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205 lines
10 KiB
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TSL2591 Ambient Light Sensor
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============================
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.. seo::
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:description: Instructions for setting up TSL2591 ambient light sensors in ESPHome.
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:image: tsl2591.jpg
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:keywords: TSL2591
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The ``tsl2591`` sensor platform allows you to use the AMS TSL2591 ambient light sensor with ESPHome.
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Communication with the device is over :ref:`I²C <i2c>`, which must be present in your configuration.
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The TSL2591 device is available on breakout boards from a few vendors
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(for example, `Adafruit`_, `CQRobot`_, `Waveshare`_).
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.. _Adafruit: http://www.adafruit.com/products/1980
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.. _CQRobot: https://www.cqrobot.com/index.php?route=product/product&product_id=1112
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.. _Waveshare: https://www.waveshare.net/shop/TSL25911-Light-Sensor.htm
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.. figure:: images/tsl2591.jpg
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:align: center
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:width: 50.0%
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TSL2591 Ambient Light Sensor on a breakout board.
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.. figure:: images/tsl2591-ui.jpg
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:align: center
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:width: 100.0%
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TSL2591 sensors in Home Assistant UI.
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The sensor claims a dynamic range of 600 million to 1 with an effective maximum of 88000 lux.
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It achieves that large range by having a configurable ``gain`` value.
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For many applications, you can use AUTO gain to have the ESP select a suitable gain setting based on
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the previous measurement. If light levels change dramatically this may cause the next reading to saturate,
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after which the gain will adjust down and subsequent readings will be in range.
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Use a higher gain value when measuring less intense light sources.
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On the other hand, if you get ADC readings of 65,535 for either physical sensor,
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you may be saturating that sensor and need to reduce the gain.
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This Wikipedia `article <https://en.wikipedia.org/wiki/Lux>`__ has a table of some lux values for comparison.
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The implementation offers four sensors.
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Only one of them, ``calculated_lux``, is a true ``lux`` value, and even that is a bit subjective.
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(For information about the difference between radiometric and photometric measurements, see the references.)
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The other sensors are unitless readings from the device's on-board ADCs for the physical sensors.
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The two physical sensors measure "visible and infrared" (channel 0) and "infrared" (channel 1), respectively.
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However, the sensor readings here also provide the simple "visible" value separately.
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The visible value is obtained by subtracting the reading of the physical infrared sensor
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(channel 1) from the value of the physical sensor that combines visible and infrared (channel 0).
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Since those are two different physical infrared sensor readings, there is the possibility of a small inaccuracy.
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- **full_spectrum**: Raw 16 bit reading from the on-board ADC for the physical sensor for visible and infrared light (channel 0).
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- **infrared**: Raw 16 bit reading from the on-board ADC for the physical sensor for infrared light (channel 1).
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- **visible**: For convenience, a value calculated by taking the difference between the two physical sensors (channel 0 minus channel 1).
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- **calculated_lux**: This is a calculated value for lux based on the readings of the
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physical sensors, the configured gain, and the configured integration time.
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For details of the actual calculation, which can depend on additional physical properties,
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see method ``get_calculated_lux()`` in the API reference.
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There are configuration items for the device factor and the glass attenuation factor that go into the lux equation.
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If you are not happy with that built-in calculation, you have the raw data you need to do your own.
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The manufacturer, AMS, has a few application notes that discuss this topic.
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See the references.
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Values reported are said to be in units of ``lux``, but there are some things to understand about that.
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- The gain multiplier values that can be configured are only approximations.
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The sensor will use something close to it, but the exact value can vary from device to device.
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There is no way to ask the device what precise gain value it is using.
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See the TSL2591 datasheet for the specific device characteristic ranges.
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- The measurement of any lux value requires careful calibration for the light frequency
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or frequencies under measurement, conversion coefficients for the specific device, and other factors.
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In short, to really get a true lux value measurement, you should do a laboratory-grade calibration specific to your use case.
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If you are the sort of person who can do a laboratory-grade calibration, you probably knew all of that already.
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- Even considering the above points, you can still get values that will be "in the ballpark" without calibration.
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This is especially true if you just want to distinguish among "no light", "a little bit of light",
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"a lot of light", or something similar.
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.. code-block:: yaml
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# Example configuration entry
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i2c:
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# ...
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sensor:
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- platform: tsl2591
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name: "This little light of mine"
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id: "my_tls2591"
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address: 0x29
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update_interval: 60s
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device_factor: 53
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glass_attenuation_factor: 14.4
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visible:
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name: "TSL2591 visible light"
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infrared:
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name: "TSL2591 infrared light"
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full_spectrum:
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name: "TSL2591 full spectrum light"
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calculated_lux:
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id: i_lux
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name: "TSL2591 Lux"
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Configuration variables:
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------------------------
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For the TSL2591 device:
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- **id** (*Optional*, :ref:`config-id`): Manually specify the ID used for code generation.
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- **name** (*Optional*, string): A user-friendly name for this TSL2591 device.
