List of accepted submissions
Oral Session
Presentation Number | Abstract ID. | Title |
1 | 3 | High-throughput phenotyping as a tool for cotton breeding for drought tolerance |
2 | 23 | 3-Demeter: an affordable 3-D phenotyping software |
3 | 27 | Open tools for plant phenotyping |
4 | 30 | Aerial imagery to select maize hybrids to nitrogen use efficiency |
5 | 35 | Phenotyping transpiration dynamics in real time: the key to mine the banana biodiversity for better water use efficiency? |
6 | 39 | Non-destructive Fluorescence Spectroscopy based phenotyping technique for soybeans cultivars discrimination. |
7 | 50 | UAV- based imagery for phenotyping in breeding and physiological pre-breeding of wheat at CIMMYT. |
8 | 53 | Developing plant and crop phenomics in Argentina. A project in progress |
9 | Invited* | Assessing wheat traits by spectral reflectance: do we really need to focus on predicted trait-values or directly identify the elite genotypes group? |
10 | Invited* | Genetic mapping of quantitative trait loci for longitudinal traits in a wheat MAGIC mapping population |
* Latin-American researcher and/or scientific committee member
Poster Session
Poster number | Abstract ID. | Title |
1 | 1 | Use of image phenotyping for screening Pyrenophora tritici-repentis resistance in wheat |
2 | 2 | High Resolution Magic Angle Spinning and Solid-State NMR spectroscopy methods to explore the metabolome of soybean genotypes upon abiotic stress |
3 | 4 | Evaluating the effects of microorganism biostimulants in maize to improve plant growth |
4 | 5 | Morphological characterization of two sorghum diversity panels grown in nutrient solution with low phosphorus |
5 | 6 | Exploring soybean traits through multivariate analysis in contrasting rust environments |
6 | 7 | Methodology for evaluation of biostimulants effects on maize root system |
7 | 8 | Weed species phenotyping into a culture of maize for the precision application of herbicides |
8 | 9 | Monitoring device of the health conditions of the plants using the photoacoustic detection by RGB LED lighting |
9 | 10 | A new approach for plant phenotyping and image segmentation based on contextual information |
10 | 11 | Correlations between reflectance indices and seed yield in contrasting Asian soybean rust managements |
11 | 12 | Study of mortality, growth and initial genetics parameters in Corymbia spp. populations |
12 | 13 | Low-cost thermal imager for plant phenotyping |
13 | 14 | Collecting physiological parameters in field conditions with a dedicated multispectral camera |
14 | 15 | Heat priming effects on alleviating later damages of heat stress for different wheat cultivars |
15 | 16 | Estimation of corn plant population density by digital image analysis and NDVI |
16 | 17 | Canopy sensors for estimating in-season corn grain yield potential |
17 | 18 | Phenotyping for drought tolerance of a biparental wheat population, using agronomic traits for validation of spectral and fluorescence sensors |
18 | 19 | Monitoring of evapotranspirated plant water in the SITIS Platform |
19 | 20 | Use of a capacitive sensor in the SITIS Phenotyping Platform for the automated determination of the effective area of the root system to uptake water |
20 | 21 | SITIS – Plant Phenotyping Platform |
21 | 22 | Plant irrigation automated control in the SITIS Platform |
22 | 24 | Low-cost thermal field mapping |
23 | 25 | Color correction method applied to plant phenotyping |
24 | 26 | An open source tool for automated phenotyping of seed germination through image analysis |
25 | 28 | Validation of spectral and fluorescence sensors for wheat tolerance to drought in field conditions in Cerrado region |
26 | 29 | A protocol for measuring canopy temperature of sugarcane plots in the field using a thermal imager embarked in an UAV |
27 | 31 | Non-invasive measurement of soil water, using Time Domain Reflectometry (TDR) technique to study roots growth |
28 | 32 | Use of thermal imaging for discrimination of maize genotypes submitted to water deficit stress |
29 | 33 | Traits associated with seed yield in contrasting environments for soybean rust |
30 | 34 | Validation of spectral and fluorescence sensors for soybean tolerance to drought in field conditions, in Brasilian Cerrado, using physiological parameters |
31 | 36 | Vegetation indexes for management of irrigated wine vine orchard |
32 | 37 | Global network for precision wheat phenotyping |
33 | 38 | A selective VOC biosensor based on microcantilever functionalized with enzyme. Potential application on plant investigations |
34 | 40 | Laser Induced Breakdown Spectroscopy as Analytical Tool for soybeans cultivars discrimination |
35 | 41 | Fast Detection of Tan Spot and Powdery Mildew on Wheat using Deep Learning |
36 | 42 | Image analysis for measuring pod dimensions in vegetable soybean |
37 | 43 | Validation of spectral and florescence sensors with growth parameters in sugar cane submitted to different water levels |
38 | 44 | Phenotypic screening of Toropi x IAC13 population under hydroponic solution |
39 | 45 | Imagery to study morphological responses of maize root traits under low nitrogen condition |
40 | 46 | Imagery to study the effects of Azospirillum brasiliense inoculation in maize root morphological traits |
41 | 47 | Biomass phenotyping in high yield potential rice genotypes |
42 | 48 | Use of thermographic sensors to determine the water status of plants in a controlled environment |
43 | 49 | Prediction of sun damage in Granny Smith apple fruit |
44 | 51 | Opportunities and Challenges of Phenotyping in the Genome-Assisted Breeding Era: Experiences from the International Potato Center |
45 | 52 | Portable NMR equipment applied to a non-invasive study of the water with the soil matrix |
46 | 54 | Evaluation of rice genotypes for resistance to Diatraea saccharalis (Fabricius) using phenotyping methods |
47 | 55 | Phenotyping is essential to enhance phosphorus efficiency in maize and sorghum |
48 | 56 | Chlorophyll content measured directly and indirectly in high yield potential rice genotypes |
49 | 57 | Phenotyping of creole popcorn maize for organic systems in Goiânia, GO |
50 | 58* | Microfluidic devices and surface functionalization for cell adhesion studies |
* Submission withdrawn by the authors