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electronalytics · 1 year ago

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Wireless Microwave-based Antenna Monitoring System Market Business Overview and Upcoming Trends, Outlook 2032

The wireless microwave-based antenna monitoring system market is experiencing steady growth driven by the increasing demand for reliable and high-performance communication networks, including 5G deployments, satellite communication systems, and IoT connectivity. These systems play a critical role in ensuring the optimal operation of antennas by monitoring key parameters such as signal quality, alignment, and performance. Key vendors in this market offer advanced solutions with capabilities for remote monitoring, real-time diagnostics, and compliance with evolving regulatory standards. As the telecommunications and broadcasting industries continue to evolve, wireless microwave-based antenna monitoring systems are expected to witness further innovation and adoption to support the seamless and efficient operation of critical communication infrastructure.

Market projections and forecasts are underpinned by extensive primary research, further validated through precise secondary research specific to the Wireless Microwave-based Antenna Monitoring System Market. Our research analysts have dedicated substantial time and effort to curate essential industry insights from key industry participants, including Original Equipment Manufacturers (OEMs), top-tier suppliers, distributors, and relevant government entities.

According to the Stringent Datalytics Research Reports, the Global Wireless Microwave-based Antenna Monitoring System Market size is estimated to be a million USD in 2023 to multi-million USD by 2033, exhibiting a CAGR of 7.8% from 2023 to 2033.

1. Consumption Analysis:

Consumption analysis in a market report for a wireless microwave-based antenna monitoring system would typically include data on the demand for these systems.

It may provide insights into the industries or sectors where these systems are predominantly used, such as telecommunications, broadcasting, defense, or aerospace.

Consumption data might also highlight factors driving adoption, such as the need for reliable communication, improved network performance, and regulatory compliance.

2. Market Segments:

Segmentation in the wireless microwave-based antenna monitoring system market can be based on various criteria, including:

Industry Vertical: Solutions tailored for specific industries, such as telecommunications, broadcasting, military, and satellite communications.

Type of Antenna: Different types of antennas may require specific monitoring systems.

Geographic Regions: Market dynamics can vary by region due to regulatory requirements and technological adoption rates.

3. Business Overview:

This section of the report may provide an overview of the current state of the wireless microwave-based antenna monitoring system market.

It might include a SWOT analysis, highlighting strengths, weaknesses, opportunities, and threats in the market.

Financial performance, recent developments, and growth strategies of key vendors could also be part of the business overview.

4. Upcoming Trends:

The report may forecast or suggest potential upcoming trends in the wireless microwave-based antenna monitoring system market. Some trends to watch for may include:

5G Deployment: Increased demand for antenna monitoring systems to ensure the performance and reliability of 5G networks.

IoT Expansion: As the Internet of Things (IoT) grows, there may be a need for monitoring systems to support IoT device connectivity.

Advanced Testing and Measurement: Development of more advanced testing and measurement capabilities for antennas.

Remote Monitoring: Enhanced remote monitoring capabilities for antennas, allowing for real-time diagnostics and maintenance.

Integration with AI and Analytics: Integration of artificial intelligence and analytics for predictive maintenance and optimization.

Compliance with Regulatory Standards: Evolving regulatory standards may drive the need for more robust monitoring systems.

Receive the FREE Sample Report of Wireless Microwave-based Antenna Monitoring System Market Research Insights @ https://stringentdatalytics.com/sample-request/wireless-microwave-based-antenna-monitoring-system-market/1789/

Market Segmentations:

Global Wireless Microwave-based Antenna Monitoring System Market: By Company • Ackerman Security • ADT • Comark Instruments（Fluke) • Cisco • Eltav Wireless Monitoring • Digital Security Controls • Esco • PCB Piezotronics • Honeywell • Philips Global Wireless Microwave-based Antenna Monitoring System Market: By Type • Analog Microwave Wireless Monitoring System • Digital Microwave Wireless Monitoring System Global Wireless Microwave-based Antenna Monitoring System Market: By Application • Traffic Monitoring • Industrial Monitoring • Indoor Security Monitoring • Others

Regional Analysis of Global Wireless Microwave-based Antenna Monitoring System Market

All the regional segmentation has been studied based on recent and future trends, and the market is forecasted throughout the prediction period. The countries covered in the regional analysis of the Global Wireless Microwave-based Antenna Monitoring System market report are U.S., Canada, and Mexico in North America, Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe in Europe, Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, Rest of Asia-Pacific (APAC) in the Asia-Pacific (APAC), Saudi Arabia, U.A.E, South Africa, Egypt, Israel, Rest of Middle East and Africa (MEA) as a part of Middle East and Africa (MEA), and Argentina, Brazil, and Rest of South America as part of South America.

Click to Purchase Wireless Microwave-based Antenna Monitoring System Market Research Report @ https://stringentdatalytics.com/purchase/wireless-microwave-based-antenna-monitoring-system-market/1789/

Key Report Highlights:

Key Market Participants: The report delves into the major stakeholders in the market, encompassing market players, suppliers of raw materials and equipment, end-users, traders, distributors, and more.

Comprehensive Company Profiles: Detailed company profiles are provided, offering insights into various aspects including production capacity, pricing, revenue, costs, gross margin, sales volume, sales revenue, consumption patterns, growth rates, import-export dynamics, supply chains, future strategic plans, and technological advancements. This comprehensive analysis draws from a dataset spanning 12 years and includes forecasts.

Market Growth Drivers: The report extensively examines the factors contributing to market growth, with a specific focus on elucidating the diverse categories of end-users within the market.

Data Segmentation: The data and information are presented in a structured manner, allowing for easy access by market player, geographical region, product type, application, and more. Furthermore, the report can be tailored to accommodate specific research requirements.

SWOT Analysis: A SWOT analysis of the market is included, offering an insightful evaluation of its Strengths, Weaknesses, Opportunities, and Threats.

Expert Insights: Concluding the report, it features insights and opinions from industry experts, providing valuable perspectives on the market landscape.

Report includes Competitor's Landscape:

➊ Major trends and growth projections by region and country ➋ Key winning strategies followed by the competitors ➌ Who are the key competitors in this industry? ➍ What shall be the potential of this industry over the forecast tenure? ➎ What are the factors propelling the demand for the Wireless Microwave-based Antenna Monitoring System? ➏ What are the opportunities that shall aid in significant proliferation of the market growth? ➐ What are the regional and country wise regulations that shall either hamper or boost the demand for Wireless Microwave-based Antenna Monitoring System? ➑ How has the covid-19 impacted the growth of the market? ➒ Has the supply chain disruption caused changes in the entire value chain? Customization of the Report:

This report can be customized to meet the client’s requirements. Please connect with our sales team ([email protected]), who will ensure that you get a report that suits your needs. You can also get in touch with our executives on +1 346 666 6655 to share your research requirements.

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About Stringent Datalytics

Stringent Datalytics offers both custom and syndicated market research reports. Custom market research reports are tailored to a specific client's needs and requirements. These reports provide unique insights into a particular industry or market segment and can help businesses make informed decisions about their strategies and operations.

Syndicated market research reports, on the other hand, are pre-existing reports that are available for purchase by multiple clients. These reports are often produced on a regular basis, such as annually or quarterly, and cover a broad range of industries and market segments. Syndicated reports provide clients with insights into industry trends, market sizes, and competitive landscapes. By offering both custom and syndicated reports, Stringent Datalytics can provide clients with a range of market research solutions that can be customized to their specific needs.

