Multitech mDot/UDK support.
Dependencies: ST_INTERFACES X_NUCLEO_COMMON
Fork of X_NUCLEO_IKS01A1 by
Diff: Components/hts221/hts221_class.cpp
- Revision:
- 4:566f2c41dc1d
- Child:
- 11:001a21c6ac1d
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/Components/hts221/hts221_class.cpp Tue Apr 14 15:32:06 2015 +0200 @@ -0,0 +1,411 @@ +/** + ****************************************************************************** + * @file hts221.cpp + * @author AST / EST + * @version V0.0.1 + * @date 14-April-2015 + * @brief Implementation file for the HTS221 driver class + ****************************************************************************** + * @attention + * + * <h2><center>© COPYRIGHT(c) 2015 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. + * + ****************************************************************************** +*/ + +/* betzw - based on: + X-CUBE-MEMS1/trunk/Drivers/BSP/Components/hts221/hts221.c: revision #270, + X-CUBE-MEMS1/trunk: revision #293 +*/ + +/* Includes ------------------------------------------------------------------*/ +#include "mbed.h" +#include "hts221_class.h" +#include "hts221.h" +#include "../../x_nucleo_iks01a1_targets.h" + +/* Methods -------------------------------------------------------------------*/ +/** + * @brief HTS221 Calibration procedure + * @param None + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_Calibration(void) +{ + /* Temperature Calibration */ + /* Temperature in degree for calibration ( "/8" to obtain float) */ + uint16_t T0_degC_x8_L, T0_degC_x8_H, T1_degC_x8_L, T1_degC_x8_H; + uint8_t H0_rh_x2, H1_rh_x2; + uint8_t tempReg[2] = {0,0}; + + if(HTS221_IO_Read(tempReg, HTS221_T0_degC_X8_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T0_degC_x8_L = (uint16_t)tempReg[0]; + + if(HTS221_IO_Read(tempReg, HTS221_T1_T0_MSB_X8_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T0_degC_x8_H = (uint16_t) (tempReg[0] & 0x03); + T0_degC = ((float)((T0_degC_x8_H<<8) | (T0_degC_x8_L)))/8; + + if(HTS221_IO_Read(tempReg, HTS221_T1_degC_X8_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T1_degC_x8_L = (uint16_t)tempReg[0]; + + if(HTS221_IO_Read(tempReg, HTS221_T1_T0_MSB_X8_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T1_degC_x8_H = (uint16_t) (tempReg[0] & 0x0C); + T1_degC_x8_H = T1_degC_x8_H >> 2; + T1_degC = ((float)((T1_degC_x8_H<<8) | (T1_degC_x8_L)))/8; + + if(HTS221_IO_Read(tempReg, (HTS221_T0_OUT_L_ADDR | HTS221_I2C_MULTIPLEBYTE_CMD), 2) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T0_out = ((((int16_t)tempReg[1]) << 8)+(int16_t)tempReg[0]); + + if(HTS221_IO_Read(tempReg, (HTS221_T1_OUT_L_ADDR | HTS221_I2C_MULTIPLEBYTE_CMD), 2) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T1_out = ((((int16_t)tempReg[1]) << 8)+(int16_t)tempReg[0]); + + /* Humidity Calibration */ + /* Humidity in degree for calibration ( "/2" to obtain float) */ + + if(HTS221_IO_Read(&H0_rh_x2, HTS221_H0_RH_X2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + if(HTS221_IO_Read(&H1_rh_x2, HTS221_H1_RH_X2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + if(HTS221_IO_Read(&tempReg[0], (HTS221_H0_T0_OUT_L_ADDR | HTS221_I2C_MULTIPLEBYTE_CMD), 2) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + H0_T0_out = ((((int16_t)tempReg[1]) << 8)+(int16_t)tempReg[0]); + + if(HTS221_IO_Read(&tempReg[0], (HTS221_H1_T0_OUT_L_ADDR | HTS221_I2C_MULTIPLEBYTE_CMD), 2) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + H1_T0_out = ((((int16_t)tempReg[1]) << 8)+(int16_t)tempReg[0]); + + H0_rh = ((float)H0_rh_x2)/2; + H1_rh = ((float)H1_rh_x2)/2; + + return HUM_TEMP_OK; +} + + +/** + * @brief Set HTS221 Initialization + * @param HTS221_Init the configuration setting for the HTS221 + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_Init(HUM_TEMP_InitTypeDef *HTS221_Init) +{ + uint8_t tmp = 0x00; + + /* Configure the low level interface ---------------------------------------*/ + if(HTS221_IO_Init() != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + if(HTS221_Power_On() != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + if(HTS221_Calibration() != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + if(HTS221_IO_Read(&tmp, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Output Data Rate selection */ + tmp &= ~(HTS221_ODR_MASK); + tmp |= HTS221_Init->OutputDataRate; + + if(HTS221_IO_Write(&tmp, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + HTS221_IO_ITConfig(); + + return HUM_TEMP_OK; +} + +/** + * @brief Read ID address of HTS221 + * @param ht_id the pointer where the ID of the device is stored + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_ReadID(uint8_t *ht_id) +{ + if(!ht_id) + { + return HUM_TEMP_ERROR; + } + + return HTS221_IO_Read(ht_id, HTS221_WHO_AM_I_ADDR, 1); +} + +/** + * @brief Reboot memory content of HTS221 + * @param None + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_RebootCmd(void) +{ + uint8_t tmpreg; + + /* Read CTRL_REG2 register */ + if(HTS221_IO_Read(&tmpreg, HTS221_CTRL_REG2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Enable or Disable the reboot memory */ + tmpreg |= HTS221_BOOT_REBOOTMEMORY; + + /* Write value to MEMS CTRL_REG2 regsister */ + if(HTS221_IO_Write(&tmpreg, HTS221_CTRL_REG2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + return HUM_TEMP_OK; +} + + +/** + * @brief Read HTS221 output register, and calculate the humidity + * @param pfData the pointer to data output + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_GetHumidity(float* pfData) +{ + int16_t H_T_out, humidity_t; + uint8_t tempReg[2] = {0,0}; + uint8_t tmp = 0x00; + float H_rh; + + if(HTS221_IO_Read(&tmp, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Output Data Rate selection */ + tmp &= (HTS221_ODR_MASK); + + if(tmp == 0x00) + { + if(HTS221_IO_Read(&tmp, HTS221_CTRL_REG2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Serial Interface Mode selection */ + tmp &= ~(HTS221_ONE_SHOT_MASK); + tmp |= HTS221_ONE_SHOT_START; + + if(HTS221_IO_Write(&tmp, HTS221_CTRL_REG2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + do{ + + if(HTS221_IO_Read(&tmp, HTS221_STATUS_REG_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + }while(!(tmp&&0x02)); + } + + + if(HTS221_IO_Read(&tempReg[0], (HTS221_HUMIDITY_OUT_L_ADDR | HTS221_I2C_MULTIPLEBYTE_CMD), 2) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + H_T_out = ((((int16_t)tempReg[1]) << 8)+(int16_t)tempReg[0]); + + H_rh = ( float )(((( H_T_out - H0_T0_out ) * ( H1_rh - H0_rh )) / ( H1_T0_out - H0_T0_out )) + H0_rh ); + + // Truncate to specific number of decimal digits + humidity_t = (uint16_t)(H_rh * pow(10,HUM_DECIMAL_DIGITS)); + *pfData = ((float)humidity_t)/pow(10,HUM_DECIMAL_DIGITS); + + // Prevent data going below 0% and above 100% due to linear interpolation + if ( *pfData < 0.0f ) *pfData = 0.0f; + if ( *pfData > 100.0f ) *pfData = 100.0f; + + return HUM_TEMP_OK; +} + +/** + * @brief Read HTS221 output register, and calculate the temperature + * @param pfData the pointer to data output + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_GetTemperature(float* pfData) +{ + int16_t T_out, temperature_t; + uint8_t tempReg[2] = {0,0}; + uint8_t tmp = 0x00; + float T_degC; + + if(HTS221_IO_Read(&tmp, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Output Data Rate selection */ + tmp &= (HTS221_ODR_MASK); + + if(tmp == 0x00) + { + if(HTS221_IO_Read(&tmp, HTS221_CTRL_REG2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Serial Interface Mode selection */ + tmp &= ~(HTS221_ONE_SHOT_MASK); + tmp |= HTS221_ONE_SHOT_START; + + if(HTS221_IO_Write(&tmp, HTS221_CTRL_REG2_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + do{ + + if(HTS221_IO_Read(&tmp, HTS221_STATUS_REG_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + }while(!(tmp&&0x01)); + } + + if(HTS221_IO_Read(&tempReg[0], (HTS221_TEMP_OUT_L_ADDR | HTS221_I2C_MULTIPLEBYTE_CMD), 2) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + T_out = ((((int16_t)tempReg[1]) << 8)+(int16_t)tempReg[0]); + + T_degC = ((float)(T_out - T0_out))/(T1_out - T0_out) * (T1_degC - T0_degC) + T0_degC; + + temperature_t = (int16_t)(T_degC * pow(10,TEMP_DECIMAL_DIGITS)); + + *pfData = ((float)temperature_t)/pow(10,TEMP_DECIMAL_DIGITS); + + return HUM_TEMP_OK; +} + + +/** + * @brief Exit the shutdown mode for HTS221 + * @param None + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_Power_On(void) +{ + uint8_t tmpReg; + + /* Read the register content */ + if(HTS221_IO_Read(&tmpReg, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Set the power down bit */ + tmpReg |= HTS221_MODE_ACTIVE; + + /* Write register */ + if(HTS221_IO_Write(&tmpReg, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + return HUM_TEMP_OK; +} + +/** + * @brief Enter the shutdown mode for HTS221 + * @param None + * @retval HUM_TEMP_OK in case of success, an error code otherwise + */ +HUM_TEMP_StatusTypeDef HTS221::HTS221_Power_OFF(void) +{ + uint8_t tmpReg; + + /* Read the register content */ + if(HTS221_IO_Read(&tmpReg, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + /* Reset the power down bit */ + tmpReg &= ~(HTS221_MODE_ACTIVE); + + /* Write register */ + if(HTS221_IO_Write(&tmpReg, HTS221_CTRL_REG1_ADDR, 1) != HUM_TEMP_OK) + { + return HUM_TEMP_ERROR; + } + + return HUM_TEMP_OK; +}