Ground Penetrating Radar Market Share, Challenges & Opportunities 2027

The ground penetrating radar market size is predicted to grow from USD 315 million in 2022 to USD 453 million by 2027, at a CAGR of 7.5%.

As the demand for GPR increases, the demand for GPR software is also rising. The data collected and analyzed by GPR equipment and software helps deliver valuable insights to users in 2D as well as 3D formats. However, 3D GPR data provides even greater context and clarity. The features of 3D data include generating multi-scan slice overlays, rotating and zooming the data slices for analysis, providing adjustable transparency, generating depth slices, and more. Hence, all these features will help drive the growth opportunity for GPR Software in the future.

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As the military industry is evolving every day, so is the demand for detection and investigation equipment, such as GPRs, growing worldwide. The military mainly uses GPR systems to identify the location and detection of buried explosive devices. For instance, GPR is used in old sites to identify unexploded ordnance (UXO). Additionally, the common application of GPR systems in the military sector is identifying the location of embedded wires and cables in structures. The location of buried bunkers, tunnels, and caches are also areas of growing interest. In May 2020, the US Army ordered GPR systems to detect improvised explosive devices (IEDs) buried in roadways. They found their solution from Chemring Sensors and Electronics Systems (CSES) in Dulles, Virginia, and ordered to build Husky Mounted Detection System (HMDS) kits, spare parts, maintenance, and training for themselves.

GPR is considered the underground utility locator, with the ability to detect both metallic and non-metallic utilities. Underground utilities include water and wastewater transit pipes, gas pipes, water boxes, conduits, polythene, and even fiber-optic cables, which are difficult or impossible to detect by other methods. GPR also allows the detection of leakages in pipes and voids and provides the exact depth information of these damages. Moreover, GPR equipment help minimize or prevent potential damage to buried utilities, such as water, gas, electric utility lines, and communication lines, during the excavation and digging processes; any damage to these lines may result in delays, an increase in the repair or maintenance costs, and service disruption. Additionally, these equipment help detect the exact location and physical characteristics of underground utilities, which helps minimize the cost incurred by replacement parts and avoid inconvenience to the general public by enabling asset owners to provide continued services.

Telecom Power System Market Growth, Future Scope and Analysis 2027

The global telecom power system market is projected to grow from USD 3.9 billion in 2022 to USD 5.4 billion by 2027; it is expected to grow at a CAGR of 7.1% from 2022 to 2027.

The telecom power system market includes key companies such as Eaton (US), Huawei Technologies(China), Cummins (US), ZTE Corporation(China), General Electric (US), Schneider Electric (France), Alpha Technologies (US), Delta Electronics (Taiwan), ABB (Switzerland), Ascot Industrial (Italy), UNIPOWER (US), Dynamic Power Group (China), Efore (Finland), Hangzhou Zhonheng Power Energy (China), Myers Power Products (US), Staticon (Canada), Vertiv Group (US), VoltServer (US), Corning Incorporated (US), JMA Wireless (US).

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With time and understanding about telecommunication services such as voice, internet, networking, and data services, people have started adopting them at a faster pace. With the growing need for telecommunication services, they are now used in all sectors i.e., schools, offices, data centers, healthcare, etc. With the smoother work execution including better communication services, improved internet services pertaining to better file transfer in offices, etc., people have started trusting these services for their day-to-day uses and necessities. The rapid adoption of these services will lead to enhanced telecom infrastructure development in terms of more towers to provide services to more people and hence, higher demand for telecom power systems. The increasing number of wireless devices that can access mobile networks is leading to the growth of mobile data traffic. As the number of mobile devices with advanced computing and multimedia capabilities is increasing, the demand for more capable and intelligent networks is also growing simultaneously. Mobile connections are evolving from 2G network connectivity to higher-generation network connectivity such as 3G, 3.5G, 4G, and 4.5G (LTE/LTE-A).

The telecom power systems are used to avoid operational downtime and maintain a high level of power quality. As telecom power system equipment are equipped with a number of features, their costs are high. The high-end power quality equipment are equipped with various features, such as high-power efficiency and disturbance detection, and flicker detection. Thus, these equipment are expensive and have high installation costs. Moreover, the construction and maintenance of telecom towers along with the maintenance of the power system components or devices incur more operational costs as more people are deployed to maintain the sites and it requires manpower to conduct site visits, which will majorly be on the outskirts of the city. High costs of high-end telecom power equipment are expected act as a restraint for the growth of the market.

EMC Filtration Market 2023 : Analysis, Future Prediction, Overview and Forecast 2027

EMC filtration market is projected to grow from USD 861 million in 2022 to USD 1,160 million by 2027; at a CAGR of 6.1% from 2022 to 2027.

Increasing government efforts for electronic components and equipment manufacturers to comply with stringent EMC regulations will drive the EMC filtration market growth in coming years.

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The increasing adoption of automated machinery and industrial robots is propelling growth opportunities for EMC and power quality filter manufacturers. Increasing inter- and intra-communication networks on the factory floor have accelerated the demand for EMC design objectives and electromagnetic compatibility. With the growth of factory automation, plant owners are increasingly adopting EMC filtration solutions that enhance the ability of machines to operate in the intended electromagnetic environment. Moreover, EMC filters help lower the electromagnetic interference level of the equipment in facilities without significantly impacting the cost, size, and function of sorters, packers, movers, pickers, and robots. The proliferation of IIoT technology in the manufacturing sector to increase business profitability, improve production efficiency, and ensure workers' safety are driving the adoption of EMC and power quality filters.

