observatory_state.dome_azimuth = obs_current_state.domaz self.observatory_state.filter_position = obs_current_state.filter self.observatory_state.filter_mounted = ",".join( obs_current_state.mountedfilters) self.observatory_state.filter_unmounted = ','.join( obs_current_state.unmountedfilters) return self.observatory_state def initialize(self, sal, obs_config): """Perform initialization steps. This function handles gathering the observation telemetry topic from the given SalManager instance. Parameters ---------- sal : :class:`.SalManager` A SalManager instance. obs_config : :class:`.Observatory` The instance of the observatory configuration. """ self.observation = sal.set_publish_topic("observation") self.observatory_state = sal.set_publish_topic("observatoryState") self.observatory_model.configure(obs_config) def finalize(self): """Perform finalization steps. This function logs the number or targets received and observations made. """ self.log.info("Number of targets received: {}".format( self.targets_received)) self.log.info("Number of observations made: {}".format( self.observations_made)) self.log.info("Number of targets missed: {}".format( self.targets_missed)) def observe_target(self, target, th): """Observe the given target. This function performs the necessary steps to observe the given target. The current steps are: * Update the simulation time after "slewing" * Copy target information to observation * Update the simulation time after "visit" If the targetId is -1, this means a target was not offered by the Scheduler. Time is forwarded by the idle delay time and slew and exposure information are set to None. The observation takes the target's Id. Parameters ---------- target : SALPY_scheduler.targetC A target telemetry topic containing the current target information. th : :class:`.TimeHandler` An instance of the simulation's TimeHandler. Returns ------- SALPY_scheduler.observationC An observation telemetry topic containing the observed target parameters. dict(:class:`.SlewHistory`, :class:`.SlewState`, :class:`.SlewState`, list[:class:`.SlewActivity`]) A dictionanry of all the slew information from the visit. dict(list[:class:`.TargetExposure`], list[:class:`.ObsExposure`]) A dictionary of all the exposure information from the visit. """ if target.targetId != -1: self.log.log(LoggingLevel.EXTENSIVE.value, "Received target {}".format(target.targetId)) self.targets_received += 1 self.sky_model.update(target.request_time) target.request_mjd = self.sky_model.date_profile.mjd slew_info, exposure_info = self.observatory_model.observe( th, target, self.observation) self.sky_model.update(self.observation.observation_start_time) nid = numpy.array([target.fieldId]) nra = numpy.radians(numpy.array([self.observation.ra])) ndec = numpy.radians(numpy.array([self.observation.dec])) sky_mags = self.sky_model.get_sky_brightness( nid, extrapolate=True, override_exclude_planets=False) attrs = self.sky_model.get_target_information(nid, nra, ndec) msi = self.sky_model.get_moon_sun_info(nra, ndec) self.observation.sky_brightness = sky_mags[ self.observation.filter][0] self.observation.airmass = attrs["airmass"][0] self.observation.altitude = numpy.degrees(attrs["altitude"][0]) self.observation.azimuth = numpy.degrees(attrs["azimuth"][0]) self.observation.moon_ra = numpy.degrees(msi["moonRA"]) self.observation.moon_dec = numpy.degrees(msi["moonDec"]) self.observation.moon_alt = numpy.degrees(msi["moonAlt"][0]) self.observation.moon_az = numpy.degrees(msi["moonAz"][0]) self.observation.moon_phase = msi["moonPhase"] self.observation.moon_distance = numpy.degrees(msi["moonDist"][0]) self.observation.sun_alt = numpy.degrees(msi["sunAlt"][0]) self.observation.sun_az = numpy.degrees(msi["sunAz"][0]) self.observation.sun_ra = numpy.degrees(msi["sunRA"]) self.observation.sun_dec = numpy.degrees(msi["sunDec"]) self.observation.solar_elong = numpy.degrees(msi["solarElong"][0]) else: self.log.log(LoggingLevel.EXTENSIVE.value, "No target received!") self.observation.observationId = target.targetId self.observation.targetId = target.targetId if target.filter == '': self.observation.filter = 'z' if target.seeing == 0.0: self.observation.seeing_fwhm_eff = 0.1 if sum(target.exposure_times) == 0.0: for i in range(target.num_exposures): self.observation.exposure_times[i] = 