def calibrate(self): self.calc_min_max_guess() if len(self.flt_meas) < 10: logging.warning("Not enough measurements") return cp0, np0 = calibration_utils.scale_measurements(self.flt_meas, self.p0) logging.info("initial guess : avg "+str(np0.mean())+" std "+str(np0.std())) calibration_utils.print_xml(self.p0, "MAG", 11) def err_func(p, meas, y): cp, np = calibration_utils.scale_measurements(meas, p) err = y * scipy.ones(len(meas)) - np return err p1, cov, info, msg, success = optimize.leastsq(err_func, self.p0[:], args=(self.flt_meas, 1.0), full_output=1) self.optimization_done = success in [1, 2, 3, 4] if not self.optimization_done: logging.warning("Optimization error: ", msg) cp1, np1 = calibration_utils.scale_measurements(self.flt_meas, p1) if self.optimization_done: logging.info("optimized guess : avg " + str(np1.mean()) + " std " + str(np1.std())) calibration_utils.print_xml(p1, "MAG", 11) else: logging.info("last iteration of failed optimized guess : avg " + str(np1.mean()) + " std " + str(np1.std())) if self.plot_results: calibration_utils.plot_results("MAG", np.array(self.data), range(len(self.data)), self.flt_meas, cp0, np0, cp1, np1, 1.0, blocking=False) calibration_utils.plot_mag_3d(self.flt_meas, cp1, p1)
def main(): usage = "usage: %prog [options] log_filename.data" + "\n" + "Run %prog --help to list the options." parser = OptionParser(usage) parser.add_option("-i", "--id", dest="ac_id", action="store", help="aircraft id to use") parser.add_option("-s", "--sensor", dest="sensor", type="choice", choices=["ACCEL", "MAG"], help="sensor to calibrate (ACCEL, MAG)", action="store", default="ACCEL") parser.add_option("-p", "--plot", help="Show resulting plots", action="store_true", dest="plot") parser.add_option("--noise_threshold", help="specify noise threshold instead of automatically determining it", action="store", dest="noise_threshold", default=0) parser.add_option("-v", "--verbose", action="store_true", dest="verbose") (options, args) = parser.parse_args() if len(args) != 1: parser.error("incorrect number of arguments") else: if os.path.isfile(args[0]): filename = args[0] else: print(args[0] + " not found") sys.exit(1) if not filename.endswith(".data"): parser.error("Please specify a *.data log file") if os.path.getsize(filename) == 0: print("File specified has no data.") sys.exit(1) ac_ids = calibration_utils.get_ids_in_log(filename) if options.ac_id is None: if len(ac_ids) == 1: options.ac_id = ac_ids[0] else: parser.error("More than one aircraft id found in log file. Specify the id to use.") if options.verbose: print("Using aircraft id "+options.ac_id) if options.sensor == "ACCEL": sensor_ref = 9.81 sensor_res = 10 noise_window = 20 noise_threshold = options.noise_threshold elif options.sensor == "MAG": sensor_ref = 1. sensor_res = 11 noise_window = 10 noise_threshold = 1000 if options.verbose: print("reading file "+filename+" for aircraft "+options.ac_id+" and sensor "+options.sensor) # read raw measurements from log file measurements = calibration_utils.read_log(options.ac_id, filename, options.sensor) if len(measurements) == 0: print("Error: found zero IMU_"+options.sensor+"_RAW measurements for aircraft with id "+options.ac_id+" in log file!") sys.exit(1) if options.verbose: print("found "+str(len(measurements))+" records") # check that values are not all zero if not measurements.any(): print("Error: all IMU_"+options.sensor+"_RAW measurements are zero!") sys.exit(1) # estimate the noise threshold if not explicitly given if noise_threshold <= 0: # mean over all measurements (flattended array) as approx neutral value neutral = scipy.mean(measurements) # find the median of measurement vector length after subtracting approximate neutral meas_median = scipy.median(scipy.array([scipy.linalg.norm(v - neutral) for v in measurements])) # set noise threshold to be below 10% of that noise_threshold = meas_median * 0.1 if options.verbose: print("Using noise threshold of", noise_threshold, "for filtering.") # filter out noisy measurements flt_meas, flt_idx = calibration_utils.filter_meas(measurements, noise_window, noise_threshold) if options.verbose: print("remaining "+str(len(flt_meas))+" after filtering") if len(flt_meas) == 0: print("Error: found zero IMU_" + options.sensor + "_RAW measurements for aircraft with id " + options.ac_id + " in log file after filtering with noise threshold of " + noise_threshold + "!