def __init__(self, tool_id: str = "controller", description: str or None = None):
"""
Args:
tool_id: tool name
description: description of this tool
"""
Tools.__init__(self, tool_id, description)
#: interface type (0 = demo, 4 = PCIe)
self.interface_type = 0
# create the controller Header object
self.header = Header("Controller")
self.header.set_header("controller", 2)
#: exposure time (secs)
self.exposure_time = 0
self.detpars = DetPars()
#: True if the controller has been reset
self.reset_flag = 0
azcam.db.tools_init["controller"] = self
azcam.db.tools_reset["controller"] = self
def __init__(self, tool_id="instrument", description=None):
Tools.__init__(self, tool_id, description)
# active comparisons
self.active_comps = []
# True if shutter controls comps
self.shutter_strobe = 0
# focus position
self.focus_position = 0
# system pressures
self.pressure_ids = [0]
# system currents
self.current_ids = [0]
azcam.db.tools_init["instrument"] = self
azcam.db.tools_reset["instrument"] = self
# instrument header object
self.header = Header("Instrument")
self.header.set_header("instrument", 3)
return
class Display(Tools, ObjectHeaderMethods):
"""
The base display tool for server and consoles.
Usually implemented as the "display" tool.
"""
def __init__(self, tool_id="display", description=None):
Tools.__init__(self, tool_id, description)
# create the display Header object
self.header = Header("Display")
self.header.set_header("display", 2)
# set default display server
self.default_display = 0
# allow initialization of display on server in exposure
try:
azcam.db.tools_init["display"] = self
except AttributeError:
pass
def initialize(self):
"""
Initialize display.
"""
if self.initialized:
return
if not self.enabled:
azcam.AzcamWarning("Display is not enabled")
return
self.set_display(self.default_display)
return
def set_display(self, display_number):
"""
Set the current display by number.
:param int display_number: Number for display to be used (0->N)
:return None:
"""
return
def display(self, image, extension_number=-1):
"""
Display a file on the image display.
If specified for an MEF file, only extension_number is displayed.
:param image: a filename or an image object
:param int extension_number: FITS extension number of image, -1 for all
:return None:
"""
raise NotImplementedError
def __init__(self, system_name, template_file=None):
Tools.__init__(self, "system", system_name)
self.header = Header(system_name, template_file)
self.header.set_header("system", 0)
return
class System(Tools, ObjectHeaderMethods):
"""
System tool class.
Usually implemented as the "system" tool.
"""
def __init__(self, system_name, template_file=None):
Tools.__init__(self, "system", system_name)
self.header = Header(system_name, template_file)
self.header.set_header("system", 0)
return
def __init__(self, tool_id="telescope", description=None):
Tools.__init__(self, tool_id, description)
# focus position
self.focus_position = 0
# create the temp control Header object
self.header = Header("Telescope")
self.header.set_header("telescope", 5)
azcam.db.tools_init["telescope"] = self
azcam.db.tools_reset["telescope"] = self
def __init__(self, tool_id="display", description=None):
Tools.__init__(self, tool_id, description)
# create the display Header object
self.header = Header("Display")
self.header.set_header("display", 2)
# set default display server
self.default_display = 0
# allow initialization of display on server in exposure
try:
azcam.db.tools_init["display"] = self
except AttributeError:
pass
def __init__(self, tool_id: str = "tempcon", description: str = None):
"""
Creates the tool.
Args:
tool_id: Name of tool
description: Description of tool, defaults to tool_id.
"""
Tools.__init__(self, tool_id, description)
# control temperature number (which temp is regulated)
self.control_temperature = -999.0
self.control_temperature_number = 0
# system temperatures
self.temperature_ids = [0]
# True to correct temperature offset and scale for each temperature
# Scaling is **new = old * scale + offset**
self.temperature_correction = 0
# temperature offset corrections for each temperature
self.temperature_offsets = [0.0]
# temperature scale corrections
self.temperature_scales = [1.0]
# calibration flags for each temperature
self.temperature_cals = [3]
# value returned when temperature read is bad
self.bad_temp_value = -999.9
# create the temp control Header object
self.header = Header("Temperature")
self.header.set_header("tempcon", 4)
# add keywords
self.define_keywords()
azcam.db.tools_init["tempcon"] = self
azcam.db.tools_reset["tempcon"] = self
return
class Telescope(Tools, ObjectHeaderMethods):
"""
The base telescope tool.
Usually implemented as the "telescope" tool.
"""
def __init__(self, tool_id="telescope", description=None):
Tools.__init__(self, tool_id, description)
# focus position
self.focus_position = 0
# create the temp control Header object
self.header = Header("Telescope")
self.header.set_header("telescope", 5)
azcam.db.tools_init["telescope"] = self
azcam.db.tools_reset["telescope"] = self
# ***************************************************************************
# exposure
# ***************************************************************************
def exposure_start(self):
"""
Optional call before exposure starts.
"""
return
def exposure_finish(self):
"""
Optional call after exposure finishes.
"""
return
class TempCon(Tools, ObjectHeaderMethods):
"""
The base temperature control tool.
Usually implemented as the "tempcon" tool.
"""
def __init__(self, tool_id: str = "tempcon", description: str = None):
"""
Creates the tool.
Args:
tool_id: Name of tool
description: Description of tool, defaults to tool_id.
"""
Tools.__init__(self, tool_id, description)
# control temperature number (which temp is regulated)
self.control_temperature = -999.0
self.control_temperature_number = 0
# system temperatures
self.temperature_ids = [0]
# True to correct temperature offset and scale for each temperature
# Scaling is **new = old * scale + offset**
self.temperature_correction = 0
# temperature offset corrections for each temperature
self.temperature_offsets = [0.0]
# temperature scale corrections
self.temperature_scales = [1.0]
# calibration flags for each temperature
self.temperature_cals = [3]
# value returned when temperature read is bad
self.bad_temp_value = -999.9
# create the temp control Header object
self.header = Header("Temperature")
self.header.set_header("tempcon", 4)
# add keywords
self.define_keywords()
azcam.db.tools_init["tempcon"] = self
azcam.db.tools_reset["tempcon"] = self
return
def reset(self) -> None:
"""
Reset tempcon tool.
"""
if not self.enabled:
return
if not self.initialized:
self.initialize()
self.set_control_temperature()
return
# ***************************************************************************
# exposure
# ***************************************************************************
def exposure_start(self) -> None:
"""
Custom commands before exposure starts.
"""
return
def exposure_finish(self) -> None:
"""
Custom commands after exposure finishes.
"""
return
# ***************************************************************************
# temperatures
# ***************************************************************************
def set_control_temperature(self,
temperature: float = None,
temperature_id: int = 0) -> None:
"""
Set the control temperature (set point).
Args:
temperature: control temperature in Celsius. If not specified, use saved value
temperature_id: temperature sensor identifier
"""
if temperature is None:
temperature = self.control_temperature
else:
self.control_temperature = temperature
return
def get_control_temperature(self, temperature_id: int = 0) -> float:
"""
Get the control temperature (set point).
Args:
temperature_id: temperature sensor identifier
Returns:
control_temperature: control temperature
"""
return self.control_temperature
def get_temperatures(self) -> List[float]:
"""
Return all system temperatures.
Returns:
temperatures: list of temperatures read
"""
temps = []
for temperature_id in self.temperature_ids:
p = self.get_temperature(temperature_id)
temps.append(p)
return temps
def get_temperature(self, temperature_id: int = 0) -> float:
"""
Returns a system temperature.
Args:
temperature_id: temperature sensor identifier
Returns:
temperature: temperature read
"""
return self.bad_temp_value
# ***************************************************************************
# calibrations
# ***************************************************************************
def set_calibrations(self, cals: List[int]) -> None:
"""
Set calibration curves for temperature sensors.
The values of these flags are from the list below which define the calibration curves to use
for each sensor's temperature conversion.
* 0 => DT670 diode
* 1 => AD590 sensor
* 2 => 1N4148 diode
* 3 => 1N914 diode
Args:
cals: list of flags defining each temperature sensor type
"""
self.temperature_cals = []
for i, cal in enumerate(cals):
self.temperature_cals.append(cal)
return
def set_corrections(
self,
temperature_offsets: List[float] = None,
temperature_scales: List[float] = None,
) -> None:
"""
Set temperature correction values and enable correction.
If both parameters are None then correction is disabled.
Args:
temperature_offsets: list of offsets for each temperature
temperature_scales: list of scale factors for each temperature
"""
# set and save values
if temperature_offsets is None and temperature_scales is None:
self.temperature_correction = 0
else:
self.temperature_correction = 1
if temperature_offsets is not None:
self.temperature_offsets = temperature_offsets
if temperature_scales is not None:
self.temperature_scales = temperature_scales
return
def apply_corrections(self,
temperature: float,
temperature_id: int = 0) -> None:
"""
Correct the temperatures for offset and scale is temperature correction is enabled.
Args:
temperature: temperatures to be corrected
temperature_id: temperature ID number
Returns:
corrected_temperature: temperature after correction has been appied
"""
if self.temperature_correction:
return (temperature * self.temperature_scales[temperature_id] +
self.temperature_offsets[temperature_id])
else:
return temperature
# ***************************************************************************
# keywords
# ***************************************************************************
def define_keywords(self):
"""
Defines and resets instrument keywords.
"""
return
def get_keyword(self, keyword: str) -> List:
"""
Read a temperature keyword value and returns it as [value, comment, type string]
Args:
keyword: name of keyword
Returns:
list of [keyword, comment, type]
"""
reply = self.get_temperatures()
if keyword == "CAMTEMP":
temp = reply[0]
elif keyword == "DEWTEMP":
temp = reply[1]
elif keyword in self.get_keywords():
value = self.header.values[keyword]
temp = value
else:
raise azcam.AzcamError(f"invalid keyword: {keyword}")
# store temperature values in header
if keyword == "CAMTEMP":
temp = float(f"{temp:.03f}")
self.header.set_keyword("CAMTEMP", temp, "Camera temperature in C",
"float")
self.header.set_keyword("CCDTEMP1", temp,
"Camera temperature in C", "float")
elif keyword == "DEWTEMP":
temp = float(f"{temp:.03f}")
self.header.set_keyword("DEWTEMP", temp, "Dewar temperature in C",
"float")
self.header.set_keyword("CCDTEMP2", temp, "Dewar temperature in C",
"float")
t = self.header.typestrings[keyword]
return [temp, self.header.comments[keyword], t]
class FocalPlane(ObjectHeaderMethods):
"""
The FocalPlane class describes a focalplane layout.
Used by the image tool.
