Why Choose Cloud Managed PoE Switch

lud zhu

In the rapidly evolving landscape of network technology, Cloud Managed Power over Ethernet (PoE) switches are becoming increasingly prevalent in enterprises and organizations. These switches not only provide the fundamental functionalities of traditional switches but also integrate cloud management platforms, offering network administrators greater flexibility and efficiency. This blog post delves into the advantages of Cloud Managed PoE switches, their applications, and their role in modern network architectures.

 

What is a Cloud Managed PoE Switch?
A Cloud Managed PoE Switch is a network device that combines PoE technology with remote cloud management capabilities. PoE technology enables switches to transmit data and provide power over Ethernet cables to connected devices such as IP phones, cameras, and wireless access points. Cloud management technology allows administrators to remotely configure, monitor, and manage switches through a cloud-based platform, eliminating the need to be physically present near the devices.
Advantages of Cloud Managed PoE Switches
  1. Remote Management and Monitoring: Administrators can monitor and manage all connected devices from anywhere via the cloud management platform, not limited to a specific physical location.
  2. Simplified Deployment and Configuration: Multiple switches can be configured simultaneously through the cloud platform, significantly reducing deployment time and costs.
  3. Centralized Control and Automation: Administrators can centrally manage configurations of all network devices and automate tasks such as firmware updates and implementation of security policies.
  4. Real-time Fault Diagnosis and Response: The cloud management platform provides real-time fault diagnosis and alerts, enabling administrators to promptly respond to and resolve network issues.
  5. Scalability and Flexibility: Easily scale and adjust network size to accommodate evolving business needs and increasing device connections.
Applications
Cloud Managed PoE switches find wide applications across various industries and organizations, particularly in scenarios requiring extensive device management and remote monitoring, such as:
  • Education Institutions: Managing IP phones, security cameras, and wireless access points across campuses to ensure secure and efficient network services.
  • Healthcare: Controlling medical devices and communication systems within hospitals to ensure the security and stability of real-time data and communications.
  • Retail Sector: Managing POS systems, surveillance cameras, and wireless networks distributed across different locations to maintain network connectivity and security in stores.
  • Corporate Offices: Managing various devices within office buildings to provide efficient network connectivity and IT support services.
Conclusion
Cloud Managed PoE switches offer modern enterprises and organizations more efficient, flexible, and secure network solutions through their robust remote management capabilities and integration with PoE technology. With the continuous advancement of cloud computing and IoT technologies, these network devices will continue to play a crucial role across industries, supporting digital transformation and business innovation.

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What is Inside an SFP Module? – Understanding TOSA, ROSA, BOSA

lud zhu

Networking technology is crucial in today's world, serving as the backbone that interconnects countless devices and systems globally. One vital element in the data communication sector is the Small Form-factor Pluggable (SFP) module. In this blog, we will explore the inner workings of these modules, with a particular focus on three essential optical components: TOSA, ROSA, and BOSA.

Introduction to SFP Modules and Optical Components SFP

Definition of SFP Modules and Their Role in Networking

SFP modules are small, hot-swappable devices used in both telecommunications and data communications. These modules connect a network device's motherboard to a fiber optic or copper networking cable. Standardized by the Multi-Source Agreement (MSA), SFPs are interoperable across different brands and devices, making them highly versatile for enhancing network flexibility and scalability.

Fiber optic transceivers are essential components of fiber optic transmission networks. These compact devices feature advanced integrated optical sub-assemblies, making them perfectly suited to meet the high-density networking requirements of today. The market offers a variety of SFPs, including standard SFPs and the enhanced SFP+ variants, each with unique features and specifications. Understanding their core functions is crucial. So, what are the primary functions of SFP transceiver modules?

  • SFPs are responsible for both transmitting and receiving data, essential processes for effective communication.

  • These transceivers enable the vital conversion between electrical signals and optical signals, ensuring smooth data transmission in both directions.

Importance of Understanding SFP Internal Mechanics

To fully comprehend the capabilities and reliability of SFP modules, it's essential to delve into their internal structure and operational principles. Understanding the inner workings of SFP modules is not only valuable for troubleshooting but also for making informed decisions when selecting and deploying the appropriate modules to meet specific networking requirements.

Given their compact size and complex functionality, have you considered the mechanisms at work within an SFP transceiver? These components are more than just parts of a network – they are the heart of connectivity. Nestled within the sturdy metal housing of a transceiver lie several intricate components and sub-assemblies. These work in unison to achieve the impressive capabilities of the SFP module. Amongst the most significant components housed within transceivers, we find:

  • The Transmitter Optical Sub-Assembly (TOSA), which plays a pivotal role in signal transmission.

  • The Receiver Optical Sub-Assembly (ROSA), essential for signal reception.

  • The Bi-Directional Optical Sub-Assembly (BOSA), which enables two-way communication over a single fiber path.

Every component within SFP modules is meticulously engineered to exacting standards, ensuring seamless data transmission across expansive networks, linking users and devices worldwide. This categorization is rooted in the specific functions that SFPs will perform.

SFP

It's commonly understood that a standard SFP module comprises two ports: Transmit (TX) and Receive (RX). The components housed within the Transmitter Optical Sub-Assembly (TOSA) facilitate the transmitting function, while those within the Receiver Optical Sub-Assembly (ROSA) handle reception.

