TrainRun.jl/src/behavior.jl

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#!/usr/bin/env julia
# -*- coding: UTF-8 -*-
# __author__ = "Max Kannenberg"
# __copyright__ = "2020-2022"
# __license__ = "ISC"
## This function calculates the support points of the breakFree section.
# Therefore it gets its first support point and the characteristic section and returns the characteristic section including the behavior section for breakFree if needed.
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# Info: currently the values of the breakFree section will be calculated like in the accelerating section
function addBreakFreeSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
CS = CSs[csId]
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# conditions for the break free section
endOfCSReached = drivingCourse[end][:s] >= CS[:s_exit] || stateFlags[:endOfCSReached]
trainIsHalting = drivingCourse[end][:v] == 0.0
if trainIsHalting && !endOfCSReached
drivingMode = "breakFree"
drivingCourse[end][:behavior] = drivingMode
startingPoint = length(drivingCourse)
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# traction effort and resisting forces (in N)
calculateForces!(drivingCourse[end], CSs, csId, "accelerating", train, settings.massModel) # currently the tractive effort is calculated like in the accelerating section
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# calculate the breakFree section with calculating the accelerating section and just using the first step and removing the rest
try (drivingCourse, stateFlags) = addAcceleratingSection!(drivingCourse, stateFlags, CSs, csId, settings, train)
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catch(acceleratingError)
println("This error happened during the break free phase that is using the accelerating function:")
rethrow(acceleratingError)
end
# delete every supportPoint except the first two
while length(drivingCourse) > startingPoint +1
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pop!(drivingCourse)
end
# change the accelerating data to break free
drivingCourse[end-1][:behavior] = drivingMode
drivingCourse[end][:behavior] = drivingMode
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end # else: return the characteristic section without a breakFree section
# determine state flags
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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stateFlags[:endOfCSReached] = drivingCourse[end][:s] >= CS[:s_exit]
stateFlags[:brakingStartReached] = drivingCourse[end][:s] +s_braking >= CS[:s_exit]
stateFlags[:tractionDeficit] = drivingCourse[end][:F_T] < drivingCourse[end][:F_R] # or add another flag for equal forces?
stateFlags[:resistingForceNegative] = drivingCourse[end][:F_R] < 0
stateFlags[:previousSpeedLimitReached] = false
stateFlags[:speedLimitReached] = drivingCourse[end][:v] >= CS[:v_limit]
stateFlags[:error] = drivingCourse[end][:v] > CS[:v_limit] || drivingCourse[end][:s] > CS[:s_exit]
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return (drivingCourse, stateFlags)
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end #function addBreakFreeSection!
## This function calculates the support points of the clearing section.
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# Therefore it gets its previous driving course and the characteristic section and returns the characteristic section and driving course including the clearing section.
function addClearingSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
CS = CSs[csId]
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if stateFlags[:previousSpeedLimitReached]
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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s_clearing = min(CS[:s_exit]-drivingCourse[end][:s]-s_braking, lowestSpeedLimit[:s_end] - drivingCourse[end][:s])
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if s_clearing > 0.0
(drivingCourse, stateFlags) = addCruisingSection!(drivingCourse, stateFlags, CSs, csId, settings, train, "clearing", s_clearing)
calculateForces!(drivingCourse[end], CSs, csId, "accelerating", train, settings.massModel)
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else
error("ERROR: clearing <=0.0 although it has to be >0.0 in CS ",csId)
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end
#stateFlags[:previousSpeedLimitReached] = false
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
stateFlags[:previousSpeedLimitReached] = lowestSpeedLimit[:v] != CS[:v_limit] && drivingCourse[end][:v] >= lowestSpeedLimit[:v]
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else
stateFlags[:error] = true
end
return (drivingCourse, stateFlags)
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end #function addClearingSection
## This function calculates the support points of the accelerating section.
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# Therefore it gets its previous driving course and the characteristic section and returns the characteristic section and driving course including the accelerating section
function addAcceleratingSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
CS = CSs[csId]
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calculateForces!(drivingCourse[end], CSs, csId, "accelerating", train, settings.massModel)
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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# conditions for the accelerating section
endOfCSReached = drivingCourse[end][:s] >= CS[:s_exit] || stateFlags[:endOfCSReached]
tractionSurplus = drivingCourse[end][:F_T] > drivingCourse[end][:F_R]
brakingStartReached = drivingCourse[end][:s] +s_braking >= CS[:s_exit] || stateFlags[:brakingStartReached]
previousSpeedLimitReached = stateFlags[:previousSpeedLimitReached]
speedLimitReached = drivingCourse[end][:v] >= CS[:v_limit] || stateFlags[:speedLimitReached]
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# use the conditions for the accelerating section
if !speedLimitReached && !endOfCSReached && tractionSurplus && !brakingStartReached
drivingMode = "accelerating"
drivingCourse[end][:behavior] = drivingMode
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lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
previousSpeedLimitReached = lowestSpeedLimit[:v] != CS[:v_limit] && drivingCourse[end][:v] >= lowestSpeedLimit[:v]
while !speedLimitReached && !endOfCSReached && tractionSurplus && !brakingStartReached && !previousSpeedLimitReached
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currentStepSize = settings.stepSize # initialize the step size that can be reduced near intersections
nextPointOfInterest = getNextPointOfInterest(CS[:pointsOfInterest], drivingCourse[end][:s])
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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for cycle in 1:settings.approxLevel+1 # first cycle with normal step size followed by cycles with reduced step size depending on the level of approximation
while !speedLimitReached && !brakingStartReached && !pointOfInterestReached && tractionSurplus && !previousSpeedLimitReached
if drivingCourse[end][:s] >= lowestSpeedLimit[:s_end]
# could be asked after creating an support point. This way here prevents even a minimal exceedance of speed limit. On the other hand the train cruises possibly a little to long
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
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end
