static void processFrameData(NatNetML.FrameOfMocapData data) { /* Parsing Rigid Body Frame Data */ for (int i = 0; i < mRigidBodies.Count; i++) { int rbID = mRigidBodies[i].ID; // Fetching rigid body IDs from the saved descriptions for (int j = 0; j < data.nRigidBodies; j++) { if (rbID == data.RigidBodies[j].ID) // When rigid body ID of the descriptions matches rigid body ID of the frame data. { NatNetML.RigidBody rb = mRigidBodies[i]; // Saved rigid body descriptions NatNetML.RigidBodyData rbData = data.RigidBodies[j]; // Received rigid body descriptions if (rbData.Tracked == true) { Console.WriteLine("\tRigidBody ({0}):", rb.Name); Console.WriteLine("\t\tpos ({0:N3}, {1:N3}, {2:N3})", rbData.x, rbData.y, rbData.z); // Rigid Body Euler Orientation float[] quat = new float[4] { rbData.qx, rbData.qy, rbData.qz, rbData.qw }; float[] eulers = new float[3]; eulers = NatNetClientML.QuatToEuler(quat, NATEulerOrder.NAT_XYZr); //Converting quat orientation into XYZ Euler representation. double xrot = RadiansToDegrees(eulers[0]); double yrot = RadiansToDegrees(eulers[1]); double zrot = RadiansToDegrees(eulers[2]); Console.WriteLine("\t\tori ({0:N3}, {1:N3}, {2:N3})", xrot, yrot, zrot); } else { Console.WriteLine("\t{0} is not tracked in current frame", rb.Name); } } } } /* Parsing Skeleton Frame Data */ for (int i = 0; i < mSkeletons.Count; i++) // Fetching skeleton IDs from the saved descriptions { int sklID = mSkeletons[i].ID; for (int j = 0; j < data.nSkeletons; j++) { if (sklID == data.Skeletons[j].ID) // When skeleton ID of the description matches skeleton ID of the frame data. { NatNetML.Skeleton skl = mSkeletons[i]; // Saved skeleton descriptions NatNetML.SkeletonData sklData = data.Skeletons[j]; // Received skeleton frame data Console.WriteLine("\tSkeleton ({0}):", skl.Name); Console.WriteLine("\t\tSegment count: {0}", sklData.nRigidBodies); /* Now, for each of the skeleton segments */ for (int k = 0; k < sklData.nRigidBodies; k++) { NatNetML.RigidBodyData boneData = sklData.RigidBodies[k]; /* Decoding skeleton bone ID */ int skeletonID = HighWord(boneData.ID); int rigidBodyID = LowWord(boneData.ID); int uniqueID = skeletonID * 1000 + rigidBodyID; int key = uniqueID.GetHashCode(); NatNetML.RigidBody bone = (RigidBody)mHtSkelRBs[key]; //Fetching saved skeleton bone descriptions //Outputting only the hip segment data for the purpose of this sample. if (k == 0) { Console.WriteLine("\t\t{0:N3}: pos({1:N3}, {2:N3}, {3:N3})", bone.Name, boneData.x, boneData.y, boneData.z); } } } } } /* Parsing Force Plate Frame Data */ for (int i = 0; i < mForcePlates.Count; i++) { int fpID = mForcePlates[i].ID; // Fetching force plate IDs from the saved descriptions for (int j = 0; j < data.nForcePlates; j++) { if (fpID == data.ForcePlates[j].ID) // When force plate ID of the descriptions matches force plate ID of the frame data. { NatNetML.ForcePlate fp = mForcePlates[i]; // Saved force plate descriptions NatNetML.ForcePlateData fpData = data.ForcePlates[i]; // Received forceplate frame data Console.WriteLine("\tForce Plate ({0}):", fp.Serial); // Here we will be printing out only the first force plate "subsample" (index 0) that was collected with the mocap frame. for (int k = 0; k < fpData.nChannels; k++) { Console.WriteLine("\t\tChannel {0}: {1}", fp.ChannelNames[k], fpData.ChannelData[k].Values[0]); } } } } Console.WriteLine("\n"); }
