path: root/src/ADS1115_WE.h

/******************************************************************************
 *
 * This is a library for the ADS1115 A/D Converter
 *
 * You'll find several example sketches which should enable you to use the library.
 *
 * You are free to use it, change it or build on it. In case you like it, it would
 * be cool if you give it a star.
 *
 * If you find bugs, please inform me!
 *
 * Written by Wolfgang (Wolle) Ewald
 * https://wolles-elektronikkiste.de/en/ads1115-a-d-converter-with-amplifier (English)
 * https://wolles-elektronikkiste.de/ads1115 (German)
 *
 *
 ******************************************************************************/

#ifndef ADS1115_WE_H_
#define ADS1115_WE_H_

#if (ARDUINO >= 100)
 #include "Arduino.h"
#else
 #include "WProgram.h"
#endif
#include "ADS1115_config.h"

#ifdef USE_TINY_WIRE_M_
 #include <TinyWireM.h>
#endif
#ifndef USE_TINY_WIRE_M_
 #include <Wire.h>
#endif

/* registers */
#define ADS1115_CONV_REG    0x00 // Conversion Register
#define ADS1115_CONFIG_REG  0x01 // Configuration Register
#define ADS1115_LO_THRESH_REG   0x02 // Low Threshold Register
#define ADS1115_HI_THRESH_REG   0x03 // High Threshold Register

/* other */
#define ADS1115_REG_FACTOR 32768
#define ADS1115_REG_RESET_VAL 0x8583

typedef enum ADS1115_COMP_QUE {
    ADS1115_ASSERT_AFTER_1 = 0x0000,
    ADS1115_ASSERT_AFTER_2 = 0x0001,
    ADS1115_ASSERT_AFTER_4 = 0x0002,
    ADS1115_DISABLE_ALERT  = 0x0003
} compQue;

typedef enum ADS1115_LATCH {
    ADS1115_LATCH_DISABLED = 0x0000,
    ADS1115_LATCH_ENABLED  = 0x0004,
} latch;

typedef enum ADS1115_ALERT_POL {
    ADS1115_ACT_LOW  = 0x0000,
    ADS1115_ACT_HIGH = 0x0008
} alertPol;

typedef enum ADS1115_COMP_MODE{
    ADS1115_MAX_LIMIT = 0x0000,
    ADS1115_WINDOW    = 0x0010
} compMode;

typedef enum ADS1115_CONV_RATE{
    ADS1115_8_SPS   = 0x0000,
    ADS1115_16_SPS  = 0x0020,
    ADS1115_32_SPS  = 0x0040,
    ADS1115_64_SPS  = 0x0060,
    ADS1115_128_SPS = 0x0080,
    ADS1115_250_SPS = 0x00A0,
    ADS1115_475_SPS = 0x00C0,
    ADS1115_860_SPS = 0x00E0
} convRate;

typedef enum ADS1115_MEASURE_MODE{
    ADS1115_CONTINOUS  = 0x0000, // keeping misspelled enum for backwards compatibility.
    ADS1115_CONTINUOUS = 0x0000, 
    ADS1115_SINGLE     = 0x0100
} measureMode;

typedef enum ADS1115_RANGE{
    ADS1115_RANGE_6144  = 0x0000,
    ADS1115_RANGE_4096  = 0x0200,
    ADS1115_RANGE_2048  = 0x0400,
    ADS1115_RANGE_1024  = 0x0600,
    ADS1115_RANGE_0512  = 0x0800,
    ADS1115_RANGE_0256  = 0x0A00,
} range;

typedef enum ADS1115_MUX{
    ADS1115_COMP_0_1   = 0x0000,
    ADS1115_COMP_0_3   = 0x1000,
    ADS1115_COMP_1_3   = 0x2000,
    ADS1115_COMP_2_3   = 0x3000,
    ADS1115_COMP_0_GND = 0x4000,
    ADS1115_COMP_1_GND = 0x5000,
    ADS1115_COMP_2_GND = 0x6000,
    ADS1115_COMP_3_GND = 0x7000
} mux;
#define ADS1115_COMP_INC 0x1000     // increment to next channel

