| Both sides previous revisionPrevious revisionNext revision | Previous revision |
| sunification [2019/03/28 12:56] – givanbela | sunification [2019/04/01 15:22] (current) – givanbela |
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| For the moment we are looking into building a cheap and accurate mobile/portable device, and start working with data acquisition. This is the necessary technical part. | For the moment we are looking into building a cheap and accurate mobile/portable device, and start working with data acquisition. This is the necessary technical part. |
| | |
| | References, instructables: |
| | * https://learn.adafruit.com/adafruit-si1145-breakout-board-uv-ir-visible-sensor/overview |
| | * https://petermolnar.net/raspberry-pi-bme280-si1145-collectd-mosquitto/ |
| | * next to uv+ir+visiblelight+hum+baro+temp add particles analyzer and co2 |
| |
| In a second section the historical and contemporary cultural-artistic references will be commented. | In a second section the historical and contemporary cultural-artistic references will be commented. |
| * Honza Polívka (artist, organizer, ecologist) | * Honza Polívka (artist, organizer, ecologist) |
| * Geza Roman Bopp (artist, musicologist, musician, artisan, radiomaker) | * Geza Roman Bopp (artist, musicologist, musician, artisan, radiomaker) |
| | * Joren Six (programming and electronic engineer, database expert, experimental scientific device builder) |
| | * Gívan Belá (coordination, development, aesthetics, installation and documentation) |
| |
| current support | current support |
| * absorbation: carbon, water, ozone filter, air molecules and dust particles | * absorbation: carbon, water, ozone filter, air molecules and dust particles |
| * blue light = more scattered light than red wavelengths | * blue light = more scattered light than red wavelengths |
| | * |
| |
| Of interest is the idea that all flora + fauna are influenced by a simple formula: | Of interest is the idea that all flora + fauna are influenced by a simple formula: |
| |
| Also: | Also: |
| the energy in wind comes from the sun, so the colours of skies and clouds | * the energy in wind comes from the sun, so do the colours of skies and clouds |
| (side-project look into katabatics: air is moving faster | * as a side-project, we can look into katabatics: air is moving faster around the poles |
| technically antarctica is a desert, measure humidity..) | * technically antarctica is a desert, very dry! |
| |
| IDEA DEVELOPMENT in 5 chapters | ==== Idea development in 7 chapters ==== |
| |
| 0 scientist technicians artist content exchange meetings interviews cultural references | |
| start with raymond roussel 'locus solus' and a quote... | |
| |
| 1 solar panels and batteries, turn off and start up control of all equipment | - scientist technicians artist content exchange meetings interviews cultural references -- start with raymond roussel 'locus solus' and a quote... |
| | - solar panels and batteries, turn off and start up control of all equipment |
| 2 IOT sensors in front of the windows, can be all different depending on position and function | - IOT sensors in front of the windows, can be all different depending on position and function \\ from small to big data, fast and slow, whatever fits or not \\ at the receiver end machine learning to make models out of this over 1 year time |
| from small to big data, fast and slow, whatever fits or not | - sonification: basically we want to bring out the infrared, visible light, UV (bass, mid, high)\\ then during the day the colour of the environment (air, clouds) may change due to the atmosphere\\ [finally related is also wind and cloud fluctuations, temperature, humidity, ozone and air particles also? but I don't want to make a conventional weather station]\\ IOT and machine learning for making sense of the massive amount of incoming data (see 2)\\ sonification on the sample level, analogue in referential lengths (bass, mid, high)\\ what is the sound of the sun (can only be heard on earth)\\ closest to nature = theremin? but with combinatorial oscillations like OMSynth and new synthesis with NSynth\\ so, either javascript, python (ML libraries like TensorFlow, Scikit, Theano, Matplotlib, Seaborn, etc.. for Python or TensorFlow.js, Brain.js, Convent.js, Webdnn, Deeplearnjs, Compromise, ml.js etc for Javascript)\\ or puredata (ml-lib), or supercollider (see: https://community.dur.ac.uk/nick.collins/teaching/supercollider/advanced/machinelearningresources.scd) |
