##Infrared photography for vegetation analysis##
Infrared photography can help assess a plant's health. Infrared imagery for agricultural and ecological assessment is usually captured from satellites and planes, and the information is used mainly by large farms, vineyards, and academic research projects. For example, see this illustrated [PDF](http://www.beckshybrids.com/research/2010/pg174-182.pdf) from a commercial imagery provider who has been studying the usefulness of infrared imagery and has quotes from farmers. There are public sources of infrared photography for the US available through the Department of Agriculture -- [NAIP](http://datagateway.nrcs.usda.gov/) and [Vegscape](http://nassgeodata.gmu.edu/VegScape/) -- but this imagery is not collected when, as often, or at useable scale for individuals who are managing small plots. **By creating a low-cost camera and working with farmers and environmental activists, we hope to explore grassroots uses for this kind of technology. What could farmers or activists do with leaf-scale, plant-scale, lot-scale, and field-scale data on plant health if the equipment costs as little as $10 or $35?**
![Screen_Shot_2013-05-15_at_12.44.07_PM.png](https://i.publiclab.org/system/images/photos/000/000/308/medium/Screen_Shot_2013-05-15_at_12.44.07_PM.png)
Screenshot from 2011-09-10-colorado-boulder-foothills-community-park-NRG.
See how clearly plants are identifiable from bare earth or pavement.
The unique colors in this photo will be explained below, keep reading!
##Why does it work?##
Though we cannot perceive it with our eyes, everything around us (including plants) reflect wavelengths of light in red, green, blue and beyond into infrared, ultraviolet, and more. Our colorful world is created by varying amounts of particular wavelengths being absorbed and reflected. This also means that everything has a recognizable "spectral signature". Whoa.
Plants use visible light (mainly blue and red light) as 'food' -- but not so much green light, which is why they reflect green away, and thus look green to our eyes. They also happen to reflect near infrared light (which is just beyond red light, but not visible to the human eye). This is because they chemically cannot convert infrared into usable food, and so they just bounce it away to stay cool. The illustrations show what colors of light plants _absorb_ versus _reflect_ away.
By using this unique property of plants, plus our ability to take [near-infrared photos](/tool/near-infrared-camera) we can create composite images which highlight where plants are and how much they are photosynthesizing.
[Learn about NDVI images and how they work](/wiki/ndvi)
We've been modifying cheap cameras to photograph in infrared (IR). The sensors in common digital cameras are sensitive to infrared, but come with a filter that blocks these wavelengths so that the photos look "normal" to us. Removing that filter allows us to pickup information in IR, and in that way begin to "see the invisible life of plants."
##Make an infrared camera:##
(note: this video was made when people were still putting the film negative on the outside of the camera lens. To put the film negative directly inside the camera, once you have the infrared filter removed, put your cut film negative where the filter was, replace the rubber gasket and continue with the steps in the video for reassembling.)
NDVI example:
NRG example:
##How to take infrared and visible photographs##
By putting both an infrared-pass filter and an infrared-block filter on the same camera, you can get both infrared and visible light with one photograph... though the areas don't overlap. This means you can get such imagery from the air using [balloon mapping](/tool/balloon-mapping), while only risking one camera. Another alternative is to use a [stereo camera](/tool/stereo-camera) system like the one being developed by the [New York City chapter](/place/new-york-city).
##Using Photoshop to do vegetation analysis with your pictures##
You can use Adobe Photoshop (or GIMP, for an open-source, free alternative) to composite an infrared and visible image to do vegetation/photosynthesis analysis. The example photos were taken from an airplane window by Stewart Long. For a more comprehensive description of this process, and alternative means to do this analysis, see the [infrared vegetation analysis activity](/wiki/infrared-vegetation-analysis-activity).
###Using MapKnitter to make infrared/visible composites###
If you captured infrared and visible pictures from a balloon or kite, you can stitch them into a map using mapknitter.org. Mapknitter supports [compsiting](/wiki/mapknitter-multispectral). It looks something like this, so far: