def check_center(params, white_field, dark_field): global_PVs = aps2bm.init_general_PVs(params) log.warning(' *** CHECK center of mass for the centered sphere') log.info(' *** moving rotary stage to %f deg position ***' % float(0)) global_PVs["Motor_SampleRot"].put(float(0), wait=True, timeout=600.0) log.info(' *** acquire sphere at %f deg position ***' % float(0)) sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) cmass_0 = util.center_of_mass(sphere_0) log.warning( ' *** center of mass for the centered sphere at 0 deg: [%f,%f] ***' % (cmass_0[1], cmass_0[0]))
def adjust_pitch(params, dark_field, white_field, angle_shift): global_PVs = aps2bm.init_general_PVs(params) log.warning(' *** Adjusting pitch ***') log.info( ' *** acquire sphere after moving it along the beam axis by 1mm ***') global_PVs["Motor_Sample_Top_90"].put( global_PVs["Motor_Sample_Top_90"].get() - 1.0, wait=True, timeout=600.0) log.info(' *** moving rotary stage to %f deg position ***' % float(0 + angle_shift)) global_PVs["Motor_SampleRot"].put(float(0 + angle_shift), wait=True, timeout=600.0) log.info(' *** acquire sphere at %f deg position ***' % float(0 + angle_shift)) sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) log.info(' *** moving rotary stage to %f deg position ***' % float(0 + angle_shift)) global_PVs["Motor_SampleRot"].put(float(180 + angle_shift), wait=True, timeout=600.0) log.info(' *** acquire sphere at %f deg position ***' % float(180 + angle_shift)) sphere_180 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) cmass_0 = util.center_of_mass(sphere_0) cmass_180 = util.center_of_mass(sphere_180) log.info(' *** center of mass for the initial sphere (%f,%f) ***' % (cmass_0[1], cmass_0[0])) log.info(' *** center of mass for the shifted sphere (%f,%f) ***' % (cmass_180[1], cmass_180[0])) pitch = np.rad2deg( np.arctan((cmass_180[0] - cmass_0[0]) * params.image_resolution / 1000 / 2.0)) log.warning(' *** found pitch error: %f' % pitch) log.info(' *** acquire sphere back along the beam axis by -1mm ***') global_PVs["Motor_Sample_Top_90"].put( global_PVs["Motor_Sample_Top_90"].get() + 1.0, wait=True, timeout=600.0) log.warning(' *** change pitch to %f ***' % float(global_PVs["Motor_Pitch"].get() - pitch)) global_PVs["Motor_Pitch"].put(global_PVs["Motor_Pitch"].get() - pitch, wait=True, timeout=600.0) global_PVs["Motor_SampleRot"].put(float(0 + angle_shift), wait=True, timeout=600.0) log.info(' *** TEST: acquire sphere at %f deg position ***' % float(0 + angle_shift)) sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) cmass_0 = util.center_of_mass(sphere_0) log.info(' *** TEST: center of mass for the sphere at 0 deg (%f,%f) ***' % (cmass_0[1], cmass_0[0]))
def adjust_roll(params, dark_field, white_field, angle_shift): # angle_shift is the correction that is needed to apply to the rotation axis position # to align the Z stage on top of the rotary stage with the beam global_PVs = aps2bm.init_general_PVs(params) log.warning(' *** Adjusting roll ***') log.info(' *** moving rotary stage to %f deg position ***' % float(0 + angle_shift)) global_PVs["Motor_SampleRot"].put(float(0 + angle_shift), wait=True, timeout=600.0) log.info(' *** moving sphere to the detector border ***') global_PVs["Motor_Sample_Top_0"].put( global_PVs["Motor_Sample_Top_0"].get() + global_PVs['Cam1_SizeX'].get() / 2 * params.image_resolution / 1000 - ((SPHERE_DIAMETER / 2) + GAP), wait=True, timeout=600.0) log.info(' *** acquire sphere at %f deg position ***' % float(0 + angle_shift)) sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) log.info(' *** moving rotary stage to %f deg position ***' % float(180 + angle_shift)) global_PVs["Motor_SampleRot"].put(float(180 + angle_shift), wait=True, timeout=600.0) log.info(' *** acquire sphere at %f deg position ***' % float(180 + angle_shift)) sphere_180 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) cmass_0 = util.center_of_mass(sphere_0) cmass_180 = util.center_of_mass(sphere_180) log.info(' *** center of mass for the sphere at 0 deg (%f,%f) ***' % (cmass_0[1], cmass_0[0])) log.info(' *** center of mass for the sphere at 180 deg (%f,%f) ***' % (cmass_180[1], cmass_180[0])) roll = np.rad2deg( np.arctan((cmass_180[0] - cmass_0[0]) / (cmass_180[1] - cmass_0[1]))) log.warning(' *** found roll error: %f' % roll) log.info(' *** moving rotary stage to %f deg position ***' % float(0 + angle_shift)) global_PVs["Motor_SampleRot"].put(float(0 + angle_shift), wait=True, timeout=600.0) log.info(' *** moving