"""
def __init__(self):
# header
self.header = Header("Focalplane")
# World Coordinate System
self.wcs = WCS(self)
# only needed for server side
self.header.set_header("focalplane")
# fixed values
# for multiple CCD detectors:
# 0 - each CCD has its own physical coordinates
# 1 - combine physical coordinates (physical coordinates
# are the same as detector coordinates)
self.split_physical_coords = 0
# number of detectors along X axis
self.numdet_x = 1
# number of detectors along Y axis
self.numdet_y = 1
# amplifier readout orientation
self.amp_config = "0"
# ampliefier readout orientation - new as an array
self.amp_cfg = [0]
# detector number for each detector
self.det_number = [1]
# extension number for each amplifier
self.ext_number = [1]
# extension name for each amplifier
self.ext_name = ["1"]
# extension number order for each amplifier when creating binary image
self.jpg_ext = [1]
# detector position in x direction in pixels
self.detpos_x = [1]
# detector position in y direction in pixels
self.detpos_y = [1]
# amplifier's positions along X axis
self.extpos_x = [1]
# amplifier's positions along Y axis
self.extpos_y = [1]
# amplifier's positions in pixels along X axis
self.amppix1 = [1]
# amplifier's positions in pixels along Y axis
self.amppix2 = [1]
# gap between amplifiers in X. value different than 0
# means that there is a gap on the left side of the amplifier.
# gapx is the sum of all gaps on the left side of the amplifier.
self.gapx = [0]
# gap between amplifiers in Y. value different than 0 means
# that there is a gap below of the amplifier.
# gapy is the sum of all gaps below the amplifier.
self.gapy = [0]
# number of amplifiers along X axis
self.numamps_x = 1
# number of amplifiers along Y axis
self.numamps_y = 1
# reference (zeropoint) position X (in pixels)
self.refpix1 = 1
# reference (zeropoint) position Y (in pixels)
self.refpix2 = 1
# unbinned number of visible pixels per amplifier along X axis
self.ampvispix_x = 1
# unbinned number of visible pixels per amplifier along Y axis
self.ampvispix_y = 1
# calculated values
# number of pixels in image
self.numpix_image = 0
# number of bytes per image
self.numbytes_image = 0
# number of columns per image
self.numcols_image = 0
# number of rows per image
self.numrows_image = 0
# number of total amps per image
self.numamps_image = 1
# number of detectors
self.num_detectors = 1
# number of columns per amplifier
self.numcols_amp = 1
# number of row per amplifier
self.numrows_amp = 1
# number of serial amps per detector
self.num_ser_amps_det = 1
# number of parallel amps per detector
self.num_par_amps_det = 1
# number of total amps per detector
self.num_amps_det = 1
# first column
self.first_col = 1
# first row
self.first_row = 1
# last column
self.last_col = 1
# last row
self.last_row = 1
# column binning
self.col_bin = 1
# row binning
self.row_bin = 1
# number of visible columns per amplifier
self.numviscols_amp = 1
# number of visible rows per amplifier
self.numvisrows_amp = 1
# number of visible columns per amplifier
self.numviscols_image = 1
# number of visible rows per amplifier
self.numvisrows_image = 1
# number of colums in overscan
self.numcols_overscan = 0
# number of rows in overscan
self.numrows_overscan = 0
# number of colums in underscan
self.numcols_underscan = 0
# number of rows in underscan
self.numrows_underscan = 0
# underscan skips
self.xunderscan = 0
self.yunderscan = 0
# overscan skips
self.xoverscan = 0
self.yoverscan = 0
# bias location constants
self.BL_COLUNDER = 1
self.BL_COLOVER = 2
self.BL_ROWUNDER = 3
self.BL_ROWOVER = 4
self.bias_location = self.BL_COLOVER
# number of pixels per amplifier
self.numpix_amp = 1
# number of pixels per detector
self.numpix_det = 1
# shifting
self.ns_total = 0
self.ns_predark = 0
self.ns_underscan = 0
self.ns_overscan = 0
self.np_total = 0
self.np_predark = 0
self.np_underscan = 0
self.np_overscan = 0
self.np_frametransfer = 0
# set shifting parameters
self.coltotal = 0
self.colusct = 0
self.coluscw = 0
self.coluscm = 0
self.coloscw = 0
self.coloscm = 0
self.rowtotal = 0
self.rowusct = 0
self.rowuscw = 0
self.rowuscm = 0
self.rowoscw = 0
self.rowoscm = 0
self.framet = 0
def update_header_keywords(self):
"""
Update focal plane keywords in header
"""
self.header.set_keyword("ITL-HEAD", "OK", "ITL Header flag", "str")
self.header.set_keyword("NUM-DETX", self.numdet_x,
"Number of detectors in X", "int")
self.header.set_keyword("NUM-DETY", self.numdet_y,
"Number of detectors in Y", "int")
self.header.set_keyword("NUM-AMPX", self.numamps_x,
"Number of amplifiers in X", "int")
self.header.set_keyword("NUM-AMPY", self.numamps_y,
"Number of amplifiers in Y", "int")
if type(self.refpix1) == list:
r1 = self.refpix1[0]
r2 = self.refpix2[0]
else:
r1 = self.refpix1
r2 = self.refpix2
self.header.set_keyword("REF-PIX1", r1, "Reference pixel 1", "int")
self.header.set_keyword("REF-PIX2", r2, "Reference pixel 2", "int")
return
def update_ext_keywords(self):
"""
Update focal plane keywords for single extension
"""
self.header.set_keyword("AMP-CFG", self.amp_cfg[0],
"Amplifier configuration")
self.header.set_keyword("DET-NUM", self.det_number[0],
"Detector number")
self.header.set_keyword("EXT-NUM", self.ext_number[0],
"extension number")
self.header.set_keyword("JPG-EXT", self.jpg_ext[0], "Image section")
self.header.set_keyword("DET-POSX", self.detpos_x[0],
"Detector position in X")
self.header.set_keyword("DET-POSY", self.detpos_y[0],
"Detector position in Y")
self.header.set_keyword("Ext-PosX", self.extpos_x[0],
"Amplifier position in X")
self.header.set_keyword("Ext-PosY", self.extpos_y[0],
"Amplifier position in Y")
self.header.set_keyword("AMP-PIX1", self.amppix1[0],
"Amplifier pixel position in X")
self.header.set_keyword("AMP-PIX2", self.amppix2[0],
"Amplifier pixel position in Y")
return
def update_header(self):
"""
Update headers, reading current data.
"""
self.update_header_keywords()
return
def set_format(
self,
ns_total=-1,
ns_predark=-1,
ns_underscan=-1,
ns_overscan=-1,
np_total=-1,
np_predark=-1,
np_underscan=-1,
np_overscan=-1,
np_frametransfer=-1,
):
"""
Set the detector format.
ns_total is the number of visible columns.
ns_predark is the number of physical dark underscan columns.
ns_underscan is the desired number of desired dark underscan columns.
ns_overscan is the number of dark overscan columns.
np_total is the number of visible rows.
np_predark is the number of physical dark underscan rows.
np_underscan is the number of desired dark underscan rows.
np_overscan is the number of desired dark overscan rows.
np_frametransfer is the rows to frame transfer shift.
"""
ns_total = int(ns_total)
ns_predark = int(ns_predark)
ns_underscan = int(ns_underscan)
ns_overscan = int(ns_overscan)
np_total = int(np_total)
np_predark = int(np_predark)
np_underscan = int(np_underscan)
np_overscan = int(np_overscan)
np_frametransfer = int(np_frametransfer)
# defaults
if ns_total == -1:
ns_total = self.ns_total
if ns_predark == -1:
ns_predark = self.ns_predark
if ns_underscan == -1:
ns_underscan = self.ns_underscan
if ns_overscan == -1:
ns_overscan = self.ns_overscan
if np_total == -1:
np_total = self.np_total
if np_predark == -1:
np_predark = self.np_predark
if np_underscan == -1:
np_underscan = self.np_underscan
if np_overscan == -1:
np_overscan = self.np_overscan
if np_frametransfer == -1:
np_frametransfer = self.np_frametransfer
# sets the format parameters for a detector
self.ns_total = int(ns_total)
self.ns_predark = int(ns_predark)
self.ns_underscan = int(ns_underscan)
self.ns_overscan = int(ns_overscan)
self.np_total = int(np_total)
self.np_predark = int(np_predark)
self.np_underscan = int(np_underscan)
self.np_overscan = int(np_overscan)
self.np_frametransfer = int(np_frametransfer)
# set shifting parameters
self.coltotal = int(ns_total)
self.colusct = int(ns_predark)
self.coluscw = int(ns_underscan)
self.coluscm = 0
self.coloscw = int(ns_overscan)
self.coloscm = 0
self.rowtotal = int(np_total)
self.rowusct = int(np_predark)
self.rowuscw = int(np_underscan)
self.rowuscm = 0
self.rowoscw = int(np_overscan)
self.rowoscm = 0
self.framet = int(np_frametransfer)
return
def get_format(self):
"""
Return a list of current detector format parameters
"""
return [
self.ns_total,
self.ns_predark,
self.ns_underscan,
self.ns_overscan,
self.np_total,
self.np_predark,
self.np_underscan,
self.np_overscan,
self.np_frametransfer,
]
def set_focalplane(self,
numdet_x=-1,
numdet_y=-1,
numamps_x=-1,
numamps_y=-1,
amp_config=""):
"""
Sets focal plane configuration. Use after set_format() and before set_roi().
This command replaces SetConfiguration.
Default focalplane values are set here.
numdet_x defines number of detectors in Column direction.
numdet_y defines number of detectors in Row direction.
numamps_x defines number of amplifiers in Column direction.
numamps_y defines number of amplifiers in Row direction.
amp_config defines each amplifier's orientation (ex: '1223').