| at the receiver end machine learning to make models out of this over 1 year time | - visualisation of 1 year of data, but also of remarkable events/combinations/activities resulting\\ maybe the geological layers are interesting as a constant building up of soil defined by sun and wind\\ I would be in favour to work with small battery operated cheap lcd screens |
| | - spatiality sound: either ambisonics, on each level 8 speakers, bottom floor 4x subs, but that is so classic\\ so better: fm transmitted into headphones, radioreceivers, phones, internet... \\ spatially defined according to the place of the visitor in the building\\ areas of sending and receiving sound with Tetsuo Kogawa's FM transmitters |
| 3 sonification | |
| basically we want to bring out the infrared, visible light, UV (bass, mid, high) | |
| then during the day the colour of the environment (air, clouds) may change due to the atmosphere | |
| [finally related is also wind and cloud fluctuations, temperature, humidity, ozone and air particles also? | |
| but I don't want to make a weather station] | |
| |
| IOT and machine learning for making sense of the massive amount of incoming data (see 2) | ==== method for 2019 ==== |
| | |
| sonification on the sample level, analogue in referential lengths (bass, mid, high) | |
| what is the sound of the sun (can only be heard on earth) | |
| closest to nature = theremin? but with combinatorial oscillations like OMSynth and new synthesis with NSynth | |
| | |
| so, either javascript, python (ML libraries like TensorFlow, Scikit, Theano, Matplotlib, Seaborn, etc.. for Python or | |
| TensorFlow.js, Brain.js, Convent.js, Webdnn, Deeplearnjs, Compromise, ml.js etc for Javascript); or puredata (ml-lib), | |
| or supercollider (see: https://community.dur.ac.uk/nick.collins/teaching/supercollider/advanced/machinelearningresources.scd) | |
| | |
| 4 visualisation of 1 year of data, but also of remarkable events/combinations/activities resulting | |
| maybe the geological layers are interesting as a constant building up of soil defined by sun and wind | |
| I would be in favour to work with small battery operated cheap lcd screens | |
| | |
| 5 spatiality sound | |
| either ambisonics, on each level 8 speakers, bottom floor 4x subs, but that is so classic | |
| so better: fm transmitted into headphones, radioreceivers, phones, internet... | |
| spatially defined according to the place of the visitor in the building | |
| areas of sending and receiving sound with Tetsuo Kogawa's FM transmitters | |
| |
| TEAM | monthly meetings with specific subthemes, inviting each time another expert \\ |
| xgz: artistic and technical coordinationm realisation | monthly work sessions, inviting experts with necessary technical skills \\ |
| + solar construction team: | |
| sensors and boards, research and development IOT | |
| solar panels and batteries via IMEC research? | |
| (help joren?) | |
| + audio- and data visualisation group (with lieven?) | |
| + sonification: on komakoma/omsynth, pd&max/pyo, NSynth, ... (givan + golo) | |
| + scientists: weather, geology, ... (everytime one) | |
| |
| method for 2019: monthly meetings of all people in the groups | {{ :sunification:20190208_113049.jpg?200 |}} |
| | {{ :sunification:20190208_111844.jpg?200 |}} |
| |
| measurements | |
| |
| Pyranometer: for measurement of global solar radiation | ==== Measurements ==== |
| Albedometer: for measurement of solar radiation and reflection | |
| Pyrheliometer: for measurement of direct solar radiation | |
