The employability of drone technology in various sectors

Evolving with newer capabilities at every instant, the current day unmanned aerial vehicle technology can even give you an ultimate bird’s-eye view of the land. These completely ground controlled vehicles are commonly referred to as the drones. Their use has already become mainstream in a lot of fields but they are under constant development.

Some of the recent advancements in the global drone market include:

Serving the needs of remote areas

Drone-based delivery

The ability to surpass higher altitudes, damaged roads or even flooded areas with ease have made drones a good delivery system. This is particularly helpful in remote areas where people do not have an easy access to medical supplies. A California based start-up, Zipline, is an epitome of solutions in this case. They have been using drones to deliver on-demand for the past two years. They’re in the spotlight recently for having built the fastest delivery drone that can fly at a velocity of 121kmph. The other specs of this vehicle include its potential of traversing 160 km in a single round-trip and carrying up to 1.75 kg.

Amazon has also gained good attention in the technology market to have patented a science that can help drones recognize and respond to human instructions through voice and gestures. This means that, in the future, you might even be able to call-out to a drone or help it with instructions to reach its destination!

A conduit for internet

Free space optical communications technology is on the rise as a potentially superior alternative for cabled delivery of internet. Drones are expected to serve remote places on the globe with this technology. They would supposedly use laser to deliver broadbands and these signals will be received on the ground through set-up receivers. The success of this concept has been tried and tested positive by Facebook in Yuma, Arizona.

Drones as a clean energy technology?

That surely doesn’t appear like a distant future.

Although drones are currently not being employed directly in the production of clean energy, they have definitely been viewed as capable of maintenance of structures that do so. For instance, wind turbines used to generate electricity in colder areas often tend to accumulate snow on their blades altering their properties. This reduces the efficiency of the system greatly. In systems that are devoid of a de-icing arrangement, cleaning is an expensive and labor-intensive process. Drones for such maintenance are still in the R&D phase but are expected to be a cheaper and more efficient alternative.

This technology will be able to serve all industry operations that occur at taller points from the ground like the aforementioned. These processes also include storage, job site monitoring, etc. They have also been employed to check commercial jets for dents or scratches.

Drones for research

Drones have also proved important for the behavioral study of various living organisms. With the evolving threat of Zika, mosquitoes that spread them are being targeted for identification through drones. This will allow researchers to define and study their breeding spots so they can alert health officials about it.

Studying animals like whales that reside in regions like the oceans and seas has also been aided by drones. Their behavior is recorded and tracked by drones hovering over the water bodies and studied by researchers in distant labs around the globe. This will also reduce threats to animals in the course of studies and their natural behavior can be noted without hindrance.

Market research shows that although the innovation has driven ire from a good proportion of the population for the breach of privacy, the drone continues to float in the air. In fact, the market is burgeoning at a rate which is hastening the revolutionization of the world.

Technology Market Research Solutions

Safe IOT Practices

To keep up in pace with the growing world, businesses are expected to deploy modern technology-based solutions. While this may bring some benefits, their security is a huge responsibility. Any compromise on the safekeeping of a company’s data is sufficient to mark its downfall.

The IOT technology builds a circuitry to connect multiple devices that can exchange information over the internet on request. Potential uses of this science are many. But, the use of linked devices is luring to cybercriminals and hackers and thus requires great caution.

What security threats does IOT pose?

Although the technology market is constantly innovated, successful cyber-attacks have also increased. The major risks that require consideration with the use of this technology are:

1)     Insecure interfaces

•        Web interface
•        Network services
•        Cloud interface
•       Mobile interface

Data loss and corruption, both, stem from insecure interfaces. There might also be a complete device takeover. This may lead to denial of access and a compromise on the accountability of the entire data consolidation. All data stored could be modified or accessed. Compromised network services can result in a denial of service condition of devices and the user may no longer be able to access them. Moreover, it can also be employed to facilitate attacks on other devices.

The impact also extends to consumers whose personal data can be accessed if the hacker is able to gain control over your devices.

2)     Lack of authentication

Lack of authentication refers to weak or poorly protected credentials and an insecure mode of their recovery. Cybercriminals can employ these to gain easy access to all the data and steal or modify them.

3)     Insufficient transport encryption

A transmission of data from one device to another is the essence of IOT. There needs to be a secure path for this transport of information, failing in which the attacker may be able to view user data when in transit over a local network.

Mitigation of the threats

Global market research reports suggest that while IOT is set to transform lives, web developers and cyber security service providers should be equipped to mitigate the increasing threats accompanying the use of IOT.