# acceleration (in m/s^2):
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drivingCourse[end][:a] = acceleration(drivingCourse[end][:F_T], drivingCourse[end][:F_R], train.m_train_full, train.ξ_train)
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# create the next support point
push!(drivingCourse, moveAStep(drivingCourse[end], settings.stepVariable, currentStepSize, csId))
drivingCourse[end][:behavior] = drivingMode
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calculateForces!(drivingCourse[end], CSs, csId, drivingMode, train, settings.massModel)
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# conditions for the next while cycle
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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brakingStartReached = drivingCourse[end][:s] +s_braking >= CS[:s_exit]
speedLimitReached = drivingCourse[end][:v] >= CS[:v_limit]
previousSpeedLimitReached = lowestSpeedLimit[:v] < CS[:v_limit] && (drivingCourse[end][:v] > lowestSpeedLimit[:v] || (drivingCourse[end][:v] == lowestSpeedLimit[:v] && drivingCourse[end][:s] < lowestSpeedLimit[:s_end]))
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s] # POIs include s_exit as well
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tractionSurplus = drivingCourse[end][:F_T] > drivingCourse[end][:F_R]
end #while
if csId==0
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testFlag = true
else
testFlag = false # for testing
end
# check which limit was reached and adjust the currentStepSize for the next cycle
if cycle < settings.approxLevel+1
if drivingCourse[end][:F_T] <= drivingCourse[end][:F_R]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: F_T=", drivingCourse[end][:F_T]," <= F_R=",drivingCourse[end][:F_R]) # for testing
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currentStepSize = settings.stepSize / 10.0^cycle
elseif s_braking > 0.0 && drivingCourse[end][:s] + s_braking > CS[:s_exit]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],",+",s_braking," = ",drivingCourse[end][:s] +s_braking," > s_exit=",CS[:s_exit]) # for testing
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currentStepSize = settings.stepSize / 10.0^cycle
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: s=", drivingCourse[end][:s]," > nextPOI=",nextPointOfInterest[:s]) # for testing
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if settings.stepVariable == :distance
currentStepSize = nextPointOfInterest[:s] - drivingCourse[end-1][:s]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:v] > lowestSpeedLimit[:v]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: v=", drivingCourse[end][:v]," > v_lowestLimit=", lowestSpeedLimit[:v]) # for testing
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if settings.stepVariable == :velocity
currentStepSize = lowestSpeedLimit[:v] - drivingCourse[end-1][:v]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:s] + s_braking == CS[:s_exit]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],",+",s_braking," = ",drivingCourse[end][:s] +s_braking," == s_exit=",CS[:s_exit]) # for testing
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break
elseif drivingCourse[end][:v] == lowestSpeedLimit[:v]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: v=", drivingCourse[end][:v]," == v_lowestLimit=", lowestSpeedLimit[:v]) # for testing
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break
elseif drivingCourse[end][:s] == nextPointOfInterest[:s]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: s=", drivingCourse[end][:s]," == nextPOI=",nextPointOfInterest[:s]) # for testing
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break
else
println("v=",drivingCourse[end][:v]," v_limit= ", CS[:v_limit] , " v_lowestLimit=", lowestSpeedLimit[:v])
println("s=" ,drivingCourse[end][:s]," s_exit=", CS[:s_exit], " s+s_braking=", drivingCourse[end][:s] +s_braking," nextPOI=",nextPointOfInterest[:s])
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println("F_T=",drivingCourse[end][:F_T] ," F_R=", drivingCourse[end][:F_R])
error("ERROR at accelerating section: With the step variable ",settings.stepVariable," the while loop will be left although v<v_limit and s<s_exit in CS",csId," with s=" ,drivingCourse[end][:s]," m and v=",drivingCourse[end][:v]," m/s")
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end
# delete last support point for recalculating the last step with reduced step size
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pop!(drivingCourse)
# conditions for the next for cycle
brakingStartReached = false
previousSpeedLimitReached = false
speedLimitReached = false
pointOfInterestReached = false
tractionSurplus = true
else # if the level of approximation is reached
if drivingCourse[end][:v] > lowestSpeedLimit[:v]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: v=", drivingCourse[end][:v]," > v_lowestLimit=", lowestSpeedLimit[:v], "with v_limit=",CS[:v_limit]) # for testing
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pop!(drivingCourse)
# conditions for the next section
brakingStartReached = false
elseif drivingCourse[end][:s] + s_braking > CS[:s_exit]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],",+",s_braking," = ",drivingCourse[end][:s] +s_braking," > s_exit=",CS[:s_exit]) # for testing
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if s_braking > 0.0
pop!(drivingCourse)
else
drivingCourse[end][:s] = CS[:s_exit] # round s down to CS[:s_exit]
end
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: s=", drivingCourse[end][:s]," > nextPointOfInterest[:s]=",nextPointOfInterest[:s]) # for testing
drivingCourse[end][:s] = nextPointOfInterest[:s] # round s down to nextPointOfInterest
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elseif drivingCourse[end][:F_T] <= drivingCourse[end][:F_R]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: F_T=", drivingCourse[end][:F_T]," <= F_R=",drivingCourse[end][:F_R]) # for testing
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else
if drivingCourse[end][:s] + s_braking == CS[:s_exit]
testFlag && println("in CS",csId," accelerating cycle",cycle," else case and there: s +s_braking=", drivingCourse[end][:s],",+",s_braking," = ",drivingCourse[end][:s] +s_braking," > s_exit=",CS[:s_exit]) # for testing
elseif drivingCourse[end][:v] == lowestSpeedLimit[:v]
testFlag && println("in CS",csId," accelerating cycle",cycle," case: v=", drivingCourse[end][:v]," == v_lowestLimit=", lowestSpeedLimit[:v]) # for testing
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end
end
end
end #for
if drivingCourse[end][:s] == CS[:s_exit]
endOfCSReached = true
end
if drivingCourse[end][:s] == nextPointOfInterest[:s]
drivingCourse[end][:label] = nextPointOfInterest[:label]
end
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end #while
end
# set state flags
stateFlags[:endOfCSReached] = endOfCSReached
stateFlags[:brakingStartReached] = brakingStartReached
stateFlags[:tractionDeficit] = !(tractionSurplus || drivingCourse[end][:F_T] == drivingCourse[end][:F_R]) # or add another flag for equal forces?
stateFlags[:resistingForceNegative] = drivingCourse[end][:F_R] < 0
stateFlags[:previousSpeedLimitReached] = previousSpeedLimitReached
stateFlags[:speedLimitReached] = speedLimitReached
stateFlags[:error] = !(endOfCSReached || brakingStartReached || stateFlags[:tractionDeficit] || previousSpeedLimitReached || speedLimitReached)
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return (drivingCourse, stateFlags)
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end #function addAcceleratingSection!