15 self.observation.num_exposures = 1 if target.airmass == 0.0: self.observation.airmass = 1.0 if target.sky_brightness == 0.0: self.observation.sky_brightness = 30.0 slew_info = None exposure_info = None th.update_time(*self.idle_delay) self.targets_missed += 1 return self.observation, slew_info, exposure_info def sky_brightness_config(self): """Get the configuration from the SkyModelPre files. Returns ------- list[tuple(key, value)] """ return self.sky_model.sky_brightness_config() def start_day(self, filter_swap): """Perform start of day functions. Parameters ---------- filter_swap : scheduler_filterSwapC The instance of the filter swap information. """ if filter_swap.need_swap: self.observatory_model.swap_filter(filter_swap.filter_to_unmount) def start_night(self, night, duration): """Perform start of night functions. Parameters ---------- night : int The current survey observing night. duration : int The survey duration in days. """ self.observatory_model.start_night(night, duration)
class Driver(object): def __init__(self): self.log = logging.getLogger("schedulerDriver") self.params = DriverParameters() self.location = ObservatoryLocation() self.observatoryModel = ObservatoryModel(self.location, WORDY) self.observatoryModel2 = ObservatoryModel(self.location, WORDY) self.observatoryState = ObservatoryState() self.sky = AstronomicalSkyModel(self.location) self.db = FieldsDatabase() self.build_fields_dict() self.propid_counter = 0 self.science_proposal_list = [] self.start_time = 0.0 self.time = 0.0 self.targetid = 0 self.survey_started = False self.isnight = False self.sunset_timestamp = 0.0 self.sunrise_timestamp = 0.0 self.survey_duration_DAYS = 0.0 self.survey_duration_SECS = self.survey_duration_DAYS * 24 * 60 * 60.0 self.darktime = False self.mounted_filter = "" self.unmounted_filter = "" self.midnight_moonphase = 0.0 self.nulltarget = Target() self.nulltarget.targetid = -1 self.nulltarget.num_exp = 1 self.nulltarget.exp_times = [0.0] self.nulltarget.num_props = 1 self.nulltarget.propid_list = [0] self.nulltarget.need_list = [0.0] self.nulltarget.bonus_list = [0.0] self.nulltarget.value_list = [0.0] self.nulltarget.propboost_list = [1.0] self.last_winner_target = self.nulltarget.get_copy() self.deep_drilling_target = None self.need_filter_swap = False self.filter_to_unmount = "" self.filter_to_mount = "" self.cloud = 0.0 self.seeing = 0.0 def configure_survey(self, survey_conf_file): prop_conf_path = os.path.dirname(survey_conf_file) confdict = read_conf_file(survey_conf_file) self.survey_duration_DAYS = confdict["survey"]["survey_duration"] self.survey_duration_SECS = self.survey_duration_DAYS * 24 * 60 * 60.0 self.propid_counter = 0 self.science_proposal_list = [] if 'scripted_propconf' in confdict["proposals"]: scripted_propconflist = confdict["proposals"]["scripted_propconf"] else: scripted_propconflist = [] if not isinstance(scripted_propconflist, list): # turn it into a list with one entry propconf = scripted_propconflist scripted_propconflist = [] scripted_propconflist.append(propconf) self.log.info("configure_survey: scripted proposals %s" % (scripted_propconflist)) for k in range(len(scripted_propconflist)): self.propid_counter += 1 scripted_prop = ScriptedProposal(self.propid_counter, os.path.join(prop_conf_path, "{}".format(scripted_propconflist[k])), self.sky) self.science_proposal_list.append(scripted_prop) if 'areadistribution_propconf' in confdict["proposals"]: areadistribution_propconflist = confdict["proposals"]["areadistribution_propconf"] else: areadistribution_propconflist = [] self.log.info("areadistributionPropConf:%s default" % (areadistribution_propconflist)) if not isinstance(areadistribution_propconflist, list): # turn it into a list with one entry propconf = areadistribution_propconflist areadistribution_propconflist = [] areadistribution_propconflist.append(propconf) self.log.info("init: areadistribution proposals %s" % (areadistribution_propconflist)) for k in range(len(areadistribution_propconflist)): self.propid_counter += 1 configfilepath = os.path.join(prop_conf_path, "{}".format(areadistribution_propconflist[k])) (path, name_ext) = os.path.split(configfilepath) (name, ext) = os.path.splitext(name_ext) proposal_confdict = read_conf_file(configfilepath) self.create_area_proposal(self.propid_counter, name, proposal_confdict) for