During the initial setup of devices, default credentials should be reset. The new ones should not be weak and shouldn’t be exposed to internal or external traffic. Automatic lockout should be set-up for a specific number of failed login attempts and a two-factor authentication method can be used wherever possible.

Only necessary ports should be exposed and transit protocols must be encrypted using TLS or SSL or other standard techniques.

Only data that is crucial for the functioning of the device should be collected and this should be accessible to authorised users only. This means that there should be a strict distinction between administrative users and the regular ones. The data must also be protected and should have a retention limit.

Heading next evolution: 5G

The modern telecommunication ecosystem has gone through consistent developments from the very start. Technology Market report suggests, the role of wireless technology is certainly crucial in collecting and framing data scenario for today’s position. Japan happens to be the first nation which commercially introduced 1G in 1979.

Finland then launched the next, 2G in the year 1991. It was launched on the GSM standards. 1G networks used analog to show radio signals, on the other hand, 2G networks showed digital radio signals. It was followed with rapid upgradations in the 2G from 2.5G (GRPRS) to 2.75G (EDGE).

Roughly, new cellular standards have been put after every 10 years. With this, 3G was launched in 1998 while 2008 introduced 4G network. Every consecutive upgrade has helped to boost the network’s speed,  transmission of data and reduced the latency.

The Long-Term evolution, that is 4G LTE networks have become dramatically famous especially after its launch in developing nations more than developed nations. This is due to developing where the data speeds tend to be inferior compared to their developed counterparts.

The recent years have seen a rise in the progress towards development and deployment of 5G, both for the commercial purposes as well as the masses. There are a lot of things that take place while changing the number of “G”. It evolves takes the wireless communications to the next level.

The introduction of 5G is based on the IEEE 802.11ac standards of wireless technology. It has a download speed of 1 Tbps, that is 65k times faster than usual speed of 4G.

The Group Speciale Mobile Association (GSMA) puts forth eight criteria for a network to proclaim to be defined as 5G:

●     At the endpoints in the field, there have to be 1 to 10 Gbps connections.

●     A round trip delay of one millisecond in a row

●     10 to 100x number of connection devices

●     1000x bandwidth per unit area

●     99.999 % availability

●     100 % coverage

●     90 % cutback in network energy usage

●     The battery life of low power has to be up to 10 years.

There were times that resulted in detainment mainly cause of lack of global compatibility. For example, a device won’t work effectually in a country in a similar band the way it would work in a particularly different country. It is because it is made to work in that specific country. It would be the success of IoT, that is, Internet of Things if the devices made able to connect and function in the same spectrum all across the world. It is called internetworking of devices or vehicles.

Everything that connects to the internet is considered to be “smart”. Also, it is a necessary element for 5G to call effective.

Organisations such as Nokia, Samsung, Qualcomm, Ericsson, and BT have evolved over the years, making progress in 5G.

More firms are connecting with whichever possible means to join hands and funds for further research on 5G and its application. A few of the leading companies are focusing on hardware section of 5G that includes Qualcomm producing a 5G modem while Samsung making a 5G router.

Meanwhile, other key players in the market are emphasizing on the mobile carriers. Ericsson has made a 5G radio system while Nokia came out with ‘5G First’, to offer comprehensive support to carriers.

Note:

Global Market Research Reports estimates, 5G remains in development with companies building devices to support it and run essential tests on them to adopt the next evolution in wireless communication. It predicted that more than twenty-four million subscribers will turn to 5G by 2021. 

The technical aspects are yet to be determined and hence the deployment is noticeably away as it will take time due to changes need to be done to launch the advancement in the network in the form of 5G.

3 Latest Emerging Trends in the Electronic Industry

Ever since the time the “electronic revolution” strikes the industry of telecommunication, there is exponential growth in the competition in the field, which has lead to furious investment and innovation, assisting to give rise to the digital market. The digital market supported the expansion of many electronic appliances like watches, smart phones, TVs, security system, refrigerators, and of course, environmentally friendly electric vehicles.  

As per the latest market research report, the worldwide electrical and electronics manufacturing market is predicted to reach $3 trillion by 2020, with Asia Pacific as the biggest market by geographic region and China the largest market by country. It is predicted to grow at a heady 16.8% growth rate in India. Despite of giving market segmentation and growth by country and by region, the report as well covers the top trends in the electronic industry in the coming 5 year forecast period.

1.Product Design Outsourcing:

Original Equipment Manufacturers (OEMs) are gradually moving product design and development procedures to Electronic Manufacturing Service (EMS) partners.  According to a report, a part of expertise design services market that is predicted to reach $157 billion in 2020.