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#Wireless Microwave-based Antenna Monitoring System Market #Wireless Microwave-based Antenna Monitoring System

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sunaleisocial · 1 month ago

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NASA Astronaut Health Technology Thwarts Heart Failure

New Post has been published on https://sunalei.org/news/nasa-astronaut-health-technology-thwarts-heart-failure/

NASA Astronaut Health Technology Thwarts Heart Failure

Prioritizing health is important on Earth, and it’s even more important in space. Exploring beyond the Earth’s surface exposes humans to conditions that can impact blood pressure, bone density, immune health, and much more. With this in mind, two NASA inventors joined forces 20 years ago to create a way to someday monitor astronaut heart health on long-duration spaceflight missions. This technology is now being used to monitor the health of patients with heart failure on Earth through a commercial product that is slated to launch in late 2024.

NASA inventors Dr. Rainee Simons, senior microwave communications engineer, and Dr. Félix Miranda, deputy chief of the Communications and Intelligent Systems Division, applied their expertise in radio frequency integrated circuits and antennas to create a miniature implantable sensor system to keep track of astronaut health in space. The technology, which was created at NASA’s Glenn Research Center in Cleveland with seed funds from the agency’s Technology Transfer Office, consists of a small bio-implanted sensor that can transmit a person’s health status from a sensor to a handheld device. The sensor is battery-less and wireless.

“You’re able to insert the sensor and bring it up to the heart or the aorta like a stent – the same process as in a stent implant,” Simons said. “No major surgery is needed for implantation, and operating the external handheld device, by the patient, is simple and easy.”

After Glenn patented the invention, Dr. Anthony Nunez, a heart surgeon, and Harry Rowland, a mechanical engineer, licensed the technology and founded a digital health medical technology company in 2007 called Endotronix, now an Edwards Lifesciences company. The company focuses on enabling proactive heart failure management with data-driven patient-to-physician solutions that detect dangers, based on the Glenn technology. The Endotronix primary monitoring system is called the Cordella Pulmonary Artery (PA) Sensor System. Dr. Nunez became aware of the technology while reading a technical journal that featured the concept, and he saw parallels that could be used in the medical technology industry.

The concept has proven to be an aid for heart failure management through several clinical trials, and patients have experienced improvements in their quality of life. Based on the outcome of Endotronix’s clinical testing to demonstrate safety and effectiveness, in June 2024 the U.S. Food and Drug Administration granted premarket approval to the Cordella PA Sensor System. The system is meant to help clinicians remotely assess, treat, and manage heart failure in patients at home with the goal of reducing hospitalizations.

“If you look at the statistics of how many people have congestive heart failure, high blood pressure… it’s a lot of people,” Miranda said. “To have the medical community saying we have a device that started from NASA’s intellectual property – and it could help people worldwide to be healthy, to enjoy life, to go about their business – is highly gratifying, and it’s very consistent with NASA’s mission to do work for the benefit of all.”

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lanterntelecom · 6 months ago

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Comprehensive Guide to Testing Equipment: Oscilloscope, Spectrum Analyzer, and More in Dubai, UAE

In the bustling metropolis of Dubai, UAE, where technology and innovation thrive, the demand for advanced testing equipment is paramount. From telecommunications to broadcasting, industries require precise instruments to ensure the quality and reliability of their products and services. This comprehensive guide explores some of the essential testing equipment available in Dubai, including Oscilloscopes, Spectrum Analyzers, Site Masters, Satellite Testers, DVB Testers, and TV Testers, with a focus on their applications and availability in the region.

Oscilloscope: An oscilloscope is a fundamental tool for engineers and technicians involved in electronics, telecommunications, and various other fields. It allows users to visualize and analyze the waveform of electrical signals in real-time. In Dubai, a wide range of oscilloscopes catering to different budgets and requirements are available from reputable suppliers and distributors. Whether you need a basic benchtop oscilloscope for educational purposes or a high-performance digital oscilloscope for advanced testing applications, Dubai offers numerous options from leading brands.

Spectrum Analyzer: In the realm of RF (Radio Frequency) and microwave engineering, spectrum analyzers play a crucial role in measuring the amplitude of signals across different frequencies. From troubleshooting communication systems to optimizing wireless networks, spectrum analyzers are indispensable tools for professionals in Dubai's telecommunications and broadcasting sectors. Leading suppliers in the region offer a diverse selection of spectrum analyzers, including handheld, benchtop, and portable models, suitable for various applications and environments.

Site Master: For professionals involved in the installation, maintenance, and optimization of RF infrastructure, a Site Master is an indispensable tool. Site Masters enable precise measurements of cable and antenna systems, helping to identify faults, optimize performance, and ensure compliance with industry standards. Site Master Dubai are readily available from authorized distributors, offering features such as cable and antenna analysis, distance-to-fault measurement, and frequency domain reflectometry (FDR) capabilities.

Satellite Tester Dubai: With Dubai's status as a global hub for satellite communications and broadcasting, the demand for satellite testing equipment is ever-growing. Satellite testers allow engineers and technicians to verify the performance and alignment of satellite antennas, conduct satellite signal measurements, and troubleshoot connectivity issues. In Dubai, specialized satellite testers tailored to the needs of the local market are available from trusted suppliers, offering advanced features such as DVB-S/S2 signal analysis, satellite constellation mapping, and spectrum monitoring capabilities.

DVB Tester Dubai: Digital Video Broadcasting (DVB) is the standard for digital television and radio transmission worldwide, including in Dubai and the broader UAE region. DVB testers are essential for ensuring the quality and reliability of digital TV and radio services, conducting compliance testing, and diagnosing signal issues. Dubai-based suppliers offer a range of DVB testers equipped with features such as MPEG analysis, RF signal measurement, and transport stream monitoring, enabling broadcasters and service providers to deliver a seamless viewing experience to their audiences.

TV Tester Dubai: In Dubai's dynamic broadcasting landscape, TV testers play a vital role in ensuring the quality of television signals and broadcast content. TV Tester Dubai allow operators to perform comprehensive testing and monitoring of terrestrial, cable, and satellite TV networks, identifying issues such as signal degradation, interference, and audio/video synchronization errors. Suppliers in Dubai offer a variety of TV testers equipped with features such as QAM analysis, channel scanning, and video quality assessment, empowering broadcasters and network operators to deliver superior TV experiences to viewers across the region.

Conclusion: From Oscilloscopes and Spectrum Analyzers to Satellite Testers and TV Testers, Dubai offers a wide array of testing equipment to meet the diverse needs of industries ranging from electronics and telecommunications to broadcasting and satellite communications. With leading suppliers and distributors catering to the local market, professionals in Dubai have access to cutting-edge testing solutions to ensure the quality, reliability, and compliance of their products and services in today's fast-paced technological landscape. Whether you're conducting RF measurements, analyzing digital signals, or troubleshooting broadcast networks, Dubai provides the tools you need to succeed in an ever-evolving industry.

#Oscilloscope Dubai #Spectrum Analyzer Dubai #Site Master Dubai #Satellite Tester Dubai #DVB Tester Dubai #TV Tester Dubai

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gqresearch24 · 7 months ago

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Exploring The World Above: A Deep Dive Into Satellite Antennas

In the vast expanse of space, communication is key to our understanding of the universe. Satellite antennas serve as the vital link between Earth and the cosmos, enabling us to transmit and receive data across vast distances. From weather forecasting to global telecommunications, these antennas play a crucial role in various industries and scientific endeavors. In this article, we delve into the fascinating world of satellite antennas, exploring their functionality, types, applications, and the future of satellite communication.

Understanding Satellite Antennas

At its core, a satellite antenna is a device designed to send and receive electromagnetic signals to and from satellites orbiting the Earth. These antennas come in various shapes and sizes, each optimized for specific purposes and frequencies. The primary function of a satellite antenna is to capture signals from satellites in orbit and to transmit signals back to them, facilitating two-way communication.