prop in self.science_proposal_list: prop.configure_constraints(self.params) def configure_duration(self, survey_duration): self.survey_duration_DAYS = survey_duration self.survey_duration_SECS = survey_duration * 24 * 60 * 60.0 def configure(self, confdict): self.params.configure(confdict) self.log.log(WORDY, "configure: coadd_values=%s" % (self.params.coadd_values)) self.log.log(WORDY, "configure: time_balancing=%s" % (self.params.time_balancing)) self.log.log(WORDY, "configure: timecost_dc=%.3f" % (self.params.timecost_dc)) self.log.log(WORDY, "configure: timecost_dt=%.3f" % (self.params.timecost_dt)) self.log.log(WORDY, "configure: timecost_k=%.3f" % (self.params.timecost_k)) self.log.log(WORDY, "configure: timecost_weight=%.3f" % (self.params.timecost_weight)) self.log.log(WORDY, "configure: night_boundary=%.1f" % (self.params.night_boundary)) self.log.log(WORDY, "configure: ignore_sky_brightness=%s" % (self.params.ignore_sky_brightness)) self.log.log(WORDY, "configure: ignore_airmass=%s" % (self.params.ignore_airmass)) self.log.log(WORDY, "configure: ignore_clouds=%s" % (self.params.ignore_clouds)) self.log.log(WORDY, "configure: ignore_seeing=%s" % (self.params.ignore_seeing)) self.log.log(WORDY, "configure: new_moon_phase_threshold=%.2f" % (self.params.new_moon_phase_threshold)) for prop in self.science_proposal_list: prop.configure_constraints(self.params) def configure_location(self, confdict): self.location.configure(confdict) self.observatoryModel.location.configure(confdict) self.observatoryModel2.location.configure(confdict) self.sky.update_location(self.location) def configure_observatory(self, confdict): self.observatoryModel.configure(confdict) self.observatoryModel2.configure(confdict) def configure_telescope(self, confdict): self.observatoryModel.configure_telescope(confdict) self.observatoryModel2.configure_telescope(confdict) def configure_rotator(self, confdict): self.observatoryModel.configure_rotator(confdict) self.observatoryModel2.configure_rotator(confdict) def configure_dome(self, confdict): self.observatoryModel.configure_dome(confdict) self.observatoryModel2.configure_dome(confdict) def configure_optics(self, confdict): self.observatoryModel.configure_optics(confdict) self.observatoryModel2.configure_optics(confdict) def configure_camera(self, confdict): self.observatoryModel.configure_camera(confdict) self.observatoryModel2.configure_camera(confdict) def configure_slew(self, confdict): self.observatoryModel.configure_slew(confdict) self.observatoryModel2.configure_slew(confdict) def configure_park(self, confdict): self.observatoryModel.configure_park(confdict) self.observatoryModel2.configure_park(confdict) def create_area_proposal(self, propid, name, config_dict): self.propid_counter += 1 area_prop = AreaDistributionProposal(propid, name, config_dict, self.sky) area_prop.configure_constraints(self.params) self.science_proposal_list.append(area_prop) def create_sequence_proposal(self, propid, name, config_dict): self.propid_counter += 1 seq_prop = TimeDistributionProposal(propid, name, config_dict, self.sky) seq_prop.configure_constraints(self.params) self.science_proposal_list.append(seq_prop) def build_fields_dict(self): sql = "select * from Field" res = self.db.query(sql) self.fields_dict = {} for row in res: field = Field() fieldid = row[0] field.fieldid = fieldid field.fov_rad = math.radians(row[1]) field.ra_rad = math.radians(row[2]) field.dec_rad = math.radians(row[3]) field.gl_rad = math.radians(row[4]) field.gb_rad = math.radians(row[5]) field.el_rad = math.radians(row[6]) field.eb_rad = math.radians(row[7]) self.fields_dict[fieldid] = field self.log.log(EXTENSIVE, "buildFieldsTable: %s" % (self.fields_dict[fieldid])) self.log.info("buildFieldsTable: %d fields" % (len(self.fields_dict))) def get_fields_dict(self): return self.fields_dict def start_survey(self, timestamp, night): self.start_time = timestamp self.log.info("start_survey t=%.6f" % timestamp) self.survey_started = True for prop in self.science_proposal_list: prop.start_survey() self.sky.update(timestamp) (sunset, sunrise) = self.sky.get_night_boundaries(self.params.night_boundary) self.log.debug("start_survey sunset=%.6f sunrise=%.6f" % (sunset, sunrise)) # if round(sunset) <= round(timestamp) < round(sunrise): if