SunTracker_BLE
Dependencies: BLE_API X_NUCLEO_6180XA1 X_NUCLEO_IDB0XA1 X_NUCLEO_IHM01A1 X_NUCLEO_IKS01A1 mbed
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Overview
The SunTracker is a demo application running on ST Nucleo-F401RE stacking a set of ST X-NUCLEO expansion boards.
Main features provided are:
- A solar panel follows the light source, orienting the panel in order to achieve the best panel efficiency.
- Orientation is controlled thanks to a couple of VL6180X FlightSense light sensors mounted on a X-NUCLEO-6180XA1 expansion board and driven by X-NUCLEO-IHM01A1 controlled stepper motor acting as actuator to orientate the panel.
- The system features a progressive control on the stepper motor in order to modulate the panel rotation speed according to the light angle.
- The application is also able to control the panel productivity reading the panel voltage through an ADC and proving feedback on the local display.
- A manual orientation is possible by using the accelerometer on a X-NUCLEO-IKS01A1 expansion board that, according on board tilt, controls the speed and the rotate direction.
- A remote control is available using a X-NUCLEO-IDB04A1 or a X-NUCLEO-IDB05A1 Bluetooth Low Energy expansion board. Remote control software is here.
Working Status
- SunTracker has 3 working status visible on FlightSense display and switchable by pressing the User Button:
Status 0 (Idle)
- Motor: Free Turning
- Display: Waiting for User Button
Status 1
- Motor: Driven by Light
- Display: Direction and Light Intensity = Direction and Motor Speed
Status 2
- Motor: Driven by Light
- Display: Solar Panel Efficiency
Status 3
- Motor: Driven by Accelerometer
- Display: Direction and Accelerometer Intensity
Server Startup
- When you plug the power supply, the word ‘PUSH’ is shown on display.
- You can manually rotate the structure to assign the ‘Zero Point’. Then press the User Button to launch the application.
- The display will show this status, which means that the structureis oriented to maximize the efficiency of the solar panel.
- If there is a light displacement, the structure will rotate, left or right,to follow the light source and on display is shown the direction and the speed.
- You can press the User Button to show the panel efficiencywith 4 digits that represent the range from 0v (0000) to 3,3v (3300).
- Further pressing the User Button you will manual rotate the panel by tilt the Server or Client accelerometer depending by BLE connection.
Client Startup
- The Client application can remotely control the User Button and the Accelerometer functions.
- Power on the Client AFTER the Server, it will automatically search for the SunTracker and will establish a BLE connection.
- The Green Led on Nucleo Client board will be powered on.
Rotation Features
- It has been implemented a block of rotation to avoid cables twist.
- The blocking point can be set in the firmware by changing a constant.
- You can manually rotate the structure to assign the ‘Zero Point’ before press the User Button to launch the application.
- The system features a progressive control on the stepper motor in order to modulate the rotation speed according to the light or accelerometer angle.
List of Components
SERVER SunTracker_BLE
- Nucleo-F401RE platform using a STM32F401RET6 microcontroller.
- X-NUCLEO-IHM01A1 - Stepper motor driver board based on the EasySPIN L6474.
- X-NUCLEO-6180XA1 - 3-in-1 proximity and ambient light sensor board based on ST FlightSense technology.
- VL6180X-SATEL - Satellite boards compatible with X-NUCLEO-6180XA1 board.
- X-NUCLEO-IKS01A1 - Motion MEMS and environmental sensor board.
- X-NUCLEO-IDB04A1 or X-NUCLEO-IDB05A1 - Bluetooth Low Energy Bluetooth low energy evaluation board.
- Stepper Motor 400’’ (Part Number 5350401) - To orientate the Mechanical Structure.
- Solar Panel 0.446w (Part Number 0194127) - To capture sunlight and generate electrical current.
- Power Supply 12v (Part Number 7262993) - To provide power supply at the Stepper Motor.
- Flat Cable 6 ways (Part Number 1807010) - To plug VL6180X-SATEL with X-NUCLEO-6180XA1 (60cm length each x2).
- Cable Connector (Part Number 6737694) - To plug the Flat Cable (x4).