0 - normal
1 - flip x
2 - flip y
3 - flip x and y
"""
numdet_x = int(numdet_x)
numdet_y = int(numdet_y)
numamps_x = int(numamps_x)
numamps_y = int(numamps_y)
if numdet_x == -1:
numdet_x = self.numdet_x
if numdet_y == -1:
numdet_y = self.numdet_y
if numamps_x == -1:
numamps_x = self.numamps_x
if numamps_y == -1:
numamps_y = self.numamps_y
if amp_config == "":
amp_config = self.amp_config
self.numdet_x = numdet_x
self.numdet_y = numdet_y
self.numamps_x = numamps_x
self.numamps_y = numamps_y
# special case for amp_config
if type(amp_config) == str:
self.amp_config = amp_config
self.amp_cfg = []
for x in amp_config:
self.amp_cfg.append(ord(x) - 48) # convert char to integer
elif type(amp_config) == list:
self.amp_cfg = amp_config
self.amp_config = ""
for x in amp_config:
self.amp_config += chr(x + 48)
# set the keywords in the main header
self.header.set_keyword("N-DET-X", self.numdet_x,
"Number of detectors in X", "int")
self.header.set_keyword("N-DET-Y", self.numdet_y,
"Number of detectors in Y", "int")
self.header.set_keyword("N-AMPS-X", self.numamps_x,
"Number of amplifiers in X", "int")
self.header.set_keyword("N-AMPS-Y", self.numamps_y,
"Number of amplifiers in Y", "int")
# set number of detectors
self.num_detectors = self.numdet_x * self.numdet_y
# set amps per detector
self.num_ser_amps_det = int(self.numamps_x / self.numdet_x)
self.num_par_amps_det = int(self.numamps_y / self.numdet_y)
self.num_amps_det = self.num_ser_amps_det * self.num_par_amps_det
# set amps in focal plane
self.numamps_image = self.num_detectors * self.num_amps_det
# set unbinned number of visible pixels per amplifier along X and Y axis
self.ampvispix_x = int(self.ns_total / self.numamps_x)
self.ampvispix_y = int(self.np_total / self.numamps_y)
# set default values
self.set_default_values()
# initialize WCS so array size is correct, values may be manually set later
self.wcs.initialize()
return
def get_focalplane(self):
"""
Returns the focal plane configuration.
"""
return [
self.numdet_x,
self.numdet_y,
self.numamps_x,
self.numamps_y,
self.amp_config,
]
def set_roi(
self,
first_col=-1,
last_col=-1,
first_row=-1,
last_row=-1,
col_bin=-1,
row_bin=-1,
roi_num=0,
):
"""
Sets the ROI values for a specified ROI.
Currently only one ROI (0) is supported.
These values are for the entire focal plane, not just one detector.
"""
# set current values
first_col = int(first_col)
last_col = int(last_col)
first_row = int(first_row)
last_row = int(last_row)
col_bin = int(col_bin)
row_bin = int(row_bin)
roi_num = int(roi_num)
if first_col == -1:
first_col = self.first_col
if last_col == -1:
last_col = self.last_col
if first_row == -1:
first_row = self.first_row
if last_row == -1:
last_row = self.last_row
if col_bin == -1:
col_bin = self.col_bin
if row_bin == -1:
row_bin = self.row_bin
self.first_col = int(first_col)
self.last_col = int(last_col)
self.first_row = int(first_row)
self.last_row = int(last_row)
self.col_bin = int(col_bin)
self.row_bin = int(row_bin)
self.roi_num = int(roi_num)
# bad fix for ROI now entire focalplane - change later!
if self.numdet_x > 1:
lc = last_col / self.numdet_x
lr = last_row / self.numdet_y
else:
lc = last_col
lr = last_row
fc = first_col
fr = first_row
# calculate variables for shifting a single AMPLIFIER
self.xunderscan = int(min(self.colusct / self.col_bin, self.coluscw))
self.xskip = int(
min(self.colusct - self.xunderscan * self.col_bin, self.coluscm))
self.xpreskip = self.colusct - self.xskip - self.xunderscan * self.col_bin
self.xskip += fc - 1
self.xdata = (lc - (fc - 1)) / self.col_bin
self.xdata = max(0, self.xdata)
self.xdata = int(self.xdata / self.num_ser_amps_det)
self.xpostskip = self.coltotal / self.numamps_x - (
(fc - 1) + self.xdata * self.col_bin)
self.xpostskip = int(max(0, self.xpostskip))
self.xpostskip += self.coloscm
self.xoverscan = self.coloscw
self.numcols_amp = self.xunderscan + self.xdata + self.xoverscan
self.numcols_overscan = self.xoverscan
self.numviscols_amp = self.xdata
# self.numviscols_image=self.numviscols_amp*self.num_ser_amps_det*self.numamps_x # bug? 21may15
self.numviscols_image = self.numviscols_amp * self.num_ser_amps_det * self.numdet_x
self.yunderscan = int(min(self.rowusct / self.row_bin, self.rowuscw))
self.yskip = int(
min(self.rowusct - self.yunderscan * self.row_bin, self.rowuscm))
self.ypreskip = self.rowusct - self.yskip - self.yunderscan * self.row_bin
self.yskip += self.first_row - 1
self.ydata = (lr - (fr - 1)) / self.row_bin
self.ydata = max(0, self.ydata)
self.ydata = int(self.ydata / self.num_par_amps_det)
self.ypostskip = self.rowtotal / self.numamps_y - (
(fr - 1) + self.ydata * self.row_bin)
self.ypostskip = int(max(0, self.ypostskip))
self.ypostskip += self.rowoscm
self.yoverscan = self.rowoscw
self.numrows_amp = self.yunderscan + self.ydata + self.yoverscan
self.numrows_overscan = self.yoverscan
self.numvisrows_amp = self.ydata
# self.numvisrows_image=self.numvisrows_amp*self.num_par_amps_det*self.numamps_y
self.numvisrows_image = self.numvisrows_amp * self.num_par_amps_det * self.numdet_y
self.numpix_amp = self.numcols_amp * self.numrows_amp
# totals for a single DETECTOR
self.numcols_det = self.numcols_amp * self.num_ser_amps_det
self.numrows_det = self.numrows_amp * self.num_par_amps_det
self.numpix_det = self.numcols_det * self.numrows_det
# totals for the IMAGE
self.numpix_image = self.numpix_det * self.num_detectors
self.numcols_image = self.numcols_det * self.numdet_x
self.numrows_image = self.numrows_det * self.numdet_y
self.numbytes_image = self.numpix_image * 2
# number of UNBINNED pixels to flush during clear
self.xflush = (
self.xpreskip + self.xskip + self.xpostskip +
(self.xunderscan + self.xdata + self.xoverscan) * self.col_bin)
self.yflush = (
self.ypreskip + self.yskip + self.ypostskip +
(self.yunderscan + self.ydata + self.yoverscan) * self.row_bin)
self.set_amp_positions()
return
def get_roi(self, roi_num=0):
"""
Returns a list of the ROI parameters for the roi_num specified.
Currently only one ROI (0) is supported.
Returned list format is (first_col,last_col,first_row,last_row,col_bin,row_bin).
"""
return [
self.first_col,
self.last_col,
self.first_row,
self.last_row,
self.col_bin,
self.row_bin,
]
def roi_reset(self):
"""
Resets detector ROI values to full frame, current binning.
"""
# get focalplane format
reply = self.get_format()
# update controller shifting parameters
self.set_roi(1, reply[0], 1, reply[4], -1, -1)
return reply
def set_amp_positions(self):
"""
Calculates amplifiers positions including gaps between amplifiers and CCDs
New: Zareba 23Mar2012
"""
self.amppix1 = numpy.empty(shape=[self.numamps_image], dtype="<u2")
self.amppix2 = numpy.empty(shape=[self.numamps_image], dtype="<u2")
indx = 0
for flip in self.amp_cfg:
if flip == 0:
flip_x = 0
flip_y = 0
elif flip == 1:
flip_x = 1
flip_y = 0
elif flip == 2:
flip_x = 0
flip_y = 1
else:
flip_x = 1
flip_y = 1
size_x = self.numviscols_amp * self.col_bin
size_y = self.numvisrows_amp * self.row_bin
self.amppix1[indx] = ((self.extpos_x[indx] - 1) * size_x +
flip_x * size_x + self.gapx[indx] + 1 -
flip_x)
self.amppix2[indx] = ((self.extpos_y[indx] - 1) * size_y +
flip_y * size_y + self.gapy[indx] + 1 -
flip_y)
indx += 1
return
def set_default_values(self):
"""
Sets default values for focalplane variables
"""
# set default values for the extension names, 'im1' -> 'imN'
# use _WCS.py file to set nonstandard values (focalplane.ext_name = [...])
self.ext_name = numpy.empty(shape=[self.numamps_image], dtype="S16")
for ext in range(self.numamps_image):
ext_name = "im%d" % (ext + 1)
self.ext_name[ext] = ext_name
self.ext_name = [y.decode() for y in self.ext_name] # new
# set default values for the etension numbers, 1 -> N
# use _WCS.py file to set nonstandard values ( focalplane.ext_number = [...])
self.ext_number = numpy.empty(shape=[self.numamps_image], dtype="<u2")
for ext in range(self.numamps_image):
self.ext_number[ext] = ext + 1
# set default values for the jpg extension values, 1 -> N
# use _WCS.py file to set nonstandard values (focalplane.jpg_ext = [...])
self.jpg_ext = numpy.empty(shape=[self.numamps_image], dtype="<u2")
for ext in range(self.numamps_image):
self.jpg_ext[ext] = ext + 1
# set default values for the gaps, 0
self.gapx = numpy.empty(shape=[self.numamps_image], dtype="<u2")
for ext in range(self.numamps_image):
self.gapx[ext] = 0
self.gapy = numpy.empty(shape=[self.numamps_image], dtype="<u2")
for ext in range(self.numamps_image):
self.gapy[ext] = 0
# set extension positions
self.extpos_x = numpy.empty(shape=[self.numamps_image], dtype="<u2")
for ext in range(self.numamps_image):
self.extpos_x[ext] = 1
self.extpos_y = numpy.empty(shape=[self.numamps_image], dtype="<u2")
for ext in range(self.numamps_image):
self.extpos_y[ext] = 1
self.det_number = numpy.empty(shape=[self.numamps_image], dtype="<u2")
numpy.ndarray.fill(self.det_number, 1)
self.detpos_x = numpy.empty(shape=[self.numamps_image], dtype="<u2")
numpy.ndarray.fill(self.detpos_x, 1)
self.detpos_y = numpy.empty(shape=[self.numamps_image], dtype="<u2")
numpy.ndarray.fill(self.detpos_y, 1)
return
def set_extension_name(self, ext_name):
for i, ext in enumerate(ext_name):
self.ext_name[i] = ext
return
def set_extension_extnum(self, ext_number):
for i, ext in enumerate(ext_number):
self.ext_number[i] = ext
return
def set_ref_pixel(self, xy):
"""
Set the reference pixel.
xy is [X,Y] in pixels.
"""
self.refpix1 = xy[0]
self.refpix2 = xy[1]
return
def set_extension_position(self, xy):
"""
Set the extension position of each amplifier.
xy is [[X,Y]] in index numbers, starting at [1,1].
"""
for i, xy_ in enumerate(xy):
self.extpos_x[i] = xy_[0]
self.extpos_y[i] = xy_[1]
return
def set_jpg_order(self, indices):
"""
Set JPG image positions.
