Abstract
In-field mango fruit sizing is useful for estimation of fruit maturation and size distribution, informing the decision to harvest, harvest resourcing (e.g., tray insert sizes), and marketing. In-field machine vision imaging has been used for fruit count, but assessment of fruit size from images also requires estimation of camera-to-fruit distance. Low cost examples of three technologies for assessment of camera to fruit distance were assessed: a RGB-D (depth) camera, a stereo vision camera and a Time of Flight (ToF) laser rangefinder. The RGB-D camera was recommended on cost and performance, although it functioned poorly in direct sunlight. The RGB-D camera was calibrated, and depth information matched to the RGB image. To detect fruit, a cascade detection with histogram of oriented gradients (HOG) feature was used, then Otsu’s method, followed by color thresholding was applied in the CIE L*a*b* color space to remove background objects (leaves, branches etc.). A one-dimensional (1D) filter was developed to remove the fruit pedicles, and an ellipse fitting method employed to identify well-separated fruit. Finally, fruit lineal dimensions were calculated using the RGB-D depth information, fruit image size and the thin lens formula. A Root Mean Square Error (RMSE) = 4.9 and 4.3 mm was achieved for estimated fruit length and width, respectively, relative to manual measurement, for which repeated human measures were characterized by a standard deviation of 1.2 mm. In conclusion, the RGB-D method for rapid in-field mango fruit size estimation is practical in terms of cost and ease of use, but cannot be used in direct intense sunshine. We believe this work represents the first practical implementation of machine vision fruit sizing in field, with practicality gauged in terms of cost and simplicity of operation.
Highlights
On-tree estimation of fruit size is useful for the prediction of maturity and harvest time [1,2], and estimation of crop yield [1,3], and can inform packing material purchasing and marketing arrangements [4]
In the current study we propose to continue the use of color thresholding and ellipse fitting, but with addition of cascade detection with histogram of oriented gradients (HOG) features instead of Support Vector Machines (SVM)
We extend our previous work employing a farm vehicle-mounted machine vision system with Light Emitting Diode (LED) illumination for mango fruit count estimation [15,18], with improvement in the machine vision algorithm used for detection of fruit and addition of camera to fruit distance measurement to allow for fruit sizing
Summary
On-tree estimation of fruit size is useful for the prediction of maturity and harvest time [1,2], and estimation of crop yield [1,3], and can inform packing material (tray insert) purchasing and marketing arrangements [4]. Mango fruit size varies between varieties, but a typical variety size variation from stone hardening to harvest maturity is 60 to 160 mm in length, 50 to 130 mm in width, with a rate of change of 0.3 and. To address segmentation was was conducted conducted on on the the image image snips snips from from the cascade fruit detection. The original bounding box containing detected fruit was doubled in size the cascade fruit detection. The original bounding box containing detected fruit was doubled in size to to ensure coverage of the entire fruit. Color space ensure coverage of the entire fruit. The image snip was converted into CIE L*a*b* color space and separate the fruit contour contour in in the the L* L* channel.
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