Detailed Examination of SFP Module Components

A thorough inspection of the SFP module reveals several intricate components that collaborate to manage fiber optic signals. These include the Transmitter Optical Sub-Assembly (TOSA), the Receiver Optical Sub-Assembly (ROSA), and in certain SFP variants, the Bidirectional Optical Sub-Assembly (BOSA).

Transmitter Optical Sub-Assembly (TOSA) Overview

The Transmitting Optical Sub-Assembly (TOSA) is a pivotal component situated within the transmit section of SFP ports. Its principal role is to convert electrical signals into optical signals before propelling them through the connected optical fiber strand. The TOSA comprises several vital elements, notably a laser diode responsible for generating the light signal and an optical interface that guides this signal into the fiber. Additionally, it incorporates a monitor photodiode tasked with regulating the laser output. Encased within a robust housing crafted from metal and/or plastic, the TOSA also features an electrical interface facilitating signal conversion.

As an essential building block of fiber optic transceivers, the TOSA's design may vary to accommodate diverse requirements and applications. It may integrate supplementary components like filter elements and isolators to enhance its performance, underscoring its adaptability and significance in the field of fiber optics.

TOSA

Exploring ROSA (Receiver Optical Sub-Assembly)

The Receiver Optical Sub-Assembly (ROSA) holds significant importance within the receiving segment of the SFP port. Its primary role is to capture the optical signal transmitted from the Transmitting Optical Sub-Assembly (TOSA) of a transceiver at the opposite end and convert it back into an electrical signal. This conversion is essential for making the signal intelligible to communication devices.

Comprising three primary components, the ROSA includes a photodiode responsible for detecting incoming light signals, a protective housing typically crafted from metal or plastic, and an electrical interface facilitating connection to communication equipment. This trio is fundamental for the operation of any fiber optic transceiver.

Collaborating harmoniously, a ROSA and a TOSA constitute the core of an optical transceiver module, enabling bi-directional communication. Additionally, the ROSA may integrate an amplifier to enhance the strength of the received signal, ensuring its preservation and quality for subsequent processing.

ROSA

The Role of BOSA (Bidirectional Optical Sub-Assembly) in SFP Modules

TOSA (Transmitter Optical Sub-Assembly) and ROSA (Receiver Optical Sub-Assembly) are pivotal components responsible for signal transmission and reception in conventional unidirectional transceivers. Typically, they are each linked to an optical fiber to enable unidirectional signal transmission and reception.

However, the emergence of BOSA components has revolutionized the communication field by enabling their integration into bidirectional SFP modules. This integration facilitates bidirectional (full-duplex) communication over a single optical fiber, consolidating the functions of laser emitters and photodetectors. Leveraging wavelength division multiplexing (WDM) technology, BOSA transmits and receives optical signals of varying wavelengths within the same fiber channel, streamlining network architecture, lowering deployment expenses, and enhancing system transmission efficiency.

The adoption of BOSA in bidirectional SFP modules not only streamlines design and reduces equipment footprint but also ensures minimal signal crosstalk and attenuation between wavelengths, thereby enhancing communication reliability. With its precision engineering design aligning with diverse fiber optic communication standards, BOSA technology augments network flexibility and maintainability while curbing infrastructure costs, simplifying network upgrades.

Consequently, BOSA technology stands as a vital catalyst for constructing efficient, cost-effective, and sustainable network infrastructure.

BOSA

Summary

The intricate components within an SFP module, including TOSA, ROSA, and BOSA, epitomize the remarkable technological strides in fiber optic communication. Delving into the inner workings of an SFP module enables network professionals to grasp the intricacy and precision required to facilitate our daily digital communications. From the generation and reception of light signals to the transmission of data across extensive distances with minimal loss, the mechanisms housed within these modules are indispensable to the networks that keep us interconnected in the digital era. As technology advances, the design and functionalities of these optical components will continue to evolve, fostering enhanced communication speeds, reliability, and overall network efficiency.

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How to Integrate LoRaWAN Sensor to BACnet BMS System via Linovision Gateway

lud zhu

Introduction

Linovision gateway is able to decode the data of LoRaWAN sensors and map the sensor data into BACnet objects used by BMS system or BACnet devices, which can quickly and easily integrate LoRaWAN devices to Building Management System.

 

Requirement

  • Linovision Gateway: IOT-G65/G67 with firmware version 60.0.0.41 and later
  • Any LoRaWAN sensor
  • BACnet Client tool: take Yabe as example

 

Configuration

  1. Go to Network Server > Payload Codec to check if there is decoder of your LoRaWAN node, if not please add and custom the decoder referring to article How to Use Payload Codec on Linovision Gateway.

  2. Connect LoRaWAN node to Linovision gateway referring to article How to Connect LoRaWAN Nodes to Linovision Gateway. Note that ensure the correct payload codec is selected when adding this device.

  3. Go to Network Server > Packets to check if there is uplink packet and click Details to check if the decoder works. If works, the JSON item will show the decoded result.