Types of Satellite Antennas

Satellite antennas can be classified based on their design, frequency range, and application. Some common types include:

Parabolic Dish Antennas: Perhaps the most recognizable type, parabolic dish antennas consist of a concave dish-shaped reflector and a feedhorn at the focal point. These antennas are highly directional and are commonly used for satellite television broadcasting and satellite internet services.

Yagi Antennas: Yagi antennas, also known as beam antennas, are composed of multiple parallel elements, including a driven element, reflector, and one or more directors. These antennas are widely used for terrestrial and satellite communication in both urban and rural areas.

Horn Antennas: Horn antennas are characterized by their flared, horn-shaped structure. They are often used for radar systems, satellite tracking, and microwave communication due to their wide bandwidth and high gain.

Patch Antennas: Patch antennas, also known as microstrip antennas, are flat, compact antennas commonly used in satellite communication, GPS systems, and wireless networks. They offer advantages such as low profile and ease of integration into electronic devices.

Applications of Satellite Antennas

Satellite antennas have a wide range of applications across various industries and scientific fields:

Telecommunications: Satellite antennas enable long-distance communication, facilitating global telephony, internet access, and broadcasting services. They play a crucial role in connecting remote and underserved regions to the global network.

Weather Forecasting: Weather satellites equipped with specialized antennas provide invaluable data for meteorological forecasting. These antennas capture images and atmospheric data, helping meteorologists track weather patterns and predict severe weather events.

Navigation: Satellite navigation systems, such as GPS (Global Positioning System), rely on antennas to receive signals from orbiting satellites and determine precise location information. These systems are used in navigation devices, smartphones, and vehicle tracking systems.

Earth Observation: Satellites equipped with high-resolution cameras and sensors use antennas to transmit images and data back to Earth. This data is used for environmental monitoring, agriculture, urban planning, and disaster management.

Scientific Research: Satellite antennas support a wide range of scientific research endeavors, including space exploration, astronomy, and climate studies. They enable scientists to gather data from remote locations in space and monitor phenomena such as solar activity and climate change.

Challenges and Future Trends

While many antennas have revolutionized communication and observation capabilities, they also face several challenges:

Signal Interference: Interference from terrestrial sources, such as radio frequency interference (RFI) and electromagnetic interference (EMI), can degrade signal quality and disrupt communication links. Advanced signal processing techniques and frequency management strategies are being developed to mitigate these issues.

Orbital Debris: The growing population of space debris poses a threat to satellites and their antennas. Collision avoidance measures and debris mitigation strategies are essential to safeguarding space infrastructure.

Bandwidth Limitations: With the increasing demand for high-speed internet and data transmission, there is a need for higher bandwidth satellite communication systems. Advances in antenna technology, such as phased array antennas and frequency reuse techniques, are being explored to address this challenge.

Looking ahead, the future of satellite antennas is poised for exciting developments. Emerging technologies such as 5G satellite networks, small satellites (CubeSats), and constellations of interconnected satellites promise to revolutionize communication, navigation, and Earth observation capabilities. Additionally, advancements in materials science and manufacturing techniques may lead to the development of lighter, more durable antennas with enhanced performance.

Advancements in Phased Array Antennas: Phased array antennas represent a significant advancement in satellite communication technology. Unlike traditional dish antennas, phased array antennas use multiple small antenna elements controlled by phase shifters to steer the antenna beam electronically. This enables rapid beam scanning, improved signal tracking, and the ability to establish communication with multiple satellites simultaneously. Phased array antennas offer greater flexibility, reliability, and efficiency, making them ideal for applications such as mobile satellite communication, military surveillance, and satellite-based internet services.

The emergence of LEO Satellite Constellations: Low Earth Orbit (LEO) satellite constellations have emerged as a disruptive force in the satellite communication industry. These constellations consist of hundreds or even thousands of small satellites orbiting the Earth at altitudes ranging from a few hundred to a few thousand kilometers. LEO constellations, such as SpaceX’s Starlink and OneWeb, leverage antennas to provide high-speed internet access to underserved and remote areas around the globe. By deploying dense networks of satellites with interconnected antennas, LEO constellations offer low-latency, high-bandwidth communication capabilities, revolutionizing the way we connect to the internet.

Conclusion:

In conclusion, satellite antennas are the unsung heroes of modern communication and observation systems. From enabling global connectivity to enhancing scientific exploration, these antennas play a vital role in our interconnected world. As technology continues to evolve, satellite antennas will remain at the forefront of innovation, paving the way for new discoveries and advancements in the realms of space exploration and telecommunications.

#SatelliteAntennas #SpaceCommunication #FutureTech #SatelliteTechnology #LEOConstellations #InterSatelliteCommunication

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marryp · 2 years ago

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digitalanand2 · 3 years ago

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Do you know the overhead crane remote control system and how it works?

Radio remote control with overhead crane:

The heavy types of equipment machines or electronic devices are moved through the artificially generated waves by the radio remote control and this wave vibrates at a particular frequency. For communication through radio waves, there are two things required that is a transmitter and a receiver.

This type of device is used to control the overhead crane, which travels and works at a certain distance above the head. The transmitter sends the signal in the form of radio waves which are received by the receiver through the antenna.

The transmitter has many buttons through which the device can be controlled in more ways like start, stop, up, down, left, right, forward, and reverse direction.

The working fundamental of hoist crane wireless remote control :

The transmitter is an electronic device that vibrates at the frequency range of 10khz to 300Ghz are called radio waves and microwaves. It is a wireless device and works on the battery or charging systems facility. The transmitter has a very strong communicating signal that can be operated from a long distance also i.e. up to 200 meters.

The crane remote control required two things for communication and they are transmitter and receiver. The transmitter is a handheld device that is operated by the operator from the ground floor used for sending the signal to the receiver. The receiver is an electronic device and attached to the overhead crane.

The receiver has an antenna towards which it receives the signal from the transmitter. The transmitter sends the signal in an encrypted form so that others cannot read the data. The receiver receives the encrypted data and decodes it for communication.

Whenever a push button is pressed on the overhead crane remote control systems the radio waves are generated and sends to the receiver. The transmitter converts the plain text into cipher text and when it reaches the receiver the cipher text is converted again back to plain text. So that the communication takes place between the transmitter and receiver safely and securely.

Interlocked featured are present on the transmitter device so that only a button can be used in the pair systems. Suppose you have pressed the forward button so the reverse button cannot be used until the forward reaches its destination.

Benefits of wireless remote control for overhead crane :

The transmitter and receiver work on the wireless systems so the overhead crane can be managed from a long distance also. The main advantage of using the radio remote control for crane is that transmitter is a handheld device and the operator doesn't have to go inside of the crane cabin to monitor and control the crane.

As we know it works wirelessly so there is no need for the wired systems and hence it is cost-effective also. The working range of the transmitter and receiver is so good that it can communicate over 200 meters also. The transmitter device automatically adjusts the power itself. That means if the receiver is near it consumes less power and if it is far then it adjusts accordingly.

Culmination:

For the present, there is more demand for the wireless radio remote control over the wired systems. As the industrial sector is booming drastically so there is also a need for industrial equipment. The radio remote control for the overhead crane is also one of them.

From the above points, we can say that the wireless radio remote control is more effective than the wired system. The wireless radio remote control provides safety and security also while communicating.

The Anand Systems Engineering Private Limited is the biggest crane remote control manufacturers in India based at the Mumbai location. The Anand radio remote is made in such a way that it provides the stability and durability for the device. The radio remote of Anand is highly optimized and customized and they are made according to the customer's need.

For the Anand crane remote features and crane remote control price you can visit the official website.

