public LinePath LinearizeCenterLine(LinearizationOptions options) { LinePath transformedPath = centerlinePath; if (options.Timestamp.IsValid) { RelativeTransform relTransform = Services.RelativePose.GetTransform(timestamp, options.Timestamp); OperationalTrace.WriteVerbose("in LinearizeCenterLine, tried to find {0}->{1}, got {2}->{3}", timestamp, options.Timestamp, relTransform.OriginTimestamp, relTransform.EndTimestamp); transformedPath = centerlinePath.Transform(relTransform); } LinePath.PointOnPath startPoint = transformedPath.AdvancePoint(centerlinePath.ZeroPoint, options.StartDistance); LinePath subPath = new LinePath();; if (options.EndDistance > options.StartDistance) { subPath = transformedPath.SubPath(startPoint, options.EndDistance - options.StartDistance); } if (subPath.Count < 2) { subPath.Clear(); Coordinates startPt = startPoint.Location; subPath.Add(startPt); subPath.Add(centerlinePath.GetSegment(startPoint.Index).UnitVector *Math.Max(options.EndDistance - options.StartDistance, 0.1) + startPt); } return(subPath); }
private void ProcessReverse() { double planningDistance = GetPlanningDistance(); // update the rndf path RelativeTransform relTransfrom = Services.RelativePose.GetTransform(behaviorTimestamp, curTimestamp); LinePath curRndfPath = rndfPath.Transform(relTransfrom); Console.WriteLine("cur rndf path count: " + curRndfPath.Count + ", " + curRndfPath.PathLength); Console.WriteLine("cur rndf path zero point valid: " + curRndfPath.ZeroPoint.Valid + ", loc: " + curRndfPath.ZeroPoint.Location + ", index: " + curRndfPath.ZeroPoint.Index); Console.WriteLine("planning dist: " + planningDistance + ", stop dist: " + GetSpeedCommandStopDistance()); // get the path in reverse double dist = -(planningDistance + TahoeParams.RL + 2); LinePath targetPath = curRndfPath.SubPath(curRndfPath.ZeroPoint, ref dist); if (dist < 0) { targetPath.Add(curRndfPath[0] - curRndfPath.GetSegment(0).Vector.Normalize(-dist)); } Console.WriteLine("target path count: " + targetPath.Count + ", " + targetPath.PathLength); Console.WriteLine("target path zero point valud: " + targetPath.ZeroPoint.Valid); // generate a box by shifting the path LinePath leftBound = targetPath.ShiftLateral(rndfPathWidth / 2.0); LinePath rightBound = targetPath.ShiftLateral(-rndfPathWidth / 2.0); double leftStartDist, rightStartDist; GetLaneBoundStartDists(targetPath, rndfPathWidth, out leftStartDist, out rightStartDist); leftBound = leftBound.RemoveBefore(leftBound.AdvancePoint(leftBound.StartPoint, leftStartDist)); rightBound = rightBound.RemoveBefore(rightBound.AdvancePoint(rightBound.StartPoint, rightStartDist)); AddTargetPath(targetPath, 0.0025); AddLeftBound(leftBound, false); AddRightBound(rightBound, false); avoidanceBasePath = targetPath; double targetDist = Math.Max(targetPath.PathLength - (TahoeParams.RL + 2), planningDistance); smootherBasePath = targetPath.SubPath(targetPath.StartPoint, targetDist); settings.maxSpeed = GetMaxSpeed(null, LinePath.PointOnPath.Invalid); settings.endingPositionFixed = true; settings.endingPositionMax = rndfPathWidth / 2.0; settings.endingPositionMin = -rndfPathWidth / 2.0; settings.Options.reverse = true; Services.UIService.PushLineList(smootherBasePath, curTimestamp, "subpath", true); Services.UIService.PushLineList(leftBound, curTimestamp, "left bound", true); Services.UIService.PushLineList(rightBound, curTimestamp, "right bound", true); SmoothAndTrack(commandLabel, true); }
public Coordinates[] VehiclePoints(SimVehicleState svs) { Polygon p = VehiclePolygon(svs); LinePath lp = new LinePath(p); LinePath.PointOnPath c = lp.StartPoint; List <Coordinates> cs = new List <Coordinates>(); while (!c.Equals(lp.EndPoint)) { cs.Add(lp.GetPoint(c)); c = lp.AdvancePoint(c, 0.1); } return(cs.ToArray()); }
public LinePath LinearizeLeftBound(LinearizationOptions options) { LinePath bound = FindBoundary(this.width / 2 + options.LaneShiftDistance + 0.3, path); if (options.Timestamp.IsValid) { RelativeTransform relTransform = Services.RelativePose.GetTransform(timestamp, options.Timestamp); bound.TransformInPlace(relTransform); } if (options.EndDistance > options.StartDistance) { LinePath.PointOnPath startPoint = bound.AdvancePoint(bound.ZeroPoint, options.StartDistance); return(bound.SubPath(startPoint, options.EndDistance - options.StartDistance)); } else { return(new LinePath()); } }
public LinePath LinearizeRightBound(LinearizationOptions options) { LinePath bound = rightBound; if (options.Timestamp.IsValid) { RelativeTransform relTransform = Services.RelativePose.GetTransform(timestamp, options.Timestamp); bound = bound.Transform(relTransform); } if (options.EndDistance > options.StartDistance) { // TODO: work off centerline path LinePath.PointOnPath startPoint = bound.AdvancePoint(bound.ZeroPoint, options.StartDistance); return(bound.SubPath(startPoint, options.EndDistance - options.StartDistance).ShiftLateral(options.LaneShiftDistance)); } else { return(new LinePath()); } }
/// <summary> /// Distance to another connect /// </summary> /// <param name="icaw"></param> /// <returns></returns> public double DistanceTo(IConnectAreaWaypoints icaw) { LinePath.PointOnPath current = this.PartitionPath.StartPoint; double inc = 1.0; double dist = 0; double minDist = double.MaxValue; while (dist == 0) { double tmpDist = icaw.DistanceTo(this.PartitionPath.GetPoint(current)); if (tmpDist < minDist) { minDist = tmpDist; } dist = inc; current = PartitionPath.AdvancePoint(current, ref dist); } return(minDist); }
/// <summary> /// Gets priotiy lane determination /// </summary> /// <param name="ii"></param> /// <param name="path"></param> /// <param name="end"></param> /// <returns></returns> private Coordinates?LaneIntersectsPath(IntersectionInvolved ii, LinePath path, IArbiterWaypoint end) { ArbiterLane al = (ArbiterLane)ii.Area; LinePath.PointOnPath current = path.StartPoint; bool go = true; while (go) // && !(current.Location.DistanceTo(path.EndPoint.Location) < 0.1)) { Coordinates alClose = al.LanePath().GetClosestPoint(current.Location).Location; double alDist = alClose.DistanceTo(current.Location); if (alDist <= 0.05) { return(al.LanePath().GetClosestPoint(current.Location).Location); } if (current.Location.Equals(path.EndPoint.Location)) { go = false; } current = path.AdvancePoint(current, 0.1); } /*if (ii.Exit != null) * { * ITraversableWaypoint laneExit = ii.Exit; * foreach (ArbiterInterconnect tmpAi in laneExit.OutgoingConnections) * { * if (tmpAi.FinalGeneric.Equals(end)) * { * return tmpAi.FinalGeneric.Position; * } * } * }*/ return(null); }
public void Process(object param) { if (cancelled) { return; } DateTime start = HighResDateTime.Now; OperationalVehicleState vs = Services.StateProvider.GetVehicleState(); LinePath curBasePath = basePath; LinePath curLeftBound = leftBound; LinePath curRightBound = rightBound; // transform the base path to the current iteration CarTimestamp curTimestamp = Services.RelativePose.CurrentTimestamp; if (pathTime != curTimestamp) { RelativeTransform relTransform = Services.RelativePose.GetTransform(pathTime, curTimestamp); curBasePath = curBasePath.Transform(relTransform); curLeftBound = curLeftBound.Transform(relTransform); curRightBound = curRightBound.Transform(relTransform); } // get the distance between the zero point and the start point double distToStart = Coordinates.Zero.DistanceTo(curBasePath.GetPoint(curBasePath.StartPoint)); // get the sub-path between 5 and 25 meters ahead double startDist = TahoeParams.FL; LinePath.PointOnPath startPoint = curBasePath.AdvancePoint(curBasePath.ZeroPoint, ref startDist); double endDist = 30; LinePath.PointOnPath endPoint = curBasePath.AdvancePoint(startPoint, ref endDist); if (startDist > 0) { // we've reached the end Services.BehaviorManager.Execute(new HoldBrakeBehavior(), null, false); return; } // get the sub-path LinePath subPath = curBasePath.SubPath(startPoint, endPoint); // add (0,0) as the starting point subPath.Insert(0, new Coordinates(0, 0)); // do the same for the left, right bound startDist = TahoeParams.FL; endDist = 40; startPoint = curLeftBound.AdvancePoint(curLeftBound.ZeroPoint, startDist); endPoint = curLeftBound.AdvancePoint(startPoint, endDist); curLeftBound = curLeftBound.SubPath(startPoint, endPoint); startPoint = curRightBound.AdvancePoint(curRightBound.ZeroPoint, startDist); endPoint = curRightBound.AdvancePoint(startPoint, endDist); curRightBound = curRightBound.SubPath(startPoint, endPoint); if (cancelled) { return; } Services.UIService.PushRelativePath(subPath, curTimestamp, "subpath"); Services.UIService.PushRelativePath(curLeftBound, curTimestamp, "left bound"); Services.UIService.PushRelativePath(curRightBound, curTimestamp, "right bound"); // run a path smoothing iteration lock (this) { planner = new PathPlanner(); } //////////////////////////////////////////////////////////////////////////////////////////////////// // start of obstacle manager - hik bool obstacleManagerEnable = true; PathPlanner.SmoothingResult result; if (obstacleManagerEnable == true) { // generate fake obstacles (for simulation testing only) double obsSize = 10.5 / 2; List <Coordinates> obstaclePoints = new List <Coordinates>(); List <Obstacle> obstacleClusters = new List <Obstacle>(); // fake left obstacles (for simulation only) int totalLeftObstacles = Math.Min(0, curLeftBound.Count - 1); for (int i = 0; i < totalLeftObstacles; i++) { obstaclePoints.Clear(); obstaclePoints.Add(curLeftBound[i] + new Coordinates(obsSize, obsSize)); obstaclePoints.Add(curLeftBound[i] + new Coordinates(obsSize, -obsSize)); obstaclePoints.Add(curLeftBound[i] + new Coordinates(-obsSize, -obsSize)); obstaclePoints.Add(curLeftBound[i] + new Coordinates(-obsSize, obsSize)); obstacleClusters.Add(new Obstacle()); obstacleClusters[obstacleClusters.Count - 1].obstaclePolygon = new Polygon(obstaclePoints); } // fake right obstacles (for simulation only) int totalRightObstacles = Math.Min(0, curRightBound.Count - 1); for (int i = 0; i < totalRightObstacles; i++) { obstaclePoints.Clear(); obstaclePoints.Add(curRightBound[i] + new Coordinates(obsSize, obsSize)); obstaclePoints.Add(curRightBound[i] + new Coordinates(obsSize, -obsSize)); obstaclePoints.Add(curRightBound[i] + new Coordinates(-obsSize, -obsSize)); obstaclePoints.Add(curRightBound[i] + new Coordinates(-obsSize, obsSize)); obstacleClusters.Add(new Obstacle()); obstacleClusters[obstacleClusters.Count - 1].obstaclePolygon = new Polygon(obstaclePoints); } // fake center obstacles (for simulation only) int totalCenterObstacles = Math.Min(0, subPath.Count - 1); for (int i = 2; i < totalCenterObstacles; i++) { obstaclePoints.Clear(); obstaclePoints.Add(subPath[i] + new Coordinates(obsSize, obsSize)); obstaclePoints.Add(subPath[i] + new Coordinates(obsSize, -obsSize)); obstaclePoints.Add(subPath[i] + new Coordinates(-obsSize, -obsSize)); obstaclePoints.Add(subPath[i] + new Coordinates(-obsSize, obsSize)); obstacleClusters.Add(new Obstacle()); obstacleClusters[obstacleClusters.Count - 1].obstaclePolygon = new Polygon(obstaclePoints); } obstaclePoints.Clear(); obstaclePoints.Add(new Coordinates(10000, 10000)); obstaclePoints.Add(new Coordinates(10000, 10001)); obstaclePoints.Add(new Coordinates(10001, 10000)); obstacleClusters.Add(new Obstacle()); obstacleClusters[obstacleClusters.Count - 1].obstaclePolygon = new Polygon(obstaclePoints); obstaclePoints.Clear(); obstaclePoints.Add(new Coordinates(1000, 1000)); obstaclePoints.Add(new Coordinates(1000, 1001)); obstaclePoints.Add(new Coordinates(1001, 1000)); obstacleClusters.Add(new Obstacle()); obstacleClusters[obstacleClusters.Count - 1].obstaclePolygon = new Polygon(obstaclePoints); obstaclePoints.Clear(); obstaclePoints.Add(new Coordinates(-1000, -1000)); obstaclePoints.Add(new Coordinates(-1000, -1001)); obstaclePoints.Add(new Coordinates(-1001, -1000)); obstacleClusters.Add(new Obstacle()); obstacleClusters[obstacleClusters.Count - 1].obstaclePolygon = new Polygon(obstaclePoints); foreach (Obstacle obs in obstacleClusters) { obs.cspacePolygon = new Polygon(obs.obstaclePolygon.points); } // find obstacle path and left/right classification LinePath obstaclePath = new LinePath(); //Boolean successFlag; //double laneWidthAtPathEnd = 10.0; //#warning this currently doesn't work /*obstacleManager.ProcessObstacles(subPath, new LinePath[] { curLeftBound }, new LinePath[] { curRightBound }, * obstacleClusters, laneWidthAtPathEnd, * out