The aviation industry has been working on the more electric aircraft for the past decade. Some of the more electric aircraft include Airbus 380, Boeing 787, Airbus 350, and the F-35 JSF. The sector is focusing on developing hybrid-electric, turbo-electric, and all-electric aircraft. These aircraft will require light, efficient, and high-power density motors that will be suitable with the weight and size constraints of an aircraft, mainly for architecture that uses multiple distributed fans to obtain high propulsive efficiency. In addition to high power density motors, the hybrid-electric and turbo-electric architectures will also need light, efficient and high-power density generators that convert shaft power to electricity, together with an intermediate, lightweight gearbox which will reduce the turbine’s high rotational speed to a slower rate suitable for a generator.

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The non-propulsive aircraft systems such as actuation, de-icing, and air-conditioning have been relying on mechanical, hydraulic, and pneumatic sources of power. These systems have conventionally been powered by the aircraft engines, with power generated through various mechanisms such as hydraulic and electric systems, which gain power from mechanical conversion through the engine gearbox, whereas pneumatic power is generated by engine compressor air bleed systems.

In a more electric aircraft (MEA), the aircraft employs more electrical equipment in place of systems that would earlier have been mechanical, hydraulic, or pneumatic. The B737 became the first aircraft which introduced electrical cabin equipment and avionics. After this, MEA trend followed the introduction of the fly by wire (FBW) system in the Airbus A320 in the late 1980s. This MEA concept then led to the introduction of the A380 and the employment of an electrically actuated thrust reverser, along with hybrid electro-hydraulic actuation systems for wing and tail flight control surfaces. After this, the XX became the first large commercial aircraft to have an electrically powered environmental control system (ECS) and to implement electrically actuated brakes, as well as electrical de-icing.

The more electric aircraft will increase the adoption of whole aircraft electrical power systems such as energy storage and recovery systems, high voltage battery systems, and fuel cells. Some of the alternative energy storage technologies include fuel cells, liquid air, compressed H2 or liquid H2, ultra-capacitors, or mechanical flywheels. Fuel cell systems have been explored recently for transportation applications for the purpose of on-board power generation. By replacing the main engine generators, fuel cell systems can be the solution for increasing demands of electrical power capacity with their major benefits such as higher fuel efficiency, lower to nil emissions, direct current generation, decentralization of power generation, and potential water recovery.

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The increase in air travel has made air passengers pay more attention to their travel comfort experience during flights. Aircraft manufacturers and cabin system providers such as Airbus, Boeing, Safran (Zodiac Aerospace), Thales, Honeywell, and UTC are focusing on providing cutting edge technology for cabin systems. For instance, in 2019, Airbus has begun in-flight trials of connected cabin technologies, applying IoT (Internet of Things) technology onboard an A350-900 Flight Lab aircraft.

The emerging strategies and developments by major stakeholders have resulted in the development of products in the market. Moreover, the market growth is further expected to attract the involvement of leading aviation companies across different segments of the value chain. The key players that are actively participating in the more electric aircraft market include Boeing, Thales, Raytheon Technologies (previously United Technologies Corporation), TTTech Computertechnik AG, Safran, Lockheed Martin, Rolls Royce, Israel Aerospace Industries (IAI),  Honeywell International, Inc., GE Aviation, Elbit Systems, BAE Systems, Bombardier, Astronics, and Airbus, among others.

The advancement in radar technology is mainly driven by two factors: the use of machine learning algorithms to enhance the raw radar signals, and advancements in silicon technology leading to miniaturization. The applications of radar technology such as weapon guidance, airspace monitoring and traffic management, ground surveillance and intruder detection, air and missile defense, navigation, mine detection and underground mapping, airborne mapping, ground force protection and counter battery, and weather monitoring have been grown multi-fold in recent years in the military and defense industry.