         

image-20221227095609700

 

  1. Select the Application you use and add a BACnet/IP transmission.

 

image-20221223144348974

 

 

  1. Go to Protocol Integration > BACnet Server > Server to enable BACnet server and configure the settings. Note that the Device ID should be changed to an unique value to avoid conflict with other BACnet server devices, or the BACnet client may not find this device.

 

  1. Go to Protocol Integration > BACnet Server > BACnet Object page, click Add to add an object.
  • Device Name: select the device added on Network Server > Device page
  • LoRa Object: select or customize a sensor variable decoded on JSON item of Network Server > Packets page
  • Object Name: customize an unique object name
  • Object Type: select Analog Input or Binary Input for non-editable sensor data

Example 1: temperature data

  • COV: when the change of analog type object value exceeds the COV Increment, the gateway will send notification to BACnet client actively. This should ensure the BACnet client supports COV feature.

 

 

 

Example 2: button status

  • Active/Inactive Text: display the real status when button is pressed or unpressed
  • Polarity: Define the binary status as Normal or Reverse.

 

 

Note: for LInovision buttons (IOT-S500BT and IOT-S500SP), it's suggested to add msgid value (update a random value if the press is triggered) to an object and know if the button is pressed by the change of this value.

 

 

  1. After adding, you can check if object values are updated regularly.

 

 

  1. Open Yabe BACnet client tool, click Add device to scan the devices, then you can find the BACnet server device according to the Device ID and check the object list.

 

image-20221227144927758

  

  1. Click the object to check all the properties of this object.

 

 

 

 

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How to Use Payload Codec on Linovision Gateway

lud zhu

Introduction

When Linovision gateway work as embedded network server, it supports to send data to third party server via MQTT/HTTPS and it will send every data as below JSON format:

JavaScript:
{"applicationID":"1","applicationName":"cloud","data":"A2fqAARoTwUAAA==","devEUI":"24e124136b502217","deviceName":"EM300-TH","fCnt":128,"fPort":85,"rxInfo":[{"altitude":0,"latitude":0,"loRaSNR":13.8,"longitude":0,"mac":"24e124fffef54092","name":"Local Gateway","rssi":-51,"time":"2022-12-27T07:21:27.078763Z"}],"time":"2022-12-27T07:21:27.078763Z","txInfo":{"adr":true,"codeRate":"4/5","dataRate":{"bandwidth":125,"modulation":"LORA","spreadFactor":7},"frequency":868100000},"metadata":{"mqtt_topic":"/mqtttest"}}

 

This article will guide you how to custom uplink and downlink contents via Payload Codec feature.

Requirement

  • Linovision LoRaWAN Gateway: IOT-G65/G67 with firmware version 60.0.0.41 and later

For other models or versions, please refer to How to Use Payload Codec on Linovision Gateway(old).

 

Configuration

Inbuilt Payload Codec

Linovision gateway has supported the inbuilt payload codec library to add Linovision decoders and encoders easily. It supports two obtaining types:

Online: when gateway is able to access the Internet, it will check the update and update the library automatically. You can also click Obtain to check the update.

Local Upload: upload decoder package locally.

When you add any device on Network Server > Device page, you can select the decoder and the decoded data will be shown on the packet details of Network > Packets page.

Custom Payload Codec

If you use other brand devices or the default decoder does not work with your application, please add a custom payload codec:

Uplink Content Customization

Take IOT-S500TH as example, here are 3 situations for uplink content customization.

1. Only upload decoded sensor data.

Copy IOT-S500TH decoder and paste it to Payload decoder function box.

Note: If you configure the sensor from other company, please contact their support to get the Decoder Script (Java Script), then ensure the script header is function Decode(fPort, bytes) when paste.

You can use Payload Codec Test feature to test the uplink result.

Uplink Result:

JavaScript:
{ "battery": 92, "temperature": 30.8, "humidity": 50.5,}

 

 

2. Upload specific attribute items and raw data.

Click here to know all attribute items in one package. Linovision gateways provide function LoRaOject to call every item you require. If you need to send dev EUI, RSSI, SNR and raw data, edit this example coder:

JavaScript:
function Decode(fPort, bytes) {var decoded = {};decoded.devEUI = LoRaObject.devEUI;decoded.rssi = LoRaObject.rxInfo[0].rssi;decoded.snr = LoRaObject.rxInfo[0].loRaSNR;decoded.data = LoRaObject.data;return decoded;}

 

Uplink Result:

JavaScript:
{"devEUI":24e1611234567890"rssi": -5,"snr": 11,"data": AXVkA2cgAQRoeg==}

 

After adding, you can add this payload codec to a device and go to Network Server > Packets to check the uplink result on Packet Details.

