Category Archives: Engineering
Stewart Kline named ‘Highway Engineer of the Year’ – wlfi.com
TIPPECANOE COUNTY, Ind. (WLFI)The Association of Indiana Counties recently named Stewart Kline its 2022 Engineer of the Year.
Kline has been executive director of the Tippecanoe County Highway Department since 2017.Before that, he owned a private engineering consulting firm.
In his 40-year career, Kline has been involved in many major road and bridge projects across the county.He says his favorite is Hog Point Bridge over the Tippecanoe River near Americus.The bridge is one of the few arch bridges in the area.
"It's a historic bridge and it was quite a project," Kline said. "Took the fill out of the old arches, rebuilt the light weight so we were able to widen the arches and restore them."
Kline also told News 18 that he also appreciates the artwork of the bridge.
"Transportation engineers, either in road or bridge, have a different take, see different things when you look at a bridge or road project," Kline said. "Most of the public just wants it to work and they miss the art. The beauty of the bridge."
The Association of Indiana Counties recognized Kline in South Bend during its annual conference.
Kline also thanked his dedicated staff at the highway department.
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Stewart Kline named 'Highway Engineer of the Year' - wlfi.com
What is Engineering? – College of Engineering – University of Maine
Engineering combines the fields of science and maths to solve real world problems that improve the world around us. What really distinguishes an engineer is their ability to implement ideas in a cost effective and practical approach. This ability to take a thought, or abstract idea, and translate it into reality is what separates an engineer from other fields of science and mathematics. Consider some things you use in your everyday life: Buildings, roads and bridges, vehicles (cars, planes and boats), computers and other electronic devices. Not a single one of them would exist without engineers!You wouldnt have been able to drive to work, check your Facebook status or even use the toilet this morning!
What Does A Typical Engineer Do? Engineers are problem solvers, organizers, communicators, calculators and designers. They are capable of clearly defining a problem and its relevant constraints (such as time, cost, etc.) and providing a simple solution. A senior engineer will usually perform less technical work (calculations and designs) but instead focus on managing a project or team of engineers.
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What is Engineering? - College of Engineering - University of Maine
What is Engineering? (Definition and Types) – TWI
Engineering is the application of science and maths to solve problems. While scientists and inventors come up with innovations, it is engineers who apply these discoveries to the real world.
Engineering is part of STEM education, which aims to engage students with science, technology, engineering and mathematics yet, as a discipline, it has been practiced for thousands of years.
You can see examples of engineering in the Pyramids of Giza, at Stonehenge, the Parthenon and elsewhere. Yet, todays engineers operate in many different areas as well as building structures.
Engineers work on everything from cell membranes to construction and prosthetics to improving engine and transport efficiencies and developing renewable energy resources.
While engineering dates right back to the invention of the wheel (and beyond), the term itself comes from the word engineer, which goes back to the 14th century, when an engineer meant someone who constructed military engines like catapults and other siege engines. This military meaning can still be seen in use today with the Corps of Royal Engineers and the U.S. Army Corps of Engineers.
The word engine itself comes from the Latin word ingenium (c. 1250), which means innate quality, especially mental power, hence a clever invention.
Engineering developed beyond military applications and began to be applied to civilian structures like bridges and buildings, leading to the creation of the term civil engineering, to differentiate it from the original military engineering field.
Engineers are involved in the design, evaluation, development, testing, modification, inspection and maintaining of a wide range of products, structures and systems. This involves everything from the recommending of materials and processes, overseeing manufacturing and construction processes, and conducting failure analysis and investigation, to providing consultancy services and teaching engineering to students and trainees.
There are many different types of engineering, often divided into areas in which the engineer operates. For example, engineers working within the oil and gas industry could be petroleum engineers, while those working in farming-related applications could be called agricultural engineers.
While there are some traditional areas of engineering, such as mechanical and civil engineering, other engineering fields require an overlapping of different specialities. So, for example, a civil engineer may also need an understanding of structural engineering or an aerospace engineer may need to understand aspects of electrical or computer engineering too.
These types of engineering are commonly known as interdisciplinary engineering and include manufacturing engineering, acoustic engineering, corrosion engineering, aerospace, automotive, computer, textiles, geological, materials and nuclear engineering, among others. These areas of engineering are all among the branches of engineering that are represented by the 36 licensed member institutions of the UK Engineering Council.