The latest 3D & 4D radars are expensive to develop, and hence many developing countries lack the funds to invest in the development of such radar systems. In 2014, the U.S. allocated $XX billion for the development and installation of missile defense radars in Alaska. Most of the 3D & 4D radars are multi-functional radars that offer more than one application. The budgetary constraints and the incapability of developing radar systems indigenously by several nations act as a roadblock in the growth of this market. Hence, some companies are trying to develop smaller, short-range radars cost-effective. However, the high cost of equipment and components such as sensors, transmitters, receivers, and systems are making it difficult for smaller developing and underdeveloped nations to procure the latest, technologically advanced radar systems. Apart from procurement costs, installation and maintenance costs are also pretty high.

The threats to civilian and military assets are accelerating in diversity, ferocity, and volume every day. Thus, the militaries of various countries require advanced radar systems that can adapt to a changing landscape and help in crucial missions. Manufacturers are also focusing on developing a wide range of software-based radar systems that are upgradeable, durable, and reliable to thrive in the digital age. These next-generation digital radar systems have the ability to neutralize and detect threats that have not been imagined yet.

There has been a significant rise in the interference activities among hostile nations, which has resulted in growing interest and escalating demand for integration of advanced radar technology with different military platforms such as airborne, ground, and naval across the globe. Due to increasing military budget inflows across the globe and growing conflicts among various countries, the demand for more robust positioning, navigation, and 3D & 4D military radars are in substantial demand.

The rise in the number of military programs and growing military budgets have resulted in growing interest in the development and deployment activities of 3D & 4D military radars by various military agencies across the globe. Growing military budgets have provided a much-needed boost to the procurement programs of different platforms with integration of these advanced 3D & 4D radar solutions. The U.S. has dominated the  3D & 4D military radars market, with a military budget of $718 billion for FY2020. In April 2020, Lockheed Martin Corporation supplied the first Q-53 radar system integrated with Gallium Nitride (GaN) to the U.S. Army. This critical upgradation enables U.S. Army to enhance its capabilities to meet changing mission demands. GaN offers additional power with enhanced capabilities, such as counterfire target acquisition (CTA), extended range, and multi-mission, to radars.

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The global 3D & 4D military radars market is expected to witness significant growth during the forecast period 2020-2025 owing to the rise in the integration of these radars on different platforms including ground defense systems (combat tanks, and multi-purpose armored vehicles), airborne (unmanned aerial vehicles and combat aircraft), and ship-based platforms. Additionally, the decline in cost and miniaturization will drive the deployment and integration of 3D & 4D military radars systems.

The key players that are actively participating in the 3D & 4D military radars market include Thales Group, Northrop Grumman Corporation, Lockheed Martin Corporation, Saab AB, Leonardo S.p.A., Raytheon Technologies, BAE Systems, Mitsubishi Electric Corporation, L3Harris Technologies, Inc., Bharat Electronics Limited, Hensoldt, Israel Aerospace Industries, Airbus S.A.S, and government agencies, among others.

The C5 and ISR operations are integrated together to perform as a whole. C5ISR technologies provide real-time data to the commanders in the battlefield that enhances their situational awareness and provide support in the process of decision making. In addition, these systems turn complex data into knowledge for commanders. C5ISR technologies enable the users to achieve different set of missions, i.e., on the ocean’s surface, air, land, and space. C5ISR integrates all the four platforms (air, land, naval, and space) enabling interoperability and maximum utilization of the military assets.

Global C5ISR systems market has gained widespread importance in military operations due to increasing political conflicts, migrations issues, and extensive defense modernization programs. Growing market for space-based C5ISR systems and increasing demand of AI in C5ISR systems for military operations are likely to increase opportunities for C5ISR systems. However, difficulties in maintenance of C5ISR systems and subsystems and interoperability issues are expected to hamper the overall growth of C5ISR systems market.

The competitive landscape of the C5ISR systems market includes different strategies undertaken by the manufacturers to gain market presence. Some of the strategies adopted by C5ISR systems manufacturers are product launches and developments, partnerships, agreements, and contracts, mergers and acquisitions. Among all the strategies adopted, partnerships, contracts, and agreements have dominated the market and is the most widely adopted strategy among the C5ISR systems manufacturers.

