00001
00002
00003
00004
00005
00006
00007
00008
00009
00010
00011
00012
00013
00014
00015
00016
00017
00018
00019
00020
00021
00022
00023
00024
00025
00026
00027
00028
00029
00030
00031
00032
00033
00034
00035
00036 #include <assert.h>
00037 #include <math.h>
00038 #include <iostream>
00039
00040 #include <boost/format.hpp>
00041
00042 #include "microstrain_3dmgx2_imu/3dmgx2.h"
00043
00044 #include "ros/time.h"
00045 #include "self_test/self_test.h"
00046 #include "diagnostic_msgs/DiagnosticStatus.h"
00047 #include "diagnostic_updater/diagnostic_updater.h"
00048 #include "diagnostic_updater/update_functions.h"
00049 #include "diagnostic_updater/DiagnosticStatusWrapper.h"
00050
00051 #include "sensor_msgs/Imu.h"
00052 #include "std_srvs/Empty.h"
00053
00054 #include "tf/transform_datatypes.h"
00055 #include "microstrain_3dmgx2_imu/AddOffset.h"
00056
00057 #include "std_msgs/Bool.h"
00058
00059 using namespace std;
00060
00061 class ImuNode
00062 {
00063 public:
00064 microstrain_3dmgx2_imu::IMU imu;
00065 sensor_msgs::Imu reading;
00066
00067 string port;
00068
00069 microstrain_3dmgx2_imu::IMU::cmd cmd;
00070
00071 self_test::TestRunner self_test_;
00072 diagnostic_updater::Updater diagnostic_;
00073
00074 ros::NodeHandle node_handle_;
00075 ros::NodeHandle private_node_handle_;
00076 ros::Publisher imu_data_pub_;
00077 ros::ServiceServer add_offset_serv_;
00078 ros::ServiceServer calibrate_serv_;
00079 ros::Publisher is_calibrated_pub_;
00080
00081 bool running;
00082
00083 bool autocalibrate_;
00084 bool calibrate_requested_;
00085 bool calibrated_;
00086
00087 int error_count_;
00088 int slow_count_;
00089 std::string was_slow_;
00090 std::string error_status_;
00091
00092 string frameid_;
00093
00094 double offset_;
00095
00096 double bias_x_;
00097 double bias_y_;
00098 double bias_z_;
00099
00100 double angular_velocity_stdev_, angular_velocity_covariance_;
00101 double linear_acceleration_covariance_, linear_acceleration_stdev_;
00102 double orientation_covariance_, orientation_stdev_;
00103
00104 double max_drift_rate_;
00105
00106 double desired_freq_;
00107 diagnostic_updater::FrequencyStatus freq_diag_;
00108
00109 ImuNode(ros::NodeHandle h) : self_test_(), diagnostic_(),
00110 node_handle_(h), private_node_handle_("~"), calibrate_requested_(false),
00111 error_count_(0),
00112 slow_count_(0),
00113 desired_freq_(100),
00114 freq_diag_(diagnostic_updater::FrequencyStatusParam(&desired_freq_, &desired_freq_, 0.05))
00115 {
00116 ros::NodeHandle imu_node_handle(node_handle_, "imu");
00117
00118 private_node_handle_.param("autocalibrate", autocalibrate_, true);
00119 private_node_handle_.param("assume_calibrated", calibrated_, false);
00120 private_node_handle_.param("port", port, string("/dev/ttyUSB0"));
00121 private_node_handle_.param("max_drift_rate", max_drift_rate_, 0.000100);
00122
00123
00124 imu_data_pub_ = imu_node_handle.advertise<sensor_msgs::Imu>("data", 100);
