Esempio n. 1
0
        public void Update(ManagedHand managedHand, Vector3 keyPointLocation, params Vector3[] decayPoints)
        {
            if (!managedHand.Visible)
            {
                //lost:
                if (Visible)
                {
                    FireLostEvent();
                    _progress.locationHistory.Clear();
                }

                return;
            }

            //visibility status:
            bool currentVisibility = true;

            //too close to next joint in chain means visibility failed:
            if (Vector3.Distance(keyPointLocation, _mainCamera.transform.position) < _minHeadDistance)
            {
                currentVisibility = false;
            }
            else
            {
                for (int i = 0; i < decayPoints.Length; i++)
                {
                    if (Vector3.Distance(keyPointLocation, decayPoints[i]) < _lostKeyPointDistance)
                    {
                        currentVisibility = false;
                        break;
                    }
                }
            }

            positionRaw = keyPointLocation;

            //lost visibility:
            if (!currentVisibility && Visible)
            {
                FireLostEvent();
                _progress.locationHistory.Clear();
                return;
            }

            //history cache:
            _progress.locationHistory.Add(keyPointLocation);

            //only need 3 in our history:
            if (_progress.locationHistory.Count > 3)
            {
                _progress.locationHistory.RemoveAt(0);
            }

            //we have enough history:
            if (_progress.locationHistory.Count == 3)
            {
                //movement intent stats:
                Vector3 vectorA = _progress.locationHistory[_progress.locationHistory.Count - 2] - _progress.locationHistory[_progress.locationHistory.Count - 3];
                Vector3 vectorB = _progress.locationHistory[_progress.locationHistory.Count - 1] - _progress.locationHistory[_progress.locationHistory.Count - 2];
                float   delta   = Vector3.Distance(_progress.locationHistory[_progress.locationHistory.Count - 3], _progress.locationHistory[_progress.locationHistory.Count - 1]);
                float   angle   = Vector3.Angle(vectorA, vectorB);
                Stability = 1 - Mathf.Clamp01(delta / _maxDistance);

                //moving in a constant direction?
                if (angle < 90)
                {
                    _progress.target = _progress.locationHistory[_progress.locationHistory.Count - 1];
                }

                //snap or smooth:
                if (Stability == 0)
                {
                    positionFiltered = _progress.target;
                }
                else
                {
                    positionFiltered = Vector3.SmoothDamp(positionFiltered, _progress.target, ref _progress.velocity, _smoothTime * Stability);
                }
            }
            else
            {
                positionFiltered = keyPointLocation;
            }

            //inside the camera plane - flatten against the plane?
            InsideClipPlane = TransformUtilities.InsideClipPlane(positionFiltered);
            if (InsideClipPlane)
            {
                if (HideInsideClipPlane)
                {
                    positionFiltered = keyPointLocation;
                    FireLostEvent();
                    _progress.locationHistory.Clear();
                    return;
                }
                positionFiltered = TransformUtilities.LocationOnClipPlane(positionFiltered);
            }

            //gained visibility:
            if (currentVisibility && !Visible)
            {
                //we must also break distance for point proximity:
                for (int i = 0; i < decayPoints.Length; i++)
                {
                    if (Vector3.Distance(keyPointLocation, decayPoints[i]) < _foundKeyPointDistance)
                    {
                        currentVisibility = false;
                        break;
                    }
                }

