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raddoseLib.py
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raddoseLib.py
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# RD3D_calc Raddose3D interface
import subprocess
import numpy as np
from numpy.lib import recfunctions as rfn # needs to be imported separately
from shutil import copyfile
import fileinput
import sys
import os.path
import os
import logging
logger = logging.getLogger(__name__)
#12/19 - See Martin about this code!
def replaceLine(file,searchExp,replaceExp):
for line in fileinput.input(file, inplace=1):
if searchExp in line:
line = replaceExp
sys.stdout.write(line)
def run_rd3d(inputFileName):
prc = subprocess.Popen(["java", "-jar", os.environ['CONFIGDIR'] + "/raddose3d.jar", "-i", inputFileName, "-p", "rd3d/rd3d_"],
stdout=subprocess.PIPE,
universal_newlines=True)
out = prc.communicate()[0]
return out
def rd3d_calc(flux=3.5e12, energy=12.66,
beamType='GAUSSIAN', fwhmX=2, fwhmY=1, collimationX=10, collimationY=10,
wedge=0, exposureTime=1,
translatePerDegX=0, translatePerDegY=0, translatePerDegZ=0,
startOffsetX=0, startOffsetY=0, startOffsetZ=0,
dimX=20, dimY=20, dimZ=20,
pixelsPerMicron=2, angularResolution=2,
templateFileName = os.environ["CONFIGDIR"] + '/rd3d_input_template.txt',
verbose=True,
):
"""
RADDOSE3D dose estimate
This version calculates dose values for an average protein crystal.
The estimates need to be adjusted proportionally for a crystal if it is more/less sensitive.
All paramaters listed below can be set. If they are not set explicitly, RADDOSE3D will use
the listed default value.
A complete manual with explanations is available at
https://github.com/GarmanGroup/RADDOSE-3D/blob/master/doc/user-guide.pdf
Photon flux [ph/s]: flux=3.5e12
Photon energy [keV]: energy=12.66,
Beamtype (GAUSSIAN | TOPHAT): beamType='GAUSSIAN'
Vertical beamsize FHWM [um]: fwhmX=1
Horizontal beamsize FHWM [um]: fwhmY=2
Vertical collimation (for TOPHAT beams this is the size) [um]: collimationX=10
Horizontal collimation (for TOPHAT beams this is the size) [um]: collimationY=10
Omega range [deg]: wedge=0
Exposure time for the complete wedge [s]: exposureTime=1
Translation per degree V [um]: translatePerDegX=0
Translation per degree H [um]: translatePerDegY=0
Translation along beam per degree [um]: translatePerDegZ=0
Crystal position offset V [um]: startOffsetX=0
Crystal position offset H [um]: startOffsetY=0
Crystal position offset along beam [um]: startOffsetZ=0
Crystal dimension V [um]: dimX=20
Crystal dimension H [um]: dimY=20
Crystal dimension along beam [um]: dimZ=20
Pixels per micron: pixelsPerMicron=2
Angular resolution: angularResolution=2
Template file (in 'rd3d' subdir of active notebook): templateFileName = 'rd3d_input_template.txt'
Return value is a structured numpy array. You can use it for follow-up calculations
of the results returned by RADDOSE3D in "output-Summary.csv". Call the return variable
to find the field names.
Examples:
rd3d_out = rd3d_calc(flux=1.35e12, exposuretime=0.01, dimx=1, dimy=1, dimz=1)
rd3d_calc(flux=1e12, energy=12.7, fwhmX=3, fwhmY=5, collimationX=9, collimationY=15, wedge=180,
exposureTime=8, translatePerDegX=0, translatePerDegY=0.27, startOffsetY=-25,
dimX=3, dimY=80, dimZ=3, pixelsPerMicron=0.5, angularResolution=2, verbose=False)
Setup:
* rd3d_input_template.txt and raddose.jar in subdir rd3d/
* PDB file 2vb1.pdb in notebook dir
2vb1.pdb
rd3d/raddose.jar
rd3d/rd3d_input_template.txt
Todo:
* Cannot call PDB file in subdir or active dir, i.e. only 'PDB 2vb1.pdb' works in rd3d_input_template.txt
* run_rd3d() with subdir option
* Is the subdir really worth it? Use 'raddose' prefix instead? (Tentative: yes)
* If subdir: Clean code (run_rd3d()), subdir name as option, description in help text
(how if it's an option?)
