Kenji Arai
Based on F401 example.Changed reset sequence and added RESET control and Power On/Off control. Check several mbed, LPC1768, LPC1114, NucleoF401RE, F411RE, L152RE and GR-PEACH
Dependencies: BNO055_fusion TextLCD
Please see follows.
/users/kenjiArai/notebook/bno055---orientation-sensor/
Diff: main.cpp
- Revision:
- 4:6d1118089a36
- Parent:
- 3:f5b5c4d795ce
- Child:
- 5:9594519c9462
--- a/main.cpp Wed Apr 08 11:30:09 2015 +0000
+++ b/main.cpp Fri Apr 10 11:19:49 2015 +0000
@@ -7,7 +7,7 @@
* http://www.page.sannet.ne.jp/kenjia/index.html
* http://mbed.org/users/kenjiArai/
* Created: March 30th, 2015
- * Revised: April 8th, 2015
+ * Revised: April 10th, 2015
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED,
* INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE
@@ -23,9 +23,6 @@
// Definition ------------------------------------------------------------------------------------
#define NUM_LOOP 100
-#define FORMAT_0 0
-#define FORMAT_1 1
-
// Object ----------------------------------------------------------------------------------------
Serial pc(USBTX,USBRX);
#if defined(TARGET_LPC1114)
@@ -64,8 +61,127 @@
//-------------------------------------------------------------------------------------------------
// Control Program
//-------------------------------------------------------------------------------------------------
-#if FORMAT_0
+// Calibration
+// Please refer BNO055 Data sheet 3.10 Calibration & 3.6.4 Sensor calibration data
+void bno055_calbration(void){
+ uint8_t d;
+ pc.printf("------ Enter BNO055 Manual Calibration Mode ------\r\n");
+ //---------- Gyroscope Caliblation ------------------------------------------------------------
+ // (a) Place the device in a single stable position for a period of few seconds to allow the
+ // gyroscope to calibrate
+ pc.printf("Step1) Please wait few seconds\r\n");
+ t.start();
+ while (t.read() < 10){
+ d = imu.read_calib_status();
+ pc.printf("Calb dat = 0x%x target = 0x30(at least)\r\n", d);
+ if ((d & 0x30) == 0x30){
+ break;
+ }
+ wait(1.0);
+ }
+ pc.printf("-> Step1) is done\r\n\r\n");
+ //---------- Magnetometer Caliblation ---------------------------------------------------------
+ // (a) Make some random movements (for example: writing the number ‘8’ on air) until the
+ // CALIB_STAT register indicates fully calibrated.
+ // (b) It takes more calibration movements to get the magnetometer calibrated than in the
+ // NDOF mode.
+ pc.printf("Step2) random moving (try to change the BNO055 axis)\r\n");
+ t.start();
+ while (t.read() < 30){
+ d = imu.read_calib_status();
+ pc.printf("Calb dat = 0x%x target = 0x33(at least)\r\n", d);
+ if ((d & 0x03) == 0x03){
+ break;
+ }
+ wait(1.0);
+ }
+ pc.printf("-> Step2) is done\r\n\r\n");
+ //---------- Magnetometer Caliblation ---------------------------------------------------------
+ // a) Place the device in 6 different stable positions for a period of few seconds
+ // to allow the accelerometer to calibrate.
+ // b) Make sure that there is slow movement between 2 stable positions
+ // The 6 stable positions could be in any direction, but make sure that the device is
+ // lying at least once perpendicular to the x, y and z axis.
+ pc.printf("Step3) Change rotation each X,Y,Z axis KEEP SLOWLY!!");
+ pc.printf(" Each 90deg stay a 5 sec and set at least 6 position.\r\n");
+ pc.printf(" e.g. (1)ACC:X0,Y0,Z-9,(2)ACC:X9,Y0,Z0,(3)ACC:X0,Y0,Z9,");
+ pc.printf("(4)ACC:X-9,Y0,Z0,(5)ACC:X0,Y-9,Z0,(6)ACC:X0,Y9,Z0,\r\n");
+ pc.printf(" If you will give up, hit any key.\r\n", d);
+ t.stop();
+ while (true){
+ d = imu.read_calib_status();
+ imu.get_gravity(&gravity);
+ pc.printf("Calb dat = 0x%x target = 0xff ACC:X %3.0f, Y %3.0f, Z %3.0f\r\n",
+ d, gravity.x, gravity.y, gravity.z);
+ if (d == 0xff){ break;}
+ if (pc.readable()){ break;}
+ wait(1.0);
+ }
+ if (imu.read_calib_status() == 0xff){
+ pc.printf("-> All of Calibration steps are done successfully!\r\n\r\n");
+ } else {
+ pc.printf("-> Calibration steps are suspended!\r\n\r\n");
+ }
+ t.stop();
+}
+
+int main(){
+ imu.set_mounting_position(MT_P6);
+ pwr_onoff = 0;
+ pc.printf("\r\n\r\nIf pc terminal soft is ready, please hit any key!\r\n");
+ char c = pc.getc();
+ pc.printf("Bosch Sensortec BNO055 test program on " __DATE__ "/" __TIME__ "\r\n");
+ // Is BNO055 avairable?