#radio remote control #hoist crane wireless remote control #crane remote control price #wireless remote control for overhead crane #overhead crane remote control systems #crane remote control manufacturers

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daisyri-me · 3 years ago

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Metamaterial Market - Forecast to Grow at a CAGR of 17.8% During 2014-2025

The global Metamaterials Market size was estimated at USD 316.0 million in 2016 and is expected to reach USD 1.35 billion by 2025, with a CAGR of 17.8%. Metamaterials are widely used in telecommunication and medical field. These materials are artificial having electromagnetic properties that may not be found in nature. The rare properties of metamaterial have led to the development of metamaterial antennas, sensors and lenses for minute wireless systems that are expected to be more efficient than other traditional systems. They exhibit a sensitive response to the dielectric media, strain, biological sensing applications and chemicals.

Metamaterials are artificial engineered materials that provide unique advantages over other conventional substitutes owing to properties that are not readily found in nature. They gain their distinctive properties from the structure of the homogeneities infused in them. Due to these factors, metamaterials have a long list of lucrative applications including invisible super lens, cloaking devices, absorbers and flat antennas which are highly impossible with traditional materials that are found in nature.

The growing demand for graphene based metamaterials in medical field is estimated to drive the market growth over the forecast period. Need for implementing wireless telemetry systems in medical field is expected to increase significantly increased owing to necessity for early diagnosis of infections or diseases and continuous intensive care monitoring of physiological parameters. Sensors and microwave antennas are major components of telemetry systems since they provide communication between the base station and patient. Metamaterials show electromagnetic properties at frequencies which is expected to attract interests form physicist and microwave engineers. These factors are anticipated to drive the market growth and provide a potential base to metamaterials in the next seven years.

Lack of inadequate customer awareness of metamaterials are expected to pose a major challenge to the global market. Technical difficulties coupled with high cost and time taken for development cycle can be attributed as major challenges to the growth of the global market.

Based on the metamaterial types, the global market is segmented into terahertz, acoustic, photonic, microwave and radio metamaterials, other types include infrared and ultraviolet metamaterials. Microwave and radio frequency electromagnetic metamaterials are expected to contribute the largest market share owing to increase in wireless broadband, mobile communications and technological advancements in communication infrastructure.

Access Sample Report of this report @ https://www.millioninsights.com/industry-reports/metamaterial-market/request-sample

On the basis of product type. The market is segmented into super lens, antennas, absorbers and cloaking devices. Metamaterial antennas are expected to have the largest market share than other segments. They provide efficient performance and size, high tunable directivity, operational efficiency coupled with improved bandwidth and radiation. The fastest growing segment is attribute to cloaking devices. These devices are stealth technology that provides objects with wholly or partially invisible properties to the electromagnetic spectrum which are widely used in defense and aerospace.

Based on the application the global market can be segmented into medical, optic, sensing, radar, telecommunication and aerospace & defense. Radar and communication were the largest application segment in 2014 and are likely to dominate the market over the forecast period. Medical imaging is expected to grow at a significant growth rate owing to various innovations and product development in this field. Optics and sensing are expected to emerge as the fastest growing markets for metamaterials over the next seven years.

Browse Full Report With TOC @ https://www.millioninsights.com/industry-reports/metamaterial-market

Key players in the global market are Applied EM, Kymeta, Teraview, Plasmonics Inc., JEM Engineering and Microwave Measurement Systems LLC. Other industry participants include Harris Corporation, Newport Corp. and Photonic Lattice Inc. Applied EM introduced tiny form factor antennas that reliably perform at low voltages and also developed enhanced electromagnetic simulation tools using asymptotic computational techniques.

Get in touch

At Million Insights, we work with the aim to reach the highest levels of customer satisfaction. Our representatives strive to understand diverse client requirements and cater to the same with the most innovative and functional solutions.

Contact Person:

Ryan Manuel

Research Support Specialist, USA

Email:

[email protected]

#metamaterial market

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electronalytics · 1 year ago

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Wireless Microwave-based Antenna Monitoring System Market

#Wireless Microwave-based Antenna Monitoring System Market #uk Wireless Microwave-based Antenna Monitoring System Market #us Wireless Microwave-based Antenna Monitoring System Market

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market-researchm · 3 years ago

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Metamaterials Industry Analysis, Growth Overview And Segment Forecasts, 2014-2025

The global metamaterials market size was estimated at USD 316.0 million in 2016 and is expected to reach USD 1.35 billion by 2025, with a CAGR of 17.8%. Metamaterials are widely used in telecommunication and medical field. These materials are artificial having electromagnetic properties that may not be found in nature. The rare properties of metamaterial have led to the development of metamaterial antennas, sensors and lenses for minute wireless systems that are expected to be more efficient than other traditional systems. They exhibit a sensitive response to the dielectric media, strain, biological sensing applications and chemicals.

Get Free PDF Sample Copy of the Report (Including Full TOC, List of Tables & Figures) @ https://www.millioninsights.com/industry-reports/metamaterial-market/request-sample

Access Full Research Report @ https://www.millioninsights.com/industry-reports/metamaterial-market

#Metamaterial Market #Metamaterials Industry #Metamaterial Market Growth #Metamaterials Market Analysis #Metamaterial Market Size #Metamaterials Market Share #Metamaterial Market Report #Metamaterials Market Research #Metamaterial Industry Outlook

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esglatestmarketnews · 3 years ago

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Metamaterial Market Opportunities, Drivers and Growth Factors till 2025

June 24, 2021: The global metamaterials market size was estimated at USD 316.0 million in 2016 and is expected to reach USD 1.35 billion by 2025, with a CAGR of 17.8%. Metamaterials are widely used in telecommunication and medical field. These materials are artificial having electromagnetic properties that may not be found in nature. The rare properties of metamaterial have led to the development of metamaterial antennas, sensors and lenses for minute wireless systems that are expected to be more efficient than other traditional systems. They exhibit a sensitive response to the dielectric media, strain, biological sensing applications and chemicals.

Request a Free Sample Copy of this Report @ https://www.millioninsights.com/industry-reports/metamaterial-market/request-sample

Browse Full Research Report @ https://www.millioninsights.com/industry-reports/metamaterial-market

Market Segment:

Metamaterials Product Outlook (Revenue, USD Million, 2014 - 2025)

• Electromagnetic

• Terahertz

• Photonic

• Tunable

• Frequency Selective Surface

• Non-linear

Metamaterials Application Outlook (Revenue, USD Million, 2014 - 2025)

• Antenna

• Absorber

• Superlens

• Cloaking devices

• Others

Metamaterials End-use Outlook (Revenue, USD Million, 2014 - 2025)

• Aerospace & defense

• Medical

• Automotive

• Consumer electronics

• Energy & power

Regional Outlook (Revenue, USD Million, 2014 - 2025)

• North America

• U.S.

• Europe

• Germany

• UK

• Asia Pacific

• China

• India

• Japan

• Central & South America

• Brazil

• Middle East & Africa

• South Africa

Get in touch

Contact Person:

Ryan Manuel

Research Support Specialist, USA

Email: [email protected]

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latestmarketresearchtrends-blog · 4 years ago

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Metamaterial Market - Latest Innovations by Industry Experts Till 2025

31st March 2021 – The global metamaterials market size was estimated at USD 316.0 million in 2016 and is expected to reach USD 1.35 billion by 2025, with a CAGR of 17.8%. Metamaterials are widely used in telecommunication and medical field. These materials are artificial having electromagnetic properties that may not be found in nature. The rare properties of metamaterial have led to the development of metamaterial antennas, sensors and lenses for minute wireless systems that are expected to be more efficient than other traditional systems. They exhibit a sensitive response to the dielectric media, strain, biological sensing applications and chemicals.