Electronic Manufacturing Service companies are providing more design services for sub-assemblies and finished products.  EMS partners are working together with OEMS and moving into new models like outsourced design manufacturing (ODM) and joint design manufacturing (JDM).

2.VR in Electronic Manufacturing:

VR technology is being adapted by Electronic Manufacturing Companies to enhanced manufacturing efficiency. This technology in the industry of electronic manufacturing is often termed to as simulation, digital design, and integration. Considering the growth rate of worldwide electronic equipment market, which is 5.2%, VR has a big implementation scope in the forecast period.

3.Robotic and Automation:

A number of electronic markets of equipments are using robotics and automation to enhance plant productivity and effectiveness. Sensors are being used in several machines to access invaluable information for enhancing and diminishing potential breakdowns. For examples, as per a report, 1.2 million industrial robots are estimated to be deployed by 2025, whereas the electronic equipment is predicted to reach $2.1 trillion by 2020, therefore indicating a rise in robotics and automation technology adoption to enhance productivity and decrease production costs.

Modernized Materials and Technologies in the Electronics Industry

The electronics industry is very dynamic like materials, industries and business models are always efficient to meet developing consumer demand. The demand for lighter, smaller, and thinner electronics products enhanced computing power, and connectivity, faster data speeds, and most importantly, sustainability, is encouraging improvements in this industry.

Durability or Sustainability is a major concern area in the electronics industry as products with a shorter shelf are discarded by consumers that in turn raise electronics waste. To overcome such issues, manufacturers are now focusing on developing modernized materials to enhance the performance and life of electronic devices.

Modernized materials definition:

Highly developed materials refer to a new material or the advanced of an existing material. These materials have superior features that can better traditional materials. The top modernized materials and technologies in the electronics market such as quantum dots, G fast chipset, grapheme, flexible battery, silicon carbide, smart glass, carbon nanotubes and biochips.

G. fast chipset:

Market players have adopted a strategy of new product launches, which is the key strategy in order to attain growth in the G fast chipset market. It accounted for a share of about 66% of this strategy, all growth strategies taken on by market players between 2014 and 2016, according to a market research. Market players have adopted this strategy due to the growing use of ultra-fast fixed broadband offered by internet service providers to gain a competitive advantage also a high-growth chance in the European markets.

Quantum dots (QDs):

Quantum dots are small particles of a semiconductor material that were discovered in 1980. They provide unique electronics properties of bulk semiconductor and discrete molecules; they can as well produce different colors as per the size of a particle. Quantum dots are predicted to transform TVs and electronics displays with minimal cost and high energy saving. They get energy from a light source and emit color palette of bright greens and deep red; they are incorporated in display films.

Flexible battery:

Flexible battery is a battery that is compatible, compact, and flexible. It can be molded or twisted in any shape as per the requirement devoid of degradation in its performance and quality, to make sure superior functionality of the final product. It can maintain its characteristics even when it is best, cut into parts, or twisted.

Graphene:

Graphene is a 2-D carbon allotrope that is 200 times stronger than steel, extremely thin, flexible, ultra-light, and an efficient light and heat conductor. It is prepared by several manufacturing procedures with exfoliation and chemical vapor deposition (CVD) being the most preferred procedures.

Carbon nanotubes:

Carbon nanotubes are small sized of nanometers, having minuscule allotropes of carbon. The properties such as electrical, physical, and thermal, make them a superior material for some end-use applications. CNT (carbon nanotubes) have a very high tensile strength outstanding electrical conductivity, and the ability to bear high working temperatures.

Silicon carbide (SiC):

Silicon carbide (SiC) is a very hard material this is found under the earth’s crust. Silicon carbide is used as a rough material for various industrial applications due to its hardness. It can be manufactured unnaturally by blending sand/silica and petroleum coke under high temperature and pressure condition.

Smart glass:

Smart glass as well known as dimmable glass, regulate the light transmission properties statically or dynamically, depending upon stimuli like voltage, light and heat. These glasses do not need electricity to retain its state of opacity or color change. The growth for smart glass is predicted to explode with adoption of VR/AR and rising preferences for wearable’s devices among the millennial and teens.

Biochip:

A biochip is a gathering of miniaturized test sites set on a solid substrate that allows a number of tests to be carried out with increased efficiency and higher speed to achieve higher throughout. Biochips have major applications in the fields of genetic analysis, protein analysis, toxicology, biochemical research, personalized medicine, and diagnostics. 

