A color composite technique for detecting root dynamics of barley (Hordeum vulgare L.) from minirhizotron images

Heeraman, D. A.; Crown, P.H.; Juma, N. G.

doi:10.1007/bf00011056

Cited by 12 publications

(13 citation statements)

References 19 publications

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“…Methodological imperfection such as over and under estimation of detected areas (RingroseVoase 1991; Pan et al 1998) or inclusion of background objects (Heeraman et al 1993) were minimized by the definition of suitable thresholds. Hence, the visualization and detection technique applied in this study allows an improved analysis of the oxidized and reduced areas of the soil in terms of their development in space and time (Fig.…”

Section: Image Analysismentioning

confidence: 99%

Monitoring of root growth and redox conditions in paddy soil rhizotrons by redox electrodes and image analysis

2010

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The root-zone of wetland rice was monitored in a paddy soil throughout a vegetation period with the aid of a rhizotron experiment. For this purpose (a) digital images of the root-zone were taken daily, and (b) the redox potential was measured in situ every day. The images were processed by image analysis in order to display areas of oxidation and reduction in the soil. Therefore, thresholds were set to simplify the localization and quantification of discrete areas which were colourized due to the redox potential. Both, images and measured redox potentials, provide the basis for the visualization of the root and redox dynamics in the root-zone. The anaerobic root-zone of flooded paddy soils is significantly influenced by the aerenchymal transport of oxygen to rice roots. The release of oxygen into the rhizosphere, which causes different patterns of oxidized and reduced areas in the course of the vegetation period, also affects microbial communities such as methane producing archaea or methane oxidizing bacteria. The visualization of redox dynamics may, therefore, be useful to localize potential hotspots for the microorganisms in the root-zone of paddy soils. The reduced and oxidized conditions changed spatiotemporally. Oxidized areas were mostly found in the surrounding of active roots and in a distinct layer next to the soil surface. Reduced areas shifted from beneath the oxidized surface layer into sparsely-rooted soil. The ratio of the analyzed oxidized and reduced areas was oscillating with increasing intensity throughout the monitored vegetation period.

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Section: Image Analysismentioning

confidence: 99%

Monitoring of root growth and redox conditions in paddy soil rhizotrons by redox electrodes and image analysis

2010

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“…Numerous nondestructive studies have been conducted using belowground rhizosphere images to examine root dynamics (e.g., Hendrick and Pregitzer 1992;Heeraman et al 1993;Majdi and Öhrvik 2004). For example, in the minirhizotron method (Hendrick and Pregitzer 1992), which is currently one of the most widely used methods in field studies, fine-root dynamics are observed through the repeated capture of images of roots growing on the sides of transparent tubes installed in the soil.…”

Section: Introductionmentioning

confidence: 99%

Classification of rhizosphere components using visible–near infrared spectral images

2007

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To establish new techniques for automatic classification of rhizosphere components, we investigated the utility of visible (VIS) and near-infrared (NIR) spectral images of the rhizosphere under two soil moisture conditions (mean volumetric water content: 0.39 and 0.16 cm 3 cm −3 ). Spectral reflectance images of the belowground parts of hybrid poplar cuttings (Populus deltoides × P. euramericana, I45/ 51) grown in a rhizobox were recorded at 120 spectral bands ranging from 480 to 972 nm. We examined which wavelengths were suitable and the number of spectral bands needed to accurately classify live roots of four age classes, dead roots, leaf mold, and soil. VIS reflectance (<700 nm) of live roots first increased and then decreased with age, whereas NIR reflectance (≥700 nm) was stable in mature roots. The reflectance of dead roots was lower than that of mature roots in both the VIS and NIR spectral regions. VIS reflectance did not differ among dead roots, leaf mold, and soil, but the NIR reflectance was clearly lower in soil than in the other materials. The reflectance of leaf mold and soil increased mainly in the NIR spectral region with reducing soil moisture, but this increase did not affect the order of reflectance intensity among the rhizosphere components in general. Although the most suitable spectral bands statistically selected for classifying rhizosphere components differed somewhat between moist and dry conditions, the spectral bands 580-679 nm (VIS) and 848-894 nm (NIR) provided high reliability under both conditions. Classification accuracy was higher when using two to five VIS-NIR images (overall accuracy ≥87.8%) than three VIS images (red, green, and blue; accuracy <67.1%). The high accuracy with VIS-NIR was mainly due to successful separation of leaf mold and soil. Irrespective of soil moisture condition, the overall accuracy tended to be stable at 92-94% with use of four VIS-NIR images. The spectral bands effective in wet soil conditions could also be used for classification in dry conditions, with overall accuracies >86.9%. These results suggest that automatic image analysis using VIS-NIR images at four spectral bands, including red and NIR, allows for accurate classification of the growth stage or live/dead status of roots and distinguishes between leaf mold and soil.

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“…coring (Bragg et al 1983;Hansson and Andren 1987;McMichael and Taylor 1987;Hansson et al 1992;Andren et al 1993;Heeraman and Juma 1993;Wiesler and Horst 1994). Minirhizotrons have been widely used to estimate the rooting distribution in the surrounding soil.…”

Section: Estimation Of Sulk Soi/ Parametersmentioning

confidence: 98%

“…Minirhizotrons have been widely used to estimate the rooting distribution in the surrounding soil. Various explanations have been given for this discrepancy in root data: (Upchurch and Ritchie 1983;Bragg et al 1984;Heeraman and Juma 1993), 3. coring (Bragg et al 1983;Hansson and Andren 1987;McMichael and Taylor 1987;Hansson et al 1992;Andren et al 1993;Heeraman and Juma 1993;Wiesler and Horst 1994).…”

Section: Estimation Of Sulk Soi/ Parametersmentioning

confidence: 99%

“…There are several factors that may contribute to the poor quality of minirhizotron images. Low battery power can also contribute to photometric distortion due to poor illumination by the incandescent bulbs of the minirhizotron camera (Heeraman et al 1993). Non-perpendicular viewing or camera-tube non-linearity may lead to geometrically distorted images (Heeraman et al 1993).…”

Section: Segmentation Of Minirhizotron Imagesmentioning

confidence: 99%

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Root Methods

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A color composite technique for detecting root dynamics of barley (Hordeum vulgare L.) from minirhizotron images

Cited by 12 publications

References 19 publications

Monitoring of root growth and redox conditions in paddy soil rhizotrons by redox electrodes and image analysis

Monitoring of root growth and redox conditions in paddy soil rhizotrons by redox electrodes and image analysis

Classification of rhizosphere components using visible–near infrared spectral images

Root Methods

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