Here are some of the traditional and more common interdisciplinary engineering fields:
Mechanical engineers are involved in the design, manufacture, inspection and maintenance of machinery, equipment and components such as vehicles, engines, aerospace products, weapon systems, robotics, turbines, construction and farm machinery, as well as a wide range of tools and devices. This type of engineering is also associated with the management of control systems and instruments for measuring the performance and status of machinery.
Electrical engineers work on the design, testing, manufacture, construction, control, monitoring and inspection of electrical and electronic devices, components, machines and systems. These range in size from the smallest microchips to large transmission and power generation systems. This includes everything from broadcast engineering to electromagnetic devices, computer systems, telecommunications and more.
Civil engineers are involved in the design, construction, maintenance and inspection of large civil infrastructure projects, including roads, railways, bridges, tunnels and dams.
Working on both public and private projects, civil engineers traditionally work in sub-disciplines such as environmental engineering, structural engineering or surveying.
As mentioned above, civil engineering was originally created to differentiate it from military engineering.
As a specialised branch of mechanical and electrical engineering, aerospace engineering focuses on the design, manufacture and testing of aircraft and spacecraft, including all parts and components. Covering everything from vehicle aerodynamics and efficiencies to electrical control and navigation systems, much of the expertise is also used for other vehicles, such as cars.
Nuclear engineers work on the design, manufacture, construction, operation, and testing of the equipment, systems and processes for the production and control of nuclear power. From nuclear power plant reactors to particle accelerators, nuclear engineers also work on factors such as monitoring and the storage of nuclear waste in order to protect people from potentially harmful situations.
Biomedical engineers are concerned with the design of systems, equipment and devices for use in healthcare and medicine. By working with medical specialists such as doctors, therapists and researchers, biomedical engineers are able to meet the requirements of healthcare professionals.
Chemical engineers use physics, chemistry, biology and engineering principles for the design of equipment, systems and processes for refining raw materials for mixing, compounding and processing chemicals for a variety of products. Carrying out processes on a commercial scale, chemical engineers are involved in processes ranging from petroleum refining to fermentation and the production of biomolecules.
Computer engineers design computer hardware, systems, networks and software. Computer engineering combines other disciplines, such as electrical engineering and computer science, as well as software engineering and design.
Industrial engineers design and optimise facilities, equipment and systems for manufacturing, materials processing and other industrial applications.
Environmental engineers are concerned with the prevention, removal and elimination of sources of pollution that affect the environment. Measuring pollution levels, determining sources of pollution and cleaning up polluted areas, these engineers need to work in compliance with government regulations.
Marine engineering is related to any engineering tasks on or near the oceans. This includes design and development for shipping, submarines, oil rigs, on-board, harbours, plants and more. This specialised area of engineering combines other types of engineering, including mechanical engineering, electrical engineering, civil engineering, and programming.
Engineering has been a part of human history, in one form or another, for thousands of years. Of course, as our knowledge and understanding of science and mathematics grew, so our engineering expertise and competence also improved.
Todays engineers use the most advanced technologies, alongside established scientific principles, to apply cutting-edge solutions and innovation to real world challenges.
It is hard to over-emphasise the importance of engineering on human history, from designing transportation systems to powering our homes, engineering is all around us, right down to the device you are using to read this.
As our scientific knowledge continues to advance, so engineering will find ways to take this new information and apply it to the world around us.
Engineering is all around us and is an integral part of our everyday lives. It is something that many people take for granted, but it is engineering that allows you to make a coffee in the morning, heats or cools your home, allows you to travel, communicate on your mobile device, and so much more besides.
As James A. Michener wrote in his 1983 novel, Space, "Scientists dream about doing great things. Engineers do them."
TWIs engineering expertise covers a range of industrial applications, from automotive to power generation and aerospace to marine, as we work to offer support and solutions to our Industrial Members.
Contact us, below, to find out more.
Engineers shape the world around us, innovating solutions to our problems and creating new technologies to help advance society. This ranges from air or space travel to electronics engineering and through to water supply engineering to make sure those in remote communities have access to fresh, clean water.
Helping those in need through the development of new technologies to prevent disease or protecting the planet from environmental issues, engineers use science, maths and problem solving to find answers to both local and global challenges.
Engineering cannot literally solve any problem, but it can be used to solve a wide range of them. Engineers work within the bounds of reality, finding real-world solutions to real-world problems. Many engineering problems have more than one solution, allowing engineers to find the most suitable one given the resources at hand.
Engineering has existed since ancient times with the invention of the wheel, pulley, wedge and lever. However, the first named civil engineer is Imhotep, who is believed to have designed and supervised the construction of the Pyramid of Djoser (the Step Pyramid) at Saqqara in Egypt around 26302611 BC.
