Types of Linux Zigbee Gateways
A Linux Zigbee gateway serves as a critical bridge between Zigbee-based IoT devices and broader network ecosystems. Running on the robust and customizable Linux operating system, these gateways enable secure, scalable, and reliable communication in smart homes, industrial automation, and large-scale IoT deployments. This guide explores the primary types of Linux-based Zigbee gateways, their functionalities, advantages, and ideal use cases.
Embedded Zigbee Gateway
Compact, purpose-built devices designed for dedicated IoT tasks such as sensor monitoring, machine control, or environmental data collection. These gateways run lightweight Linux distributions optimized for real-time performance and low power consumption.
Advantages
- High reliability with 24/7 operation capability
- Efficient resource utilization
- Supports multiple concurrent Zigbee connections
- Customizable firmware for specific applications
Limitations
- Limited processing power for complex analytics
- Smaller memory footprint restricts feature expansion
- May require technical expertise for configuration
Best for: Industrial monitoring, factory automation, edge computing nodes, and remote sensing applications
Bridge Gateway
Facilitates seamless communication between Zigbee networks and other protocols such as Wi-Fi, Ethernet, or cellular networks. These gateways translate data formats and ensure interoperability across heterogeneous systems.
Advantages
- Enables integration with existing home or enterprise networks
- Supports remote access via web interfaces or mobile apps
- Plug-and-play compatibility with popular IoT platforms
- Enhances device accessibility and control flexibility
Limitations
- Network latency may affect real-time responsiveness
- Security configuration is critical to prevent breaches
- Dependent on stable external network connectivity
Best for: Smart homes, office buildings, and multi-protocol IoT environments requiring cross-network communication
Pro Hub (Professional Hub)
The central command unit for large-scale or mission-critical IoT installations. Pro hubs are built on powerful Linux platforms capable of managing thousands of connected Zigbee devices with high throughput and advanced data handling.
Advantages
- High scalability for enterprise-level deployments
- Advanced processing for real-time analytics and automation
- Robust security features including encryption and access control
- Support for redundant systems and failover mechanisms
Limitations
- Higher cost compared to consumer-grade gateways
- Requires professional setup and maintenance
- Larger physical footprint and power requirements
Best for: Smart cities, industrial automation, precision agriculture, and large commercial facilities
Cloud Gateway
Connects Zigbee devices directly to cloud platforms such as AWS IoT, Google Cloud IoT, or Microsoft Azure. These gateways offload data processing, storage, and analytics to remote servers, enabling advanced capabilities like AI-driven insights and centralized management.
Advantages
- Enables remote monitoring and control from anywhere
- Leverages cloud computing for big data analytics and machine learning
- Facilitates integration with third-party services and APIs
- Automatic software updates and scalability via cloud infrastructure
Limitations
- Dependent on consistent internet connectivity
- Potential latency in time-sensitive applications
- Ongoing cloud service costs may apply
Best for: Enterprise IoT, predictive maintenance systems, data-intensive applications, and distributed sensor networks
| Gateway Type | Scalability | Use Case Focus | Processing Power | Ideal Environment |
|---|---|---|---|---|
| Embedded | Medium | Task-specific automation | Low to Medium | Industrial sensors, edge devices |
| Bridge | Medium | Interoperability | Medium | Smart homes, small offices |
| Pro Hub | Very High | Centralized control | High | Smart cities, factories, farms |
| Cloud Gateway | Extremely High | Data integration & analytics | Medium (cloud-dependent) | Distributed systems, enterprise IoT |
Expert Tip: When selecting a Linux Zigbee gateway, consider the long-term scalability and security features. Open-source Linux gateways often allow customization and regular security patches, making them ideal for future-proof IoT deployments.
Industrial Applications of Linux Zigbee Gateway
The Linux Zigbee gateway has emerged as a pivotal component in modern industrial IoT (Internet of Things) ecosystems. Leveraging the open-source flexibility of Linux and the low-power, mesh-networking capabilities of Zigbee, this gateway enables seamless communication between sensors, controllers, and cloud platforms. Its robust architecture supports secure, real-time data aggregation and remote management across diverse industrial environments.
Designed for scalability and reliability, the Linux Zigbee gateway integrates effortlessly with wireless sensor networks to deliver actionable insights, enhance automation, and reduce operational costs. Below are key industrial applications where this technology delivers transformative impact.
