- Step 1: Select color range
- Step 2: Detect weeds
- Step 3: Scan the entire garden
- Step 4: Remove weeds with FarmBot
- How it works
- What’s next?
FarmBot is designed to remove weeds early and often, so that the weeds are always small, young, and fragile, and therefore easily removed by the weeding tool. FarmBot finds weeds by using computer vision software to detect all plants in the bed and then mark any detected plant that was not planted by FarmBot as a weed.
To use the weed detection feature, you must first calibrate the camera.
The weed detector software needs a range of color to look for when determining what is a plant and what is soil or other background. Use the sliders for HUE, SATURATION, and VALUE to select a range of colors you want to detect. The color boxes will give an indication of the range selected. For the hue slider, a green color range is approximately
Move the FarmBot over a section of soil. Press Weeds for additional information.to instruct FarmBot to take a photo and then process that image with the weed detection software. Any weeds found in the image will appear in the map, and be listed as PENDING in the weeds panel. See
can be used to run weed detection on an image already taken, instead of taking a new photo.
Detect weeds across FarmBot’s entire bed by creating a sequence of movements in a grid pattern with a detect weeds command at each grid point. For step-by-step instructions, see the Scan the Garden for Weeds How-to guide.
Weed removal can be performed by creating a weed removal sequence that uses the weeding tool on weeds in the farm designer.
If we process a photo of our garden bed without providing any information, we would detect all the plants in the image:
However, we want to determine what is a weed, and the locations of those weeds.
So we feed the plant detection software some calibration parameters, letting it determine the location of the objects in the image. Based on the known locations of desired plants in the image, we can determine which plants are desired plants, and which ones are weeds.
Known (desired) plants are marked with a green circle, the detected plants that match the desired plants are marked with a blue circle, and the detected plants that do not match desired plants are marked with a red circle (those are weeds):
You can see a grid overlay showing the coordinate system and that the image has been rotated slightly to adjust for camera rotation.
But wait! Our weeding tool is a certain size, and disrupts the soil within a certain area, its region of influence. We can represent that disrupted region with a grey circle:
We see that the weeder might affect the lower left plant when weeding weed number
1, since its region of influence is intersecting the desired plant’s circle. We also see that we wouldn’t be able to weed
2 without significantly disrupting the upper right plant. We can weed
The software takes the weeding tool size into consideration with a feature called Safe Remove.
It adjusts the location to be weeded for weed
1 away from the lower left plant, removes weed
2 from the list since it can’t be removed safely, and keeps
3 on the list of weeds to remove since there are no conflicts. You can see the weeds to remove and the weeder location represented with the red and grey circles as before, and cyan circles drawn for weeds that may not be removed completely (or at all) because the action might harm a desired plant:
You may now instruct the machine to remove the weeds marked in red, and remove the weeds marked in cyan by hand.
Program text output
7 plants detected in image. 4 known plants inputted. Plants at the following machine coordinates ( X Y ) with R = radius are to be saved: ( 600 400 ) R = 45 ( 600 500 ) R = 45 ( 700 400 ) R = 25 ( 700 500 ) R = 25 2 plants marked for removal. Plants at the following machine coordinates ( X Y ) with R = radius are to be removed: ( 743 541 ) R = 6 ( 654 447 ) R = 6 2 plants marked for safe removal. Plants at the following machine coordinates ( X Y ) with R = radius were too close to the known plant to remove completely: ( 651 446 ) R = 7 ( 676 512 ) R = 3 4 detected plants are known or have escaped removal. Plants at the following machine coordinates ( X Y ) with R = radius have been saved: ( 700 410 ) R = 31 ( 596 396 ) R = 53 ( 698 485 ) R = 29 ( 600 499 ) R = 42
These are some common errors that can occur when doing weed detection.
[plant-detection] ERROR: Coordinate conversion calibration values invalid for provided image.
This error occurs because the camera was calibrated at a different z-axis height than the current z height. This error can also happen if the camera rotation value was changed significantly after camera calibration. The solution is to move to the calibrated height (usually 0) or re-calibrate the camera.
These advanced settings are not shown by default.
Once an image has been taken with the camera, the weed detector software will process it. There are several advanced processing parameters (BLUR, MORPH, and ITERATION) that can help you fine tune the system to perform the best in your environment. The default values should work in most circumstances, though if you are seeing poor results or working in a non-standard environment, you may adjust these settings to further tune your system.