- Power Connector (Part Number 0487842) - To provide Power Supply to X-NUCLEO-IHM01A1.
CLIENT SunTracker_BLE_Remote
- Nucleo-F401RE platform using a STM32F401RET6 microcontroller.
- X-NUCLEO-IKS01A1 - Motion MEMS and environmental sensor board.
- X-NUCLEO-IDB04A1 or X-NUCLEO-IDB05A1- Bluetooth Low Energy Bluetooth low energy evaluation board.
MECHANICAL STRUCTURE
Find here the STL files to print with a 3D printer.
FLAT CABLE ASSEMBLY
HARDWARE SETUP
Nucleo ADC + Solar Panel
Connect Solar Panel cables to Nucleo Morpho PC_3 (white) and Nucleo Morpho GND (black). Connect a capacitor 10uF between PC_3 and GND to stabilize its voltage value shown on display.
EasySpin (L6474) + BLE
Hardware conflict between EasySpin DIR1 and BLE Reset, both on same Arduino Pin PA_8. Disconnect PA_8 between EasySpin and Nucleo by fold EasySpin Pin. PB_2 has been configured as EasySpin DIR1 in the firmware .Connect Nucleo Morpho PB_2 to FlightSense Arduino PA_8 by a wire.
FlightSense Satellites
In case of instability with I2C due to long flat cables, solder 4 SMD capacitors 47pF on FlightSense board in parallel between R15, R16, R17, R18 and plug 2 capacitors 15pF between FlightSense Arduino PB_8 and PB_9 to GND pin to cut-off noises over 720 KHz.
Arduino & Morpho Pinout
main.cpp
- Committer:
- fabiombed
- Date:
- 2016-03-21
- Revision:
- 15:019b8d60c89d
- Parent:
- 14:644f9e7278e9
- Child:
- 16:d69c0d5d5ab2
File content as of revision 15:019b8d60c89d:
/** ****************************************************************************** * @file main.cpp * @author Fabio Brembilla * @version V2.0.0 * @date March, 2016 * @brief SunTracker + BLE (Server) Vertical Application * This application use IHM01A1, 6180XA1, IKS01A1, IDB0XA1 expansion boards ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2016 STMicroelectronics</center></h2> * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * 3. Neither the name of STMicroelectronics nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************** */ /* Define --------------------------------------------------------------------*/ #define FlightSense //6180XA1 Main (remove only for debug) #define EasySpin //IHM01A1 Main (remove only for debug) #define Sensors //IKS01A1 Option #define Ble //IDB0XA1 Option /* Includes ------------------------------------------------------------------*/ // Mbed specific header files #include "mbed.h" // Helper header files #include "DevSPI.h" #include "DevI2C.h" // Component specific header files #ifdef FlightSense #include "x_nucleo_6180xa1.h" #endif #ifdef EasySpin #include "l6474_class.h" #endif #ifdef Sensors #include "x_nucleo_iks01a1.h" #endif // C header files #include <string.h> #include <stdlib.h> #include <stdio.h> #include <assert.h> /* BlueTooth -----------------------------------------------------------------*/ #ifdef Ble #include "debug.h" // Need for PRINTF #include "Utils.h" // Need for STORE_LE_16 and STORE_LE_32 const unsigned LENGTH_OF_LONG_UUID = 16; typedef uint16_t ShortUUIDBytes_t; typedef uint8_t LongUUIDBytes_t[LENGTH_OF_LONG_UUID]; typedef enum ConnectionStatus_t { DISCONNECTED =0, CONNECTED =1 } cns_t; #define BLE_DEV_NAME "SunTracker" #define BLE_DEV_MAC 0xAA,0xBB,0xCC,0xDD,0xEE,0xFF // SERVER address (must be set into CLIENT BLE_peer_address_BE) //#define BLE_DEV_MAC 0xFD,0x66,0x05,0x13,0xBE,0xBA // Default ST #define BLE_ADVERTISING_INTERVAL 1000 #include "CustomControlService.h" #include "CustomSensorsService.h" static