* Keep template file as option? Then it should be in same dir as PDB file (notebook dir)
* Protein option PDB (on xf17id1 cannot reach PDB URL) or JJDUMMY (how to cite?)
"""
rd3d_dir = "rd3d"
inputFileName = "rd3d_input.txt"
outputFileName = "rd3d_Summary.csv"
templateFilePath=os.path.join(rd3d_dir,templateFileName)
inputFilePath=os.path.join(rd3d_dir,inputFileName)
outputFilePath=os.path.join(rd3d_dir,outputFileName)
copyfile(templateFilePath, inputFilePath)
replaceLine(inputFilePath,"FLUX",'FLUX {:.2e}\n'.format(flux))
replaceLine(inputFilePath,"ENERGY",'ENERGY {:.2f}\n'.format(energy))
replaceLine(inputFilePath,"TYPE GAUSSIAN",'TYPE {:s}\n'.format(beamType))
replaceLine(inputFilePath,"FWHM",'FWHM {:.1f} {:.1f}\n'.format(fwhmX,fwhmY))
replaceLine(inputFilePath,"COLLIMATION",'COLLIMATION RECTANGULAR {:.1f} {:.1f}\n'.format(collimationX,collimationY))
replaceLine(inputFilePath,"WEDGE",'WEDGE 0 {:0.1f}\n'.format(wedge))
replaceLine(inputFilePath,"EXPOSURETIME",'EXPOSURETIME {:0.3f}\n'.format(exposureTime))
replaceLine(inputFilePath,"TRANSLATEPERDEGREE",
'TRANSLATEPERDEGREE {:0.4f} {:0.4f} {:0.4f}\n'.format(translatePerDegX,translatePerDegY,translatePerDegZ))
replaceLine(inputFilePath,"DIMENSION",'DIMENSION {:0.1f} {:0.1f} {:0.1f}\n'.format(dimX,dimY,dimZ))
replaceLine(inputFilePath,"PIXELSPERMICRON",'PIXELSPERMICRON {:0.1f}\n'.format(pixelsPerMicron))
replaceLine(inputFilePath,"ANGULARRESOLUTION",'ANGULARRESOLUTION {:0.1f}\n'.format(angularResolution))
replaceLine(inputFilePath,"STARTOFFSET",
'STARTOFFSET {:f} {:f} {:f}\n'.format(startOffsetX,startOffsetY,startOffsetZ))
out = run_rd3d(inputFilePath)
if verbose:
logger.info(out)
rd3d_out = np.genfromtxt(outputFilePath, delimiter=',', names=True)
logger.info("\n=== rd3d_calc summary ===")
# append_fields has issues with 1d arrays, use reshape() and [] to make len() work on size 1 array:
# https://stackoverflow.com/questions/53137822/adding-a-field-to-a-structured-numpy-array-4
rd3d_out = rd3d_out.reshape(1)
logger.info("Diffraction weighted dose = " + "%.3f" % rd3d_out['DWD'] + " MGy")
logger.info("Max dose = " + "%.3f" % rd3d_out['Max_Dose'] + " MGy")
if rd3d_out['DWD']:
t2gl = exposureTime * 30 / rd3d_out['DWD'] # Time to Garman limit based on diffraction weighted dose
else:
t2gl = 0
rd3d_out = rfn.append_fields(rd3d_out,'t2gl',[t2gl],usemask=False)
logger.info("Time to Garman limit = " + "%.3f" % rd3d_out['t2gl'] + " s")
return rd3d_out
# ## Experiment time to reach 10 MGy dose
#
# ### Inputs:
# * Flux: From flux-at-sample PV
# * Beam size: For now, set by hand, or determine from PV, or get from get_beamsize(TBD)
# * Crystal size: Match to beam size
# * Vector length: Start with assumption, LSDC vector length is along X-axis. Update could use the real projections
#
# * Exposure time = 1 s
# * Translation per degree has to match total vector length
#
# * RD3D output = AWD [MGy]
#
# ### Input from LSDC:
# * Protocol standard or vector
# * Beamsize settings
#
# ### Output:
# * Experiment time [s] to Average Diffraction Weighted Dose = 10 MGy
import epics
def fmx_expTime(avg_dwd = 10, #Default of 10MGy
beamsizeV = 1.0, beamsizeH = 2.0,
vectorL = 0,
energy = 12.66,
flux = -1,
wedge = 180,
verbose = False
):
"""
RD3D output = AWD [MGy]
Parameters
----------
beamsizeV, beamsizeH: float
Beam size (V, H) [um]. Default 1x2 (VxH). For now, set explicitly.