typedef enum ADS1115_STATUS_OR_START{
    ADS1115_BUSY          = 0x0000,
    ADS1115_START_ISREADY = 0x8000
} statusOrStart;


class ADS1115_WE
{
public:
    ADS1115_WE(int addr = 0x48);
#ifndef USE_TINY_WIRE_M_    
    ADS1115_WE(TwoWire *w, int addr = 0x48);
#endif

    void reset();
    bool init();

    /* Set number of conversions after which the alert pin will be active
     * - or you can disable the alert
     *
     *  ADS1115_ASSERT_AFTER_1  -> after 1 conversion
     *  ADS1115_ASSERT_AFTER_2  -> after 2 conversions
     *  ADS1115_ASSERT_AFTER_4  -> after 4 conversions
     *  ADS1115_DISABLE_ALERT   -> disable comparator // alert pin (default)
     */
    void setAlertPinMode(ADS1115_COMP_QUE mode);

    /* Enable or disable latch. If latch is enabled the alarm pin will be active until the
     * conversion register is read (getResult functions). If disabled the alarm pin will be
     * deactivated with next value within limits.
     *
     * ADS1115_LATCH_DISABLED (default)
     * ADS1115_LATCH_ENABLED
     */
    void setAlertLatch(ADS1115_LATCH latch);

    /* Sets the alert pin polarity if active:
     *
     * Enable or disable latch. If latch is enabled the alarm pin will be active until the
     * conversion register is read (getResult functions). If disabled the alarm pin will be
     * deactivated with next value within limits.
     *
     * ADS1115_ACT_LOW  ->  active low (default)
     * ADS1115_ACT_HIGH ->  active high
     */
    void setAlertPol(ADS1115_ALERT_POL polarity);

    /* Choose maximum limit or maximum and minimum alert limit (window)in Volt - alert pin will
     * be active when measured values are beyond the maximum limit or outside the window
     * Upper limit first: setAlertLimit_V(MODE, maximum, minimum)
     * In max limit mode the minimum value is the limit where the alert pin will be deactivated (if
     * not latched)
     *
     * ADS1115_MAX_LIMIT
     * ADS1115_WINDOW
     */
    void setAlertModeAndLimit_V(ADS1115_COMP_MODE mode, float hithres, float lothres);

    /* Set the conversion rate in SPS (samples per second)
     * Options should be self-explaining:
     *
     * ADS1115_8_SPS
     * ADS1115_16_SPS
     * ADS1115_32_SPS
     * ADS1115_64_SPS
     * ADS1115_128_SPS (default)
     * ADS1115_250_SPS
     * ADS1115_475_SPS
     * ADS1115_860_SPS
     */
    void setConvRate(ADS1115_CONV_RATE rate);
    
    /* returns the conversion rate */
    convRate getConvRate();

    /* Set continuous or single shot mode:
     *
     * ADS1115_CONTINUOUS  ->  continuous mode
     * ADS1115_SINGLE     ->  single shot mode (default)
     */
    void setMeasureMode(ADS1115_MEASURE_MODE mode);
    
    /* Set the voltage range of the ADC to adjust the gain:
     * Please note that you must not apply more than VDD + 0.3V to the input pins!
     *
     * ADS1115_RANGE_6144  ->  +/- 6144 mV
     * ADS1115_RANGE_4096  ->  +/- 4096 mV
     * ADS1115_RANGE_2048  ->  +/- 2048 mV (default)
     * ADS1115_RANGE_1024  ->  +/- 1024 mV
     * ADS1115_RANGE_0512  ->  +/- 512 mV
     * ADS1115_RANGE_0256  ->  +/- 256 mV
     */
    void setVoltageRange_mV(ADS1115_RANGE range);
    
