Re-inventing model-based decision support with Australian dryland farmers. 4. Yield Prophet® helps farmers monitor and manage crops in a variable climate

Hochman, Zvi; Rees, Harm van; Carberry, Peter; Hunt, James R.; McCown, R. L.; Gartmann, A.; Holzworth, Dean; Rees, Stephen van; Dalgliesh, Neal; Long, W.H.; Peake, Allan; Poulton, Perry; McClelland, Tim

doi:10.1071/cp09020

Cited by 142 publications

(62 citation statements)

References 23 publications

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“…Approximately 30% of ET must occur after AN for the maximum HI, as determined by cultivar and other aspects of climate, can be reached. Use of the wheat simulation model APSIM (see later) has further improved consideration of the effect of rainfall distribution, and simulations with historical weather suggests that PY w is best represented by a boundary function of about the same slope as determined by French and Schultz (1984), but which cannot be reached in all years because of poor rainfall distribution or water losses through deep drainage, run-off, or very late rain events (Hochman et al 2009b).…”

Section: A Simple Modelmentioning

confidence: 99%

“…CERES 0.90 t/ha, and Sirius 0.90 t/ ha]. In Australia, APSIM-Wheat was developed from CERES and now dominates (Asseng et al 1998(Asseng et al , 2011Wang et al 2003;Hochman et al 2009aHochman et al , 2009bLudwig and Asseng 2010). The model uses daily time steps and includes a phenological framework, leaf expansion, crop growth driven by either radiation interception and RUE or transpiration and TE (whichever is most limiting), root penetration and layered soil water and N uptake, water and N stress indices feeding back into leaf area and RUE, and finally estimates of GN and GW.…”

Section: Simulation Modellingmentioning

confidence: 99%

“…weeds, disease) could be part of the error; inadequate physiology is presumably the rest. Interestingly, the model, using 'best bet' values for plant density, N and time of sowing, gives an estimate of PY w against which to benchmark the farmers' yields; the latter averaged 77% of PY w (Hochman et al 2009b).…”

Section: Simulation Modellingmentioning

confidence: 99%

“…APSIM-Wheat is certainly sufficiently accurate and user friendly to inform farm management decisions, especially in dryland situations where rain is uncertain, and yield response risk needs to be quantified, and adjusted according to somewhat skilful seasonal forecasts and unfolding seasonal weather; in this role in Australia it has been renamed Yield Prophet (Hochman et al 2009b). Model accuracy across a sample of 334 crops of 'elite' farmers over 2004-07, however, remains an issue; farmers want 0.5 t/ha accuracy while currently the RMSD of model versus observed is 0.8 t/ha, and there was a bias towards yield underestimate at high yield levels (Hochman et al 2009a, Fig.…”

Section: Simulation Modellingmentioning

confidence: 99%

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Wheat physiology: a review of recent developments

Fischer¹

2011

Crop Pasture Sci.

339

251

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Abstract. This review focuses on recent advances in some key areas of wheat physiology, namely phasic development, determination of potential yield and water-limited potential yield, tolerance to some other abiotic stresses (aluminium, salt, heat shock), and simulation modelling. Applications of the new knowledge to breeding and crop agronomy are emphasized. The linking of relatively simple traits like time to flowering, and aluminium and salt tolerance, in each case to a small number of genes, is being greatly facilitated by the development of molecular gene markers, and there is some progress on the functional basis of these links, and likely application in breeding. However with more complex crop features like potential yield, progress at the gene level is negligible, and even that at the level of the physiology of seemingly important component traits (e.g., grain number, grain weight, soil water extraction, sensitivity to water shortage at meiosis) is patchy and generally slow although a few more heritable traits (e.g. carbon isotope discrimination, coleoptile length) are seeing application. This is despite the advent of smart tools for molecular analysis and for phenotyping, and the move to study genetic variation in soundly-constituted populations. Exploring the functional genomics of traits has a poor record of application; while trait validation in breeding appears underinvested. Simulation modeling is helping to unravel G Â E interaction for yield, and is beginning to explore genetic variation in traits in this context, but adequate validation is often lacking. Simulation modelling to project agronomic options over time is, however, more successful, and has become an essential tool, probably because less uncertainty surrounds the influence of variable water and climate on the performance of a given cultivar. It is the everincreasing complexity we are seeing with genetic variation which remains the greatest challenge for modelling, molecular biology, and indeed physiology, as they all seek to progress yield at a rate greater than empirical breeding is achieving.