EMC design principles are considered at the stage of equipment design, where improved mechanical designs such as cable routing and the component layout are used to reduce EMC problems. Even with efficient EMC practice, a certain amount of filtering is required. The oversimplification of EMC filters to reduce the cost and size can hamper product performance and results in a false economy. Several older EMC specifications require equipment emissions and vulnerability requirements up to 30MHz. This may require a simplified design, and a filter containing two-terminal capacitors may be sufficient to comply with these specification requirements.

HVAC Controls Market Growth, Top Manufacturers, Regions and Forecast by 2027

HVAC controls market report share is estimated to be USD 17.2 billion in 2022 and is projected to reach USD 26.7 billion by 2027; it is expected to grow at a CAGR of 9.2% from 2022 to 2027.

The major factors driving the growth of the market include the consolidation trend of smart homes, the boom in the construction sector, the emergence of IoT-enabled HVAC systems, and the need to achieve energy efficiency in buildings.

The HVAC controls market is dominated by players such as Honeywell International Inc. (US), Johnson Controls (US), Siemens (Germany), Carrier (US), and Emerson Electric Co. (US).

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Smart building technologies such as building automation are increasingly being adopted as they automate processes and reduce human intervention, improve the efficiency of the HVAC systems, eliminate energy wastage, and diminish cost. Post-COVID-19, organizations have started resuming offices. Generally, offices are huge enough to accommodate a large number of employees. Hence, the energy consumption of conventional HVAC systems and lighting is very high in offices, resulting in high operational costs as the systems are continuously being operated. Hence, companies are focusing on reducing costs by implementing smart building automation technologies, which can detect the presence of an occupant in a specific room or an area. This will enable building automation systems to operate the HVAC and lighting systems in rooms in which employees are occupied, reducing energy consumption and thereby decreasing costs.

The increased adoption of cloud computing has offered benefits for various industry sectors by providing advanced Artificial Intelligence capabilities for various applications, including HVAC. The advanced application of cloud computing and IoT is Digital twin; a real-time-based simulation of the system model, which takes real-time operational data of the HVAC system and performs simulation to reduce operational cost; provides information on the optimal maintenance schedule of HVAC equipment and perform remote diagnostics. Digital twins can help create smarter buildings by automating processes through machine learning.

The Power of Geo Radar: The Advantages of Ground-Penetrating Radar

Geo radar, also known as ground-penetrating radar (GPR), is a geophysical method that uses radar pulses to image the subsurface. It is an effective instrument for mapping and examining subterranean features and structures, such as pipes, cables, artefacts from the past, and geological formations. Numerous fields, including engineering, environmental science, archaeology, and building, use geo radar.

Geo radar operates on the fundamental tenet that radar pulses are transmitted into the earth and recorded in order to produce an image of the subsurface. The system makes use of an antenna that is buried in the earth, as well as a transmitter and receiver that are placed on the surface of the ground. The radar waves are transmitted and received by the antenna, and the data is then processed to produce a picture of the subsurface.

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Geo radar's ability to find items and structures buried underground without the need for excavation is one of its main advantages. It can be used to map the locations of pipes, cables, and other underground infrastructure, making it a useful tool in building and engineering projects. It can also be used to find possible dangers like hidden tanks or other things that might endanger workers.

Geo radar is helpful for mapping subterranean aquifers and spotting possible groundwater contamination in environmental science. Additionally, it can be used to map subsurface geology, which aids in understanding an area's geological past and aids in the prediction of geological dangers, such as landslides or sinkholes.

Geo radar can also be used in archaeology to map buried buildings and relics, which is another use for the technology. Additionally, it can be used to locate prospective excavation sites, eliminating the need for lengthy and pricey excavations.

Geo radar is a flexible and effective instrument for imaging the subsurface. It has a wide range of uses in many different fields, including engineering, natural science, and archaeology. The capabilities of geo radar are anticipated to grow as technology develops, making it an even more useful instrument for comprehending and mapping the subsurface.

The Key to Reliable Telecommunications: Telecom Energy Systems Explained

Modern communication and commerce depend on telecommunications networks, which require a dependable energy supply to run continuously. Telecom Energy Systems (TES) are useful in this situation. For telecommunications infrastructure, these systems offer a dependable and effective source of energy, guaranteeing continuous data transmission and communication.

Batteries, rectifiers, and power processors are among the common parts found in TESs. In the event of a grid failure, the batteries provide backup power, and rectifiers transform the grid's AC power into DC power that powers the elecommunications devices. The equipment is always supplied with the proper quantity of power thanks to the power controllers, which control the flow of power to it.

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A TES's ability to provide backup electricity in the event of a grid failure is one of its main advantages. For internet networks that must run continuously, this is essential.Having a trustworthy secondary power source is crucial because a power outage can cause lost income, data loss, and other issues.

A TES can also lower energy expenses, which is an added bonus. Due to the constant need for power, telecom equipment can have expensive energy costs. A TES can offer a more effective power source, lowering energy expenses and enhancing the network's overall sustainability.

In off-grid locations without access to power, TES is also crucial. The TES serves as the main power source for the communications network in such areas. The TES is the best option for telecommunications infrastructure in rural areas because it is made to function in remote places.

In general, TES is an essential part of contemporary information networks. It offers a dependable and effective supply of power, guaranteeing continuous data transmission and communication. Additionally, it lowers energy expenses and increases the network's sustainability. The need for TES will only grow as the telecommunications sector continues to expand, making it a crucial tool for communication in the future.