Abstract
Grape yield estimation has traditionally been performed using manual techniques. However, these tend to be labour intensive and can be inaccurate. Computer vision techniques have therefore been developed for automated grape yield estimation. However, errors occur when grapes are occluded by leaves, other bunches, etc. Synthetic aperture radar has been investigated to allow imaging through leaves to detect occluded grapes. However, such equipment can be expensive. This paper investigates the potential for using ultrasound to image through leaves and identify occluded grapes. A highly directional low frequency ultrasonic array composed of ultrasonic air-coupled transducers and microphones is used to image grapes through leaves. A fan is used to help differentiate between ultrasonic reflections from grapes and leaves. Improved resolution and detail are achieved with chirp excitation waveforms and near-field focusing of the array. The overestimation in grape volume estimation using ultrasound reduced from 222% to 112% compared to the 3D scan obtained using photogrammetry or from 56% to 2.5% compared to a convex hull of this 3D scan. This also has the added benefit of producing more accurate canopy volume estimations which are important for common precision viticulture management processes such as variable rate applications.
Highlights
While promising, the results suggest that more resolution and detail of the canopy can be obtained if the acoustic array had a narrower beamwidth
Near-field focusing of the array could help improve imaging resolution and provide more accurate representation of the scene resulting in a better understanding of the true canopy volume
This paper presents a novel approach for the detection of grape clusters which are occluded by foliage using an ultrasonic array
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The effectiveness of these studies was limited by their use of ultrasonic transducers, which operated independently and not as arrays, to measure the distance to the outer surface of the foliage. These individual transducers have had a relatively wide beamwidth, and generally, the only information used from the reflected signal is the time of first echo from the foliage [11]. We present a new technique for improving the resolution of the array based cross-correlation for near-field echoes This approach simulates the effect of focusing the transmission of the array at any desired depth in postprocessing.
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