The C5ISR systems market is a highly competitive industry, with all the players competing with each other to gain a greater market share. Most of the C5ISR systems manufacturers are of similar financial capability and the landscape is extremely competitive because of a large number of established players in the market. Therefore, innovation and development have been the key for gaining growth in this market. To increase the global footprint, C5ISR systems manufacturers are also entering into mergers and acquisitions to strengthen their product portfolio.

Raytheon, Lockheed Martin, Northrop Grumman, Elbit Systems, and BAE Systems are some of the prominent companies which have remained in the limelight because of their wide range of product launches and partnerships, collaborations, contracts, & agreements.

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Some of the other key players contributing to the C5ISR systems market includes Israel Aerospace Industries, Elbit Systems, General Dynamics, L-3 Communications, The Boeing Company, Harris Corporation, and Leonardo DRS. These companies offer a broad product portfolio for specific needs in defense applications. The geographical presence of these companies are mainly concentrated in the U.S. and the European region. With ongoing efforts of industry players to develop high-end solutions for different end users, the C5SIR systems market is anticipated to grow at a robust pace in the years ahead.

C4ISR technologies had been used in every major conflict since radio communications started in the 19th century. C4ISR systems techniques came into existence in World War II and played an important role in modernizing warfare. Furthermore, C4ISR technologies have been witnessing major advancement with the evolution in technology over time. The whole implementation and exercise of this technology lie in strengthening one’s defense system, which sometimes act as a strength in maintaining global harmony whenever any conflict arises. Moreover, currently C5ISR systems are being used which are updated version of C4ISR systems having better response time and efficiency.

Video analytics has the ability to reduce the huge amount of data available in the video, thus making it more controllable. The benefits of video analytics include reduced load on network and storage demand, easy and fast retrieval of stored video, and productive use of manpower, among others. Moreover, in case of any abnormal activity, the system raises an alarm to alert the concerned officials. Additionally, with the advantage of analyzing live as well as recorded data, the need for reviewing the recorded data by a human operator, which is a quite expensive resource, has been eliminated. These features, along with the numerous technological advancements, such as facial recognition and automatic license plate recognition, make the video surveillance cameras appropriate for application in different verticals, especially in the current scenario. Therefore, with the help of VSaaS, and video analytics, the time and monetary benefits can be availed by the installer. Bosch Security Systems and Honeywell are some of the major market players providing video analytics-based solutions. Below are some instances which highlight the demand for VCA and VSaaS.

The video surveillance market has been witnessing a rapid transition from analog-based surveillance systems to digital or networked systems. In digital surveillance, the use of higher resolution cameras for high definition images implies better and more detailed video evidence. However, large and detailed images require appropriate technical solutions to efficiently store the videos which must be accessible as and when required. In this section, the presently available storage technologies and their impact on a surveillance system design have been discussed. Various players, including VMware, Microsoft, and Xen, are providing constant support for using storage area networks (SANs), direct-attached storage (DAS), and network-attached storage (NAS), which in turn foster the growth of the market. Further, many industries are expanding into businesses to cover many applications, including business intelligence, enterprise resource planning, supply chain reengineering, and customer relationship management. Such expansion requires reliable storage systems which able to protect and manage critical information. Thus, it is expected to create a large demand for IT solution providers to offer enhance storage services for efficient work of these businesses.

One of the major factors that has led to the increasing adoption of these video surveillance systems has been the rise of IP camera-based solutions. This can be attributed to the fact that it allows the users to convert their local broadband connection into a home surveillance system. These cameras provide several benefits compared to traditional analog cameras, such as low cost and high durability. Further, IP cameras provide high-resolution images and wide-angle video capturing feature and also allows authorized access to live and recorded video footage on smartphones and tablets. One of the major benefits of using IP surveillance systems has been cloud storage, which makes the video surveillance system more effective. With the rise of built-in wireless connection, the IP cameras have become subtle and discreet, avoiding unnecessary attention. Since these cameras run on Wi-Fi signals, the problem of interference or loss of network in the transmission wires has been eliminated.