00125 add_offset_serv_ = private_node_handle_.advertiseService("add_offset", &ImuNode::addOffset, this);
00126 calibrate_serv_ = imu_node_handle.advertiseService("calibrate", &ImuNode::calibrate, this);
00127 is_calibrated_pub_ = imu_node_handle.advertise<std_msgs::Bool>("is_calibrated", 1, true);
00128
00129 publish_is_calibrated();
00130
00131 cmd = microstrain_3dmgx2_imu::IMU::CMD_ACCEL_ANGRATE_ORIENT;
00132
00133 running = false;
00134
00135 bias_x_ = bias_y_ = bias_z_ = 0;
00136
00137 private_node_handle_.param("frame_id", frameid_, string("imu"));
00138 reading.header.frame_id = frameid_;
00139
00140 private_node_handle_.param("time_offset", offset_, 0.0);
00141
00142 private_node_handle_.param("linear_acceleration_stdev", linear_acceleration_stdev_, 0.098);
00143 private_node_handle_.param("orientation_stdev", orientation_stdev_, 0.035);
00144 private_node_handle_.param("angular_velocity_stdev", angular_velocity_stdev_, 0.012);
00145
00146 double angular_velocity_covariance = angular_velocity_stdev_ * angular_velocity_stdev_;
00147 double orientation_covariance = orientation_stdev_ * orientation_stdev_;
00148 double linear_acceleration_covariance = linear_acceleration_stdev_ * linear_acceleration_stdev_;
00149
00150 reading.linear_acceleration_covariance[0] = linear_acceleration_covariance;
00151 reading.linear_acceleration_covariance[4] = linear_acceleration_covariance;
00152 reading.linear_acceleration_covariance[8] = linear_acceleration_covariance;
00153
00154 reading.angular_velocity_covariance[0] = angular_velocity_covariance;
00155 reading.angular_velocity_covariance[4] = angular_velocity_covariance;
00156 reading.angular_velocity_covariance[8] = angular_velocity_covariance;
00157
00158 reading.orientation_covariance[0] = orientation_covariance;
00159 reading.orientation_covariance[4] = orientation_covariance;
00160 reading.orientation_covariance[8] = orientation_covariance;
00161
00162 self_test_.add("Close Test", this, &ImuNode::pretest);
00163 self_test_.add("Interruption Test", this, &ImuNode::InterruptionTest);
00164 self_test_.add("Connect Test", this, &ImuNode::ConnectTest);
00165 self_test_.add("Read ID Test", this, &ImuNode::ReadIDTest);
00166 self_test_.add("Gyro Bias Test", this, &ImuNode::GyroBiasTest);
00167 self_test_.add("Streamed Data Test", this, &ImuNode::StreamedDataTest);
00168 self_test_.add("Gravity Test", this, &ImuNode::GravityTest);
00169 self_test_.add("Disconnect Test", this, &ImuNode::DisconnectTest);
00170 self_test_.add("Resume Test", this, &ImuNode::ResumeTest);
00171
00172 diagnostic_.add( freq_diag_ );
00173 diagnostic_.add( "Calibration Status", this, &ImuNode::calibrationStatus );
00174 diagnostic_.add( "IMU Status", this, &ImuNode::deviceStatus );
00175 }
00176
00177 ~ImuNode()
00178 {
00179 stop();
00180 }
00181
00182 void setErrorStatusf(const char *format, ...)
