SunTracker_BLE
Dependencies: BLE_API X_NUCLEO_6180XA1 X_NUCLEO_IDB0XA1 X_NUCLEO_IHM01A1 X_NUCLEO_IKS01A1 mbed
Fork of SunTracker_BLE by
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
CustomSensorsService.h@5:76fb6b783487, 2016-02-03 (annotated)
- Committer:
- fabiombed
- Date:
- Wed Feb 03 11:22:17 2016 +0000
- Revision:
- 5:76fb6b783487
- Parent:
- CustomSunTrackerService.h@4:1d3d071a4c2c
- Child:
- 6:4cbf7303b496
BLE Services Created
Who changed what in which revision?
User | Revision | Line number | New contents of line |
---|---|---|---|
fabiombed | 4:1d3d071a4c2c | 1 | /****************************************************************************** |
fabiombed | 5:76fb6b783487 | 2 | * @file CustomSensorsService.h |
fabiombed | 5:76fb6b783487 | 3 | * @author Fabio Brembilla |
fabiombed | 5:76fb6b783487 | 4 | * @version V1.0.0 |
fabiombed | 5:76fb6b783487 | 5 | * @date January 22th, 2016 |
fabiombed | 5:76fb6b783487 | 6 | * @brief SunTracker Custom Service for BlueTooth (IDB0XA1 expansion board) |
fabiombed | 5:76fb6b783487 | 7 | ***************************************************************************** |
fabiombed | 5:76fb6b783487 | 8 | * @attention |
fabiombed | 5:76fb6b783487 | 9 | * |
fabiombed | 5:76fb6b783487 | 10 | * <h2><center>© COPYRIGHT(c) 2016 STMicroelectronics</center></h2> |
fabiombed | 5:76fb6b783487 | 11 | * |
fabiombed | 5:76fb6b783487 | 12 | * Redistribution and use in source and binary forms, with or without modification, |
fabiombed | 5:76fb6b783487 | 13 | * are permitted provided that the following conditions are met: |
fabiombed | 5:76fb6b783487 | 14 | * 1. Redistributions of source code must retain the above copyright notice, |
fabiombed | 5:76fb6b783487 | 15 | * this list of conditions and the following disclaimer. |
fabiombed | 5:76fb6b783487 | 16 | * 2. Redistributions in binary form must reproduce the above copyright notice, |
fabiombed | 5:76fb6b783487 | 17 | * this list of conditions and the following disclaimer in the documentation |
fabiombed | 5:76fb6b783487 | 18 | * and/or other materials provided with the distribution. |
fabiombed | 5:76fb6b783487 | 19 | * 3. Neither the name of STMicroelectronics nor the names of its contributors |
fabiombed | 5:76fb6b783487 | 20 | * may be used to endorse or promote products derived from this software |
fabiombed | 5:76fb6b783487 | 21 | * without specific prior written permission. |
fabiombed | 5:76fb6b783487 | 22 | * |
fabiombed | 5:76fb6b783487 | 23 | * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" |
fabiombed | 5:76fb6b783487 | 24 | * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
fabiombed | 5:76fb6b783487 | 25 | * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE |
fabiombed | 5:76fb6b783487 | 26 | * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE |
fabiombed | 5:76fb6b783487 | 27 | * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL |
fabiombed | 5:76fb6b783487 | 28 | * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR |
fabiombed | 5:76fb6b783487 | 29 | * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER |
fabiombed | 5:76fb6b783487 | 30 | * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, |
fabiombed | 5:76fb6b783487 | 31 | * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
fabiombed | 5:76fb6b783487 | 32 | * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
fabiombed | 5:76fb6b783487 | 33 | * |
fabiombed | 5:76fb6b783487 | 34 | ****************************************************************************** |
fabiombed | 5:76fb6b783487 | 35 | */ |
fabiombed | 4:1d3d071a4c2c | 36 | |
fabiombed | 4:1d3d071a4c2c | 37 | #ifndef __CUSTOM_BLE_SENSORS_SERVICE_H__ |
fabiombed | 4:1d3d071a4c2c | 38 | #define __CUSTOM_BLE_SENSORS_SERVICE_H__ |
fabiombed | 4:1d3d071a4c2c | 39 | #include "BLE.h" |
fabiombed | 5:76fb6b783487 | 40 | #include "UUID.h" |
fabiombed | 4:1d3d071a4c2c | 41 | |
fabiombed | 5:76fb6b783487 | 42 | /* BLE Services: Primary + 2 Secondary (Char Desk) */ |
fabiombed | 5:76fb6b783487 | 43 | const LongUUIDBytes_t SENS_SERVICE_UUID_128 = {0x00,0x00,0x00,0x00,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B}; //Primary |
fabiombed | 5:76fb6b783487 | 44 | const LongUUIDBytes_t SENS_POSITION_CHAR_UUID_128 = {0x00,0x00,0x00,0x01,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B}; //Motor Position |
fabiombed | 5:76fb6b783487 | 45 | const LongUUIDBytes_t SENS_SUNPANEL_CHAR_UUID_128 = {0x00,0x00,0x00,0x02,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B,0x0B}; //SunPanel Voltage |
fabiombed | 4:1d3d071a4c2c | 46 | |
fabiombed | 5:76fb6b783487 | 47 | #define POSITION_DATA_LEN 2+2 |
fabiombed | 5:76fb6b783487 | 48 | #define SUNPANEL_DATA_LEN 2+2 |
fabiombed | 4:1d3d071a4c2c | 49 | |
fabiombed | 4:1d3d071a4c2c | 50 | /* Custom Sensors Service */ |
fabiombed | 4:1d3d071a4c2c | 51 | class CustomSensorService { |
fabiombed | 4:1d3d071a4c2c | 52 | public: |
fabiombed | 4:1d3d071a4c2c | 53 | CustomSensorService(BLEDevice &_ble) : |
fabiombed | 4:1d3d071a4c2c | 54 | ble(_ble), |
fabiombed | 5:76fb6b783487 | 55 | positionCharacteristic(SENS_POSITION_CHAR_UUID_128, envPosition, POSITION_DATA_LEN, POSITION_DATA_LEN, |
fabiombed | 5:76fb6b783487 | 56 | GattCharacteristic::BLE_GATT_CHAR_PROPERTIES_READ | GattCharacteristic::BLE_GATT_CHAR_PROPERTIES_WRITE | GattCharacteristic::BLE_GATT_CHAR_PROPERTIES_NOTIFY), |
fabiombed | 5:76fb6b783487 | 57 | sunpanelCharacteristic(SENS_SUNPANEL_CHAR_UUID_128, envSunpanel, SUNPANEL_DATA_LEN, SUNPANEL_DATA_LEN, |
fabiombed | 5:76fb6b783487 | 58 | GattCharacteristic::BLE_GATT_CHAR_PROPERTIES_READ | GattCharacteristic::BLE_GATT_CHAR_PROPERTIES_WRITE) |
fabiombed | 5:76fb6b783487 | 59 | { |
fabiombed | 5:76fb6b783487 | 60 | static bool serviceAdded = false; // To be sure to define just one time |
fabiombed | 4:1d3d071a4c2c | 61 | if (serviceAdded) { |
fabiombed | 4:1d3d071a4c2c | 62 | return; |
fabiombed | 4:1d3d071a4c2c | 63 | } |
fabiombed | 4:1d3d071a4c2c | 64 | |
fabiombed | 5:76fb6b783487 | 65 | GattCharacteristic *charTable[] = {&positionCharacteristic, &sunpanelCharacteristic}; |
fabiombed | 4:1d3d071a4c2c | 66 | |
fabiombed | 4:1d3d071a4c2c | 67 | GattService envService(SENS_SERVICE_UUID_128, charTable, sizeof(charTable) / sizeof(GattCharacteristic *)); |