\nMaybe try specifying manually with the --noise_threshold option.") if options.plot: calibration_utils.plot_measurements(options.sensor, measurements) sys.exit(1) # get an initial min/max guess p0 = calibration_utils.get_min_max_guess(flt_meas, sensor_ref) cp0, np0 = calibration_utils.scale_measurements(flt_meas, p0) print("initial guess : avg "+str(np0.mean())+" std "+str(np0.std())) # print p0 def err_func(p, meas, y): cp, np = calibration_utils.scale_measurements(meas, p) err = y*scipy.ones(len(meas)) - np return err p1, cov, info, msg, success = optimize.leastsq(err_func, p0[:], args=(flt_meas, sensor_ref), full_output=1) optimze_failed = success not in [1, 2, 3, 4] if optimze_failed: print("Optimization error: ", msg) print("Please try to provide a clean logfile with proper distribution of measurements.") #sys.exit(1) cp1, np1 = calibration_utils.scale_measurements(flt_meas, p1) if optimze_failed: print("last iteration of failed optimized guess : avg "+str(np1.mean())+" std "+str(np1.std())) else: print("optimized guess : avg "+str(np1.mean())+" std "+str(np1.std())) if not optimze_failed: calibration_utils.print_xml(p1, options.sensor, sensor_res) if options.plot: # if we are calibrating a mag, just draw first plot (non-blocking), then show the second if options.sensor == "MAG": calibration_utils.plot_results(options.sensor, measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref, blocking=False) calibration_utils.plot_mag_3d(flt_meas, cp1, p1) # otherwise show the first plot (blocking) else: calibration_utils.plot_results(options.sensor, measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref)
def main(): usage = "usage: %prog [options] log_filename.data" + "\n" + "Run %prog --help to list the options." parser = OptionParser(usage) parser.add_option("-i", "--id", dest="ac_id", action="store", help="aircraft id to use") parser.add_option("-s", "--sensor", dest="sensor", type="choice", choices=["ACCEL", "MAG"], help="sensor to calibrate (ACCEL, MAG)", action="store", default="ACCEL") parser.add_option("-p", "--plot", help="Show resulting plots", action="store_true", dest="plot") parser.add_option("-a", "--auto_threshold", help="Try to automatically determine noise threshold", action="store_true", dest="auto_threshold") parser.add_option("-v", "--verbose", action="store_true", dest="verbose") (options, args) = parser.parse_args() if len(args) != 1: parser.error("incorrect number of arguments") else: if os.path.isfile(args[0]): filename = args[0] else: print(args[0] + " not found") sys.exit(1) ac_ids = calibration_utils.get_ids_in_log(filename) if options.ac_id == None: if len(ac_ids) == 1: options.ac_id = ac_ids[0] else: parser.error("More than one aircraft id found in log file. Specify the id to use.") if options.verbose: print("Using aircraft id "+options.ac_id) if options.sensor == "ACCEL": sensor_ref = 9.81 sensor_res = 10 noise_window = 20; noise_threshold = 40; elif options.sensor == "MAG": sensor_ref = 1. sensor_res = 11 noise_window = 10; noise_threshold = 1000; if not filename.endswith(".data"): parser.error("Please specify a *.data log file") if options.verbose: print("reading file "+filename+" for aircraft "+options.ac_id+" and sensor "+options.sensor) # read raw measurements from log file measurements = calibration_utils.read_log(options.ac_id, filename, options.sensor) if len(measurements) == 0: print("Error: found zero IMU_"+options.sensor+"_RAW measurements for aircraft with id "+options.ac_id+" in log file!") sys.exit(1) if options.verbose: print("found "+str(len(measurements))+" records") # estimate the noise threshold # find the median of measurement vector lenght if options.auto_threshold: meas_median = scipy.median(scipy.array([scipy.linalg.norm(v) for v in measurements])) # set noise threshold to be below 10% of that noise_threshold = meas_median * 0.1 if options.verbose: print("Using noise threshold of", noise_threshold, "for filtering.") # filter out noisy measurements flt_meas, flt_idx = calibration_utils.filter_meas(measurements, noise_window, noise_threshold) if options.verbose: print("remaining "+str(len(flt_meas))+" after filtering") if len(flt_meas) == 0: print("Error: found zero IMU_"+options.sensor+"_RAW measurements for aircraft with id "+options.ac_id+" in log file after