Despite its roots in antiquity, it wasnt until 1390 when the word engineer came into use. Originally known as engineers these specialists were responsible for the construction of military engines, such as catapults, ballista, the trebuchet and other siege engines and engines of war. This military connection can still be seen with the Corps of Royal Engineers and the U.S. Army Corps of Engineers. This later led to the creation of civil engineering and other engineering disciplines distinct from military engineering.
Since then, engineering graduates have gone on to work in a range of disciplines including aeronautical, chemical, mechanical, civil, computer, electrical, and other types of engineering (see above). Each of these types of engineering deals with different specialities although there is a degree of cross-over between disciplines as solutions are shared across industry.
Engineering can literally take you around the world, travelling to work on projects in foreign countries, as well as being an in-demand and well-paid career choice.
Walking the line between academia and a vocational discipline, engineering combines soft skills and academic knowledge with a practical application. In addition, it opens up potential opportunities in consulting, technical writing, manufacturing, logistics, business and more.
Automation is spreading though many industries, including engineering, with the advent of the fourth industrial revolution. As increased automation removes repeatable tasks from workplaces, there have been concerns that roles will be replaced. These concerns existed during the previous industrial revolutions, but were ultimately unfounded. This looks set to be the case with this fourth wave of concern as engineering still has an emphasis on human-focused activities such as design, quality control and problem resolution.
Automation has seeped into engineering over the decades but, rather than replacing people, the use of automation frees up engineers to solve challenges, innovate and move to more specialised roles and duties.
Engineers will certainly be needed in the future and, in fact, many forecasts say that the demand for engineers will actually increase. Engineering has one of the lowest unemployment rates of any large job sectors and, as technology continues to evolve, engineers will remain integral to solving our problems and delivering innovations to society.
With an Oxford University study estimating that nearly 50% of the jobs in the United States are at risk of being automated in the next twenty years, it is understandable that people are concerned about job security.
However, it is more likely that the increase in artificial intelligence and robotic systems will actually have a positive impact. Routine and simple tasks can be easily automated but there are many more complex and nuanced roles that will still require humans. Indeed technological advancements in the past have created new jobs, including researching and maintaining the very systems that people fear will replace them.
In fact, while robots take on the more mundane tasks, it means that people will be able to use their time completing more engaging work, such as design, R&D, and those roles where communicating with other people is important.
Rather than replacing humans, it seems that robots and A.I. will provide more engaging work opportunities for people leaving the tedious tasks to the machines.
It is difficult to forecast where engineering will go in the future but many of the skills required of engineers today will still be relevant in the future, such as analytical skills, creativity, communication skills, ethics, agility, and the pursuit of continuous learning.
With technology continuing to advance and the increase in automation, professionals with an ability to work with technology and electronics will be sought after. Being able to use smart devices and a joined up, Internet of Things (IoT) approach also looks set to be important.
Engineers working at hazardous locations could be remotely monitored with devices to check their location and ensure their safety, and an increased use of automation and electronics will mean that software and embedded systems will become increasingly important. Engineering will also become more streamlined as lean processes are rolled out across industries, removing unnecessary tasks and making processes as efficient as possible.
Engineering is a great choice for people who like to learn new things, make a difference, earn a good wage, and enjoy excellent employment prospects.
Skilled and qualified engineers are in high demand across a range of industries and many enjoy good wages and benefits.
However, you will need to keep your skills up-to-date during your career and so will need to learn new things. However, with that being said, the more skilled you are, the more in demand you become, the higher wage you can command, and the more opportunities you will have to travel or work on different projects.
Engineering jobs tend to be in high demand due to the many projects that are occurring across all areas of society. However, you must also take account of the fact that demand is driven by global or local necessity, so certain industries will be more buoyant than others at different times.
Like any subject, engineering becomes more in-depth and complex the further you go with your studies. However, it does require a grasp of maths and science as well as being able to apply common sense and logic to solve problems.
Although it has been said that engineering ranks as one of the more difficult degrees, engineer educators have experience in helping their students through to graduation, so if it interests you and you think you have what it takes, then you should certainly not be put off.
Engineering involves the application of the principles of science and mathematics to solve real world problems and to innovate new products and processes across a wide range of industries and applications. Designing, testing and building structures, machines, devices and processes using maths and science is all part of an engineers role, so there will be certain similarities in study. However, the details will change depending on which field of engineering you study, from aerospace and chemical to civil and electronics through to mechanical engineering and beyond.
Engineering technicians can become engineers with the addition of the right skills and qualifications. You can find out more about becoming an EngTech here.