fabiombed | 4:1d3d071a4c2c | 68 | |
fabiombed | 4:1d3d071a4c2c | 69 | ble.gattServer().addService(envService); |
fabiombed | 4:1d3d071a4c2c | 70 | |
fabiombed | 5:76fb6b783487 | 71 | isEnabledPositionNotify = false; |
fabiombed | 5:76fb6b783487 | 72 | isEnabledSunpanelNotify = false; |
fabiombed | 4:1d3d071a4c2c | 73 | |
fabiombed | 5:76fb6b783487 | 74 | memset (envPosition, 0, POSITION_DATA_LEN); |
fabiombed | 5:76fb6b783487 | 75 | memset (envSunpanel, 0, SUNPANEL_DATA_LEN); |
fabiombed | 4:1d3d071a4c2c | 76 | |
fabiombed | 4:1d3d071a4c2c | 77 | isBTLEConnected = DISCONNECTED; |
fabiombed | 4:1d3d071a4c2c | 78 | serviceAdded = true; |
fabiombed | 4:1d3d071a4c2c | 79 | } |
fabiombed | 4:1d3d071a4c2c | 80 | |
fabiombed | 5:76fb6b783487 | 81 | // Tests Method |
fabiombed | 5:76fb6b783487 | 82 | //----------------INIZIO |
fabiombed | 5:76fb6b783487 | 83 | /* |
fabiombed | 5:76fb6b783487 | 84 | |
fabiombed | 4:1d3d071a4c2c | 85 | void sendEnvTemperature (int16_t Temp, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 86 | STORE_LE_16(envTemperature,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 87 | STORE_LE_16(envTemperature+2,Temp); |
fabiombed | 4:1d3d071a4c2c | 88 | PRINTF("sendEnvTemperature!! handle: %d\n\r", envTemperatureCharacteristic.getValueAttribute().getHandle()); |
fabiombed | 4:1d3d071a4c2c | 89 | memcpy (pastenvTemperature, envTemperature, TEMP_DATA_LEN); |
fabiombed | 4:1d3d071a4c2c | 90 | ble.gattServer().write(envTemperatureCharacteristic.getValueAttribute().getHandle(), envTemperature, TEMP_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 91 | } |
fabiombed | 4:1d3d071a4c2c | 92 | |
fabiombed | 4:1d3d071a4c2c | 93 | void updateEnvTemperature (int16_t Temp, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 94 | if (memcmp (&pastenvTemperature[2], &Temp, 2) != 0) { |
fabiombed | 4:1d3d071a4c2c | 95 | sendEnvTemperature (Temp, TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 96 | } |
fabiombed | 4:1d3d071a4c2c | 97 | } |
fabiombed | 4:1d3d071a4c2c | 98 | |
fabiombed | 4:1d3d071a4c2c | 99 | void sendEnvHumidity(uint16_t Hum, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 100 | STORE_LE_16(envHumidity,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 101 | STORE_LE_16(envHumidity+2,Hum); |
fabiombed | 4:1d3d071a4c2c | 102 | memcpy (pastenvHumidity, envHumidity, HUM_DATA_LEN); |
fabiombed | 4:1d3d071a4c2c | 103 | ble.gattServer().write(envHumidityCharacteristic.getValueAttribute().getHandle(), envHumidity, HUM_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 104 | |
fabiombed | 4:1d3d071a4c2c | 105 | } |
fabiombed | 4:1d3d071a4c2c | 106 | |
fabiombed | 4:1d3d071a4c2c | 107 | void updateEnvHumidity(uint16_t Hum, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 108 | if (memcmp (&pastenvHumidity[2], &Hum, 2) != 0) { |
fabiombed | 4:1d3d071a4c2c | 109 | sendEnvHumidity(Hum, TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 110 | } |
fabiombed | 4:1d3d071a4c2c | 111 | } |
fabiombed | 4:1d3d071a4c2c | 112 | |