filtering!") sys.exit(1) # get an initial min/max guess p0 = calibration_utils.get_min_max_guess(flt_meas, sensor_ref) cp0, np0 = calibration_utils.scale_measurements(flt_meas, p0) print("initial guess : avg "+str(np0.mean())+" std "+str(np0.std())) # print p0 def err_func(p, meas, y): cp, np = calibration_utils.scale_measurements(meas, p) err = y*scipy.ones(len(meas)) - np return err p1, success = optimize.leastsq(err_func, p0[:], args=(flt_meas, sensor_ref)) cp1, np1 = calibration_utils.scale_measurements(flt_meas, p1) print("optimized guess : avg "+str(np1.mean())+" std "+str(np1.std())) # print p1 calibration_utils.print_xml(p1, options.sensor, sensor_res) print("") if options.plot: # if we are calibrating a mag, just draw first plot (non-blocking), then show the second if options.sensor == "MAG": calibration_utils.plot_results(False, measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref) calibration_utils.plot_mag_3d(flt_meas, cp1, p1) # otherwise show the first plot (blocking) else: calibration_utils.plot_results(True, measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref)
def main(): usage = "usage: %prog [options] log_filename.data" + "\n" + "Run %prog --help to list the options." parser = OptionParser(usage) parser.add_option("-i", "--id", dest="ac_id", action="store", help="aircraft id to use") parser.add_option("-s", "--sensor", dest="sensor", type="choice", choices=["ACCEL", "MAG"], help="sensor to calibrate (ACCEL, MAG)", action="store", default="ACCEL") parser.add_option("-p", "--plot", help="Show resulting plots", action="store_true", dest="plot") parser.add_option("-v", "--verbose", action="store_true", dest="verbose") (options, args) = parser.parse_args() if len(args) != 1: parser.error("incorrect number of arguments") else: if os.path.isfile(args[0]): filename = args[0] else: print(args[0] + " not found") sys.exit(1) ac_ids = calibration_utils.get_ids_in_log(filename) if options.ac_id == None: if len(ac_ids) == 1: options.ac_id = ac_ids[0] else: parser.error( "More than one aircraft id found in log file. Specify the id to use." ) if options.verbose: print("Using aircraft id " + options.ac_id) if options.sensor == "ACCEL": sensor_ref = 9.81 sensor_res = 10 noise_window = 20 noise_threshold = 40 elif options.sensor == "MAG": sensor_ref = 1. sensor_res = 11 noise_window = 10 noise_threshold = 1000 if not filename.endswith(".data"): parser.error("Please specify a *.data log file") if options.verbose: print("reading file " + filename + " for aircraft " + options.ac_id + " and sensor " + options.sensor) # read raw measurements from log file measurements = calibration_utils.read_log(options.ac_id, filename, options.sensor) if len(measurements) == 0: print("Error: found zero IMU_" + options.sensor + "_RAW measurements for aircraft with id " + options.ac_id + " in log file!") sys.exit(1) if options.verbose: print("found " + str(len(measurements)) + " records") # filter out noisy measurements flt_meas, flt_idx = calibration_utils.filter_meas(measurements, noise_window, noise_threshold) if options.verbose: print("remaining " + str(len(flt_meas)) + " after low pass") if len(flt_meas) == 0: print("Error: found zero IMU_" + options.sensor + "_RAW measurements for aircraft with id " + options.ac_id + " in log file after low pass!") sys.exit(1) # get an initial min/max guess p0 = calibration_utils.get_min_max_guess(flt_meas, sensor_ref) cp0, np0 = calibration_utils.scale_measurements(flt_meas, p0) print("initial guess : avg " + str(np0.mean()) + " std " + str(np0.std())) # print p0 def err_func(p, meas, y): cp, np = calibration_utils.scale_measurements(meas, p) err = y * scipy.ones(len(meas)) - np return err p1, success = optimize.leastsq(err_func, p0[:], args=(flt_meas, sensor_ref)) cp1, np1 = calibration_utils.scale_measurements(flt_meas, p1) print("optimized guess : avg " + str(np1.mean()) + " std " + str(np1.std())) # print p1 calibration_utils.print_xml(p1, options.sensor, sensor_res) print("") if options.plot: # if we are calibrating a mag, just draw first plot (non-blocking), then show the second if options.sensor == "MAG": calibration_utils.plot_results(False, measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref) calibration_utils.plot_mag_3d(flt_meas, cp1, p1) # otherwise show the first plot (blocking) else: calibration_utils.plot_results(True, measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref)