Increasing competitive advantages of video surveillance over conventional physical surveillance techniques have made video surveillance an essential system for homeland security and commercial applications. Factors such as low operation cost, rapid deployment, and large coverage area of surveillance cameras have led to an increase in its adoption in defense and infrastructure sectors. Moreover, do-it-yourself (DIY) methods of video surveillance has facilitated the wider adoption of video surveillance systems by the homeowners. Additionally, the growing coverage of Internet of Things (IoT) ecosystem enables the consumer to monitor the video footage of his/her house/object over the virtual network through gadgets.

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The cloud-based analytics offers intelligent video services without the need for additional hardware or licensing fees. The data coming from different locations through a single web-based interface is analyzed at one place. Since analog cameras work with digital video recorder (DVR) storage technology, they cannot highlight any event. In case of a crime detection event, it might take a longer period of time to play or analyze the full video. However, an IP system with video analytics can highlight or flag events with functions such as motion detection, camera tampering, and a range of other events.

The growth of the directed energy weapon systems market is majorly due to the factors such as the impending need for the modernization of defense forces, strengthening deterrence capability against rising threats from weapons like drones, mortars and missiles. Moreover, the increasing capital expenditure in the field of optics and lasers drive the market of directed energy weapon systems.

On account to counter cross-border conflicts, infiltration and terrorist activities, the government and defense forces of leading countries are focusing on allocating defense budget for development of advanced laser and microwave weapon system. Countries such as the U.S., U.K., China, India, Japan, Germany, South Korea, and France are actively engaging in development activities of directed energy weapon systems with private and public defense equipment manufacturing companies.

The directed energy weapon systems market has witnessed different market dynamics across various regions of the globe. Moreover, the key directed energy weapon systems manufacturing companies have witnessed a rising demand from countries such as the U.S., the U.K., China, and India. Major defense companies around the globe are headquartered in this region, leading to high revenue generation in North America. However, the presence of major players and intense competition among them makes North America the most technologically advanced region. The companies in the region have signed contracts with the U.S. Army and armed forces to provide directed energy weapon systems over the recent years.

The demand for directed energy weapon systems is based on the country’s sustained investment in research and development programs. Additionally, U.S Department of Defense (DoD) has given various contracts to defense contractors for the development of prototypes of high energy laser weapons and high energy microwave weapon systems. The U.S. was the first country to test and demonstrate high energy laser and microwave weapons. Even in 2010, U.S. Army deployed Active Denial System (ADS) in Afghanistan but withdrawn without been used. Moreover, U.S. Department of Defense (DoD) has requested $XX million for Implementation of directed energy for base defense, testing and procurement of multiple types of lasers and R&D for scalable high-power density applications. Growing demand of directed energy weapon systems in U.S. is underpinned by the ramp-up production of prototypes for high energy laser and microwave weapons.

There have been significant developments in the field of directed energy weapon systems resulting in growing interest and escalating demand for deployment of these advanced weapons by military forces across the globe. Due to increasing military budget inflows across the globe due growing conflicts among various countries, the demand of cutting-edge technologies such as laser and microwave weapon are in substantial demand. The directed energy weapon systems are developed with the aim of countering the growing threats from unmanned aerial vehicles, mortars, missiles, and small boats at a low engagement cost. Key advantages of directed energy weapon systems are their high speed, precision, flexibility, and low operation cost.

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The need for enhanced border security due to increasing land disputes, migration, and smuggling, has compelled several countries to further strengthen their security. This has led to the increase demand in the development of advanced directed energy weapon systems to provide enhanced situational awareness to the soldiers so as to have a competitive edge over the opponents. With recent developments in the field of optics, laser and microwave technology, directed energy weapon systems are becoming available at a reliable cost.