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Section: A Simple Modelmentioning

confidence: 99%

Section: Simulation Modellingmentioning

confidence: 99%

Section: Simulation Modellingmentioning

confidence: 99%

Section: Simulation Modellingmentioning

confidence: 99%

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Wheat physiology: a review of recent developments

Fischer¹

2011

Crop Pasture Sci.

339

251

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“…Decision support tools based on agrometeorological models have been developed or are in development for various semiarid regions to serve large-scale mechanized agriculture or smallholder systems (Sadras et al, 2003;Hochman et al, 2009;McCown et al, 2009;Chen, 2017;Prokopy et al, 2017; http:// climateengine.org, https://www.agbizlogic.com). The increasing accessibility of data, continuing innovation, and improvement of user interfaces, and improvement of climate models is certain to accelerate development and deployment of these tools into the future.…”

Section: Social and Economic Dimensionsmentioning

confidence: 99%

Confronting Climate Change Challenges to Dryland Cereal Production: A Call for Collaborative, Transdisciplinary Research, and Producer Engagement

Eigenbrode

Binns²,

Huggins

2018

Front. Ecol. Evol.

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Semi-arid cereal systems face challenges worldwide that are driven by ongoing and projected climate change. These challenges include ensuring cropping system resilience and productivity under changing water and temperature regimes while reversing soil degradation, reducing crop susceptibility to pests, pathogens and weed competition, and exploiting genetic resources to develop cultivars with resilience to climate stresses and improved compatibility with cropping system innovations. Meeting these interdependent challenges requires transdisciplinary efforts that integrate knowledge across many scientific domains. The USDA-NIFA-funded coordinated agricultural project, "Regional Approaches to Climate Change for Pacific Northwest Agriculture" (REACCH), employed this transdisciplinary approach to address climate change and sustainability challenges for rain-fed cereal-based systems in the semi-arid intermountain Pacific Northwest. To engage with and contribute to similar efforts globally, REACCH sponsored a workshop "Transitioning Cereal Systems to Adapt to Climate Change" (TCSACC) in November 2015. Participants from 17 countries and five continents with expertise in agronomy, crop physiology, crop modeling, crop protection, breeding and genetics, sociology and economics shared their perspectives, successes, and challenges to achieving transdisciplinary research integration for semi-arid cereal systems under changing climates. Conference goals were to: (1) strengthen the global network of researchers addressing climate change effects on semi-arid cereal-based systems, (2) share the approaches to achieving transdisciplinary collaboration to advance climate change resilience in cereal systems, and (3) identify the elements of a collaborative research agenda that are needed to advance global food security in the twenty-first century. This paper distills the conference themes and summarizes the calls to action that were discussed: Establish coordinated, large scale, transdisciplinary efforts; Consider Genetic × Environment × Management × Social system (G × E × M × S) interactions; Integrate social, economic, and biophysical science, and Eigenbrode et al.Dryland Cereal Production and Climate Change engineering; Improve integration among knowledge communities; Consider global context of production systems; Develop more inclusive cropping system models; Enable comprehensive data management and data sharing; Include landscape and ecosystem services perspectives; Establish and support existing global collaboration networks.

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Agronomic Principles of Water‐ and Nutrient‐Use Efficiency

Kirkegaard¹,

Robertson²

2013

Improving Water and Nutrient‐Use Efficiency in Food Production Systems

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Re-inventing model-based decision support with Australian dryland farmers. 4. Yield Prophet® helps farmers monitor and manage crops in a variable climate

Cited by 142 publications

References 23 publications

Wheat physiology: a review of recent developments

Wheat physiology: a review of recent developments

Confronting Climate Change Challenges to Dryland Cereal Production: A Call for Collaborative, Transdisciplinary Research, and Producer Engagement

Agronomic Principles of Water‐ and Nutrient‐Use Efficiency

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