Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems

Anas Abouaomar; Mohammed El Hanjri; Abdellatif Kobbane; Anis Laouiti; Khalid Nafil

doi:10.1109/WINCOM65874.2025.11313439

Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems

Anas Abouaomar
, Mohammed El Hanjri
, Abdellatif Kobbane
, Anis Laouiti
, Khalid Nafil

Université Mohammed V-Souissi

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

In this paper, we presents a novel hierarchical federated learning architecture specifically designed for smart agricultural production systems and crop yield prediction. Our approach introduces a seasonal subscription mechanism where farms join crop-specific clusters at the beginning of each agricultural season. The proposed three-layer architecture consists of individual smart farms at the client level, crop-specific aggregators at the middle layer, and a global model aggregator at the top level. Within each crop cluster, clients collaboratively train specialized models tailored to specific crop types, which are then aggregated to produce a higher-level global model that integrates knowledge across multiple crops. This hierarchical design enables both local specialization for individual crop types and global generalization across diverse agricultural contexts while preserving data privacy and reducing communication overhead. Experiments demonstrate the effectiveness of the proposed system, showing that local and crop-layer models closely follow actual yield patterns with consistent alignment, significantly outperforming standard machine learning models. The results validate the advantages of hierarchical federated learning in the agricultural context, particularly for scenarios involving heterogeneous farming environments and privacy-sensitive agricultural data.

Original language	English
Title of host publication	Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025
Editors	Bandar Alrami, Khaled Suwais, Ahmed Drissi El Maliani, Mohamed El Kamili, Khalil Ibrahimi, Abdellatif Kobbane
Publisher	Institute of Electrical and Electronics Engineers Inc.
Edition	2025
ISBN (Electronic)	9798331598785
DOIs	https://doi.org/10.1109/WINCOM65874.2025.11313439
Publication status	Published - 1 Jan 2025
Event	12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025 - Riyadh, Saudi Arabia Duration: 25 Nov 2025 → 27 Nov 2025

Conference

Conference	12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025
Country/Territory	Saudi Arabia
City	Riyadh
Period	25/11/25 → 27/11/25

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 2 Zero Hunger

Keywords

Agricultural Production Management
Crop Yield Prediction
Crop-Type Clustering
Hierarchical Federated Learning
Smart Agriculture

Access to Document

10.1109/WINCOM65874.2025.11313439

Cite this

Abouaomar, A., El Hanjri, M., Kobbane, A., Laouiti, A., & Nafil, K. (2025). Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems. In B. Alrami, K. Suwais, A. D. El Maliani, M. El Kamili, K. Ibrahimi, & A. Kobbane (Eds.), Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025 (2025 ed.). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/WINCOM65874.2025.11313439

Abouaomar, Anas ; El Hanjri, Mohammed ; Kobbane, Abdellatif et al. / Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems. Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025. editor / Bandar Alrami ; Khaled Suwais ; Ahmed Drissi El Maliani ; Mohamed El Kamili ; Khalil Ibrahimi ; Abdellatif Kobbane. 2025. ed. Institute of Electrical and Electronics Engineers Inc., 2025.

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title = "Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems",

abstract = "In this paper, we presents a novel hierarchical federated learning architecture specifically designed for smart agricultural production systems and crop yield prediction. Our approach introduces a seasonal subscription mechanism where farms join crop-specific clusters at the beginning of each agricultural season. The proposed three-layer architecture consists of individual smart farms at the client level, crop-specific aggregators at the middle layer, and a global model aggregator at the top level. Within each crop cluster, clients collaboratively train specialized models tailored to specific crop types, which are then aggregated to produce a higher-level global model that integrates knowledge across multiple crops. This hierarchical design enables both local specialization for individual crop types and global generalization across diverse agricultural contexts while preserving data privacy and reducing communication overhead. Experiments demonstrate the effectiveness of the proposed system, showing that local and crop-layer models closely follow actual yield patterns with consistent alignment, significantly outperforming standard machine learning models. The results validate the advantages of hierarchical federated learning in the agricultural context, particularly for scenarios involving heterogeneous farming environments and privacy-sensitive agricultural data.",

keywords = "Agricultural Production Management, Crop Yield Prediction, Crop-Type Clustering, Hierarchical Federated Learning, Smart Agriculture",

author = "Anas Abouaomar and \{El Hanjri\}, Mohammed and Abdellatif Kobbane and Anis Laouiti and Khalid Nafil",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025 ; Conference date: 25-11-2025 Through 27-11-2025",

year = "2025",

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publisher = "Institute of Electrical and Electronics Engineers Inc.",