00183 {
00184 va_list va;
00185 char buff[1000];
00186 va_start(va, format);
00187 if (vsnprintf(buff, 1000, format, va) >= 1000)
00188 ROS_DEBUG("Really long string in setErrorStatus, it was truncated.");
00189 std::string value = std::string(buff);
00190 setErrorStatus(buff);
00191 }
00192
00193
00194 void setErrorStatus(const std::string msg)
00195 {
00196 if (error_status_ != msg)
00197 {
00198 error_status_ = msg;
00199 ROS_ERROR("%s You may find further details at http://www.ros.org/wiki/microstrain_3dmgx2_imu/Troubleshooting", msg.c_str());
00200 }
00201 else
00202 {
00203 ROS_DEBUG("%s You may find further details at http://www.ros.org/wiki/microstrain_3dmgx2_imu/Troubleshooting", msg.c_str());
00204 }
00205 }
00206
00207 void clearErrorStatus()
00208 {
00209 error_status_.clear();
00210 }
00211
00212 int start()
00213 {
00214 stop();
00215
00216 try
00217 {
00218 try
00219 {
00220 imu.openPort(port.c_str());
00221 } catch (microstrain_3dmgx2_imu::Exception& e) {
00222 error_count_++;
00223 setErrorStatus(e.what());
00224 diagnostic_.broadcast(2, e.what());
00225 return -1;
00226 }
00227
00228 diagnostic_.setHardwareID(getID(true));
00229
00230 if (autocalibrate_ || calibrate_requested_)
00231 {
00232 doCalibrate();
00233 calibrate_requested_ = false;
00234 autocalibrate_ = false;
00235 }
00236 else
00237 {
00238 ROS_INFO("Not calibrating the IMU sensor. Use the calibrate service to calibrate it before use.");
00239 }
00240
00241 ROS_INFO("Initializing IMU time with offset %f.", offset_);
00242
00243 imu.initTime(offset_);
00244
00245 ROS_INFO("IMU sensor initialized.");
00246
00247 imu.setContinuous(cmd);
00248
00249 freq_diag_.clear();
00250
00251 running = true;
00252
00253 } catch (microstrain_3dmgx2_imu::Exception& e) {
00254 error_count_++;
00255 setErrorStatusf("Exception thrown while starting IMU. This sometimes happens if you are not connected to an IMU or if another process is trying to access the IMU port. You may try 'lsof|grep %s' to see if other processes have the port open. %s", port.c_str(), e.what());
00256 diagnostic_.broadcast(2, "Error opening IMU.");
00257 return -1;
00258 }
00259
00260 return(0);
00261 }
00262
00263 std::string getID(bool output_info = false)
00264 {
00265 char dev_name[17];
00266 char dev_model_num[17];
00267 char dev_serial_num[17];
00268 char dev_opt[17];
00269 imu.getDeviceIdentifierString(microstrain_3dmgx2_imu::IMU::ID_DEVICE_NAME, dev_name);
00270 imu.getDeviceIdentifierString(microstrain_3dmgx2_imu::IMU::ID_MODEL_NUMBER, dev_model_num);
00271 imu.getDeviceIdentifierString(microstrain_3dmgx2_imu::IMU::ID_SERIAL_NUMBER, dev_serial_num);
00272 imu.getDeviceIdentifierString(microstrain_3dmgx2_imu::IMU::ID_DEVICE_OPTIONS, dev_opt);
00273
00274 if (output_info)
00275 ROS_INFO("Connected to IMU [%s] model [%s] s/n [%s] options [%s]",
00276 dev_name, dev_model_num, dev_serial_num, dev_opt);
00277
00278 char *dev_name_ptr = dev_name;
00279 char *dev_model_num_ptr = dev_model_num;
00280 char *dev_serial_num_ptr = dev_serial_num;
00281
00282 while (*dev_name_ptr == ' ')
00283 dev_name_ptr++;
00284 while (*dev_model_num_ptr == ' ')
00285 dev_model_num_ptr++;
00286 while (*dev_serial_num_ptr == ' ')
00287 dev_serial_num_ptr++;
00288
00289 return (boost::format("%s_%s-%s")%dev_name_ptr%dev_model_num_ptr%dev_serial_num_ptr).str();
00290 }
00291
00292 int stop()
00293 {
00294 if(running)
00295 {
00296 try
00297 {
00298 imu.closePort();