"""
self.jpg_ext = indices
return
def __init__(self):
# header
self.header = Header("Focalplane")
# World Coordinate System
self.wcs = WCS(self)
# only needed for server side
self.header.set_header("focalplane")
# fixed values
# for multiple CCD detectors:
# 0 - each CCD has its own physical coordinates
# 1 - combine physical coordinates (physical coordinates
# are the same as detector coordinates)
self.split_physical_coords = 0
# number of detectors along X axis
self.numdet_x = 1
# number of detectors along Y axis
self.numdet_y = 1
# amplifier readout orientation
self.amp_config = "0"
# ampliefier readout orientation - new as an array
self.amp_cfg = [0]
# detector number for each detector
self.det_number = [1]
# extension number for each amplifier
self.ext_number = [1]
# extension name for each amplifier
self.ext_name = ["1"]
# extension number order for each amplifier when creating binary image
self.jpg_ext = [1]
# detector position in x direction in pixels
self.detpos_x = [1]
# detector position in y direction in pixels
self.detpos_y = [1]
# amplifier's positions along X axis
self.extpos_x = [1]
# amplifier's positions along Y axis
self.extpos_y = [1]
# amplifier's positions in pixels along X axis
self.amppix1 = [1]
# amplifier's positions in pixels along Y axis
self.amppix2 = [1]
# gap between amplifiers in X. value different than 0
# means that there is a gap on the left side of the amplifier.
# gapx is the sum of all gaps on the left side of the amplifier.
self.gapx = [0]
# gap between amplifiers in Y. value different than 0 means
# that there is a gap below of the amplifier.
# gapy is the sum of all gaps below the amplifier.
self.gapy = [0]
# number of amplifiers along X axis
self.numamps_x = 1
# number of amplifiers along Y axis
self.numamps_y = 1
# reference (zeropoint) position X (in pixels)
self.refpix1 = 1
# reference (zeropoint) position Y (in pixels)
self.refpix2 = 1
# unbinned number of visible pixels per amplifier along X axis
self.ampvispix_x = 1
# unbinned number of visible pixels per amplifier along Y axis
self.ampvispix_y = 1
# calculated values
# number of pixels in image
self.numpix_image = 0
# number of bytes per image
self.numbytes_image = 0
# number of columns per image
self.numcols_image = 0
# number of rows per image
self.numrows_image = 0
# number of total amps per image
self.numamps_image = 1
# number of detectors
self.num_detectors = 1
# number of columns per amplifier
self.numcols_amp = 1
# number of row per amplifier
self.numrows_amp = 1
# number of serial amps per detector
self.num_ser_amps_det = 1
# number of parallel amps per detector
self.num_par_amps_det = 1
# number of total amps per detector
self.num_amps_det = 1
# first column
self.first_col = 1
# first row
self.first_row = 1
# last column
self.last_col = 1
# last row
self.last_row = 1
# column binning
self.col_bin = 1
# row binning
self.row_bin = 1
# number of visible columns per amplifier
self.numviscols_amp = 1
# number of visible rows per amplifier
self.numvisrows_amp = 1
# number of visible columns per amplifier
self.numviscols_image = 1
# number of visible rows per amplifier
self.numvisrows_image = 1
# number of colums in overscan
self.numcols_overscan = 0
# number of rows in overscan
self.numrows_overscan = 0
# number of colums in underscan
self.numcols_underscan = 0
# number of rows in underscan
self.numrows_underscan = 0
# underscan skips
self.xunderscan = 0
self.yunderscan = 0
# overscan skips
self.xoverscan = 0
self.yoverscan = 0
# bias location constants
self.BL_COLUNDER = 1
self.BL_COLOVER = 2
self.BL_ROWUNDER = 3
self.BL_ROWOVER = 4
self.bias_location = self.BL_COLOVER
# number of pixels per amplifier
self.numpix_amp = 1
# number of pixels per detector
self.numpix_det = 1
# shifting
self.ns_total = 0
self.ns_predark = 0
self.ns_underscan = 0
self.ns_overscan = 0
self.np_total = 0
self.np_predark = 0
self.np_underscan = 0
self.np_overscan = 0
self.np_frametransfer = 0
# set shifting parameters
self.coltotal = 0
self.colusct = 0
self.coluscw = 0
self.coluscm = 0
self.coloscw = 0
self.coloscm = 0
self.rowtotal = 0
self.rowusct = 0
self.rowuscw = 0
self.rowuscm = 0
self.rowoscw = 0
self.rowoscm = 0
self.framet = 0
def __init__(self, tool_id="exposure", description=None):
Tools.__init__(self, tool_id, description)
Filename.__init__(self)
self.obstime = ObsTime()
self.image = Image()
# exposure flags, may be used anywhere
self.exposureflags = {
"NONE": 0,
"EXPOSING": 1,
"ABORT": 2,
"PAUSE": 3,
"RESUME": 4,
"READ": 5,
"PAUSED": 6,
"READOUT": 7,
"SETUP": 8,
"WRITING": 9,
"GUIDEERROR": 10,
"ERROR": 11,
}
azcam.db.exposureflags = self.exposureflags
self.exposureflags_rev = {v: k for k, v in self.exposureflags.items()}
# exposure flag defining state of current exposure
self.exposure_flag = self.exposureflags["NONE"]
# current image type, 'zero', 'object', 'dark', 'flat', 'ramp', etc
self.image_type = "zero"
# default imagetypes
self.image_types = ["zero", "object", "flat", "dark"]
# dictionary of shutter states for imagetypes {imagetype:ShutterState}
self.shutter_dict = {
"zero": 0,
"object": 1,
"flat": 1,
"dark": 0,
"ramp": 1,
}
# True to flush detector before exposures
self.flush_array = 1
# True to display an image after readout
self.display_image = 1
# True to send image to remote image server after readout
self.send_image = 0
self.message = "" # exposure status message
self.guide_status = 0
self.guide_image_copy = 0
# TdiMode flag, 0=not in TDI mode, 1=TDI mode
self.tdi_mode = 0
# TdiDelay mode
self.tdi_delay = 5
# ParDelay mode
self.par_delay = 5
# guide mode
self.guide_mode = 0
# True when exposure type is a comparision, to turn on comp lamps
self.comp_exposure = 0
# True when in a comparision exposure sequence so lamps stay on
self.comp_sequence = 0
# True when exposure has been aborted
self.aborted = 0
# True when exposure is completed, then toggled off
self.completed = 0
# requested exposure time in seconds
self.exposure_time = 1.0
# remaining exposure time in seconds for an exposure in progress
self.exposure_time_remaining = 0.0
# actual elapsed exposure time in seconds of last/current exposure
self.exposure_time_actual = 0.0
# exposure time saved for each exposure, used for zeros
self.exposure_time_saved = 0.0
# total time in seconds an exposure was paused
self.paused_time = 0.0
# starting clock paused time of exposure
self.paused_time_start = 0.0
# actual elapsed dark time of last/current exposure
self.dark_time = 0.0
# starting clock dark time of exposure
self.dark_time_start = 0.0
# True when in an exposure sequence
self.is_exposure_sequence = 0
# current exposure sequence number
self.exposure_sequence_number = 1
# total number of exposures in sequence
self.exposure_sequence_total = 1
# delay between sequence exposures in seconds
self.exposure_sequence_delay = 0.0
# sequence flush flag: -1=> use FlushArray, 0==> flush all, 1=> flush only first exposure, 2=> no flush
self.exposure_sequence_flush = 0
# remaining number of pixels to read for an exposure in progress
self.pixels_remaining = 0
# True to update headers in a thread to save time
self.update_headers_in_background = 0
self.updating_header = 0
# True to save image file after exposure
self.save_file = 1
# file types
self.filetypes = {"FITS": 0, "MEF": 1, "BIN": 2, "ASM": 6}
self.filetype = self.filetypes["MEF"]
# Exposure title
self.title = ""
# True to make image title the same as image type
self.auto_title = 0
# deinterlace mode; 1 = generic mode; x = ODI mode
self.deinterlace_mode = 1
# temporary image files
self.temp_image_file = ""
# filename of current image
self.last_filename = ""
# write data asynchronously
self.write_async = 0
# create the exposure header
self.header = Header("Exposure")
# flag indicating ROI has been changed
self.new_roi = 0
self.header.set_header("exposure", 1)
# data order
self.data_order = []
self.imageheaderfile = ""
self.pgress = 0 # debug
class Exposure(Tools, Filename, ObjectHeaderMethods):
"""
The base exposure tool.
Usually implemented as the "exposure" tool.
Only required attributes and stub methods are defined here. Additional
methods and attributes are added as needed in exposure-specific classes
which should inherit this class.
"""
def __init__(self, tool_id="exposure", description=None):
Tools.__init__(self, tool_id, description)
Filename.__init__(self)
self.obstime = ObsTime()
self.image = Image()
# exposure flags, may be used anywhere
self.exposureflags = {
"NONE": 0,
"EXPOSING": 1,
"ABORT": 2,
"PAUSE": 3,
"RESUME": 4,
"READ": 5,
"PAUSED": 6,
"READOUT": 7,
"SETUP": 8,
"WRITING": 9,
"GUIDEERROR": 10,
"ERROR": 11,
}
azcam.db.exposureflags = self.exposureflags
self.exposureflags_rev = {v: k for k, v in self.exposureflags.items()}
# exposure flag defining state of current exposure
self.exposure_flag = self.exposureflags["NONE"]
# current image type, 'zero', 'object', 'dark', 'flat', 'ramp', etc
self.image_type = "zero"
# default imagetypes
self.image_types = ["zero", "object", "flat", "dark"]
# dictionary of shutter states for imagetypes {imagetype:ShutterState}
self.shutter_dict = {
"zero": 0,
"object": 1,
"flat": 1,
"dark": 0,
"ramp": 1,
}
# True to flush detector before exposures
self.flush_array = 1
# True to display an image after readout
self.display_image = 1
# True to send image to remote image server after readout
self.send_image = 0
self.message = "" # exposure status message
self.guide_status = 0
self.guide_image_copy = 0
# TdiMode flag, 0=not in TDI mode, 1=TDI mode
self.tdi_mode = 0
# TdiDelay mode
self.tdi_delay = 5
# ParDelay mode
self.par_delay = 5
# guide mode
self.guide_mode = 0
# True when exposure type is a comparision, to turn on comp lamps
self.comp_exposure = 0
# True when in a comparision exposure sequence so lamps stay on
self.comp_sequence = 0
# True when exposure has been aborted
self.aborted = 0
# True when exposure is completed, then toggled off
self.completed = 0
# requested exposure time in seconds
self.exposure_time = 1.0
# remaining exposure time in seconds for an exposure in progress
self.exposure_time_remaining = 0.0
# actual elapsed exposure time in seconds of last/current exposure
self.exposure_time_actual = 0.0
# exposure time saved for each exposure, used for zeros
self.exposure_time_saved = 0.0
# total time in seconds an exposure was paused
self.paused_time = 0.0
# starting clock paused time of exposure
self.paused_time_start = 0.0
# actual elapsed dark time of last/current exposure
self.dark_time = 0.0
# starting clock dark time of exposure
self.dark_time_start = 0.0
# True when in an exposure sequence
self.is_exposure_sequence = 0
# current exposure sequence number
self.exposure_sequence_number = 1
# total number of exposures in sequence
self.exposure_sequence_total = 1
# delay between sequence exposures in seconds
self.exposure_sequence_delay = 0.0
# sequence flush flag: -1=> use FlushArray, 0==> flush all, 1=> flush only first exposure, 2=> no flush
self.exposure_sequence_flush = 0
# remaining number of pixels to read for an exposure in progress
self.pixels_remaining = 0
# True to update headers in a thread to save time
self.update_headers_in_background = 0
self.updating_header = 0
# True to save image file after exposure
self.save_file = 1
# file types
self.filetypes = {"FITS": 0, "MEF": 1, "BIN": 2, "ASM": 6}
self.filetype = self.filetypes["MEF"]
# Exposure title
self.title = ""
# True to make image title the same as image type
self.auto_title = 0
# deinterlace mode; 1 = generic mode; x = ODI mode
self.deinterlace_mode = 1
# temporary image files
self.temp_image_file = ""
# filename of current image
self.last_filename = ""
# write data asynchronously
self.write_async = 0
# create the exposure header
self.header = Header("Exposure")
# flag indicating ROI has been changed
self.new_roi = 0
self.header.set_header("exposure", 1)
# data order
self.data_order = []
self.imageheaderfile = ""
self.pgress = 0 # debug
def initialize(self):
"""
Initialize exposure.