Transforming Healthcare with Big Data

The business of saving lives is the only biggest business than any other businesses. There hasn’t been a more relevant time for businesses in healthcare to think out of the box to find answers to pressing problems. In 2012, Centers for Disease Control and Prevention reported, around half of all adults (nearly 117 million people) globally, had chronic diseases and conditions like heart disease, cancer, stroke, type 2 diabetes, arthritis and obesity. The need is to prioritize prevention as much as finding cures for diseases as this is the only method to verify their rampant spread.    

In a short span of 10 years, there has been an extreme generation of data and the use of technology to analyze the same has given birth to a new industry, Big Data. Through effective use of Big Data; healthcare industry analysis have found newer methods of decreasing many preventable deaths, curing disease and improving quality of life, while cutting their business overheads and rising productivity. Treatment modalities have changed and that has a lot to do with the way healthcare experts are using Big Data to make knowledgeable decisions about patient care. At present, the impetus is on understanding patient information quicker and better to estimate the onset of sickness and to stall them in the early stages.

Begin at the very starting:

One of the most physical methods data has changed healthcare is in the method used to collect it. Electronic Health Records (EHR) is now a reality across most hospitals in the U.S. By 2020, centralized EHRs is likely to come into being.  European Health Record System have eradicated the need for paperwork, diminished data duplicity, and also allowed for better treatment tracking. At present, the novelty of EHRs has worn off as technology has gotten way more avant-grade, as per a market research.

Telemedicine has been around for no less than 4 decades however mobile technology market has changed the face of it with wireless devices and video conference tools. Distant yet personalized treatment has been made very likely and this has considerably cut costs in healthcare. Money of the patient’s is saved on repeat visits to hospitals, and saves on valuable time of physicians as distant treatment has made some facets of medical treatment location skeptic. Some smart wearables have also made their way into everyday life and it isn’t uncommon for friends and peers to switch over personal data, which is collected via these devices.  Industry professionals estimate that there will soon come a time when physicians rely on Big Data as step one in charting treatment plans.

The very fact that few companies are searching to collect and study an insubstantial variable like stress is a testament to difference Big Data can make. The adoption of preventive study as opposed to conventional statistical study is a clear sign of things to come. Prediction modeling, the basis of preventive analysis, makes an estimation algorithm or profile of a person utilizing techniques like artificial intelligence to analyze data. This can be better individual outcomes, enhance the accuracy of predictive study, and guide to pharmaceuticals creating more effective medicines.

The common thread, which runs through the applications of Big Data, is the ability to offer real-time analysis of data. When it comes to making a decision on health, time is absolutely of essence and further use of Big Data will help professionals and patients take quick calls without compromising on correctness. 

Forecast on Internet of Things Testing Market

The Internet of things testing market size is predicted to rise from $302.9 million in 2016 to $1,378.5 million by 2021, at CAGR of 35.4% between these years. For development, testing and management applications, enterprises need flexible platform and infrastructure for developing.

There are many companies that offer end-to-end planning, execution of releases, coordination, and helps organization to build mutual workflows between development and operations, to speed up release series of Internet of ThingsTesting Market applications and boost up the ROI of businesses.  

Nevertheless, for the nimble development of IoT applications, there is a critical need for pro-active robotic testing equipments and solutions to test IoT functions at the necessary benchmark and make sure the performance and functionality of IoT applications.       

Device field testing professional service type is predicted to gain maximum traction during the anticipated period:

This type of service provider proffers real-time testing assurance of the device workability and operability in the actual field. These service providers not only test the devices in the static field environment, however also in the energetic field environment to make sure it’s real on field operation to commercial clients. It gives surety of device’s functionality, accessibility, compatibility, performance, and security to IoT vendors.

Mobile application testing services sector is anticipated to have IoT testing market’s main market-size during the estimated period:

This type of services proffers by chief testing sellers essentially test handheld mobile devices for their usability, functionality, security, performance, among others. Additionally, to this testing, installation testing, lab testing, and memory leakage testing are also performed on mobile devices for its usability and functionality. Technology market  of mobile application testing gives offer both manual and automated mobile application testing to their commercial clients, to test both hybrid and native mobile application.   

North America is estimated to have the largest market size and Asia-Pacific is anticipated to rise at the highest rate during the projected period.

According to a market research, North America is estimated to hold the largest market share during the calculated period. The place holds chief dominance due to its sustainable and fixed economies, which allows companies to strongly invest in development and research activities, thus contributing to the development of new technologies. Several organizations are keen on incorporating IoT technologies in their procedures that has enhanced the growth of the IoT testing market considerably.  

The Asia-Pacific market is predicted to witness the notable growth and is estimated to be the fastest-growing place in the IoT testing market. North America has a competitive benefit over other places with number of players providing local cost-efficient results, hassle-free accessibility of trained labors, and flexible policies & regulations.