sphere back to the detector center ***') global_PVs["Motor_Sample_Top_0"].put( global_PVs["Motor_Sample_Top_0"].get() - (global_PVs['Cam1_SizeX'].get() / 2 * params.image_resolution / 1000 - ((SPHERE_DIAMETER / 2) + GAP)), wait=True, timeout=600.0) log.info(' *** find shifts resulting by the roll change ***') log.info(' *** acquire sphere at the current roll position ***') sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) ang = roll / 2 # if roll is too big then ang should be decreased to keep the sphere in the field of view log.info(' *** acquire sphere after testing roll change %f ***' % float(global_PVs["Motor_Roll"].get() + ang)) global_PVs["Motor_Roll"].put(global_PVs["Motor_Roll"].get() + ang, wait=True, timeout=600.0) sphere_1 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) shift0 = register_translation(sphere_1, sphere_0, 100)[0][1] shift1 = shift0 * np.sin(roll) * (np.cos(roll) * 1 / np.tan(ang) + np.sin(roll)) log.info( ' *** the testing roll change corresponds to %f shift in x, calculated resulting roll change gives %f shift in x ***' % (shift0, shift1)) log.warning(' *** change roll to %f ***' % float(global_PVs["Motor_Roll"].get() + roll - ang)) global_PVs["Motor_Roll"].put(global_PVs["Motor_Roll"].get() + roll - ang, wait=True, timeout=600.0) log.info(' *** moving sphere to the detector center ***') global_PVs["Motor_SampleX"].put(global_PVs["Motor_SampleX"].get() - shift1 * params.image_resolution / 1000, wait=True, timeout=600.0) log.info(' *** TEST: acquire sphere at %f deg position ***' % float(0 + angle_shift)) sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) cmass_0 = util.center_of_mass(sphere_0) log.info(' *** TEST: center of mass for the sphere at 0 deg (%f,%f) ***' % (cmass_0[1], cmass_0[0]))
def adjust_center(params, dark_field, white_field): global_PVs = aps2bm.init_general_PVs(params) log.warning(' *** Adjusting center ***') for ang in [params.adjust_center_angle_1, params.adjust_center_angle_2]: log.warning(' *** take 3 spheres angular %f deg ***' % float(ang)) #sphere 0 log.info(' *** sphere 0') log.info(' *** *** moving rotary stage to %f deg position ***' % float(0)) global_PVs["Motor_SampleRot"].put(float(0), wait=True, timeout=600.0) log.error(' *** *** acquire sphere at %f deg position ***' % float(0)) sphere_0 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) #sphere 1 log.info(' *** sphere 1') log.info(' *** *** moving rotary stage to %f deg position ***' % float(ang)) global_PVs["Motor_SampleRot"].put(float(ang), wait=True, timeout=600.0) log.error(' *** *** acquire sphere at %f deg position ***' % float(ang)) sphere_1 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) #sphere 2 log.info(' *** sphere 2') log.info(' *** *** moving rotary stage to %f deg position ***' % float(2 * ang)) global_PVs["Motor_SampleRot"].put(float(2 * ang), wait=True, timeout=600.0) log.error(' *** *** acquire sphere at %f deg position ***' % float(2 * ang)) sphere_2 = util.normalize(flir.take_image(global_PVs, params), white_field, dark_field) # find shifts shift0 = register_translation(sphere_1, sphere_0, 100)[0][1] shift1 = register_translation(sphere_2, sphere_1, 100)[0][1] a = ang * np.pi / 180 # x=-(1/4) (d1+d2-2 d1 Cos[a]) Csc[a/2]^2, x = -(1 / 4) * (shift0 + shift1 - 2 * shift0 * np.cos(a)) * 1 / np.sin( a / 2)**2 # r = 1/2 Csc[a/2]^2 Csc[a] Sqrt[(d1^2+d2^2-2 d1 d2 Cos[a]) Sin[a/2]^2] r = 1 / 2 * 1 / np.sin(a / 2)**2 * 1 / np.sin(a) * np.sqrt( np.abs((shift0**2 + shift1**2 - 2 * shift0 * shift1 * np.cos(a)) * np.sin(a / 2)**2)) # g = ArcCos[((-d1-d2+2 d1 Cos[a]) Sin[a])/(2 Sqrt[(d1^2+d2^2-2 d1 d2 Cos[a]) Sin[a/2]^2])] g = np.arccos( ((-shift0 - shift1 + 2 * shift0 * np.cos(a)) * np.sin(a)) / (2 * np.sqrt( np.abs( (shift0**2 + shift1**2 - 2 * shift0 * shift1 * np.cos(a)) * np.sin(a / 2)**2)))) y = r * np.sin(g) * np.sign(shift0) # find center of mass cmass_0 = util.center_of_mass(sphere_0) log.info(' ') log.info( ' *** position of the initial sphere wrt to the rotation center (%f,%f) ***' % (x, y)) log.info(' *** center of mass for the initial sphere (%f,%f) ***' % (cmass_0[1], cmass_0[0])) log.info( ' *** moving sphere to the position of the rotation center ***') if (params.ask): if util.yes_or_no(' *** Yes or No'): move_center(params, cmass_0, x, y) check_center(params, white_field, dark_field) else: log.warning(' No motion ') exit() else: move_center(params, cmass_0, x, y) check_center(params, white_field, dark_field)