The major driving force behind the growth of the directed energy weapon systems market is largely attributed to the increase in the number of defense programs related to directed energy weapon systems and associated investments. Laser Developed Atmospheric Lens (LDAL) system is a technology which is currently in a phase of research and development. Defense technology companies like BAE Systems is working on development of LDAL technology. The prime objective for the development of this technology is to safeguard friendly troops, aircraft, ships, and land vehicles from attacks from high-power laser weapons. With the help of this technology, LDAL system can be capable to temporarily alter the atmosphere into lens-like structures capable of redirecting Electro Magnetic (EM) energy, including light beams and radio waves.

Robot Operating System (ROS) is a meta-operating system for robotics which is something in between operating system and middleware. It provides high level functionalities apart from standard operating system services such as synchronous and asynchronous calls, robot configuration systems, centralized database, and so on. Prior to the existence of ROS, every robotic researcher and robotic designer spent a considerable amount of time on designing the embedded software within the robot, which demanded skills in electronics and embedded programming apart from mechanical engineering. The major idea of robotics OS is to offer standardized functionalities such as performing hardware abstraction, similar to conventional OS for PCs. ROS combines expertise from different disciplines as the field of robotics generally demands people to have diverse skill sets. Most of the existing OS are developed for a specific purpose, however, ROS is a general purpose OS. Nevertheless, it is not capable of carrying out every task. Hence, a proliferation in adoption of open source operating system in industrial and service robot in order to reduce development cost for robotic applications, has been witnessed.

Robots are the machines which automate the tasks that are usually carried out by humans. Initially, there were very few robots that were introduced into the manufacturing sector for performing some of the repetitive manufacturing operations. Gradually, other industries realized its potential across various applications that help the humans to save time and energy. In the mid of 20th century, there was a rapid surge in the demand of production and the industrial revolution was at its peak. Lack of labor forced industries to employ machines to perform tedious and repetitive jobs which could be performed with present instructions and negligible human interactions. The requirement of such machines led to the invention and popularization of numerically controlled devices.

The global robotic industry has experienced rapid technological advancements over the decades. Robots are considered to be the most valuable asset and have been used for various industrial as well as commercial applications. The robotic industry mainly caters to two types of applications i.e. industrial and service segments. Industrial segment includes automotive, electrical/electronic, metal and machinery, rubber and plastic, food and beverages, pharmaceuticals and cosmetics, and others whereas the service segment includes applications such as logistics and warehouse, public relations, defense and security, healthcare, agriculture, entertainment, household, and other such applications.

The first mechanized human-like figures were made in Greece. Ancient Greek engineer named Ctesibius developed water clocks in around 270 B.C. using automatons or loose figures. However, robots that mimicked lifelike behavior were first developed in 1948 by British robotics pioneer William Grey Walter and he named them Elmer and Elsie. In 1954, “Unimate”, the first programmable and digitally-operated robot was invented by George Devol. In 1961, this robot went online in New Jersey in the General Motors automobile factory. Today, robots are being widely used for a number of purposes for carry out tasks more accurately, reliably, and cost effectively than humans.

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The introduction of robots in manufacturing industry has rapidly transformed the process of production, further leading to a growing demand for more automated solutions (both hardware and software) to increase the visibility into the manufacturing process for increasing the production and decreasing the production cost. According to World Robotics report 2018, published by International Federation of Robotics, the total number of industrial robots sold in 2017 is approximately 381,000 which is 30% more than that in the previous year. This is expected to reach 630,000 units by 2021.

The global space economy has been growing at a rapid pace owing to the increasing requirement of satellite-based connectivity services across different applications such as communication, navigation, Earth observation and others. The global space economy was worth more than $400 billion in 2018, out of which, 76% was generated through services such as earth observation, telecommunication, remote sensing, satellite TV, GNSS equipment, satellite systems, and others. This burgeoning growth in the overall space industry is driving the growth of ground stations which offer satellite connectivity.