obstaclePath, out successFlag); */ // prepare left and right lane bounds double laneMinSpacing = 0.1; double laneDesiredSpacing = 0.5; double laneAlphaS = 10000; List <Boundary> leftBounds = new List <Boundary>(); List <Boundary> rightBounds = new List <Boundary>(); leftBounds.Add(new Boundary(curLeftBound, laneMinSpacing, laneDesiredSpacing, laneAlphaS)); rightBounds.Add(new Boundary(curRightBound, laneMinSpacing, laneDesiredSpacing, laneAlphaS)); // sort out obstacles as left and right double obstacleMinSpacing = 0.1; double obstacleDesiredSpacing = 1.0; double obstacleAlphaS = 10000; Boundary bound; int totalObstacleClusters = obstacleClusters.Count; for (int i = 0; i < totalObstacleClusters; i++) { if (obstacleClusters[i].avoidanceStatus == AvoidanceStatus.Left) { // obstacle cluster is to the left of obstacle path bound = new Boundary(obstacleClusters[i].obstaclePolygon.points, obstacleMinSpacing, obstacleDesiredSpacing, obstacleAlphaS, true); bound.CheckFrontBumper = true; leftBounds.Add(bound); } else if (obstacleClusters[i].avoidanceStatus == AvoidanceStatus.Right) { // obstacle cluster is to the right of obstacle path bound = new Boundary(obstacleClusters[i].obstaclePolygon.points, obstacleMinSpacing, obstacleDesiredSpacing, obstacleAlphaS, true); bound.CheckFrontBumper = true; rightBounds.Add(bound); } else { // obstacle cluster is outside grid, hence ignore obstacle cluster } } Stopwatch stopwatch = new Stopwatch(); stopwatch.Start(); // PlanPath function call with obstacle path and obstacles result = planner.PlanPath(obstaclePath, obstaclePath, leftBounds, rightBounds, 0, maxSpeed, vs.speed, null, curTimestamp, false); stopwatch.Stop(); Console.WriteLine("============================================================"); Console.WriteLine("With ObstacleManager - Planner - Elapsed (ms): {0}", stopwatch.ElapsedMilliseconds); Console.WriteLine("============================================================"); } else { Stopwatch stopwatch = new Stopwatch(); stopwatch.Start(); // original PlanPath function call result = planner.PlanPath(subPath, curLeftBound, curRightBound, 0, maxSpeed, vs.speed, null, curTimestamp); stopwatch.Stop(); Console.WriteLine("============================================================"); Console.WriteLine("Without ObstacleManager - Planner - Elapsed (ms): {0}", stopwatch.ElapsedMilliseconds); Console.WriteLine("============================================================"); } // end of obstacle manager - hik //////////////////////////////////////////////////////////////////////////////////////////////////// //PathPlanner.PlanningResult result = planner.PlanPath(subPath, curLeftBound, curRightBound, 0, maxSpeed, vs.speed, null, curTimestamp); //SmoothedPath path = new SmoothedPath(pathTime); lock (this) { planner = null; } if (cancelled) { return; } if (result.result == UrbanChallenge.PathSmoothing.SmoothResult.Sucess) { // start tracking the path Services.TrackingManager.QueueCommand(TrackingCommandBuilder.GetSmoothedPathVelocityCommand(result.path)); //Services.TrackingManager.QueueCommand(TrackingCommandBuilder.GetConstantSteeringConstantSpeedCommand(-.5, 2)); /*TrackingCommand cmd = new TrackingCommand( * new FeedbackSpeedCommandGenerator(new ConstantSpeedGenerator(2, null)), * new SinSteeringCommandGenerator(), * true); * Services.TrackingManager.QueueCommand(cmd);*/ // send the path's we're tracking to the UI Services.UIService.PushRelativePath(result.path, curTimestamp, "smoothed path"); cancelled = true; } }
public static void SmoothAndTrack(LinePath basePath, bool useTargetPath, IList<LinePath> leftBounds, IList<LinePath> rightBounds, double maxSpeed, double? endingHeading, bool endingOffsetBound, CarTimestamp curTimestamp, bool doAvoidance, SpeedCommand speedCommand, CarTimestamp behaviorTimestamp, string commandLabel, ref bool cancelled, ref LinePath previousSmoothedPath, ref CarTimestamp previousSmoothedPathTimestamp, ref double? approachSpeed) { // if we're in listen mode, just return for now if (OperationalBuilder.BuildMode == BuildMode.Listen) { return; } PathPlanner.PlanningResult result; double curSpeed = Services.StateProvider.GetVehicleState().speed; LinePath targetPath = new LinePath(); double initialHeading = 0; // get the part we just used to make a prediction if (useTargetPath && previousSmoothedPath != null) { //targetPath = previousSmoothedPath.Transform(Services.RelativePose.GetTransform(previousSmoothedPathTimestamp, curTimestamp)); // interpolate the path with a smoothing spline //targetPath = targetPath.SplineInterpolate(0.05); //Services.UIService.PushRelativePath(targetPath, curTimestamp, "prediction path2"); // calculate the point speed*dt ahead /*double lookaheadDist = curSpeed*0.20; if (lookaheadDist > 0.1) { LinePath.PointOnPath pt = targetPath.AdvancePoint(targetPath.ZeroPoint, lookaheadDist); // get the heading initialHeading = targetPath.GetSegment(pt.Index).UnitVector.ArcTan; // adjust the base path start point to be the predicted location basePath[0] = pt.Location; // get the part we just used to make a prediction predictionPath = targetPath.SubPath(targetPath.ZeroPoint, pt); // push to the UI Services.UIService.PushRelativePath(predictionPath, curTimestamp, "prediction path"); //basePath[0] = new Coordinates(lookaheadDist, 0); Services.UIService.PushRelativePath(basePath, curTimestamp, "subpath2"); Services.Dataset.ItemAs<double>("initial heading").Add(initialHeading, curTimestamp); // calculate a piece of the sub path //targetPath = targetPath.SubPath(targetPath.ZeroPoint, 7); }*/ // get the tracking manager to predict stuff like whoa AbsolutePose absPose; OperationalVehicleState vehicleState; Services.TrackingManager.ForwardPredict(out absPose, out vehicleState); // insert the stuff stuff basePath[0] = absPose.xy; initialHeading = absPose.heading; // start walking down the path until the angle is cool double angle_threshold = 30*Math.PI/180.0; double dist; LinePath.PointOnPath newPoint = new LinePath.PointOnPath(); for (dist = 0; dist < 10; dist += 1) { // get the point advanced from the 2nd point on the base path by dist double distTemp = dist; newPoint = basePath.AdvancePoint(basePath.GetPointOnPath(1), ref distTemp); // check if we're past the end if (distTemp > 0) { break; } // check if the angle is coolness or not double angle = Math.Acos((newPoint.Location-basePath[0]).Normalize().Dot(basePath.GetSegment(newPoint.Index).UnitVector)); if (Math.Acos(angle) < angle_threshold) { break; } } // create a new version of the base path with the stuff section removed basePath = basePath.RemoveBetween(basePath.StartPoint, newPoint); Services.UIService.PushRelativePath(basePath, curTimestamp, "subpath2"); // zero that stuff out targetPath = new LinePath(); } StaticObstacles obstacles = null; // only do the planning is we're in a lane scenario // otherwise, the obstacle grid will be WAY too large if (doAvoidance && leftBounds.Count == 1 && rightBounds.Count == 1) { // get the obstacles predicted to the current timestamp obstacles = Services.ObstaclePipeline.GetProcessedObstacles(curTimestamp); } // start the planning timer Stopwatch planningTimer = Stopwatch.StartNew(); // check if there are any obstacles if (obstacles != null && obstacles.polygons != null && obstacles.polygons.Count > 0) { if (cancelled) return; // we need to do the full obstacle avoidance // execute the obstacle manager LinePath avoidancePath; List<ObstacleManager.ObstacleType> obstacleSideFlags; bool success; Services.ObstacleManager.ProcessObstacles(basePath, leftBounds, rightBounds, obstacles.polygons, out avoidancePath, out obstacleSideFlags, out success); // check if we have success if (success) { // build the boundary lists // start with the lanes List<Boundary> leftSmootherBounds = new List<Boundary>(); List<Boundary> rightSmootherBounds = new List<Boundary>(); double laneMinSpacing = 0.1; double laneDesiredSpacing = 0.1; double laneAlphaS = 0.1; leftSmootherBounds.Add(new Boundary(leftBounds[0], laneMinSpacing, laneDesiredSpacing, laneAlphaS)); rightSmootherBounds.Add(new Boundary(rightBounds[0], laneMinSpacing, laneDesiredSpacing, laneAlphaS)); // sort out obstacles as left and right double obstacleMinSpacing = 0.8; double obstacleDesiredSpacing = 0.8; double obstacleAlphaS = 100; int totalObstacleClusters = obstacles.polygons.Count; for (int i = 0; i < totalObstacleClusters; i++) { if (obstacleSideFlags[i] == ObstacleManager.ObstacleType.Left) { Boundary bound = new Boundary(obstacles.polygons[i], obstacleMinSpacing, obstacleDesiredSpacing, obstacleAlphaS); bound.CheckFrontBumper = true; leftSmootherBounds.Add(bound); } else if (obstacleSideFlags[i] == ObstacleManager.ObstacleType.Right) { Boundary bound = new Boundary(obstacles.polygons[i], obstacleMinSpacing, obstacleDesiredSpacing, obstacleAlphaS); bound.CheckFrontBumper = true; rightSmootherBounds.Add(bound); } } if (cancelled) return; // execute the smoothing PathPlanner planner = new PathPlanner(); planner.Options.alpha_w = 0; planner.Options.alpha_d = 10; planner.Options.alpha_c = 10; result = planner.PlanPath(avoidancePath, targetPath, leftSmootherBounds, rightSmootherBounds, initialHeading, maxSpeed, Services.StateProvider.GetVehicleState().speed, endingHeading, curTimestamp, endingOffsetBound); } else { // mark that we did not succeed result = new PathPlanner.PlanningResult(SmoothResult.Infeasible, null); } } else { if (cancelled) return; // do the path smoothing PathPlanner planner = new PathPlanner(); List<LineList> leftList = new List<LineList>(); foreach (LinePath ll in leftBounds) leftList.Add(ll); List<LineList> rightList = new List<LineList>(); foreach (LinePath rl in rightBounds) rightList.Add(rl); planner.Options.alpha_w = 0; planner.Options.alpha_s = 0.1; planner.Options.alpha_d = 10; planner.Options.alpha_c = 10; result = planner.PlanPath(basePath, targetPath, leftList, rightList, initialHeading, maxSpeed, Services.StateProvider.GetVehicleState().speed, endingHeading, curTimestamp, endingOffsetBound); } planningTimer.Stop(); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "planning took {0} ms", planningTimer.ElapsedMilliseconds); Services.Dataset.ItemAs<bool>("route feasible").Add(result.result == SmoothResult.Sucess, LocalCarTimeProvider.LocalNow); if (result.result == SmoothResult.Sucess) { // insert the point (-1,0) so we make sure that the zero point during tracking is at the vehicle //Coordinates startingVec = result.path[1].Point-result.path[0].Point; //Coordinates insertPoint = result.path[0].Point-startingVec.Normalize(); //result.path.Insert(0, new OperationalLayer.PathPlanning.PathPoint(insertPoint, maxSpeed)); previousSmoothedPath = new LinePath(result.path); previousSmoothedPathTimestamp = curTimestamp; Services.UIService.PushLineList(previousSmoothedPath, curTimestamp, "smoothed path", true); if (cancelled) return; // we've planned out the path, now build up the command ISpeedGenerator speedGenerator; if (speedCommand is ScalarSpeedCommand) { /*if (result.path.HasSpeeds) { speedGenerator = result.path; } else {*/ speedGenerator = new ConstantSpeedGenerator(maxSpeed, null); //} } else if (speedCommand is StopAtDistSpeedCommand) { StopAtDistSpeedCommand stopCommand = (StopAtDistSpeedCommand)speedCommand; IDistanceProvider distProvider = new TravelledDistanceProvider(behaviorTimestamp, stopCommand.Distance); speedGenerator = new StopSpeedGenerator(distProvider, approachSpeed.Value); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "stay in lane - remaining stop stop dist {0}", distProvider.GetRemainingDistance()); } else if (speedCommand is StopAtLineSpeedCommand) { IDistanceProvider distProvider = new StoplineDistanceProvider(); speedGenerator = new StopSpeedGenerator(distProvider, approachSpeed.Value); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "stay in lane - remaining stop stop dist {0}", distProvider.GetRemainingDistance()); } else if (speedCommand == null) { throw new InvalidOperationException("Speed command is null"); } else { throw new InvalidOperationException("Speed command " + speedCommand.GetType().FullName + " is not supported"); } if (cancelled) return; // build up the command TrackingCommand trackingCommand = new TrackingCommand(new FeedbackSpeedCommandGenerator(speedGenerator), new PathSteeringCommandGenerator(result.path), false); trackingCommand.Label = commandLabel; // queue it to execute Services.TrackingManager.QueueCommand(trackingCommand); } }