"""
# call initialize() method on other tools
for tool in azcam.db.tools_init:
azcam.db.tools[tool].initialize()
self.initialized = 1
return
def reset(self):
"""
Reset exposure tool.
"""
# initialize only once
if not self.initialized:
self.initialize()
# set temporary filenames
self.set_temp_files()
# setup for exposures
self.is_exposure_sequence = 0
self.exposure_sequence_number = 1
self.set_auto_title()
azcam.db.abortflag = 0
self.save_file = 1
self.exposure_flag = self.exposureflags["NONE"]
# call reset() method on other tools
for tool in azcam.db.tools_reset:
azcam.db.tools[tool].reset()
return
# **********************************************************************************************
# Exposure control
# **********************************************************************************************
def start(self):
"""
Allow custom operations at start of exposure.
"""
try:
azcam.db.tools["instrument"].exposure_start()
except KeyError:
pass
try:
azcam.db.tools["telescope"].exposure_start()
except KeyError:
pass
return
def finish(self):
"""
Allow custom operations at end of exposure.
"""
try:
azcam.db.tools["instrument"].exposure_finish()
except KeyError:
pass
try:
azcam.db.tools["telescope"].exposure_finish()
except KeyError:
pass
return
def finished(self):
if self.completed:
return 1
else:
return 0
def get_exposureflag(self):
return [self.exposure_flag, self.exposureflags_rev[self.exposure_flag]]
def test(self, exposure_time=0.0, shutter=0):
"""
Make a test exposure.
exposure_time is the exposure time in seconds
shutter is 0 for closed and 1 for open
title is the image title.
"""
old_testimage = self.test_image
old_imagetype = self.image_type
old_exposuretime = self.exposure_time
self.test_image = 1
if shutter:
shutter_state = "object"
else:
shutter_state = "dark"
self.expose(exposure_time, shutter_state, "test image")
self.test_image = old_testimage
self.image_type = old_imagetype
self.exposure_time = old_exposuretime
return
def expose(self, exposure_time=-1, imagetype="", title=""):
"""
Make a complete exposure.
exposure_time is the exposure time in seconds
imagetype is the type of exposure ('zero', 'object', 'flat', ...)
title is the image title.
"""
# allow custom operations
self.start()
azcam.log("Exposure started")
# if last exposure was aborted, warn before clearing flag
if self.exposure_flag == self.exposureflags["ABORT"]:
azcam.AzcamWarning("Previous exposure was aborted")
# begin
if self.exposure_flag != self.exposureflags["ABORT"]:
self.begin(exposure_time, imagetype, title)
# integrate
if self.exposure_flag != self.exposureflags["ABORT"]:
self.integrate()
# readout
if (self.exposure_flag != self.exposureflags["ABORT"]
and self.exposure_flag == self.exposureflags["READ"]):
try:
self.readout()
except azcam.AzcamError:
pass
# end
if self.exposure_flag != self.exposureflags["ABORT"]:
self.end()
self.exposure_flag = self.exposureflags["NONE"]
self.completed = 1
azcam.log("Exposure finished")
# allow custom operations
self.finish()
return
def expose1(self,
exposure_time: float = -1,
image_type: str = "",
image_title: str = ""):
"""
Make a complete exposure with immediate return to caller.
:param exposure_time: the exposure time in seconds
:param image_type: type of exposure ('zero', 'object', 'flat', ...)
:param image_title: image title, usually surrounded by double quotes
"""
arglist = [exposure_time, image_type, image_title]
thread = threading.Thread(target=self.expose,
name="expose1",
args=arglist)
thread.start()
return
def guide(self, number_exposures=1):
"""
Make a complete guider exposure sequence.
NumberExposures is the number of exposures to make, -1 loop forever
"""
AbortFlag = 0
number_exposures = int(number_exposures)
# system must be reset once before an exposure can be made
if not azcam.db.tools["controller"].is_reset:
azcam.db.tools["controller"].reset()
# parameters for faster operation
flusharray = self.flush_array
azcam.log("Guide started")
# this loop continues even for errors since data is sent to a seperate client receiving images
LoopCount = 0
while True:
if 0:
self.begin(exposure_time=-1,
imagetype="object",
title="guide image")
# integrate
self.integrate()
# readout
if self.exposure_flag == self.exposureflags["READ"]:
try:
self.readout()
self.guide_status = 1 # image read OK
self.guide_image_copy = self.image
except Exception:
self.guide_status = 2 # image not read OK, but don't stop guide loop
self.image = self.guide_image_copy
# image writing
self.end()
self.exposure_flag = self.exposureflags["NONE"]
else:
self.expose(-1, "object", "guide image")
AbortFlag = azcam.db.abortflag
if AbortFlag:
break
if number_exposures == -1:
continue
else:
LoopCount += 1
if LoopCount >= number_exposures:
break
# finish
self.guide_status = 0
self.flush_array = flusharray
if AbortFlag:
azcam.AzcamWarning("Guide aborted")
else:
azcam.log("Guide finished")
return
def guide1(self, number_exposures=1):
"""
Make a complete guider exposure with an immediate return.
NumberExposures is the number of exposures to make, -1 loop forever
"""
arglist = [number_exposures]
thread = threading.Thread(target=self.guide,
name="guide1",
args=arglist)
thread.start()
return
def begin(self, exposure_time=-1, imagetype="", title=""):
"""
Initiates the first part of an exposure, through image flushing.
exposure_time is in seconds.
imagetype is one of zero, object, flat, dark, ramp, ...
"""
# system must be reset once before an exposure can be made
x = self.is_exposure_sequence # save this flag which is lost by reset
if not azcam.db.tools["controller"].is_reset:
self.reset()
self.is_exposure_sequence = x
# set exposure flag
self.exposure_flag = self.exposureflags["SETUP"]
# reset flags as new data coming
self.image.valid = 0
self.image.written = 0
self.image.toggle = 0
self.image.assembled = 0
# clear the image header
self.image.header.delete_all_items()
self.image.header.delete_all_keywords()
# update image size
try:
self.set_roi() # bug?
except Exception:
pass
if self.new_roi:
self.image.data = numpy.empty(
shape=[
self.image.focalplane.numamps_image,
self.image.focalplane.numpix_amp,
],
dtype="<u2",
)
self.new_roi = 0
# imagetype
if imagetype != "":
self.image_type = imagetype
self.image.image_type = self.image_type
imagetype = self.image_type.lower()
# exposure times
exposure_time = float(exposure_time)
self.exposure_time_saved = self.exposure_time
if exposure_time >= 0:
self.exposure_time = float(exposure_time)
if imagetype == "zero":
self.exposure_time = 0.0
self.paused_time = 0.0 # reset paused time
self.paused_time_start = 0.0 # reset paused start time
self.exposure_time_remaining = self.exposure_time
# update title and set OBJECT keyword using title
self.set_image_title(title)
# send exposure time to controller
self.set_exposuretime(self.exposure_time)
# set total number of pixels to readout
self.pixels_remaining = self.image.focalplane.numpix_image
# set CompExposure flag for any undefined image types (comp names)
if imagetype not in self.image_types:
self.comp_exposure = 1
else:
self.comp_exposure = 0
if not self.guide_mode: # for speed
try:
shutterstate = self.shutter_dict[imagetype]
except KeyError:
shutterstate = 1 # other types are comps, so open shutter
azcam.db.tools["controller"].set_shutter_state(shutterstate)
self.delete_keyword("COMPLAMP")
# set comp lamps, turn on, set keyword
if self.comp_exposure and azcam.db.tools["instrument"].enabled:
if self.comp_sequence: # lamps already on
pass
else:
azcam.db.tools["instrument"].set_comps(imagetype)
if not azcam.db.tools["instrument"].shutter_strobe:
azcam.db.tools["instrument"].comps_on()
lampnames = " ".join(azcam.db.tools["instrument"].get_comps())
self.set_keyword("COMPLAMP", lampnames, "Comp lamp names", "str")
self.set_keyword("IMAGETYP", "comp", "Image type", "str")
azcam.db.tools["instrument"].comps_delay() # delay for lamp warmup
else:
if not self.guide_mode:
try:
if (azcam.db.tools["instrument"] is not None
) and azcam.db.tools["instrument"].enabled:
azcam.db.tools["instrument"].set_comps() # reset
except KeyError:
pass
self.set_keyword("IMAGETYP", imagetype, "Image type", "str")
# update all headers with current data
if self.update_headers_in_background:
headerthread = threading.Thread(target=self.update_headers,
name="updateheaders",
args=[])
headerthread.start()
else:
self.update_headers()
# flush detector
if self.flush_array:
self.flush()
else:
azcam.db.tools["controller"].stop_idle()
# record current time and date in header
self.record_current_times()
return
def integrate(self):
"""
Integration.
"""
return
def readout(self):
"""
Exposure readout.
"""
return
def end(self):
"""
Completes an exposure by writing file and displaying image.
"""
return
def start_readout(self):
"""
Start immediate readout of an exposing image.
Returns immediately, not waiting for readout to finish.
Really sets a flag which is read in expose().