 

3. Upload specific attribute items and decoded data.

Copy IOT-S500-TH decoder and paste it to Payload decoder function box, then add attribute items before return decoded statement:


JavaScript:
function Decode(fPort, bytes) { var decoded = {}; //Data decoder for (var i = 0; i < bytes.length;) { var channel_id = bytes[i++]; var channel_type = bytes[i++]; // BATTERY if (channel_id === 0x01 && channel_type === 0x75) { decoded.battery = bytes[i]; i += 1; } // TEMPERATURE else if (channel_id === 0x03 && channel_type === 0x67) { decoded.temperature = readInt16LE(bytes.slice(i, i + 2)) / 10; i += 2; } // HUMIDITY else if (channel_id === 0x04 && channel_type === 0x68) { decoded.humidity = bytes[i] / 2; i += 1; } else { break; } } decoded.devEUI = LoRaObject.devEUI; return decoded;}/* ****************************************** * bytes to number ********************************************/function readUInt16LE(bytes) { var value = (bytes[1] << 8) + bytes[0]; return value & 0xffff;}function readInt16LE(bytes) { var ref = readUInt16LE(bytes); return ref > 0x7fff ? ref - 0x10000 : ref;}

Uplink Result:


JavaScript:
{ "battery": 92, "temperature": 30.8, "humidity": 50.5,"devEUI":24e1611234567890}

Note: If you need to add all attribute items, add decoded.obj= LoRaObject; before return decoded statement.

After adding, you can add this payload codec to a device and go to Network Server > Packets to check the uplink result on Packet Details.

 

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Build a Resilient & Reliable Retail Network with Linovision Retail Solutions

lud zhu

Retail businesses depend on a robust network to operate effectively. A resilient and reliable network ensures business continuity, enhances customer experience, and boosts productivity. The rise of e-commerce in recent years has intensified competition and heightened customer expectations, necessitating stronger network infrastructures for retailers.

This article discusses crucial factors retailers should consider when building a resilient and reliable network and demonstrates how Linovision retail solutions can help meet these requirements.

Essential Considerations

When constructing a resilient and reliable network, retailers must account for several key factors to ensure their network can support the demands of contemporary retail.

Bandwidth and Application Requirements

Retailers need to assess their network bandwidth requirements to adequately support their applications and services. This includes considering the number of connected devices, the volume of data transmission, and the necessary network speed.

With the expansion of e-commerce, retailers require networks that can handle substantial data loads. This necessitates high-speed connections, ample bandwidth, and low latency. Planning for future scalability is also crucial.

Alternatives to Legacy Connectivity

Retailers should explore alternative solutions for high-bandwidth applications, such as implementing secondary networks or using broadband bonding instead of a single high-capacity circuit. Considering IPSec virtual private networks (VPNs) as alternatives to multiprotocol label switching (MPLS) can also be beneficial.

Evaluating these alternatives allows retailers to optimize their network infrastructure and maximize return on investment (RoI).

Integrating Other Systems

Consolidating other systems, such as phone and security systems, onto the network can enhance its reliability and resilience. This integration reduces the number of physical systems to manage, thereby simplifying complexity and improving reliability.

For instance, moving security systems onto the network enables remote monitoring and integration with access control and video surveillance systems.

Building a Resilient & Reliable Network with Linovision Retail Solutions

Linovision offers a suite of products and services tailored to help retailers develop resilient and reliable networks.

Flexible Wired Infrastructure

Linovision provides a variety of switches, routers, and other networking products designed for high-speed, reliable connectivity. For example, the POE-SW716GM-10G switch features 10G ports for versatile retail network deployments. The POE-SW708GM and POE-SWR608G switches incorporate advanced chips for superior network performance. Linovision switches also support various network security strategies to ensure the network’s reliability and flexibility.

Linovision RemoteMonit Cloud Management

The Linovision RemoteMonit Cloud management platform offers a cloud-based solution that simplifies retail network management. RemoteMonit provides real-time network performance visibility, enabling retailers to quickly identify and address issues.

Retail-Built Wi-Fi 6

The Retail-Built Wi-Fi 6 IOT-CPE5G delivers fast, reliable connectivity with 2.4G & 5GHz dual-band Wi-Fi and 2x2 MIMO Dual Radios for optimized performance. Featuring a Qualcomm Quad-Core Processor and 512MB DDR RAM, it is designed for quick and cost-effective deployment. Managed via Linovision cloud, the IOT-CPE5G is highly scalable, allowing for network expansion as business needs grow.

Conclusion

Retailers must ensure their networks can meet the increasing demand for fast, reliable, and secure connectivity to support their business objectives. Linovision retail solutions offer the tools and support necessary to build and maintain such networks.

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Layer 2 vs Layer 3 Switch: Which One Do You Need?

lud zhu


Network switch can connect to various terminal devices, set up LANs, and enable direct communication among all equipment. With the evolution of networks, different types of switches have been introduced. According to the OSI model, a Layer 2 switch operates at the data link layer, while a Layer 3 switch functions at the network layer. This raises the question: Should I use a Layer 2 or Layer 3 switch?
Before addressing this, it’s important to understand the OSI model and the role of network switches.

OSI Model and Network Switch: What Are They?

OSI Model

The Open Systems Interconnection (OSI) model is a conceptual framework that divides network communication functions into seven layers: Physical, Data Link, Network, Transport, Session, Presentation, and Application.

Transmitting data over a network is a complex process requiring the collaboration of various hardware and software technologies, crossing geographical and political boundaries. The OSI model provides a universal language for computer networks, enabling different technologies to communicate using standard protocols or communication rules. Each layer within the OSI model has specific functions and tasks that ensure the network operates smoothly. Higher-level technologies benefit from this abstraction, as they can utilize lower-level technologies without needing to understand the underlying implementation details.