fabiombed | 4:1d3d071a4c2c | 113 | void sendEnvPressure(uint32_t Press, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 114 | STORE_LE_16(envPressure,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 115 | STORE_LE_32(envPressure+2,Press); |
fabiombed | 4:1d3d071a4c2c | 116 | memcpy (pastenvPressure, envPressure, PRES_DATA_LEN); |
fabiombed | 4:1d3d071a4c2c | 117 | ble.gattServer().write(envPressureCharacteristic.getValueAttribute().getHandle(), envPressure, PRES_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 118 | } |
fabiombed | 4:1d3d071a4c2c | 119 | |
fabiombed | 4:1d3d071a4c2c | 120 | void updateEnvPressure(uint32_t Press, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 121 | if (memcmp (&pastenvPressure[2], &Press, 2) != 0) { |
fabiombed | 4:1d3d071a4c2c | 122 | sendEnvPressure(Press, TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 123 | } |
fabiombed | 4:1d3d071a4c2c | 124 | } |
fabiombed | 4:1d3d071a4c2c | 125 | |
fabiombed | 4:1d3d071a4c2c | 126 | void sendEnvMagnetometer(AxesRaw_TypeDef *Magn, uint16_t TimeStamp, osxMFX_calibFactor magOffset) { |
fabiombed | 4:1d3d071a4c2c | 127 | STORE_LE_16(envMagn,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 128 | STORE_LE_16(envMagn+2,(Magn->AXIS_X - magOffset.magOffX)); |
fabiombed | 4:1d3d071a4c2c | 129 | STORE_LE_16(envMagn+4,(Magn->AXIS_Y - magOffset.magOffY)); |
fabiombed | 4:1d3d071a4c2c | 130 | STORE_LE_16(envMagn+6,(Magn->AXIS_Z - magOffset.magOffZ)); |
fabiombed | 4:1d3d071a4c2c | 131 | ble.gattServer().write(envMagnetometerCharacteristic.getValueAttribute().getHandle(), envMagn, MAG_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 132 | } |
fabiombed | 4:1d3d071a4c2c | 133 | |
fabiombed | 4:1d3d071a4c2c | 134 | void updateEnvMagnetometer(AxesRaw_TypeDef *Magn, uint16_t TimeStamp, osxMFX_calibFactor magOffset) { |
fabiombed | 4:1d3d071a4c2c | 135 | if (isMagNotificationEn()) sendEnvMagnetometer(Magn, TimeStamp, magOffset); |
fabiombed | 4:1d3d071a4c2c | 136 | } |
fabiombed | 4:1d3d071a4c2c | 137 | |
fabiombed | 4:1d3d071a4c2c | 138 | void sendEnvAccelerometer (AxesRaw_TypeDef *Acc, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 139 | STORE_LE_16(envAcce,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 140 | STORE_LE_16(envAcce+2,Acc->AXIS_X); |
fabiombed | 4:1d3d071a4c2c | 141 | STORE_LE_16(envAcce+4,Acc->AXIS_Y); |
fabiombed | 4:1d3d071a4c2c | 142 | STORE_LE_16(envAcce+6,Acc->AXIS_Z); |
fabiombed | 4:1d3d071a4c2c | 143 | ble.gattServer().write(envAccelerometerCharacteristic.getValueAttribute().getHandle(), envAcce, ACC_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 144 | } |
fabiombed | 4:1d3d071a4c2c | 145 | |
fabiombed | 4:1d3d071a4c2c | 146 | void updateEnvAccelerometer (AxesRaw_TypeDef *Acc, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 147 | if (isAccNotificationEn()) sendEnvAccelerometer (Acc, TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 148 | } |
fabiombed | 4:1d3d071a4c2c | 149 | |
fabiombed | 4:1d3d071a4c2c | 150 | void sendEnvGyroscope (AxesRaw_TypeDef *Gyro, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 151 | STORE_LE_16(envGyro,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 152 | STORE_LE_16(envGyro+2,Gyro->AXIS_X); |
