Development of an Intelligent Service Platform for a Poultry House Facility Environment Based on the Internet of Things
Abstract
:1. Introduction
2. Design of Platform System Structure
2.1. Data Acquisition Scheme
2.2. Data Flow and Storage Scheme
3. System Design and Implementation
3.1. Real-Time Data Collection and Display
3.2. Production Data Management
3.3. Data Analysis
3.4. Basic Information Management and System Management
3.5. System Implementation
4. Results and Discussions
4.1. Data Display Interface on Web Page
4.2. Comprehensive Analysis of Historical Data
fixed costs + variable costs,
4.3. Data Collection Volume and Validity
4.4. Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
Symbols and Expressions | |
CMR | cumulative mortality rate |
DAQ | data acquisition |
EPR | egg production rate |
IaaS | Infrastructure as a Service |
IoT | Internet of things |
IQR | interquartile range |
LabVIEW | Laboratory Virtual Instrument Engineering Workbench |
LAN | local area network |
LoRa | Long Range Radio |
MQTT | Message Queuing Telemetry Transport |
PaaS | Platform as a Service |
PPMU | portable particulate monitoring unit |
PLF | precision livestock farming |
P and L | profit and loss |
RFID | Radio Frequency Identification |
ResNet | residual network |
SaaS | Software as a Service |
Q1 | the lower quartile |
Q3 | the upper quartile |
WSNs | wireless sensor nodes |
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System Component | Technology Application | Functionality Description | References |
---|---|---|---|
Perception Layer | Sound sensors | Monitor chicken welfare level | [10] |
Digital image sensors | Observe bird conditions | [11] | |
Near-infrared sensors | Assist in observing birds | [12] | |
Acceleration sensors | Record intricate chicken movements | [13] | |
Network Layer | ZigBee wireless sensor network + embedded server | Collect environmental data | [15] |
LoRa and MQTT communication technology | Develop environmental data acquisition scheme | [16] | |
3G communication technology | Design real-time poultry monitoring platform | [17] | |
3G + VPN communication technology | Design real-time poultry monitoring platform with enhanced security | [18] | |
Application Layer | Fuzzy Logic Decision System | Establish decision-making system for livestock control | [19] |
Business Layer | Cloud computing platform | Form comprehensive digital intelligent monitoring system | [20,21] |
Remote server infrastructure | Enable seamless remote work | [23] |
Technology Application | Functionality Description | Pros | Cons | References |
---|---|---|---|---|
IoT-Based Weather Monitoring System | Monitoring and notifying deviations in greenhouse weather parameters | Offers ergonomic, power-efficient, and scalable solutions for greenhouse weather monitoring. | Scalability and accuracy improvement challenges | [8] |
Smart Poultry Management System | Using smart sensors, big data, and IoT tech for monitoring house environment monitor, bird welfare, precision feeding, and disease detection | Enhances production while minimizing costs and resource usage, offering real-time data collection. | Sensors and devices technical problems and data governance | [9] |
Camera-Based Real-Time Monitoring | Broiler flock welfare, assessing activity and occupation patterns | Correlates activity and occupation patterns with welfare assessments | Latent limitations during dark period | [11] |
Wireless Activity Sensor Network | Avian influenza monitoring, abnormal states detection | Early chicken abnormal state detection, earlier than body-temperature sensing | false positive detections may be due to bird physiology and movement patterns | [13] |
Smart Animal Monitoring System | Wireless sensor network and IoT platform for monitoring animal health, and environmental parameter monitoring | Provides continuous mobile surveillance of the entire dairy farm and saves on labor expenses. | Extension needed by adding body-area sensors for capturing animal health data and AI/ML algorithms | [14] |
IoT-Based Henhouse Monitoring System | Remote henhouse environment monitoring using IoT technology, collecting data through wireless sensors | Using wireless monitoring and environmental factors with high estimation accuracy. | Requires strategies for data loss recovery and missing data filling | [15] |
Aviary Remote Monitoring System | IoT-based environmental parameter monitoring for poultry farming | Cost-effective and provides real-time monitoring capabilities. | May have limitations in wireless signal range and reliability | [16] |