                //still good?
                if (currentVisibility)
                {
                    FireFoundEvent();
                }
            }
        }
        //Public Methods:
        public void Update()
        {
            //update keypoints and fingers:
            WristCenter.Update(_managedHand, _managedHand.Hand.Wrist.Center.Position, _managedHand.Hand.Center);
            HandCenter.Update(_managedHand, _managedHand.Hand.Center);
            _thumbMCP.Update(_managedHand, _managedHand.Hand.Thumb.MCP.Position, _managedHand.Hand.Index.MCP.Position, _managedHand.Hand.Center);
            _thumbPIP.Update(_managedHand, _managedHand.Hand.Thumb.IP.Position, _managedHand.Hand.Thumb.MCP.Position, _managedHand.Hand.Center);
            _thumbTip.Update(_managedHand, _managedHand.Hand.Thumb.Tip.Position, _managedHand.Hand.Thumb.IP.Position, _managedHand.Hand.Middle.Tip.Position, _managedHand.Hand.Thumb.MCP.Position, _managedHand.Hand.Center);
            Thumb.Update();
            _indexMCP.Update(_managedHand, _managedHand.Hand.Index.MCP.Position, _managedHand.Hand.Center);
            _indexPIP.Update(_managedHand, _managedHand.Hand.Index.PIP.Position, _managedHand.Hand.Index.MCP.Position, _managedHand.Hand.Center);
            _indexTip.Update(_managedHand, _managedHand.Hand.Index.Tip.Position, _managedHand.Hand.Index.PIP.Position, _managedHand.Hand.Index.MCP.Position, _managedHand.Hand.Center, _managedHand.Hand.Thumb.IP.Position, _managedHand.Hand.Middle.Tip.Position);
            Index.Update();
            _middleMCP.Update(_managedHand, _managedHand.Hand.Middle.MCP.Position, _managedHand.Hand.Center);
            _middlePIP.Update(_managedHand, _managedHand.Hand.Middle.PIP.Position, _managedHand.Hand.Middle.MCP.Position, _managedHand.Hand.Center);
            _middleTip.Update(_managedHand, _managedHand.Hand.Middle.Tip.Position, _managedHand.Hand.Middle.PIP.Position, _managedHand.Hand.Middle.MCP.Position, _managedHand.Hand.Ring.Tip.Position, _managedHand.Hand.Center);
            Middle.Update();
            _ringMCP.Update(_managedHand, _managedHand.Hand.Ring.MCP.Position, _managedHand.Hand.Center);
            _ringTip.Update(_managedHand, _managedHand.Hand.Ring.Tip.Position, _managedHand.Hand.Ring.MCP.Position, _managedHand.Hand.Pinky.Tip.Position, _managedHand.Hand.Middle.Tip.Position, _managedHand.Hand.Center);
            Ring.Update();
            _pinkyMCP.Update(_managedHand, _managedHand.Hand.Pinky.MCP.Position, _managedHand.Hand.Center);
            _pinkyTip.Update(_managedHand, _managedHand.Hand.Pinky.Tip.Position, _managedHand.Hand.Pinky.MCP.Position, _managedHand.Hand.Ring.Tip.Position, _managedHand.Hand.Center);
            Pinky.Update();

            //we need a hand to continue:
            if (!_managedHand.Visible)
            {
                return;
            }

            //correct distances:
            float thumbMcpToWristDistance = Vector3.Distance(_thumbMCP.positionFiltered, WristCenter.positionFiltered) * .5f;
            //fix the distance between the wrist and thumbMcp as it incorrectly expands as the hand gets further from the camera:
            float distancePercentage = Mathf.Clamp01(Vector3.Distance(_mainCamera.transform.position, WristCenter.positionFiltered) / .5f);

            distancePercentage       = 1 - Percentage(distancePercentage, .90f, 1) * .4f;
            thumbMcpToWristDistance *= distancePercentage;
            Vector3 wristToPalmDirection = Vector3.Normalize(Vector3.Normalize(HandCenter.positionFiltered - WristCenter.positionFiltered));
            Vector3 center = WristCenter.positionFiltered + (wristToPalmDirection * thumbMcpToWristDistance);
            Vector3 camToWristDirection = Vector3.Normalize(WristCenter.positionFiltered - _mainCamera.transform.position);

            //rays needed for planarity discovery for in/out palm facing direction:
            Vector3 camToWrist    = new Ray(WristCenter.positionFiltered, camToWristDirection).GetPoint(1);
            Vector3 camToThumbMcp = new Ray(_thumbMCP.positionFiltered, Vector3.Normalize(_thumbMCP.positionFiltered - _mainCamera.transform.position)).GetPoint(1);
            Vector3 camToPalm     = new Ray(center, Vector3.Normalize(center - _mainCamera.transform.position)).GetPoint(1);

            //discover palm facing direction to camera:
            Plane palmFacingPlane = new Plane(camToWrist, camToPalm, camToThumbMcp);

            if (_managedHand.Hand.Type == MLHandTracking.HandType.Left)
            {
                palmFacingPlane.Flip();
            }
            float palmForwardFacing = Mathf.Sign(Vector3.Dot(palmFacingPlane.normal, _mainCamera.transform.forward));