## This function calculates the support points of the cruising section.
# Therefore it gets its first support point and the characteristic section and returns the characteristic section including the behavior section for cruising if needed.
function addCruisingSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train, cruisingType::String, s_cruising::Real)
CS = CSs[csId]
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trainIsClearing = cruisingType == "clearing"
trainIsBrakingDownhill = cruisingType == "downhillBraking"
# traction effort and resisting forces (in N)
if !trainIsBrakingDownhill # TODO: or just give drivingMode instead of "cruising"/"braking"?
calculateForces!(drivingCourse[end], CSs, csId, "cruising", train, settings.massModel)
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else
calculateForces!(drivingCourse[end], CSs, csId, "braking", train, settings.massModel)
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end
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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# conditions for cruising section
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#s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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brakingStartReached = drivingCourse[end][:s] + s_braking >= CS[:s_exit] || stateFlags[:brakingStartReached]
speedIsValid = drivingCourse[end][:v] > 0.0 && drivingCourse[end][:v] <= CS[:v_limit]
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tractionDeficit = drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
targetPositionReached = s_cruising == 0.0
resistingForceNegative = drivingCourse[end][:F_R] < 0
if speedIsValid && !brakingStartReached && !tractionDeficit && !targetPositionReached
drivingMode = cruisingType
drivingCourse[end][:behavior] = drivingMode
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# TODO: necessary?
targetPosition = min(drivingCourse[end][:s] + s_cruising, CS[:s_exit])
# 07/12 old: s_cruising = min(s_cruising, CS[:s_exit]-drivingCourse[end][:s])
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# traction effort and resisting forces (in N)
if !trainIsBrakingDownhill
calculateForces!(drivingCourse[end], CSs, csId, "cruising", train, settings.massModel)
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else
calculateForces!(drivingCourse[end], CSs, csId, "braking", train, settings.massModel)
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end
if settings.massModel == :homogeneous_strip && csId > 1
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# conditions for cruising section
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trainInPreviousCS = drivingCourse[end][:s] < CS[:s_entry] + train.length
targetPositionReached = drivingCourse[end][:s] >= targetPosition
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resistingForceNegative = drivingCourse[end][:F_R] < 0.0
# TODO: change? to: correctCruisingType = (trainIsClearing || (trainIsBrakingDownhill == drivingCourse[end][:F_R] < 0)) # while clearing tractive or braking force can be used
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# use the conditions for the cruising section
while trainInPreviousCS && !targetPositionReached && !tractionDeficit && (trainIsClearing || (trainIsBrakingDownhill == resistingForceNegative)) # while clearing tractive or braking force can be used
currentStepSize = settings.stepSize
nextPointOfInterest = getNextPointOfInterest(CS[:pointsOfInterest], drivingCourse[end][:s])
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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for cycle in 1:settings.approxLevel+1 # first cycle with normal step size followed by cycles with reduced step size depending on the level of approximation
while trainInPreviousCS && !targetPositionReached && !pointOfInterestReached && !tractionDeficit && (trainIsClearing || (trainIsBrakingDownhill == resistingForceNegative)) # while clearing tractive or braking force can be used
# the tractive effort is lower than the resisting forces and the train has to use the highest possible effort to try to stay at v_limit OR the mass model homogeneous strip is used and parts of the train are still in former CS
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#TODO: maybe just consider former CS with different path resistance?
# tractive effort (in N):
if !trainIsBrakingDownhill
drivingCourse[end][:F_T] = min(drivingCourse[end][:F_T], max(0.0, drivingCourse[end][:F_R]))
else
drivingCourse[end][:F_T] = 0.0
end
# acceleration (in m/s^2):
drivingCourse[end][:a] = 0.0
# create the next support point
if settings.stepVariable == :distance || settings.stepVariable == :time
push!(drivingCourse, moveAStep(drivingCourse[end], settings.stepVariable, currentStepSize, csId))
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else
push!(drivingCourse, moveAStep(drivingCourse[end], settings.stepVariable, train.length/(10.0^cycle), csId)) # TODO which step size should be used?