| Pyrgeometer: for measurement of infra red radiation | |
| Net radiometer: for measurement of radiation balance | |
| |
| pyranometers | * Pyranometer: for measurement of global solar radiation |
| | * Albedometer: for measurement of solar radiation and reflection |
| https://www.kippzonen.com/Product/13/CMP11-Pyranometer | * Pyrheliometer: for measurement of direct solar radiation |
| used in https://www.researchgate.net/publication/318040880_Raspberry_Pi_Based_Real_Time_Data_Acquisition_Node_for_Environmental_Data_Collection | * Pyrgeometer: for measurement of infra red radiation |
| | * Net radiometer: for measurement of radiation balance |
| |
| https://www.apogeeinstruments.com/su-100-ss-uv-sensor/ | ==== Pyranometers ==== |
| used in https://www.14core.com/working-on-pyranometer-with-apogee-su-100-si1145-radiation-sensor/ | |
| also see: https://learn.adafruit.com/adafruit-si1145-breakout-board-uv-ir-visible-sensor/overview | |
| or make wearables with the https://www.adafruit.com/product/1981 | |
| |
| https://www.licor.com/env/products/light/pyranometer.html?gclid=CjwKCAiA8OjjBRB4EiwAMZe6y46w0wXwmvDwow-x-zUdy6m3Zyjx7BRtD5ReG2A8DO3ZyeGTQv9pEhoCBFAQAvD_BwE | The oldest principle seems to be measuring the temperature of a white and black ring in the sunlight. But nowadays there seem to be a lot of materials and designs for experimenting and making DIY measure tools. |
| https://www.hukseflux.com/products/solar-radiation-sensors/pyranometers?gclid=CjwKCAiA8OjjBRB4EiwAMZe6y7ngiQWJBhPBuZHZZGKKBNegu_yhL-k0i4VDiOoRDNAeFNJ0uhrtQBoC0xoQAvD_BwE | |
| https://www.cooking-hacks.com/solar-radiation-sensor (for their waspmode thingies) | |
| |
| https://www.alibaba.com/product-detail/Secondary-Standard-Pyranometer_50031142386.html?spm=a2700.7724838.2017115.291.63b327a6jOjwSz | * https://www.kippzonen.com/Product/13/CMP11-Pyranometer \\ used in https://www.researchgate.net/publication/318040880_Raspberry_Pi_Based_Real_Time_Data_Acquisition_Node_for_Environmental_Data_Collection |
| https://www.alibaba.com/trade/search?fsb=y&IndexArea=product_en&CatId=&SearchText=pyranometer | * https://www.apogeeinstruments.com/su-100-ss-uv-sensor/ \\ used in https://www.14core.com/working-on-pyranometer-with-apogee-su-100-si1145-radiation-sensor/ \\ also see: https://learn.adafruit.com/adafruit-si1145-breakout-board-uv-ir-visible-sensor/overview \\ or make wearables with the https://www.adafruit.com/product/1981 |
| | * https://www.licor.com/env/products/light/pyranometer.html?gclid=CjwKCAiA8OjjBRB4EiwAMZe6y46w0wXwmvDwow-x-zUdy6m3Zyjx7BRtD5ReG2A8DO3ZyeGTQv9pEhoCBFAQAvD_BwE |
| | * https://www.hukseflux.com/products/solar-radiation-sensors/pyranometers?gclid=CjwKCAiA8OjjBRB4EiwAMZe6y7ngiQWJBhPBuZHZZGKKBNegu_yhL-k0i4VDiOoRDNAeFNJ0uhrtQBoC0xoQAvD_BwE |
| | * https://www.cooking-hacks.com/solar-radiation-sensor (for their waspmode thingies) |
| | * https://www.alibaba.com/product-detail/Secondary-Standard-Pyranometer_50031142386.html?spm=a2700.7724838.2017115.291.63b327a6jOjwSz |
| | * https://www.alibaba.com/trade/search?fsb=y&IndexArea=product_en&CatId=&SearchText=pyranometer |
| |
| https://www.hackster.io/jeffrey2/measuring-solar-radiation-with-arduino-f741ac | Using an Arduino or Raspberry pi, the following ready to make designs are online available: |
| http://www.instesre.org/construction/pyranometer/pyranometer.htm | |
| https://oceanoptics.com/wp-content/uploads/Fernando-Guerra-Hidalgo-Sensors-Design.pdf | |
| https://www.analogweather.com/-eppley-model-50-pyrheliometer.html | |
| https://ourlittlefield.blogspot.com/2014/08/home-made-pyranometer-or.html (with rpi) | |
| http://eprints.ucm.es/46744/1/TrabajoFinDeMaster.pdf (with rpi) | |
| https://www.richardmudhar.com/blog/2013/03/constructing-a-pyranometer-monitoring-daylight-levels-using-a-photodiode-and-pic/ | |
| |
| TECHNICAL COMPONENTS FOR RPI OR ARDUINO-ALIKES | * https://www.hackster.io/jeffrey2/measuring-solar-radiation-with-arduino-f741ac |
| | * http://www.instesre.org/construction/pyranometer/pyranometer.htm |
