Get The Best Diploma in Electronics and Telecommunication Engineering in 2023

Are you looking for the best electronics training courses from the best electronic and telecommunication engineering institute in Kolkata? then visit George Telegraph today and know your course fees details. We provide 100% job placement assistance. Join Now.

Get The Best Diploma in Electronics And Telecommunication Engineering Course in Kolkata 2023 | George Telegraph

If you looking for the top electronics and communication engineering course in Kolkata for your telecommunication engineering courses, then Visit at George Telegraph today and get your course fees details.

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Elaine Liu: Charging ahead

New Post has been published on https://thedigitalinsider.com/elaine-liu-charging-ahead/

Elaine Liu: Charging ahead

MIT senior Elaine Siyu Liu doesn’t own an electric car, or any car. But she sees the impact of electric vehicles (EVs) and renewables on the grid as two pieces of an energy puzzle she wants to solve.

The U.S. Department of Energy reports that the number of public and private EV charging ports nearly doubled in the past three years, and many more are in the works. Users expect to plug in at their convenience, charge up, and drive away. But what if the grid can’t handle it?

Electricity demand, long stagnant in the United States, has spiked due to EVs, data centers that drive artificial intelligence, and industry. Grid planners forecast an increase of 2.6 percent to 4.7 percent in electricity demand over the next five years, according to data reported to federal regulators. Everyone from EV charging-station operators to utility-system operators needs help navigating a system in flux.

That’s where Liu’s work comes in.

Liu, who is studying mathematics and electrical engineering and computer science (EECS), is interested in distribution — how to get electricity from a centralized location to consumers. “I see power systems as a good venue for theoretical research as an application tool,” she says. “I’m interested in it because I’m familiar with the optimization and probability techniques used to map this level of problem.”

Liu grew up in Beijing, then after middle school moved with her parents to Canada and enrolled in a prep school in Oakville, Ontario, 30 miles outside Toronto.

Liu stumbled upon an opportunity to take part in a regional math competition and eventually started a math club, but at the time, the school’s culture surrounding math surprised her. Being exposed to what seemed to be some students’ aversion to math, she says, “I don’t think my feelings about math changed. I think my feelings about how people feel about math changed.”

Liu brought her passion for math to MIT. The summer after her sophomore year, she took on the first of the two Undergraduate Research Opportunity Program projects she completed with electric power system expert Marija Ilić, a joint adjunct professor in EECS and a senior research scientist at the MIT Laboratory for Information and Decision Systems.

Predicting the grid

Since 2022, with the help of funding from the MIT Energy Initiative (MITEI), Liu has been working with Ilić on identifying ways in which the grid is challenged.

One factor is the addition of renewables to the energy pipeline. A gap in wind or sun might cause a lag in power generation. If this lag occurs during peak demand, it could mean trouble for a grid already taxed by extreme weather and other unforeseen events.

If you think of the grid as a network of dozens of interconnected parts, once an element in the network fails — say, a tree downs a transmission line — the electricity that used to go through that line needs to be rerouted. This may overload other lines, creating what’s known as a cascade failure.

“This all happens really quickly and has very large downstream effects,” Liu says. “Millions of people will have instant blackouts.”

Even if the system can handle a single downed line, Liu notes that “the nuance is that there are now a lot of renewables, and renewables are less predictable. You can’t predict a gap in wind or sun. When such things happen, there’s suddenly not enough generation and too much demand. So the same kind of failure would happen, but on a larger and more uncontrollable scale.”

Renewables’ varying output has the added complication of causing voltage fluctuations. “We plug in our devices expecting a voltage of 110, but because of oscillations, you will never get exactly 110,” Liu says. “So even when you can deliver enough electricity, if you can’t deliver it at the specific voltage level that is required, that’s a problem.”

Liu and Ilić are building a model to predict how and when the grid might fail. Lacking access to privatized data, Liu runs her models with European industry data and test cases made available to universities. “I have a fake power grid that I run my experiments on,” she says. “You can take the same tool and run it on the real power grid.”