//static uint GPS_LEAPSECONDS_MILLIS = 18000; static void processFrameData(NatNetML.FrameOfMocapData data) { bool data_gogo = true; /* Parsing Rigid Body Frame Data */ for (int i = 0; i < mRigidBodies.Count; i++) { int rbID = mRigidBodies[i].ID; // Fetching rigid body IDs from the saved descriptions for (int j = 0; j < data.nRigidBodies; j++) { if (rbID == data.RigidBodies[j].ID) // When rigid body ID of the descriptions matches rigid body ID of the frame data. { NatNetML.RigidBody rb = mRigidBodies[i]; // Saved rigid body descriptions NatNetML.RigidBodyData rbData = data.RigidBodies[j]; // Received rigid body descriptions if (rbData.Tracked == true) { #if DEBUG_MSG Console.WriteLine("\tRigidBody ({0}):", rb.Name); Console.WriteLine("\t\tpos ({0:N3}, {1:N3}, {2:N3})", rbData.x, rbData.y, rbData.z); // Rigid Body Euler Orientation float[] quat = new float[4] { rbData.qx, rbData.qy, rbData.qz, rbData.qw }; float[] eulers = new float[3]; eulers = NatNetClientML.QuatToEuler(quat, NATEulerOrder.NAT_XYZr); //Converting quat orientation into XYZ Euler representation. double xrot = RadiansToDegrees(eulers[0]); double yrot = RadiansToDegrees(eulers[1]); double zrot = RadiansToDegrees(eulers[2]); Console.WriteLine("\t\tori ({0:N3}, {1:N3}, {2:N3})", xrot, yrot, zrot); #endif if (drones.ContainsKey(rb.Name)) { DroneData drone = drones[rb.Name]; drone.lost_count = 0; long cur_ms = stopwatch.ElapsedMilliseconds; if (drone.send_count > 0) { drone.send_count--; } else if (data_gogo) { drone.send_count = 10; data_gogo = false; MAVLink.mavlink_att_pos_mocap_t att_pos = new MAVLink.mavlink_att_pos_mocap_t(); att_pos.time_usec = (ulong)(cur_ms * 1000); att_pos.x = rbData.x; //north att_pos.y = rbData.z; //east att_pos.z = -rbData.y; //down att_pos.q = new float[4] { rbData.qw, rbData.qx, rbData.qz, -rbData.qy }; byte[] pkt = mavlinkParse.GenerateMAVLinkPacket10(MAVLink.MAVLINK_MSG_ID.ATT_POS_MOCAP, att_pos); if (drone.lastTime >= 0) { MAVLink.mavlink_vision_speed_estimate_t vis_speed = new MAVLink.mavlink_vision_speed_estimate_t(); float total_s = (cur_ms - drone.lastTime) * 0.001f; vis_speed.x = (rbData.x - drone.lastPosN) / total_s; vis_speed.y = (rbData.z - drone.lastPosE) / total_s; vis_speed.z = (-rbData.y - drone.lastPosD) / total_s; vis_speed.usec = (ulong)(cur_ms * 1000); byte[] pkt2 = mavlinkParse.GenerateMAVLinkPacket10(MAVLink.MAVLINK_MSG_ID.VISION_SPEED_ESTIMATE, vis_speed); int total_len = pkt.Length + pkt2.Length; byte[] uwb_data = new byte[10 + total_len + 1]; uwb_data[0] = 0x54; uwb_data[1] = 0xf1; uwb_data[2] = 0xff; uwb_data[3] = 0xff; uwb_data[4] = 0xff; uwb_data[5] = 0xff; uwb_data[6] = 2; uwb_data[7] = drone.uwb_tag_id; uwb_data[8] = (byte)(total_len & 0xff); uwb_data[9] = (byte)(total_len >> 16); Array.Copy(pkt, 0, uwb_data, 10, pkt.Length); Array.Copy(pkt2, 0, uwb_data, 10 + pkt.Length, pkt2.Length); byte chk_sum = 0; foreach (byte uwb_data_byte in uwb_data) { chk_sum += uwb_data_byte; } uwb_data[uwb_data.Length - 1] = chk_sum; mavSock.SendTo(uwb_data, drone.ep); } } drone.lastTime = cur_ms; drone.lastPosN = rbData.x; drone.lastPosE = rbData.z; drone.lastPosD = -rbData.y; } } else { Console.WriteLine("\t{0} is not tracked in current frame", rb.Name); /*if (drones.ContainsKey(rb.Name)) * { * DroneData drone = drones[rb.Name]; * drone.lost_count++; * if (drone.lost_count > 3) * { * drone.lost_count = 0; * MAVLink.mavlink_gps_input_t gps_input = new MAVLink.mavlink_gps_input_t(); * gps_input.gps_id = 0; * gps_input.fix_type = (byte)MAVLink.GPS_FIX_TYPE.NO_FIX; * byte[] pkt = mavlinkParse.GenerateMAVLinkPacket10(MAVLink.MAVLINK_MSG_ID.GPS_INPUT, gps_input); * mavSock.SendTo(pkt, drone.ep); * } * }*/ } } } } /* Parsing Skeleton Frame Data */ for (int i = 0; i < mSkeletons.Count; i++) // Fetching skeleton IDs from the saved descriptions { int sklID = mSkeletons[i].ID; for (int j = 0; j < data.nSkeletons; j++) { if (sklID == data.Skeletons[j].ID) // When skeleton ID of the description matches skeleton ID of the frame data. { NatNetML.Skeleton skl = mSkeletons[i]; // Saved skeleton descriptions NatNetML.SkeletonData sklData = data.Skeletons[j]; // Received skeleton frame data Console.WriteLine("\tSkeleton ({0}):", skl.Name); Console.WriteLine("\t\tSegment count: {0}", sklData.nRigidBodies); /* Now, for each of the skeleton segments */ for (int k = 0; k < sklData.nRigidBodies; k++) { NatNetML.RigidBodyData boneData = sklData.RigidBodies[k]; /* Decoding skeleton bone ID */ int skeletonID = HighWord(boneData.ID); int rigidBodyID = LowWord(boneData.ID); int uniqueID = skeletonID * 1000 + rigidBodyID; int key = uniqueID.GetHashCode(); NatNetML.RigidBody bone = (RigidBody)mHtSkelRBs[key]; //Fetching saved skeleton bone descriptions //Outputting only the hip segment data for the purpose of this sample. if (k == 0) { Console.WriteLine("\t\t{0:N3}: pos({1:N3}, {2:N3}, {3:N3})", bone.Name, boneData.x, boneData.y, boneData.z); } } } } } /* Parsing Force Plate Frame Data */ for (int i = 0; i < mForcePlates.Count; i++) { int fpID = mForcePlates[i].ID; // Fetching force plate IDs from the saved descriptions for (int j = 0; j < data.nForcePlates; j++) { if (fpID == data.ForcePlates[j].ID) // When force plate ID of the descriptions matches force plate ID of the frame data. { NatNetML.ForcePlate fp = mForcePlates[i]; // Saved force plate descriptions NatNetML.ForcePlateData fpData = data.ForcePlates[i]; // Received forceplate frame data Console.WriteLine("\tForce Plate ({0}):", fp.Serial); // Here we will be printing out only the first force plate "subsample" (index 0) that was collected with the mocap frame. for (int k = 0; k < fpData.nChannels; k++) { Console.WriteLine("\t\tChannel {0}: {1}", fp.ChannelNames[k], fpData.ChannelData[k].Values[0]); } } } } #if DEBUG_MSG Console.WriteLine("\n"); #endif }