There has been an emergence of market players that are employing new business models in space ground stations. Companies such as Amazon, Infostellar, Copernicus Space and BridgeSat, have entirely transformed the way ground station business was perceived in earlier times. For instance, in May 2018, Amazon initiated ground station-as-a-service model wherein, it allows its users to download the information from multiple satellites. In this way, the company is promising to provide an easier and cost-effective experience to attain analyzed and integrated data from AWS platform. Similarly, BridgeSat is revolutionizing the ground station industry by offering laser terminals over traditional radio frequency-driven ground terminals. According to BridgeSat, these ground stations are cheap and can be operated with better performance as compared to traditional terminals. BridgeSat has acquired multiple contracts from satellite operators to develop laser ground stations. For instance, in May 2018, the company received a contract from ICEYE, to develop low-cost and innovative terminals. Japan-based company named Infostellar is also designing a cloud-based platform which will allow the user to share the antennas at various ground stations, described as Airbnb for satellites. Such advancements in the technologies are expected to drive huge growth in the global space ground station equipment market.

With the huge growth in the small satellites, there has been emergence of new companies which are investing in the development of ground station network for small satellites. For instance, Leaf Space, an Italy-based company founded in 2014 has four operational ground stations in Lithuania, Italy, Ireland and Spain as of November 2019, and is planning to expand it further to 20 ground stations by late 2020. These stations are expected to cater to microsatellites in LEO. Similarly, Copernicus Space, an Australia-based start up founded in 2018 is establishing ground station network which will cater to small satellites in LEO and MEO. Not only new startups, but established companies are also focusing to develop ground station infrastructure for small satellites.

Space ground station is equipped with a number of equipment broadly classified into consumer and network segment. Consumer is the dominant segment in the market and includes satellite navigation equipment, broadband equipment, dish antenna, satellite radios and mobile satellite terminals. Whereas, network segment is anticipated to witness the highest growth during the forecast period owing to increasing number of satellites which will consequently require higher number of ground station or small earth station, globally. Network equipment segment is further categorized into network operation center (NOCs) equipment, VSAT equipment, antennas, power units, gateways, and test and monitoring equipment.

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Space ground station equipment cater to different end users such as government and military, commercial, consumer, and enterprise. Consumer is the dominant segment in the market due to high adoption of satellite dish and navigation equipment. Whereas, enterprise segment is anticipated to witness the highest growth during the forecast period owing to anticipation of high adoption of satellite terminals which will enable them to incorporate automation with seamless flexibility to switch between terrestrial and satellite connectivity.

Global agriculture industry has undergone significant and dynamic changes in the past decades, specifically with the introduction of technologies introduced to improve crop yield. With the increase in world population leading to the rise in the global demand for food, growers are prompted to adopt the most advanced and productive methods in farming operations to increase crop yield. One of new-age methods applied for increase in production is the new efficient mode of farming known as precision agriculture. This way of farming has resulted in creation of large number of data points leading to the growth of data-driven farming. Consequently, the growers and consumers of agricultural products are left with complex big data to analyze. The analysis for this data  has prompted the need for cognitive computing with human-like intelligence in farm equipment and solutions based on such computing to yield healthier crops, as well as to monitor crops and soil conditions, control weeds, aid with farm workload, optimize data for growers, and enhance the farm operation efficiency. The set of cognitive computing technologies introduced in agriculture for the said purpose is known as artificial intelligence technology.

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Precision agriculture encompasses several technologies such as guidance technologies, sensing technologies, analytics, and other precision technologies that reduce the misutilization of agri-inputs and enable efficient farming with profitability. Introduction of precision agriculture technologies has also resulted in the creation of hundreds of thousands of data points on farms. The rise in these data points has enabled data-driven farming, aiding the growers and consumers of agriculture products with insight-backed decision-making. However, the abundance of these data points has also left the agriculture industry plagued with massive amounts of data. To navigate through these big data in farms and to attain efficient farming solutions, the industry is bringing about significant product innovations in farm data analysis using the artificial intelligence technology.

