doc/device-tree-bindings/adc/adc.txt - uboot-imx - Git at Google

 ADC device binding

 There are no mandatory properties for ADC. However, if Voltage info is required,
 then there are two options:
 - use microvolts constraint or
 - use regulator phandle to enable/read supply's Voltage

 Properties and constraints:
 *optional and always checked, Voltage polarity info:
 - vdd-polarity-negative:  positive reference Voltage has a negative polarity
 - vss-polarity-negative:  negative reference Voltage has a negative polarity

 Chose one option, for each supply (Vdd/Vss):

 *optional and always checked, supply Voltage constants:
 - vdd-supply:            phandle to Vdd regulator's node
 - vss-supply:            phandle to Vss regulator's node

 *optional and checked only if the above corresponding, doesn't exist:
 - vdd-microvolts:        positive reference Voltage value [uV]
 - vss-microvolts:        negative reference Voltage value [uV]

 Example with constant 'Vdd' value:
 adc@1000000 {
 	compatible = "some-adc";
 	reg = <0xaabb000 0x100>;
 	status = "enabled";
 	vdd-microvolts = <1800000>;
 };

 Example of supply phandle usage, for the ADC's VDD/VSS references as below:
    _______         _______
   |Sandbox|       |Sandbox|
   : PMIC  :       :  ADC  :
   .       .       .       .
   |       | (Vdd) |   AIN0|-->
   |  BUCK2|-------|VDDref |
   | (3.3V)|      _|VSSref |
   |_______|     | |_______|
                _|_

 For the above PMIC, the node can be defined as follows:
 sandbox_pmic {
 	compatible = "sandbox,pmic";
 	...
 	buck2: buck2 {
 		regulator-name = "SUPPLY_3.3V";
 		regulator-min-microvolt = <3300000>;
 		regulator-max-microvolt = <3300000>;
 	};
 	...
 };

 For the above ADC, the node can be defined as follows:
 adc@0 {
 	compatible = "sandbox,adc";
 	vdd-supply = <&buck2>;
 	vss-microvolts = <0>;
 };

 The ADC uclass code, will enable the supply before start of the conversion,
 but it will not configure the regulator settings.
	ADC device binding

	There are no mandatory properties for ADC. However, if Voltage info is required,
	then there are two options:
	- use microvolts constraint or
	- use regulator phandle to enable/read supply's Voltage

	Properties and constraints:
	*optional and always checked, Voltage polarity info:
	- vdd-polarity-negative: positive reference Voltage has a negative polarity
	- vss-polarity-negative: negative reference Voltage has a negative polarity

	Chose one option, for each supply (Vdd/Vss):

	*optional and always checked, supply Voltage constants:
	- vdd-supply: phandle to Vdd regulator's node
	- vss-supply: phandle to Vss regulator's node

	*optional and checked only if the above corresponding, doesn't exist:
	- vdd-microvolts: positive reference Voltage value [uV]
	- vss-microvolts: negative reference Voltage value [uV]

	Example with constant 'Vdd' value:
	adc@1000000 {
	compatible = "some-adc";
	reg = <0xaabb000 0x100>;
	status = "enabled";
	vdd-microvolts = <1800000>;
	};

	Example of supply phandle usage, for the ADC's VDD/VSS references as below:
	_______ _______
	\|Sandbox\| \|Sandbox\|
	: PMIC : : ADC :
	. . . .
	\| \| (Vdd) \| AIN0\|-->
	\| BUCK2\|-------\|VDDref \|
	\| (3.3V)\| _\|VSSref \|
	\|_______\| \| \|_______\|
	_\|_

	For the above PMIC, the node can be defined as follows:
	sandbox_pmic {
	compatible = "sandbox,pmic";
	...
	buck2: buck2 {
	regulator-name = "SUPPLY_3.3V";
	regulator-min-microvolt = <3300000>;
	regulator-max-microvolt = <3300000>;
	};
	...
	};

	For the above ADC, the node can be defined as follows:
	adc@0 {
	compatible = "sandbox,adc";
	vdd-supply = <&buck2>;
	vss-microvolts = <0>;
	};

	The ADC uclass code, will enable the supply before start of the conversion,
	but it will not configure the regulator settings.