Liu’s model predicts cascade failures as they evolve. Supply from a wind generator, for example, might drop precipitously over the course of an hour. The model analyzes which substations and which households will be affected. “After we know we need to do something, this prediction tool can enable system operators to strategically intervene ahead of time,” Liu says.

Dictating price and power

Last year, Liu turned her attention to EVs, which provide a different kind of challenge than renewables.

In 2022, S&P Global reported that lawmakers argued that the U.S. Federal Energy Regulatory Commission’s (FERC) wholesale power rate structure was unfair for EV charging station operators.

In addition to operators paying by the kilowatt-hour, some also pay more for electricity during peak demand hours. Only a few EVs charging up during those hours could result in higher costs for the operator even if their overall energy use is low.

Anticipating how much power EVs will need is more complex than predicting energy needed for, say, heating and cooling. Unlike buildings, EVs move around, making it difficult to predict energy consumption at any given time. “If users don’t like the price at one charging station or how long the line is, they’ll go somewhere else,” Liu says. “Where to allocate EV chargers is a problem that a lot of people are dealing with right now.”

One approach would be for FERC to dictate to EV users when and where to charge and what price they’ll pay. To Liu, this isn’t an attractive option. “No one likes to be told what to do,” she says.

Liu is looking at optimizing a market-based solution that would be acceptable to top-level energy producers — wind and solar farms and nuclear plants — all the way down to the municipal aggregators that secure electricity at competitive rates and oversee distribution to the consumer.

Analyzing the location, movement, and behavior patterns of all the EVs driven daily in Boston and other major energy hubs, she notes, could help demand aggregators determine where to place EV chargers and how much to charge consumers, akin to Walmart deciding how much to mark up wholesale eggs in different markets.

Last year, Liu presented the work at MITEI’s annual research conference. This spring, Liu and Ilić are submitting a paper on the market optimization analysis to a journal of the Institute of Electrical and Electronics Engineers.

Liu has come to terms with her early introduction to attitudes toward STEM that struck her as markedly different from those in China. She says, “I think the (prep) school had a very strong ‘math is for nerds’ vibe, especially for girls. There was a ‘why are you giving yourself more work?’ kind of mentality. But over time, I just learned to disregard that.”

After graduation, Liu, the only undergraduate researcher in Ilić’s MIT Electric Energy Systems Group, plans to apply to fellowships and graduate programs in EECS, applied math, and operations research.

Based on her analysis, Liu says that the market could effectively determine the price and availability of charging stations. Offering incentives for EV owners to charge during the day instead of at night when demand is high could help avoid grid overload and prevent extra costs to operators. “People would still retain the ability to go to a different charging station if they chose to,” she says. “I’m arguing that this works.”

what is tumblr good for if not to turn up out of the blue and rant

am trying so hard to survive&thrive at uni but my course says no - lost count of the number of times we’ve been neglected or looked over and the stress of it is not what u need on top of the ordeal of ... doing this course. got a lab session on tuesday on opamps, but we are the 11 out of 200 people who have not covered them (scheduled to do that after easter) and yet!! we have to complete 3 hours of preparation for a 3 hour lab about opamps! yes i can teach myself this stuff (how-hard-can-it-possibly-be mentality) but this is far from the first time we’ve been forgotten about and i can’t carry on like this i do Not have the time or energy

Information Engineering and Information Technology are two distinct fields that have their differences. While both focus on the use of technology to better manage data and information, they each offer unique advantages in terms of implementation. Information Engineering focuses more on the development of software solutions while engineering in information technology is focused more on the management of those solutions. By understanding these distinctions, businesses can make thoughtful decisions when determining which field best fits their needs.

The ECE Department at KRCT, Trichy, organized a PCB Design Value-Added Course on March 24–25, 2024, for second-year students. Led by expert Kasthuri, the course provided comprehensive training on PCB design fundamentals, layout techniques, software tools, and manufacturing considerations, coupled with hands-on projects.