It is certainly possible to learn aspects of engineering on your own, but you will still need to be assessed and get a qualification before you are able to work as a professional. There are also aspects of engineering, particularly the more hands-on aspects, that are difficult to learn on your own. It also depends on which area of engineering you are interested in!
As such, we would recommend you seek proper training if you want to become an engineer.
Engineering is all around us, from the device you are reading this on to the buildings we live in, cars we drive and more. From bridges to computers and medical devices to railways engineers have been involved at some step of the way. Although they are not required in every business, they will still have been involved in setting up or creating initial technologies.
Engineering is critical to industrial innovation, combining scientific and mathematical principles with practical knowhow to deliver products, services and processes.
Engineers keep pushing humankind forward, developing new innovations, protecting lives, preventing diseases and helping to keep the planet itself safe and clean. Certainly, industry has been responsible for problems such as fossil fuel use and the associated climate change, but it is to engineering we must turn to solve the crisis and deliver sustainable alternatives.
As real world problem solvers, engineers continue to be important across all parts of society.
Aside from the good job prospects and security, as well as the higher average wages, engineering is a good career because it gives you the opportunity to work for the benefit of society.
Whether it is through improved transportation systems, delivering better medical devices and technologies, finding new cleaner energy sources, increasing living standards for underdeveloped nations or solving the problem of global hunger, engineering plays a part in changing peoples lives for the better.
The career can bring you a great many personal benefits, such as travel, high rates of pay and good job security, but it also gives you the opportunity to use your knowledge, skills and experience to make a real difference to the world.
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What is Engineering?- Types of Engineering
What is Engineering?
Engineering is the use of scientific principles to design and build machines, structures, and other items, including bridges, tunnels, roads, vehicles, and buildings. The discipline of engineering encompasses a broad range of more specialized fields of engineering, each with a more specific emphasis on particular areas of applied mathematics, applied science, and types of application.
Engineering is the application of science and maths to solve problems. While scientists and inventors come up with innovations, it is engineers who apply these discoveries to the real world. Yet, todays engineers operate in many different areas as well as building structures.
Engineering is part of STEM education, which aims to engage students with science, technology, engineering, and mathematics yet, as a discipline, it has been practiced for thousands of years.
You can see examples of engineering in the Pyramids of Giza, at Stonehenge, the Parthenon, and elsewhere. Engineers work on everything from cell membranes to construction and prosthetics to improving engine and transport efficiencies and developing renewable energy resources.
While engineering dates right back to the invention of the wheel (and beyond), the term itself comes from the word engineer, which goes back to the 14th century, when an engineer meant someone who constructed military engines like catapults and other siege engines. This military meaning can still be seen in use today with the Corps of Royal Engineers and the U.S. Army Corps of Engineers.
The word engine itself comes from the Latin word ingenium (c. 1250), which means innate quality, especially mental power, hence a clever invention.
Engineering developed beyond military applications and began to be applied to civilian structures like bridges and buildings, leading to the creation of the term civil engineering, to differentiate it from the original military engineering field.
Engineers are involved in the design, evaluation, development, testing, modification, inspection, and maintenance of a wide range of products, structures, and systems.
This involves everything from the recommending of materials and processes, overseeing manufacturing and construction processes, and conducting failure analysis and investigation, to providing consultancy services and teaching engineering to students and trainees.
The field of engineering is divided into a large number of specialty areas:
There is often considerable overlap among the different specialties. For this reason, engineers need to have a general understanding of several areas of engineering besides their specialty. For example, a civil engineer needs to understand concepts of structural engineering, an aerospace engineer needs to apply principles of mechanical engineering, and nuclear engineers need a working knowledge of electrical engineering.
There are tons of different types of degrees in engineering you can earn in college and graduate school. This list contains more than 50 examples of engineering majors, organized by the five engineering branches (which are also majors in and of themselves).
Not all schools offer all these exact majors and specializations, so be sure to check each college youre interested in to see what types of degrees in engineering it offers. As a general rule, tech schools, such as Caltech, MIT, and Georgia Tech, will typically offer a much wider array of engineering majors and degrees.
While this is certainly not an exhaustive list, it should hopefully give you an idea of the different types of engineering you could study in college and what kinds of specializations you can select. You might also consider checking out our picks for the best engineering schools.
This type of engineering uses the principles of chemistry, biology, physics, and math to design and manufacture products through chemical processes.
Civil engineering is a professional discipline that entails the design, construction, and maintenance of the natural world and man-made structures, such as bridges, dams, and sewage systems.