+ if (imu.chip_ready() == 0){
+ do {
+ pc.printf("Bosch BNO055 is NOT avirable!!\r\n Reset\r\n");
+ pwr_onoff = 1; // Power off
+ wait(0.1);
+ pwr_onoff = 0; // Power on
+ wait(0.02);
+ } while(imu.reset());
+ }
+ pc.printf("Bosch BNO055 is available now!!\r\n");
+ pc.printf("AXIS_REMAP_CONFIG:0x%02x, AXIS_REMAP_SIGN:0x%02x\r\n",
+ imu.read_reg0(BNO055_AXIS_MAP_CONFIG), imu.read_reg0(BNO055_AXIS_MAP_SIGN));
+ imu.read_id_inf(&bno055_id_inf);
+ pc.printf("CHIP ID:0x%02x, ACC ID:0x%02x, MAG ID:0x%02x, GYR ID:0x%02x, ",
+ bno055_id_inf.chip_id, bno055_id_inf.acc_id, bno055_id_inf.mag_id, bno055_id_inf.gyr_id);
+ pc.printf("SW REV:0x%04x, BL REV:0x%02x\r\n",
+ bno055_id_inf.sw_rev_id, bno055_id_inf.bootldr_rev_id);
+ pc.printf("If you would like to calibrate the BNO055, please hit 'y' (No: any other key)\r\n");
+ c = pc.getc();
+ if (c == 'y'){
+ bno055_calbration();
+ }
+ pc.printf("[E]:Euler Angles[deg],[Q]:Quaternion[],[L]:Linear accel[m/s*s],");
+ pc.printf("[G]:Gravity vector[m/s*s],[T]:Chip temperature,Acc,Gyr[degC],[S]:Status,[M]:time[mS]\r\n");
+ t.start();
+ while(1) {
+ imu.get_Euler_Angles(&euler_angles);
+ pc.printf("[E],Y,%+6.1f,R,%+6.1f,P,%+6.1f,",
+ euler_angles.h, euler_angles.r, euler_angles.p);
+ imu.get_quaternion(&quaternion);
+ pc.printf("[Q],W,%d,X,%d,Y,%d,Z,%d,",
+ quaternion.w, quaternion.x, quaternion.y, quaternion.z);
+ imu.get_linear_accel(&linear_acc);
+ pc.printf("[L],X,%+6.1f,Y,%+6.1f,Z,%+6.1f,",
+ linear_acc.x, linear_acc.y, linear_acc.z);
+ imu.get_gravity(&gravity);
+ pc.printf("[G],X,%+6.1f,Y,%+6.1f,Z,%+6.1f,",
+ gravity.x, gravity.y, gravity.z);
+ imu.get_chip_temperature(&chip_temp);
+ pc.printf("[T],%+d,%+d,",
+ chip_temp.acc_chip, chip_temp.gyr_chip);
+ pc.printf("[S],0x%x,[M],%d\r\n",
+ imu.read_calib_status(), t.read_ms());
+ }
+}
+
+
+// Diffrent output format as for your reference
+#if 0
int main() {
uint8_t i;
@@ -126,53 +242,4 @@
}
}
}
-
-#elif FORMAT_1
-
-int main() {
- pwr_onoff = 0;
- pc.printf("\r\n\r\nIf pc terminal soft is ready, please hit any key!\r\n");
- char c = pc.getc();
- pc.printf("Bosch Sensortec BNO055 test program on " __DATE__ "/" __TIME__ "\r\n");
- // Is BNO055 avairable?
- if (imu.chip_ready() == 0){
- do {
- pc.printf("Bosch BNO055 is NOT avirable!!\r\n");
- pwr_onoff = 1; // Power off
- wait(0.1);
- pwr_onoff = 0; // Power on
- wait(0.02);
- } while(imu.reset());
- }
- imu.set_mounting_position(MT_P6);
- pc.printf("AXIS_REMAP_CONFIG:0x%02x, AXIS_REMAP_SIGN:0x%02x\r\n",
- imu.read_reg0(BNO055_AXIS_MAP_CONFIG), imu.read_reg0(BNO055_AXIS_MAP_SIGN));
- imu.read_id_inf(&bno055_id_inf);
- pc.printf("CHIP:0x%02x, ACC:0x%02x, MAG:0x%02x, GYR:0x%02x, , SW:0x%04x, , BL:0x%02x\r\n",
- bno055_id_inf.chip_id, bno055_id_inf.acc_id, bno055_id_inf.mag_id,
- bno055_id_inf.gyr_id, bno055_id_inf.sw_rev_id, bno055_id_inf.bootldr_rev_id);
- pc.printf("[E]:Euler Angles[deg],[Q]:Quaternion[],[L]:Linear accel[m/s*s],");
- pc.printf("[G]:Gravity vector[m/s*s],[T]:Chip temperature,Acc,Gyr[degC],[S]:Status,[M]:time[mS]\r\n");
- t.start();
- while(1) {
- imu.get_Euler_Angles(&euler_angles);
- pc.printf("[E],Y,%+6.1f,R,%+6.1f,P,%+6.1f,",
- euler_angles.h, euler_angles.r, euler_angles.p);
- imu.get_quaternion(&quaternion);
- pc.printf("[Q],W:%d,X:%d,Y:%d,Z:%d,",
- quaternion.w, quaternion.x, quaternion.y, quaternion.z);
- imu.get_linear_accel(&linear_acc);
- pc.printf("[L],X,%+6.1f,Y,%+6.1f,Z,%+6.1f,",
- linear_acc.x, linear_acc.y, linear_acc.z);
- imu.get_gravity(&gravity);
- pc.printf("[G],X,%+6.1f,Y,%+6.1f,Z,%+6.1f,",
- gravity.x, gravity.y, gravity.z);
- imu.get_chip_temperature(&chip_temp);
- pc.printf("[T],%+d,%+d,",
- chip_temp.acc_chip, chip_temp.gyr_chip);
- pc.printf("[S],0x%x,[M],%d\r\n",
- imu.read_calib_status(), t.read_ms());
- }
-}
-
#endif