00299 } catch (microstrain_3dmgx2_imu::Exception& e) {
00300 error_count_++;
00301 ROS_INFO("Exception thrown while stopping IMU. %s", e.what());
00302 }
00303 running = false;
00304 }
00305
00306 return(0);
00307 }
00308
00309 int publish_datum()
00310 {
00311 try
00312 {
00313 static double prevtime = 0;
00314 double starttime = ros::Time::now().toSec();
00315 if (prevtime && prevtime - starttime > 0.05)
00316 {
00317 ROS_WARN("Full IMU loop took %f ms. Nominal is 10ms.", 1000 * (prevtime - starttime));
00318 was_slow_ = "Full IMU loop was slow.";
00319 slow_count_++;
00320 }
00321 getData(reading);
00322 double endtime = ros::Time::now().toSec();
00323 if (endtime - starttime > 0.05)
00324 {
00325 ROS_WARN("Gathering data took %f ms. Nominal is 10ms.", 1000 * (endtime - starttime));
00326 was_slow_ = "Full IMU loop was slow.";
00327 slow_count_++;
00328 }
00329 prevtime = starttime;
00330 starttime = ros::Time::now().toSec();
00331 imu_data_pub_.publish(reading);
00332 endtime = ros::Time::now().toSec();
00333 if (endtime - starttime > 0.05)
00334 {
00335 ROS_WARN("Publishing took %f ms. Nominal is 10 ms.", 1000 * (endtime - starttime));
00336 was_slow_ = "Full IMU loop was slow.";
00337 slow_count_++;
00338 }
00339
00340 freq_diag_.tick();
00341 clearErrorStatus();
00342 } catch (microstrain_3dmgx2_imu::Exception& e) {
00343 error_count_++;
00344 usleep(20000);
00345 if (!ros::isShuttingDown())
00346 ROS_WARN("Exception thrown while trying to get the IMU reading. This sometimes happens due to a communication glitch, or if another process is trying to access the IMU port. You may try 'lsof|grep %s' to see if other processes have the port open. %s", port.c_str(), e.what());
00347 return -1;
00348 }
00349
00350 return(0);
00351 }
00352
00353 bool spin()
00354 {
00355 while (!ros::isShuttingDown())
00356 {
00357 if (start() == 0)
00358 {
00359 while(node_handle_.ok()) {
00360 if(publish_datum() < 0)
00361 break;
00362 self_test_.checkTest();
00363 diagnostic_.update();
00364 ros::spinOnce();
00365 }
00366 } else {
00367
00368
00369 usleep(1000000);
00370 self_test_.checkTest();
00371 ros::spinOnce();
00372 }
00373 }
00374
00375 stop();
00376
00377 return true;
00378 }
00379
00380 void publish_is_calibrated()
00381 {
00382 std_msgs::Bool msg;
00383 msg.data = calibrated_;
00384 is_calibrated_pub_.publish(msg);
00385 }
00386
00387 void pretest(diagnostic_updater::DiagnosticStatusWrapper& status)
00388 {
00389 try
00390 {
00391 imu.closePort();
00392
00393 status.summary(0, "Device closed successfully.");
00394 } catch (microstrain_3dmgx2_imu::Exception& e) {
00395 status.summary(1, "Failed to close device.");
00396 }
00397 }
00398
00399 void InterruptionTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00400 {
00401 if (imu_data_pub_.getNumSubscribers() == 0 )
00402 status.summary(0, "No operation interrupted.");
00403 else
00404 status.summary(1, "There were active subscribers. Running of self test interrupted operations.");
00405 }
00406
00407 void ConnectTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00408 {
00409 imu.openPort(port.c_str());
00410
00411 status.summary(0, "Connected successfully.");
00412 }
00413
00414 void ReadIDTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00415 {
00416 self_test_.setID(getID());
00417
00418 status.summary(0, "Read Successfully");
00419 }
00420
00421 void GyroBiasTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00422 {
00423 imu.initGyros(&bias_x_, &bias_y_, &bias_z_);