sunset <= timestamp < sunrise: self.start_night(timestamp, night) self.sunset_timestamp = sunset self.sunrise_timestamp = sunrise def end_survey(self): self.log.info("end_survey") for prop in self.science_proposal_list: prop.end_survey() def start_night(self, timestamp, night): timeprogress = (timestamp - self.start_time) / self.survey_duration_SECS self.log.info("start_night t=%.6f, night=%d timeprogress=%.2f%%" % (timestamp, night, 100 * timeprogress)) self.isnight = True for prop in self.science_proposal_list: prop.start_night(timestamp, self.observatoryModel.current_state.mountedfilters, night) def end_night(self, timestamp, night): timeprogress = (timestamp - self.start_time) / self.survey_duration_SECS self.log.info("end_night t=%.6f, night=%d timeprogress=%.2f%%" % (timestamp, night, 100 * timeprogress)) self.isnight = False self.last_winner_target = self.nulltarget self.deep_drilling_target = None total_filter_visits_dict = {} total_filter_goal_dict = {} total_filter_progress_dict = {} for prop in self.science_proposal_list: prop.end_night(timestamp) filter_visits_dict = {} filter_goal_dict = {} filter_progress_dict = {} for filter in self.observatoryModel.filters: if filter not in total_filter_visits_dict: total_filter_visits_dict[filter] = 0 total_filter_goal_dict[filter] = 0 filter_visits_dict[filter] = prop.get_filter_visits(filter) filter_goal_dict[filter] = prop.get_filter_goal(filter) filter_progress_dict[filter] = prop.get_filter_progress(filter) total_filter_visits_dict[filter] += filter_visits_dict[filter] total_filter_goal_dict[filter] += filter_goal_dict[filter] self.log.debug("end_night propid=%d name=%s filter=%s progress=%.2f%%" % (prop.propid, prop.name, filter, 100 * filter_progress_dict[filter])) for filter in self.observatoryModel.filters: if total_filter_goal_dict[filter] > 0: total_filter_progress_dict[filter] = \ float(total_filter_visits_dict[filter]) / total_filter_goal_dict[filter] else: total_filter_progress_dict[filter] = 0.0 self.log.info("end_night filter=%s progress=%.2f%%" % (filter, 100 * total_filter_progress_dict[filter])) previous_midnight_moonphase = self.midnight_moonphase self.sky.update(timestamp) (sunset, sunrise) = self.sky.get_night_boundaries(self.params.night_boundary) self.log.debug("end_night sunset=%.6f sunrise=%.6f" % (sunset, sunrise)) self.sunset_timestamp = sunset self.sunrise_timestamp = sunrise next_midnight = (sunset + sunrise) / 2 self.sky.update(next_midnight) info = self.sky.get_moon_sun_info(numpy.array([0.0]), numpy.array([0.0])) self.midnight_moonphase = info["moonPhase"] self.log.info("end_night next moonphase=%.2f%%" % (self.midnight_moonphase)) self.need_filter_swap = False self.filter_to_mount = "" self.filter_to_unmount = "" if self.darktime: if self.midnight_moonphase > previous_midnight_moonphase: self.log.info("end_night dark time waxing") if self.midnight_moonphase > self.params.new_moon_phase_threshold: self.need_filter_swap = True self.filter_to_mount = self.unmounted_filter self.filter_to_unmount = self.mounted_filter self.darktime = False else: self.log.info("end_night dark time waning") else: if self.midnight_moonphase < previous_midnight_moonphase: self.log.info("end_night bright time waning") if self.midnight_moonphase < self.params.new_moon_phase_threshold: self.need_filter_swap = True self.filter_to_mount = self.observatoryModel.params.filter_darktime max_progress = -1.0 for filter in self.observatoryModel.params.filter_removable_list: if total_filter_progress_dict[filter] > max_progress: self.filter_to_unmount = filter max_progress = total_filter_progress_dict[filter] self.darktime = True else: self.log.info("end_night bright time waxing") if self.need_filter_swap: self.log.debug("end_night filter swap %s=>cam=>%s" % (self.filter_to_mount, self.filter_to_unmount)) def swap_filter(self, filter_to_unmount, filter_to_mount): self.log.info("swap_filter swap %s=>cam=>%s" % (filter_to_mount, filter_to_unmount)) self.observatoryModel.swap_filter(filter_to_unmount) self.unmounted_filter = filter_to_unmount self.mounted_filter = filter_to_mount return def update_time(self, timestamp, night): self.time = timestamp self.observatoryModel.update_state(self.time) if not self.survey_started: self.start_survey(timestamp, night) if self.isnight: # if