BLE *p_BLEdev = NULL; static CustomControlService *p_customcontrolservice = NULL; static CustomSensorService *p_customsensorservice = NULL; int16_t value_read = 0; #endif /* Definitions ---------------------------------------------------------------*/ #define SET_ACC 400 // Set Motor Acceleration #define SET_DEC 400 // Set Motor Deceleration #define SET_MAX 200 // Set Motor MaxSpeed #define SET_MIN 100 // Set Motor MinSpeed #define STOP 1000 // Set Motor Stop Position #define TOLLERANCE 100 // Tollerance between Left and Right before Start Movement #define RANGE_1 200 // Range 1 for Motor Speed #define RANGE_2 500 // Range 2 for Motor Speed /* Variables -----------------------------------------------------------------*/ int8_t dir=0; // Motor Rotation Direction: 0 = Stop, 1 = Anticlockwise, 2 = Clockwise int8_t changedir=0; // Change Direction: 0 = No, 1 = Yes int8_t arrest=0; // Arrest: 0 = No, 1 = Yes int16_t babybear=0; // Difference (in Lux) between Left and Right int32_t acc_data[3]; // Difference of Accelerometer int16_t diff=0; // Babybear or Accelerometer difference [--> Send BLE] int16_t diff_abs=0; // Abs of Babybear or Accelerometer difference int8_t left=0; // Left Command for Rotate Direction int8_t right=0; // Right Command for Rotate Direction int8_t start=0; // Waiting User Button Push int16_t pos=0; // Motor Position [--> Send BLE] int16_t measure=0; // ADC Value from SunPanel [--> Send BLE] char DisplayStr[5]; // Status Display int8_t display=0; // Shown on Display: 0 = Motor Speed, 1 = Solar Panel Value, 2 = Manual Control [--> Send BLE] int16_t status, status_t, status_b, status_l, status_r; // Babybear Status /* Initializations ------------------------------------------------------------*/ // Initializing SPI bus DevSPI dev_spi(D11, D12, D13); // Initializing I2C bus DevI2C dev_i2c(D14, D15); #ifdef FlightSense // Initializing FlightSense Component 6180XA1 static X_NUCLEO_6180XA1 *board; MeasureData_t data_sensor_top, data_sensor_bottom, data_sensor_left, data_sensor_right; #endif #ifdef EasySpin // Initializing EasySpin Component IHM01A1 static L6474 *motor; #endif #ifdef Sensors // Initializing Sensors Component IKS01A1 static X_NUCLEO_IKS01A1 *mems; MotionSensor *accelerometer; #endif InterruptIn mybutton(USER_BUTTON); AnalogIn analog_read(PC_3); // A1 Conflict with BLE SPI_CS --> Changed in Morpho PC_3 /* User_Button_Pressed -------------------------------------------------------*/ void User_Button_Pressed(void) { if (start>0) { display++; } #ifdef Sensors if (display>2) { display=0; } #else if (display>1) { display=0; } #endif if (start==0) { start=1; } char State[12]; // Characters into State must be <12 and never =>12 or it crash!!! if (display==0) strcpy(State,"FlightSense"); if (display==1) strcpy(State,"ADCSunPanel"); if (display==2) strcpy(State,"Sensors"); printf("\r\n\r\nPUSH Display: %s", State); } #ifdef Ble /* Bluetooth CallBack ---------------------------------------------------------*/ static void onUpdatesEnabledCallback(GattAttribute::Handle_t handle) { if (p_customcontrolservice->isContHandle(handle)) p_customcontrolservice->enNotify(handle); if (p_customsensorservice->isDifferenceHandle(handle)) p_customsensorservice->enNotify(handle); if (p_customsensorservice->isPositionHandle(handle)) p_customsensorservice->enNotify(handle); if (p_customsensorservice->isSunpanelHandle(handle)) p_customsensorservice->enNotify(handle); } static void