mirror of https://github.com/ArduPilot/ardupilot
164 lines
6.5 KiB
Python
164 lines
6.5 KiB
Python
# AP_FLAKE8_CLEAN
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import collections
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import DataflashLog
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from LogAnalyzer import Test, TestResult
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from VehicleType import VehicleType
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class TestPitchRollCoupling(Test):
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'''test for divergence between input and output pitch/roll, i.e. mechanical failure or bad PID tuning'''
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# TODO: currently we're only checking for roll/pitch outside of max lean angle, will come back later to analyze
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# roll/pitch in versus out values
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def __init__(self):
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Test.__init__(self)
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self.name = "Pitch/Roll"
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def run(self, logdata, verbose):
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self.result = TestResult()
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self.result.status = TestResult.StatusType.GOOD
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if logdata.vehicleType != VehicleType.Copter:
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self.result.status = TestResult.StatusType.NA
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return
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if "ATT" not in logdata.channels:
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self.result.status = TestResult.StatusType.UNKNOWN
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self.result.statusMessage = "No ATT log data"
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return
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if "CTUN" not in logdata.channels:
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self.result.status = TestResult.StatusType.UNKNOWN
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self.result.statusMessage = "No CTUN log data"
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return
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if "BarAlt" in logdata.channels['CTUN']:
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self.ctun_baralt_att = 'BarAlt'
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else:
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self.ctun_baralt_att = 'BAlt'
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# figure out where each mode begins and ends, so we can treat auto and manual modes differently and ignore
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# acro/tune modes
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autoModes = [
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"RTL",
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"AUTO",
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"LAND",
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"LOITER",
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"GUIDED",
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"CIRCLE",
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"OF_LOITER",
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"POSHOLD",
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"BRAKE",
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"AVOID_ADSB",
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"GUIDED_NOGPS",
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"SMARTRTL",
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]
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# use CTUN RollIn/DesRoll + PitchIn/DesPitch
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manualModes = ["STABILIZE", "DRIFT", "ALTHOLD", "ALT_HOLD", "POSHOLD"]
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# ignore data from these modes:
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ignoreModes = [
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"ACRO",
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"SPORT",
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"FLIP",
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"AUTOTUNE",
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"",
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"THROW",
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]
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autoSegments = [] # list of (startLine,endLine) pairs
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manualSegments = [] # list of (startLine,endLine) pairs
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orderedModes = collections.OrderedDict(sorted(logdata.modeChanges.items(), key=lambda t: t[0]))
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isAuto = False # we always start in a manual control mode
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prevLine = 0
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mode = ""
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for line, modepair in orderedModes.items():
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mode = modepair[0].upper()
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if prevLine == 0:
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prevLine = line
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if mode in autoModes:
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if not isAuto:
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manualSegments.append((prevLine, line - 1))
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prevLine = line
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isAuto = True
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elif mode in manualModes:
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if isAuto:
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autoSegments.append((prevLine, line - 1))
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prevLine = line
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isAuto = False
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elif mode in ignoreModes:
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if isAuto:
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autoSegments.append((prevLine, line - 1))
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else:
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manualSegments.append((prevLine, line - 1))
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prevLine = 0
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else:
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raise Exception("Unknown mode in TestPitchRollCoupling: %s" % mode)
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# and handle the last segment, which doesn't have an ending
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if mode in autoModes:
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autoSegments.append((prevLine, logdata.lineCount))
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elif mode in manualModes:
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manualSegments.append((prevLine, logdata.lineCount))
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# figure out max lean angle, the ANGLE_MAX param was added in AC3.1
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maxLeanAngle = 45.0
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if "ANGLE_MAX" in logdata.parameters:
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maxLeanAngle = logdata.parameters["ANGLE_MAX"] / 100.0
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maxLeanAngleBuffer = 10 # allow a buffer margin
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# ignore anything below this altitude, to discard any data while not flying
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minAltThreshold = 2.0
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# look through manual+auto flight segments
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# TODO: filter to ignore single points outside range?
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(maxRoll, maxRollLine) = (0.0, 0)
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(maxPitch, maxPitchLine) = (0.0, 0)
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for (startLine, endLine) in manualSegments + autoSegments:
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# quick up-front test, only fallover into more complex line-by-line check if max()>threshold
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rollSeg = logdata.channels["ATT"]["Roll"].getSegment(startLine, endLine)
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pitchSeg = logdata.channels["ATT"]["Pitch"].getSegment(startLine, endLine)
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if not rollSeg.dictData and not pitchSeg.dictData:
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continue
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# check max roll+pitch for any time where relative altitude is above minAltThreshold
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roll = max(abs(rollSeg.min()), abs(rollSeg.max()))
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pitch = max(abs(pitchSeg.min()), abs(pitchSeg.max()))
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if (roll > (maxLeanAngle + maxLeanAngleBuffer) and abs(roll) > abs(maxRoll)) or (
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pitch > (maxLeanAngle + maxLeanAngleBuffer) and abs(pitch) > abs(maxPitch)
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):
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lit = DataflashLog.LogIterator(logdata, startLine)
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assert lit.currentLine == startLine
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while lit.currentLine <= endLine:
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relativeAlt = lit["CTUN"][self.ctun_baralt_att]
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if relativeAlt > minAltThreshold:
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roll = lit["ATT"]["Roll"]
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pitch = lit["ATT"]["Pitch"]
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if abs(roll) > (maxLeanAngle + maxLeanAngleBuffer) and abs(roll) > abs(maxRoll):
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maxRoll = roll
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maxRollLine = lit.currentLine
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if abs(pitch) > (maxLeanAngle + maxLeanAngleBuffer) and abs(pitch) > abs(maxPitch):
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maxPitch = pitch
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maxPitchLine = lit.currentLine
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next(lit)
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# check for breaking max lean angles
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if maxRoll and abs(maxRoll) > abs(maxPitch):
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self.result.status = TestResult.StatusType.FAIL
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self.result.statusMessage = "Roll (%.2f, line %d) > maximum lean angle (%.2f)" % (
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maxRoll,
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maxRollLine,
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maxLeanAngle,
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)
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return
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if maxPitch:
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self.result.status = TestResult.StatusType.FAIL
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self.result.statusMessage = "Pitch (%.2f, line %d) > maximum lean angle (%.2f)" % (
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maxPitch,
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maxPitchLine,
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maxLeanAngle,
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)
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return
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# TODO: use numpy/scipy to check Roll+RollIn curves for fitness (ignore where we're not airborne)
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# ...
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