Smart Agriculture
Environmental Monitoring
Linux Zigbee gateways collect real-time data from wireless sensors deployed across farmland to monitor critical environmental parameters such as soil moisture, ambient temperature, humidity, and light intensity. This data enables precision farming practices—such as automated irrigation scheduling and climate-controlled greenhouse management—leading to optimized crop yields and reduced resource waste.
By analyzing trends over time, farmers can make data-driven decisions that improve planting cycles, pest control, and harvest timing, ultimately increasing profitability and sustainability.
Livestock Management
In animal husbandry, wearable Zigbee-enabled sensors track vital signs (e.g., body temperature, heart rate) and movement patterns of livestock. The Linux gateway aggregates this information, alerting farmers to potential health issues like illness or estrus cycles before they escalate.
GPS-based location tracking helps prevent theft and loss, while automated feeding and health monitoring systems reduce labor costs and improve animal welfare. This level of oversight enhances productivity and minimizes human error in large-scale operations.
Smart Cities
Traffic and Air Quality Monitoring
Integrated into urban infrastructure, Linux Zigbee gateways support intelligent traffic management by collecting data from road sensors to analyze vehicle flow and detect congestion hotspots. This enables dynamic traffic signal control and real-time rerouting suggestions via digital signage or mobile apps.
Simultaneously, air quality sensors connected through the gateway measure pollutants like CO₂, NOₓ, and PM2.5 levels. Municipal authorities use this data to issue public health advisories, plan green zones, and enforce emission regulations—contributing to cleaner, safer cities.
Intelligent Street Lighting & Public Safety
By interfacing with light sensors and pedestrian detection systems, the gateway enables adaptive street lighting that dims or brightens based on ambient conditions and foot traffic. This reduces energy consumption by up to 60% compared to traditional systems.
Integration with surveillance cameras and emergency call boxes enhances public safety. In case of incidents, the system can trigger alerts, activate nearby lights, and notify law enforcement—making urban spaces more secure and responsive.
Remote Monitoring and Control
Oil and Gas Industry
In remote or hazardous environments such as offshore rigs and pipelines, Linux Zigbee gateways enable continuous monitoring of pressure, temperature, flow rates, and valve statuses. Data is transmitted securely to central control rooms, allowing operators to detect leaks, prevent equipment failure, and ensure regulatory compliance without requiring on-site personnel.
This capability significantly improves worker safety, reduces downtime, and lowers maintenance costs through predictive analytics and early warning systems.
Mining Operations
Underground and surface mining sites utilize Zigbee sensor networks to monitor equipment health, gas concentrations (e.g., methane), and structural integrity. The Linux gateway acts as a resilient data hub, even in challenging RF environments, ensuring uninterrupted communication between sensors and command centers.
Real-time alerts help prevent catastrophic events such as explosions or collapses, while asset tracking optimizes logistics and maintenance schedules—boosting both safety and productivity.
Industrial Automation
Factory Floor Integration
Within manufacturing facilities, the Linux Zigbee gateway connects a wide array of devices—including temperature sensors, vibration monitors, robotic arms, and conveyor systems—into a unified IIoT (Industrial Internet of Things) network. This integration allows for centralized monitoring and control of production processes.
Data collected from machines is used to identify bottlenecks, optimize workflows, and implement predictive maintenance strategies, minimizing unplanned downtime and extending equipment lifespan.
Inventory and Process Management
The gateway supports RFID and weight sensors to automate inventory tracking across warehouses and assembly lines. Managers gain real-time visibility into raw material availability, work-in-progress status, and finished goods, enabling just-in-time production and reducing overstocking.
Automated reporting and dashboards streamline compliance and auditing, while machine learning-ready data sets pave the way for AI-driven process optimization and quality assurance.
| Industry | Key Use Cases | Benefits |
|---|---|---|
| Smart Agriculture | Soil monitoring, livestock tracking, automated irrigation | Increased yield, reduced labor, improved sustainability |
| Smart City | Traffic optimization, air quality monitoring, smart lighting | Energy savings, enhanced safety, better urban planning |
| Oil & Gas / Mining | Pipeline monitoring, gas detection, equipment health | Improved safety, reduced downtime, lower operational costs |
| Manufacturing | Production line monitoring, robotic control, inventory tracking | Higher efficiency, predictive maintenance, cost reduction |
Important: To maximize the performance and security of a Linux Zigbee gateway in industrial settings, ensure regular firmware updates, strong network encryption (e.g., AES-128), and proper physical placement to avoid signal interference. Always follow best practices for IoT device management and network segmentation to protect against cyber threats.