As its name suggests, this type of engineering focuses on technology, specifically the design and production of electronic devices.
Industrial engineering is all about efficiency and optimization in areas such as business, finance, production, and management.
This original branch of engineering involves designing, manufacturing, operating, and testing machines and other devices.
Below are some types of engineering that dont exactly fit into any of the five major categories above.
Engineering has been a part of human history, in one form or another, for thousands of years. Of course, as our knowledge and understanding of science and mathematics grew, so our engineering expertise and competence also improved.
Todays engineers use the most advanced technologies, alongside established scientific principles, to apply cutting-edge solutions and innovation to real-world challenges.
It is hard to over-emphasize the importance of engineering in human history, from designing transportation systems to powering our homes, engineering is all around us, right down to the device you are using to read this.
As our scientific knowledge continues to advance, so engineering will find ways to take this new information and apply it to the world around us.
As you saw above, there are tons of different types of engineering fields you could enter. But which is ultimately the best choice for you? Here are four factors to keep in mind as you consider what type of engineering you want to major in and use in your career.
First, you should think about what your biggest academic and personal interests are.
For example, have you always been fascinated by how things are built? Maybe you often played with LEGO bricks as a child and can easily envision yourself helping construct and design public buildings and roads. In that case, civil engineering would be an excellent fit for you.
Or perhaps youre interested in computers and coding, in which case a career as a software or computer engineer would be a great choice.
Take some time to really ask yourself which of your interests youre most passionate about. It might even help to write down a list of your favorite hobbies and the most interesting classes youve taken in school. Afterward, compare those interests to the five major types of engineering and try to see how they align.
In addition to your interests, take some time to consider your biggest strengths. For instance, was chemistry a total breeze for you? Then chemical engineering might be a smart choice for a college major.
Or maybe youre a natural-born leader whos always managing projects and looking for ways to increase productivity. In that case, you might think about studying industrial engineering.
To figure out your strengths, look at your grades in different classes youve taken and make a list of what you believe to be your best skills. Then, try to match these to the five different types of engineering listed above.
According to the Bureau of Labor Statistics, architecture and engineering workers reported a median annual income of $83,160 in May 2020 about $40,000 more than the median salary for all jobs in the U.S. Certain types of engineering jobs may offer higher incomes depending on factors like demand and industry.
Here are the median salaries for some of the most popular engineering branches.
Engineering is all around us and is an integral part of our everyday lives. It is something that many people take for granted, but it is engineering that allows you to make a coffee in the morning, heats or cools your home, allows you to travel, communicate on your mobile device, and so much more besides.
Within each of these branches are dozens of specializations you can study. As a whole, engineers make good money, and many engineering jobs are in fairly high demand.
When it comes to deciding which engineering, field is right for you, be sure to look at the following four factors:
Overall, engineering is a great field to get into, with lots of unique options to choose from. Just be sure to take lots of time to figure out which type of engineering will work best for you!
Engineers design, build, and maintain various complex systems and structures, from buildings to software. While there are many engineering professions, there is one consistent engineering mindset: to innovate.
Engineering is widely considered as one of the most lucrative and in-demand career choices, with multiple engineering disciplines and job types, as well as salaries that can exceed $100k per year once the engineer has some experience behind them.
Engineering is a scientific field and job that involves taking our scientific understanding of the natural world and using it to invent, design, and build things to solve problems and achieve practical goals. This can include the development of roads, bridges, cars, planes, machines, tools, processes, and computers.
As per research, engineering graduates with top-notch qualities and extensive knowledge get high-paying and highly rewarding careers in the industry. And of course, the income keeps on getting better with time and as you keep gaining more skills.
To engineer literally means to make things happen. Most of what engineers do on a daily basis can fall into four categories: communicating, problem-solving, analyzing, and planning. Depending on an engineers industry and role, their day will typically consist of a various mix of these functions.
Computer Engineering is one of the most sought-after engineering career choices available to girl students in India. The best part of this course is, that there is no fieldwork at all. The expansion in the IT sector and software revolution in India has also made this course demanding.
Considered one of the toughest courses in the world, engineering students are required to have tactical skills, analytical skills, critical thinking, and problem-solving abilities. Engineering continues to be one of the most preferred choices of students after pursuing Science PCM in class 12th.
Yes. They need to understand calculus, multivariable calculus, differential equations, linear algebra, and statistics so that they can understand whats going on with the engineering models they use.