public Coordinates[] VehiclePoints(SimVehicleState svs) { Polygon p = VehiclePolygon(svs); LinePath lp = new LinePath(p); LinePath.PointOnPath c = lp.StartPoint; List<Coordinates> cs = new List<Coordinates>(); while (!c.Equals(lp.EndPoint)) { cs.Add(lp.GetPoint(c)); c = lp.AdvancePoint(c, 0.1); } return cs.ToArray(); }
public static Polygon PartitionPolygon(ArbiterLanePartition alp) { if (alp.Initial.PreviousPartition != null && alp.Final.NextPartition != null && alp.Length < 30.0 && alp.Length > 4.0) { // get partition turn direction ArbiterTurnDirection pTD = PartitionTurnDirection(alp); // check if angles of previous and next are such that not straight through if (pTD != ArbiterTurnDirection.Straight) { // get partition poly ArbiterInterconnect tmpAi = alp.ToInterconnect; tmpAi.TurnDirection = pTD; GenerateInterconnectPolygon(tmpAi); Polygon pPoly = tmpAi.TurnPolygon; // here is default partition polygon LinePath alplb = alp.PartitionPath.ShiftLateral(-alp.Lane.Width / 2.0); LinePath alprb = alp.PartitionPath.ShiftLateral(alp.Lane.Width / 2.0); alprb.Reverse(); List <Coordinates> alpdefaultPoly = alplb; alpdefaultPoly.AddRange(alprb); // get full poly pPoly.AddRange(alpdefaultPoly); pPoly = Polygon.GrahamScan(pPoly); return(pPoly); } } else if (alp.Length >= 30) { Polygon pBase = GenerateSimplePartitionPolygon(alp, alp.PartitionPath, alp.Lane.Width); if (alp.Initial.PreviousPartition != null && Math.Abs(FinalIntersectionAngle(alp.Initial.PreviousPartition)) > 15) { // initial portion Coordinates i1 = alp.Initial.Position - alp.Initial.PreviousPartition.Vector().Normalize(15.0); Coordinates i2 = alp.Initial.Position; Coordinates i3 = i2 + alp.Vector().Normalize(15.0); LinePath il12 = new LinePath(new Coordinates[] { i1, i2 }); LinePath il23 = new LinePath(new Coordinates[] { i2, i3 }); LinePath il13 = new LinePath(new Coordinates[] { i1, i3 }); Coordinates iCC = il13.GetClosestPoint(i2).Location; if (GeneralToolkit.TriangleArea(i1, i2, i3) < 0) { il13 = il13.ShiftLateral(iCC.DistanceTo(i2) + alp.Lane.Width / 2.0); } else { il13 = il13.ShiftLateral(-iCC.DistanceTo(i2) + alp.Lane.Width / 2.0); } LinePath.PointOnPath iCCP = il13.GetClosestPoint(iCC); iCCP = il13.AdvancePoint(iCCP, -10.0); il13 = il13.SubPath(iCCP, 20.0); Polygon iBase = GenerateSimplePolygon(il23, alp.Lane.Width); iBase.Add(il13[1]); Polygon iP = Polygon.GrahamScan(iBase); pBase = PolygonToolkit.PolygonUnion(new List <Polygon>(new Polygon[] { pBase, iP })); } if (alp.Final.NextPartition != null && Math.Abs(FinalIntersectionAngle(alp)) > 15) { // initial portion Coordinates i1 = alp.Final.Position - alp.Vector().Normalize(15.0); Coordinates i2 = alp.Final.Position; Coordinates i3 = i2 + alp.Final.NextPartition.Vector().Normalize(15.0); LinePath il12 = new LinePath(new Coordinates[] { i1, i2 }); LinePath il23 = new LinePath(new Coordinates[] { i2, i3 }); LinePath il13 = new LinePath(new Coordinates[] { i1, i3 }); Coordinates iCC = il13.GetClosestPoint(i2).Location; if (GeneralToolkit.TriangleArea(i1, i2, i3) < 0) { il13 = il13.ShiftLateral(iCC.DistanceTo(i2) + alp.Lane.Width / 2.0); } else { il13 = il13.ShiftLateral(-iCC.DistanceTo(i2) + alp.Lane.Width / 2.0); } LinePath.PointOnPath iCCP = il13.GetClosestPoint(iCC); iCCP = il13.AdvancePoint(iCCP, -10.0); il13 = il13.SubPath(iCCP, 20.0); Polygon iBase = GenerateSimplePolygon(il12, alp.Lane.Width); iBase.Add(il13[0]); Polygon iP = Polygon.GrahamScan(iBase); pBase = PolygonToolkit.PolygonUnion(new List <Polygon>(new Polygon[] { pBase, iP })); } return(pBase); } // fall out return(null); }
public static void SmoothAndTrack(LinePath basePath, bool useTargetPath, IList <LinePath> leftBounds, IList <LinePath> rightBounds, double maxSpeed, double?endingHeading, bool endingOffsetBound, CarTimestamp curTimestamp, bool doAvoidance, SpeedCommand speedCommand, CarTimestamp behaviorTimestamp, string commandLabel, ref bool cancelled, ref LinePath previousSmoothedPath, ref CarTimestamp previousSmoothedPathTimestamp, ref double?approachSpeed) { // if we're in listen mode, just return for now if (OperationalBuilder.BuildMode == BuildMode.Listen) { return; } PathPlanner.PlanningResult result; double curSpeed = Services.StateProvider.GetVehicleState().speed; LinePath targetPath = new LinePath(); double initialHeading = 0; // get the part we just used to make a prediction if (useTargetPath && previousSmoothedPath != null) { //targetPath = previousSmoothedPath.Transform(Services.RelativePose.GetTransform(previousSmoothedPathTimestamp, curTimestamp)); // interpolate the path with a smoothing spline //targetPath = targetPath.SplineInterpolate(0.05); //Services.UIService.PushRelativePath(targetPath, curTimestamp, "prediction path2"); // calculate the point speed*dt ahead /*double lookaheadDist = curSpeed*0.20; * if (lookaheadDist > 0.1) { * LinePath.PointOnPath pt = targetPath.AdvancePoint(targetPath.ZeroPoint, lookaheadDist); * // get the heading * initialHeading = targetPath.GetSegment(pt.Index).UnitVector.ArcTan; * // adjust the base path start point to be the predicted location * basePath[0] = pt.Location; * * // get the part we just used to make a prediction * predictionPath = targetPath.SubPath(targetPath.ZeroPoint, pt); * // push to the UI * Services.UIService.PushRelativePath(predictionPath, curTimestamp, "prediction path"); * //basePath[0] = new Coordinates(lookaheadDist, 0); * Services.UIService.PushRelativePath(basePath, curTimestamp, "subpath2"); * Services.Dataset.ItemAs<double>("initial heading").Add(initialHeading, curTimestamp); * // calculate a piece of the sub path * //targetPath = targetPath.SubPath(targetPath.ZeroPoint, 7); * }*/ // get the tracking manager to predict stuff like whoa AbsolutePose absPose; OperationalVehicleState vehicleState; Services.TrackingManager.ForwardPredict(out absPose, out vehicleState); // insert the stuff stuff basePath[0] = absPose.xy; initialHeading = absPose.heading; // start walking down the path until the angle is cool double angle_threshold = 30 * Math.PI / 180.0; double dist; LinePath.PointOnPath newPoint = new LinePath.PointOnPath(); for (dist = 0; dist < 10; dist += 1) { // get the point advanced from the 2nd point on the base path by dist double distTemp = dist; newPoint = basePath.AdvancePoint(basePath.GetPointOnPath(1), ref distTemp); // check if we're past the end if (distTemp > 0) { break; } // check if the angle is coolness or not double angle = Math.Acos((newPoint.Location - basePath[0]).Normalize().Dot(basePath.GetSegment(newPoint.Index).UnitVector)); if (Math.Acos(angle) < angle_threshold) { break; } } // create a new version of the base path with the stuff section removed basePath = basePath.RemoveBetween(basePath.StartPoint, newPoint); Services.UIService.PushRelativePath(basePath, curTimestamp, "subpath2"); // zero that stuff out targetPath = new LinePath(); } StaticObstacles obstacles = null; // only do the planning is we're in a lane scenario // otherwise, the obstacle grid will be WAY too large if (doAvoidance && leftBounds.Count == 1 && rightBounds.Count == 1) { // get the obstacles predicted to the current timestamp obstacles = Services.ObstaclePipeline.GetProcessedObstacles(curTimestamp); } // start the planning timer Stopwatch planningTimer = Stopwatch.StartNew(); // check if there are any obstacles if (obstacles != null && obstacles.polygons != null && obstacles.polygons.Count > 0) { if (cancelled) { return; } // we need to do the full obstacle avoidance // execute the obstacle manager LinePath avoidancePath; List <ObstacleManager.ObstacleType> obstacleSideFlags; bool success; Services.ObstacleManager.ProcessObstacles(basePath, leftBounds, rightBounds, obstacles.polygons, out avoidancePath, out obstacleSideFlags, out success); // check if we have success if (success) { // build the boundary lists // start with the lanes List <Boundary> leftSmootherBounds = new List <Boundary>(); List <Boundary> rightSmootherBounds = new List <Boundary>(); double laneMinSpacing = 0.1; double laneDesiredSpacing = 0.1; double laneAlphaS = 0.1; leftSmootherBounds.Add(new Boundary(leftBounds[0], laneMinSpacing, laneDesiredSpacing, laneAlphaS)); rightSmootherBounds.Add(new Boundary(rightBounds[0], laneMinSpacing, laneDesiredSpacing, laneAlphaS)); // sort out obstacles as left and right double obstacleMinSpacing = 0.8; double obstacleDesiredSpacing = 0.8; double obstacleAlphaS = 100; int totalObstacleClusters = obstacles.polygons.Count; for (int i = 0; i < totalObstacleClusters; i++) { if (obstacleSideFlags[i] == ObstacleManager.ObstacleType.Left) { Boundary bound = new Boundary(obstacles.polygons[i], obstacleMinSpacing, obstacleDesiredSpacing, obstacleAlphaS); bound.CheckFrontBumper = true; leftSmootherBounds.Add(bound); } else if (obstacleSideFlags[i] == ObstacleManager.ObstacleType.Right) { Boundary bound = new Boundary(obstacles.polygons[i], obstacleMinSpacing, obstacleDesiredSpacing, obstacleAlphaS); bound.CheckFrontBumper = true; rightSmootherBounds.Add(bound); } } if (cancelled) { return; } // execute the smoothing PathPlanner planner = new PathPlanner(); planner.Options.alpha_w = 0; planner.Options.alpha_d = 10; planner.Options.alpha_c = 10; result = planner.PlanPath(avoidancePath, targetPath, leftSmootherBounds, rightSmootherBounds, initialHeading, maxSpeed, Services.StateProvider.GetVehicleState().speed, endingHeading, curTimestamp, endingOffsetBound); } else { // mark that we did not succeed result = new PathPlanner.PlanningResult(SmoothResult.Infeasible, null); } } else { if (cancelled) { return; } // do the path smoothing PathPlanner planner = new PathPlanner(); List <LineList> leftList = new List <LineList>(); foreach (LinePath ll in leftBounds) { leftList.Add(ll); } List <LineList> rightList = new List <LineList>(); foreach (LinePath rl in rightBounds) { rightList.Add(rl); } planner.Options.alpha_w = 0; planner.Options.alpha_s = 0.1; planner.Options.alpha_d = 10; planner.Options.alpha_c = 10; result = planner.PlanPath(basePath, targetPath, leftList, rightList, initialHeading, maxSpeed, Services.StateProvider.GetVehicleState().speed, endingHeading, curTimestamp, endingOffsetBound); } planningTimer.Stop(); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "planning took {0} ms", planningTimer.ElapsedMilliseconds); Services.Dataset.ItemAs <bool>("route feasible").Add(result.result == SmoothResult.Sucess, LocalCarTimeProvider.LocalNow); if (result.result == SmoothResult.Sucess) { // insert the point (-1,0) so we make sure that the zero point during tracking is at the vehicle //Coordinates startingVec = result.path[1].Point-result.path[0].Point; //Coordinates insertPoint = result.path[0].Point-startingVec.Normalize(); //result.path.Insert(0, new OperationalLayer.PathPlanning.PathPoint(insertPoint, maxSpeed)); previousSmoothedPath = new LinePath(result.path); previousSmoothedPathTimestamp = curTimestamp; Services.UIService.PushLineList(previousSmoothedPath, curTimestamp, "smoothed path", true); if (cancelled) { return; } // we've planned out the path, now build up the command ISpeedGenerator speedGenerator; if (speedCommand is ScalarSpeedCommand) { /*if (result.path.HasSpeeds) { * speedGenerator = result.path; * } * else {*/ speedGenerator = new ConstantSpeedGenerator(maxSpeed, null); //} } else if (speedCommand is StopAtDistSpeedCommand) { StopAtDistSpeedCommand stopCommand = (StopAtDistSpeedCommand)speedCommand; IDistanceProvider distProvider = new TravelledDistanceProvider(behaviorTimestamp, stopCommand.Distance); speedGenerator = new StopSpeedGenerator(distProvider, approachSpeed.Value); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "stay in lane - remaining stop stop dist {0}", distProvider.GetRemainingDistance()); } else if (speedCommand is StopAtLineSpeedCommand) { IDistanceProvider distProvider = new StoplineDistanceProvider(); speedGenerator = new StopSpeedGenerator(distProvider, approachSpeed.Value); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "stay in lane - remaining stop stop dist {0}", distProvider.GetRemainingDistance()); } else if (speedCommand == null) { throw new InvalidOperationException("Speed command is null"); } else { throw new InvalidOperationException("Speed command " + speedCommand.GetType().FullName + " is not supported"); } if (cancelled) { return; } // build up the command TrackingCommand trackingCommand = new TrackingCommand(new FeedbackSpeedCommandGenerator(speedGenerator), new PathSteeringCommandGenerator(result.path), false); trackingCommand.Label = commandLabel; // queue it to execute Services.TrackingManager.QueueCommand(trackingCommand); } }