round(timestamp) >= round(self.sunrise_timestamp): if timestamp >= self.sunrise_timestamp: self.end_night(timestamp, night) else: # if round(timestamp) >= round(self.sunset_timestamp): if timestamp >= self.sunset_timestamp: self.start_night(timestamp, night) return self.isnight def get_need_filter_swap(self): return (self.need_filter_swap, self.filter_to_unmount, self.filter_to_mount) def update_internal_conditions(self, observatory_state, night): if observatory_state.unmountedfilters != self.observatoryModel.current_state.unmountedfilters: unmount = observatory_state.unmountedfilters[0] mount = self.observatoryModel.current_state.unmountedfilters[0] self.swap_filter(unmount, mount) for prop in self.science_proposal_list: prop.start_night(observatory_state.time, observatory_state.mountedfilters, night) self.time = observatory_state.time self.observatoryModel.set_state(observatory_state) self.observatoryState.set(observatory_state) def update_external_conditions(self, cloud, seeing): self.cloud = cloud self.seeing = seeing return def select_next_target(self): if not self.isnight: return self.nulltarget targets_dict = {} ranked_targets_list = [] propboost_dict = {} sumboost = 0.0 timeprogress = (self.time - self.start_time) / self.survey_duration_SECS for prop in self.science_proposal_list: progress = prop.get_progress() if self.params.time_balancing: if progress > 0.0: if timeprogress < 1.0: needindex = (1.0 - progress) / (1.0 - timeprogress) else: needindex = 0.0 if timeprogress > 0.0: progressindex = progress / timeprogress else: progressindex = 1.0 propboost_dict[prop.propid] = needindex / progressindex else: propboost_dict[prop.propid] = 1.0 else: propboost_dict[prop.propid] = 1.0 sumboost += propboost_dict[prop.propid] if self.deep_drilling_target is not None: self.log.debug("select_next_target: in deep drilling %s" % str(self.deep_drilling_target)) if self.observatoryModel.is_filter_change_allowed(): constrained_filter = None else: constrained_filter = self.observatoryModel.current_state.filter num_filter_changes = self.observatoryModel.get_number_filter_changes() delta_burst = self.observatoryModel.get_delta_filter_burst() delta_avg = self.observatoryModel.get_delta_filter_avg() self.log.debug("select_next_target: filter changes num=%i tburst=%.1f tavg=%.1f constrained=%s" % (num_filter_changes, delta_burst, delta_avg, constrained_filter)) for prop in self.science_proposal_list: propboost_dict[prop.propid] = \ (propboost_dict[prop.propid] * len(self.science_proposal_list) / sumboost) ** self.params.propboost_weight proptarget_list = prop.suggest_targets(self.time, self.deep_drilling_target, constrained_filter, self.cloud, self.seeing) self.log.log(EXTENSIVE, "select_next_target propid=%d name=%s " "targets=%d progress=%.2f%% propboost=%.3f" % (prop.propid, prop.name, len(proptarget_list), 100 * progress, propboost_dict[prop.propid])) for target in proptarget_list: target.num_props = 1 target.propboost = propboost_dict[prop.propid] target.propid_list = [prop.propid] target.need_list = [target.need] target.bonus_list = [target.bonus] target.value_list = [target.value] target.propboost_list = [target.propboost] target.sequenceid_list = [target.sequenceid] target.subsequencename_list = [target.subsequencename] target.groupid_list = [target.groupid] target.groupix_list = [target.groupix] target.is_deep_drilling_list = [target.is_deep_drilling] target.is_dd_firstvisit_list = [target.is_dd_firstvisit] target.remaining_dd_visits_list = [target.remaining_dd_visits] target.dd_exposures_list = [target.dd_exposures] target.dd_filterchanges_list = [target.dd_filterchanges] target.dd_exptime_list = [target.dd_exptime] fieldfilter = (target.fieldid, target.filter) if fieldfilter in targets_dict: if self.params.coadd_values: targets_dict[fieldfilter][0] = targets_dict[fieldfilter][0].get_copy() targets_dict[fieldfilter][0].need += target.need targets_dict[fieldfilter][0].bonus += target.bonus targets_dict[fieldfilter][0].value += target.value targets_dict[fieldfilter][0].propboost += target.propboost if target.is_deep_drilling: # overrides to make the coadded target a consistent deep drilling targets_dict[fieldfilter][0].is_deep_drilling = target.is_deep_drilling targets_dict[fieldfilter][0].is_dd_firstvisit = target.is_dd_firstvisit