onUpdatesDisabledCallback(Gap::Handle_t handle) { if (p_customcontrolservice->isContHandle(handle)) p_customcontrolservice->disNotify(handle); if (p_customsensorservice->isDifferenceHandle(handle)) p_customsensorservice->disNotify(handle); if (p_customsensorservice->isPositionHandle(handle)) p_customsensorservice->disNotify(handle); if (p_customsensorservice->isSunpanelHandle(handle)) p_customsensorservice->disNotify(handle); } static void onDataReadCallback(const GattReadCallbackParams *eventDataP) { } // This Callback happen when it RECEIVE a WRITE static void myonDataWriteCallback(const GattWriteCallbackParams *eventDataP) { //printf ("myonDataWriteCallback attr_handle: %x att_data[3]: %x data_length: %d\n\r", eventDataP->handle, eventDataP->data[3], eventDataP->len ); // Return original value after inverted with STORE_LE_16 to send by BLE value_read = eventDataP->data[0] + (eventDataP->data[1]<<8); if (p_customcontrolservice->isContHandle(eventDataP->handle)) { //printf("\r\n\r\nmyonDataWriteCallback (data[0] %x)", eventDataP->data[0]); //printf("\r\nmyonDataWriteCallback (data[1] %x)", eventDataP->data[1]); printf("\r\n\r\nonDataRead BUTTON (data %d)", value_read); User_Button_Pressed(); // Change Display Status } if (p_customsensorservice->isDifferenceHandle(eventDataP->handle)) { //printf("\r\n\r\nmyonDataWriteCallback (data[0] %x)", eventDataP->data[0]); //printf("\r\nmyonDataWriteCallback (data[1] %x)", eventDataP->data[1]); //printf("\r\n\r\nonDataRead (data %d)", value_read); diff = value_read; // Change Diff } } static void onConnectionCallback(const Gap::ConnectionCallbackParams_t * connectionParams) { printf("\r\n\r\nonConnectionCallback (Line %d)", __LINE__); } static void onDisconnectionCallback(const Gap::DisconnectionCallbackParams_t * disConnectionReason) { printf("\r\n\r\nonDisconnectionCallback (Line %d)", __LINE__); p_BLEdev->gap().startAdvertising(); } #endif /* Bluetooth Initialization ---------------------------------------------------*/ bool BLE_Initialization(void) { #ifdef Ble p_BLEdev = new BLE; if (!p_BLEdev) { printf("\r\nBLE Device creation failed\r\n"); } const Gap::Address_t BLE_address_BE = {BLE_DEV_MAC}; p_BLEdev->gap().setAddress(BLEProtocol::AddressType::PUBLIC, BLE_address_BE); p_BLEdev->init(); // Set BLE CallBack Functions p_BLEdev->gattServer().onUpdatesEnabled(onUpdatesEnabledCallback); p_BLEdev->gattServer().onUpdatesDisabled(onUpdatesDisabledCallback); p_BLEdev->gattServer().onDataRead(onDataReadCallback); p_BLEdev->gattServer().onDataWritten(myonDataWriteCallback); p_BLEdev->gap().onConnection(onConnectionCallback); p_BLEdev->gap().onDisconnection(onDisconnectionCallback); //p_BLEdev->gattServer().onConfirmationReceived(onConfirmationReceivedCallback); //p_BLEdev->gattServer().onDataSent(onDataSentCallback); //p_BLEdev->gap().onTimeout(onTimeoutCallback); // BLE Services p_customcontrolservice = new CustomControlService(*p_BLEdev); p_customsensorservice = new CustomSensorService(*p_BLEdev); // Setup BLE Advertising const static char DEVICE_NAME[] = BLE_DEV_NAME; p_BLEdev->gap().accumulateAdvertisingPayload(GapAdvertisingData::BREDR_NOT_SUPPORTED | GapAdvertisingData::LE_GENERAL_DISCOVERABLE); uint8_t dat[] = {0x01,0x80,0x00,0xFC,0x00,0x00}; p_BLEdev->gap().accumulateScanResponse(GapAdvertisingData::MANUFACTURER_SPECIFIC_DATA,dat,6); p_BLEdev->gap().accumulateAdvertisingPayload(GapAdvertisingData::UNKNOWN); p_BLEdev->gap().accumulateAdvertisingPayload(GapAdvertisingData::COMPLETE_LOCAL_NAME, (uint8_t *)DEVICE_NAME, sizeof(DEVICE_NAME)); p_BLEdev->gap().setAdvertisingType(GapAdvertisingParams::ADV_CONNECTABLE_UNDIRECTED); p_BLEdev->gap().setAdvertisingInterval(BLE_ADVERTISING_INTERVAL); p_BLEdev->gap().startAdvertising(); printf("Initialization Ble OK (Line %d)\r\n", __LINE__); #endif return true; } /* Initialization ------------------------------------------------------------*/ bool Initialization(void) { dev_i2c.frequency(100000); // Default 100KHz. At 10KHz, 20KHz, 200KHz and 400KHz doesn't work //---- #ifdef FlightSense // Initializing FlightSense Component board=X_NUCLEO_6180XA1::Instance(&dev_i2c, NC, NC, NC, NC); // NC as Interrupt fixed from FlightSense library 42 status=board->InitBoard(); if(status) VL6180x_ErrLog("Failed to init the board!\n\r"); // Put GPIO not used as Interrupt in Hi-Z status_t=board->sensor_top->SetGPIOxFunctionality(1, GPIOx_SELECT_OFF); //status_b=board->sensor_botton->SetGPIOxFunctionality(1, GPIOx_SELECT_OFF); Not Present status_l=board->sensor_left->SetGPIOxFunctionality(1, GPIOx_SELECT_OFF); status_r=board->sensor_right->SetGPIOxFunctionality(1, GPIOx_SELECT_OFF); // Set Babybears status_l=board->sensor_left->AlsSetAnalogueGain(3); status_r=board->sensor_right->AlsSetAnalogueGain(3); status_l=board->sensor_left->StartMeasurement(als_continuous_polling, NULL, NULL, NULL); status_r=board->sensor_right->StartMeasurement(als_continuous_polling, NULL, NULL, NULL); printf("Init FlightSense OK\r\n"); #endif //---- #ifdef EasySpin // Initializing EasySpin Component motor = new L6474(D2, D8, PB_2, D9, D10, dev_spi); // D7 conflict with BNRG_RST (when motor change direction 0-1 reset BLE) // Used Morpho PB_2 and made HW wiring if (motor->Init(NULL) != COMPONENT_OK) return false; motor->SetStepMode(STEP_MODE_1_8); // Default is STEP_MODE_1_16 // Set defaults Motor Speed motor->SetAcceleration(SET_ACC); motor->SetDeceleration(SET_DEC); motor->SetMaxSpeed(SET_MAX); // Variable by Light/Mems Sensors motor->SetMinSpeed(SET_MIN); printf("Init EasySpin OK\r\n"); #endif //---- #ifdef Sensors // Initializing Sensors Component mems=X_NUCLEO_IKS01A1::Instance(&dev_i2c); accelerometer = mems->GetAccelerometer(); printf("Init Sensors OK\r\n"); #endif printf("Initialization OK (Line %d)\r\n", __LINE__); return true; } /* Measure_Babybear ----------------------------------------------------------*/ void Measure_Babybear(void) { #ifdef FlightSense status_l=board->sensor_left->GetMeasurement(als_continuous_polling, &data_sensor_left); status_r=board->sensor_right->GetMeasurement(als_continuous_polling, &data_sensor_right); babybear = data_sensor_right.lux - data_sensor_left.lux; diff = babybear; #endif } /* Measure_Accelerometer -----------------------------------------------------*/ void Measure_Accelerometer(void) { #ifdef Sensors accelerometer->Get_X_Axes(acc_data); diff = acc_data[0]; #endif } /* Control_Motor -------------------------------------------------------------*/ void Control_Motor(void) { #ifdef EasySpin diff_abs = abs(diff); //printf("Diff: %d lux/mems\n\r", diff_abs); motor->SetMaxSpeed(diff_abs); if (diff>0) { left=0; right=1; } if (diff<0) { left=1; right=0; } if (diff_abs>TOLLERANCE) { if (diff_abs <=RANGE_1) { if (left) { strcpy(DisplayStr,"E___"); } if (right) { strcpy(DisplayStr,"___3"); } } else if (diff_abs >RANGE_1 & diff_abs <=RANGE_2) { if (left) { strcpy(DisplayStr,"E==="); } if (right) { strcpy(DisplayStr,"===3"); } } else