private PlanningPhase PlanStartingLane(LinePath curStartingLane, LinePath curEndingLane) { ILaneModel startingLaneModel = Services.RoadModelProvider.GetLaneModel(curStartingLane, startingLaneWidth + extraWidth, curTimestamp, startingLanesLeft, startingLanesRight); // figure out where we are along the starting lane path LinePath.PointOnPath startingLanePoint = curStartingLane.ZeroPoint; // calculate the planning distance double planningDistance = GetPlanningDistance(); if (sparse && planningDistance > 10) { planningDistance = 10; } // get the distance to the end point of the lane from our current point double remainingDistance = curStartingLane.DistanceBetween(startingLanePoint, curStartingLane.EndPoint); double? boundStartDistMin; double? boundEndDistMax; DetermineSparseStarting(planningDistance, out boundStartDistMin, out boundEndDistMax); double avoidanceExtra = sparse ? 5 : 7.5; // linearize the lane model LinePath centerLine, leftBound, rightBound; if (boundEndDistMax != null || boundStartDistMin != null) { if (boundEndDistMax != null) { boundEndDistMax = Math.Min(boundEndDistMax.Value, remainingDistance - starting_lane_trim_dist); } else { boundEndDistMax = remainingDistance - starting_lane_trim_dist; } LinearizeStayInLane(startingLaneModel, planningDistance + avoidanceExtra, null, boundEndDistMax, boundStartDistMin, null, curTimestamp, out centerLine, out leftBound, out rightBound); } else { LinearizeStayInLane(startingLaneModel, planningDistance + avoidanceExtra, null, remainingDistance - starting_lane_trim_dist, null, curTimestamp, out centerLine, out leftBound, out rightBound); } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in stay in lane, center line count: {0}, left bound count: {1}, right bound count: {2}", centerLine.Count, leftBound.Count, rightBound.Count); // add to the planning setup avoidanceBasePath = centerLine; double targetDist = Math.Max(centerLine.PathLength-avoidanceExtra, planningDistance); smootherBasePath = centerLine.SubPath(centerLine.StartPoint, targetDist); // calculate time to collision of opposing obstacle if it exists LinePath targetLine = centerLine; double targetWeight = default_lane_alpha_w; if (sparse) { targetWeight = 0.00000025; } else if (oncomingVehicleExists) { double shiftDist = -(TahoeParams.T + 1); targetLine = centerLine.ShiftLateral(shiftDist); targetWeight = 0.01; } else if (opposingLaneVehicleExists) { double timeToCollision = opposingLaneVehicleDist/(Math.Abs(vs.speed)+Math.Abs(opposingLaneVehicleSpeed)); Services.Dataset.ItemAs<double>("time to collision").Add(timeToCollision, curTimestamp); if (timeToCollision < 5) { // shift to the right double laneWidth = startingLaneModel.Width; double shiftDist = -Math.Min(TahoeParams.T/2.0, laneWidth/2.0 - TahoeParams.T/2.0); targetLine = centerLine.ShiftLateral(shiftDist); } } // set up the planning AddTargetPath(targetLine, targetWeight); if (!sparse || boundStartDistMin != null || boundEndDistMax != null) { // add the lane bounds AddLeftBound(leftBound, true); if (!oncomingVehicleExists) { AddRightBound(rightBound, false); } } Services.UIService.PushLineList(centerLine, curTimestamp, "subpath", true); Services.UIService.PushLineList(leftBound, curTimestamp, "left bound", true); Services.UIService.PushLineList(rightBound, curTimestamp, "right bound", true); // calculate max speed for the path over the next 120 meters double advanceDist = speed_path_advance_dist; LinePath.PointOnPath startingLaneEndPoint = curStartingLane.AdvancePoint(startingLanePoint, ref advanceDist); LinePath combinedPath = curStartingLane.SubPath(startingLanePoint, startingLaneEndPoint); Coordinates endingLaneFirstPoint = curEndingLane[0]; Coordinates startingLaneLastPoint = curStartingLane.EndPoint.Location; double intersectionDist = startingLaneLastPoint.DistanceTo(endingLaneFirstPoint); // add a portion of the ending lane of the appropriate length LinePath.PointOnPath endingLanePoint = curEndingLane.AdvancePoint(curEndingLane.StartPoint, Math.Max(advanceDist - intersectionDist, 5)); int endIndex = endingLanePoint.Index + 1; combinedPath.AddRange(curEndingLane.GetSubpathEnumerator(0, endIndex)); // add to the planning setup settings.maxSpeed = GetMaxSpeed(combinedPath, combinedPath.StartPoint); settings.maxEndingSpeed = GetMaxSpeed(combinedPath, combinedPath.AdvancePoint(combinedPath.StartPoint, planningDistance)); if (sparse) { // limit to 5 mph laneWidthAtPathEnd = 20; pathAngleCheckMax = 50; pathAngleMax = 5 * Math.PI / 180.0; settings.maxSpeed = Math.Min(settings.maxSpeed, 2.2352); LinePath leftEdge = RoadEdge.GetLeftEdgeLine(); LinePath rightEdge = RoadEdge.GetRightEdgeLine(); if (leftEdge != null) { leftLaneBounds.Add(new Boundary(leftEdge, 0.1, 1, 100, false)); } if (rightEdge != null) { rightLaneBounds.Add(new Boundary(rightEdge, 0.1, 1, 100, false)); } maxAvoidanceBasePathAdvancePoint = avoidanceBasePath.AdvancePoint(avoidanceBasePath.EndPoint, -2); //maxSmootherBasePathAdvancePoint = smootherBasePath.AdvancePoint(smootherBasePath.EndPoint, -2); PlanningResult result = new PlanningResult(); ISteeringCommandGenerator commandGenerator = SparseArcVoting.SparcVote(ref prevCurvature, goalPoint); if (commandGenerator == null) { // we have a block, report dynamically infeasible result = OnDynamicallyInfeasible(null, null); } else { result.steeringCommandGenerator = commandGenerator; result.commandLabel = commandLabel; } Track(result, commandLabel); if (planningDistance > remainingDistance) { return PlanningPhase.BeginEnteringTurn; } else { return PlanningPhase.StartingLane; } } else if (oncomingVehicleExists) { laneWidthAtPathEnd = 10; } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "max speed set to {0}", settings.maxSpeed); SmoothAndTrack(commandLabel, true); if (cancelled) return PlanningPhase.StartingLane; // check if we need to transition to the turn phase for the next iteration // if the planning distance is greater than the remaining distance, i.e. we want to plan into the intersection, then // we want to partially run the turn behavior next iteration if (planningDistance > remainingDistance) { return PlanningPhase.BeginEnteringTurn; } else { return PlanningPhase.StartingLane; } }
private ILaneModel GetLaneModel(LocalLaneModel laneModel, LinePath rndfPath, double rndfPathWidth, CarTimestamp rndfPathTimestamp) { // check the lane model probability if (laneModel.Probability < lane_probability_reject_threshold) { // we're rejecting this, just return a path lane model return new PathLaneModel(rndfPathTimestamp, rndfPath, rndfPathWidth); } // project the lane model's path into the rndf path's timestamp RelativeTransform relTransform = Services.RelativePose.GetTransform(localRoadModel.Timestamp, rndfPathTimestamp); LinePath laneModelPath = laneModel.LanePath.Transform(relTransform); // iterate through the waypoints in the RNDF path and project onto the lane model // the first one that is over the threshold, we consider the waypoint before as a potential ending point LinePath.PointOnPath laneModelDeviationEndPoint = new LinePath.PointOnPath(); // flag indicating if any of the waypoint tests failed because of the devation was too high bool anyDeviationTooHigh = false; // number of waypoints accepted int numWaypointsAccepted = 0; // get the vehicle's position on the rndf path LinePath.PointOnPath rndfZeroPoint = rndfPath.ZeroPoint; // get the vehicle's position on the lane model LinePath.PointOnPath laneModelZeroPoint = laneModelPath.ZeroPoint; // get the last point we want to consider on the lane model LinePath.PointOnPath laneModelFarthestPoint = laneModelPath.AdvancePoint(laneModelZeroPoint, lane_model_max_dist); // start walking forward through the waypoints on the rndf path // this loop will implicitly exit when we're past the end of the lane model as the waypoints // will stop being close to the lane model (GetClosestPoint returns the end point if we're past the // end of the path) for (int i = rndfZeroPoint.Index+1; i < rndfPath.Count; i++) { // get the waypoint Coordinates rndfWaypoint = rndfPath[i]; // get the closest point on the lane model LinePath.PointOnPath laneModelClosestPoint = laneModelPath.GetClosestPoint(rndfWaypoint); // compute the distance between the two double deviation = rndfWaypoint.DistanceTo(laneModelClosestPoint.Location); // if this is above the deviation threshold, leave the loop if (deviation > lane_deviation_reject_threshold || laneModelClosestPoint > laneModelFarthestPoint) { // if we're at the end of the lane model path, we don't want to consider this a rejection if (laneModelClosestPoint < laneModelFarthestPoint) { // mark that at least on deviation was too high anyDeviationTooHigh = true; } break; } // increment the number of waypoint accepted numWaypointsAccepted++; // update the end point of where we're valid as the local road model was OK up to this point laneModelDeviationEndPoint = laneModelClosestPoint; } // go through and figure out how far out the variance is within tolerance LinePath.PointOnPath laneModelVarianceEndPoint = new LinePath.PointOnPath(); // walk forward from this point until the end of the lane mode path for (int i = laneModelZeroPoint.Index+1; i < laneModelPath.Count; i++) { // check if we're within the variance toleration if (laneModel.LaneYVariance[i] <= y_var_reject_threshold) { // we are, update the point on path laneModelVarianceEndPoint = laneModelPath.GetPointOnPath(i); } else { // we are out of tolerance, break out of the loop break; } } // now figure out everything out // determine waypoint rejection status WaypointRejectionResult waypointRejectionResult; if (laneModelDeviationEndPoint.Valid) { // if the point is valid, that we had at least one waypoint that was ok // check if any waypoints were rejected if (anyDeviationTooHigh) { // some waypoint was ok, so we know that at least one waypoint was accepted waypointRejectionResult = WaypointRejectionResult.SomeWaypointsAccepted; } else { // no waypoint triggered a rejection, but at least one was good waypointRejectionResult = WaypointRejectionResult.AllWaypointsAccepted; } } else { // the point is not valid, so we either had no waypoints or we had all rejections if (anyDeviationTooHigh) { // the first waypoint was rejected, so all are rejected waypointRejectionResult = WaypointRejectionResult.AllWaypointsRejected; } else { // the first waypoint (if any) was past the end of the lane model waypointRejectionResult = WaypointRejectionResult.NoWaypoints; } } // criteria for determining if this path is valid: // - if some or all waypoints were accepted, than this is probably a good path // - if some of the waypoints were accepted, we go no farther than the last waypoint that was accepted // - if there were no waypoints, this is a potentially dangerous situation since we can't reject // or confirm the local road model. for now, we'll assume that it is correct but this may need to change // if we start handling intersections in this framework // - if all waypoints were rejected, than we don't use the local road model // - go no farther than the laneModelVarianceEndPoint, which is the last point where the y-variance of // the lane model was in tolerance // now build out the lane model ILaneModel finalLaneModel; // check if we rejected all waypoints or no lane model points satisified the variance threshold if (waypointRejectionResult == WaypointRejectionResult.AllWaypointsRejected || !laneModelVarianceEndPoint.Valid) { // want to just use the path lane model finalLaneModel = new PathLaneModel(rndfPathTimestamp, rndfPath, rndfPathWidth); } else { // we'll use the lane model // need to build up the center line as well as left and right bounds // to build up the center line, use the lane model as far as we feel comfortable (limited by either variance // or by rejections) and then use the rndf lane after that. LinePath centerLine = new LinePath(); // figure out the max distance // if there were no waypoints, set the laneModelDeviationEndPoint to the end of the lane model if (waypointRejectionResult == WaypointRejectionResult.NoWaypoints) { laneModelDeviationEndPoint = laneModelFarthestPoint; } // figure out the closer of the end points LinePath.PointOnPath laneModelEndPoint = (laneModelDeviationEndPoint < laneModelVarianceEndPoint) ? laneModelDeviationEndPoint : laneModelVarianceEndPoint; bool endAtWaypoint = laneModelEndPoint == laneModelDeviationEndPoint; // add the lane model to the center line centerLine.AddRange(laneModelPath.GetSubpathEnumerator(laneModelZeroPoint, laneModelEndPoint)); // create a list to hold the width expansion values List<double> widthValue = new List<double>(); // make the width expansion values the width of the path plus the 1-sigma values for (int i = laneModelZeroPoint.Index; i < laneModelZeroPoint.Index+centerLine.Count; i++) { widthValue.Add(laneModel.Width/2.0 + Math.Sqrt(laneModel.LaneYVariance[i])); } // now figure out how to add the rndf path // get the projection of the lane model end point on the rndf path LinePath.PointOnPath rndfPathStartPoint = rndfPath.GetClosestPoint(laneModelEndPoint.Location); // if the closest point is past the end of rndf path, then we don't want to tack anything on if (rndfPathStartPoint != rndfPath.EndPoint) { // get the last segment of the new center line Coordinates centerLineEndSegmentVec = centerLine.EndSegment.UnitVector; // get the last point of the new center line Coordinates laneModelEndLoc = laneModelEndPoint.Location; // now figure out the distance to the next waypoint LinePath.PointOnPath rndfNextPoint = new LinePath.PointOnPath(); // figure out if we're ending at a waypoint or not if (endAtWaypoint) { rndfNextPoint = rndfPath.GetPointOnPath(rndfPathStartPoint.Index+1); // if the distance from the start point to the next point is less than rndf_dist_min, then // use the waypont after double dist = rndfPath.DistanceBetween(rndfPathStartPoint, rndfNextPoint); if (dist < rndf_dist_min) { if (rndfPathStartPoint.Index < rndfPath.Count-2) { rndfNextPoint = rndfPath.GetPointOnPath(rndfPathStartPoint.Index + 2); } else if (rndfPath.DistanceBetween(rndfPathStartPoint, rndfPath.EndPoint) < rndf_dist_min) { rndfNextPoint = LinePath.PointOnPath.Invalid; } else { rndfNextPoint = rndfPath.AdvancePoint(rndfPathStartPoint, rndf_dist_min*2); } } } else { // track the last angle we had double lastAngle = double.NaN; // walk down the rndf path until we find a valid point for (double dist = rndf_dist_min; dist <= rndf_dist_max; dist += rndf_dist_step) { // advance from the start point by dist double distTemp = dist; rndfNextPoint = rndfPath.AdvancePoint(rndfPathStartPoint, ref distTemp); // if the distTemp is > 0, then we're past the end of the path if (distTemp > 0) { // if we're immediately past the end, we don't want to tack anything on if (dist == rndf_dist_min) { rndfNextPoint = LinePath.PointOnPath.Invalid; } break; } // check the angle made by the last segment of center line and the segment // formed between the end point of the center line and this new point double angle = Math.Acos(centerLineEndSegmentVec.Dot((rndfNextPoint.Location-laneModelEndLoc).Normalize())); // check if the angle satisfies the threshold or we're increasing the angle if (Math.Abs(angle) < rndf_angle_threshold || (!double.IsNaN(lastAngle) && angle > lastAngle)) { // break out of the loop, we're done searching break; } lastAngle = angle; } } // tack on the rndf starting at next point going to the end if (rndfNextPoint.Valid) { LinePath subPath = rndfPath.SubPath(rndfNextPoint, rndfPath.EndPoint); centerLine.AddRange(subPath); // insert the lane model end point into the sub path subPath.Insert(0, laneModelEndLoc); // get the angles List<Pair<int, double>> angles = subPath.GetIntersectionAngles(0, subPath.Count-1); // add the width of the path inflated by the angles for (int i = 0; i < angles.Count; i++) { // calculate the width expansion factor // 90 deg, 3x width // 45 deg, 1.5x width // 0 deg, 1x width double widthFactor = Math.Pow(angles[i].Right/(Math.PI/2.0), 2)*2 + 1; // add the width value widthValue.Add(widthFactor*laneModel.Width/2); } // add the final width widthValue.Add(laneModel.Width/2); } // set the rndf path start point to be the point we used rndfPathStartPoint = rndfNextPoint; } // for now, calculate the left and right bounds the same way we do for the path lane model // TODO: figure out if we want to do this more intelligently using knowledge of the lane model uncertainty LinePath leftBound = centerLine.ShiftLateral(widthValue.ToArray()); // get the next shifts for (int i = 0; i < widthValue.Count; i++) { widthValue[i] = -widthValue[i]; } LinePath rightBound = centerLine.ShiftLateral(widthValue.ToArray()); // build the final lane model finalLaneModel = new CombinedLaneModel(centerLine, leftBound, rightBound, laneModel.Width, rndfPathTimestamp); } SendLaneModelToUI(finalLaneModel, rndfPathTimestamp); // output the fit result return finalLaneModel; }
private PlanningPhase PlanEnteringTurn(LinePath curStartingLane, LinePath curEndingLane) { // figure out where we are along the starting lane path LinePath.PointOnPath startingLanePoint = curStartingLane.ZeroPoint; // get the distance to the end point of the lane from our current point double remainingDistance = curStartingLane.DistanceBetween(startingLanePoint, curStartingLane.EndPoint); // immediately switch to the mid turn mode if the remaining distance is less than the front-length // this prevents problems with the lane linearization extending out past the end of the lane if (remainingDistance < TahoeParams.FL) { return PlanMidTurn(curStartingLane, curEndingLane); } // get the lane mode for the starting lane ILaneModel startingLaneModel = Services.RoadModelProvider.GetLaneModel(curStartingLane, startingLaneWidth + extraWidth, curTimestamp, startingLanesLeft, startingLanesRight); double? boundStartDistMin; double? boundEndDistMax; DetermineSparseStarting(remainingDistance - starting_lane_trim_dist, out boundStartDistMin, out boundEndDistMax); // linearize the lane model LinePath centerLine, leftBound, rightBound; if (boundEndDistMax != null || boundStartDistMin != null) { if (boundEndDistMax != null) { boundEndDistMax = Math.Min(boundEndDistMax.Value, remainingDistance - starting_lane_trim_dist); } else { boundEndDistMax = remainingDistance - starting_lane_trim_dist; } LinearizeStayInLane(startingLaneModel, remainingDistance, 0, boundEndDistMax, boundStartDistMin, null, curTimestamp, out centerLine, out leftBound, out rightBound); } else { LinearizeStayInLane(startingLaneModel, remainingDistance, 0, remainingDistance - starting_lane_trim_dist, null, curTimestamp, out centerLine, out leftBound, out rightBound); } // create a copy so when we add to the center line later we don't change this version LinePath startingCenterLine = centerLine.Clone(); // calculate time to collision of opposing obstacle if it exists LinePath targetLine = startingCenterLine; double targetWeight = default_lane_alpha_w; if (oncomingVehicleExists) { double shiftDist = -(TahoeParams.T + 1); targetLine = centerLine.ShiftLateral(shiftDist); targetWeight = 0.01; } if (opposingLaneVehicleExists) { double timeToCollision = opposingLaneVehicleDist/(Math.Abs(vs.speed)+Math.Abs(opposingLaneVehicleSpeed)); Services.Dataset.ItemAs<double>("time to collision").Add(timeToCollision, curTimestamp); if (timeToCollision < 5) { // shift to the right double laneWidth = startingLaneModel.Width; double shiftDist = -Math.Min(TahoeParams.T/2.0, laneWidth/2.0 - TahoeParams.T/2.0); targetLine = centerLine.ShiftLateral(shiftDist); } } // set up the planning AddTargetPath(targetLine, targetWeight); // add the lane bounds if (!sparse || boundStartDistMin != null || boundEndDistMax != null) { // add the lane bounds AddLeftBound(leftBound, true); if (!oncomingVehicleExists) { AddRightBound(rightBound, false); } } LinePath endingCenterLine, endingLeftBound, endingRightBound; LinearizeLane(curEndingLane, endingLaneWidth, 0, 5, 2, 6, out endingCenterLine, out endingLeftBound, out endingRightBound); // add the ending lane center line to the target paths AddTargetPath(endingCenterLine, 0.001); // add the lane bounds AddLeftBound(endingLeftBound, false); AddRightBound(endingRightBound, false); // intert a small portion of the ending lane centerLine.AddRange(endingCenterLine); // get the intersection pull path LinePath intersectionPullPath = new LinePath(); double pullWeighting = 0; GetIntersectionPullPath(startingCenterLine, endingCenterLine, intersectionPolygon, true, true, intersectionPullPath, ref pullWeighting); if (intersectionPullPath.Count > 0) { // add as a weighting term AddTargetPath(intersectionPullPath, pullWeighting); } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in stay in lane, center line count: {0}, left bound count: {1}, right bound count: {2}", centerLine.Count, leftBound.Count, rightBound.Count); Services.UIService.PushLineList(centerLine, curTimestamp, "subpath", true); Services.UIService.PushLineList(leftBound, curTimestamp, "left bound", true); Services.UIService.PushLineList(rightBound, curTimestamp, "right bound", true); // calculate max speed for the path over the next 120 meters double advanceDist = speed_path_advance_dist; LinePath.PointOnPath startingLaneEndPoint = curStartingLane.AdvancePoint(startingLanePoint, ref advanceDist); LinePath combinedPath = curStartingLane.SubPath(startingLanePoint, startingLaneEndPoint); if (advanceDist > 0) { Coordinates endingLaneFirstPoint = curEndingLane[0]; Coordinates startingLaneLastPoint = curStartingLane.EndPoint.Location; double intersectionDist = startingLaneLastPoint.DistanceTo(endingLaneFirstPoint); double addDist = Math.Max(advanceDist - intersectionDist, 5); // add a portion of the ending lane of the appropriate length LinePath.PointOnPath endingLanePoint = curEndingLane.AdvancePoint(curEndingLane.StartPoint, addDist); int endIndex = endingLanePoint.Index + 1; combinedPath.AddRange(curEndingLane.GetSubpathEnumerator(0, endIndex)); } settings.maxSpeed = GetMaxSpeed(combinedPath, combinedPath.StartPoint); if (sparse) { // limit to 5 mph //laneWidthAtPathEnd = 20; settings.maxSpeed = Math.Min(settings.maxSpeed, 2.2352); LinePath leftEdge = RoadEdge.GetLeftEdgeLine(); LinePath rightEdge = RoadEdge.GetRightEdgeLine(); if (leftEdge != null) { additionalLeftBounds.Add(new Boundary(leftEdge, 0.1, 1, 100, false)); } if (rightEdge != null) { additionalRightBounds.Add(new Boundary(rightEdge, 0.1, 1, 100, false)); } } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "max speed set to {0}", settings.maxSpeed); // set the avoidance path to be the previously smoothed path AbsoluteTransformer absTransform = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); avoidanceBasePath = turnBasePath.Transform(absTransform); avoidanceBasePath = avoidanceBasePath.SubPath(avoidanceBasePath.ZeroPoint, avoidanceBasePath.EndPoint); smootherBasePath = avoidanceBasePath.Clone(); maxSmootherBasePathAdvancePoint = smootherBasePath.GetClosestPoint(startingCenterLine.EndPoint.Location); // set auxillary settings settings.endingHeading = centerLine.EndSegment.UnitVector.ArcTan; //useAvoidancePath = true; SmoothAndTrack(commandLabel, true); if (cancelled) return PlanningPhase.EnteringTurn; // check if the remaining distance on the starting lane is less than some small tolerance. // if it is, switch to the mid-turn phase if (remainingDistance <= TahoeParams.FL) { return PlanningPhase.MidTurn; } else { return PlanningPhase.EnteringTurn; } }
private LinePath ReplaceFirstPoint(LinePath path, LinePath.PointOnPath maxAdvancePoint, Coordinates pt) { LinePath ret; if (!disablePathAngleCheck) { // start walking down the path until the angle is cool double angle_threshold = pathAngleMax; LinePath.PointOnPath newPoint = new LinePath.PointOnPath(); for (double dist = 0; dist < pathAngleCheckMax; dist += 1) { // get the point advanced from the 2nd point on the base path by dist double distTemp = dist; newPoint = path.AdvancePoint(path.GetPointOnPath(1), ref distTemp); // check if we're past the end if (distTemp > 0) { break; } else if (maxAdvancePoint.Valid && newPoint >= maxAdvancePoint) { newPoint = maxAdvancePoint; break; } // check if the angle is coolness or not double angle = Math.Acos((newPoint.Location-pt).Normalize().Dot(path.GetSegment(newPoint.Index).UnitVector)); if (angle < angle_threshold) { break; } } // create a new version of the base path with the stuff section removed ret = path.RemoveBetween(path.StartPoint, newPoint); ret[0] = pt; } else { ret = path.Clone(); ret[0] = pt; } return ret; }