This initiative enhanced students' practical skills, industry readiness, and confidence. With support from Dr. M. Kavitha, the program bridged academic learning with real-world applications, reaffirming KRCT’s commitment to student success and career growth.

 The Future of Electrical and Electronics Engineering Education in the UAE

The landscape of electrical and electronics engineering education in the UAE is rapidly evolving, driven by emerging trends that are reshaping how students learn and prepare for their careers. One significant trend is the increasing emphasis on industry partnerships, which play a crucial role in shaping curricula to meet the demands of a dynamic job market. By collaborating with leading companies, educational institutions can ensure that their programs are aligned with current technological advancements and industry needs.

Innovative teaching methods and technologies are also making waves in engineering education. From virtual labs to interactive simulations, these tools enhance the learning experience by providing students with hands-on opportunities to apply theoretical knowledge. This approach not only fosters a deeper understanding of complex concepts but also prepares graduates for real-world challenges they will face in their careers.

As globalization continues to influence various sectors, its impact on engineering education in the UAE cannot be overlooked. With an increasingly interconnected world, universities are adapting their programs to include international perspectives, ensuring that students are equipped with a global mindset. This focus opens up diverse career opportunities and contributes significantly to workforce development within the region.

In summary, the future of electrical and electronics engineering education in the UAE is bright, characterized by strong industry collaborations, innovative teaching strategies, and a global outlook that prepares students for successful careers in an ever-evolving field.

Power electronics involves the use of solid-state electronics to control and convert electric power. This course covers the application of power electronic converters in modifying electrical energy. Students learn about semiconductor-switching devices like power diodes, SCR, and transistors for power conversion. The course also covers electrical machines, basic and advanced electronics concepts, microcontroller applications in the power industry, and electronic instrumentation techniques for high-power systems. Practical training includes hands-on experience in high-frequency DC converters, PCB designing and fabrication, and power component mounting. Students work on projects to apply their theoretical knowledge before completing the course.

Get The Best Diploma in Electronics and Telecommunication Engineering in 2023

Are you looking for the best electronics training courses from the best electronic and telecommunication engineering institute in Kolkata? then visit George Telegraph today and know your course fees details. We provide 100% job placement assistance. Join Now.

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Smart handling of neutrons is crucial to fusion power success

New Post has been published on https://thedigitalinsider.com/smart-handling-of-neutrons-is-crucial-to-fusion-power-success/

Smart handling of neutrons is crucial to fusion power success

In fall 2009, when Ethan Peterson ’13 arrived at MIT as an undergraduate, he already had some ideas about possible career options. He’d always liked building things, even as a child, so he imagined his future work would involve engineering of some sort. He also liked physics. And he’d recently become intent on reducing our dependence on fossil fuels and simultaneously curbing greenhouse gas emissions, which made him consider studying solar and wind energy, among other renewable sources.

Things crystallized for him in the spring semester of 2010, when he took an introductory course on nuclear fusion, taught by Anne White, during which he discovered that when a deuterium nucleus and a tritium nucleus combine to produce a helium nucleus, an energetic (14 mega electron volt) neutron — traveling at one-sixth the speed of light — is released. Moreover, 1020 (100 billion billion) of these neutrons would be produced every second that a 500-megawatt fusion power plant operates. “It was eye-opening for me to learn just how energy-dense the fusion process is,” says Peterson, who became the Class of 1956 Career Development Professor of nuclear science and engineering in July 2024. “I was struck by the richness and interdisciplinary nature of the fusion field. This was an engineering discipline where I could apply physics to solve a real-world problem in a way that was both interesting and beautiful.”