Advantages of OSI Model:

  • Clear distinction between hardware and software
  • Improved understanding and communication of processes
  • Efficient troubleshooting
  • Open interoperability between different systems
  • Clear communication of product functionality

Network Switch

A network switch (also known as a switching hub, bridging hub, or MAC bridge by the IEEE) is networking hardware that connects devices on a computer network by using packet switching to receive and forward data to the destination device.

A network switch is a multiport network bridge that uses MAC addresses to forward data at the data link layer (Layer 2) of the OSI model. Some switches can also forward data at the network layer (Layer 3) by incorporating routing functionality, known as Layer 3 or multilayer switches.

What Is a Layer 2 Switch?

A Layer 2 switch operates at the data link layer of the OSI model, efficiently forwarding data packets based on MAC addresses. It works within the hardware layer, eliminating the need for frame modification. Layer 2 switches are commonly used for workgroup connectivity and network segmentation, enhancing performance and reducing collision domains.

Key functionalities of a Layer 2 switch include:

  1. High-speed forwarding: These switches achieve fast data frame forwarding by referencing an address table to find the port associated with the destination MAC address, eliminating the need for decapsulation and encapsulation of data frames.

  2. Collision domain isolation: Each port on a Layer 2 switch is treated as an independent collision domain, reducing collisions and retransmissions of data frames, thus improving network performance.

  3. VLAN support: Layer 2 switches enable the creation and management of virtual LANs (VLANs). By adding VLAN identifiers to data frames, different logical networks can be divided and controlled effectively.

What Is a Layer 3 Switch?

Layer 2 and Layer 3 switches differ primarily in their routing capabilities. A Layer 2 switch operates solely based on MAC addresses, disregarding IP addresses and higher layer elements. In contrast, a Layer 3 switch, or multilayer switch, performs the functions of a Layer 2 switch while adding static and dynamic routing capabilities. This means a Layer 3 switch maintains both MAC address and IP routing tables, facilitating intra-VLAN communication and packet routing across different VLANs. Additionally, there are Layer 2+ (Layer 3 Lite) switches that offer static routing exclusively. Layer 3 switches not only route packets but also provide advanced features like VLAN traffic tagging based on IP addresses, enhancing power, security, and network management capabilities.

Key functionalities of a Layer 3 switch include:

  1. Isolated broadcast domains: Each port on a Layer 3 switch functions as an independent broadcast domain, minimizing the impact of broadcast storms on network performance and bolstering network security.

  2. Routing protocol support: Layer 3 switches can accommodate various routing protocols (such as RIP, OSPF, BGP, etc.), enabling dynamic routing updates and exchanges with other routers or Layer 3 switches. This enhances network reliability and flexibility.

  3. Policy routing support: Layer 3 switches offer policy routing capabilities based on source IP addresses, destination IP addresses, protocol types, and other conditions. This allows for differentiated processing or forwarding of data packets based on their types or priorities, optimizing network efficiency and quality.

For superior processing performance and network reliability, Linovision offers different types of managed poe switch. Visit linovision.com for more information.

 

What Are the Differences Between Layer 2 and Layer 3 Switches?

Below is a comparison of the key differences between Layer 2 and Layer 3 switches:

How to Choose the Suitable Switches for Your Network Need

When deciding between a Layer 2 switch and a Layer 3 switch, consider the following factors:

For Layer 2 Switch:

Network Size: Suitable for small to medium-sized networks that require high-speed connectivity within the same network segment.

Network Segmentation: Helps reduce congestion and improve performance by dividing the network into smaller domains within a LAN setting.

Cost-Effectiveness: Generally less expensive due to its limited functionality.

Simple Subnet Networks: Adequate for single subnet networks with low traffic volumes.

  

For Layer 3 Switch:

Advanced Routing: Necessary for networks that require inter-VLAN routing, Quality of Service (QoS), and enhanced security features.

Multiple VLANs: Enables routing between VLANs, making it ideal for large organizations with complex network setups.

Network Scalability: Offers greater scalability by managing routing between multiple segments, preventing congestion and accommodating complex traffic patterns.

Future Expansion: Recommended for networks with anticipated growth, providing advanced routing capabilities to support future needs.

Summary

This post has explained the differences between Layer 2 and Layer 3 Switch. The comparison of their functions is also made, in the hope of solving the problem of deciding between these devices. In network systems, Layer 2 and Layer 3 switches can be selected and combined according to different needs and scenarios to achieve high efficiency and reliability of network communication.

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Exploring the Future of Remote Connectivity: Solar PoE Switches

lud zhu

In our increasingly interconnected world, the demand for reliable and sustainable connectivity in remote locations continues to grow. Traditional power sources are often unavailable or impractical in these environments, making innovative solutions like Solar PoE Switches with Built-in MPPT Solar Charge Controllers essential for bridging the gap.

Harnessing Solar Power for Connectivity

Imagine a scenario where surveillance cameras need to be installed in a remote wildlife reserve or a wireless network must be established in a rural community without access to grid electricity. This is where Solar PoE Switches shine. These devices integrate cutting-edge Maximum Power Point Tracking (MPPT) technology with Power over Ethernet (PoE) capabilities, allowing them to efficiently harness solar energy and distribute both power and data over a single Ethernet cable.