Access Metamaterial Market Report with TOC @ https://www.millioninsights.com/industry-reports/metamaterial-market

The global metamaterials market is driven by surge in wireless mobile communication, to improve the efficiency of solar photovoltaic cells and increasing investments by venture capital firms in the market. Metamaterials absorb a wide range of light with exceptionally high efficiency, which is expected to generate optical sensors and solar cells. These metamaterials can be extremely thin, saving weight and cost. Rising demand and awareness of benefits that solar cells provide to generate energy is expected to drive this technology. These materials can be extremely thin, saving both cost and weight. Lacks of inadequate customer awareness of metamaterials are expected to pose a major challenge to the global market. Technical difficulties coupled with high cost and time taken for development cycle can be attributed as major challenges to the growth of the global market.

On the basis of product type, the market is segmented into super lens, antennas, absorbers and cloaking devices. Metamaterial antennas are expected to have the largest market share than other segments. They provide efficient performance and size, high tunable directivity, operational efficiency coupled with improved bandwidth and radiation. The fastest growing segment is attributing to cloaking devices. These devices are stealth technology that provides objects with wholly or partially invisible properties to the electromagnetic spectrum which are widely used in defense and aerospace. Based on the application the global market can be segmented into medical, optic, sensing, radar, telecommunication and aerospace & defense. Radar and communication was the largest application segment in 2014 and are likely to dominate the market over the forecast period. Medical imaging is expected to grow at a significant growth rate owing to various innovations and product development in this field. Optics and sensing are expected to emerge as the fastest growing markets for metamaterials over the next seven years.

North America is expected to be the largest market for metamaterials owing to government research investments, particularly in communication infrastructure and defense sector. The intensity of active association between companies, universities and metamaterials technologies to develop various products for civilian use is estimated to drive the market demand in Asia pacific and Europe. Emerging economies such as Brazil, China, and India are highly investing in medical, defense and infrastructure to increase their economic development. Key players in the global market are Applied EM, Kymeta, Teraview, Plasmonics Inc., JEM Engineering and Microwave Measurement Systems LLC. Other industry participants include Harris Corporation, Newport Corp. and Photonic Lattice Inc. Applied EM introduced tiny form factor antennas that reliably perform at low voltages and also developed enhanced electromagnetic simulation tools using asymptotic computational techniques.

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igeotechgps · 4 years ago

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Global Positioning System (GPS)

Global Positioning System (GPS) is a worldwide radio-navigation system formed from the constellation of 24 satellites and their ground stations. The Global Positioning System is mainly funded and controlled by the U.S Department of Defense (DOD). The system was initially designed for the operation of the U. S. military. But today, there are also many civil users of GPS tracker systems across the whole world. The civil users are allowed to use the Standard Positioning Service without any kind of charge or restrictions

Global Positioning System tracking is a method of working out exactly where something is. A GPS tracker system, for example, maybe placed in a vehicle, on a cell phone, or on special GPS devices, which can either be a fixed or portable unit.GPS works by providing information on the exact location. It can also track the movement of a vehicle or person. So, for example, a gps tracker malaysia can be used by a company to monitor the route and progress of a delivery truck, and by parents to check on the location of their child, or even to monitor high-valued assets in transit.

A GPS tracking system uses the Global Navigation Satellite System (GNSS) network. This network incorporates a range of satellites that use microwave signals that are transmitted to GPS devices to give information on location, vehicle speed, time, and direction. So, a GPS tracking system can potentially give both real-time and historic navigation data on any kind of journey. GPS provides special satellite signals, which are processed by a receiver. These GPS receivers not only track the exact location but can also compute velocity and time. The positions can even be computed in three-dimensional views with the help of four GPS satellite signals. The Space Segment of the Global Positioning System consists of 27 Earth-orbiting GPS satellites. There are 24 operational and 3 extra (in case one fails) satellites that move around the Earth every 12 hours and send radio signals from space that are received by the GPS receiver.

The control of the Positioning System consists of different tracking stations that are located across the globe. These monitoring stations help in tracking signals from the GPS satellites that are continuously orbiting the earth. Space vehicles transmit microwave carrier signals. The users of Global Positioning Systems have GPS receivers that convert these satellite signals so that one can estimate the actual position, velocity, and time.

The operation of the system is based on a simple mathematical principle called trilateration. Trilateration falls into two categories: 2-D Trilateration and 3-D Trilateration. In order to make a simple mathematical calculation, the GPS receiver must know two things. First, it must know the location of the place is to be traced by at least three satellites above the place. Second, it must know the distance between the place and each of those Space Vehicles. Units that have multiple receivers that pick up signals from several GPS satellites at the same time. These radio waves are electromagnetic energy that travels at the speed of light.

A GPS tracking system can work in various ways. From a commercial perspective, GPS devices are generally used to record the position of vehicles as they make their journeys. Some systems will store the data within the GPS tracking system itself (known as passive tracking) and some send the information to a centralized database or system via a modem within the GPS system unit on a regular basis (known as active tracking) or 2-Way GPS. A passive GPS tracking system will monitor the location and will store its data on journeys based on certain types of events. So, for example, this kind of GPS system may log data such as where the device has traveled in the past 12 hours. The data stored on this kind of GPS tracking system is usually stored in the internal memory or on a memory card, which can then be downloaded to a computer at a later date for analysis. In some cases the data can be sent automatically for wireless download at predetermined points/times or can be requested at specific points during the journey.

An active GPS tracking system is also known as a real-time system as this method automatically sends the information on the GPS system to a central tracking portal or system in real-time as it happens. This kind of system is usually a better option for commercial purposes such as fleet tracking or monitoring of people, such as children or elderly, as it allows a caregiver to know exactly where loved ones are, whether they are on time and whether they are where they are supposed to be during a journey. This is also a useful way of monitoring the behavior of employees as they carry out their work and of streamlining internal processes and procedures for delivery fleets. Real-time tracking is also particularly useful from a security perspective as it allows vehicle owners to pinpoint the exact location of a vehicle at any given time. And, the GPS tracking system in the vehicle may then be able to help police work out where the vehicle was taken to if it was stolen.

Mobile Phone Tracking

The development of communications technology has long since surpassed the sole ability to access others when they are mobile. Today, mobile communication devices are becoming much more advanced and offer more than the ability to just carry on a conversation. Cell phone GPS tracking is one of those advances. All cell phones constantly broadcast a radio signal, even when not on a call. The cell phone companies have been able to estimate the location of a cell phone for many years using triangulation information from the towers receiving the signal. However, the introduction of GPS technology into cell phones has meant that cell phone GPS tracking now makes this information a lot more accurate.

With GPS technology now more commonplace in many new smartphones, this means that the location of anyone carrying a GPS-enabled smartphone can be accurately tracked at any time. Cell phone GPS tracking can therefore be a useful feature for business owners, parents, friends, and co-workers looking to connect with one another. GPS Tracking Apps (www.gpstrackingapps.com) provides a suit of Apps for the iPhone, iPad, Android, Blackberry, and the latest Samsung operating system bad all of which can be used to track one another on a location-based social networking portal or from phone to phone.

The technology of locating is based on measuring power levels and antenna patterns and uses the concept that a mobile phone always communicates wirelessly with one of the closest base stations, so if you know which base station the phone communicates with, you know that the phone is close to the respective base station.