| | * https://oceanoptics.com/wp-content/uploads/Fernando-Guerra-Hidalgo-Sensors-Design.pdf |
| | * https://www.analogweather.com/-eppley-model-50-pyrheliometer.html |
| | * https://ourlittlefield.blogspot.com/2014/08/home-made-pyranometer-or.html (with rpi) |
| | * http://eprints.ucm.es/46744/1/TrabajoFinDeMaster.pdf (with rpi) |
| | * https://www.richardmudhar.com/blog/2013/03/constructing-a-pyranometer-monitoring-daylight-levels-using-a-photodiode-and-pic/ |
| |
| Tetsuo Kogawa (FM transmitters) | ==== Other electronic components for extending the sunlight measurements ==== |
| https://anarchy.translocal.jp/radio/micro/howtotx.html | |
| |
| Light to Frequency Converter - TSL235R | === Tetsuo Kogawa (FM transmitters) === |
| https://www.sparkfun.com/products/9768 | |
| https://playground.arduino.cc/Main/TSL235R | |
| https://shop.pimoroni.com/products/light-to-frequency-converter-tsl235r | |
| UV | |
| BH1750GUVA-S12SD | |
| http://arduinolearning.com/code/arduino-bh1750-sensor.php | |
| http://arduinolearning.com/code/arduino-guva-s12sd-uv-sensor.php | |
| sparkfun DEV-15089 UV Light Sensor Breakout sparkfun | |
| sparkfun VEML6075 | |
| https://www.sparkfun.com/products/15089 | |
| https://learn.sparkfun.com/tutorials/qwiic-uv-sensor-veml6075-hookup-guide | |
| https://learn.adafruit.com/adafruit-veml6075-uva-uvb-uv-index-sensor | |
| https://github.com/ControlEverythingCommunity/VEML6070 | |
| LUX TSL-2561 | |
| https://learn.sparkfun.com/tutorials/tsl2561-luminosity-sensor-hookup-guide/all | |
| https://www.adafruit.com/product/439 | |
| https://www.instructables.com/id/Lux-Sensor-TSL2561-Raspberry-Pi/ | |
| AMBIENT LIGHT TEMT-6000 | |
| https://www.sparkfun.com/products/8688 | |
| COLORPAL | |
| https://www.parallax.com/product/28380 | |
| color recognition TCS3200 | |
| https://howtomechatronics.com/tutorials/arduino/arduino-color-sensing-tutorial-tcs230-tcs3200-color-sensor/ | |
| https://www.raspberrypi.org/blog/colour-sensing-raspberry-pi/ | |
| infrared detection | |
| http://forum.arduino.cc/index.php?topic=134089.0 | |
| CO2 sensors | |
| MQ 135 (may be too inaccurate) | |
| http://sandboxelectronics.com/?product=mh-z16-ndir-co2-sensor-with-i2cuart-5v3-3v-interface-for-arduinoraspeberry-pi&gclid=CjwKCAiA8OjjBRB4EiwAMZe6y3DxYm0QQQ5xS7yTbE8hKYpdvKlpHz5E7USG_WEz7jLoTxCSQ3GusRoCwFIQAvD_BwE | |
| https://www.co2meter.com/collections/co2-sensors | |
| ozone sensors | |
| MQ131 Ozone O3 Gas Sensor | |
| 3SP-O3-20 | |
| https://www.spec-sensors.com/product/ozone-sensor/ | |
| dust particles | |
| https://learn.adafruit.com/pm25-air-quality-sensor/arduino-code | |
| https://www.instructables.com/id/Arduino-Powered-Dust-Particles-Monitoring-Station/ | |
| https://www.instructables.com/id/How-to-Interface-With-Optical-Dust-Sensor/ | |
| humidity/temperature | |
| https://learn.adafruit.com/am2315-encased-i2c-temperature-humidity-sensor | |
| BME280 I2C or SPI Temperature Humidity Pressure Sensor | |
| https://www.adafruit.com/product/2652 | |
| more partially interesting things (interesting combination UV gas temp/hum) | |
| https://learn.adafruit.com/adafruit-io-air-quality-monitor | |
| cloud sensor (expensive) | |
| http://diffractionlimited.com/product/portable-cloud-sensor/ | |
| solar operated rpi | |
| https://www.youtube.com/watch?v=YpAYDcW_Jx0 | |
| https://www.youtube.com/watch?v=pOpqQs_u5mU | |
| https://www.youtube.com/watch?v=ZMZCBaCXruA | |
| |
| First test and introduction: | * https://anarchy.translocal.jp/radio/micro/howtotx.html |
| RPI sunlight sensing project | |
| https://www.switchdoc.com/2016/10/simple-iot-sunlight-sensing-raspberry-pi-project-part-1/ | |
| https://shop.switchdoc.com/products/grove-sunlight-ir-uv-i2c-sensor | |
| http://wiki.seeedstudio.com/Grove-Sunlight_Sensor/ | |
| also available on adafruit | |
| https://learn.adafruit.com/adafruit-si1145-breakout-board-uv-ir-visible-sensor/overview | |
| |
| | === Light to Frequency Converter - TSL235R === |
| |
| | * https://www.sparkfun.com/products/9768 |
| | * https://playground.arduino.cc/Main/TSL235R |