Product Characteristics of Linux Zigbee Gateway
The Linux Zigbee Gateway is a powerful and versatile hub designed for modern smart environments, combining the reliability of open-source technology with advanced wireless communication capabilities. This comprehensive overview highlights the key features that make this gateway an ideal choice for both home automation and industrial IoT applications.
Open-Source Linux Platform
At its core, the gateway runs on a fully open-source Linux operating system, providing unparalleled flexibility and transparency. This foundation empowers developers, system integrators, and tech-savvy users to access, inspect, and modify the source code according to their specific requirements.
- Full root access enables deep customization of system behavior and performance tuning
- Supports integration of proprietary protocols, custom automation scripts, and third-party services
- Community-driven development ensures continuous improvements, security patches, and feature enhancements
- Ideal for businesses requiring tailored solutions for unique operational workflows or compliance standards
Key advantage: Future-proofs your smart ecosystem by avoiding vendor lock-in and enabling long-term adaptability.
Zigbee Protocol Support (Zigbee 3.0)
The gateway is engineered to support Zigbee 3.0—the unified global standard that ensures interoperability across all Zigbee-certified devices. This eliminates fragmentation seen in earlier versions and allows seamless communication between products from different manufacturers.
- Enables reliable, low-power wireless connectivity with a wide range of smart devices including sensors, lights, locks, and thermostats
- Supports mesh networking, where each device acts as a signal repeater to extend coverage and improve network stability
- Acts as a central bridge between Zigbee devices and other networks such as Wi-Fi, Ethernet, or cloud platforms (e.g., AWS, Google Cloud, Azure)
- Delivers low-latency communication for real-time control and responsive automation
Practical benefit: Simplifies smart home or industrial setup by unifying diverse devices under one cohesive, scalable network.
Robust Security Features
With the growing number of connected devices, cybersecurity has become a top priority. The Linux Zigbee Gateway incorporates multiple layers of protection to safeguard data integrity and prevent unauthorized access.
- End-to-end encryption: All data transmissions are encrypted using AES-128 or higher standards to protect against eavesdropping and tampering
- Secure boot process: Ensures only authenticated firmware is loaded during startup, preventing malicious code injection
- User authentication: Role-based access control (RBAC) and multi-factor authentication options enhance user-level security
- Regular security updates: Open-source nature allows rapid patching of vulnerabilities and ongoing community scrutiny
Critical insight: These measures are essential for protecting sensitive personal data, maintaining privacy, and ensuring compliance with regulations like GDPR or HIPAA in professional environments.
Cross-Platform Compatibility
Designed for universal accessibility, the gateway offers seamless integration across various platforms and devices, making it highly adaptable to different user preferences and technical ecosystems.
- Accessible via web-based dashboards compatible with Windows, macOS, Linux, and Chrome OS
- Mobile apps available for iOS and Android devices allow remote monitoring and control from anywhere
- API support enables integration with popular home automation platforms like Home Assistant, OpenHAB, and Node-RED
- Hardware agnostic—runs efficiently on various ARM/x86 architectures, making it suitable for embedded systems, servers, or edge computing devices
User advantage: Whether used in a residential smart home or an enterprise IoT deployment, the gateway provides consistent performance and management across diverse environments.
Expert Recommendation: For optimal performance and security, pair the Linux Zigbee Gateway with regularly updated firmware and use strong network segmentation practices. Consider deploying it within a VLAN for IoT devices to isolate traffic and reduce potential attack surfaces. Developers should leverage the open-source SDKs and documentation to build custom integrations that maximize return on investment.