Advanced systems determine the sector in which the mobile phone resides and roughly estimate also the distance to the base station. Further approximation can be accomplished by interpolating signals between adjacent antenna towers. Qualified services may achieve a precision of down to 50 meters in urban areas where mobile traffic and density of antenna towers (base stations) is sufficiently high. Rural and desolate areas may see miles between base stations and therefore determine locations less precisely. GSM localization is the use of multilateration to determine the location of GSM mobile phones, usually with the intent to locate the user. Localization-based Systems can be broadly divided into: • Network-based • Handset based • Hybrid

• Network Based

Network-based techniques utilize the service provider’s network infrastructure to identify the location of the handset. The advantage of network-based techniques (from the mobile operator’s point of view) is that they can be implemented non-intrusively, without affecting the handsets. The accuracy of network-based techniques varies, with cell identification as the least accurate and triangulation as the most accurate. The accuracy of network-based techniques is closely dependent on the concentration of base station cells, with urban environments achieving the highest possible accuracy. Handset Based

Handset-based technology requires the installation of client software on the handset to determine its location for E-911 purposes. This technique determines the location of the handset by computing its location by cell identification, signal strengths of the home and neighboring cells, which is continuously sent to the carrier. In addition, if the handset is also equipped with GPS then significantly more precise location information is then sent from the handset to the carrier.

This technology requires the installation of client software on the mobile phone, which acts as its biggest drawback since it’s difficult to install software on a mobile phone without the user’s consent. More importantly, the software has to be compatible with various operating systems. It requires the active cooperation of the mobile subscriber as well as software that must be able to handle the different operating systems of the handsets. Typically, smartphones, such as one based on Symbian, Windows Mobile, iPhone/iPhoneOS or Android would be able to run such software.

#gps tracker malaysia

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newinnovationalmarketresearch · 4 years ago

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Metamaterial Market 2025 Report by Global Size, Key Companies, Trends, Growth and Regional Forecasts

Metamaterial Market size was estimated at USD 316.0 million in 2016 and is expected to reach USD 1.35 billion by 2025, with a CAGR of 17.8%. Metamaterials are widely used in telecommunication and medical field. These materials are artificial having electromagnetic properties that may not be found in nature. The rare properties of metamaterial have led to the development of metamaterial antennas, sensors and lenses for minute wireless systems that are expected to be more efficient than other traditional systems. They exhibit a sensitive response to the dielectric media, strain, biological sensing applications and chemicals.

Request a Sample PDF Copy of This Report @ https://www.millioninsights.com/industry-reports/metamaterial-market/request-sample

Market Synopsis of Metamaterial Market:

View Full Table of Contents of This Report @ https://www.millioninsights.com/industry-reports/metamaterial-market

Table of Contents:-

Chapter 1 Methodology and Scope

Chapter 2 Executive Summary

Chapter 3 Metamaterial: Market Variables, Trends & Scope

Chapter 4 Metamaterial: Product Estimates & Trend Analysis

Chapter 5 Metamaterial: Application Estimates & Trend Analysis

Chapter 6 Metamaterial: End-use Estimates & Trend Analysis

Chapter 7 Metamaterial: Industrial End-use Estimates & Trend Analysis

Chapter 8 Metamaterial: Regional Estimates & Trend Analysis

Chapter 9 Competitive Landscape

Chapter 10 Metamaterial: Manufacturers Company Profiles

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xiaoquebanxiaoqueban · 4 years ago

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Application of monitoring platform in stadium construction site

[security knowledge network] the implementation of video monitoring of roads is very common in large and medium-sized cities in China. It can realize real-time monitoring of roads not only in the daytime but also at night. This is of great significance for the management of road traffic order: it can save manpower and material resources, and can realize unattended work for some intersections >lpda antenna manufacturer</a>and roads; it can also effectively prevent and control the occurrence of road traffic accidents; the video data provided by video monitoring can also provide strong evidence and materials for the treatment of traffic accidents.

1、 Overview the implementation of video monitoring of roads is very common in large and medium-sized cities in China. It can realize real-time monitoring of roads not only in the daytime but also at night. This has a very important significance for the management of road traffic order: it can save manpower and material resources, and can realize unattended work for some intersections and roads, and do the most effective work with limited human and material resources; it can also effectively prevent and control the occurrence of road traffic accidents, and ensure the safety of people's lives and property; the video data provided by video monitoring can also be used for traffic control The handling of accidents provides strong evidence and materials. Therefore, the installation of video monitoring system can not only save manpower and material resources, but also truly serve the people. It is of great significance to improve the image of traffic police, public security system and even the city.

The realization of video monitoring itself is not difficult, which is very mature in technology. Because of the characteristics of urban roads, it is difficult to realize video monitoring: unlike a factory, mine or enterprise, the scope is small, only the most difficultMore than a few hundred meters range, so the transmission part is very simple, cloth on the same axis video line can be. To achieve the monitoring of urban roads, the scope is relatively wide, usually in the range of several kilometers to dozens of kilometers. Coaxial video cable can't transmit so far, it can only transmit hundreds of meters at most. Therefore, the difficulty lies in the transmission part. How to transmit the image (and possibly sound) back to the command and control center safely, clearly and cheaply is the problem we should focus on.

Video signal transmission mainly adopts the following aspects: first, renting the line of telecom operators. Since the image signal is a signal with a large amount of data, the bandwidth of each image transmission should not be less than 1Mbps, and the monthly rent of one image is about 5000 yuan, which is obviously not cost-effective. Second, it is very unrealistic to lay optical cables by ourselves, because under the current municipal planning, it is very difficult to lay lines by ourselves in the examination and approval process. Moreover, the investment in the early stage is too large. The cost per kilometer in the city is about 10000 to 20000 yuan, which is obviously not cost-effective under the condition of tight funds. Third, through microwave transmission, we only need to place a wireless image microwave transmitting device at the monitoring point and a wireless microwave receiving device in the control center. The cost of the transmission part is only equivalent to the laying cost of one or two kilometers of optical cable, so the cost is very low. And the microwave image transmission equipment we use has been widely used in border police and traffic police, and the technology is very matureThe quality is also very reliable. In addition, the frequency band of this kind of microwave can be flexibly changed, and it can be set in the special frequency band of public security system, and it can have a certain diffraction ability, which is very suitable for use in small and medium-sized cities.

2、 Brief introduction of video monitoring system video surveillance can bring intuitive and convenient visual effects to you and your organization. It is widely used in various occasions, such as the monitoring of warehouses, important traffic arteries and other important locations of video monitoring. You can sit in your own office, you can see the real-time image situation of each important occasion of your organization; you can also handle the emergency events on the scene without leaving the office, monitor the whole process of event processing, and see the effect of the processed scene image.

You can use the following three ways to realize the video monitoring of your organization. [NextPage]

1. Analog image monitoring: composed of camera, analog codec, video matrix system, monitor, control keyboard and video recorder. When building such a system, we need to lay special video cable, power line and control line. Therefore, its disadvantages are also obvious: the transmission distance is short, generally only one or two kilometers; it can only be monitored in the local control center, and can not be monitored by important personnel in their own office; if optical fiber is used, remote transmission can be carried out, but the cost is too high.

2. Multimedia video monitoring: by camera, codec, industrial computer (or embedded equipment), andIt consists of video codec card and monitoring software. In the construction of such a system, we also need to lay special video cable, power line and control line. The computer (or embedded device) replaces the video matrix and monitor of the analog monitoring system, and the hard disk replaces the video recorder. Such a system has strong function and high flexibility. The computer (or embedded device) has Ethernet interface, which can transmit the image to the computer of relevant leadership office through Ethernet, which can be viewed at any time through authorization. The disadvantages are: it needs to lay a special circuit; the software is not open enough, so it can only be controlled on the computer (or embedded device) with special video codec card.

3. Remote video monitoring based on IP video server: you only need camera and IP video server to transmit the monitoring image to the computer network inside your organization, and any computer on the network can be authorized to watch. Managers can control the camera by moving the mouse or tapping the keyboard. Its advantage is that there is no need to lay a special line separately, which saves all kinds of complicated cables, thus reducing the cost; as long as the internal computer network of your organization can reach, the image can be transmitted to where, so you can watch the monitoring image or control the action of pan tilt and lens on any computer. The disadvantage is: must use the network cable transmission, does not apply to the organization which does not have the network resources.