def main(): usage = "usage: %prog [options] log_filename" parser = OptionParser(usage) parser.add_option("-i", "--id", dest="ac_id", action="store", help="aircraft id to use") parser.add_option("-s", "--sensor", dest="sensor", help="sensor to calibrate ( ACCEL or MAG)", action="store", default="ACCEL") parser.add_option("-v", "--verbose", action="store_true", dest="verbose") (options, args) = parser.parse_args() if len(args) != 1: parser.error("incorrect number of arguments") else: if os.path.isfile(args[0]): filename = args[0] else: print args[0] + " not found" sys.exit(1) if options.sensor == "GYRO": print "You can't calibate gyros with this!" sys.exit(1) ac_ids = calibration_utils.get_ids_in_log(filename) # import code; code.interact(local=locals()) if options.ac_id == None and len(ac_ids) == 1: options.ac_id = ac_ids[0] if options.verbose: print "reading file "+filename+" for aircraft "+options.ac_id+" and sensor "+options.sensor measurements = calibration_utils.read_log(options.ac_id, filename, options.sensor) if options.verbose: print "found "+str(len(measurements))+" records" if options.sensor == "ACCEL": sensor_ref = 9.81 sensor_res = 10 noise_window = 20; noise_threshold = 40; else: # MAG sensor_ref = 1. sensor_res = 11 noise_window = 10; noise_threshold = 1000; flt_meas, flt_idx = calibration_utils.filter_meas(measurements, noise_window, noise_threshold) if options.verbose: print "remaining "+str(len(flt_meas))+" after low pass" p0 = calibration_utils.get_min_max_guess(flt_meas, sensor_ref) cp0, np0 = calibration_utils.scale_measurements(flt_meas, p0) print "initial guess : avg "+str(np0.mean())+" std "+str(np0.std()) # print p0 def err_func(p,meas,y): cp, np = calibration_utils.scale_measurements(meas, p) err = y*scipy.ones(len(meas)) - np return err p1, success = optimize.leastsq(err_func, p0[:], args=(flt_meas, sensor_ref)) cp1, np1 = calibration_utils.scale_measurements(flt_meas, p1) print "optimized guess : avg "+str(np1.mean())+" std "+str(np1.std()) # print p1 calibration_utils.print_xml(p1, options.sensor, sensor_res) print "" calibration_utils.plot_results(measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref)
def main(): usage = "usage: %prog [options] log_filename" parser = OptionParser(usage) parser.add_option("-i", "--id", dest="ac_id", action="store", help="aircraft id to use") parser.add_option("-s", "--sensor", dest="sensor", help="sensor to calibrate ( ACCEL or MAG)", action="store", default="ACCEL") parser.add_option("-v", "--verbose", action="store_true", dest="verbose") (options, args) = parser.parse_args() if len(args) != 1: parser.error("incorrect number of arguments") else: if os.path.isfile(args[0]): filename = args[0] else: print args[0] + " not found" sys.exit(1) ac_ids = calibration_utils.get_ids_in_log(filename) # import code; code.interact(local=locals()) if options.ac_id == None and len(ac_ids) == 1: options.ac_id = ac_ids[0] if options.verbose: print "reading file " + filename + " for aircraft " + options.ac_id + " and sensor " + options.sensor measurements = calibration_utils.read_log(options.ac_id, filename, options.sensor) if options.verbose: print "found " + str(len(measurements)) + " records" if options.sensor == "ACCEL": sensor_ref = 9.81 sensor_res = 10 noise_window = 20 noise_threshold = 40 else: # MAG sensor_ref = 1. sensor_res = 11 noise_window = 10 noise_threshold = 1000 flt_meas, flt_idx = calibration_utils.filter_meas(measurements, noise_window, noise_threshold) if options.verbose: print "remaining " + str(len(flt_meas)) + " after low pass" p0 = calibration_utils.get_min_max_guess(flt_meas, sensor_ref) cp0, np0 = calibration_utils.scale_measurements(flt_meas, p0) print "initial guess : avg " + str(np0.mean()) + " std " + str(np0.std()) # print p0 def err_func(p, meas, y): cp, np = calibration_utils.scale_measurements(meas, p) err = y * scipy.ones(len(meas)) - np return err p1, success = optimize.leastsq(err_func, p0[:], args=(flt_meas, sensor_ref)) cp1, np1 = calibration_utils.scale_measurements(flt_meas, p1) print "optimized guess : avg " + str(np1.mean()) + " std " + str(np1.std()) # print p1 calibration_utils.print_xml(p1, options.sensor, sensor_res) print "" calibration_utils.plot_results(measurements, flt_idx, flt_meas, cp0, np0, cp1, np1, sensor_ref)