"""
if self.exposure_flag != self.exposureflags["NONE"]:
self.exposure_flag = self.exposureflags["READ"]
return
def flush(self, Cycles=1):
"""
Flush/clear detector.
Cycles is the number of times to flush the detector.
"""
azcam.log("Flushing")
return azcam.db.tools["controller"].flush(int(Cycles))
def sequence(self, number_exposures=1, flush_array_flag=-1, delay=-1):
"""
Take an exposure sequence.
Uses pre-set exposure time, image type and image title.
NumberExposures is the number of exposures to make.
FlushArrayFlag defines detector flushing:
-1 => current value defined by exposure.exposure_sequence_flush [default]
0 => flush for each exposure
1 => flush after first exposure only
2 => no flush
Delay => delay between exposures in seconds
-1 => no change
"""
AbortFlag = 0
self.is_exposure_sequence = 1
self.exposure_sequence_number = 1
self.exposure_sequence_total = number_exposures
number_exposures = int(number_exposures)
flush_array_flag = int(flush_array_flag)
if delay != -1 and delay != "-1":
self.exposure_sequence_delay = float(delay)
# set flushing
currentflush = self.flush_array
if flush_array_flag == -1:
flush_array_flag = self.exposure_sequence_flush
if flush_array_flag == 0 or flush_array_flag == 1:
FlushArray = True
else:
FlushArray = False
self.flush_array = FlushArray
self.comp_sequence = (self.check_comparison_imagetype()
and azcam.db.tools["instrument"].enabled)
if self.comp_sequence:
azcam.log("Starting comparison sequence")
azcam.db.tools["instrument"].set_comps(self.image_type)
if azcam.db.tools["instrument"].shutter_strobe:
pass # these instruments use shutter to turn on comps
else:
azcam.db.tools["instrument"].comps_on()
azcam.db.tools["instrument"].comps_delay(
) # delay for lamp warmup if needed
for i in range(number_exposures):
if i > 0:
time.sleep(self.exposure_sequence_delay)
if i > 0 and flush_array_flag == 1:
self.flush_array = False
self.expose(self.exposure_time, self.image_type, self.title)
# check and clear user abort
AbortFlag = azcam.db.abortflag
if AbortFlag:
break
# sequence may have been stopped
if not self.is_exposure_sequence:
break
self.exposure_sequence_number += 1
# turn off comps
if self.comp_sequence:
azcam.db.tools["instrument"].comps_off()
self.comp_sequence = 0
self.flush_array = currentflush
self.is_exposure_sequence = 0
self.exposure_sequence_number = 1
if AbortFlag:
self.aborted = 1
return
def sequence1(self, number_exposures=1, flush_array_flag=-1, delay=-1):
"""
Take an exposure sequence.
Uses pre-set image type and image title.
number_exposures is the number of exposures to make.
flush_array_flag defines detector flushing:
-1 => current value defined by exposure.exposure_sequence_flush [default]
0 => flush for each exposure
1 => flush after first exposure only
2 => no flush
Delay => delay between exposures in seconds
-1 => no change
"""
arglist = [number_exposures, flush_array_flag, delay]
thread = threading.Thread(target=self.sequence,
name="sequence1",
args=arglist)
thread.start()
return
def pause(self):
"""
Pause an exposure in progress (integration only).
Really sets a flag which is read in expose().
"""
self.paused_time_start = time.time() # save paused clock time
if self.exposure_flag != self.exposureflags["NONE"]:
self.exposure_flag = self.exposureflags["PAUSE"]
return
def resume(self):
"""
Resume a paused exposure.
Really sets a flag which is read in expose().
"""
self.paused_time = (
time.time() - self.paused_time_start
) + self.paused_time # total paused time in seconds
if self.exposure_flag != self.exposureflags["NONE"]:
self.exposure_flag = self.exposureflags["RESUME"]
return
def abort(self):
"""
Abort an exposure in progress.
Really sets a flag which is read in expose().
"""
if self.exposure_flag != self.exposureflags["NONE"]:
self.exposure_flag = self.exposureflags["ABORT"]
return
def set_shutter(self, state: int = 0, shutter_id: int = 0):
"""
Open or close a shutter.
:param state:
:param shutter_id: Shutter ID flag
* 0 => controller default shutter.
* 1 => instrument default shutter.
"""
if shutter_id == 0:
azcam.db.tools["controller"].set_shutter(state)
elif shutter_id == 1:
azcam.db.tools["instrument"].set_shutter(state)
return
def parshift(self, number_rows: int):
"""
Shift sensor by number_rows.
:param number_rows: number of rows to shift (positive is toward readout, negative is away)
"""
number_rows = int(float(number_rows))
azcam.db.tools["controller"].parshift(number_rows)
return
# ***************************************************************************
# pixel counter
# ***************************************************************************
def get_pixels_remaining(self):
"""
Return number of remaining pixels to be read (counts down).
"""
reply = azcam.db.tools["controller"].get_pixels_remaining()
self.pixels_remaining = reply
return reply
# ***************************************************************************
# exposure time
# ***************************************************************************
def get_exposuretime(self):
"""
Return current exposure time in seconds.
"""
if azcam.db.tools["controller"].is_reset:
self.exposure_time = azcam.db.tools["controller"].get_exposuretime(
)
return self.exposure_time
def set_exposuretime(self, exposure_time):
"""
Set current exposure time in seconds.
"""
self.exposure_time = float(exposure_time)
self.exposure_time_actual = self.exposure_time # may be changed later
azcam.db.tools["controller"].set_exposuretime(self.exposure_time)
self.header.set_keyword("EXPREQ", exposure_time,
"Exposure time requested (seconds)", "float")
self.header.set_keyword("EXPTIME", exposure_time,
"Exposure time (seconds)", "float")
return
def get_exposuretime_remaining(self):
"""
Return remaining exposure time (in seconds).
"""
if azcam.db.tools["controller"].is_reset:
self.exposure_time_remaining = azcam.db.tools[
"controller"].update_exposuretime_remaining()
return self.exposure_time_remaining
# **********************************************************************************************
# header
# **********************************************************************************************
def record_current_times(self):
"""
Record the current times and data info in the header.
"""
# get current time and date
self.obstime.update(0)
# format should be YYYY-MM-DDThh:mm:ss.sss ISO 8601
self.header.set_keyword("DATE-OBS", self.obstime.date[0],
"UTC shutter opened", "str")
self.header.set_keyword("DATE", self.obstime.date[0],
"UTC date and time file writtten",
"str") # OLD
self.header.set_keyword("TIME-OBS", self.obstime.ut[0],
"UTC at start of exposure", "str")
self.header.set_keyword("UTC-OBS", self.obstime.ut[0],
"UTC at start of exposure", "str")
self.header.set_keyword("UT", self.obstime.ut[0],
"UTC at start of exposure", "str")
self.header.set_keyword("TIMESYS", self.obstime.time_system[0],
"Time system", "str")
self.header.set_keyword("TIMEZONE", self.obstime.time_zone[0],
"Local time zone", "str")
self.header.set_keyword(
"LOCTIME",
self.obstime.local_time[0],
"Local time at start of exposure",
"str",
)
return
def update_headers(self):
"""
Update all headers, reading current data.
"""
# set flag that update is in progress
self.updating_header = 1
# all headers to be updated must be in azcam.db['headers']
for objectname in azcam.db.headers:
if (objectname == "controller" or objectname == "system"
or objectname == "exposure" or objectname == "focalplane"):
continue
try:
azcam.db.tools[objectname].update_header(
) # dont crash so all headers get updated
except Exception as e:
azcam.log(f"could not get {objectname} header: {e}")
# update focalplane header which is not in db
self.image.focalplane.update_header()
# try to update system header last
if "system" in azcam.db.headers:
try:
azcam.db.headers["system"].update_header()
except Exception:
pass
# set flag that update is finished
self.updating_header = 0
return
# ***************************************************************************
# misc
# ***************************************************************************
def set_auto_title(self, flag=-1):
"""
Set the AutoTitle flag so that image title matches lowercase imagetype.
"""
if flag != -1:
self.auto_title = flag
self.set_image_title()
if flag != 0:
self.set_image_title()
return
def set_image_title(self, title=""):
"""
Set the image title.
Allows for AutoTitle.
"""
if self.auto_title:
if self.image_type.lower(
) == "object": # don't change object title in AutoTitle mode
pass
else:
if title == "":
title = self.image_type.lower()
# set OBJECT keyword to title or autotitle value
self.set_keyword("OBJECT", title, "", "str")
self.title = title
self.image.title = title
return
def get_image_title(self):
"""
Get the current image title.
Allows for AutoTitle.
"""
return self.title
def set_image_type(self, imagetype="zero"):
"""
Set image type for an exposure.
imagetype is system defines, and typically includes:
zero, object, dark, flat.
"""
self.image_type = imagetype
return
def check_image_ready(self):
"""
Returns True (1) if exposure image is ready and then toggles the flag off
so that image is not detected multiple times. Used only for clients which need to know
when an image is ready.
An image is ready when written to disk if SaveFile is true, or when valid if SaveFile is false.
"""
if self.image.toggle:
self.image.toggle = 0
return 1
else:
return 0
def get_image_type(self):
"""
Get current image type for an exposure.
imagetype is system defines, and typically includes:
zero, object, dark, flat.
"""
return self.image_type
def get_image_types(self):
"""
Return a list of valid imagetypes.
Gets imagetypes and comparisons.
"""
l1 = self.image_types
try:
l2 = azcam.db.tools["instrument"].get_all_comps()
except Exception:
return l1
return l1 + l2 if len(l2) > 0 else l1
def check_comparison_imagetype(self, imagetype=""):
"""
Returns 1 if imagetype is a comparision, 0 if not.
If imagetype is not specified, checks the current type.
"""
if imagetype == "":
imagetype = self.image_type # if not specified use previous (global)
# any undefined image types are comps
if imagetype in self.image_types:
return 0
else:
return 1
def set_temp_files(self):
"""
Update TempImageFile and TempDisplayFile file names based on CommandServer port.
"""
if not os.path.isabs(self.temp_image_file):
self.temp_image_file = os.path.join(azcam.db.datafolder,
"TempImage")
self.temp_image_file = os.path.normpath(self.temp_image_file)
self.temp_image_file = "%s%d" % (
self.temp_image_file,
azcam.db.tools["cmdserver"].port,
) # make unique for multiple processes
return
def set_test_image(self, flag):
"""
Sets TestImage flag is True, clears if False.
"""
self.test_image = flag
return
def get_test_image(self):
"""
Returns TestImage flag.
"""
flag = self.test_image
return ["OK", flag]
# **********************************************************************************************
# detector parameters
# **********************************************************************************************
def set_detpars(self, sensor_data):
"""
Set detector parameters from sensor data dictionary.