3、 The selection of the scheme is based on the above analysis and descriptionIn this paper, we propose to adopt the multimedia video monitoring system with microwave transmission mode. The reasons are as follows:

1. The cost of microwave transmission mode is lower than that of renting lines or laying optical cables.

2. The microwave audio-visual transmission system we use has a certain diffraction ability, which is suitable for counties where the buildings are not very high or very dense. If there is an iron tower on the top of the command center building, it can radiate around very well.5g wifi antenna</a>

3. Due to the flexible interface of the multimedia video monitoring system, it can only be controlled by a special computer. The date and integrity of the image recorded by the hard disk can be set as unchangeable, which is suitable for the use of relevant evidence and this special condition.

4. Multimedia video monitoring system omits video matrix system and picture segmentation system, and its reliability is greatly improved compared with analog video monitoring system. It is suitable for the special system of traffic police.

4、 Networking scheme (1), monitoring site networking scheme 1, fixed lens networking scheme because once the fixed lens is debugged, it does not need the pan tilt to rotate the camera, so it only needs to transmit the scene image and sound back to the command center. The specific schematic 5g wifi antenna</a> diagram is as follows: [NextPage]

the camera transmits the image signal through the feeder line to the microwave transmitter for modulation, and then transmits it through the transmitting antenna, and the receiving antenna transmits the received image signal to the microwave receivingFinally, the demodulated image signal is transmitted to the monitor for display.

2. As the camera with PTZ needs to receive the control command from the command center to rotate the camera, or adjust the focal length of the lens to enlarge and reduce the image, the corresponding encoding and decoding equipment and wireless remote transmission equipment are also needed. The specific schematic diagram is as follows:

the camera transmits the image signal through the feeder line to the microwave transmitter for modulation, and then transmits it through the transmitting antenna. The receiving antenna transmits the received image signal to the microwave receiver for demodulation, and finally transmits the demodulated image signal to the monitor for display. [NextPage]

in the command center, the signals from the keyboard are modulated by the microwave transmitter and transmitted through the transmitting antenna. The receiving antenna transmits the received control signals to the microwave receiver for demodulation, and then transmits the control signals to the PTZ decoder for demodulation to control the corresponding actions of PTZ and lens.

3. Multi channel camera network with PTZ Because the multi-channel camera with PTZ not only needs to receive the control command from the command center to rotate the camera or adjust the focal length of the lens to enlarge and reduce the image, but also needs to compress the multi-channel video and audio signals and convert them into one image for transmission. Therefore, not only the corresponding encoding and decoding equipment but also the special multi-channel remote control audio and video switcher and audio are neededVideo wireless remote transmission equipment. The specific schematic diagram is as follows:

In the command center, the signals sent by the keyboard to control a certain camera on the scene are modulated by the audio and video switching microwave transmitter and then transmitted through the transmitting antenna. The receiving antenna transmits the received control signal to the microwave receiver for demodulation, and then transmits the control signal to the PTZ decoder for demodulation, so as to control the corresponding camera pan tilt and mirror The corresponding movement of the head. [NextPage]

(2) networking scheme of monitoring center the signal demodulated by each microwave image receiver is transmitted to the monitoring host, in which the hard disk recording can be realized, and the image can be transmitted to the large TV wall to display the images of each scene. In addition, the monitoring host also has an Ethernet interface, which can transmit the image to the internal computer network through Ethernet, and view through authorization.

（3） The overall scheme is as follows:

the overall scheme is shown in the figure below

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curegbm · 4 years ago

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GLOBAL 5G PROTEST WARNS OF HEALTH AND ECOLOGICAL COSTS

Olle Johansson, Newsvoice.se, Sep 5, 2020

The drive by tech giants to develop artificial intelligence envisages every facet of our lives dominated by 5G networks. The media paints it as the technology of the future but 5G is invading the public domain without public oversight.

By Olle Johansson, associate professor, retired from The Karolinska Institute Medical University, Stockholm, Sweden. Tanja Katarina Rebel, eco-philosopher, member of Stop 5G International, Cowes, Isle of Wight, UK. Brian McGavin, writer/environmentalist, Stockport, UK.

The costs are huge. Research by Greensill, a capital finance company, estimates that developing 5G globally will reach more than $2.7 trillion by the end of 2020. Operators paid almost £1.4bn for the UK government 5G wavelengths auction alone. When the world is reeling under the strain of a virus pandemic, a debt crisis, climate breakdown and economic collapse, how does it possibly make sense to throw so much money at a potentially harmful tech fantasy when we need to spend billions on a green transition to sustainability?

Claims that ‘we need 5G because 4G can’t cope’ conflicts with the millions spent looking for things to do with it. With growing pressure to disinvest in polluting fossil fuel companies, no such restraint is shown by 5G investors. The media is pumping up an unquestioning technology love-in with an IT sector that paints visions of driverless vehicles they claim are safer and more efficient than human controlled transport, offers ultra-fast streaming to mobile cell phones, virtual reality tech fantasies, internet-enabled fridges that can re-order your milk and even drone delivery of online orders to homes, to shatter what peace we have left in an overcrowded world.

Advocates point to areas where the technology might assist, perhaps in surgical procedures, but there is no sound evidence that autonomous vehicles are reducing collisions. A 2018 US study says driverless systems would have to improve ten-fold in detecting pedestrians, compared with humans. (Guardian, October 3, 2019).

As data from billions of internet-connected ‘smart’ devices grow exponentially, it is estimated that the IT industry could consume 20% of all the world’s electricity by 2025, straining power grids to feed an incessant demand from people hooked on phone screen entertainment. The Internet of Things promises to give us more. But more of what?

Wireless cell antennas galore. 5G will bring a huge increase in microwave radiation everywhere, in cities, suburbs, parks, nature reserves. Instead of cell towers every few miles, there will be small but powerful towers—in front of every third to fifth home.Atmospheric effects and use of fossil fuels. Instead of 2,000 satellites orbiting the Earth, there will shortly be 50,000, and permission has been granted for 100,000. These satellites have a short lifespan requiring more deployment. A new hydrocarbon engine to power a fleet of suborbital rockets would emit black carbon which “could cause potentially significant changes in the global atmospheric circulation” according to a 2010 Californian study. (Guardian, October 3, 2019).Astronomical observations, including asteroid collision monitoring, will be greatly harmed by plans to deploy up to 50,000 or 100,000 small satellites in preparation for 5G. (International Astronomical Union)Disruption of natural ecosystems. Thousands of peer-reviewed studies already show electrosmog to be harmful to public health and ecology, more so with pulsed 24/7 high-frequency radiation, which will be vastly more harmful to humans and wildlife, especially bees and other pollinators. Since 2000, reports of birds abandoning nests and reduced survival are common. (cf. Alfonso Balmori, biologist, and Exposure of Insects to Radio-Frequency Electromagnetic Fields from 2 to 120 GHz).More tree culling. The 5G Innovation Centre in Surrey says that “where trees are of comparable heights to masts, coverage can be reduced by as much as 70%.”New ‘microcomb’ cable fiber technologies are safer, 10 times more efficient than 5G and could be in wide use within three years. (Monash University).Impact on human health and our environment. Despite recent revision, the International Commission on Non-Ionizing Radiation Protection guidelines remain largely unchanged since 1998.

