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Measuring soil density with a smartphone camera

13-08-2020 | |
Measuring soil density with a smartphone camera
Measuring soil density with a smartphone camera

Scientists at New Mexico State University have developed a way to use a smartphone camera and some 3D-printed tools to measure soil density.

Using a regular smartphone camera and some 3D-printed tools, scientists at New Mexico State University have developed an easier way to measure soil density, according to the American Society of Agronomy. With the volume and weight of soil samples, scientists can compare the nutrient or carbon stocks in soils in order to better manage them. With their new system, they cheaply reproduced expensive, time-consuming methods that require lasers or messy wax.

“The new approach could allow scientists around the world to speed up their work with tools they already have or can easily acquire,” says Colby Brungard, a researcher at New Mexico State University.

Determining the volume of soil clumps

To determine soil density, scientists need the weight, or mass, of a clump of soil, along with the volume. Determining weight just requires a scale. But determining the volume of soil clumps – called peds – is traditionally a much more difficult task.

The original method to measure the volume carefully coated the soil ped in wax and then placed it in water. Three-dimensional laser scanning has emerged as an alternative, but it’s pricey and time-consuming.

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Scientists can now use mobile imagery and an app to determine bulk density of soil more easily. - Photo: Rachel Schutte

Scientists can now use mobile imagery and an app to determine bulk density of soil more easily. – Photo: Rachel Schutte

Mobile app

With these challenges in mind, Brungard was casting about for a better method. Based on a colleague’s work, he knew photographs could be used to measure volume. So, he figured all he needed were photos from the right angles and a scale. Brungard decided to pitch the idea of creating a mobile app to students during a guest lecture.

“When I gave the guest lecture, I explained my idea and asked the undergraduate students if any of them had an interest in taking on the project,” says Brungard. “Michael Whiting, a student in the class and the lead author of the paper, volunteered and did the research.”

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Experimental set up showing soil sample on a 3D-printed turntable with cell phone. A light provides consistent illumination while a white background and white turntable top reduce background influence. The soil sample is rotated on the turn table while taking an image every one fourth rotation. - Photo: Colby Brungard

Experimental set up showing soil sample on a 3D-printed turntable with cell phone. A light provides consistent illumination while a white background and white turntable top reduce background influence. The soil sample is rotated on the turn table while taking an image every one fourth rotation. – Photo: Colby Brungard

Smartphone camera and 3D printer

The team turned to modern conveniences. They knew that smartphones had cameras good enough to take high-resolution photos of a soil ped. To get a consistent view of the entire soil sample, they used a 3D printer to create a tiny turntable just a few inches across. The turntable had a cradle for the phone, to keep it still. And it had a simple crank allowing it to be turned by hand while the phone grabbed multiple pictures.

The scientists uploaded the pictures to a program that could stitch them together into a 3D image, which gave a measure of the volume. When they compared the smartphone system to the old standbys of laser-scanning or wax-dipping, the final measurements were nearly identical. That accuracy proved true across five different types of soil peds.

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Examples of 3D renders derived from photogrammetry (left) and 3D laser scanning (right). The photogrammetry resulted in a render with the highest resolution. - Photo: Colby Brungard

Examples of 3D renders derived from photogrammetry (left) and 3D laser scanning (right). The photogrammetry resulted in a render with the highest resolution. – Photo: Colby Brungard

15 minutes per sample

The smartphone system was fast, too. It took just 15 minutes per sample, while a laser scan can take an hour and a half. But there was downtime while the computer program analysed the images, a computationally intensive task. Nonetheless, the method was simple, fast, cheap and accurate.

“The photogrammetry method doesn’t involve any complicated or expensive equipment like traditional 3D laser scanners as even low-budget cell phones likely have cameras that are adequate,” says Brungard. “Others can quickly replicate this because of the high functionality of cell phones.” Plus, plans for the 3D turntable are available online.

Learn more about this work in the Soil Science Society of America Journal, a publication of the Soil Science Society of America.

Claver
Hugo Claver Web editor for Future Farming





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