"""
detpars = sensor_data
if detpars.get("ref_pixel"):
self.set_ref_pixel(detpars["ref_pixel"])
if detpars.get("format"):
self.set_format(*detpars["format"])
if detpars.get("focalplane"):
self.set_focalplane(*detpars["focalplane"])
if detpars.get("roi"):
self.set_roi(*detpars["roi"])
if detpars.get("ext_position"):
self.set_extension_position(detpars["ext_position"])
if detpars.get("jpg_order"):
self.set_jpg_order(detpars["jpg_order"])
if detpars.get("det_number"):
self.set_detnum(detpars["det_number"])
if detpars.get("det_position"):
self.set_detpos(detpars["det_position"])
if detpars.get("det_gap"):
self.set_detgap(detpars["det_gap"])
if detpars.get("ext_name"):
self.set_extname(detpars["ext_name"])
if detpars.get("ext_number"):
self.set_extnum(detpars["ext_number"])
if detpars.get("ctype"):
self.image.focalplane.wcs.ctype1 = detpars["ctype"][0]
self.image.focalplane.wcs.ctype2 = detpars["ctype"][1]
return
def set_format(
self,
ns_total=-1,
ns_predark=-1,
ns_underscan=-1,
ns_overscan=-1,
np_total=-1,
np_predark=-1,
np_underscan=-1,
np_overscan=-1,
np_frametransfer=-1,
):
"""
Set the detector format for subsequent exposures.
Must call set_roi() after using this command and before starting exposure.
ns_total is the number of visible columns.
ns_predark is the number of physical dark underscan columns.
ns_underscan is the desired number of desired dark underscan columns.
ns_overscan is the number of dark overscan columns.
np_total is the number of visible rows.
np_predark is the number of physical dark underscan rows.
np_underscan is the number of desired dark underscan rows.
np_overscan is the number of desired dark overscan rows.
np_frametransfer is the rows to frame transfer shift.
"""
# update image.focalplane
self.image.focalplane.set_format(
ns_total,
ns_predark,
ns_underscan,
ns_overscan,
np_total,
np_predark,
np_underscan,
np_overscan,
np_frametransfer,
)
# update controller parameters
controller = azcam.db.tools["controller"]
controller.detpars.ns_total = self.image.focalplane.ns_total
controller.detpars.ns_predark = self.image.focalplane.ns_predark
controller.detpars.ns_underscan = self.image.focalplane.ns_underscan
controller.detpars.ns_overscan = self.image.focalplane.ns_overscan
controller.detpars.np_total = self.image.focalplane.np_total
controller.detpars.np_predark = self.image.focalplane.np_predark
controller.detpars.np_underscan = self.image.focalplane.np_underscan
controller.detpars.np_overscan = self.image.focalplane.np_overscan
controller.detpars.np_frametransfer = self.image.focalplane.np_frametransfer
controller.detpars.coltotal = self.image.focalplane.ns_total
controller.detpars.colusct = self.image.focalplane.ns_predark
controller.detpars.coluscw = self.image.focalplane.ns_underscan
controller.detpars.coluscm = 0
controller.detpars.coloscw = self.image.focalplane.ns_overscan
controller.detpars.coloscm = 0
controller.detpars.rowtotal = self.image.focalplane.np_total
controller.detpars.rowusct = self.image.focalplane.np_predark
controller.detpars.rowuscw = self.image.focalplane.np_underscan
controller.detpars.rowuscm = 0
controller.detpars.rowoscw = self.image.focalplane.np_overscan
controller.detpars.rowoscm = 0
controller.detpars.framet = self.image.focalplane.np_frametransfer
return
def get_format(self):
"""
Return the current detector format parameters.
"""
return self.image.focalplane.get_format()
def set_focalplane(self,
numdet_x=-1,
numdet_y=-1,
numamps_x=-1,
numamps_y=-1,
amp_config=""):
"""
Sets focal plane configuration for subsequent exposures. Use after set_format().
Must call set_roi() after using this command and before starting exposure.
This command replaces SetConfiguration.
Default focalplane values are set here.
numdet_x defines number of detectors in Column direction.
numdet_y defines number of detectors in Row direction.
numamps_x defines number of amplifiers in Column direction.
numamps_y defines number of amplifiers in Row direction.
amp_config defines each amplifier's orientation (ex: '1223').
0 - normal
1 - flip x
2 - flip y
3 - flip x and y
"""
# update image.focalplane
reply = self.image.focalplane.set_focalplane(numdet_x, numdet_y,
numamps_x, numamps_y,
amp_config)
# update controller parameters
controller = azcam.db.tools["controller"]
controller.detpars.numdet_x = self.image.focalplane.numdet_x
controller.detpars.numdet_y = self.image.focalplane.numdet_y
controller.detpars.numamps_x = self.image.focalplane.numamps_x
controller.detpars.numamps_y = self.image.focalplane.numamps_y
controller.detpars.amp_config = self.image.focalplane.amp_config
controller.detpars.amp_cfg = self.image.focalplane.amp_cfg
controller.detpars.num_detectors = self.image.focalplane.num_detectors
controller.detpars.num_ser_amps_det = self.image.focalplane.num_ser_amps_det
controller.detpars.num_par_amps_det = self.image.focalplane.num_par_amps_det
controller.detpars.num_amps_det = self.image.focalplane.num_amps_det
controller.detpars.numamps_image = self.image.focalplane.numamps_image
controller.detpars.ampvispix_x = self.image.focalplane.ampvispix_x
controller.detpars.ampvispix_y = self.image.focalplane.ampvispix_y
self.image.set_scaling()
return reply
def get_focalplane(self):
"""
Returns the current focal plane configuration.
"""
return self.image.focalplane.get_focalplane()
def set_data_order(self, dataOrder):
"""
Sets data order
"""
self.data_order = []
if len(dataOrder) > 0:
for item in dataOrder:
self.data_order.append(int(item))
return
def set_roi(
self,
first_col=-1,
last_col=-1,
first_row=-1,
last_row=-1,
col_bin=-1,
row_bin=-1,
roi_num=0,
):
"""
Sets the ROI values for subsequent exposures.
Currently only one ROI (0) is supported.
These values are for the entire focal plane, not just one detector.
"""
# update image.focalplane
first_col = int(first_col)
last_col = int(last_col)
first_row = int(first_row)
last_row = int(last_row)
col_bin = int(col_bin)
row_bin = int(row_bin)
roi_num = int(roi_num)
self.image.focalplane.set_roi(first_col, last_col, first_row, last_row,
col_bin, row_bin, roi_num)
# update controller parameters
controller = azcam.db.tools["controller"]
controller.detpars.first_col = self.image.focalplane.first_col
controller.detpars.last_col = self.image.focalplane.last_col
controller.detpars.first_row = self.image.focalplane.first_row
controller.detpars.last_row = self.image.focalplane.last_row
controller.detpars.col_bin = self.image.focalplane.col_bin
controller.detpars.row_bin = self.image.focalplane.row_bin
controller.detpars.xunderscan = self.image.focalplane.xunderscan
controller.detpars.xskip = self.image.focalplane.xskip
controller.detpars.xpreskip = self.image.focalplane.xpreskip
controller.detpars.xdata = self.image.focalplane.xdata
controller.detpars.xpostskip = self.image.focalplane.xpostskip
controller.detpars.xoverscan = self.image.focalplane.xoverscan
controller.detpars.yunderscan = self.image.focalplane.yunderscan
controller.detpars.yskip = self.image.focalplane.yskip
controller.detpars.ypreskip = self.image.focalplane.ypreskip
controller.detpars.ydata = self.image.focalplane.ydata
controller.detpars.ypostskip = self.image.focalplane.ypostskip
controller.detpars.yoverscan = self.image.focalplane.yoverscan
controller.detpars.numcols_amp = self.image.focalplane.numcols_amp
controller.detpars.numcols_overscan = self.image.focalplane.numcols_overscan
controller.detpars.numviscols_amp = self.image.focalplane.numviscols_amp
controller.detpars.numviscols_image = self.image.focalplane.numviscols_image
controller.detpars.numrows_amp = self.image.focalplane.numrows_amp
controller.detpars.numrows_overscan = self.image.focalplane.numrows_overscan
controller.detpars.numvisrows_amp = self.image.focalplane.numvisrows_amp
controller.detpars.numvisrows_image = self.image.focalplane.numvisrows_image
controller.detpars.numpix_amp = self.image.focalplane.numpix_amp
controller.detpars.numcols_det = self.image.focalplane.numcols_det
controller.detpars.numrows_det = self.image.focalplane.numrows_det
controller.detpars.numpix_det = self.image.focalplane.numpix_det
controller.detpars.numpix_image = self.image.focalplane.numpix_image
controller.detpars.numcols_image = self.image.focalplane.numcols_image
controller.detpars.numrows_image = self.image.focalplane.numrows_image
controller.detpars.numbytes_image = self.image.focalplane.numbytes_image
controller.detpars.xflush = self.image.focalplane.xflush
controller.detpars.yflush = self.image.focalplane.yflush
# update controller
controller.set_roi()
# update image size
self.size_x = self.image.focalplane.numcols_image
self.size_y = self.image.focalplane.numrows_image
self.image.size_x = self.image.focalplane.numcols_image
self.image.size_y = self.image.focalplane.numrows_image
# indicate that ROI has changed for next exposure
self.new_roi = 1
return
def get_roi(self, roi_num=0):
"""
Returns a list of the ROI parameters for the roi_num specified.
Currently only one ROI (0) is supported.
Returned list format is (first_col,last_col,first_row,last_row,col_bin,row_bin).
"""
return self.image.focalplane.get_roi(roi_num)
def roi_reset(self):
"""
Resets detector ROI values to full frame, current binning.
"""
self.image.focalplane.roi_reset()
return
def set_ref_pixel(self, XY):
"""
Set the reference pixel.
XY is [X,Y] in pixels.
"""
self.image.focalplane.set_ref_pixel(XY)
return
def set_extension_position(self, XY):
"""
Set the extension position of each amplifier.
XY is [[X,Y]] in index numbers, starting at [1,1].
"""
self.image.focalplane.set_extension_position(XY)
return
def set_detnum(self, det_number):
"""
Set the detector numbers.
"""
self.image.focalplane.det_number = det_number
return
def set_detgap(self, det_gap):
"""
Set the detector gaps in pixels.
"""
for i, gap in enumerate(det_gap):
self.image.focalplane.gapx[i] = gap[0]
self.image.focalplane.gapy[i] = gap[1]
return
def set_detpos(self, det_position):
"""
Set the detector positions.