Key Features and Functionality
MPPT Solar Charge Controller: The heart of the Solar PoE Switch, the MPPT controller optimizes the output from solar panels by adjusting voltage and current to ensure maximum efficiency. This means even under varying sunlight conditions, the switch can consistently deliver power to connected devices such as IP cameras, wireless access points, or environmental sensors.
Power over Ethernet (PoE): By leveraging PoE technology, the switch eliminates the need for separate power lines to each device. This simplifies installation, reduces costs, and ensures a streamlined network setup in remote locations where infrastructure is limited.
Rugged and Weatherproof Design: Designed to withstand harsh outdoor conditions, Solar PoE Switches are built with rugged, weatherproof enclosures. They can endure temperature extremes, humidity, and exposure to the elements, ensuring reliable operation in challenging environments.
Environmental and Cost Benefits: Utilizing solar power reduces reliance on traditional energy sources, making Solar PoE Switches not only environmentally friendly but also cost-effective over the long term. They contribute to sustainability efforts by minimizing carbon footprints and operational costs associated with remote infrastructure maintenance. 

Applications and Real-World Benefits

Remote Surveillance: Protecting wildlife reserves or monitoring remote industrial sites becomes feasible with solar-powered surveillance cameras powered by these switches. 

Community Networks: Facilitating internet access and connectivity in rural or underserved areas where extending traditional power lines is impractical. Combined with the use of a 4G wireless router, it makes it possible to use the Internet in areas where it is impossible to set up a wired network.
Environmental Monitoring: Supporting scientific research by powering sensors and data collection devices in remote environmental monitoring systems.

 

Conclusion: 
Solar PoE Switches represent a significant advancement in infrastructure technology, enabling connectivity where it was once thought impossible or economically unfeasible. By harnessing the power of the sun and integrating sophisticated power management capabilities, these devices empower organizations and communities to expand their networks sustainably and reliably.
As we continue to explore and expand our connectivity needs globally, solutions like Solar PoE Switches will play a crucial role in bridging the digital divide and advancing sustainable development goals. Embracing these innovations not only enhances connectivity but also contributes to a greener, more resilient future for all.

 

In conclusion, the future of remote connectivity is bright with Solar PoE Switches leading the charge towards a more connected and sustainable world.

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Why we need 4G Industrial Routers?

lud zhu

With the ongoing digital transformation in industries, the demand for reliable and efficient network connectivity is escalating. In this context, 4G industrial routers are emerging as crucial networking devices, playing a vital role in connecting industrial equipment and facilitating data transmission. This article delves into the usage scenarios and significance of 4G industrial routers in industrial applications.

  1. Remote Monitoring and Control

In industrial settings, many devices require remote monitoring and control to ensure their smooth operation and timely maintenance. 4G industrial routers provide a reliable remote connection, enabling operators to monitor device status and undertake necessary control operations from anywhere, anytime.

  1. Connectivity for Mobile Devices

Numerous industrial scenarios involve real-time communication between mobile devices such as robots and AGVs (Automated Guided Vehicles) and central control systems. Given the dynamic nature of mobile devices' locations, traditional wired connections may fall short. 4G industrial routers offer stable data transmission channels via mobile networks, ensuring seamless connectivity for these mobile devices.

  1. Emergency Response

In industrial production, prompt response to emergencies is crucial to minimize losses and mitigate risks. 4G industrial routers serve as reliable communication support for emergency response teams, enabling them to swiftly access critical information and take appropriate measures.

  1. Network Backup and Failover

To ensure the uninterrupted operation of production lines, industrial systems often deploy multiple network connections as backups. 4G industrial routers can function as one of these backup connections, automatically switching to the 4G network when the primary network encounters failure, thereby ensuring continuous operation of production lines.

  1. Network Extension and Coverage

In remote or temporary industrial locations where traditional wired network coverage is limited, 4G industrial routers can extend the network coverage via wireless connections, providing reliable network connectivity for these areas. 4G industrial routers play an important role in situations where it is difficult to set up a wired network, such as scientific field trips or smart agriculture.

Conclusion
From remote monitoring and control to emergency response and network redundancy, 4G industrial routers play a pivotal role in industrial applications. As industries continue their digital transformation journey, these routers will remain indispensable, driving the progress of the industrial Internet. Through this article, we hope readers gain a deeper understanding of the significance and applications of 4G industrial routers in industrial settings, offering insights and reflections for industrial network infrastructure development.

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What is Wide Dynamic Range (WDR) in IP Cameras?

Andy Chen

Have you ever wondered why some security camera footage appears washed out or too dark to distinguish details? This issue can be attributed to the concept of dynamic range, which refers to the balance between light and dark areas within an image. Understanding the concept of wide dynamic range (WDR) is crucial when discussing camera performance, as it plays a significant role in revolutionizing security surveillance.

What Is Wide Dynamic Range?

Wide dynamic range is a term used to describe the contrast ratio between the darkest and brightest color tones that a camera can capture in a single exposure. In video surveillance, WDR technology aims to effectively manage high-contrast environments by skillfully balancing the extremes. Its purpose is to prevent overexposure in bright areas and retain detail in dark areas, thereby avoiding under- or overexposed footage.

