Documentation/w1/slaves/w1_therm.rst - linux - Git at Google

 ======================
 Kernel driver w1_therm
 ======================

 Supported chips:

   * Maxim ds18*20 based temperature sensors.
   * Maxim ds1825 based temperature sensors.
   * GXCAS GC20MH01 temperature sensor.

 Author: Evgeniy Polyakov <johnpol@2ka.mipt.ru>


 Description
 -----------

 w1_therm provides basic temperature conversion for ds18*20, ds28ea00, GX20MH01
 devices.

 Supported family codes:

 ====================	====
 W1_THERM_DS18S20	0x10
 W1_THERM_DS1822		0x22
 W1_THERM_DS18B20	0x28
 W1_THERM_DS1825		0x3B
 W1_THERM_DS28EA00	0x42
 ====================	====

 Support is provided through the sysfs entry ``w1_slave``. Each open and
 read sequence will initiate a temperature conversion, then provide two
 lines of ASCII output. The first line contains the nine hex bytes
 read along with a calculated crc value and YES or NO if it matched.
 If the crc matched the returned values are retained. The second line
 displays the retained values along with a temperature in millidegrees
 Centigrade after t=.

 Alternatively, temperature can be read using ``temperature`` sysfs, it
 returns only the temperature in millidegrees Centigrade.

 A bulk read of all devices on the bus could be done writing ``trigger``
 to ``therm_bulk_read`` entry at w1_bus_master level. This will
 send the convert command to all devices on the bus, and if parasite
 powered devices are detected on the bus (and strong pullup is enabled
 in the module), it will drive the line high during the longer conversion
 time required by parasited powered device on the line. Reading
 ``therm_bulk_read`` will return 0 if no bulk conversion pending,
 -1 if at least one sensor still in conversion, 1 if conversion is complete
 but at least one sensor value has not been read yet. Result temperature is
 then accessed by reading the ``temperature`` entry of each device, which
 may return empty if conversion is still in progress. Note that if a bulk
 read is sent but one sensor is not read immediately, the next access to
 ``temperature`` on this device will return the temperature measured at the
 time of issue of the bulk read command (not the current temperature).

 A strong pullup will be applied during the conversion if required.

 ``conv_time`` is used to get current conversion time (read), and
 adjust it (write). A temperature conversion time depends on the device type and
 it's current resolution. Default conversion time is set by the driver according
 to the device datasheet. A conversion time for many original device clones
 deviate from datasheet specs. There are three options: 1) manually set the
 correct conversion time by writing a value in milliseconds to ``conv_time``; 2)
 auto measure and set a conversion time by writing ``1`` to
 ``conv_time``; 3) use ``features`` to enable poll for conversion
 completion. Options 2, 3 can't be used in parasite power mode. To get back to
 the default conversion time write ``0`` to ``conv_time``.

 Writing a resolution value (in bits) to ``w1_slave`` will change the
 precision of the sensor for the next readings. Allowed resolutions are defined by
 the sensor. Resolution is reset when the sensor gets power-cycled.

 To store the current resolution in EEPROM, write ``0`` to ``w1_slave``.
 Since the EEPROM has a limited amount of writes (>50k), this command should be
 used wisely.

 Alternatively, resolution can be read or written using the dedicated
 ``resolution`` entry on each device, if supported by the sensor.

 Some non-genuine DS18B20 chips are fixed in 12-bit mode only, so the actual
 resolution is read back from the chip and verified.

 Note: Changing the resolution reverts the conversion time to default.

 The write-only sysfs entry ``eeprom_cmd`` is an alternative for EEPROM operations.
 Write ``save`` to save device RAM to EEPROM. Write ``restore`` to restore EEPROM
 data in device RAM.

 ``ext_power`` entry allows checking the power state of each device. Reads
 ``0`` if the device is parasite powered, ``1`` if the device is externally powered.

 Sysfs ``alarms`` allow read or write TH and TL (Temperature High an Low) alarms.
 Values shall be space separated and in the device range (typical -55 degC
 to 125 degC). Values are integer as they are store in a 8bit register in
 the device. Lowest value is automatically put to TL. Once set, alarms could
 be search at master level.