"""
for i, pos in enumerate(det_position):
self.image.focalplane.detpos_x[i] = pos[0]
self.image.focalplane.detpos_y[i] = pos[1]
return
def set_jpg_order(self, Indices):
"""
Set JPG image positions.
"""
self.image.focalplane.set_jpg_order(Indices)
return
def set_tdi_delay(self, flag):
"""
Set TDI line delay On or Off.
flag==True sets delay to self.tdi_delay.
flag==Flase sets line delay to normal value, self.par_delay.
"""
return
def set_extname(self, ext_name):
"""
Set image extension names.
"""
self.image.focalplane.set_extension_name(ext_name)
return
def set_extnum(self, ext_number):
"""
Set image extension numbers.
"""
self.image.focalplane.set_extension_extnum(ext_number)
return
def get_status(self):
"""
Return a variety of system status data in one dictionary.
"""
progress = 0
filename = self.get_filename()
# filename = os.path.basename(filename)
et = self.get_exposuretime()
if self.is_exposure_sequence:
self.exposure_sequence_number
seqcount = self.exposure_sequence_number
seqtotal = self.exposure_sequence_total
else:
seqcount = 0
seqtotal = 0
ef = self.exposure_flag
expstate = self.exposureflags_rev.get(ef, "")
if azcam.db.tools["tempcon"].enabled:
try:
camtemp, dewtemp = azcam.db.tools["tempcon"].get_temperatures(
)[0:2]
camtemp = f"{camtemp:.1f}"
dewtemp = f"{dewtemp:.1f}"
except Exception as e:
azcam.log(e)
camtemp = -999.9 # error reading temperature
dewtemp = -666.6
else:
camtemp = -999.9
dewtemp = -666.6
# camtemp = f"{camtemp:8.3f}"
# dewtemp = f"{dewtemp:8.3f}"
if ef == 1:
expcolor = "green"
et = self.get_exposuretime()
if et == 0:
progress = 0.0
explabel = ""
else:
etr = self.get_exposuretime_remaining()
explabel = f"{etr:.1f} sec remaining"
progress = float(100.0 * (etr / et))
elif ef == 7:
expcolor = "red"
progress = int(100.0 * (self.get_pixels_remaining() /
self.image.focalplane.numpix_image))
explabel = f"{progress}% readout"
elif ef == 8:
expcolor = "cyan"
explabel = "exposure setup"
else:
expcolor = "transparent"
progress = 0.0
explabel = ""
expstate = ""
if self.message == "" and expstate != "":
message = expstate
if self.is_exposure_sequence:
message = (
f"{message} - {self.exposure_sequence_number} of {self.exposure_sequence_total}"
)
else:
message = self.message
# debug
if 0:
self.pgress += 5.0
if self.pgress > 100:
self.pgress = 0
progress = self.pgress
response = {
"message": message,
"exposurelabel": explabel,
"exposurecolor": expcolor,
"exposurestate": expstate,
"progressbar": progress,
"camtemp": camtemp,
"dewtemp": dewtemp,
"filename": filename,
"seqcount": seqcount,
"seqtotal": seqtotal,
"timestamp": self._timestamp(0),
"imagetitle": self.get_image_title(),
"imagetype": self.get_image_type(),
"imagetest": self.test_image,
"exposuretime": self.get_exposuretime(),
"colbin": self.image.focalplane.col_bin,
"rowbin": self.image.focalplane.row_bin,
"systemname": azcam.db.systemname,
"mode": azcam.db.servermode,
}
return response
def _timestamp(self, precision=0):
"""
Return a timestamp string.
precision is number of fractional seconds.
"""
dateTimeObj = datetime.datetime.now()
timestamp = str(dateTimeObj)
if precision >= 6:
pass
elif precision == 0:
timestamp = timestamp[:-7]
else:
tosecs = timestamp[:-7]
frac = str(round(float(timestamp[-7:]), precision))
timestamp = tosecs + frac
return timestamp
def read_header_file(self, filename):
"""
Read header template file.
"""
return azcam.db.headers["system"].read_file(filename)
class Controller(Tools, ObjectHeaderMethods):
"""
Base class for controller tool.
Usually implemented as the "controller" tool.
"""
def __init__(self, tool_id: str = "controller", description: str or None = None):
"""
Args:
tool_id: tool name
description: description of this tool
"""
Tools.__init__(self, tool_id, description)
#: interface type (0 = demo, 4 = PCIe)
self.interface_type = 0
# create the controller Header object
self.header = Header("Controller")
self.header.set_header("controller", 2)
#: exposure time (secs)
self.exposure_time = 0
self.detpars = DetPars()
#: True if the controller has been reset
self.reset_flag = 0
azcam.db.tools_init["controller"] = self
azcam.db.tools_reset["controller"] = self
def set_roi(self):
"""
Sets ROI parameters values in the controller based on focalplane parameters.
"""
return
def set_shutter_state(self, flag: bool = 0):
"""
Sets the shutter state during an exposure.
Args:
flag: True open shutter during exposure, False close shutter during exposure
"""
return
def set_shutter(self, state: bool, shutter_id: int = 0):
"""
Open or close controller shutter.
Args:
state: True to open shutter, False to close shutter
shutter_id: shutter ID number
"""
return
def flush(self, cycles=1):
"""
Flush or clear out the sensor.
Returns after clearing is finished, which could take many seconds.
Args:
cycles: number of times to flush sensor
"""
return
def start_idle(self):
"""
Start idle clocking.
"""
return
def stop_idle(self):
"""
Stop idle clocking.
"""
return
class Instrument(Tools, ObjectHeaderMethods):
"""
The base instrument tool.
Usually implemented as the "instrument" tool.
"""
def __init__(self, tool_id="instrument", description=None):
Tools.__init__(self, tool_id, description)
# active comparisons
self.active_comps = []
# True if shutter controls comps
self.shutter_strobe = 0
# focus position
self.focus_position = 0
# system pressures
self.pressure_ids = [0]
# system currents
self.current_ids = [0]
azcam.db.tools_init["instrument"] = self
azcam.db.tools_reset["instrument"] = self
# instrument header object
self.header = Header("Instrument")
self.header.set_header("instrument", 3)
return
# ***************************************************************************
# exposure
# ***************************************************************************
def exposure_start(self):
"""
Optional call before exposure starts.
"""
return
def exposure_finish(self):
"""
Optional tempcon.call after exposure finishes.
"""
return
# ***************************************************************************
# comparisons
# ***************************************************************************
def get_all_comps(self):
"""
Return all valid comparison names.
Useful for clients to determine which type of comparison exposures are supported.
"""
raise NotImplementedError
def get_comps(self):
"""
Return a list of the active comparison lamps.
"""
return self.active_comps
def set_comps(self, comp_names: List[str] = None):
"""
Set comparisons to be turned on and off with comps_on() and comps_off().
Args:
comp_names: list of string (or a single string) of comparison names
"""
if type(comp_names) == str:
comp_names = comp_names.split(" ")
self.active_comps = comp_names
return
def comps_on(self):
"""
Turn on active comparisons.
"""
return
def comps_off(self):
"""
Turn off active comparisons.
"""
return
def comps_delay(self, delay_time=0):
"""
Delays for delay_time for comparison lamp warmup.
May internally set delay based on comp selection.
Args:
delay_time: delay in seconds
"""
time.sleep(delay_time)
return
# ***************************************************************************
# filters
# ***************************************************************************
def get_filters(self, filter_id=0):
"""
Return a list of all available/loaded filters.
Args:
filter_id: filter mechanism ID
"""
raise NotImplementedError
def get_filter(self, filter_id=0):
"""
Return the current/loaded filter, typically the filter in the beam.
Args:
filter_id: filter mechanism ID
"""
raise NotImplementedError
def set_filter(self, filter_name, filter_id=0):
"""
Set the current/loaded filter, typically the filter in the beam.
Args:
filter_name: filter name to set. Could be a number or filter name.
filter_id: filter mechanism ID
"""
raise NotImplementedError
# ***************************************************************************
# wavelengths
# ***************************************************************************
def get_wavelengths(self, wavelength_id: int = 0):
"""
Returns a list of valid wavelengths.
Used for filter and LED based systems.
Args:
wavelength_id: wavelength mechanism ID
"""
raise NotImplementedError
def get_wavelength(self, wavelength_id: int = 0):
"""
Returns the current wavelength.
Args:
wavelength_id: wavelength mechanism ID
"""
raise NotImplementedError
def set_wavelength(self, wavelength: Any, wavelength_id: int = 0):
"""
Set the current wavelength, typically for a filter or grating.
Args:
wavelength: wavelength value to set. Could be a number or filter name.
wavelength_id: wavelength mechanism ID
"""
raise NotImplementedError
# ***************************************************************************
# focus
# ***************************************************************************
def get_focus(self, focus_id=0):
"""
Return the current instrument focus position.
focus_id is the focus mechanism ID.
"""
raise NotImplementedError("get_focus")
def set_focus(self, focus_position, focus_id=0, focus_type="absolute"):
"""
Move (or step) the instrument focus.
focus_position is the focus position or step size.
focus_id is the focus mechanism ID.
focus_type is "absolute" or "step".
"""
raise NotImplementedError("set_focus")
# ***************************************************************************
# pressure
# ***************************************************************************
def get_pressures(self):
"""
Return a list of all instrument pressures.
"""
pressures = []
for pressure_id in self.pressure_ids:
p = self.get_pressure(pressure_id)
pressures.append(p)
return pressures
def get_pressure(self, pressure_id=0):
"""
Read an instrument pressure.
"""
raise NotImplementedError
def set_pressure(self, pressure, pressure_id=0):
"""
Sets an instrument pressure.
"""
raise NotImplementedError
# ***************************************************************************
# shutter
# ***************************************************************************
def set_shutter(self, state, shutter_id=0):
"""
Open or close the instrument shutter.
state is 1 for open and 0 for close.
shutter_id is the shutter mechanism ID.
"""
raise NotImplementedError
# ***************************************************************************
# power meter
# ***************************************************************************
def get_power(self, wavelength: float, power_id: int = 0) -> float:
"""
Returns power meter reading.
Args:
wavelength: wavelength for power meter
power_id: power ID flag
Returns:
mean_power: mean power in Watts/cm2
"""
raise NotImplementedError
# ***************************************************************************
# electrometer
# ***************************************************************************
def get_currents(self):
"""
Return a list of all instrument currents.
"""
currents = []
for current_id in self.current_ids:
p = self.get_current(current_id)
currents.append(p)
return currents
def get_current(self, shutter_state: int = 1, current_id: int = 0) -> float:
"""
Read instrument current, usually from an electrometer.
Args:
current_id: current source ID
shutter_state: shutter state during read
Returns:
current: measured current in amps
"""
raise NotImplementedError