The measurement of a camera's dynamic range is expressed in decibels (dB), with the industry standard defined by IHS Markit stating that WDR should have a range of 60 dB or higher. However, it is not uncommon to find WDR cameras that offer dynamic ranges of 120 dB or even greater.

To illustrate the effectiveness of WDR technology in surveillance cameras, let's compare two images. In the first image without WDR, the camera's exposure is affected by the intense light coming from the window. As a result, the exterior view is overexposed, obscuring the details, while the room's interior appears too dark. However, in the second image with WDR enabled, the camera achieves balanced exposure. Both the bright outdoor scenery and the interior details of the conference room are captured clearly, ensuring visibility of both areas within the same frame.

WDR Off vs. WDR On

How Does WDR Work?

WDR technology utilizes two processors, namely a light image processor and a dark image processor, to enhance the overall image quality and clarity.

When employing WDR technology in a PoE IP camera, the camera lens allows different amounts of light to enter specific areas of the image by utilizing varying shutter speeds. This control of light exposure helps achieve a well-balanced WDR image.

In areas with brighter lighting conditions, the camera lens employs a higher shutter speed, resulting in a shorter duration of light exposure for the camera sensor.

Conversely, in darker areas, the camera lens adopts a relatively slower shutter speed, allowing the sensor to capture more light over an extended period.

By combining the information from both images captured at different exposure settings, a final image is generated, which exhibits improved quality and clarity compared to a single-exposure image.

True WDR vs DWDR

True WDR (Wide Dynamic Range) and DWDR (Digital Wide Dynamic Range) are two technologies utilized in cameras to handle high-contrast lighting conditions.

True WDR employs a combination of hardware and software to capture multiple frames simultaneously at different exposure levels. These frames are then merged to create a single image with well-balanced exposure, ensuring that both the brightest highlights and darkest shadows retain their detail.

In contrast, DWDR operates solely through software manipulation on a single image. It adjusts the brightness of shadows and reduces the intensity of highlights. While DWDR is a cost-effective solution, it is generally less effective than True WDR and more suitable for lighting situations that are less challenging.

WDR vs HDR

WDR (Wide Dynamic Range) and HDR (High Dynamic Range) are two distinct image processing techniques that aim to improve image capture performance in high-contrast scenes. It is important to understand the differences between WDR and HDR to choose the appropriate surveillance technology that meets the requirements of various environments and image quality needs.

When comparing HDR and WDR, we recommend using WDR technology for security cameras due to the following advantages:

  1. High-Speed Processing: WDR technology is supported by high-speed digital signal processing (DSP), enabling it to effectively handle dynamic images and videos.

  2. Adjustable Exposure: WDR allows for the output of multiple frames with different exposure times, and each frame's gain can be individually set. This flexibility allows for precise control over the exposure settings.

  3. Backlight Compensation: WDR enables imaging systems to compensate for intense backlighting surrounding subjects. This feature enhances the ability to distinguish features and shapes on the subject, ensuring clearer and more detailed images.

  4. Better Low-Light Imaging: WDR technology excels at capturing images in low-light environments. It can effectively illuminate dark areas, ensuring security even in situations with low or no power supply.

  5. Sharp Details: Compared to HDR, WDR technology produces images with exceptional sharpness and more pronounced details. This results in improved image quality and enhanced visibility of important information.

  6. Cost-Effective: WDR cameras are more cost-effective in terms of installation and purchase price compared to HDR cameras. This makes WDR technology a practical choice for various surveillance applications, providing high-quality imaging at a more affordable cost.

Where to Use WDR Cameras?

WDR cameras find extensive use in environments characterized by demanding lighting conditions, particularly in areas where there is a significant contrast between bright and dark areas. Here are some common applications where WDR cameras are employed:

Where to Use WDR Cameras

Entrance

The primary application for WDR cameras is monitoring the entrances of buildings. Whether it's a store, bank, ATM, transportation facility, restaurant, or hospital, every establishment has entrance doors that introduce bright light compared to the interior space. WDR cameras excel at compensating for areas that are excessively bright or dark and provide clear snapshots or videos.

Garage

In high-contrast scenarios where vehicles frequently enter parking lots, darkened garages, or cars with bright headlights approach surveillance cameras, WDR cameras can capture license plates with enhanced clarity.

Window Side

In areas where sunlight streams through glass panes, creating sharp contrasts of light and shadow within interior spaces, WDR cameras meticulously balance the intense glare from the outdoors with the softer indoor lighting. This ensures that every detail, from people's expressions near the window to the movement of curtains in the sunlight, is captured accurately.

Outdoor

Outdoor surveillance cameras often face the challenge of strong sunlight, which contrasts with the shadows of buildings or areas without direct sunlight. WDR cameras effectively compensate for these differences, providing clear and balanced images.

To further enhance security with high-quality video capture in challenging lighting conditions, Linovision offers a range of security cameras equipped with WDR technology. These options include the 4K bullet PoE IP camera, the 4MP dome network camera, the 4MP turret network camera. Linovision not only provides security cameras but also offers comprehensive video surveillance solutions tailored for enterprises, retail supermarkets, campuses, and other specific needs.