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end
drivingCourse[end][:behavior] = drivingMode
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# traction effort and resisting forces (in N)
calculateForces!(drivingCourse[end], CSs, csId, "default", train, settings.massModel)
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# conditions for the next while cycle
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s] # POIs include s_exit as well
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tractionDeficit = drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
targetPositionReached = drivingCourse[end][:s] >= targetPosition
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trainInPreviousCS = drivingCourse[end][:s] < CS[:s_entry] + train.length
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resistingForceNegative = drivingCourse[end][:F_R] < 0.0
end #while
# check which limit was reached and adjust the currentStepSize for the next cycle
if cycle < settings.approxLevel+1
if drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
currentStepSize = settings.stepSize / 10.0^cycle
elseif !trainIsBrakingDownhill && resistingForceNegative
currentStepSize = settings.stepSize / 10.0^cycle
elseif trainIsBrakingDownhill && !resistingForceNegative
currentStepSize = settings.stepSize / 10.0^cycle
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
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if settings.stepVariable == :distance
currentStepSize = nextPointOfInterest[:s] - drivingCourse[end-1][:s]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:s] > targetPosition # TODO also the following? drivingCourse[end][:s] > CS[:s_entry] + train.length))
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if settings.stepVariable == :distance
currentStepSize = targetPosition - drivingCourse[end-1][:s]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:s] == targetPosition # || drivingCourse[end][:s]==CS[:s_exit]
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break
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elseif drivingCourse[end][:s] >= CS[:s_entry] + train.length
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break
elseif drivingCourse[end][:s] == nextPointOfInterest[:s]
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break
elseif !trainInPreviousCS
break
else
error("ERROR at cruising section: With the step variable ",settings.stepVariable," the while loop will be left although the if cases don't apply in CS",csId," with s=" ,drivingCourse[end][:s]," m and v=",drivingCourse[end][:v]," m/s")
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end
# delete last support point for recalculating the last step with reduced step size
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pop!(drivingCourse)
# conditions for the next for cycle
pointOfInterestReached = false
tractionDeficit = false
targetPositionReached = false
trainInPreviousCS = true
resistingForceNegative = drivingCourse[end][:F_R] < 0.0
else # if the level of approximation is reached
if drivingCourse[end][:s] > nextPointOfInterest[:s]
drivingCourse[end][:s] = nextPointOfInterest[:s] # round s down to nextPointOfInterest
elseif drivingCourse[end][:s] > targetPosition
if drivingMode != "clearing"
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pop!(drivingCourse)
end
elseif drivingCourse[end][:s] == targetPosition
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break
elseif drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
break
elseif !trainIsBrakingDownhill && resistingForceNegative
break
elseif trainIsBrakingDownhill && !resistingForceNegative
break
elseif !trainInPreviousCS
break
else
end
end
end #for
if drivingCourse[end][:s] == nextPointOfInterest[:s]
drivingCourse[end][:label] = nextPointOfInterest[:label]
end
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end #while
end #if
# conditions for the next while cycle
targetPositionReached = drivingCourse[end][:s] >= targetPosition
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tractionDeficit = drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
resistingForceNegative = drivingCourse[end][:F_R] < 0.0
while !targetPositionReached && !tractionDeficit && (trainIsClearing || (trainIsBrakingDownhill == resistingForceNegative)) # while clearing tractive or braking force can be used
nextPointOfInterest = getNextPointOfInterest(CS[:pointsOfInterest], drivingCourse[end][:s])
if nextPointOfInterest[:s] > targetPosition
nextPointOfInterest = (s = targetPosition, label = "") #[targetPosition, ""]
end
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# tractive effort (in N):
if !trainIsBrakingDownhill
drivingCourse[end][:F_T] = min(drivingCourse[end][:F_T], max(0.0, drivingCourse[end][:F_R]))
else
drivingCourse[end][:F_T] = 0.0
end
drivingCourse[end][:a] = 0.0 # acceleration (in m/s^2)
# calculate the remaining cruising way
#s_cruisingRemaining=targetPosition-drivingCourse[end][:s]
s_cruisingRemaining = min(nextPointOfInterest[:s] -drivingCourse[end][:s], targetPosition -drivingCourse[end][:s])
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# create the next support point
push!(drivingCourse, moveAStep(drivingCourse[end], :distance, s_cruisingRemaining, csId))
drivingCourse[end][:behavior] = drivingMode
if drivingCourse[end][:s] == nextPointOfInterest[:s]
drivingCourse[end][:label] = nextPointOfInterest[:label]
end
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calculateForces!(drivingCourse[end], CSs, csId, "default", train, settings.massModel)
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# conditions for the next while cycle
targetPositionReached = drivingCourse[end][:s] >= targetPosition
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tractionDeficit = drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
resistingForceNegative = drivingCourse[end][:F_R] < 0
end #while
end # else: return the characteristic section without a cruising section
# set state flags
stateFlags[:endOfCSReached] = drivingCourse[end][:s] == CS[:s_exit]
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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stateFlags[:brakingStartReached] = brakingStartReached || drivingCourse[end][:s] + s_braking >= CS[:s_exit]
stateFlags[:tractionDeficit] = tractionDeficit
stateFlags[:resistingForceNegative] = drivingCourse[end][:F_R] < 0.0
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
stateFlags[:previousSpeedLimitReached] = lowestSpeedLimit[:v] != CS[:v_limit] && drivingCourse[end][:v] >= lowestSpeedLimit[:v]
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stateFlags[:error] = !(targetPositionReached || tractionDeficit || !(cruisingType == "clearing" || ((cruisingType == "downhillBraking") == resistingForceNegative)))
return (drivingCourse, stateFlags)
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end #function addCruisingSection!