Engineers develop new technological solutions. During the engineering design process, the responsibilities of the engineer may include defining problems, conducting and narrowing research, analyzing criteria, finding and analyzing solutions, and making decisions.
Civil engineers use mathematics equations to study the chemistry of materials. In order to use the right material for the project, engineers measure the strength of the material and apply chemical equations to judge the strength of the material.
According to the U.S. Bureau of Labor Statistics (BLS) engineers have a median annual wage of $91,010 and the engineering field projects to have employment growth of nearly 140,000 new jobs over the next decade. The bottom line: it is well worth the time and effort it takes to become an engineer.
So, in that case, engineers can get a good job earlier than doctors. After an engineering degree, it will be easier to get jobs, but after a medical degree, it wont be easy to open your own clinic or hospital if nobody in your family background is a doctor, or if you have no good connections with any doctor.
This requires very involved mathematics from algebra through calculus to differential equations and vector analysis. There are, however, quite a few engineering jobs that require almost no advanced math and very little basic math or algebra. It is a very broad field.
It takes four to five years to become an engineer. Engineering degrees are followed by post-education examinations, specialization, supervised training, and continued education. It can take 8-12 years for advanced engineering degrees. You can study for two years and earn an associates degree in engineering technology.
An engineering major is an interdisciplinary study of math, science, and some business principles. General engineering courses teach students how to design and conduct experiments, identify and solve problems, understand professional and ethical responsibility, and communicate effectively.
Yes, an average student can do engineering department easily. In CSE you have to face lots of mathematics stuffs like Linear Algebra, Probability, Statistics, Modern Algebra, etc. Maybe you will face difficulty in starting but if you are average in math then you can improve yourself and do very well in CSE courses.
Subjects such as physics, chemistry, or agricultural science can provide a good foundation for students of engineering, as the first year at college usually involves the study of core scientific concepts.
Engineering positions typically require a bachelors degree in engineering or a relevant field. Some engineering jobs, especially in management, require a masters degree. An engineering degree in a specialty area may qualify engineers for a career in a related field.
Engineering requires creativity, dedication, and patience in your work. Its not that anyone can become an engineer. For engineering, your basic education must include geometry, trigonometry, algebra and calculus, physics, chemistry, and biology depending on which field your interest resides.
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Engineering innovation opportunities are topic of 2022 Porth Lecture at S&T – Missouri S&T News and Research
There are many opportunities to transform innovations into successful commercial ventures, but it requires entrepreneurial leadership and a firm grasp of markets and economics. National Academy of Engineering member Dr. Corale Brierley will discuss this and more about successful entrepreneurship during the Porth Lecture at Missouri S&T.
The lecture, titled Strategies for Entrepreneurial Success, will be held at 3 p.m. Thursday, Oct. 13, in Room 125 Butler Carlton Hall. The lecture will also be available byZoom.
Brierleys talk will address what she calls the four Es entrepreneurism, economics, equity and equality as they relate to capitalizing on innovations.
Opportunities for engineering innovation abound, particularly at the interfaces of disparate disciplines, she says. Transforming innovations to successful commercial outcomes requires entrepreneurial leadership; creative talent of a diverse team that embraces inclusion, equity and equality; a firm grasp of markets and economics; and capital management.
Brierleys lengthy career comprises academic research and development, founding and managing a metals biotechnology company, process development for a mining enterprise, board service for startup companies and a university innovation center, and 30 years of international consulting for the mining and investment sectors. She has received numerous industry awards, is an elected member and eight-year vice president of the National Academy of Engineering, and currently senior advisor to the NAE president.
The Harry William Lee Porth Distinguished Lecture Series in Engineering at Missouri S&T was created in memory of Porth, who earned a bachelors degree in mining engineering from the university in 1911. His wife, Virginia Lee Porth, provided for the establishment of the lecture series in her will. Porth Worked for the Nevada Hills Mining Co. and for Swift and Co. in Chicago.
About Missouri University of Science and Technology
Missouri University of Science and Technology (Missouri S&T) is a STEM-focused research university of over 7,000 students. Part of the four-campus University of Missouri System and located in Rolla, Missouri, Missouri S&T offers 101 degrees in 40 areas of study and is among the nations top 10 universities for return on investment, according to Business Insider. S&T also is home to the Kummer Institute, made possible by a $300 million gift from Fred and June Kummer. For more information about Missouri S&T, visitwww.mst.edu.