 The module parameter strong_pullup can be set to 0 to disable the
 strong pullup, 1 to enable autodetection or 2 to force strong pullup.
 In case of autodetection, the driver will use the "READ POWER SUPPLY"
 command to check if there are pariste powered devices on the bus.
 If so, it will activate the master's strong pullup.
 In case the detection of parasite devices using this command fails
 (seems to be the case with some DS18S20) the strong pullup can
 be force-enabled.

 If the strong pullup is enabled, the master's strong pullup will be
 driven when the conversion is taking place, provided the master driver
 does support the strong pullup (or it falls back to a pullup
 resistor).  The DS18b20 temperature sensor specification lists a
 maximum current draw of 1.5mA and that a 5k pullup resistor is not
 sufficient.  The strong pullup is designed to provide the additional
 current required.

 The DS28EA00 provides an additional two pins for implementing a sequence
 detection algorithm.  This feature allows you to determine the physical
 location of the chip in the 1-wire bus without needing pre-existing
 knowledge of the bus ordering.  Support is provided through the sysfs
 ``w1_seq``. The file will contain a single line with an integer value
 representing the device index in the bus starting at 0.

 ``features`` sysfs entry controls optional driver settings per device.
 Insufficient power in parasite mode, line noise and insufficient conversion
 time may lead to conversion failure. Original DS18B20 and some clones allow for
 detection of invalid conversion. Write bit mask ``1`` to ``features`` to enable
 checking the conversion success. If byte 6 of scratchpad memory is 0xC after
 conversion and temperature reads 85.00 (powerup value) or 127.94 (insufficient
 power), the driver returns a conversion error. Bit mask ``2`` enables poll for
 conversion completion (normal power only) by generating read cycles on the bus
 after conversion starts. In parasite power mode this feature is not available.
 Feature bit masks may be combined (OR). More details in
 Documentation/ABI/testing/sysfs-driver-w1_therm

 GX20MH01 device shares family number 0x28 with DS18*20. The device is generally
 compatible with DS18B20. Added are lowest 2\ :sup:`-5`, 2\ :sup:`-6` temperature
 bits in Config register; R2 bit in Config register enabling 13 and 14 bit
 resolutions. The device is powered up in 14-bit resolution mode. The conversion
 times specified in the datasheet are too low and have to be increased. The
 device supports driver features ``1`` and ``2``.
	======================
	Kernel driver w1_therm
	======================

	Supported chips:

	* Maxim ds18*20 based temperature sensors.
	* Maxim ds1825 based temperature sensors.
	* GXCAS GC20MH01 temperature sensor.

	Author: Evgeniy Polyakov <johnpol@2ka.mipt.ru>


	Description
	-----------

	w1_therm provides basic temperature conversion for ds18*20, ds28ea00, GX20MH01
	devices.

	Supported family codes:

	==================== ====
	W1_THERM_DS18S20 0x10
	W1_THERM_DS1822 0x22
	W1_THERM_DS18B20 0x28
	W1_THERM_DS1825 0x3B
	W1_THERM_DS28EA00 0x42
	==================== ====

	Support is provided through the sysfs entry ``w1_slave``. Each open and
	read sequence will initiate a temperature conversion, then provide two
	lines of ASCII output. The first line contains the nine hex bytes
	read along with a calculated crc value and YES or NO if it matched.
	If the crc matched the returned values are retained. The second line
	displays the retained values along with a temperature in millidegrees
	Centigrade after t=.

	Alternatively, temperature can be read using ``temperature`` sysfs, it
	returns only the temperature in millidegrees Centigrade.

	A bulk read of all devices on the bus could be done writing ``trigger``
	to ``therm_bulk_read`` entry at w1_bus_master level. This will
	send the convert command to all devices on the bus, and if parasite
	powered devices are detected on the bus (and strong pullup is enabled
	in the module), it will drive the line high during the longer conversion
	time required by parasited powered device on the line. Reading
	``therm_bulk_read`` will return 0 if no bulk conversion pending,
	-1 if at least one sensor still in conversion, 1 if conversion is complete
	but at least one sensor value has not been read yet. Result temperature is
	then accessed by reading the ``temperature`` entry of each device, which
	may return empty if conversion is still in progress. Note that if a bulk
	read is sent but one sensor is not read immediately, the next access to
	``temperature`` on this device will return the temperature measured at the
	time of issue of the bulk read command (not the current temperature).

	A strong pullup will be applied during the conversion if required.