if (diff_abs >RANGE_2) { if (left) { strcpy(DisplayStr,"E~~~"); } if (right) { strcpy(DisplayStr,"~~~3"); } } // In Case of Change Direction if (left & dir==2) { changedir=1; } if (right & dir==1) { changedir=1; } // Run only if Stop or Change Direction if (diff_abs>TOLLERANCE & (dir==0 | changedir==1)) { if (left) { motor->Run(StepperMotor::FWD); dir=1; changedir=0; } if (right) { motor->Run(StepperMotor::BWD); dir=2; changedir=0; } printf("\n\rRUN"); } } // Get Motor Position and Control Rotation Block pos = motor->GetPosition(); if (pos>STOP | pos<-STOP) { if (pos>0) { motor->GoTo(STOP); } if (pos<0) { motor->GoTo(-STOP); } printf("\n\rGOTO"); } // Stop Motor if (diff_abs<=TOLLERANCE) { arrest=1; if (display==0) { strcpy(DisplayStr,"----"); } if (display==2) { strcpy(DisplayStr,"E 3"); } } if (arrest==1 && dir!=0 ) { // Stop just one time motor->HardStop(); dir=0; changedir=0; arrest=0; printf("\n\rSTOP"); } #endif } /* Measure_SolarPanel --------------------------------------------------------*/ void Measure_SolarPanel(void) { // AnalogIn: 0V return 0.0 , 3.3V return 1.0 measure = analog_read.read() * 3300; //printf("Measure = %.0f mV\r\n", measure); //board->display->DisplayDigit("A", 0); if (display==1) { sprintf(DisplayStr, "%d", measure); } } /* Main ----------------------------------------------------------------------*/ int main() { // Printing to the console printf("\r\n\r\nSunTracker by Fabio Brembilla\r\n\r\n"); Initialization(); BLE_Initialization(); mybutton.fall(&User_Button_Pressed); // Loop until push User Button to Set 0 Point printf("\r\nWait PUSH Button"); strcpy(DisplayStr,"pusH"); while(start<1) { #ifdef FlightSense board->display->DisplayString(DisplayStr, 4); p_BLEdev->waitForEvent(); //printf("%s\n\r", DisplayStr); #endif } printf("\r\n\r\nStart Main Loop"); #ifdef EasySpin motor->Enable(); // To put the motor on hold by execute CmdEnable #endif #ifdef Ble static int INTLOOP=0; #endif // Main Loop while(true) { if (display==0 | display==1) { Measure_Babybear(); } #ifndef Ble // without BLE it uses Accelerometer from SERVER, otherwise receive the value from CLIENT if (display==2) { Measure_Accelerometer(); } #endif Control_Motor(); Measure_SolarPanel(); #ifdef FlightSense board->display->DisplayString(DisplayStr, 4); //printf("%s\n\r", DisplayStr); #endif #ifdef Ble INTLOOP++; if (INTLOOP==100) { //if (p_customcontrolservice->isControlNotificationEn()) { printf("\n\r\n\rSend BLE Display %d", display); p_customcontrolservice->sendControlState(display); //p_customcontrolservice->updateControlState(display); //} //if (p_customsensorservice->isDifferenceNotificationEn()) { printf("\n\rSend BLE Difference %d lux/mems", diff); // Send BLE diff, no diff_abs p_customsensorservice->sendEnvDifference(diff); //p_customsensorservice->updateEnvDifference(diff); //} //if (p_customsensorservice->isPositionNotificationEn()) { printf("\n\rSend BLE Position %d", pos); p_customsensorservice->sendEnvPosition(pos); //p_customsensorservice->updateEnvPosition(pos); //} //if (p_customsensorservice->isSunpanelNotificationEn()) { printf("\n\rSend BLE Sunpanel %d mV", measure); p_customsensorservice->sendEnvSunpanel(measure); //p_customsensorservice->updateEnvSunpanel(measure); //} INTLOOP=0; } p_BLEdev->waitForEvent(); #endif } //status_l=board->sensor_left->StopMeasurement(als_continuous_polling); //status_r=board->sensor_right->StopMeasurement(als_continuous_polling); }