vectorL: float
Vector length [um]: Default 0 um. Make assumption that the vector is completely oriented
along X-axis.
energy: float
Photon energy [keV]. Default 12.66 keV
wedge: float
Crystal rotation for complete experiment [deg]. Start at 0, end at wedge
flux: float
Flux at sample position [ph/s]. By default this value is copied from the beamline's
flux-at-sample PV. Can also be set explicitly.
verbose: boolean
True: Print out RADDOSE3D output. Default False
Internal parameters
-------------------
Crystal size XYZ: Match to beam size perpendicular to (XZ), and to vector length along the
rotation axis (Y)
Returns
-------
Experiment time [s] to Average Diffraction Weighted Dose = 10 MGy
Todo
----
* Beamsize: Read from a beamsize PV, or get from a get_beamsize() function
- Check CRL settings
- Check BCU attenuator
- If V1H1 then 10x10 (dep on E)
- If V0H0 then
- If BCU-Attn-T < 1.0 then 3x5
- If BCU-Attn-T = 1.0 then 1x2
* Vector length: Use the real projections
"""
# Beam size [um]
fwhmX = beamsizeV
fwhmY = beamsizeH
collimationX = 3*beamsizeV
collimationY = 3*beamsizeH
# Set explicitly or use current flux
if flux == -1:
# Current flux [ph/s]: From flux-at-sample PV
fluxSample = epics.caget('XF:17IDA-OP:FMX{Mono:DCM-dflux-MA}')
logger.info('Flux at sample = {:.4g} ph/s'.format(fluxSample))
else:
fluxSample = flux
# Crystal size [um]: Match to beam size in V, longer than vector in H
# XYZ as defined by Raddose3D
dimX = beamsizeV # Crystal dimension V [um]
dimY = vectorL + beamsizeH # Crystal dimension H [um]
dimZ = dimX # Crystal dimension along beam [um]
# Start offset for horizontal vector to stay within crystal [um]
startOffsetY = -vectorL / 2
# Exposure time [s]
exposureTime = 1.0
# Avoid division by zero when calculating translatePerDegY
if wedge == 0: wedge = 1e-3
# Vector length [um]: Assume LSDC vector length is along X-axis (Raddose3D Y).
# Translation per degree has to match total vector length
translatePerDegY = vectorL / wedge
try:
rd3d_out = rd3d_calc(flux=fluxSample, energy=energy,
fwhmX=fwhmX, fwhmY=fwhmY,
collimationX=collimationX, collimationY=collimationY,
wedge=wedge,
exposureTime=exposureTime,
translatePerDegY=translatePerDegY,
startOffsetY=startOffsetY,
pixelsPerMicron=5, angularResolution=1,
dimX=dimX, dimY=dimY, dimZ=dimZ,
verbose=verbose
)
logger.info("\n=== fmx_expTime summary ===")
dose1s = rd3d_out['DWD'].item() # .item() to convert 1d array to scalar
logger.info('Average Diffraction Weighted Dose for 1s exposure = {:f} MGy'.format(dose1s))
except Exception as e:
logger.error(f'Exception in rd3d calc: {e}')
dose1s = 0
if dose1s > 0:
expTimeMGy = avg_dwd / dose1s # Experiment time to reach an average DWD (avg_dwd)
else:
expTimeMGy = 0
logger.info(f'Experiment time to reach an average diffraction weighted dose of {avg_dwd} MGy = {expTimeMGy} s')
return expTimeMGy
# Copy of Wuxian's 100 um vector (http://www.raddo.se/rd3d/job.php?u=16843&s=mLl5kFm5oXgRgpnf&id=16915)
#rd3d_calc(flux=1e12, energy=12.7,
# fwhmX=3, fwhmY=5, collimationX=9, collimationY=15,
# wedge=180,
# exposureTime=16,
# translatePerDegX=0, translatePerDegY=0.556,
# startOffsetY=-50,
# dimX=3, dimY=110, dimZ=3,
# pixelsPerMicron=0.5, angularResolution=2,
# )
#fmx_expTime_to_10MGy(beamsizeV = 3.0, beamsizeH = 5.0, vectorL = 50, energy = 12.7, wedge = 180, flux = 1e12)
#fmx_expTime_to_10MGy(beamsizeV = 3.0, beamsizeH = 5.0, vectorL = 100, energy = 12.7, wedge = 180, flux = 1e12, verbose = True)