| | * https://shop.pimoroni.com/products/light-to-frequency-converter-tsl235r |
| | |
| | === UV === |
| |
| and if we need to add a weather station (wind dir/speed temp hum barometer CO2 particles) expand | BH1750GUVA-S12SD |
| use maybe a peer-to-peer network with arduinos and raspberry pis and a homeserver? | * http://arduinolearning.com/code/arduino-bh1750-sensor.php |
| ask gepeto and dom | * http://arduinolearning.com/code/arduino-guva-s12sd-uv-sensor.php |
| | * sparkfun DEV-15089 UV Light Sensor Breakout sparkfun |
| | sparkfun VEML6075 |
| | * https://www.sparkfun.com/products/15089 |
| | * https://learn.sparkfun.com/tutorials/qwiic-uv-sensor-veml6075-hookup-guide |
| | * https://learn.adafruit.com/adafruit-veml6075-uva-uvb-uv-index-sensor |
| | * https://github.com/ControlEverythingCommunity/VEML6070 |
| | LUX TSL-2561 |
| | * https://learn.sparkfun.com/tutorials/tsl2561-luminosity-sensor-hookup-guide/all |
| | * https://www.adafruit.com/product/439 |
| | * https://www.instructables.com/id/Lux-Sensor-TSL2561-Raspberry-Pi/ |
| | AMBIENT LIGHT TEMT-6000 |
| | * https://www.sparkfun.com/products/8688 |
| |
| future | === Other sensors === |
| | |
| | COLORPAL |
| | * https://www.parallax.com/product/28380 |
| | color recognition TCS3200 |
| | * https://howtomechatronics.com/tutorials/arduino/arduino-color-sensing-tutorial-tcs230-tcs3200-color-sensor/ |
| | * https://www.raspberrypi.org/blog/colour-sensing-raspberry-pi/ |
| | infrared detection |
| | * http://forum.arduino.cc/index.php?topic=134089.0 |
| | CO2 sensors -- MQ 135 (may be too inaccurate) |
| | * http://sandboxelectronics.com/?product=mh-z16-ndir-co2-sensor-with-i2cuart-5v3-3v-interface-for-arduinoraspeberry-pi&gclid=CjwKCAiA8OjjBRB4EiwAMZe6y3DxYm0QQQ5xS7yTbE8hKYpdvKlpHz5E7USG_WEz7jLoTxCSQ3GusRoCwFIQAvD_BwE |
| | * https://www.co2meter.com/collections/co2-sensors |
| | ozone sensors |
| | * MQ131 Ozone O3 Gas Sensor |
| | * 3SP-O3-20 https://www.spec-sensors.com/product/ozone-sensor/ |
| | dust particles |
| | * https://learn.adafruit.com/pm25-air-quality-sensor/arduino-code |
| | * https://www.instructables.com/id/Arduino-Powered-Dust-Particles-Monitoring-Station/ |
| | * https://www.instructables.com/id/How-to-Interface-With-Optical-Dust-Sensor/ |
| | humidity/temperature |
| | * https://learn.adafruit.com/am2315-encased-i2c-temperature-humidity-sensor |
| | BME280 I2C or SPI Temperature Humidity Pressure Sensor |
| | * https://www.adafruit.com/product/2652 |
| | more partially interesting things (interesting combination UV gas temp/hum) |
| | * https://learn.adafruit.com/adafruit-io-air-quality-monitor |
| | cloud sensor (expensive) |
| | * http://diffractionlimited.com/product/portable-cloud-sensor/ |
| | solar operated rpi |
| | * https://www.youtube.com/watch?v=YpAYDcW_Jx0 |
| | * https://www.youtube.com/watch?v=pOpqQs_u5mU |
| | * https://www.youtube.com/watch?v=ZMZCBaCXruA |
| | |
| | First test and introduction: RPI sunlight sensing project |
| | * https://www.switchdoc.com/2016/10/simple-iot-sunlight-sensing-raspberry-pi-project-part-1/ |
| | * https://shop.switchdoc.com/products/grove-sunlight-ir-uv-i2c-sensor |
| | * http://wiki.seeedstudio.com/Grove-Sunlight_Sensor/ |
| | * also available on adafruit https://learn.adafruit.com/adafruit-si1145-breakout-board-uv-ir-visible-sensor/overview |
| | |
| | ... and if we need to add a weather station (wind dir/speed temp hum barometer CO2 particles) expand use maybe a peer-to-peer network with arduinos and raspberry pis and a homeserver? (ask gepeto and dom) |
| | |
| | ==== the future is as speculative as the past? ==== |
| | |
| expand the 'studio as organizm (Kra-Sao)' and the Tube-Observatory with mobile units (to be placed in several places): | expand the 'studio as organizm (Kra-Sao)' and the Tube-Observatory with mobile units (to be placed in several places): |
| | |
| * sun (light, colour) and wind (air flow) | * sun (light, colour) and wind (air flow) |
| * ozone, CO2 and particles | * ozone, CO2 and particles |