targets_dict[fieldfilter][0].remaining_dd_visits = target.remaining_dd_visits targets_dict[fieldfilter][0].dd_exposures = target.dd_exposures targets_dict[fieldfilter][0].dd_filterchanges = target.dd_filterchanges targets_dict[fieldfilter][0].dd_exptime = target.dd_exptime targets_dict[fieldfilter][0].sequenceid = target.sequenceid targets_dict[fieldfilter][0].subsequencename = target.subsequencename targets_dict[fieldfilter][0].groupid = target.groupid targets_dict[fieldfilter][0].groupix = target.groupix else: # new target to coadd is not deep drilling if not targets_dict[fieldfilter][0].is_deep_drilling: # coadded target is not deep drilling # overrides with new sequence information targets_dict[fieldfilter][0].sequenceid = target.sequenceid targets_dict[fieldfilter][0].subsequencename = target.subsequencename targets_dict[fieldfilter][0].groupid = target.groupid targets_dict[fieldfilter][0].groupix = target.groupix # if coadded target is already deep drilling, don't override targets_dict[fieldfilter][0].num_props += 1 targets_dict[fieldfilter][0].propid_list.append(prop.propid) targets_dict[fieldfilter][0].need_list.append(target.need) targets_dict[fieldfilter][0].bonus_list.append(target.bonus) targets_dict[fieldfilter][0].value_list.append(target.value) targets_dict[fieldfilter][0].propboost_list.append(target.propboost) targets_dict[fieldfilter][0].sequenceid_list.append(target.sequenceid) targets_dict[fieldfilter][0].subsequencename_list.append(target.subsequencename) targets_dict[fieldfilter][0].groupid_list.append(target.groupid) targets_dict[fieldfilter][0].groupix_list.append(target.groupix) targets_dict[fieldfilter][0].is_deep_drilling_list.append(target.is_deep_drilling) targets_dict[fieldfilter][0].is_dd_firstvisit_list.append(target.is_dd_firstvisit) targets_dict[fieldfilter][0].remaining_dd_visits_list.append( target.remaining_dd_visits) targets_dict[fieldfilter][0].dd_exposures_list.append(target.dd_exposures) targets_dict[fieldfilter][0].dd_filterchanges_list.append(target.dd_filterchanges) targets_dict[fieldfilter][0].dd_exptime_list.append(target.dd_exptime) else: targets_dict[fieldfilter].append(target) else: targets_dict[fieldfilter] = [target] filtercost = self.compute_filterchange_cost() * self.params.filtercost_weight for fieldfilter in targets_dict: slewtime = self.observatoryModel.get_slew_delay(targets_dict[fieldfilter][0]) if slewtime >= 0: timecost = self.compute_slewtime_cost(slewtime) * self.params.timecost_weight for target in targets_dict[fieldfilter]: target.slewtime = slewtime if target.filter != self.observatoryModel.current_state.filter: target.cost = timecost + filtercost else: target.cost = timecost target.rank = (target.value * target.propboost) - target.cost ranked_targets_list.append((-target.rank, target)) sorted_list = sorted(ranked_targets_list, key=itemgetter(0)) winner_found = False while len(sorted_list) > 0 and not winner_found: winner_target = sorted_list.pop(0)[1] self.observatoryModel2.set_state(self.observatoryState) self.observatoryModel2.observe(winner_target) if winner_target.is_dd_firstvisit: ttime = self.observatoryModel2.get_deep_drilling_time(winner_target) else: ttime = 0.0 ntime = self.observatoryModel2.current_state.time + ttime + 30.0 if ntime < self.sunrise_timestamp: self.observatoryModel2.update_state(ntime) if self.observatoryModel2.current_state.tracking: self.targetid += 1 winner_target.targetid = self.targetid winner_target.time = self.time winner_found = True else: self.log.debug("select_next_target: target rejected ttime=%.1f %s" % (ttime, str(winner_target))) self.log.debug("select_next_target: state rejected %s" % str(self.observatoryModel2.current_state)) else: self.log.debug("select_next_target: target rejected ttime=%.1f %s" % (ttime, str(winner_target))) self.log.debug("select_next_target: rejected due to end of night") if ttime == 0.0: # ttime == 0 means it is a regular visit (not DD) # if there is no time left for a single visit then quit break if winner_found: if not self.params.coadd_values: first_target = targets_dict[(winner_target.fieldid, winner_target.filter)][0] if first_target.propid != winner_target.propid: winner_target.copy_driver_state(first_target) self.last_winner_target = winner_target.get_copy() else: self.last_winner_target = self.nulltarget return