docs: hwmon: da9052, da9055: convert to ReST format

Kernel driver da9052

====================

Supported chips:

  * Dialog Semiconductors DA9052-BC and DA9053-AA/Bx PMICs

    Prefix: 'da9052'

    Datasheet: Datasheet is not publicly available.

Authors: David Dajun Chen <dchen@diasemi.com>

the input of the ADC during the conversion.

The ADC is used to measure the following inputs:

Channel 0: VDDOUT - measurement of the system voltage

Channel 1: ICH - internal battery charger current measurement

Channel 2: TBAT - output from the battery NTC

Channel 3: VBAT - measurement of the battery voltage

Channel 4: ADC_IN4 - high impedance input (0 - 2.5V)

Channel 5: ADC_IN5 - high impedance input (0 - 2.5V)

Channel 6: ADC_IN6 - high impedance input (0 - 2.5V)

Channel 7: XY - TSI interface to measure the X and Y voltage of the touch

========= ===================================================================

Channel 0 VDDOUT - measurement of the system voltage

Channel 1 ICH - internal battery charger current measurement

Channel 2 TBAT - output from the battery NTC

Channel 3 VBAT - measurement of the battery voltage

Channel 4 ADC_IN4 - high impedance input (0 - 2.5V)

Channel 5 ADC_IN5 - high impedance input (0 - 2.5V)

Channel 6 ADC_IN6 - high impedance input (0 - 2.5V)

Channel 7 XY - TSI interface to measure the X and Y voltage of the touch

	  screen resistive potentiometers

Channel 8: Internal Tjunc. - sense (internal temp. sensor)

Channel 9: VBBAT - measurement of the backup battery voltage

Channel 8 Internal Tjunc. - sense (internal temp. sensor)

Channel 9 VBBAT - measurement of the backup battery voltage

========= ===================================================================

By using sysfs attributes we can measure the system voltage VDDOUT, the battery

charging current ICH, battery temperature TBAT, battery junction temperature

Voltages are sampled by a 10 bit ADC.

The battery voltage is calculated as:

	Milli volt = ((ADC value * 1000) / 512) + 2500

The backup battery voltage is calculated as:

	Milli volt = (ADC value * 2500) / 512;

The voltages on ADC channels 4, 5 and 6 are calculated as:

	Milli volt = (ADC value * 2500) / 1023

Temperature Monitoring

are monitored by the ADC channels.

The junction temperature is calculated:

	Degrees celsius = 1.708 * (TJUNC_RES - T_OFFSET) - 108.8

The junction temperature attribute is supported by the driver.

The battery temperature is calculated:

	Degree Celsius = 1 / (t1 + 1/298) - 273

where t1 = (1/B)* ln(( ADCval * 2.5)/(R25*ITBAT*255))

Default values of R25, B, ITBAT are 10e3, 3380 and 50e-6 respectively.

Kernel driver da9055

====================

Supported chips:

  * Dialog Semiconductors DA9055 PMIC

    Prefix: 'da9055'

    Datasheet: Datasheet is not publicly available.

Authors: David Dajun Chen <dchen@diasemi.com>

the input of the ADC during the conversion.

The ADC is used to measure the following inputs:

Channel 0: VDDOUT - measurement of the system voltage

Channel 1: ADC_IN1 - high impedance input (0 - 2.5V)

Channel 2: ADC_IN2 - high impedance input (0 - 2.5V)

Channel 3: ADC_IN3 - high impedance input (0 - 2.5V)

Channel 4: Internal Tjunc. - sense (internal temp. sensor)

- Channel 0: VDDOUT - measurement of the system voltage

- Channel 1: ADC_IN1 - high impedance input (0 - 2.5V)

- Channel 2: ADC_IN2 - high impedance input (0 - 2.5V)

- Channel 3: ADC_IN3 - high impedance input (0 - 2.5V)

- Channel 4: Internal Tjunc. - sense (internal temp. sensor)

By using sysfs attributes we can measure the system voltage VDDOUT,

chip junction temperature and auxiliary channels voltages.

are stored in a 10 bit ADC.

The system voltage is calculated as:

	Milli volt = ((ADC value * 1000) / 85) + 2500

The voltages on ADC channels 1, 2 and 3 are calculated as:

	Milli volt = (ADC value * 1000) / 102

Temperature Monitoring

are monitored by the ADC channels.

The junction temperature is calculated:

	Degrees celsius = -0.4084 * (ADC_RES - T_OFFSET) + 307.6332

The junction temperature attribute is supported by the driver.