private PlanningPhase PlanBeginningTurn(LinePath curStartingLane, LinePath curEndingLane) { // figure out where we are along the starting lane path LinePath.PointOnPath startingLanePoint = curStartingLane.ZeroPoint; // get the distance to the end point of the lane from our current point double remainingDistance = curStartingLane.DistanceBetween(startingLanePoint, curStartingLane.EndPoint); // get the lane mode for the starting lane ILaneModel startingLaneModel = Services.RoadModelProvider.GetLaneModel(curStartingLane, startingLaneWidth + extraWidth, curTimestamp, startingLanesLeft, startingLanesRight); double? boundStartDistMin; double? boundEndDistMax; DetermineSparseStarting(remainingDistance - starting_lane_trim_dist, out boundStartDistMin, out boundEndDistMax); // linearize the lane model LinePath centerLine, leftBound, rightBound; if (boundEndDistMax != null || boundStartDistMin != null) { if (boundEndDistMax != null) { boundEndDistMax = Math.Min(boundEndDistMax.Value, remainingDistance - starting_lane_trim_dist); } else { boundEndDistMax = remainingDistance - starting_lane_trim_dist; } LinearizeStayInLane(startingLaneModel, remainingDistance, 0, boundEndDistMax, boundStartDistMin, null, curTimestamp, out centerLine, out leftBound, out rightBound); } else { LinearizeStayInLane(startingLaneModel, remainingDistance, 0, remainingDistance - starting_lane_trim_dist, null, curTimestamp, out centerLine, out leftBound, out rightBound); } //LinearizeLane(curStartingLane, startingLaneWidth, TahoeParams.FL, remainingDistance, 5, remainingDistance - 5, out centerLine, out leftBound, out rightBound); // create a copy so when we add to the center line later we don't change this version LinePath startingCenterLine = centerLine.Clone(); // calculate time to collision of opposing obstacle if it exists LinePath targetLine = startingCenterLine; if (opposingLaneVehicleExists) { double timeToCollision = opposingLaneVehicleDist/(Math.Abs(vs.speed)+Math.Abs(opposingLaneVehicleSpeed)); if (timeToCollision < 3) { // shift to the right double shiftDist = -TahoeParams.T/2.0; targetLine = centerLine.ShiftLateral(shiftDist); } } // set up the planning AddTargetPath(targetLine, default_lane_alpha_w); if (!sparse || boundStartDistMin != null || boundEndDistMax != null) { // add the lane bounds AddLeftBound(leftBound, true); if (!oncomingVehicleExists) { AddRightBound(rightBound, false); } } LinePath endingCenterLine, endingLeftBound, endingRightBound; LinearizeLane(curEndingLane, endingLaneWidth, 0, 5, 2, 6, out endingCenterLine, out endingLeftBound, out endingRightBound); // add the ending lane center line to the target paths AddTargetPath(endingCenterLine, default_lane_alpha_w); // add the lane bounds AddLeftBound(endingLeftBound, false); AddRightBound(endingRightBound, false); // intert a small portion of the ending lane centerLine.AddRange(endingCenterLine); // add to the planning setup smootherBasePath = centerLine; maxSmootherBasePathAdvancePoint = smootherBasePath.GetClosestPoint(startingCenterLine.EndPoint.Location); // get the intersection pull path LinePath intersectionPullPath = new LinePath(); double pullWeighting = 0; GetIntersectionPullPath(startingCenterLine, endingCenterLine, intersectionPolygon, true, true, intersectionPullPath, ref pullWeighting); if (intersectionPullPath.Count > 0) { // add as a weighting term AddTargetPath(intersectionPullPath, pullWeighting); } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in stay in lane, center line count: {0}, left bound count: {1}, right bound count: {2}", centerLine.Count, leftBound.Count, rightBound.Count); // calculate max speed for the path over the next 120 meters double advanceDist = speed_path_advance_dist; LinePath.PointOnPath startingLaneEndPoint = curStartingLane.AdvancePoint(startingLanePoint, ref advanceDist); LinePath combinedPath = curStartingLane.SubPath(startingLanePoint, startingLaneEndPoint); if (advanceDist > 0) { Coordinates endingLaneFirstPoint = curEndingLane[0]; Coordinates startingLaneLastPoint = curStartingLane.EndPoint.Location; double intersectionDist = startingLaneLastPoint.DistanceTo(endingLaneFirstPoint); double addDist = Math.Max(advanceDist - intersectionDist, 5); // add a portion of the ending lane of the appropriate length LinePath.PointOnPath endingLanePoint = curEndingLane.AdvancePoint(curEndingLane.StartPoint, addDist); int endIndex = endingLanePoint.Index + 1; combinedPath.AddRange(curEndingLane.GetSubpathEnumerator(0, endIndex)); } // set the planning settings max speed settings.maxSpeed = GetMaxSpeed(combinedPath, combinedPath.StartPoint); if (sparse) { // limit to 5 mph //laneWidthAtPathEnd = 20; settings.maxSpeed = Math.Min(settings.maxSpeed, 2.2352); } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "max speed set to {0}", settings.maxSpeed); // set auxillary settings settings.endingHeading = centerLine.EndSegment.UnitVector.ArcTan; PlanningResult planningResult = Smooth(false); if (!planningResult.pathBlocked && !planningResult.dynamicallyInfeasible) { AbsoluteTransformer absTransform = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); turnBasePath = planningResult.smoothedPath.Transform(absTransform.Invert()); return PlanningPhase.EnteringTurn; } else { // keep trying I guess return PlanningPhase.BeginEnteringTurn; } }
public override void Process(object param) { if (!base.BeginProcess()) { return; } // check if we're given a param if (param != null && param is TurnBehavior) { TurnBehavior turnParam = (TurnBehavior)param; HandleTurnBehavior(turnParam); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "turn behavior - got new param, speed command {0}", turnParam.SpeedCommand); } LinePath curTargetPath = targetPath.Clone(); LinePath curLeftBound = null; if (leftBound != null) { curLeftBound = leftBound.Clone(); } LinePath curRightBound = null; if (rightBound != null) { curRightBound = rightBound.Clone(); } // transform the path into the current timestamp if (behaviorTimestamp != curTimestamp) { // get the relative transform RelativeTransform relTransform = Services.RelativePose.GetTransform(behaviorTimestamp, curTimestamp); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in turn behavior, transforming from {0}->{1}, wanted {2}->{3}", relTransform.OriginTimestamp, relTransform.EndTimestamp, behaviorTimestamp, curTimestamp); curTargetPath.TransformInPlace(relTransform); if (curLeftBound != null) { curLeftBound.TransformInPlace(relTransform); } if (curRightBound != null) { curRightBound.TransformInPlace(relTransform); } } // get the distance between our current location and the start point double distToStart = Coordinates.Zero.DistanceTo(curTargetPath[0]); double startDist = Math.Max(0, TahoeParams.FL - distToStart); // extract off the first 5 m of the target path LinePath.PointOnPath endTarget = curTargetPath.AdvancePoint(curTargetPath.StartPoint, TahoeParams.VL); curTargetPath = curTargetPath.SubPath(curTargetPath.StartPoint, endTarget); curTargetPath = curTargetPath.RemoveZeroLengthSegments(); // adjust the left bound and right bounds starting distance if (curLeftBound != null) { LinePath.PointOnPath leftBoundStart = curLeftBound.AdvancePoint(curLeftBound.StartPoint, 2); curLeftBound = curLeftBound.SubPath(leftBoundStart, curLeftBound.EndPoint); AddLeftBound(curLeftBound, false); Services.UIService.PushLineList(curLeftBound, curTimestamp, "left bound", true); } if (curRightBound != null) { LinePath.PointOnPath rightBoundStart = curRightBound.AdvancePoint(curRightBound.StartPoint, 2); curRightBound = curRightBound.SubPath(rightBoundStart, curRightBound.EndPoint); AddRightBound(curRightBound, false); Services.UIService.PushLineList(curRightBound, curTimestamp, "right bound", true); } if (cancelled) { return; } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in turn behavior, dist to start: {0}", distToStart); if (distToStart < TahoeParams.FL * 0.75) { BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "in turn behavior, past start point of target path"); // return a completion report ForwardCompletionReport(new SuccessCompletionReport(typeof(TurnBehavior))); } AddTargetPath(curTargetPath.Clone(), 0.005); // transform the pseudo start lane to the current timestamp AbsoluteTransformer trans = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); LinePath curStartPath = pseudoStartLane.Transform(trans); // add the intersection pull path LinePath intersectionPullPath = new LinePath(); double pullWeight = 0; GetIntersectionPullPath(curStartPath, curTargetPath, intersectionPolygon, true, true, intersectionPullPath, ref pullWeight); if (intersectionPullPath.Count > 0) { AddTargetPath(intersectionPullPath, pullWeight); } // set up planning details // add our position to the current target path LinePath origTargetPath = curTargetPath.Clone(); curTargetPath.Insert(0, new Coordinates(0, 0)); //curTargetPath.Insert(1, new Coordinates(1, 0)); smootherBasePath = curTargetPath; // add the bounds // calculate max speed settings.maxSpeed = GetMaxSpeed(null, LinePath.PointOnPath.Invalid); settings.Options.w_diff = 4; BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "max speed set to {0}", settings.maxSpeed); if (cancelled) { return; } Services.UIService.PushLineList(curTargetPath, curTimestamp, "subpath", true); // set the avoidance path to the previously planned path // transform to the current timestamp disablePathAngleCheck = true; if (turnBasePath != null) { avoidanceBasePath = turnBasePath.Transform(trans); avoidanceBasePath = avoidanceBasePath.SubPath(avoidanceBasePath.GetClosestPoint(Coordinates.Zero), avoidanceBasePath.EndPoint); maxAvoidanceBasePathAdvancePoint = avoidanceBasePath.GetPointOnPath(1); if (avoidanceBasePath.PathLength > 7.5) { smootherBasePath = avoidanceBasePath.SubPath(avoidanceBasePath.StartPoint, avoidanceBasePath.AdvancePoint(avoidanceBasePath.EndPoint, -7.5)); } else { smootherBasePath = avoidanceBasePath.Clone(); } disablePathAngleCheck = false; } // fill in auxiliary settings if (curLeftBound != null || curRightBound != null) { settings.endingHeading = curTargetPath.EndSegment.UnitVector.ArcTan; } settings.endingPositionFixed = false; settings.endingPositionMax = 16; settings.endingPositionMin = -16; if (curLeftBound != null && curLeftBound.Count > 0 && curTargetPath.Count > 0) { double leftWidth = curLeftBound[0].DistanceTo(origTargetPath[0]) - TahoeParams.T / 2; settings.endingPositionMax = leftWidth; settings.endingPositionFixed = true; } if (curRightBound != null && curRightBound.Count > 0 && curTargetPath.Count > 0) { double rightWidth = curRightBound[0].DistanceTo(origTargetPath[0]) - TahoeParams.T / 2; settings.endingPositionFixed = true; settings.endingPositionMin = -rightWidth; } //disablePathAngleCheck = true; //useAvoidancePath = true; // do the planning SmoothAndTrack(commandLabel, true); }
private void DoInitialPlan() { InitializePlanningSettings(); curTimestamp = Services.RelativePose.CurrentTimestamp; vs = Services.StateProvider.GetVehicleState(); LinePath curTargetPath = targetPath.Clone(); LinePath curLeftBound = null; if (leftBound != null) { curLeftBound = leftBound.Clone(); } LinePath curRightBound = null; if (rightBound != null) { curRightBound = rightBound.Clone(); } // get the distance between our current location and the start point double distToStart = Coordinates.Zero.DistanceTo(curTargetPath[0]); // extract off the first 5 m of the target path LinePath.PointOnPath endTarget = curTargetPath.AdvancePoint(curTargetPath.StartPoint, 12); curTargetPath = curTargetPath.SubPath(curTargetPath.StartPoint, endTarget); AddTargetPath(curTargetPath.Clone(), 0.005); // adjust the left bound and right bounds starting distance if (curLeftBound != null) { LinePath.PointOnPath leftBoundStart = curLeftBound.AdvancePoint(curLeftBound.StartPoint, 2); curLeftBound = curLeftBound.SubPath(leftBoundStart, curLeftBound.EndPoint); AddLeftBound(curLeftBound, false); } if (curRightBound != null) { LinePath.PointOnPath rightBoundStart = curRightBound.AdvancePoint(curRightBound.StartPoint, 2); curRightBound = curRightBound.SubPath(rightBoundStart, curRightBound.EndPoint); AddRightBound(curRightBound, false); } // add the intersection pull path LinePath intersectionPullPath = new LinePath(); double pullWeight = 0; AbsoluteTransformer trans = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); GetIntersectionPullPath(pseudoStartLane.Transform(trans), curTargetPath, intersectionPolygon, true, true, intersectionPullPath, ref pullWeight); if (intersectionPullPath.Count > 0) { AddTargetPath(intersectionPullPath, pullWeight); } // set up planning details // add our position to the current target path curTargetPath.Insert(0, new Coordinates(0, 0)); smootherBasePath = curTargetPath; // add the bounds // calculate max speed settings.maxSpeed = GetMaxSpeed(null, LinePath.PointOnPath.Invalid); // fill in auxiliary settings if (curLeftBound != null || curRightBound != null) { settings.endingHeading = curTargetPath.EndSegment.UnitVector.ArcTan; } disablePathAngleCheck = true; settings.Options.w_diff = 4; // do the planning PlanningResult planningResult = Smooth(false); // if the planning was a success, store the result if (!planningResult.dynamicallyInfeasible) { // transform to absolute coordinates AbsoluteTransformer absTransform = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); turnBasePath = planningResult.smoothedPath.Transform(absTransform.Invert()); } }