self.last_winner_target def register_observation(self, observation): target_list = [] if observation.targetid > 0: if self.observation_fulfills_target(observation, self.last_winner_target): observation = self.last_winner_target else: self.log.info("register_observation: unexpected observation %s" % str(observation)) for prop in self.science_proposal_list: target = prop.register_observation(observation) if target is not None: target_list.append(target) self.last_observation = observation.get_copy() if self.last_observation.is_deep_drilling and (self.last_observation.remaining_dd_visits > 1): self.deep_drilling_target = self.last_observation else: self.deep_drilling_target = None return target_list def compute_slewtime_cost(self, slewtime): cost = (self.params.timecost_k / (slewtime + self.params.timecost_dt) - self.params.timecost_dc - self.params.timecost_cref) / (1.0 - self.params.timecost_cref) #cost = self.params.timecost_k / (slewtime + self.params.timecost_dt) - self.params.timecost_dc return cost def compute_filterchange_cost(self): t = self.observatoryModel.get_delta_last_filterchange() T = self.observatoryModel.params.filter_max_changes_avg_interval if t < T: cost = 1.0 - t / T else: cost = 0.0 return cost def observation_fulfills_target(self, observ, target): return (observ.fieldid == target.fieldid) and (observ.filter == target.filter)
class Driver(object): def __init__(self): self.log = logging.getLogger("schedulerDriver") self.params = DriverParameters() self.location = ObservatoryLocation() self.observatoryModel = ObservatoryModel(self.location, WORDY) self.observatoryModel2 = ObservatoryModel(self.location, WORDY) self.observatoryState = ObservatoryState() self.sky = AstronomicalSkyModel(self.location) self.propid_counter = 0 self.night = 0 self.start_time = 0.0 self.time = 0.0 self.targetid = 0 self.survey_started = False self.isnight = False self.sunset_timestamp = 0.0 self.sunrise_timestamp = 0.0 self.survey_duration_DAYS = 0.0 self.survey_duration_SECS = self.survey_duration_DAYS * 24 * 60 * 60.0 self.darktime = False self.mounted_filter = "" self.unmounted_filter = "" self.midnight_moonphase = 0.0 self.nulltarget = Target() self.nulltarget.targetid = -1 self.nulltarget.num_exp = 1 self.nulltarget.exp_times = [0.0] self.nulltarget.num_props = 1 self.nulltarget.propid_list = [0] self.nulltarget.need_list = [0.0] self.nulltarget.bonus_list = [0.0] self.nulltarget.value_list = [0.0] self.nulltarget.propboost_list = [1.0] self.last_winner_target = self.nulltarget.get_copy() self.deep_drilling_target = None self.need_filter_swap = False self.filter_to_unmount = "" self.filter_to_mount = "" self.cloud = 0.0 self.seeing = 0.0 def configure_scheduler(self, **kwargs): raise NotImplemented def configure_duration(self, survey_duration): self.survey_duration_DAYS = survey_duration self.survey_duration_SECS = survey_duration * 24 * 60 * 60.0 def configure(self, confdict): self.params.configure(confdict) self.log.log(WORDY, "configure: night_boundary=%.1f" % (self.params.night_boundary)) def configure_location(self, confdict): self.location.configure(confdict) self.observatoryModel.location.configure(confdict) self.observatoryModel2.location.configure(confdict) self.sky.update_location(self.location) def configure_observatory(self, confdict): """This method calls the configure()method in ObservatoryModel class, which configures all its submodules. When initializing one can issue a call to this method with a complete set of parameters on confdict. Parameters ---------- confdict : dict() Returns ------- None """ self.observatoryModel.configure(confdict) self.observatoryModel2.configure(confdict) def configure_telescope(self, confdict): self.observatoryModel.configure_telescope(confdict) self.observatoryModel2.configure_telescope(confdict) def configure_rotator(self, confdict): self.observatoryModel.configure_rotator(confdict) self.observatoryModel2.configure_rotator(confdict) def configure_dome(self, confdict): self.observatoryModel.configure_dome(confdict) self.observatoryModel2.configure_dome(confdict) def configure_optics(self, confdict): self.observatoryModel.configure_optics(confdict) self.observatoryModel2.configure_optics(confdict) def configure_camera(self, confdict): self.observatoryModel.configure_camera(confdict) self.observatoryModel2.configure_camera(confdict) def