## This function calculates the support points for diminishing run when using maximum tractive effort and still getting slower
function addDiminishingSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
CS = CSs[csId]
calculateForces!(drivingCourse[end], CSs, csId, "diminishing", train, settings.massModel)
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s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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# conditions for diminishing section
targetSpeedReached = drivingCourse[end][:v] <= 0.0
endOfCSReached = drivingCourse[end][:s] >= CS[:s_exit] || stateFlags[:endOfCSReached]
tractionDeficit = drivingCourse[end][:F_T] < drivingCourse[end][:F_R] #|| stateFlags[:tractionDeficit]
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#s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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brakingStartReached = drivingCourse[end][:s] + s_braking >= CS[:s_exit] || stateFlags[:brakingStartReached]
# use the conditions for the diminishing section
if tractionDeficit && !targetSpeedReached && !endOfCSReached
drivingMode = "diminishing"
drivingCourse[end][:behavior] = drivingMode
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while tractionDeficit && !targetSpeedReached && !endOfCSReached && !brakingStartReached
currentStepSize = settings.stepSize # initialize the step size that can be reduced near intersections
nextPointOfInterest = getNextPointOfInterest(CS[:pointsOfInterest], drivingCourse[end][:s])
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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for cycle in 1:settings.approxLevel+1 # first cycle with normal step size followed by cycles with reduced step size depending on the level of approximation
while tractionDeficit && !brakingStartReached && !pointOfInterestReached && !targetSpeedReached
# acceleration (in m/s^2):
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drivingCourse[end][:a] = acceleration(drivingCourse[end][:F_T], drivingCourse[end][:F_R], train.m_train_full, train.ξ_train)
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# create the next support point
push!(drivingCourse, moveAStep(drivingCourse[end], settings.stepVariable, currentStepSize, csId))
drivingCourse[end][:behavior] = drivingMode
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calculateForces!(drivingCourse[end], CSs, csId, drivingMode, train, settings.massModel)
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# conditions for the next while cycle
s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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brakingStartReached = drivingCourse[end][:s] +s_braking >= CS[:s_exit]
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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targetSpeedReached = drivingCourse[end][:v] <= 0.0
tractionDeficit = drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
end #while
if csId==0
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testFlag = true
else
testFlag = false # for testing
end
# check which limit was reached and adjust the currentStepSize for the next cycle
if cycle < settings.approxLevel+1
if drivingCourse[end][:v] < 0.0
# if settings.stepVariable == :velocity
# currentStepSize = drivingCourse[end-1][:v]
# else
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currentStepSize = settings.stepSize / 10.0^cycle
# end
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elseif drivingCourse[end][:F_T] > drivingCourse[end][:F_R]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: F_T=", drivingCourse[end][:F_T]," > F_R=",drivingCourse[end][:F_R]) # for testing
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currentStepSize = settings.stepSize / 10.0^cycle
elseif s_braking > 0.0 && drivingCourse[end][:s] + s_braking > CS[:s_exit]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],"+",s_braking," = ",drivingCourse[end][:s] +s_braking," > s_exit=",CS[:s_exit]) # for testing
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currentStepSize = settings.stepSize / 10.0^cycle
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: s=", drivingCourse[end][:s]," > nextPOI=",nextPointOfInterest[:s]) # for testing
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if settings.stepVariable == :distance
currentStepSize = nextPointOfInterest[:s] - drivingCourse[end-1][:s]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:s] + s_braking == CS[:s_exit]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],"+",s_braking," = ",drivingCourse[end][:s] +s_braking," == s_exit=",CS[:s_exit]) # for testing
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break
elseif drivingCourse[end][:s] == nextPointOfInterest[:s]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: s=", drivingCourse[end][:s]," == nextPOI=",nextPointOfInterest[:s]) # for testing
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break
elseif drivingCourse[end][:F_T] == drivingCourse[end][:F_R]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: F_T=", drivingCourse[end][:F_T]," == F_R=",drivingCourse[end][:F_R]) # for testing
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break
elseif drivingCourse[end][:v] == 0.0
error("ERROR: The train stops during diminishing run in CS",csId," at position s=",drivingCourse[end][:s]," m because the maximum tractive effort is lower than the resistant forces.",
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" Before the stop the last point has the values s=",drivingCourse[end-1][:s]," m v=",drivingCourse[end-1][:v]," m/s a=",drivingCourse[end-1][:a]," m/s^2",
" F_T=",drivingCourse[end-1][:F_T]," N R_traction=",drivingCourse[end-1][:R_traction]," N R_wagons=",drivingCourse[end-1][:R_wagons]," N R_path=",drivingCourse[end-1][:R_path]," N.")
else
error("ERROR during diminishing run: With the step variable ",settings.stepVariable," the while loop will be left although s+s_braking<s_exit && v>0.0 in CS",csId," with s=" ,drivingCourse[end][:s]," m and v=",drivingCourse[end][:v]," m/s")
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end
# delete last support point for recalculating the last step with reduced step size
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pop!(drivingCourse)
# conditions for the next for cycle
brakingStartReached = false
pointOfInterestReached = false
targetSpeedReached = false
tractionDeficit = true
else # if the level of approximation is reached
if drivingCourse[end][:v] <= 0.0
testFlag && println("in CS",csId," diminishing cycle",cycle," case: v=", drivingCourse[end][:v]," <= 0.0") # for testing
error("ERROR: The train stops during diminishing run in CS",csId," because the maximum tractive effort is lower than the resistant forces.",
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" Before the stop the last point has the values s=",drivingCourse[end-1][:s]," m v=",drivingCourse[end-1][:v]," m/s a=",drivingCourse[end-1][:a]," m/s^2",
" F_T=",drivingCourse[end-1][:F_T]," N R_traction=",drivingCourse[end-1][:R_traction]," N R_wagons=",drivingCourse[end-1][:R_wagons]," N R_path=",drivingCourse[end-1][:R_path]," N.")
elseif s_braking > 0.0 && drivingCourse[end][:s] + s_braking > CS[:s_exit]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],"+",s_braking," = ",drivingCourse[end][:s] +s_braking," > s_exit=",CS[:s_exit]) # for testing
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pop!(drivingCourse)
pointOfInterestReached = false
targetSpeedReached = false
tractionDeficit = true
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: s=", drivingCourse[end][:s]," > nextPointOfInterest[:s]=",nextPointOfInterest[:s]) # for testing
drivingCourse[end][:s] = nextPointOfInterest[:s] # round s down to nextPointOfInterest
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elseif drivingCourse[end][:F_T] >= drivingCourse[end][:F_R]
testFlag && println("in CS",csId," diminishing cycle",cycle," case: F_T=", drivingCourse[end][:F_T]," >= F_R=", drivingCourse[end][:F_R]) # for testing
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break
else
testFlag && println("in CS",csId," diminishing cycle",cycle," case: else with v=", drivingCourse[end][:v]," > 0.0 and F_T=", drivingCourse[end][:F_T]," <= F_R=", drivingCourse[end][:F_R]) # for testing
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#println(" and s +s_braking=", drivingCourse[end][:s],"+",s_braking," = ",drivingCourse[end][:s] +s_braking," <= s_exit=",CS[:s_exit]) # for testing
#println(" and s=", drivingCourse[end][:s]," <= nextPointOfInterest[:s]=",nextPointOfInterest[:s]) # for testing
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end #if
end #if
end #for
endOfCSReached = drivingCourse[end][:s] == CS[:s_exit]
if drivingCourse[end][:s] == nextPointOfInterest[:s]
drivingCourse[end][:label] = nextPointOfInterest[:label]
end
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end #while
end
# set state flags
stateFlags[:endOfCSReached] = endOfCSReached
stateFlags[:brakingStartReached] = brakingStartReached
stateFlags[:tractionDeficit] = tractionDeficit
stateFlags[:resistingForceNegative] = drivingCourse[end][:F_R] < 0
stateFlags[:speedLimitReached] = drivingCourse[end][:v] >= CS[:v_limit]
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stateFlags[:error] = !(endOfCSReached || brakingStartReached || !tractionDeficit)
return (drivingCourse, stateFlags)
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end #function addDiminishingSection!