fabiombed | 4:1d3d071a4c2c | 153 | STORE_LE_16(envGyro+4,Gyro->AXIS_Y); |
fabiombed | 4:1d3d071a4c2c | 154 | STORE_LE_16(envGyro+6,Gyro->AXIS_Z); |
fabiombed | 4:1d3d071a4c2c | 155 | ble.gattServer().write(envGyroCharacteristic.getValueAttribute().getHandle(), envGyro, GYRO_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 156 | } |
fabiombed | 4:1d3d071a4c2c | 157 | |
fabiombed | 4:1d3d071a4c2c | 158 | void updateEnvGyroscope (AxesRaw_TypeDef *Gyro, uint16_t TimeStamp) { |
fabiombed | 4:1d3d071a4c2c | 159 | if (isGyroNotificationEn()) sendEnvGyroscope (Gyro, TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 160 | } |
fabiombed | 4:1d3d071a4c2c | 161 | |
fabiombed | 4:1d3d071a4c2c | 162 | void sendEnvAccGyroMag (AxesRaw_TypeDef *Acc, AxesRaw_TypeDef *Gyro, AxesRaw_TypeDef *Magn, uint16_t TimeStamp, osxMFX_calibFactor magOffset) { |
fabiombed | 4:1d3d071a4c2c | 163 | STORE_LE_16(envAccGyroMag,TimeStamp); |
fabiombed | 4:1d3d071a4c2c | 164 | STORE_LE_16(envAccGyroMag+2,Acc->AXIS_X); |
fabiombed | 4:1d3d071a4c2c | 165 | STORE_LE_16(envAccGyroMag+4,Acc->AXIS_Y); |
fabiombed | 4:1d3d071a4c2c | 166 | STORE_LE_16(envAccGyroMag+6,Acc->AXIS_Z); |
fabiombed | 4:1d3d071a4c2c | 167 | |
fabiombed | 4:1d3d071a4c2c | 168 | STORE_LE_16(envAccGyroMag+8,Gyro->AXIS_X); |
fabiombed | 4:1d3d071a4c2c | 169 | STORE_LE_16(envAccGyroMag+10,Gyro->AXIS_Y); |
fabiombed | 4:1d3d071a4c2c | 170 | STORE_LE_16(envAccGyroMag+12,Gyro->AXIS_Z); |
fabiombed | 4:1d3d071a4c2c | 171 | |
fabiombed | 4:1d3d071a4c2c | 172 | STORE_LE_16(envAccGyroMag+14,(Magn->AXIS_X - magOffset.magOffX)); |
fabiombed | 4:1d3d071a4c2c | 173 | STORE_LE_16(envAccGyroMag+16,(Magn->AXIS_Y - magOffset.magOffY)); |
fabiombed | 4:1d3d071a4c2c | 174 | STORE_LE_16(envAccGyroMag+18,(Magn->AXIS_Z - magOffset.magOffZ)); |
fabiombed | 4:1d3d071a4c2c | 175 | ble.gattServer().write(envAccGyroMagCharacteristic.getValueAttribute().getHandle(), envAccGyroMag, ACCGYROMAG_DATA_LEN, 0); |
fabiombed | 4:1d3d071a4c2c | 176 | } |
fabiombed | 4:1d3d071a4c2c | 177 | |
fabiombed | 4:1d3d071a4c2c | 178 | void updateEnvAccGyroMag (AxesRaw_TypeDef *Acc, AxesRaw_TypeDef *Gyro, AxesRaw_TypeDef *Magn, uint16_t TimeStamp, osxMFX_calibFactor magOffset) { |
fabiombed | 4:1d3d071a4c2c | 179 | if (isAccGyroMagNotificationEn())sendEnvAccGyroMag (Acc, Gyro, Magn, TimeStamp, magOffset); |
fabiombed | 5:76fb6b783487 | 180 | } |
fabiombed | 5:76fb6b783487 | 181 | |
fabiombed | 5:76fb6b783487 | 182 | */ |
fabiombed | 5:76fb6b783487 | 183 | //----------------FINE |
fabiombed | 5:76fb6b783487 | 184 | |
fabiombed | 4:1d3d071a4c2c | 185 | |
fabiombed | 4:1d3d071a4c2c | 186 | void enNotify (Gap::Handle_t handle) { |
fabiombed | 5:76fb6b783487 | 187 | if (isPositionHandle(handle)) { isEnabledPositionNotify = true; memset(envPosition,0,POSITION_DATA_LEN); return; } |
fabiombed | 5:76fb6b783487 | 188 | if (isSunpanelHandle(handle)) { isEnabledSunpanelNotify = true; memset(envSunpanel,0,SUNPANEL_DATA_LEN); return; } |
fabiombed | 4:1d3d071a4c2c | 189 | } |
fabiombed | 4:1d3d071a4c2c | 190 | |
fabiombed | 4:1d3d071a4c2c | 191 | void disNotify (Gap::Handle_t handle) { |