            //use thumb/palm/wrist alignment to determine amount of roll in the hand:
            Vector3 toThumbMcp     = Vector3.Normalize(_thumbMCP.positionFiltered - center);
            Vector3 toPalm         = Vector3.Normalize(center - WristCenter.positionFiltered);
            float   handRollAmount = (1 - Vector3.Dot(toThumbMcp, toPalm)) * palmForwardFacing;

            //where between the wrist and thumbMcp should we slide inwards to get the palm in the center:
            Vector3 toPalmOrigin = Vector3.Lerp(WristCenter.positionFiltered, _thumbMCP.positionFiltered, .35f);

            //get a direction from the camera to toPalmOrigin as psuedo up for use in quaternion construction:
            Vector3 toCam = Vector3.Normalize(_mainCamera.transform.position - toPalmOrigin);

            //construct a quaternion that helps get angles needed between the wrist and thumbMCP to point towards the palm center:
            Vector3    wristToThumbMcp       = Vector3.Normalize(_thumbMCP.positionFiltered - WristCenter.positionFiltered);
            Quaternion towardsCamUpReference = Quaternion.identity;

            if (wristToThumbMcp != Vector3.zero && toCam != Vector3.zero)
            {
                towardsCamUpReference = Quaternion.LookRotation(wristToThumbMcp, toCam);
            }

            //rotate the inwards vector depending on hand roll to know where to push the palm back:
            float inwardsVectorRotation = 90;

            if (_managedHand.Hand.Type == MLHandTracking.HandType.Left)
            {
                inwardsVectorRotation = -90;
            }
            towardsCamUpReference = Quaternion.AngleAxis(handRollAmount * inwardsVectorRotation, towardsCamUpReference * Vector3.forward) * towardsCamUpReference;
            Vector3 inwardsVector = towardsCamUpReference * Vector3.up;

            //slide palm location along inwards vector to get it into proper physical location in the center of the hand:
            center = toPalmOrigin - inwardsVector * thumbMcpToWristDistance;
            Vector3 deadCenter = center;

            //as the hand flattens back out balance corrected location with originally provided location for better forward origin:
            center = Vector3.Lerp(center, HandCenter.positionFiltered, Mathf.Abs(handRollAmount));

            //get a forward using the corrected palm location:
            Vector3 forward = Vector3.Normalize(center - WristCenter.positionFiltered);

            //switch back to physical center of hand - this reduces surface-to-surface movement of the center between back and palm:
            center = deadCenter;

            //get an initial hand up:
            Plane handPlane = new Plane(WristCenter.positionFiltered, _thumbMCP.positionFiltered, center);

            if (_managedHand.Hand.Type == MLHandTracking.HandType.Left)
            {
                handPlane.Flip();
            }
            Vector3 up = handPlane.normal;

            //find out how much the back of the hand is facing the camera so we have a safe set of features for a stronger forward:
            Vector3 centerToCam = Vector3.Normalize(_mainCamera.transform.position - WristCenter.positionFiltered);
            float   facingDot   = Vector3.Dot(centerToCam, up);

            if (facingDot > .5f)
            {
                float handBackFacingCamAmount = Percentage(facingDot, .5f, 1);

                //steer forward for more accuracy based on the visibility of the back of the hand:
                if (_middleMCP.Visible)
                {
                    Vector3 toMiddleMcp = Vector3.Normalize(_middleMCP.positionFiltered - center);
                    forward = Vector3.Lerp(forward, toMiddleMcp, handBackFacingCamAmount);
                }
                else if (_indexMCP.Visible)
                {
                    Vector3 inIndexMcp = Vector3.Normalize(_indexMCP.positionFiltered - center);
                    forward = Vector3.Lerp(forward, inIndexMcp, handBackFacingCamAmount);
                }
            }

            //make sure palm distance from wrist is consistant while also leveraging steered forward:
            center = WristCenter.positionFiltered + (forward * thumbMcpToWristDistance);

            //an initial rotation of the hand:
            Quaternion orientation = Quaternion.identity;

            if (forward != Vector3.zero && up != Vector3.zero)
            {
                orientation = Quaternion.LookRotation(forward, up);
            }

