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Leveraging Artificial Intelligence to Transform Agrifood Systems: A Comprehensive Survey of Progress, Challenges, and Opportunities


核心概念
Artificial intelligence (AI) techniques, such as deep learning, can significantly transform agrifood systems by enhancing food security, reducing waste, and improving supply chain management through comprehensive data analysis and accurate predictions.
摘要

This survey provides a comprehensive review of how AI techniques are being applied to empower agrifood systems, covering a wide range of topics across agriculture, animal husbandry, and fishery.

The key highlights include:

  1. Data Acquisition in Agrifood Systems:

    • Discusses various data sources, including satellites, unmanned aerial vehicles (UAVs), onsite devices, and laboratory conditions, and their characteristics for different agrifood applications.
    • Covers data storage and preprocessing approaches to prepare the data for AI-based analysis.
  2. Progress Review of AI Methods in Agrifood Systems:

    • Categorizes existing AI methods into traditional machine learning and deep learning approaches.
    • Examines the application of AI techniques in diverse agrifood tasks, such as agrifood classification, growth monitoring, yield prediction, and more.
    • Showcases the advantages of AI methods in terms of accuracy, scalability, and cost-effectiveness compared to traditional approaches.
  3. Potential Challenges and Future Opportunities:

    • Identifies key challenges, including data collection, appropriate method selection, and data storage and processing.
    • Discusses promising research directions, such as leveraging foundation models, ensuring trustworthy AI, and integrating IoT technologies.

The survey aims to provide an overview of the current state of AI in agrifood systems, inspire further research, and promote the application of advanced AI techniques to overcome challenges and unlock the full potential of this field.

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"With the world population rapidly increasing, transforming our agrifood systems to be more productive, efficient, safe, and sustainable is crucial to mitigate potential food shortages." "Recent advances in artificial intelligence (AI) techniques have demonstrated their ability to handle large-scale data in various fields, including natural language processing, computer vision, medical imaging, remote sensing (RS), and more."
引用
"Achieving this requires a smarter system that can handle the large amounts of data generated by agrifood systems and make accurate predictions." "Despite these challenges, recent progress in AI techniques, such as DL, has shown great potential in solving these issues and improving the performance of smart agrifood systems."

更深入的查询

How can advanced AI techniques, such as large-scale foundation models, be effectively leveraged to address the unique challenges in agrifood systems?

Advanced AI techniques, particularly large-scale foundation models, can be effectively leveraged in agrifood systems to tackle unique challenges such as data scarcity, variability in environmental conditions, and the need for real-time decision-making. These models, trained on vast datasets, can generalize well across different agrifood applications, enabling them to handle diverse tasks such as crop yield prediction, disease detection, and resource optimization. Data Integration and Analysis: Large-scale foundation models can integrate heterogeneous data sources, including remote sensing (RS) data, UAV imagery, and ground-based sensor data. By employing techniques like transfer learning, these models can adapt to specific agrifood tasks, improving their predictive accuracy and robustness. For instance, they can analyze multi-temporal satellite images to monitor crop health and predict yields, thereby enhancing food security. Real-time Monitoring and Decision Support: The ability of these models to process and analyze data in real-time allows for dynamic monitoring of agrifood systems. This capability is crucial for timely interventions, such as detecting crop diseases early or optimizing irrigation schedules based on current weather conditions. By providing actionable insights, AI can significantly reduce waste and improve resource management. Scalability and Efficiency: Large-scale foundation models can efficiently process large volumes of data, making them suitable for large-scale agricultural operations. Their scalability ensures that they can be deployed across various regions and crop types, facilitating the development of precision agriculture practices that are tailored to local conditions. Predictive Analytics: These models can enhance predictive analytics in agrifood systems by utilizing historical data to forecast future trends. For example, they can predict the impact of climate change on crop yields or assess the long-term sustainability of farming practices, thereby informing policy decisions and agricultural strategies. In summary, leveraging advanced AI techniques like large-scale foundation models can lead to significant improvements in the efficiency, productivity, and sustainability of agrifood systems, addressing the pressing challenges posed by a growing global population and environmental changes.

What are the potential ethical and societal implications of deploying AI-powered agrifood systems, and how can we ensure their responsible development and deployment?