00424
00425 status.summary(0, "Successfully calculated gyro biases.");
00426
00427 status.add("Bias_X", bias_x_);
00428 status.add("Bias_Y", bias_y_);
00429 status.add("Bias_Z", bias_z_);
00430 }
00431
00432
00433 void getData(sensor_msgs::Imu& data)
00434 {
00435 uint64_t time;
00436 double accel[3];
00437 double angrate[3];
00438 double orientation[9];
00439
00440 imu.receiveAccelAngrateOrientation(&time, accel, angrate, orientation);
00441 data.linear_acceleration.x = accel[0];
00442 data.linear_acceleration.y = accel[1];
00443 data.linear_acceleration.z = accel[2];
00444
00445 data.angular_velocity.x = angrate[0];
00446 data.angular_velocity.y = angrate[1];
00447 data.angular_velocity.z = angrate[2];
00448
00449 btQuaternion quat;
00450 (btMatrix3x3(-1,0,0,
00451 0,1,0,
00452 0,0,-1)*
00453 btMatrix3x3(orientation[0], orientation[3], orientation[6],
00454 orientation[1], orientation[4], orientation[7],
00455 orientation[2], orientation[5], orientation[8])).getRotation(quat);
00456
00457 tf::quaternionTFToMsg(quat, data.orientation);
00458
00459 data.header.stamp = ros::Time::now().fromNSec(time);
00460 }
00461
00462
00463 void StreamedDataTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00464 {
00465 uint64_t time;
00466 double accel[3];
00467 double angrate[3];
00468
00469 if (!imu.setContinuous(microstrain_3dmgx2_imu::IMU::CMD_ACCEL_ANGRATE))
00470 {
00471 status.summary(2, "Could not start streaming data.");
00472 } else {
00473
00474 for (int i = 0; i < 100; i++)
00475 {
00476 imu.receiveAccelAngrate(&time, accel, angrate);
00477 }
00478
00479 imu.stopContinuous();
00480
00481 status.summary(0, "Data streamed successfully.");
00482 }
00483 }
00484
00485 void GravityTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00486 {
00487 uint64_t time;
00488 double accel[3];
00489 double angrate[3];
00490
00491 double grav = 0.0;
00492
00493 double grav_x = 0.0;
00494 double grav_y = 0.0;
00495 double grav_z = 0.0;
00496
00497 if (!imu.setContinuous(microstrain_3dmgx2_imu::IMU::CMD_ACCEL_ANGRATE))
00498 {
00499 status.summary(2, "Could not start streaming data.");
00500 } else {
00501
00502 int num = 200;
00503
00504 for (int i = 0; i < num; i++)
00505 {
00506 imu.receiveAccelAngrate(&time, accel, angrate);
00507
00508 grav_x += accel[0];
00509 grav_y += accel[1];
00510 grav_z += accel[2];
00511
00512 }
00513
00514 imu.stopContinuous();
00515
00516 grav += sqrt( pow(grav_x / (double)(num), 2.0) +
00517 pow(grav_y / (double)(num), 2.0) +
00518 pow(grav_z / (double)(num), 2.0));
00519
00520
00521 double err = (grav - 9.796);
00522
00523 if (fabs(err) < .05)
00524 {
00525 status.summary(0, "Gravity detected correctly.");
00526 } else {
00527 status.summaryf(2, "Measured gravity deviates by %f", err);
00528 }
00529
00530 status.add("Measured gravity", grav);
00531 status.add("Gravity error", err);
00532 }
00533 }
00534
00535 void DisconnectTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00536 {
00537 imu.closePort();
00538
00539 status.summary(0, "Disconnected successfully.");
00540 }
00541
00542 void ResumeTest(diagnostic_updater::DiagnosticStatusWrapper& status)
00543 {
00544 if (running)
00545 {
00546
00547 imu.openPort(port.c_str());
00548 freq_diag_.clear();
00549
00550 if (imu.setContinuous(cmd) != true)
00551 {
00552 status.summary(2, "Failed to resume previous mode of operation.");
00553 return;
00554 }
00555 }
00556
00557 status.summary(0, "Previous operation resumed successfully.");