            //as the hand rolls counter-clockwise the thumbMcp loses accuracy so we need to interpolate to the back of the hand's features:
            if (_indexMCP.Visible && _middleMCP.Visible)
            {
                Vector3 knucklesVector = Vector3.Normalize(_middleMCP.positionFiltered - _indexMCP.positionFiltered);
                float   knucklesDot    = Vector3.Dot(knucklesVector, Vector3.up);
                if (knucklesDot > .5f)
                {
                    float counterClockwiseRoll = Percentage(Vector3.Dot(knucklesVector, Vector3.up), .35f, .7f);
                    center  = Vector3.Lerp(center, HandCenter.positionFiltered, counterClockwiseRoll);
                    forward = Vector3.Lerp(forward, Vector3.Normalize(_middleMCP.positionFiltered - HandCenter.positionFiltered), counterClockwiseRoll);
                    Plane backHandPlane = new Plane(HandCenter.positionFiltered, _indexMCP.positionFiltered, _middleMCP.positionFiltered);
                    if (_managedHand.Hand.Type == MLHandTracking.HandType.Left)
                    {
                        backHandPlane.Flip();
                    }
                    up          = Vector3.Lerp(up, backHandPlane.normal, counterClockwiseRoll);
                    orientation = Quaternion.LookRotation(forward, up);
                }
            }

            //as the wrist tilts away from the camera (with the thumb down) at extreme angles the hand center will move toward the thumb:
            float   handTiltAwayAmount          = 1 - Percentage(Vector3.Distance(HandCenter.positionFiltered, WristCenter.positionFiltered), .025f, .04f);
            Vector3 handTiltAwayCorrectionPoint = WristCenter.positionFiltered + camToWristDirection * thumbMcpToWristDistance;

            center  = Vector3.Lerp(center, handTiltAwayCorrectionPoint, handTiltAwayAmount);
            forward = Vector3.Lerp(forward, Vector3.Normalize(handTiltAwayCorrectionPoint - WristCenter.positionFiltered), handTiltAwayAmount);
            Plane wristPlane = new Plane(WristCenter.positionFiltered, _thumbMCP.positionFiltered, center);

            if (_managedHand.Hand.Type == MLHandTracking.HandType.Left)
            {
                wristPlane.Flip();
            }
            up = Vector3.Lerp(up, wristPlane.normal, handTiltAwayAmount);
            if (forward != Vector3.zero && up != Vector3.zero)
            {
                orientation = Quaternion.LookRotation(forward, up);
            }

            //steering for if thumb/index are not available from self-occlusion to help rotate the hand better outwards better:
            float forwardUpAmount = Vector3.Dot(forward, Vector3.up);

            if (forwardUpAmount > .7f && _indexMCP.Visible && _ringMCP.Visible)
            {
                float angle = 0;
                if (_managedHand.Hand.Type == MLHandTracking.HandType.Right)
                {
                    Vector3 knucklesVector = Vector3.Normalize(_ringMCP.positionFiltered - _indexMCP.positionFiltered);
                    angle  = Vector3.Angle(knucklesVector, orientation * Vector3.right);
                    angle *= -1;
                }
                else
                {
                    Vector3 knucklesVector = Vector3.Normalize(_indexMCP.positionFiltered - _ringMCP.positionFiltered);
                    angle = Vector3.Angle(knucklesVector, orientation * Vector3.right);
                }
                Quaternion selfOcclusionSteering = Quaternion.AngleAxis(angle, forward);
                orientation = selfOcclusionSteering * orientation;
            }
            else
            {
                //when palm is facing down we need to rotate some to compensate for an offset:
                float rollCorrection       = Mathf.Clamp01(Vector3.Dot(orientation * Vector3.up, Vector3.up));
                float rollCorrectionAmount = -30;
                if (_managedHand.Hand.Type == MLHandTracking.HandType.Left)
                {
                    rollCorrectionAmount = 30;
                }
                orientation = Quaternion.AngleAxis(rollCorrectionAmount * rollCorrection, forward) * orientation;
            }

            //inside the camera plane:
            InsideClipPlane = TransformUtilities.InsideClipPlane(center);

            //set pose:
            Position = center;
            Rotation = orientation;

            UpdateKeypointRotations();
        }