The deployment of AI-powered agrifood systems carries several ethical and societal implications that must be carefully considered to ensure responsible development and deployment. Data Privacy and Security: The collection and analysis of vast amounts of data from various sources raise concerns about data privacy and security. Farmers and stakeholders may be apprehensive about how their data is used, shared, or stored. To address this, it is essential to implement robust data governance frameworks that prioritize transparency, consent, and data protection measures. Equity and Access: There is a risk that AI technologies may exacerbate existing inequalities in the agrifood sector. Smallholder farmers and marginalized communities may lack access to advanced technologies and the necessary resources to implement AI solutions. Ensuring equitable access to AI tools and training is crucial for fostering inclusivity and preventing a digital divide. Collaborative initiatives that provide support and resources to underserved communities can help bridge this gap. Job Displacement: The automation of agricultural processes through AI may lead to job displacement in rural areas, particularly for labor-intensive tasks. While AI can enhance productivity, it is vital to consider the social implications of workforce changes. Strategies such as reskilling and upskilling programs can help workers transition to new roles that require human oversight and expertise in AI technologies. Environmental Impact: The use of AI in agrifood systems can lead to more efficient resource use, but it may also result in unintended environmental consequences, such as increased chemical usage or monoculture practices. Ethical considerations should include the long-term sustainability of agricultural practices and the potential impact on biodiversity. Implementing AI solutions that promote sustainable practices, such as precision agriculture, can mitigate these risks. Accountability and Transparency: As AI systems make decisions that affect food production and safety, it is essential to establish accountability mechanisms. Stakeholders must understand how AI models arrive at their conclusions, particularly in critical areas such as pest management and crop disease detection. Developing explainable AI models and fostering stakeholder engagement in the decision-making process can enhance trust and accountability. In conclusion, addressing the ethical and societal implications of AI-powered agrifood systems requires a multi-faceted approach that prioritizes equity, transparency, and sustainability. By fostering collaboration among stakeholders, including policymakers, technologists, and farmers, we can ensure the responsible development and deployment of AI technologies in the agrifood sector.

Given the interdisciplinary nature of agrifood systems, how can AI researchers collaborate with domain experts in agriculture, animal husbandry, and fishery to drive meaningful advancements in this field?

Collaboration between AI researchers and domain experts in agriculture, animal husbandry, and fishery is essential for driving meaningful advancements in agrifood systems. Here are several strategies to facilitate this interdisciplinary collaboration: Cross-disciplinary Research Teams: Forming research teams that include AI experts, agronomists, veterinarians, and fisheries scientists can foster a holistic understanding of the challenges faced in agrifood systems. These teams can work together to identify specific problems that can be addressed through AI solutions, ensuring that the technology is relevant and applicable to real-world scenarios. Joint Workshops and Conferences: Organizing workshops and conferences that bring together AI researchers and domain experts can facilitate knowledge exchange and collaboration. These events can provide a platform for discussing the latest advancements in AI and their potential applications in agrifood systems, as well as for sharing best practices and lessons learned from field experiences. Collaborative Projects and Funding: Encouraging collaborative projects that involve both AI and agrifood experts can lead to innovative solutions. Funding agencies can promote interdisciplinary research by providing grants that require collaboration between AI researchers and domain experts, ensuring that projects are grounded in practical applications. Data Sharing and Open Access: Establishing data-sharing agreements between AI researchers and agrifood practitioners can enhance the quality and quantity of data available for training AI models. Open access to datasets related to crop yields, animal health, and fishery practices can enable AI researchers to develop more accurate and robust models that address specific challenges in the field. Training and Education Programs: Developing training programs that educate domain experts about AI technologies and vice versa can bridge the knowledge gap between disciplines. These programs can empower agrifood professionals to leverage AI tools effectively while enabling AI researchers to understand the complexities and nuances of agrifood systems. Feedback Loops: Creating feedback mechanisms where domain experts can provide insights and evaluations of AI models can enhance the relevance and effectiveness of AI applications. Continuous engagement with end-users ensures that AI solutions are user-friendly and meet the practical needs of farmers, livestock managers, and fishery operators. In summary, fostering collaboration between AI researchers and domain experts in agrifood systems is crucial for developing innovative solutions that address the unique challenges of the sector. By leveraging interdisciplinary expertise, we can drive advancements that enhance productivity, sustainability, and food security.
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