3G-Based Remote Monitoring System | 3G network-based poultry production management system | Reliable environmental parameter monitoring | Dependent on 3G network availability and quality | [17] |
3G + VPN Remote Monitoring System | Remote monitoring system based on 3G and VPN, sufficient video bandwidth and cheap wireless network access | Economical, feasible remote monitoring | Currently unable to run uninterrupted, requiring development of automatic reconnection for improved stability | [18] |
Smart Poultry Management System | precision livestock farming technologies, big data analytics, and IoT-based poultry farming system | Offers real-time monitoring, automated farm procedures, and data-driven decision-making | Requires manual sampling and operation for biosensor-based diagnostics | [20] |
Cloud-Based Poultry Farming Information Management System | Cloud-based poultry farming information management, including production management and office management modules | Flexibility and scalability data management, enabling data mining and traceability. | Relies on secure and reliable cloud services for data storage and management | [21] |
Sick Chicken Automatic Detection System | Improved residual network-based sick chicken detection | Improves identification speed and accuracy, saving manpower costs. | Needs extensive training data and computational resources | [25] |
IoT-Based Environmental Monitoring Instrument | Developed an IoT instrument for monitoring temperature, humidity, light intensity, and ammonia levels in poultry farms. | Low-cost alternative, efficient data recording, and quick data transmission. | IoT connectivity dependence and may need software improvements and additional sensors for air quality maintenance | [26] |
IoT-Based Intelligent Poultry Environment Control System | IoT-based system for intelligent control of poultry house environments, collecting and analyzing environmental data | Automates environmental data collection and analysis for optimal poultry house conditions. | Requires robust network infrastructure for seamless operation | [27] |
Deep Belief Network in IoT-Based Agri-System | Agricultural information system using deep belief network | Capable of handling complex data patterns in agricultural settings. | High computational cost and large dataset requirements | [28] |
Type | Range | Resolution | Accuracy | Model |
---|---|---|---|---|
Temperature/°C Relative humidity/% | −20~60 0~100% | 0.1 0.1 | ±0.3 °C ±1.5% | JWSH-5 |
CO2 concentration/ppm NH3 concentration/ppm | 0~5000 0~500 | 1 0.01 (0~100 ppm), 0.1 (100~500 ppm) | ±(40 ppm + 3%FS *) ±3% | JQAW-3AC JQB-G-NH3-1 |
Air velocity/m·s−1 | 0~5 | 0.01 | ±(0.2 + 3%FS *) | KL-15G |
Environmental Data | Raw Data Quantity | Processed Data Quantity | Estimated Data Quantity | Data Integrity * (%) | Data Validity ** (%) |
---|---|---|---|---|---|
Temperature | 1,633,590 | 1,628,491 | 1,684,800 | 96.96 | 99.69 |
Humidity | 1,632,949 | 1,632,022 | 1,684,800 | 96.92 | 99.94 |
Wind speed | 1,643,868 | 1,553,535 | 1,684,800 | 97.57 | 94.50 |
Carbon dioxide concentration | 1,466,454 | 1,459,908 | 1,684,800 | 87.04 | 99.55 |
Ammonia concentration | 796,320 | 770,576 | 842,400 | 94.53 | 96.77 |
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Share and Cite
Liu, M.; Chen, H.; Zhou, Z.; Du, X.; Zhao, Y.; Ji, H.; Teng, G. Development of an Intelligent Service Platform for a Poultry House Facility Environment Based on the Internet of Things. Agriculture 2024, 14, 1277. https://doi.org/10.3390/agriculture14081277
Liu M, Chen H, Zhou Z, Du X, Zhao Y, Ji H, Teng G. Development of an Intelligent Service Platform for a Poultry House Facility Environment Based on the Internet of Things. Agriculture. 2024; 14(8):1277. https://doi.org/10.3390/agriculture14081277
Chicago/Turabian StyleLiu, Mulin, Hongxi Chen, Zhenyu Zhou, Xiaodong Du, Yuxiao Zhao, Hengyi Ji, and Guanghui Teng. 2024. "Development of an Intelligent Service Platform for a Poultry House Facility Environment Based on the Internet of Things" Agriculture 14, no. 8: 1277. https://doi.org/10.3390/agriculture14081277
APA StyleLiu, M., Chen, H., Zhou, Z., Du, X., Zhao, Y., Ji, H., & Teng, G. (2024). Development of an Intelligent Service Platform for a Poultry House Facility Environment Based on the Internet of Things. Agriculture, 14(8), 1277. https://doi.org/10.3390/agriculture14081277