| Feature | Description | Benefit | Use Case |
|---|---|---|---|
| Open-Source OS | Based on Linux kernel with full source code access | Customization, transparency, no vendor lock-in | Developers, DIY enthusiasts, enterprise integrators |
| Zigbee 3.0 Support | Unified protocol for all Zigbee device types | Interoperability, mesh networking, energy efficiency | Smart homes, commercial buildings, sensor networks |
| Advanced Security | Encryption, secure boot, authentication mechanisms | Data protection, compliance readiness, trust | Healthcare, finance, privacy-sensitive applications |
| Cross-Platform Access | Web, mobile, API, and cloud compatibility | Remote management, ecosystem integration, flexibility | Home automation, industrial IoT, remote monitoring |
Additional Advantages
- Scalability: Supports hundreds of connected devices, making it suitable for large-scale deployments
- Energy Efficiency: Optimized for low power consumption, ideal for always-on operation
- Community & Support: Backed by active developer communities and extensive documentation
- Extensibility: Can be enhanced with add-ons like Z-Wave, Bluetooth, or LoRa through expansion modules
- Cost-Effective: Reduces long-term costs through open-source software and reduced dependency on proprietary ecosystems
Factors To Consider When Selecting a Linux Zigbee Gateway
Selecting the right Linux-based Zigbee gateway is crucial for building a reliable, scalable, and secure smart home or industrial automation system. Unlike proprietary hubs, Linux Zigbee gateways offer greater flexibility, customization, and long-term control. This guide outlines the key factors to evaluate when choosing a gateway that aligns with your technical requirements, use case, and future expansion plans.
Important Note: The performance and reliability of your Zigbee network depend heavily on the quality and capabilities of the gateway. Investing time in selecting the right model can prevent connectivity issues, security vulnerabilities, and integration challenges down the line.
1. Number of Connected Devices and Network Scalability
The scale of your intended Zigbee network is one of the most critical factors in gateway selection. Zigbee networks operate on a mesh topology, where each device can relay signals, but the gateway acts as the central coordinator and communication bridge to your local network or cloud services.
- Home Users: For typical smart homes with 10–30 devices (lights, sensors, switches), most modern Linux Zigbee gateways can handle the load efficiently. Look for gateways supporting at least 50+ device connections to allow room for future expansion.
- Business/Enterprise Users: Large-scale deployments in commercial buildings, factories, or campuses may involve hundreds of devices. In such cases, choose a gateway with proven scalability, robust processing power (e.g., multi-core CPU), and sufficient RAM to manage routing tables and real-time data without latency.
- Mesh Network Stability: Ensure the gateway firmware supports dynamic mesh optimization and efficient routing algorithms (like AODV) to maintain stable communication across large networks.
Expert Tip: Consider gateways that support Zigbee 3.0 or later, as they offer improved interoperability and better handling of large device counts compared to older Zigbee HA or SE profiles.
2. Data Security and Privacy Requirements
Security is paramount, especially when dealing with sensitive environments such as healthcare facilities, offices, or homes with surveillance systems. Linux-based gateways provide greater transparency and control over security configurations compared to closed-source alternatives.
- End-to-End Encryption: Ensure the gateway supports AES-128 encryption for Zigbee communications and TLS/SSL for network transmission between the gateway and other services.
- Local Processing: Opt for gateways that allow data to be processed locally (on-premise) rather than being sent to the cloud, minimizing exposure to external threats.
- VPN and Firewall Support: Enterprise-grade gateways should support OpenVPN, WireGuard, or IPsec for secure remote access and network segmentation.
- Regular Security Updates: Choose a gateway from a vendor or open-source project with a consistent track record of timely firmware and OS updates to patch vulnerabilities.
- Access Control: Look for role-based access control (RBAC), user authentication, and audit logging features for enterprise deployments.
While individual users may prioritize convenience, businesses must treat the gateway as a critical security node in their IoT infrastructure.
3. Community Support and Open-Source Ecosystem
One of the primary advantages of Linux-based Zigbee gateways is access to vibrant open-source communities. These communities provide invaluable resources including troubleshooting guides, custom firmware, integration plugins, and development tools.
- Active Development: Gateways backed by active GitHub repositories, forums (like Home Assistant, Zigbee2MQTT, or Z2M), and regular contributor activity are more likely to remain compatible with new devices and protocols.
- Documentation Quality: Comprehensive documentation—installation guides, API references, and configuration examples—can significantly reduce setup time and complexity.
- Troubleshooting Assistance: Active community forums allow users to quickly resolve issues, share configurations, and contribute improvements.
- Long-Term Viability: A strong community ensures the gateway won’t become obsolete if the original manufacturer discontinues support.