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- **address** (*Optional*, int): Manually specify the I²C address of the device.
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Defaults to ``0x29``.
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It is not possible to change this for this device without additional hardware.
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It also automatically uses a secondary address of ``0x28`` (see the datasheet),
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making that address unavailable for other devices on the same I²C bus.
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- **integration_time** (*Optional*, :ref:`config-time`):
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The time the device will use for each measurement. Longer means more accurate values.
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You cannot specify an arbitrary amount of time. It must be the equivalent of one of:
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- ``100ms`` *(default)*
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- ``200ms``
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- ``300ms``
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- ``400ms``
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- ``500ms``
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- ``600ms``
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- **gain** (*Optional*, string): The gain the device will use. Higher values are better in low-light conditions.
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Multipliers here are approximate. Values below on the same line are aliases.
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You cannot specify an arbitrary gain multiplier. It must be one of:
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- ``low``, ``1x``
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- ``medium``, ``med``, ``25x``
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- ``high``, ``400x``
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- ``maximum``, ``max``, ``9500x``
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- ``auto`` *(default)*
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- **update_interval** (*Optional*, :ref:`config-time`): The interval for checking the sensors.
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Defaults to ``60s``.
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- **power_save_mode** (*Optional*, boolean): Should the device be powered down between update intervals?
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Defaults to ``True``.
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- **device_factor** (*Optional*, float): The default is ``53.0``.
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The device factor to be used as part of the lux equation for ``calculated_lux``.
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- **glass_attenuation_factor** (*Optional*, float): The default is ``7.7``.
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The glass attenuation factor to be used as part of the lux equation for ``calculated_lux``.
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- All other options for I²C devices described at :ref:`I²C Bus <i2c>`.
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You can configure all or any subset of the sensors described earlier.
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Each configured sensor is reported separately on each ``update_interval``.
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- **full_spectrum** (*Optional*): The reading for the full spectrum sensor.
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- **name** (**Required**, string): The name for the sensor.
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- All other options from :ref:`Sensor <config-sensor>`.
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- **infrared** (*Optional*): The reading for the infrared sensor.
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- **name** (**Required**, string): The name for the sensor.
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- All other options from :ref:`Sensor <config-sensor>`.
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- **visible** (*Optional*): The reading for visible light.
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- **name** (**Required**, string): The name for the sensor.
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- All other options from :ref:`Sensor <config-sensor>`.
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- **calculated_lux** (*Optional*): The value of the calculated lux.
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- **name** (**Required**, string): The name for the sensor.
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- All other options from :ref:`Sensor <config-sensor>`.
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Power save mode
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...............
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Sensor readings are only taken when the device indicates that the ADC values are valid.
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If the device is powered down between readings,
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there is a delay for the ADC to go through an integration cycle before a reliable reading is available.
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The delay is appoximately the configured integration time.
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The implementation uses asynchronous delays to wait for the ADC readings to become available.
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This avoids slowing down the overall ESPHome update loop,
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but it means that the publishing of state updates for the TSL2591 might come slightly later.
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If you use the TSL2591 API to change the gain or integration time value,
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the device is internally disabled and re-enabled.
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Otherwise, the next set of ADC readings would be unreliable
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because the current ADC integration cycle will have been done with mixed gain values.
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(The ADCs are not automatically "aware" that the gain or integration time was changed.)
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Even if power save mode is not enabled, there can be the same sort of slight
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delay for the first sensor reading after the change if it happens to come at an unlucky time.
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Since the delays are only a fraction of a second (a maximum of 600-700 ms)
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and update intervals are typically many seconds,
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the delays are not generally very interesting.
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To see if delays are occurring, you can turn on debug logging.
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See Also
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--------
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- :ref:`sensor-filters`
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- `AMS TSL2591 document library <https://ams.com/tsl25911#tab/documents>`__
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- `AMS TSL2591 datasheet <https://ams.com/documents/20143/36005/TSL2591_DS000338_6-00.pdf>`__
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- AMS Application Note, `Developing a Custom Lux Equation <https://ams.com/documents/20143/36005/AmbientLightSensors_AN000173_2-00.pdf>`__
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- `Radiometric vs. Photometric Units <https://www.thorlabs.de/catalogPages/506.pdf>`__
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- `Adafruit TSL2591 Arduino Library <https://github.com/adafruit/Adafruit_TSL2591_Library>`__ by `Adafruit <https://adafruit.com/>`__ *(for comparison only)*
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- `Waveshare TSL2591 Libraries <https://github.com/waveshare/TSL2591X-Light-Sensor>`__ by `Waveshare Electronics <https://www.waveshare.net/>`__ *(for comparison only)*
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- :doc:`tsl2561`
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- :doc:`bh1750`
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- `The Water Watcher (a DIY project using a TSL2591) <https://hackaday.io/project/176690-the-water-watcher>`__
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- :apiref:`tsl2591/tsl2591.h`
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- :ghedit:`Edit`
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