He soon became a physics and nuclear engineering double major, and by the time he graduated from MIT in 2013, the U.S. Department of Energy (DoE) had already decided to cut funding for MIT’s Alcator C-Mod fusion project. In view of that facility’s impending closure, Peterson opted to pursue graduate studies at the University of Wisconsin. There, he acquired a basic science background in plasma physics, which is central not only to nuclear fusion but also to astrophysical phenomena such as the solar wind.

When Peterson received his PhD from Wisconsin in 2019, nuclear fusion had rebounded at MIT with the launch, a year earlier, of the SPARC project — a collaborative effort being carried out with the newly founded MIT spinout Commonwealth Fusion Systems. He returned to his alma mater as a postdoc and then a research scientist in the Plasma Science and Fusion Center, taking his time, at first, to figure out how to best make his mark in the field.

Minding your neutrons

Around that time, Peterson was participating in a community planning process, sponsored by the DoE, that focused on critical gaps that needed to be closed for a successful fusion program. In the course of these discussions, he came to realize that inadequate attention had been paid to the handling of neutrons, which carry 80 percent of the energy coming out of a fusion reaction — energy that needs to be harnessed for electrical generation. However, these neutrons are so energetic that they can penetrate through many tens of centimeters of material, potentially undermining the structural integrity of components and damaging vital equipment such as superconducting magnets. Shielding is also essential for protecting humans from harmful radiation.

One goal, Peterson says, is to minimize the number of neutrons that escape and, in so doing, to reduce the amount of lost energy. A complementary objective, he adds, “is to get neutrons to deposit heat where you want them to and to stop them from depositing heat where you don’t want them to.” These considerations, in turn, can have a profound influence on fusion reactor design. This branch of nuclear engineering, called neutronics — which analyzes where neutrons are created and where they end up going — has become Peterson’s specialty.

It was never a high-profile area of research in the fusion community — as plasma physics, for example, has always garnered more of the spotlight and more of the funding. That’s exactly why Peterson has stepped up. “The impacts of neutrons on fusion reactor design haven’t been a high priority for a long time,” he says. “I felt that some initiative needed to be taken,” and that prompted him to make the switch from plasma physics to neutronics. It has been his principal focus ever since — as a postdoc, a research scientist, and now as a faculty member.

A code to design by

The best way to get a neutron to transfer its energy is to make it collide with a light atom. Lithium, with an atomic number of three, or lithium-containing materials are normally good choices — and necessary for producing tritium fuel. The placement of lithium “blankets,” which are intended to absorb energy from neutrons and produce tritium, “is a critical part of the design of fusion reactors,” Peterson says. High-density materials, such as lead and tungsten, can be used, conversely, to block the passage of neutrons and other types of radiation. “You might want to layer these high- and low-density materials in a complicated way that isn’t immediately intuitive” he adds. Determining which materials to put where — and of what thickness and mass — amounts to a tricky optimization problem, which will affect the size, cost, and efficiency of a fusion power plant.

To that end, Peterson has developed modelling tools that can make analyses of these sorts easier and faster, thereby facilitating the design process. “This has traditionally been the step that takes the longest time and causes the biggest holdups,” he says. The models and algorithms that he and his colleagues are devising are general enough, moreover, to be compatible with a diverse range of fusion power plant concepts, including those that use magnets or lasers to confine the plasma.

Now that he’s become a professor, Peterson is in a position to introduce more people to nuclear engineering, and to neutronics in particular. “I love teaching and mentoring students, sharing the things I’m excited about,” he says. “I was inspired by all the professors I had in physics and nuclear engineering at MIT, and I hope to give back to the community in the same way.”

He also believes that if you are going to work on fusion, there is no better place to be than MIT, “where the facilities are second-to-none. People here are extremely innovative and passionate. And the sheer number of people who excel in their fields is staggering.” Great ideas can sometimes be sparked by off-the-cuff conversations in the hallway — something that happens more frequently than you expect, Peterson remarks. “All of these things taken together makes MIT a very special place.”