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Technical Guide to IP Cameras- Overview, Types, Applications

Andy Chen

IP cameras, also known as Internet Protocol cameras or network cameras, are a type of security camera that utilizes an IP network to receive and transmit video data. Their primary function is to capture video footage and send it over the network. These cameras are commonly used in various sectors and environments as remote monitoring and management tools to enhance security and protect property.

How Does An IP Camera Work?

IP cameras function similarly to digital cameras in capturing high-quality images. However, what distinguishes them is their ability to compress image files and transmit them automatically to a network video recorder (NVR) through a network connection. Typically, IP cameras can be linked to the network either via an Ethernet cable connected to a broadband modem or router, or wirelessly through a Wi-Fi router.

In the case of a building already equipped with a network infrastructure, setting up IP surveillance cameras is a straightforward process. Similar to connecting your laptop or cell phone to a Wi-Fi network, you simply need to integrate the IP cameras and other devices into your existing network system. This involves establishing connections and configuring the cameras to communicate within the network.

By seamlessly integrating IP cameras into the network, you can take advantage of their features for remote monitoring and enhanced security. These cameras enable you to conveniently access and manage them from any location with network access, providing effective surveillance and peace of mind.

 

Once all the connections have been properly established, the cameras can begin their operation by capturing video footage and transmitting it to the network video recorder.

Four Common Types of IP Camera

There are various video surveillance solutions, in which many different types of security cameras are adopted. Among those surveillance cameras, there are four most commonly used ones, dome cameras, bullet cameras, and turret cameras.  

 

Four Important Specifications of IP Cameras

When selecting a security camera, it is important to consider not only the type of camera but also its specifications, as they can significantly impact performance. Here are four crucial specifications to keep in mind:

Resolution

The resolution of an IP camera refers to the total number of pixels that compose an image, typically measured by its width and height. Common resolutions include 720p, 1080p, 5MP, 4K, and 8MP. Higher resolutions generally translate to a greater number of pixels per inch (PPI), resulting in sharper, high-quality images.

Field of View

The field of view (FOV) of an IP camera is determined by its lens and represents the coverage area that can be observed. Different lenses offer varying FOVs, influencing how wide an area the camera can capture. A wider FOV enables monitoring of larger areas. For instance, a large parking lot may require a different lens with a broader viewing angle compared to a small room.

Focal Length

The focal length of a camera lens, measured in millimeters (mm), determines the angle of view and the distance at which the camera can effectively capture images. There are two types of lenses commonly used: fixed focal length and varifocal lenses. Fixed focal lengths, such as 3.6mm or 8mm, provide specific viewing angles and identification distances. Varifocal lenses, like 2.8-12mm, offer adjustable focal lengths, allowing for flexibility in field of view and identification range.

Low Light Sensitivity

Low light sensitivity, often measured in Lux (lx), indicates a camera's ability to produce high-quality images in low-light environments, minimizing noise and preserving details. Factors such as pixel size, signal-to-noise ratio, and lens aperture contribute to a camera's low-light performance. Lower Lux values indicate superior performance in darker areas. For example, cameras with a range of 100-1,000lx are suitable for well-lit workspaces, while cameras with 0.0001lx are designed for moonless or overcast nights.

Most Popular IP Camera Applications

 

Home Use

For individuals seeking tools to enhance family connections, monitor home security, or safeguard their property, IP cameras are a must-have item. Many homeowners opt to install video surveillance systems to provide a sense of safety for themselves and their families.

IP cameras utilized in home security systems serve a multitude of purposes. They can be positioned near the front door to capture images of anyone entering or lurking around the house. They can also be installed in the backyard to preserve cherished moments with family members. Additionally, they can be placed inside rooms to ensure the well-being of babies or monitor specific areas of the house.

Business Use

Commercial security cameras are commonly employed in business premises, supermarkets, shops, restaurants, and other commercial establishments. For business owners, security cameras not only protect their property, ensuring uninterrupted operations and deterring criminal activities through real-time monitoring, but they also keep them connected to daily operations and employee safety.

Video surveillance solutions can be utilized to maintain outdoor perimeter security and monitor the surrounding areas. Compared to traditional systems, commercial IP video surveillance systems offer enhanced reliability and security with built-in encryption, data compression, network connectivity, and cybersecurity measures.

Public Safety

Surveillance cameras play a vital role in managing public order, safeguarding public safety, and protecting public property. It is common to find monitoring cameras positioned along traffic roads, parking lots, government buildings, and hospitals. Moreover, security cameras are prevalent in public areas such as schools, parks, communities, and neighborhoods.

Conclusion

IP cameras have become an integral part of home, business, and public surveillance systems. With the appropriate video management software, footage captured by IP cameras can be accessed from anywhere worldwide through network connectivity, be it through a laptop or a mobile phone. In many cases, IP cameras can also be remotely controlled, bringing significant convenience to our lives.

There are various types of security cameras designed for specific applications, which is why it is important to consider multiple factors when purchasing IP cameras for your security system. Before proceeding, it is advisable to determine your budget and specific requirements.

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