protected void LinearizeStayInLane(ILaneModel laneModel, double laneDist, double? laneStartDistMax, double? boundDistMax, double? boundStartDistMin, double? boundStartDistMax, CarTimestamp curTimestamp, out LinePath centerLine, out LinePath leftBound, out LinePath rightBound) { // get the center line, left bound and right bound LinearizationOptions laneOpts = new LinearizationOptions(0, laneDist, curTimestamp); centerLine = laneModel.LinearizeCenterLine(laneOpts); if (centerLine == null || centerLine.Count < 2) { BehaviorManager.TraceSource.TraceEvent(TraceEventType.Error, 0, "center line linearization SUCKS"); } double leftStartDist = vs.speed*TahoeParams.actuation_delay + 1; double rightStartDist = vs.speed*TahoeParams.actuation_delay + 1; double offtrackDistanceBack = centerLine.ZeroPoint.OfftrackDistance(Coordinates.Zero); bool offtrackLeftBack = offtrackDistanceBack > 0; double additionalDistBack = 5*Math.Abs(offtrackDistanceBack)/laneModel.Width; if (offtrackLeftBack) { leftStartDist += additionalDistBack; } else { rightStartDist += additionalDistBack; } // now determine how to generate the left/right bounds // figure out the offtrack distance from the vehicle's front bumper double offtrackDistanceFront = centerLine.ZeroPoint.OfftrackDistance(new Coordinates(TahoeParams.FL, 0)); // offtrackDistance > 0 => we're to left of path // offtrackDistance < 0 => we're to right of path bool offsetLeftFront = offtrackDistanceFront > 0; double additionalDistFront = 10*Math.Abs(offtrackDistanceFront)/laneModel.Width; if (offsetLeftFront) { leftStartDist += additionalDistFront; } else { rightStartDist += additionalDistFront; } if (boundStartDistMax.HasValue) { if (leftStartDist > boundStartDistMax.Value) { leftStartDist = boundStartDistMax.Value; } if (rightStartDist > boundStartDistMax.Value) { rightStartDist = boundStartDistMax.Value; } } if (boundStartDistMin.HasValue) { if (leftStartDist < boundStartDistMin.Value) { leftStartDist = boundStartDistMin.Value; } if (rightStartDist < boundStartDistMin.Value) { rightStartDist = boundStartDistMin.Value; } } double boundEndDist = laneDist + 5; if (boundDistMax.HasValue && boundDistMax.Value < boundEndDist) { boundEndDist = boundDistMax.Value; } laneOpts = new LinearizationOptions(leftStartDist, boundEndDist, curTimestamp); leftBound = laneModel.LinearizeLeftBound(laneOpts); laneOpts = new LinearizationOptions(rightStartDist, boundEndDist, curTimestamp); rightBound = laneModel.LinearizeRightBound(laneOpts); double laneStartDist = TahoeParams.FL; if (laneStartDistMax.HasValue && laneStartDistMax.Value < laneStartDist) { laneStartDist = laneStartDistMax.Value; } // remove the first FL distance of the center line if (laneStartDist > 0) { centerLine = centerLine.RemoveBefore(centerLine.AdvancePoint(centerLine.ZeroPoint, laneStartDist)); centerLine.Insert(0, Coordinates.Zero); } }
private ILaneModel GetLaneModel(LocalLaneModel laneModel, LinePath rndfPath, double rndfPathWidth, CarTimestamp rndfPathTimestamp) { // check the lane model probability if (laneModel.Probability < lane_probability_reject_threshold) { // we're rejecting this, just return a path lane model return(new PathLaneModel(rndfPathTimestamp, rndfPath, rndfPathWidth)); } // project the lane model's path into the rndf path's timestamp RelativeTransform relTransform = Services.RelativePose.GetTransform(localRoadModel.Timestamp, rndfPathTimestamp); LinePath laneModelPath = laneModel.LanePath.Transform(relTransform); // iterate through the waypoints in the RNDF path and project onto the lane model // the first one that is over the threshold, we consider the waypoint before as a potential ending point LinePath.PointOnPath laneModelDeviationEndPoint = new LinePath.PointOnPath(); // flag indicating if any of the waypoint tests failed because of the devation was too high bool anyDeviationTooHigh = false; // number of waypoints accepted int numWaypointsAccepted = 0; // get the vehicle's position on the rndf path LinePath.PointOnPath rndfZeroPoint = rndfPath.ZeroPoint; // get the vehicle's position on the lane model LinePath.PointOnPath laneModelZeroPoint = laneModelPath.ZeroPoint; // get the last point we want to consider on the lane model LinePath.PointOnPath laneModelFarthestPoint = laneModelPath.AdvancePoint(laneModelZeroPoint, lane_model_max_dist); // start walking forward through the waypoints on the rndf path // this loop will implicitly exit when we're past the end of the lane model as the waypoints // will stop being close to the lane model (GetClosestPoint returns the end point if we're past the // end of the path) for (int i = rndfZeroPoint.Index + 1; i < rndfPath.Count; i++) { // get the waypoint Coordinates rndfWaypoint = rndfPath[i]; // get the closest point on the lane model LinePath.PointOnPath laneModelClosestPoint = laneModelPath.GetClosestPoint(rndfWaypoint); // compute the distance between the two double deviation = rndfWaypoint.DistanceTo(laneModelClosestPoint.Location); // if this is above the deviation threshold, leave the loop if (deviation > lane_deviation_reject_threshold || laneModelClosestPoint > laneModelFarthestPoint) { // if we're at the end of the lane model path, we don't want to consider this a rejection if (laneModelClosestPoint < laneModelFarthestPoint) { // mark that at least on deviation was too high anyDeviationTooHigh = true; } break; } // increment the number of waypoint accepted numWaypointsAccepted++; // update the end point of where we're valid as the local road model was OK up to this point laneModelDeviationEndPoint = laneModelClosestPoint; } // go through and figure out how far out the variance is within tolerance LinePath.PointOnPath laneModelVarianceEndPoint = new LinePath.PointOnPath(); // walk forward from this point until the end of the lane mode path for (int i = laneModelZeroPoint.Index + 1; i < laneModelPath.Count; i++) { // check if we're within the variance toleration if (laneModel.LaneYVariance[i] <= y_var_reject_threshold) { // we are, update the point on path laneModelVarianceEndPoint = laneModelPath.GetPointOnPath(i); } else { // we are out of tolerance, break out of the loop break; } } // now figure out everything out // determine waypoint rejection status WaypointRejectionResult waypointRejectionResult; if (laneModelDeviationEndPoint.Valid) { // if the point is valid, that we had at least one waypoint that was ok // check if any waypoints were rejected if (anyDeviationTooHigh) { // some waypoint was ok, so we know that at least one waypoint was accepted waypointRejectionResult = WaypointRejectionResult.SomeWaypointsAccepted; } else { // no waypoint triggered a rejection, but at least one was good waypointRejectionResult = WaypointRejectionResult.AllWaypointsAccepted; } } else { // the point is not valid, so we either had no waypoints or we had all rejections if (anyDeviationTooHigh) { // the first waypoint was rejected, so all are rejected waypointRejectionResult = WaypointRejectionResult.AllWaypointsRejected; } else { // the first waypoint (if any) was past the end of the lane model waypointRejectionResult = WaypointRejectionResult.NoWaypoints; } } // criteria for determining if this path is valid: // - if some or all waypoints were accepted, than this is probably a good path // - if some of the waypoints were accepted, we go no farther than the last waypoint that was accepted // - if there were no waypoints, this is a potentially dangerous situation since we can't reject // or confirm the local road model. for now, we'll assume that it is correct but this may need to change // if we start handling intersections in this framework // - if all waypoints were rejected, than we don't use the local road model // - go no farther than the laneModelVarianceEndPoint, which is the last point where the y-variance of // the lane model was in tolerance // now build out the lane model ILaneModel finalLaneModel; // check if we rejected all waypoints or no lane model points satisified the variance threshold if (waypointRejectionResult == WaypointRejectionResult.AllWaypointsRejected || !laneModelVarianceEndPoint.Valid) { // want to just use the path lane model finalLaneModel = new PathLaneModel(rndfPathTimestamp, rndfPath, rndfPathWidth); } else { // we'll use the lane model // need to build up the center line as well as left and right bounds // to build up the center line, use the lane model as far as we feel comfortable (limited by either variance // or by rejections) and then use the rndf lane after that. LinePath centerLine = new LinePath(); // figure out the max distance // if there were no waypoints, set the laneModelDeviationEndPoint to the end of the lane model if (waypointRejectionResult == WaypointRejectionResult.NoWaypoints) { laneModelDeviationEndPoint = laneModelFarthestPoint; } // figure out the closer of the end points LinePath.PointOnPath laneModelEndPoint = (laneModelDeviationEndPoint < laneModelVarianceEndPoint) ? laneModelDeviationEndPoint : laneModelVarianceEndPoint; bool endAtWaypoint = laneModelEndPoint == laneModelDeviationEndPoint; // add the lane model to the center line centerLine.AddRange(laneModelPath.GetSubpathEnumerator(laneModelZeroPoint, laneModelEndPoint)); // create a list to hold the width expansion values List <double> widthValue = new List <double>(); // make the width expansion values the width of the path plus the 1-sigma values for (int i = laneModelZeroPoint.Index; i < laneModelZeroPoint.Index + centerLine.Count; i++) { widthValue.Add(laneModel.Width / 2.0 + Math.Sqrt(laneModel.LaneYVariance[i])); } // now figure out how to add the rndf path // get the projection of the lane model end point on the rndf path LinePath.PointOnPath rndfPathStartPoint = rndfPath.GetClosestPoint(laneModelEndPoint.Location); // if the closest point is past the end of rndf path, then we don't want to tack anything on if (rndfPathStartPoint != rndfPath.EndPoint) { // get the last segment of the new center line Coordinates centerLineEndSegmentVec = centerLine.EndSegment.UnitVector; // get the last point of the new center line Coordinates laneModelEndLoc = laneModelEndPoint.Location; // now figure out the distance to the next waypoint LinePath.PointOnPath rndfNextPoint = new LinePath.PointOnPath(); // figure out if we're ending at a waypoint or not if (endAtWaypoint) { rndfNextPoint = rndfPath.GetPointOnPath(rndfPathStartPoint.Index + 1); // if the distance from the start point to the next point is less than rndf_dist_min, then // use the waypont after double dist = rndfPath.DistanceBetween(rndfPathStartPoint, rndfNextPoint); if (dist < rndf_dist_min) { if (rndfPathStartPoint.Index < rndfPath.Count - 2) { rndfNextPoint = rndfPath.GetPointOnPath(rndfPathStartPoint.Index + 2); } else if (rndfPath.DistanceBetween(rndfPathStartPoint, rndfPath.EndPoint) < rndf_dist_min) { rndfNextPoint = LinePath.PointOnPath.Invalid; } else { rndfNextPoint = rndfPath.AdvancePoint(rndfPathStartPoint, rndf_dist_min * 2); } } } else { // track the last angle we had double lastAngle = double.NaN; // walk down the rndf path until we find a valid point for (double dist = rndf_dist_min; dist <= rndf_dist_max; dist += rndf_dist_step) { // advance from the start point by dist double distTemp = dist; rndfNextPoint = rndfPath.AdvancePoint(rndfPathStartPoint, ref distTemp); // if the distTemp is > 0, then we're past the end of the path if (distTemp > 0) { // if we're immediately past the end, we don't