Artificial intelligence technology brings the concept of cognitive computing to agriculture where the farm equipment intelligence is modeled on human intelligence. The capabilities enabled by this technology allow the farm equipment and solutions to interpret, acquire, and react to unpredictable farm situations with enhanced efficiency. Artificial intelligence technologies help farmers in optimizing their planning to generate profitable crop yields using predictable analytics for agri-input choices and farm process planning. For instance, AI technology has found use cases in crop disease detection, crop growth assessment, and crop yield prediction, preventing over-application of fertilizers and other agri-inputs. The forecast of results for these agricultural processes in the market are powered by AI sensors and imaging equipment. The presence of these AI-based software and hardware products and services in the agriculture market has led to an optimistic growth of the precision agriculture market.

Originally, artificial intelligence in the agriculture industry had been offered as a software platform. However, since past three years, a new pricing model and mode of product offering has emerged where the solution providers are billing the customers on the amount of artificial intelligence capability used including AI-based hardware and software. This pricing and business model are popularly termed as AI-as-a-Service (AIaaS). Presently, the AI companies in agriculture also offer support services as product offerings.

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Agriculture technologies are offered for a host of agriculture applications and cover the entire farming cycle including data management, soil management, yield mapping, as well as monitoring, spraying, harvesting, and planting, among others. Adoption of agriculture technologies across the globe has resulted into the rapid accumulation of a large amount of agricultural data on farm operations and fields. Management of this big data for increased accuracy, productivity, and reduced manual data feeding has become a pressing requirement. Hence, the advent of artificial intelligence in the agriculture sector is welcomed by the growers and other agriculture customers, as AI technology has been critically used to optimize agricultural operations based on this data and has found innovative use cases and applications. Predictive analytics is one of the most deployed use cases of AI in agriculture, where it aids in efficient farm production with reduced losses.

The metal 3D printing industry landscape is very competitive because of the large number of players in the market. Innovation and development have been the key factors for large scale growth in this market. To increase their overall global footprint, companies are also entering into mergers and acquisitions in addition to the partnerships and collaborations to target a greater audience.

The metal 3D printing market has been impacted to a certain extent due to the advent of the pandemic COVID 19. Although the technology is capable of producing in-house objects in quick time, without much dependence on the supply chain of raw materials, the market has got impacted due to the unequal availability of the metal powders and metal 3D printers in some regions of the globe. For instance, as per 2019 data, Australia holds the maximum reserves for titanium in the world, but the country has limited availability of metal 3D printers compared to the countries such as the U.S. and Germany. This can potentially lead to the disruptions in 3D printing of titanium.

Due to the global lockdown, which has highly disrupted the logistics, the free flow trade of the materials related to metal 3D printing, which prevailed before the pandemic, has been completely disturbed. As a result of this, there has been an unevenness in the availability of metal powders and metal 3D printers across some countries of the globe, which has impacted the smooth business operations of metal 3D printing globally.

In terms of the adoption of metal 3D printing from the end-use industries, there has been a sharp change as the major adopters (before the advent of the pandemic) such as aerospace, defense and automotive have been badly hit which has drastically impacted the adoption trend of this technology. However, there has been almost no significant change towards the adoption of metal 3D printing in the medical and healthcare sector as the demand for the 3D printed surgical tools and bio-implants could be easily met with this technology due to its capability of in-house production of objects in very short notice, thus maintaining the demand-supply balance with great ease.

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However, amidst all these positives, one area of concern is that the medical sector has been mostly adopting titanium (Ti64) for its implants due to the low toxicity of the alloy, the disruption in 3D printing of titanium could have an impact on the medical industry at the current hour of the pandemic. Thus, the adoption of metal 3D printing toward the medical sector is expected to remain slightly sluggish during the COVID-19 period (2020-2022) and is expected to get back to grow at normal rates during the period (2023-2025). The same holds true for the other end-use industries such as aerospace and automotive sectors, remaining sluggish for (2020-2022), which are expected to return to their normal growth states post COVID-19 during the period (2023-2025).