configure_slew(self, confdict): self.observatoryModel.configure_slew(confdict) self.observatoryModel2.configure_slew(confdict) def configure_park(self, confdict): self.observatoryModel.configure_park(confdict) self.observatoryModel2.configure_park(confdict) def start_survey(self, timestamp, night): """This method begins the survey. Parameters ---------- timestamp : float night : int Returns ------- None """ self.start_time = timestamp self.log.info("start_survey t=%.6f" % timestamp) self.survey_started = True self.sky.update(timestamp) (sunset, sunrise) = self.sky.get_night_boundaries(self.params.night_boundary) self.log.debug("start_survey sunset=%.6f sunrise=%.6f" % (sunset, sunrise)) # if round(sunset) <= round(timestamp) < round(sunrise): if sunset <= timestamp < sunrise: self.start_night(timestamp, night) self.sunset_timestamp = sunset self.sunrise_timestamp = sunrise def end_survey(self): """This method ends the survey. Parameters ---------- None Returns ------- None """ self.log.info("end_survey") def start_night(self, timestamp, night): """This method is called once per night before observations begin. It is not called if the observatory is undergoing downtime. Parameters ---------- timestamp : float night : int Returns ------- None """ timeprogress = (timestamp - self.start_time) / self.survey_duration_SECS self.log.info("start_night t=%.6f, night=%d timeprogress=%.2f%%" % (timestamp, night, 100 * timeprogress)) self.isnight = True def end_night(self, timestamp, night): """This method is called once per night after observing completes. Parameters ---------- timestamp : float night : int Returns ------- None """ pass def swap_filter(self, filter_to_unmount, filter_to_mount): self.log.info("swap_filter swap %s=>cam=>%s" % (filter_to_mount, filter_to_unmount)) self.observatoryModel.swap_filter(filter_to_unmount) self.unmounted_filter = filter_to_unmount self.mounted_filter = filter_to_mount return def update_time(self, timestamp, night): self.time = timestamp self.observatoryModel.update_state(self.time) if not self.survey_started: self.start_survey(timestamp, night) if self.isnight: # if round(timestamp) >= round(self.sunrise_timestamp): if timestamp >= self.sunrise_timestamp: self.end_night(timestamp, night) else: # if round(timestamp) >= round(self.sunset_timestamp): if timestamp >= self.sunset_timestamp: self.start_night(timestamp, night) return self.isnight def get_need_filter_swap(self): """When scheduler determines that a filter swap is needed, this shall return a tuple where the first element is a TRUE value, and the second and third elements are single-character strings identifying which filter to remove from the carousel, and which filter to add, respectively. Parameters ---------- None Returns ------- Tuple (bool, str, str) """ return (self.need_filter_swap, self.filter_to_unmount, self.filter_to_mount) def update_internal_conditions(self, observatory_state, night): if observatory_state.unmountedfilters != self.observatoryModel.current_state.unmountedfilters: unmount = observatory_state.unmountedfilters[0] mount = self.observatoryModel.current_state.unmountedfilters[0] self.swap_filter(unmount, mount) self.time = observatory_state.time self.observatoryModel.set_state(observatory_state) self.observatoryState.set(observatory_state) def update_external_conditions(self, cloud, seeing): self.cloud = cloud self.seeing = seeing return def cold_start(self, observations): """Rebuilds the internal state of the scheduler from a list of observations. Parameters ---------- observations : list of Observation objects Returns ------- None """ raise NotImplemented def select_next_target(self): """Picks a target and returns it as a target object. Parameters ---------- None Returns ------- Target """ raise NotImplemented def register_observation(self, observation): """Validates observation and returns a list of successfully completed observations. Parameters ---------- observation : Observation or a python list of Observations Returns ------- Python list of one or more Observations """ raise NotImplemented
def setUpClass(cls): warnings.filterwarnings('ignore', category=FutureWarning, append=True) location = ObservatoryLocation() location.for_lsst() cls.skyModel = AstronomicalSkyModel(location)