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+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>
+Description
+-----------
+The DA9052/53 provides an Analogue to Digital Converter (ADC) with 10 bits
+resolution and track and hold circuitry combined with an analogue input
+multiplexer. The analogue input multiplexer will allow conversion of up to 10
+different inputs. The track and hold circuit ensures stable input voltages at
+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
+           screen resistive potentiometers
+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
+TJUNC, battery voltage VBAT and the back up battery voltage VBBAT.
+Voltage Monitoring
+------------------
+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
+----------------------
+Temperatures are sampled by a 10 bit ADC.  Junction and battery temperatures
+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 Celcius = 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.

diff --git a/Documentation/hwmon/da9052 b/Documentation/hwmon/da9052 new file mode 100644 index 000000000000..ef898553638e --- /dev/null +++ b/Documentation/hwmon/da9052
@@ -0,0 +1,61 @@
	1	Supported chips:
	2	* Dialog Semiconductors DA9052-BC and DA9053-AA/Bx PMICs
	3	Prefix: 'da9052'
	4	Datasheet: Datasheet is not publicly available.
	5
	6	Authors: David Dajun Chen <dchen@diasemi.com>
	7
	8	Description
	9	-----------
	10
	11	The DA9052/53 provides an Analogue to Digital Converter (ADC) with 10 bits
	12	resolution and track and hold circuitry combined with an analogue input
	13	multiplexer. The analogue input multiplexer will allow conversion of up to 10
	14	different inputs. The track and hold circuit ensures stable input voltages at
	15	the input of the ADC during the conversion.
	16
	17	The ADC is used to measure the following inputs:
	18	Channel 0: VDDOUT - measurement of the system voltage
	19	Channel 1: ICH - internal battery charger current measurement
	20	Channel 2: TBAT - output from the battery NTC
	21	Channel 3: VBAT - measurement of the battery voltage
	22	Channel 4: ADC_IN4 - high impedance input (0 - 2.5V)
	23	Channel 5: ADC_IN5 - high impedance input (0 - 2.5V)
	24	Channel 6: ADC_IN6 - high impedance input (0 - 2.5V)
	25	Channel 7: XY - TSI interface to measure the X and Y voltage of the touch
	26	screen resistive potentiometers
	27	Channel 8: Internal Tjunc. - sense (internal temp. sensor)
	28	Channel 9: VBBAT - measurement of the backup battery voltage
	29
	30	By using sysfs attributes we can measure the system voltage VDDOUT, the battery
	31	charging current ICH, battery temperature TBAT, battery junction temperature
	32	TJUNC, battery voltage VBAT and the back up battery voltage VBBAT.
	33
	34	Voltage Monitoring
	35	------------------
	36
	37	Voltages are sampled by a 10 bit ADC.
	38
	39	The battery voltage is calculated as:
	40	Milli volt = ((ADC value * 1000) / 512) + 2500
	41
	42	The backup battery voltage is calculated as:
	43	Milli volt = (ADC value * 2500) / 512;
	44
	45	The voltages on ADC channels 4, 5 and 6 are calculated as:
	46	Milli volt = (ADC value * 2500) / 1023
	47
	48	Temperature Monitoring
	49	----------------------
	50
	51	Temperatures are sampled by a 10 bit ADC. Junction and battery temperatures
	52	are monitored by the ADC channels.
	53
	54	The junction temperature is calculated:
	55	Degrees celsius = 1.708 * (TJUNC_RES - T_OFFSET) - 108.8
	56	The junction temperature attribute is supported by the driver.
	57
	58	The battery temperature is calculated:
	59	Degree Celcius = 1 / (t1 + 1/298)- 273
	60	where t1 = (1/B)* ln(( ADCval * 2.5)/(R25ITBAT255))
	61	Default values of R25, B, ITBAT are 10e3, 3380 and 50e-6 respectively.