fabiombed | 5:76fb6b783487 | 192 | if (isPositionHandle(handle)) { isEnabledPositionNotify = false; memset(envPosition,0,POSITION_DATA_LEN); return; } |
fabiombed | 5:76fb6b783487 | 193 | if (isSunpanelHandle(handle)) { isEnabledSunpanelNotify = false; memset(envSunpanel,0,SUNPANEL_DATA_LEN); return; } |
fabiombed | 4:1d3d071a4c2c | 194 | } |
fabiombed | 4:1d3d071a4c2c | 195 | |
fabiombed | 5:76fb6b783487 | 196 | bool isPositionNotificationEn (void) { |
fabiombed | 5:76fb6b783487 | 197 | return isEnabledPositionNotify; |
fabiombed | 4:1d3d071a4c2c | 198 | } |
fabiombed | 4:1d3d071a4c2c | 199 | |
fabiombed | 5:76fb6b783487 | 200 | bool isSunpanelNotificationEn (void) { |
fabiombed | 5:76fb6b783487 | 201 | return isEnabledSunpanelNotify; |
fabiombed | 5:76fb6b783487 | 202 | } |
fabiombed | 5:76fb6b783487 | 203 | |
fabiombed | 5:76fb6b783487 | 204 | bool isPositionHandle (Gap::Handle_t handle) { |
fabiombed | 5:76fb6b783487 | 205 | if (handle == positionCharacteristic.getValueAttribute().getHandle()) return true; |
fabiombed | 4:1d3d071a4c2c | 206 | return false; |
fabiombed | 4:1d3d071a4c2c | 207 | } |
fabiombed | 4:1d3d071a4c2c | 208 | |
fabiombed | 5:76fb6b783487 | 209 | bool isSunpanelHandle (Gap::Handle_t handle) { |
fabiombed | 5:76fb6b783487 | 210 | if (handle == sunpanelCharacteristic.getValueAttribute().getHandle()) return true; |
fabiombed | 4:1d3d071a4c2c | 211 | return false; |
fabiombed | 4:1d3d071a4c2c | 212 | } |
fabiombed | 4:1d3d071a4c2c | 213 | |
fabiombed | 4:1d3d071a4c2c | 214 | void updateConnectionStatus(ConnectionStatus_t status) { |
fabiombed | 5:76fb6b783487 | 215 | isEnabledPositionNotify = false; |
fabiombed | 5:76fb6b783487 | 216 | isEnabledSunpanelNotify = false; |
fabiombed | 4:1d3d071a4c2c | 217 | |
fabiombed | 5:76fb6b783487 | 218 | memset (envPosition, 0, POSITION_DATA_LEN); |
fabiombed | 5:76fb6b783487 | 219 | memset (envSunpanel, 0, SUNPANEL_DATA_LEN); |
fabiombed | 4:1d3d071a4c2c | 220 | isBTLEConnected = status; |
fabiombed | 4:1d3d071a4c2c | 221 | } |
fabiombed | 4:1d3d071a4c2c | 222 | |
fabiombed | 5:76fb6b783487 | 223 | // Variables Initialization |
fabiombed | 4:1d3d071a4c2c | 224 | private: |
fabiombed | 4:1d3d071a4c2c | 225 | |
fabiombed | 4:1d3d071a4c2c | 226 | BLEDevice &ble; |
fabiombed | 5:76fb6b783487 | 227 | uint8_t envPosition [POSITION_DATA_LEN]; |
fabiombed | 5:76fb6b783487 | 228 | uint8_t envSunpanel [SUNPANEL_DATA_LEN]; |
fabiombed | 4:1d3d071a4c2c | 229 | |
fabiombed | 5:76fb6b783487 | 230 | GattCharacteristic positionCharacteristic; |
fabiombed | 5:76fb6b783487 | 231 | GattCharacteristic sunpanelCharacteristic; |
fabiombed | 5:76fb6b783487 | 232 | |
fabiombed | 4:1d3d071a4c2c | 233 | ConnectionStatus_t isBTLEConnected; |
fabiombed | 4:1d3d071a4c2c | 234 | |
fabiombed | 5:76fb6b783487 | 235 | bool isEnabledPositionNotify; |
fabiombed | 5:76fb6b783487 | 236 | bool isEnabledSunpanelNotify; |
fabiombed | 4:1d3d071a4c2c | 237 | |
fabiombed | 4:1d3d071a4c2c | 238 | }; |
fabiombed | 4:1d3d071a4c2c | 239 | |
fabiombed | 4:1d3d071a4c2c | 240 | #endif /* #ifndef __CUSTOM_BLE_SENSORS_SERVICE_H__*/ |