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Students protest Engineering Career Fair for inviting companies that ’cause harm’ The Daily Free Press – Daily Free Press
The Engineering Career Fair in the GSU. BU Revolutionary Marxist Students held the protest to challenge BU inviting companies that participate in weapon-making and surveillance technology to the fair. FIONA BROADIE/DFP STAFF
The Boston University Revolutionary Marxist Students held a protest at the Engineering Career Fair outside the George Sherman Union Oct. 6 to oppose BU promoting societal engineers, because it invites companies that participate in weapon-making and surveillance technology.
Sam Fogelberg, a junior in the College of Engineering and member of the BU Revolutionary Marxist Students, said they are protesting the defense contractors invited to the career fair such as General Electric, General Dynamics and MIT Lincoln Lab who have all participated in making weapons used against civilians.
If you look at the type of technology that theyre creating, theyre creating bombs or parts that go into bombs, missiles and stuff thats being used by the U.S. military abroad for a number of horrible different things, Fogelberg said.
Luke Sweeney, a junior in the College of Arts and Science and another member of the BU Revolutionary Marxist Students, said a lot of colleges promote the idea that technological innovation always benefits society influencing students to produce technology without considering its consequences.
Were not just doing this for advocacy to raise awareness or anything, were doing this because we really want people to realize careerism is not something to devote your life to, Sweeney said. It is something to abandon and to instead, join in struggles that really help people.
BU Spokesperson Colin Riley said the career fairs at BU are meant to help students see the opportunities in the branch theyre studying, and what companies look for in terms of recruitment.
Theyre great employers, Riley said of the companies at the engineering career fair. Giving great opportunities to BU students to apply for and possibly be recruited to be employed by high quality engineer firms.
Instead of being told to aspire for a career with defense contractors, Harishan Ganesan, a BU alumni and participant in the protest, said students should be exposed to the things they do and fight against the systems they uphold.
Theres a need for students to actually let go of these aspirations and see the need to fight against the system itself that promotes this type of collaboration, Ganesan said. The system that supports a minority wealthy elite in this country, while parasitically leeching off of people in this country and people all over the world.
Fahim Rabbi, a junior in the College of Engineering who attended the career fair, said these companies play an important role in our society by creating engines, transportation vehicles and planes.
They do have other projects that may be harmful to mankind and stuff but at the same time, they are also a big company with other good stuff, Rabbi said.
Rabbi said he feels like there is a wide array of opportunities presented for students.
If youre interested in a specific subject or specific thing within engineering, there are professors that are specialized in those areas, Rabbi said. So I dont feel any kind of pressure in any certain direction.
Fiona Broadie contributed to the reporting of this article.
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Engineering lecture series focuses on health care for the brain – University of Washington
Engineering | Research | UW News blog
October 10, 2022
Injury or disease in our most complex organ the human brain can be hard to detect and even harder to treat. Advancing technologies for brain health requires interdisciplinary collaboration from clinicians and engineers in fields that range from data science to medicine.
This fall the University of Washingtons annual Engineering Lecture Series will feature research with potential to transform brain therapeutics from infancy to late adulthood. Two UW engineers will speak about their work on detecting and treating Alzheimers disease as well as on developing therapies for childrens brains. These lectures are free and open to the public, and this year they will be both in person and livestreamed. Registration is required.
From discovery to design: Toward early detection and treatment of Alzheimers disease
Valerie Daggett
The series kicks off Oct. 13, at 7:30 p.m. in Kane Hall 130 with Valerie Daggett, a professor of bioengineering. Daggett has been studying misfolded proteins that lead diseases such as Alzheimers, as well as Parkinsons and others, since the 1990s. More than 5 million Americans are living with Alzheimers disease a number projected to rise to 14 million by 2050 and currently, there is no cure. Daggetts research uses computational and experimental methods to design diagnostic and therapeutic agents to target these diseases. This work has been spun out to form a company with a promising platform for early diagnosis and treatment of Alzheimers. Hear from Daggett about the technology and collaborations driving this research.
Engineering therapies for the pediatric brain
Elizabeth Nance
On Oct. 26, at 7:30 p.m. in Kane Hall 130, Elizabeth Nance, an associate professor of chemical engineering and of bioengineering, will talk about developing therapeutics for newborn and pediatric brain disease, with the goal of improving neurological function and quality of life. Children make up 27% of the worlds population, but most therapeutics for brain disease are tested on adults. Pediatric clinical trials often follow years later. This has led to a significant gap in medical technology for infants and children. Nances research focuses on understanding the brains response to injury or disease and developing nanotherapeutic platforms to treat brain disease using nanotechnology, neurobiology and data science tools.