For enterprises, community-driven development also means greater transparency and the ability to audit or modify the source code for compliance purposes.
4. Ease of Integration with Third-Party Systems
The true value of a Zigbee gateway lies in its ability to integrate seamlessly with other platforms and services. Linux gateways excel in this area due to their support for open standards and APIs.
- Smart Home Ecosystems: Ensure compatibility with popular platforms such as Home Assistant, OpenHAB, Google Home, Amazon Alexa, Apple HomeKit (via bridges), and IFTTT for voice control and automation.
- MQTT and REST APIs: Gateways that expose device data via MQTT brokers or RESTful APIs enable deep integration with custom dashboards, monitoring tools, and enterprise applications.
- Cloud and Local Services: Some gateways support both cloud-based management (e.g., for remote access) and local operation (for privacy and reliability). Choose based on your preference for control vs. convenience.
- Automation and Scripting: Linux gateways allow advanced users to write custom scripts (Bash, Python) to automate tasks, process sensor data, or trigger actions based on events.
Poor integration can lead to fragmented systems, increased maintenance overhead, and higher costs due to the need for additional middleware or bridging devices.
| Evaluation Factor | Home User Priority | Business/Enterprise Priority | Recommended Gateway Features |
|---|---|---|---|
| Device Capacity | Medium (10–50 devices) | High (50–200+ devices) | Zigbee 3.0, Multi-threaded OS, ≥1GB RAM |
| Security | Basic encryption, Firmware updates | End-to-end encryption, VPN, RBAC, Audit logs | TLS, OpenVPN, Secure boot, Regular patches |
| Community & Support | Helpful forums, Basic documentation | Active development, Enterprise support options | GitHub presence, Commercial support available |
| Integration | Google/Alexa, Home Assistant | MQTT, REST API, Custom scripting | OpenHAB, Node-RED, Docker support |
| Deployment Model | Local or hybrid | Fully local or secure cloud | On-premise operation, Zero cloud dependency option |
Pro Tip: Before purchasing, check if the gateway is supported by popular open-source projects like Zigbee2MQTT or ZHA (Zigbee Home Automation). This often indicates strong community backing and long-term compatibility.
Final Recommendations
- For Home Users: Prioritize ease of setup, compatibility with voice assistants, and solid community support. Models like Raspberry Pi with a Zigbee USB adapter running Zigbee2MQTT are cost-effective and highly customizable.
- For Businesses: Focus on security, scalability, and integration capabilities. Consider industrial-grade gateways with redundant power, Ethernet connectivity, and commercial support options.
- Future-Proofing: Choose a gateway with expandable storage, USB ports, and support for containerized applications (e.g., Docker) to accommodate future upgrades.
- Testing: Whenever possible, test the gateway in your environment before full deployment to evaluate performance, stability, and integration ease.
By carefully evaluating these factors, you can select a Linux Zigbee gateway that not only meets your current needs but also supports future growth and evolving technological demands. Remember, the gateway is the foundation of your Zigbee network—choosing wisely ensures reliability, security, and long-term satisfaction.
Frequently Asked Questions About Linux Zigbee Gateways
For reliable performance in professional settings, a Linux-based Zigbee gateway should be equipped with a robust set of hardware and software capabilities. These include:
- High Processing Power: A multi-core processor and sufficient RAM (e.g., 1GB or more) ensure smooth handling of concurrent device communications, real-time data processing, and automation logic.
- Scalable Device Support: The gateway should support hundreds of Zigbee nodes without latency or packet loss, making it suitable for large-scale deployments in offices, factories, or smart buildings.
- Advanced Security: Features such as end-to-end encryption, secure boot, firewall integration, and regular OS updates are essential to protect sensitive data and prevent unauthorized access.
- Cloud Integration: Professional gateways often include APIs and protocols (like MQTT, REST, or CoAP) to connect with cloud platforms for remote monitoring, data analytics, and centralized control.
- Redundancy & Reliability: Support for failover mechanisms, backup configurations, and uptime monitoring ensures continuous operation critical for industrial or enterprise use.
Together, these features ensure that the gateway can handle complex workflows, maintain stability under heavy loads, and comply with enterprise IT standards.