In 2016 The Global Union Against Radiation Deployment from Space (GUARD) wrote to US officials about the potential harm 5G will inflict – parentsforsafetechnology.orgEffects on the skin – Sweat glands may act like antennas when exposed to these wavelengths, meaning that we could become more conductive. Another study found 90% of the transmitted power is absorbed in the skin. (Dr. Ben-Ishai, Hebrew University, Israel). The skin is intimately connected to the nervous system, opening the door to an increase in neurological disorders primarily of the peripheral nervous system.Effects on plant health – millimetre waves are particularly susceptible to being absorbed by plants, which humans and animals consume as a food source; see https://www.hindawi.com/journals/ijfr/2010/836278/. Abuse of informed consent. 5G is invading the public domain without public oversight. Nowhere in its seven ‘terms of reference’ did the UK government’s consultation ‘Call for Evidence and the Road to 5G’, even mention ‘health and environmental’ concerns. It is a monumental bias to promote the tech lobby investment, oblivious to the health and ecological impact. Similar to the playbook used by tobacco, asbestos, Teflon, and other toxins, the telecom industry has neglected to disclose risks from 5G. Instead, it unabashedly asserts 5G’s safety while providing no substantive independent studies to support this claim. They are flying blind on the health and environmental effects and putting profit before people.

People are rising across the world to say no to 5G which is being rolled out without independent health or environmental impacts assessments and without informed consent, enshrined in UN Law. People should have the right to decide what kind of radiation they are exposed to and whether they want it at all without being labelled ”conspiracy theorists.” The Stop 5G movement bases its concerns about radiofrequency radiation on evidence-based independent science. Instead of peddling a one-sided ‘conspiracy’ narrative, the media needs to engage in serious debate.

On June 6, 2020, 5G protests took place across the world, including in New Zealand, Australia, South Africa, The Philippines, USA, Canada, Sweden, Norway, Denmark, The Netherlands, Ireland, Germany, Portugal, Spain, France, Greece, Bulgaria, and the UK. A new “Stop 5G Global Protest” will take place on September 26.

***

Finally, do not get us wrong. The current exposures to other sources of electromagnetic fields and signals, such as 2G, 3G and 4G, WiFi, baby alarms, smart meters, etc., are not safe. That’s the reason why we want to – in time – address the potential health consequences as well as biological impacts of the next generations, such as 5G. But we are very well understanding the need to also warn of health and ecological costs of the earlier versions.

By Olle Johansson, Tanja Katarina Rebel, Brian McGavin

References

We can point to thousands of relevant scientific reports on environmental and linked health issues, see: https://www.powerwatch.org.uk/science/studies.asp, www.EMF-portal.org at Aachen University, and http://www.bioinitiative.org.

For more information see the “Global 5G Protest Facebook Group” and “Stop 5G International”:

https://www.facebook.com/groups/548912049259423/ and https://www.stop5ginternational.org

For further reading, see:

Johansson O, ”Associate professor: Wireless radiation – the biggest full-scale biomedical experiment ever done on Earth”, Newsvoice.se 5/8, 2018a, https://newsvoice.se/2018/08/wireless-radiation-biomedical-experiment/

Johansson O, “To understand adverse health effects of artificial electromagnetic fields… …is “rocket science” needed or just common sense?”, In: Essays on Consciousness – Towards a New Paradigm (ed. I. Fredriksson), Balboa Press, Bloomington, IN, USA, 2018b, pp 1-38, ISBN 978-1-9822-0811-0

Johansson O, “Is the ‘electrosmog’ finally clearing?”, Newsvoice.se 4/2, 2019a, https://newsvoice.se/2019/02/electrosmog-clearing/

Johansson O, ”To bee, or not to bee, that is the five “G” question”, Newsvoice.se 28/5, 2019, https://newsvoice.se/2019/05/5g-question-olle-johansson/

Johansson O, Ferm R, ” “Yes, Prime Minister” Stefan Löfven, but no! This is not good enough!”, Newsvoice.se 3/5, 2020, https://newsvoice.se/2020/05/stefan-lofven-5g-microwave-radiation/

Santini R, Johansson O, ”If 5G is not deemed safe in the USA, and nowhere in the rest of the world, by the insurance industry … why is it by the Danish government?”, Newsvoice.se 8/7, 2020, https://newsvoice.se/2020/07/5g-not-safe-usa/

https://newsvoice.se/2020/09/global-5g-protest-warns-of-health-and-ecological-costs/

Joel M. Moskowitz, Ph.D., Director

Center for Family and Community Health

School of Public Health

University of California, Berkeley

Electromagnetic Radiation Safety

Website: https://www.saferemr.com

Facebook: https://www.facebook.com/SaferEMR

Twitter: @berkeleyprc

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digitalanand2 · 3 years ago

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What is Overhead crane remote control systems

What are crane and its types?

Crane is one type of machine that is used to lift and lower heavy objects with the help of hoist rope or hoist chains. And this crane can be controlled be a device called overhead crane remote control systems. Besides lifting the objects can be moved in particular directions like up, down, left, right, forward and backward. As the industrial works increasing widely so there is much more demand of cranes. And hence there are multiple types of cranes are built and they are as follows: Carry deck crane, floating crane, rough train crane, truck mounted crane, Bulk handling crane, Hammered crane, EOT crane, and many more. EOT crane is currently more in demand for Industrial purposes.

EOT crane:

EOT crane stands for Electric overhead traveling crane. The EOT crane is managed by a device called an remote control crane. With the help of this wireless remote control for crane device, the materials and objects can easily be moved from one direction to another. This hoist crane wireless remote control works on radio waves technology.

What are Radio waves?

An electromagnetic wave is a kind of visible light that travels over space and vibrates at a specific frequency. Waves vibrating at different frequencies make up the entire electromagnetic spectrum. Radio waves and Microwaves are electromagnetic waves with frequencies ranging from 10 kHz to 300 GHz. Alternating current in a conductor can emit energy at these frequencies.

Radio remote control for EOT cranes:

A Radio Remote Control for EOT cranes is a control system that uses artificially generated radio waves to control any sort of machinery or equipment wirelessly. It usually comprises a transmitter device that transmits data in the form of a radio wave in free space to a receiver through an antenna. The receiver then uses an antenna to take up this signal and decodes it.

Working Principle of industrial crane remote control system:

An Industrial Crane radio remote control system consists of two components: a transmitter and a receiver. The transmitter is a small, compact hand-held remote control. The crane receiver receives a mixture of data from each push button switch on the EOT crane remote control. This information is encrypted before being sent to the receiver. When the receiver receives the data, it decodes and decrypts it before turning on an assigned relay, which triggers the required switch on the EOT Crane Control Panel.

Communication between the Anand Transmitter and Anand Receiver occurs more than ten times per second. Many characteristics of the communication link, such as the number of tries for successful transmission, received signal strength, Link Quality Indication, missing packets, and so on, maybe continually monitored by the transmitter. To minimize interference from unwanted radio signals, Anand Transmitters and Receivers employ the Automatic Frequency Hopping technology to continually shift the broadcast frequency.

Feedback informs the transmitter whether or not the broadcast signal was accurately received by the receiver. Any defects or noise interference in the receiver might be sent back to the transmitter as well. This permits the transmitter to be constantly aware of the receiver's surroundings.

Manufacturer of Radio remote control:

Anand Systems Engineering Private Limited build the best quality of radio remote control for EOT cranes. Anand hoist crane wireless remote control are specifically designed and optimized for your Electric Overhead Crane. We provide a wide selection of Crane remote controls to achieve two goals: decrease production downtime while maintaining exceptionally high dependability and increase safety by fulfilling the highest possible safety requirements.

Anand crane wireless remote control can send and receive at full strength at a distance of more than 200 meters line of sight. Without altering any hardware, the software may be configured to have a bespoke range ranging from 10 meters to 200 meters based on customer requirements. Anand radio remote were built from the bottom up to send signals over great distances while using the least amount of power feasible.

To know more about EOT crane control panel and Anand engineering Systems private limited visit here: https://www.anandcontrol.in/radio-remote-control/anand-remote.html

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