## This function calculates the support points of the coasting section.
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# Therefore it gets its previous driving course and the characteristic section and returns the characteristic section and driving course including the coasting section
function addCoastingSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
CS = CSs[csId]
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# conditions for coasting section
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
previousSpeedLimitReached = lowestSpeedLimit[:v] != CS[:v_limit] && drivingCourse[end][:v] > lowestSpeedLimit[:v]
speedLimitReached = drivingCourse[end][:v] > CS[:v_limit]
targetSpeedReached = drivingCourse[end][:v] <= CS[:v_exit] || previousSpeedLimitReached || speedLimitReached
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endOfCSReached = drivingCourse[end][:s] >= CS[:s_exit] || stateFlags[:endOfCSReached]
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s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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brakingStartReached = drivingCourse[end][:s] + s_braking >= CS[:s_exit] || stateFlags[:brakingStartReached]
# use the conditions for the coasting section
if !targetSpeedReached && !endOfCSReached
drivingMode = "coasting"
drivingCourse[end][:behavior] = drivingMode
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while !targetSpeedReached && !endOfCSReached && !brakingStartReached
currentStepSize = settings.stepSize # initialize the step size that can be reduced near intersections
nextPointOfInterest[:s] = getNextPointOfInterest(CS[:pointsOfInterest], drivingCourse[end][:s])
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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for cycle in 1:settings.approxLevel+1 # first cycle with normal step size followed by cycles with reduced step size depending on the level of approximation
while !targetSpeedReached && !brakingStartReached && !pointOfInterestReached
if drivingCourse[end][:s] >= lowestSpeedLimit[:s_end]
# could be asked after creating an support point. This way here prevents even a minimal exceedance of speed limit.
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
end
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# traction effort and resisting forces (in N):
calculateForces!(drivingCourse[end], CSs, csId, drivingMode, train, settings.massModel)
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# acceleration (in m/s^2):
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drivingCourse[end][:a] = acceleration(drivingCourse[end][:F_T], drivingCourse[end][:F_R], train.m_train_full, train.ξ_train)
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# create the next support point
push!(drivingCourse, moveAStep(drivingCourse[end], settings.stepVariable, currentStepSize, csId))
drivingCourse[end][:behavior] = drivingMode
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# conditions for the next while cycle
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s_braking = brakingDistance(drivingCourse[end][:v], CS[:v_exit], train.a_braking, settings.approxLevel)
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brakingStartReached = drivingCourse[end][:s] + s_braking >= CS[:s_exit]
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
targetSpeedReached = drivingCourse[end][:v] <= CS[:v_exit] || drivingCourse[end][:v] > CS[:v_limit] || lowestSpeedLimit[:v] < CS[:v_limit] && (drivingCourse[end][:v] > lowestSpeedLimit[:v] || (drivingCourse[end][:v] == lowestSpeedLimit[:v] && drivingCourse[end][:s] < lowestSpeedLimit[:s_end]))
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end # while
testFlag = false
# check which limit was reached and adjust the currentStepSize for the next cycle
if cycle < settings.approxLevel+1
if drivingCourse[end][:s] + s_braking > CS[:s_exit]
testFlag && println("in CS",csId," coasting cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],"+",s_braking," = ",drivingCourse[end][:s] +s_braking," > s_exit=",CS[:s_exit]) # for testing
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currentStepSize = settings.stepSize / 10.0^cycle
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
testFlag && println("in CS",csId," coasting cycle",cycle," case: s=", drivingCourse[end][:s]," > nextPointOfInterest[:s]=",nextPointOfInterest[:s]) # for testing
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if settings.stepVariable == :distance
currentStepSize = nextPointOfInterest[:s] - drivingCourse[end-1][:s]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:v] < CS[:v_exit] # TODO: if accelereation and coasting functions will be combined this case is only for coasting
testFlag && println("in CS",csId," coasting cycle",cycle," case: v=", drivingCourse[end][:v]," < v_exit=", CS[:v_exit]) # for testing
if settings.stepVariable == :velocity
currentStepSize = drivingCourse[end-1][:v] - CS[:v_exit]
else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:v] > lowestSpeedLimit[:v]
testFlag && println("in CS",csId," coasting cycle",cycle," case: v=", drivingCourse[end][:v]," > v_lowestLimit=", lowestSpeedLimit[:v]) # for testing
if settings.stepVariable == :velocity
currentStepSize = lowestSpeedLimit[:v] - drivingCourse[end-1][:v]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
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elseif drivingCourse[end][:s] + s_braking == CS[:s_exit]
testFlag && println("in CS",csId," coasting cycle",cycle," case: s +s_braking=", drivingCourse[end][:s],"+",s_braking," = ",drivingCourse[end][:s] +s_braking," == s_exit=",CS[:s_exit]) # for testing
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break
elseif drivingCourse[end][:v] == CS[:v_exit]
testFlag && println("in CS",csId," coasting cycle",cycle," case: v=", drivingCourse[end][:v]," == v_exit=", CS[:v_exit]) # for testing
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break
elseif drivingCourse[end][:s] == nextPointOfInterest[:s]
testFlag && println("in CS",csId," coasting cycle",cycle," case: s =", drivingCourse[end][:s]," > nextPointOfInterest[:s]=",nextPointOfInterest[:s]) # for testing
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break
else
# TODO: not needed. just for testing
error("ERROR at coasting until braking section: With the step variable ",settings.stepVariable," the while loop will be left although v<v_limit and s+s_braking<s_exit in CS",csId," with s=" ,drivingCourse[end][:s]," m and v=",drivingCourse[end][:v]," m/s")
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end
# delete last support point for recalculating the last step with reduced step size
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pop!(drivingCourse)
# conditions for the next for cycle
brakingStartReached = false
pointOfInterestReached = false
targetSpeedReached = false
else # if the level of approximation is reached
if drivingCourse[end][:v] <= 0.0
println("INFO: The train stops during the coasting section in CS",csId," ",
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" Before the stop the last point has the values s=",drivingCourse[end-1][:s]," m v=",drivingCourse[end-1][:v]," m/s a=",drivingCourse[end-1][:a]," m/s^2",
" F_T=",drivingCourse[end-1][:F_T]," N R_traction=",drivingCourse[end-1][:R_traction]," N R_wagons=",drivingCourse[end-1][:R_wagons]," N R_path=",drivingCourse[end-1][:R_path]," N and s_braking=",s_braking,"m.")