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Abouaomar, A, El Hanjri, M, Kobbane, A, Laouiti, A & Nafil, K 2025, Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems. in B Alrami, K Suwais, AD El Maliani, M El Kamili, K Ibrahimi & A Kobbane (eds), Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025. 2025 edn, Institute of Electrical and Electronics Engineers Inc., 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025, Riyadh, Saudi Arabia, 25/11/25. https://doi.org/10.1109/WINCOM65874.2025.11313439

Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems. / Abouaomar, Anas; El Hanjri, Mohammed; Kobbane, Abdellatif et al.
Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025. ed. / Bandar Alrami; Khaled Suwais; Ahmed Drissi El Maliani; Mohamed El Kamili; Khalil Ibrahimi; Abdellatif Kobbane. 2025. ed. Institute of Electrical and Electronics Engineers Inc., 2025.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems

AU - Abouaomar, Anas

AU - El Hanjri, Mohammed

AU - Kobbane, Abdellatif

AU - Laouiti, Anis

AU - Nafil, Khalid

PY - 2025/1/1

Y1 - 2025/1/1

N2 - In this paper, we presents a novel hierarchical federated learning architecture specifically designed for smart agricultural production systems and crop yield prediction. Our approach introduces a seasonal subscription mechanism where farms join crop-specific clusters at the beginning of each agricultural season. The proposed three-layer architecture consists of individual smart farms at the client level, crop-specific aggregators at the middle layer, and a global model aggregator at the top level. Within each crop cluster, clients collaboratively train specialized models tailored to specific crop types, which are then aggregated to produce a higher-level global model that integrates knowledge across multiple crops. This hierarchical design enables both local specialization for individual crop types and global generalization across diverse agricultural contexts while preserving data privacy and reducing communication overhead. Experiments demonstrate the effectiveness of the proposed system, showing that local and crop-layer models closely follow actual yield patterns with consistent alignment, significantly outperforming standard machine learning models. The results validate the advantages of hierarchical federated learning in the agricultural context, particularly for scenarios involving heterogeneous farming environments and privacy-sensitive agricultural data.

AB - In this paper, we presents a novel hierarchical federated learning architecture specifically designed for smart agricultural production systems and crop yield prediction. Our approach introduces a seasonal subscription mechanism where farms join crop-specific clusters at the beginning of each agricultural season. The proposed three-layer architecture consists of individual smart farms at the client level, crop-specific aggregators at the middle layer, and a global model aggregator at the top level. Within each crop cluster, clients collaboratively train specialized models tailored to specific crop types, which are then aggregated to produce a higher-level global model that integrates knowledge across multiple crops. This hierarchical design enables both local specialization for individual crop types and global generalization across diverse agricultural contexts while preserving data privacy and reducing communication overhead. Experiments demonstrate the effectiveness of the proposed system, showing that local and crop-layer models closely follow actual yield patterns with consistent alignment, significantly outperforming standard machine learning models. The results validate the advantages of hierarchical federated learning in the agricultural context, particularly for scenarios involving heterogeneous farming environments and privacy-sensitive agricultural data.

KW - Agricultural Production Management

KW - Crop Yield Prediction

KW - Crop-Type Clustering

KW - Hierarchical Federated Learning

KW - Smart Agriculture

UR - https://www.scopus.com/pages/publications/105034094379

U2 - 10.1109/WINCOM65874.2025.11313439

DO - 10.1109/WINCOM65874.2025.11313439

M3 - Conference contribution

AN - SCOPUS:105034094379

BT - Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025

A2 - Alrami, Bandar

A2 - Suwais, Khaled

A2 - El Maliani, Ahmed Drissi

A2 - El Kamili, Mohamed

A2 - Ibrahimi, Khalil

A2 - Kobbane, Abdellatif

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025

Y2 - 25 November 2025 through 27 November 2025

ER -

Abouaomar A, El Hanjri M, Kobbane A, Laouiti A, Nafil K. Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems. In Alrami B, Suwais K, El Maliani AD, El Kamili M, Ibrahimi K, Kobbane A, editors, Proceedings - 12th International Conference on Wireless Networks and Mobile Communications, WINCOM 2025. 2025 ed. Institute of Electrical and Electronics Engineers Inc. 2025 doi: 10.1109/WINCOM65874.2025.11313439

Hierarchical Federated Learning for Crop Yield Prediction in Smart Agricultural Production Systems

Abstract

Conference

UN SDGs

Keywords

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