Deccan Education Society: Excellence in Pune's B Tech & PG Diplomas

Pune, often dubbed as the "Oxford of the East," has been a pivotal hub for higher education in India. Amidst its educational glory, the Deccan Education Society stands out as a beacon of academic excellence and tradition. Founded with the aim of creating a literate, enlightened society, the Deccan Education Society has etched its name in the annals of educational history. Today, it opens the doors to a plethora of opportunities for aspiring engineers and professionals through its distinguished B.Tech and PG Diploma courses, particularly in the sought-after fields of Computer Science and Electronics & Communication Engineering.

A Legacy of Enlightenment

The Deccan Education Society Pune University is an emblem of educational heritage, reflecting the vision of its founders to impart quality education to all segments of society. This prestigious institution is not just a name but a legacy that has been nurturing minds and fostering innovation for decades. Its commitment to excellence has made it a preferred destination for students aiming to excel in the realms of technology and engineering.

B.Tech Computer Science Colleges in Pune

For tech enthusiasts dreaming of diving into the world of programming, algorithms, and systems, the B Tech in Computer Science colleges in Pune affiliated with the Deccan Education Society offers an unmatched curriculum. These institutions are renowned for their cutting-edge laboratories, experienced faculty, and a dynamic learning environment that encourages practical learning and innovation. Students are prepared to face the global challenges of the IT industry, making these colleges a prime choice for aspiring software engineers and tech professionals.

B.Tech Electronics and Communication Engineering

The field of Electronics and Communication Engineering (ECE) is at the heart of the digital revolution. Btech electronics and communication engineering colleges under the Deccan Education Society provide a comprehensive B.Tech program in ECE designed to meet the ever-evolving demands of the telecommunications, electronics, and information technology sectors. Through a blend of theoretical knowledge and hands-on experience, students gain expertise in designing, analyzing, and implementing electronic systems, opening a pathway to a future filled with promising opportunities in both the public and private sectors.

PG Diploma Courses in Pune

Beyond undergraduate programs, the Deccan Education Society also offers an array of PG Diploma courses in Pune, catering to the need for specialized knowledge and skills in various professional fields. These courses are tailored for graduates seeking to enhance their qualifications, improve job prospects, or shift career paths. With a focus on industry-relevant curricula, these PG Diploma programs ensure that students are well-equipped to tackle the challenges of the professional world.

DES Pune University: A Pinnacle of Academic Excellence

As we delve deeper into the academic opportunities in Pune, it's imperative to highlight the role of DES Pune University in shaping the educational landscape. The Deccan Education Society's affiliation with Pune University marks a collaboration that leverages the best of tradition and modernity, fostering an environment of excellence and innovation. DES Pune University is not just an institution; it is a community of scholars, educators, and students committed to the pursuit of knowledge and the betterment of society.

This partnership enriches the academic offerings, with DES leveraging the resources, research facilities, and academic prowess of Pune University. The synergy between the two institutions amplifies their impact, creating an ecosystem that nurtures critical thinking, creativity, and a passion for lifelong learning. Students of DES have the unique advantage of accessing Pune University's vast library, engaging in interdisciplinary research, and participating in seminars, workshops, and conferences that broaden their academic horizons.

Conclusion

The Deccan Education Society stands as a testament to the power of education in transforming lives and communities. Through its top-tier B.Tech and PG Diploma courses in Pune, the society continues to mold future leaders, innovators, and professionals. Whether it's breaking new ground in Computer Science or pioneering advancements in Electronics and Communication Engineering, the institutions under this venerable society are paving the way for a brighter, more technologically advanced future. Aspiring students and professionals looking to make their mark in the engineering and technology fields will find the Deccan Education Society an exemplary gateway to achieving their dreams.

Mtech In Electronics And Communication Engineering In Kolkata

The course has a detailed M tech electronics and communication engineering syllabus that emphasizes a balanced approach between theoretical concepts and practical applications. Students will have access to state-of-the-art laboratories equipped with cutting-edge equipment and software.