elseif drivingCourse[end][:s] + s_braking > CS[:s_exit]
# delete last support point because it went to far
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pop!(drivingCourse)
# conditions for the next for cycle
# brakingStartReached = true
pointOfInterestReached = false
targetSpeedReached = false
elseif drivingCourse[end][:v] > lowestSpeedLimit[:v] # if the train gets to fast it has to brake to hold the velocity limit
# delete last support point because it went to far
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pop!(drivingCourse)
# conditions for the next for cycle
brakingStartReached = false
pointOfInterestReached = false
if lowestSpeedLimit[:v] != CS[:v_limit]
previousSpeedLimitReached = true
else
speedLimitReached = true
end
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elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
drivingCourse[end][:s] = nextPointOfInterest[:s] # round s down to nextPointOfInterest
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else
# do nothing for example for drivingCourse[end][:s] + s_braking == CS[:s_exit]
end
end
end #for
endOfCSReached = drivingCourse[end][:s] == CS[:s_exit]
if drivingCourse[end][:s] == nextPointOfInterest[:s]
drivingCourse[end][:label] = nextPointOfInterest[:label]
end
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end #while
end
# set state flags
stateFlags[:endOfCSReached] = endOfCSReached
stateFlags[:brakingStartReached] = brakingStartReached
stateFlags[:tractionDeficit] = drivingCourse[end][:F_T] < drivingCourse[end][:F_R]
stateFlags[:resistingForceNegative] = drivingCourse[end][:F_R] < 0
stateFlags[:previousSpeedLimitReached] = previousSpeedLimitReached
stateFlags[:speedLimitReached] = speedLimitReached
stateFlags[:error] = !(endOfCSReached || brakingStartReached || stateFlags[:tractionDeficit] || previousSpeedLimitReached || speedLimitReached)
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return (drivingCourse, stateFlags)
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end #function addCoastingSection!
## This function calculates the support points of the braking section.
# Therefore it gets its first support point and the characteristic section and returns the characteristic section including the behavior section for braking if needed.
function addBrakingSection!(drivingCourse::Vector{Dict}, stateFlags::Dict, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
CS = CSs[csId]
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# conditions for braking section
targetSpeedReached = drivingCourse[end][:v] <= CS[:v_exit]
endOfCSReached = drivingCourse[end][:s] >= CS[:s_exit] || stateFlags[:endOfCSReached]
# use the conditions for the braking section
if !targetSpeedReached && !endOfCSReached
drivingMode = "braking"
drivingCourse[end][:behavior] = drivingMode
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while !targetSpeedReached && !endOfCSReached
currentStepSize = settings.stepSize # initialize the step size that can be reduced near intersections
nextPointOfInterest = getNextPointOfInterest(CS[:pointsOfInterest], drivingCourse[end][:s])
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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for cycle in 1:settings.approxLevel+1 # first cycle with normal step size followed by cycles with reduced step size depending on the level of approximation
while !targetSpeedReached && !endOfCSReached && !pointOfInterestReached
# traction effort and resisting forces (in N):
calculateForces!(drivingCourse[end], CSs, csId, drivingMode, train, settings.massModel)
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# acceleration (in m/s^2):
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drivingCourse[end][:a] = train.a_braking
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# TODO or: drivingCourse[end][:a] = brakingAcceleration(drivingCourse[end][:v], CS[:v_exit], CS[:s_exit]-drivingCourse[end][:s])
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if settings.stepVariable == :distance && ((drivingCourse[end][:v]/drivingCourse[end][:a])^2+2*currentStepSize/drivingCourse[end][:a])<0.0 || (drivingCourse[end][:v]^2+2*currentStepSize*drivingCourse[end][:a])<0.0
# create empty support point and set it for the values of s_exit and v_exit
push!(drivingCourse, SupportPoint())
drivingCourse[end][:behavior] = drivingMode
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recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
else
# create the next support point
push!(drivingCourse, moveAStep(drivingCourse[end], settings.stepVariable, currentStepSize, csId))
drivingCourse[end][:behavior] = drivingMode
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end
# conditions for the next while cycle
pointOfInterestReached = drivingCourse[end][:s] >= nextPointOfInterest[:s]
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endOfCSReached = drivingCourse[end][:s] >= CS[:s_exit]
targetSpeedReached = drivingCourse[end][:v] <= CS[:v_exit]
end # while
# check which limit was reached and adjust the currentStepSize for the next cycle
# TODO: is there a better way than rounding like in the following?
if cycle < settings.approxLevel+1
if drivingCourse[end][:v] < CS[:v_exit]
if settings.stepVariable == :velocity
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currentStepSize = drivingCourse[end-1][:v] - CS[:v_exit]
else
currentStepSize = settings.stepSize / 10.0^cycle
end
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
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if settings.stepVariable == :distance
currentStepSize = nextPointOfInterest[:s] - drivingCourse[end-1][:s]
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else
currentStepSize = settings.stepSize / 10.0^cycle
end
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elseif drivingCourse[end][:v] == CS[:v_exit] && drivingCourse[end][:s] == CS[:s_exit]
break
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elseif drivingCourse[end][:v] == CS[:v_exit]
recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
endOfCSReached = true
break
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elseif drivingCourse[end][:s] == CS[:s_exit]
recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
targetSpeedReached = true
break
elseif drivingCourse[end][:s] == nextPointOfInterest[:s]
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break
end
# delete last support point for recalculating the last step with reduced step size
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pop!(drivingCourse)