want to tack anything on if (dist == rndf_dist_min) { rndfNextPoint = LinePath.PointOnPath.Invalid; } break; } // check the angle made by the last segment of center line and the segment // formed between the end point of the center line and this new point double angle = Math.Acos(centerLineEndSegmentVec.Dot((rndfNextPoint.Location - laneModelEndLoc).Normalize())); // check if the angle satisfies the threshold or we're increasing the angle if (Math.Abs(angle) < rndf_angle_threshold || (!double.IsNaN(lastAngle) && angle > lastAngle)) { // break out of the loop, we're done searching break; } lastAngle = angle; } } // tack on the rndf starting at next point going to the end if (rndfNextPoint.Valid) { LinePath subPath = rndfPath.SubPath(rndfNextPoint, rndfPath.EndPoint); centerLine.AddRange(subPath); // insert the lane model end point into the sub path subPath.Insert(0, laneModelEndLoc); // get the angles List <Pair <int, double> > angles = subPath.GetIntersectionAngles(0, subPath.Count - 1); // add the width of the path inflated by the angles for (int i = 0; i < angles.Count; i++) { // calculate the width expansion factor // 90 deg, 3x width // 45 deg, 1.5x width // 0 deg, 1x width double widthFactor = Math.Pow(angles[i].Right / (Math.PI / 2.0), 2) * 2 + 1; // add the width value widthValue.Add(widthFactor * laneModel.Width / 2); } // add the final width widthValue.Add(laneModel.Width / 2); } // set the rndf path start point to be the point we used rndfPathStartPoint = rndfNextPoint; } // for now, calculate the left and right bounds the same way we do for the path lane model // TODO: figure out if we want to do this more intelligently using knowledge of the lane model uncertainty LinePath leftBound = centerLine.ShiftLateral(widthValue.ToArray()); // get the next shifts for (int i = 0; i < widthValue.Count; i++) { widthValue[i] = -widthValue[i]; } LinePath rightBound = centerLine.ShiftLateral(widthValue.ToArray()); // build the final lane model finalLaneModel = new CombinedLaneModel(centerLine, leftBound, rightBound, laneModel.Width, rndfPathTimestamp); } SendLaneModelToUI(finalLaneModel, rndfPathTimestamp); // output the fit result return(finalLaneModel); }
private PlanningPhase PlanMidTurn(LinePath curStartingLane, LinePath curEndingLane) { // get the distance to the first point of the ending lane double remainingDistance = Coordinates.Zero.DistanceTo(curEndingLane[0]); // get the desired planning distance double planningDistance = GetPlanningDistance(); // calculate the distance of the target lane that we want double targetLaneDist = Math.Max(planningDistance - remainingDistance, 5); // get the lane model ILaneModel endingLaneModel = Services.RoadModelProvider.GetLaneModel(curEndingLane, endingLaneWidth, curTimestamp, endingLanesLeft, endingLanesRight); // linearize the lane model LinePath centerLine, leftBound, rightBound; LinearizeStayInLane(endingLaneModel, targetLaneDist, 0, null, 2, 2, curTimestamp, out centerLine, out leftBound, out rightBound); // create a copy LinePath endingCenterLine = centerLine.Clone(); // add as a target path AddTargetPath(endingCenterLine, 0.001); // add the lane bounds AddLeftBound(leftBound, false); AddRightBound(rightBound, false); // insert our position into the center line path centerLine.Insert(0, Coordinates.Zero); // get the intersection pull path LinePath intersectionPullPath = new LinePath(); double pullWeighting = 0; GetIntersectionPullPath(curStartingLane, endingCenterLine, intersectionPolygon, true, true, intersectionPullPath, ref pullWeighting); if (intersectionPullPath.Count > 0) { // add as a weighting term AddTargetPath(intersectionPullPath, pullWeighting); } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in stay in lane, center line count: {0}, left bound count: {1}, right bound count: {2}", centerLine.Count, leftBound.Count, rightBound.Count); Services.UIService.PushLineList(centerLine, curTimestamp, "subpath", true); Services.UIService.PushLineList(leftBound, curTimestamp, "left bound", true); Services.UIService.PushLineList(rightBound, curTimestamp, "right bound", true); // calculate max speed for the path over the next 120 meters double advanceDist = speed_path_advance_dist - remainingDistance; LinePath combinedPath = new LinePath(); combinedPath.Add(Coordinates.Zero); if (advanceDist > 0) { // add the ending lane with the appropriate distance combinedPath.AddRange(curEndingLane.GetSubpathEnumerator(0, curEndingLane.AdvancePoint(curEndingLane.StartPoint, advanceDist).Index + 1)); } else { // add the first segment of the ending lane combinedPath.Add(curEndingLane[0]); combinedPath.Add(curEndingLane[1]); } settings.maxSpeed = GetMaxSpeed(combinedPath, combinedPath.StartPoint); settings.maxEndingSpeed = GetMaxSpeed(combinedPath, combinedPath.AdvancePoint(combinedPath.StartPoint, planningDistance)); BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "max speed set to {0}", settings.maxSpeed); if (remainingDistance >= 15) { // get the ending lane heading //settings.endingHeading = centerLine.EndSegment.UnitVector.ArcTan; } // set the avoidance path to be the previously smoothed path updated to the current time AbsoluteTransformer absTransform = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); avoidanceBasePath = turnBasePath.Transform(absTransform); avoidanceBasePath = avoidanceBasePath.SubPath(avoidanceBasePath.ZeroPoint, avoidanceBasePath.EndPoint); //avoidanceBasePath = null; smootherBasePath = avoidanceBasePath.Clone(); maxSmootherBasePathAdvancePoint = smootherBasePath.GetClosestPoint(endingCenterLine.StartPoint.Location); //useAvoidancePath = true; SmoothAndTrack(commandLabel, true); if (cancelled) return PlanningPhase.MidTurn; // check if the remaining distance on the starting lane is less than some small tolerance. // if it is, switch to the mid-turn phase if (remainingDistance < 6) { return PlanningPhase.EndingLane; } else { return PlanningPhase.MidTurn; } }
public override void Process(object param) { // inform the base that we're beginning processing if (!BeginProcess()) { return; } // check if we were given a parameter if (param != null && param is StayInLaneBehavior) { HandleBehavior((StayInLaneBehavior)param); } if (reverseGear) { ProcessReverse(); return; } // figure out the planning distance double planningDistance = GetPlanningDistance(); if (sparse && planningDistance > 10) { planningDistance = 10; } double?boundStartDistMin = null; double?boundEndDistMax = null; if (laneID != null && Services.RoadNetwork != null) { ArbiterLane lane = Services.RoadNetwork.ArbiterSegments[laneID.SegmentId].Lanes[laneID]; AbsolutePose pose = Services.StateProvider.GetAbsolutePose(); ArbiterLanePartition partition = lane.GetClosestPartition(pose.xy); LinePath partitionPath = partition.UserPartitionPath; LinePath.PointOnPath closestPoint = partitionPath.GetClosestPoint(pose.xy); double remainingDist = planningDistance; double totalDist = partitionPath.DistanceBetween(closestPoint, partitionPath.EndPoint); remainingDist -= totalDist; if (sparse) { // walk ahead and determine where sparsity ends bool nonSparseFound = false; while (remainingDist > 0) { // get the next partition partition = partition.Final.NextPartition; if (partition == null) { break; } if (partition.Type != PartitionType.Sparse) { nonSparseFound = true; break; } else { double dist = partition.UserPartitionPath.PathLength; totalDist += dist; remainingDist -= dist; } } if (nonSparseFound) { boundStartDistMin = totalDist; } } else { // determine if there is a sparse segment upcoming bool sparseFound = false; while (remainingDist > 0) { partition = partition.Final.NextPartition; if (partition == null) { break; } if (partition.Type == PartitionType.Sparse) { sparseFound = true; break; } else { double dist = partition.Length; totalDist += dist; remainingDist -= dist; } } if (sparseFound) { boundEndDistMax = totalDist; sparse = true; } } } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "in stay in lane, planning distance {0}", planningDistance); // update the rndf path RelativeTransform relTransfrom = Services.RelativePose.GetTransform(behaviorTimestamp, curTimestamp); LinePath curRndfPath = rndfPath.Transform(relTransfrom); ILaneModel centerLaneModel = Services.RoadModelProvider.GetLaneModel(curRndfPath, rndfPathWidth + extraWidth, curTimestamp, numLanesLeft, numLanesRight); double avoidanceExtra = sparse ? 5 : 7.5; LinePath centerLine, leftBound, rightBound; if (boundEndDistMax != null || boundStartDistMin != null) { LinearizeStayInLane(centerLaneModel, planningDistance + avoidanceExtra, null, boundEndDistMax, boundStartDistMin, null, curTimestamp, out centerLine, out leftBound, out rightBound); } else { LinearizeStayInLane(centerLaneModel, planningDistance + avoidanceExtra, curTimestamp, out centerLine, out leftBound, out rightBound); } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Verbose, 0, "in stay in lane, center line count: {0}, left bound count: {1}, right bound count: {2}", centerLine.Count, leftBound.Count, rightBound.Count); // calculate time to collision of opposing obstacle if it exists LinePath targetLine = centerLine; double targetWeight = default_lane_alpha_w; if (sparse) { targetWeight = 0.00000025; } else if (oncomingVehicleExists) { double shiftDist = -(TahoeParams.T + 1); targetLine = centerLine.ShiftLateral(shiftDist); targetWeight = 0.01; } else if (opposingLaneVehicleExists) { double timeToCollision = opposingLaneVehicleDist / (Math.Abs(vs.speed) + Math.Abs(opposingLaneVehicleSpeed)); Services.Dataset.ItemAs <double>("time to collision").Add(timeToCollision, curTimestamp); if (timeToCollision < 5) { // shift to the right double shiftDist = -TahoeParams.T / 2.0; targetLine = centerLine.ShiftLateral(shiftDist); } } // set up the planning AddTargetPath(targetLine, targetWeight); if (!sparse || boundStartDistMin != null || boundEndDistMax != null) { AddLeftBound(leftBound, true); if (!oncomingVehicleExists) { AddRightBound(rightBound, false); } } double targetDist = Math.Max(centerLine.PathLength - avoidanceExtra, planningDistance); smootherBasePath = centerLine.SubPath(centerLine.StartPoint, targetDist); maxSmootherBasePathAdvancePoint = smootherBasePath.EndPoint; double extraDist = (planningDistance + avoidanceExtra) - centerLine.PathLength; extraDist = Math.Min(extraDist, 5); if (extraDist > 0) { centerLine.Add(centerLine[centerLine.Count - 1] + centerLine.EndSegment.Vector.Normalize(extraDist)); } avoidanceBasePath = centerLine; Services.UIService.PushLineList(centerLine, curTimestamp, "subpath", true); Services.UIService.PushLineList(leftBound, curTimestamp, "left bound", true); Services.UIService.PushLineList(rightBound, curTimestamp, "right bound", true); // get the overall max speed looking forward from our current point settings.maxSpeed = GetMaxSpeed(curRndfPath, curRndfPath.AdvancePoint(curRndfPath.ZeroPoint, vs.speed * TahoeParams.actuation_delay)); // get the max speed at the end point settings.maxEndingSpeed = GetMaxSpeed(curRndfPath, curRndfPath.AdvancePoint(curRndfPath.ZeroPoint, planningDistance)); useAvoidancePath = false; if (sparse) { // limit to 5 mph laneWidthAtPathEnd = 20; pathAngleCheckMax = 50; pathAngleMax = 5 * Math.PI / 180.0; settings.maxSpeed = Math.Min(settings.maxSpeed, 2.2352); maxAvoidanceBasePathAdvancePoint = avoidanceBasePath.AdvancePoint(avoidanceBasePath.EndPoint, -2); //maxSmootherBasePathAdvancePoint = smootherBasePath.AdvancePoint(smootherBasePath.EndPoint, -2); LinePath leftEdge = RoadEdge.GetLeftEdgeLine(); LinePath rightEdge = RoadEdge.GetRightEdgeLine(); if (leftEdge != null) { leftLaneBounds.Add(new Boundary(leftEdge, 0.1, 1, 100, false)); } if (rightEdge != null) { rightLaneBounds.Add(new Boundary(rightEdge, 0.1, 1, 100, false)); } PlanningResult result = new PlanningResult(); ISteeringCommandGenerator commandGenerator = SparseArcVoting.SparcVote(ref prevCurvature, goalPoint); if (commandGenerator == null) { // we have a block, report dynamically infeasible result = OnDynamicallyInfeasible(null, null); } else { result.steeringCommandGenerator = commandGenerator; result.commandLabel = commandLabel; } Track(result, commandLabel); return; } else if (oncomingVehicleExists) { laneWidthAtPathEnd = 10; } BehaviorManager.TraceSource.TraceEvent(TraceEventType.Information, 0, "max speed set to {0}", settings.maxSpeed); disablePathAngleCheck = false; SmoothAndTrack(commandLabel, true); }