A cloud-connected Linux Zigbee gateway is best suited for managing large-scale IoT networks. This type of gateway excels in:
- Scalability: It can dynamically accommodate hundreds or even thousands of connected devices by offloading processing and storage to cloud infrastructure.
- Data Aggregation and Analysis: The gateway collects sensor data from multiple sources and forwards it to cloud platforms where advanced analytics, machine learning, and visualization tools can extract meaningful insights.
- Remote Management: Administrators can monitor device status, push firmware updates, and configure automation rules from anywhere via web or mobile dashboards.
- Interoperability: Cloud gateways often support multiple communication protocols (e.g., Zigbee, Z-Wave, BLE, Wi-Fi), enabling integration across diverse IoT ecosystems.
- High Availability: With cloud-based redundancy and load balancing, downtime is minimized, ensuring consistent performance across geographically distributed deployments.
This makes cloud gateways ideal for smart cities, industrial automation, agriculture monitoring, and large commercial buildings where real-time data and centralized control are paramount.
Yes, home users benefit significantly from the active community support surrounding Linux-based Zigbee gateways. Key advantages include:
- Comprehensive Documentation: Open-source projects like Zigbee2MQTT, Home Assistant, or Z2M offer detailed setup guides, troubleshooting tips, and configuration examples that help users get started quickly.
- Forums and Discussion Boards: Platforms like GitHub, Reddit, and dedicated forums allow users to ask questions, share automation scripts, and receive advice from experienced developers and hobbyists.
- User-Developed Plugins and Integrations: The community frequently contributes custom add-ons, device compatibility patches, and UI enhancements that expand the gateway’s functionality beyond official releases.
- Rapid Issue Resolution: Bugs and compatibility problems are often identified and resolved quickly due to transparent development and peer review.
- Learning Resources: Tutorials, video guides, and open codebases help users understand how the system works, empowering them to customize and improve their smart home setups.
This collaborative ecosystem lowers the barrier to entry and enables even non-technical users to build powerful, personalized home automation systems with confidence.
A bridge gateway serves as a critical intermediary between Zigbee-based devices and other network infrastructures. Its primary functions include:
- Protocol Translation: It converts Zigbee communication (based on IEEE 802.15.4) into standard IP-based protocols like TCP/IP used on Ethernet or Wi-Fi networks, enabling seamless integration with home routers, servers, and cloud services.
- Network Interoperability: By bridging Zigbee with Wi-Fi, Ethernet, or cellular networks, it allows non-Zigbee devices (e.g., smartphones, tablets, or cloud platforms) to interact with Zigbee sensors, lights, locks, and thermostats.
- Data Routing: The gateway receives data packets from Zigbee end devices, processes them, and forwards them to the appropriate destination—such as a local server, mobile app, or IoT platform.
- Security Enforcement: It can apply authentication, encryption, and access control policies when relaying data between networks, enhancing overall system security.
- Local Control Capability: Many bridge gateways support local execution of automation rules, reducing reliance on internet connectivity and improving response times.
In essence, a bridge gateway acts as the central nervous system of a smart environment, ensuring that all components—regardless of their native protocol—can communicate effectively and securely.
Yes, one of the most powerful advantages of Linux-based Zigbee gateways is their high degree of customizability, thanks to the open-source nature of the operating system and associated software. Users can:
- Modify Source Code: Developers can access and alter the underlying firmware or application logic to tailor behavior, optimize performance, or add new features not available in stock versions.
- Create Custom Automation Rules: Using scripting languages like Python or Node-RED, users can design complex automation workflows based on sensor inputs, time schedules, or external triggers.
- Integrate with Third-Party Systems: APIs and plugin architectures allow integration with home automation platforms (e.g., Home Assistant, OpenHAB), voice assistants (Alexa, Google Assistant), or enterprise systems (BMS, SCADA).
- Optimize for Specific Use Cases: Whether it's a smart office, factory floor, or residential setup, users can fine-tune the gateway’s behavior—for example, adjusting polling intervals, prioritizing certain devices, or implementing custom security policies.
- Build Proprietary Solutions: Businesses can develop branded, white-labeled gateways for resale or internal deployment, leveraging Linux’s flexibility and low licensing costs.
This level of control makes Linux Zigbee gateways highly adaptable to both personal preferences and demanding professional requirements, setting them apart from closed, proprietary alternatives.
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