	``conv_time`` is used to get current conversion time (read), and
	adjust it (write). A temperature conversion time depends on the device type and
	it's current resolution. Default conversion time is set by the driver according
	to the device datasheet. A conversion time for many original device clones
	deviate from datasheet specs. There are three options: 1) manually set the
	correct conversion time by writing a value in milliseconds to ``conv_time``; 2)
	auto measure and set a conversion time by writing ``1`` to
	``conv_time``; 3) use ``features`` to enable poll for conversion
	completion. Options 2, 3 can't be used in parasite power mode. To get back to
	the default conversion time write ``0`` to ``conv_time``.

	Writing a resolution value (in bits) to ``w1_slave`` will change the
	precision of the sensor for the next readings. Allowed resolutions are defined by
	the sensor. Resolution is reset when the sensor gets power-cycled.

	To store the current resolution in EEPROM, write ``0`` to ``w1_slave``.
	Since the EEPROM has a limited amount of writes (>50k), this command should be
	used wisely.

	Alternatively, resolution can be read or written using the dedicated
	``resolution`` entry on each device, if supported by the sensor.

	Some non-genuine DS18B20 chips are fixed in 12-bit mode only, so the actual
	resolution is read back from the chip and verified.

	Note: Changing the resolution reverts the conversion time to default.

	The write-only sysfs entry ``eeprom_cmd`` is an alternative for EEPROM operations.
	Write ``save`` to save device RAM to EEPROM. Write ``restore`` to restore EEPROM
	data in device RAM.

	``ext_power`` entry allows checking the power state of each device. Reads
	``0`` if the device is parasite powered, ``1`` if the device is externally powered.

	Sysfs ``alarms`` allow read or write TH and TL (Temperature High an Low) alarms.
	Values shall be space separated and in the device range (typical -55 degC
	to 125 degC). Values are integer as they are store in a 8bit register in
	the device. Lowest value is automatically put to TL. Once set, alarms could
	be search at master level.

	The module parameter strong_pullup can be set to 0 to disable the
	strong pullup, 1 to enable autodetection or 2 to force strong pullup.
	In case of autodetection, the driver will use the "READ POWER SUPPLY"
	command to check if there are pariste powered devices on the bus.
	If so, it will activate the master's strong pullup.
	In case the detection of parasite devices using this command fails
	(seems to be the case with some DS18S20) the strong pullup can
	be force-enabled.

	If the strong pullup is enabled, the master's strong pullup will be
	driven when the conversion is taking place, provided the master driver
	does support the strong pullup (or it falls back to a pullup
	resistor). The DS18b20 temperature sensor specification lists a
	maximum current draw of 1.5mA and that a 5k pullup resistor is not
	sufficient. The strong pullup is designed to provide the additional
	current required.

	The DS28EA00 provides an additional two pins for implementing a sequence
	detection algorithm. This feature allows you to determine the physical
	location of the chip in the 1-wire bus without needing pre-existing
	knowledge of the bus ordering. Support is provided through the sysfs
	``w1_seq``. The file will contain a single line with an integer value
	representing the device index in the bus starting at 0.

	``features`` sysfs entry controls optional driver settings per device.
	Insufficient power in parasite mode, line noise and insufficient conversion
	time may lead to conversion failure. Original DS18B20 and some clones allow for
	detection of invalid conversion. Write bit mask ``1`` to ``features`` to enable
	checking the conversion success. If byte 6 of scratchpad memory is 0xC after
	conversion and temperature reads 85.00 (powerup value) or 127.94 (insufficient
	power), the driver returns a conversion error. Bit mask ``2`` enables poll for
	conversion completion (normal power only) by generating read cycles on the bus
	after conversion starts. In parasite power mode this feature is not available.
	Feature bit masks may be combined (OR). More details in
	Documentation/ABI/testing/sysfs-driver-w1_therm

	GX20MH01 device shares family number 0x28 with DS18*20. The device is generally
	compatible with DS18B20. Added are lowest 2\ :sup:`-5`, 2\ :sup:`-6` temperature
	bits in Config register; R2 bit in Config register enabling 13 and 14 bit
	resolutions. The device is powered up in 14-bit resolution mode. The conversion
	times specified in the datasheet are too low and have to be increased. The
	device supports driver features ``1`` and ``2``.