Till date before the advent of the pandemic COVID-19, North America has been dominating the global metal 3D printing market with the U.S. as the prime country (in terms of adoption) in this region. However, the pandemic has hit this region hardest with the U.S. topping the death tolls globally. Also, all the highly demanding aerospace and aviation projects for this technology have come to a temporary halt. This is expected to cause major disruption in the regional adoption of metal 3D. As a result, the market of North America is expected to remain sluggish for the period (2020-2022) and is assumed to gain normality from 2023, post-COVID-19.

The video surveillance market research study offers a wide perspective on the analysis of the industry. The research is based on extensive primary interviews (in-house experts, industry leaders, and market players) and secondary research (a host of paid and unpaid databases), along with the analytical tools that have been used to build the forecast and the predictive models.

The increase in security concerns and the growing need for highly efficient, time-saving surveillance systems at reasonable costs, is one of the matters to be looked upon in the current scenario. The attempt to deliver such solutions with the growing application across many verticals is considered as one of the major drivers for the video surveillance industry. With the increasing security concerns, along with rising initiatives by the government to spend on surging digitization and smart cities, the number of cameras being used for video surveillance is also increasing. The governments of various nations are deploying video cameras on a massive scale in order to create stronger security systems for their respective countries. These video surveillance systems provide various benefits, such as asset and theft protection, remote monitoring services, gathering evidence to help legal authorities to arrive at the right decisions, increased workplace productivity, and traffic management via automatic license plate recognition. Some private sectors, including banking and finance, hospitals, research labs, sports facilities, corporate headquarters, and auditoriums also require cutting-edge video surveillance technology with improved security features whereas commercial and residential sectors may require cost-effective and efficient cameras solutions, such as zoom-specific cameras and low-light cameras.

Video analytics has the ability to reduce the huge amount of data available in the video, thus making it more controllable. The benefits of video analytics include reduced load on network and storage demand, easy and fast retrieval of stored video, and productive use of manpower, among others. Moreover, in case of any abnormal activity, the system raises an alarm to alert the concerned officials. Additionally, with the advantage of analyzing live as well as recorded data, the need for reviewing the recorded data by a human operator, which is a quite expensive resource, has been eliminated. These features, along with the numerous technological advancements, such as facial recognition and automatic license plate recognition, make the video surveillance cameras appropriate for application in different verticals, especially in the current scenario. Therefore, with the help of VSaaS, and video analytics, the time and monetary benefits can be availed by the installer. Bosch Security Systems and Honeywell are some of the major market players providing video analytics-based solutions. Below are some instances which highlight the demand for VCA and VSaaS.

The cloud-based analytics offers intelligent video services without the need for additional hardware or licensing fees. The data coming from different locations through a single web-based interface is analyzed at one place. Since analog cameras work with digital video recorder (DVR) storage technology, they cannot highlight any event. In case of a crime detection event, it might take a longer period of time to play or analyze the full video. However, an IP system with video analytics can highlight or flag events with functions such as motion detection, camera tampering, and a range of other events.

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With the increasing adoption of video surveillance systems for various applications such as infrastructure security, business intelligence, and preserving law and order, the dependence on these surveillance systems has gradually increased. Their performance not only depends on efficiency but is also driven by promptness, accuracy, and embedded processors employed. These processors basically provide features such as securing intellectual property, lowering power dissipation, minimizing cost, and reducing the overall development time. Therefore, the developers are readily grabbing the opportunity of introducing such processors. The existing options for processors in the video surveillance systems are digital still camera (DSC) processors, application-specific integrated circuits (ASIC), digital signal processors (DSP), and field-programmable gate arrays (FPGA).

The rise in public security concerns is expected to create the need for the deployment of more surveillance systems. Further, governments of various countries are deploying video cameras on a large scale to create a stronger security system for their respective countries. With a greater number of cameras being installed globally, there arises an impending need for more people to monitor those cameras. It is extremely difficult and expensive to employ and manage a workforce big enough to monitor those many cameras. However, this issue can be solved by utilizing video content analytics (VCA), video surveillance as a service (VSaaS), and real-time analytics.