00558 }
00559
00560 void deviceStatus(diagnostic_updater::DiagnosticStatusWrapper &status)
00561 {
00562 if (!running)
00563 status.summary(2, "IMU is stopped");
00564 else if (!was_slow_.empty())
00565 {
00566 status.summary(1, "Excessive delay");
00567 was_slow_.clear();
00568 }
00569 else
00570 status.summary(0, "IMU is running");
00571
00572 status.add("Device", port);
00573 status.add("TF frame", frameid_);
00574 status.add("Error count", error_count_);
00575 status.add("Excessive delay", slow_count_);
00576 }
00577
00578 void calibrationStatus(diagnostic_updater::DiagnosticStatusWrapper& status)
00579 {
00580 if (calibrated_)
00581 {
00582 status.summary(0, "Gyro is calibrated");
00583 status.add("X bias", bias_x_);
00584 status.add("Y bias", bias_y_);
00585 status.add("Z bias", bias_z_);
00586 }
00587 else
00588 status.summary(2, "Gyro not calibrated");
00589
00590
00591
00592 }
00593
00594 bool addOffset(microstrain_3dmgx2_imu::AddOffset::Request &req, microstrain_3dmgx2_imu::AddOffset::Response &resp)
00595 {
00596 double offset = req.add_offset;
00597 offset_ += offset;
00598
00599 ROS_INFO("Adding %f to existing IMU time offset.", offset);
00600 ROS_INFO("Total IMU time offset is now %f.", offset_);
00601
00602
00603 imu.setFixedOffset(offset_);
00604
00605
00606 private_node_handle_.setParam("time_offset", offset_);
00607
00608
00609 resp.total_offset = offset_;
00610
00611 return true;
00612 }
00613
00614 bool calibrate(std_srvs::Empty::Request &req, std_srvs::Empty::Response &resp)
00615 {
00616 bool old_running = running;
00617
00618 try
00619 {
00620 calibrate_requested_ = true;
00621 if (old_running)
00622 {
00623 stop();
00624 start();
00625 }
00626 else
00627 {
00628 imu.openPort(port.c_str());
00629 doCalibrate();
00630 imu.closePort();
00631 }
00632 } catch (microstrain_3dmgx2_imu::Exception& e) {
00633 error_count_++;
00634 ROS_ERROR("Exception thrown while calibrating IMU %s", e.what());
00635 stop();
00636 if (old_running)
00637 start();
00638 return false;
00639 }
00640
00641 return true;
00642 }
00643
00644 void doCalibrate()
00645 {
00646 ROS_INFO("Calibrating IMU gyros.");
00647 imu.initGyros(&bias_x_, &bias_y_, &bias_z_);
00648
00649
00650 if (!imu.setContinuous(microstrain_3dmgx2_imu::IMU::CMD_ACCEL_ANGRATE_ORIENT)){
00651 ROS_ERROR("Could not start streaming data to verify calibration");
00652 }
00653 else {
00654
00655 getData(reading);
00656 double angle1 = tf::getYaw(reading.orientation);
00657 ros::Duration(2.0).sleep();
00658 getData(reading);
00659 double angle2 = tf::getYaw(reading.orientation);
00660
00661 if (fabs((angle2-angle1)/2.0) < max_drift_rate_){
00662 ROS_INFO("Imu: calibration check succeeded: angular drift %f deg/msec < %f deg/msec", fabs((angle2 - angle1)*180*1000/(2.0*M_PI)), max_drift_rate_*180*1000/M_PI);
00663 calibrated_ = true;
00664 publish_is_calibrated();
00665 ROS_INFO("IMU gyro calibration completed.");
00666 freq_diag_.clear();
00667 }
00668
00669 else{
00670 ROS_ERROR("Imu: calibration check failed: angular drift = %f deg/msec > %f deg/msec", fabs((angle2 - angle1)*180*1000/(2.0*M_PI)), max_drift_rate_*180*1000/M_PI);
00671 }
00672 imu.stopContinuous();
00673 }
00674 }
00675 };
00676
00677 int
00678 main(int argc, char** argv)
00679 {
00680 ros::init(argc, argv, "microstrain_3dmgx2_node");
00681
00682 ros::NodeHandle nh;
00683
00684 ImuNode in(nh);
00685 in.spin();
00686
00687 return(0);
00688 }