Method Article

Cross-Layer Reliability Analysis and Edge-Adaptive Multi-Objective Optimization Strategies for Network-Physical Modeling in Intelligent Agriculture CPS Management

DOI:

10.3791/69826

January 20th, 2026

In This Article

Summary

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This protocol presents a cross-layer cyber-physical modeling and optimization strategy for intelligent greenhouse management, enabling reproducible assessment of reliability and ecological performance.

Abstract

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Growing food demand and climate stresses drive smart agriculture implementation, but existing Cyber-Physical Systems (CPS) lack dependable cross-layer integration and real-time flexibility, limiting performance in dynamic environments. This protocol aims to provide a cross-layer cyber-physical modeling and optimization strategy for intelligent greenhouse agriculture. It demonstrates potential applicability for enhancing the reliability and adaptability of agricultural Cyber-Physical Systems. The approach integrates a physical layer with the Soil-Plant-Atmosphere Continuum model and Ensemble Kalman Filter (EnKF) calibration for accurate soil moisture prediction. It includes a network layer employing multi-protocol fusion with Stochastic Petri Net modeling to evaluate communication reliability. A control layer builds on a stochastic hybrid system to coordinate joint decision-making. Reliability is further assessed through a functional-temporal-ecological indicator framework, while optimization combines multi-objective reinforcement learning with safety constraints and Bayesian meta-learning to enable rapid adaptation during crop switching. An edge-intelligent deployment ensures robust control during communication interruptions. Results from greenhouse tomato cultivation in Shouguang, China, show reproducible and stable performance in yield prediction, water use efficiency, and control latency under challenging conditions. This methodology provides a practical and replicable workflow for implementing adaptive and reliable agricultural Cyber-Physical Systems.

Introduction

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The world population is growing rapidly, and resource availability is declining, which is transforming the way agriculture is developed. The conventional models of agriculture, where labor and material input are high, and the reliance on the natural circumstances is strong, cannot offer efficiency and sustainability. Smart agriculture has, in this case, become the transformative approach. It allows achieving a complete field perception, making accurate decisions, and controlling the field intelligently through the combination of the Internet of Things, big data analytics, artificial intelligence, and spatial information systems, which enhances the efficiency of the us....

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Protocol

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It is noted that no experiments on human beings or vertebrate animals are involved in this protocol. In case of any future studies that will involve human involvement or biological samples, this has to be approved by the concerned institutional review board, and the approval number must be recorded prior to implementation.

1. Site and hardware preparation

NOTE: This step builds a standardized sensor network, which gives precise and synchronized information about the environment to be used in subsequent physical modeling and control.

  1. Establish the location of the greenhouse by inputtin....

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Results

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Soil moisture and SNR have the greatest positive SHapley Additive exPlanations (SHAP) influence on irrigation decisions, according to the SHAP summary plot (Figure 3). High latency drives the policy toward conservative fallback options, demonstrating conformity with the reliability-aware control architecture. Table 4 depicts operational instructions and configuration details for computational modules

Experimental setup

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Discussion

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The experimental evidence shows that the proposed CPS framework and optimization strategies excel across the three dimensions of reliability, safety, and computational efficiency. Cross-layer coupling modeling successfully overcomes the historical separation between physical and network representations. By embedding SPAC and SPN within a unified SHS framework, the system reduced yield prediction error by 32.7% and shortened delays by 45% under extreme high temperatures. Safety constraints ensured that ecological performa.......

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Disclosures

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The authors have nothing to disclose.

Acknowledgements

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This work was supported by the Project of Huzhou College Scientific Research (Grant No. 2024HXKM15) and the Talent Research Startup Project of Huzhou College (Grant No. RK65010). The authors thank Shouguang National Modern Agricultural Industrial Park for providing experimental facilities and technical support. We also extend our gratitude to colleagues from Huzhou College and Zhejiang Agriculture & Forestry University for their valuable insights.

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Materials

List of materials used in this article
NameCompanyCatalog NumberComments
Multispectral CameraMicaSenseRedEdge-MXCaptures canopy reflectance for LAI estimation
NVIDIA Jetson NanoNVIDIA945-13450-0000-100Edge device for local AI inference
Soil Moisture SensorDecagon DevicesEC-5Measures volumetric water content in soil
Weather StationCampbell ScientificCR300Records temperature, humidity, and rainfall

References

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  1. A novel framework for smart agriculture using internet of things and enabling technologies. Haq, Z. A., Jaffery, Z. A., Mehfuz, S. 2022 Int Conf Advancement Tech (ICONAT), , 1-6 (2022).
  2. Quy, V. K., et al. Iot-enabled smart agriculture: Architecture, applications, and challenges. Appl Sci. 12 (7), 3396(2022).
  3. Oecd-fao agricultural outlook 2024-2033. , FAO.

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Tags

Cyber Physical SystemsIntelligent AgricultureCross Layer ModelingMulti Objective OptimizationSoil Moisture PredictionEnsemble Kalman FilterStochastic Petri NetReinforcement LearningEdge Intelligent ControlGreenhouse Management

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