    /* Set the voltage range automatically 
     * 1) changes into maximum range and continuous mode
     * 2) measures the voltage
     * 3) chooses the smallest range in which the measured voltage is <80% 
     *    of the range's maximum
     * 4) switches back to single shot mode if it was in this mode before
     *  
     * Please be aware that the procedure takes the the time needed for several conversions.
     * You should ony use it in case you expect stable or slowly changing voltages. 
     */
    void setAutoRange();
    
    /* Set the automatic voltage range permanantly, but the range will only be changed if the 
     * measured value is outside 30 - 80% of the maximum value of the current range. 
     * Therefore this method is faster than setAutoRange(). 
     */
    void setPermanentAutoRangeMode(bool autoMode);

    /* Set the inputs to be compared
     *
     * ADS1115_COMP_0_1    ->  compares 0 with 1 (default)
     * ADS1115_COMP_0_3    ->  compares 0 with 3
     * ADS1115_COMP_1_3    ->  compares 1 with 3
     * ADS1115_COMP_2_3    ->  compares 2 with 3
     * ADS1115_COMP_0_GND  ->  compares 0 with GND
     * ADS1115_COMP_1_GND  ->  compares 1 with GND
     * ADS1115_COMP_2_GND  ->  compares 2 with GND
     * ADS1115_COMP_3_GND  ->  compares 3 with GND
    */
    void setCompareChannels(ADS1115_MUX mux);

    /* Set to channel (0-3) in single ended mode
     */
    void setSingleChannel(size_t channel);

    bool isBusy();
    void startSingleMeasurement();
    float getResult_V();
    float getResult_mV();
    
    /* Get the raw result from the conversion register: 
     * The conversion register contains the conversion result of the amplified (!)
     * voltage. This means the value depends on the voltage as well as on the 
     * voltage range. E.g. if the voltage range is 6144 mV (ADS1115_RANGE_6144), 
     * +32767 is 6144 mV; if the range is 4096 mV, +32767 is 4096 mV, and so on.  
     */
    int16_t getRawResult();
    
    /* Scaling of the result to a different range: 
     * The results in the conversion register are in a range of -32767 to +32767
     * You might want to receive the result in a different scale, e.g. -1023 to 1023.
     * For -1023 to 1023, and if you have chosen e.g. ADS1115_RANGE_4096, 0 Volt would 
     * give 0 as result and 4096 mV would give 1023. -4096 mV would give -1023.
     */
    int16_t getResultWithRange(int16_t min, int16_t max);
    
    /* Scaling of the result to a different range plus scaling to a voltage range: 
     * You can use this variant if you also want to scale to a voltage range. E.g. in
     * in order to get results equivalent to an Arduino UNO (10 bit, 5000 mV range), you 
     * would choose getResultWithRange(-1023, 1023, 5000). A difference to the Arduino 
     * UNO is that you can measure negative voltages. 
     * You have to ensure that the voltage range you scale to is smaller than the 
     * measuring voltage range.
     */
    int16_t getResultWithRange(int16_t min, int16_t max, int16_t maxVoltage);
    
    /* This function returns the voltage range ADS1115_RANGE_XXXX in Millivolt */
    uint16_t getVoltageRange_mV();
    
    /* With this function the alert pin will be active, when a conversion is ready.
     * In order to deactivate, use the setAlertLimit_V function
     */
    void setAlertPinToConversionReady();
    void clearAlert();


private:
#ifndef USE_TINY_WIRE_M_    
    TwoWire *_wire;
#endif
    uint16_t voltageRange;
    ADS1115_MEASURE_MODE deviceMeasureMode;
    int i2cAddress;
    bool autoRangeMode;
    void delayAccToRate(convRate cr);
    int16_t calcLimit(float rawLimit);
    uint8_t writeRegister(uint8_t reg, uint16_t val);
    uint16_t readRegister(uint8_t reg);

};

#endif