# conditions for the next for cycle
pointOfInterestReached = false
endOfCSReached = false
targetSpeedReached = false
else # if the level of approximation is reached
if drivingCourse[end][:v] < 0.0
# TODO: drivingCourse[end][:v] < CS[:v_exit] should be enough
# reset last point with setting v=v_exit. still possible with v_exit now meaning v_exitMax?
# println("during braking section in CS",csId,": rounding v up from ", drivingCourse[end][:v] ," to ", CS[:v_exit]) # for testing
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recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], 0.0)
endOfCSReached = true
break
elseif drivingCourse[end][:s] > CS[:s_exit]
# println("during braking section in CS",csId,": rounding s down from ", drivingCourse[end][:s] ," to ", CS[:s_exit]) # for testing
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# recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
drivingCourse[end][:s] = CS[:s_exit]
break
elseif drivingCourse[end][:s] > nextPointOfInterest[:s]
drivingCourse[end][:s] = nextPointOfInterest[:s] # round s down to nextPointOfInterest
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break
elseif drivingCourse[end][:v] == CS[:v_exit] && drivingCourse[end][:s] == CS[:s_exit]
break
elseif drivingCourse[end][:v] < CS[:v_exit]
# reset last point with setting v=v_exit
# println("during braking section in CS",csId,": rounding s up from ", drivingCourse[end][:s] ," to ", CS[:s_exit]) # for testing
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recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
endOfCSReached = true
break
elseif drivingCourse[end][:v] == CS[:v_exit]
# println("during braking section in CS",csId,": rounding s up from ", drivingCourse[end][:s] ," to ", CS[:s_exit]) # for testing
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recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
endOfCSReached = true
break
elseif drivingCourse[end][:s] == CS[:s_exit]
# println("during braking section in CS",csId,": rounding v down from ", drivingCourse[end][:v] ," to ", CS[:v_exit]) # for testing
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recalculateLastBrakingPoint!(drivingCourse, CS[:s_exit], CS[:v_exit])
targetSpeedReached = true
break
else
# do nothing for example for drivingCourse[end][:s]==nextPointOfInterest[:s]
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end
end
end #for
if drivingCourse[end][:s] == nextPointOfInterest[:s]
drivingCourse[end][:label] = nextPointOfInterest[:label]
end
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end #while
end # else: return the characteristic section without a braking section
# set state flags
lowestSpeedLimit = getLowestSpeedLimit(CSs, csId, drivingCourse[end][:s], train.length)
stateFlags[:previousSpeedLimitReached] = lowestSpeedLimit[:v] != CS[:v_limit] && drivingCourse[end][:v] >= lowestSpeedLimit[:v]
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stateFlags[:speedLimitReached] = drivingCourse[end][:v] >= CS[:v_exit]
stateFlags[:endOfCSReached] = endOfCSReached
stateFlags[:error] = !(endOfCSReached)
calculateForces!(drivingCourse[end], CSs, csId, "default", train, settings.massModel)
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stateFlags[:resistingForceNegative] = drivingCourse[end][:F_R] < 0
return (drivingCourse, stateFlags)
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end #function addBrakingSection!
## This function calculates the support point of the halt.
# Therefore it gets its first support point and the characteristic section and returns the characteristic section including the halt if needed.
function addHalt!(drivingCourse::Vector{Dict}, CSs::Vector{Dict}, csId::Integer, settings::Settings, train::Train)
# CS = CSs[csId] # is not needed here
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if drivingCourse[end][:v] == 0.0
drivingMode = "halt"
drivingCourse[end][:behavior] = drivingMode
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# traction effort and resisting forces (in N)
calculateForces!(drivingCourse[end], CSs, csId, drivingMode, train, settings.massModel)
end # else: return the characteristic section without a halt section section
return drivingCourse
end #function addHalt!
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function recalculateLastBrakingPoint!(drivingCourse, s_target, v_target)
currentPoint = drivingCourse[end]
previousPoint = drivingCourse[end-1]
# set s and v
currentPoint[:s] = s_target # position (in m)
currentPoint[:v] = v_target # velocity (in m/s)
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# calculate other values
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previousPoint[:a] = brakingAcceleration(previousPoint[:v], currentPoint[:v], currentPoint[:s]-previousPoint[:s])
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# # TODO: just for testing
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# if previousPoint[:a]<train.a_braking || previousPoint[:a]>=0.0
# println("Warning: a_braking gets to high in CS ",csId, " with a=",previousPoint[:a] ," > ",train.a_braking)
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# end
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currentPoint[:t] = previousPoint[:t] + Δt_with_Δv(currentPoint[:v]-previousPoint[:v], previousPoint[:a]) # point in time (in s)
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end #function recalculateLastBrakingPoint
## define the intersection velocities between the characterisitc sections to secure braking behavior
function secureBrakingBehavior!(CSs::Vector{Dict}, a_braking::Real, approxLevel::Integer)
# limit the entry and exit velocities of the characteristic sections to secure that the train stops at the moving sections end
csId = length(CSs)
v_entryFollowing = 0.0 # the exit velocity of the last characteristic section is 0.0 m/s
while csId >= 1
# calculate the maximum possible entry velocity to define the previous section's maximum allowed exit velocity
CS = CSs[csId]
CS[:v_exit] = min(CS[:v_limit], v_entryFollowing)
v_entry = brakingStartVelocity(CS[:v_exit], a_braking, CS[:s_exit]-CS[:s_entry], approxLevel)
v_entryFollowing = min(CS[:v_limit], v_entry)
csId = csId - 1
end #while
return CSs
end #function secureBrakingBehavior!