Elizabeth Nance (background), and Hugo Pontes (foreground), who worked with Nance as a UW undergraduate student studying chemical engineering, examine thin sections of brain tissue under a microscope. Nance and Pontes were looking at how specific cells responded to a drug nanoparticle treatment to see if the treatment could reduce injury to the brain.Bryan Nakata
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Engineering lecture series focuses on health care for the brain - University of Washington
Basking Ridge software engineering company launches, looking to impact the world through technology – ROI-NJ.com
Ascendion, a newly formed software engineering company in Basking Ridge, has launched, according to a Monday announcement. The firm hopes to deliver talent transformation solutions that focus on user experience, cloud, digital platforms, data and insight, and practical applications of the metaverse.
The firms technology experts, skills development capabilities and enabling engineering platform known as AVA provide execution transparency and improved business outcomes.
Leaders in the industries we serve are seeking ways to accelerate digital innovation and transformation, Karthik Krishnamurthy, CEO of Ascendion, stated.
Ascendion clients, which include about a third of Fortune 100 companies, will benefit from industry-aligned engineering expertise, proactive client engagement and global delivery, according to a company news release.
The firm provides next-generation software engineering, co-creation delivery and commercial model flexibility to hundreds of enterprise clients, as well as fast-growing digital-first technology companies seeking ways to accelerate change while lowering innovation risk.
The shift to digital started years ago, and client demand for transformation is accelerating and evolving. We have always been a platform of possibilities for new high-value businesses, Hiten Patel, chairman of Ascendion, said.
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The Worldwide Geotechnical Engineering & Design Software Industry is Projected to Reach $1.7 Billion by 2027 – ResearchAndMarkets.com – Business…
DUBLIN--(BUSINESS WIRE)--The "Geotechnical Engineering & Design Software Market Research Report by Platform (App-based and Web-based), End User, Application, Region (Americas, Asia-Pacific, and Europe, Middle East & Africa) - Global Forecast to 2027 - Cumulative Impact of COVID-19" report has been added to ResearchAndMarkets.com's offering.
The Global Geotechnical Engineering & Design Software Market size was estimated at USD 934.09 million in 2021, USD 1,032.77 million in 2022, and is projected to grow at a CAGR 11.01% to reach USD 1,748.92 million by 2027.
Competitive Strategic Window:
The Competitive Strategic Window analyses the competitive landscape in terms of markets, applications, and geographies to help the vendor define an alignment or fit between their capabilities and opportunities for future growth prospects. It describes the optimal or favorable fit for the vendors to adopt successive merger and acquisition strategies, geography expansion, research & development, and new product introduction strategies to execute further business expansion and growth during a forecast period.
FPNV Positioning Matrix:
The FPNV Positioning Matrix evaluates and categorizes the vendors in the Geotechnical Engineering & Design Software Market based on Business Strategy (Business Growth, Industry Coverage, Financial Viability, and Channel Support) and Product Satisfaction (Value for Money, Ease of Use, Product Features, and Customer Support) that aids businesses in better decision making and understanding the competitive landscape.
Market Share Analysis:
The Market Share Analysis offers the analysis of vendors considering their contribution to the overall market. It provides the idea of its revenue generation into the overall market compared to other vendors in the space. It provides insights into how vendors are performing in terms of revenue generation and customer base compared to others. Knowing market share offers an idea of the size and competitiveness of the vendors for the base year. It reveals the market characteristics in terms of accumulation, fragmentation, dominance, and amalgamation traits.
The report provides insights on the following pointers:
1. Market Penetration: Provides comprehensive information on the market offered by the key players
2. Market Development: Provides in-depth information about lucrative emerging markets and analyze penetration across mature segments of the markets
3. Market Diversification: Provides detailed information about new product launches, untapped geographies, recent developments, and investments
4. Competitive Assessment & Intelligence: Provides an exhaustive assessment of market shares, strategies, products, certification, regulatory approvals, patent landscape, and manufacturing capabilities of the leading players
5. Product Development & Innovation: Provides intelligent insights on future technologies, R&D activities, and breakthrough product developments
The report answers questions such as:
1. What is the market size and forecast of the Global Geotechnical Engineering & Design Software Market?
2. What are the inhibiting factors and impact of COVID-19 shaping the Global Geotechnical Engineering & Design Software Market during the forecast period?
3. Which are the products/segments/applications/areas to invest in over the forecast period in the Global Geotechnical Engineering & Design Software Market?
4. What is the competitive strategic window for opportunities in the Global Geotechnical Engineering & Design Software Market?
5. What are the technology trends and regulatory frameworks in the Global Geotechnical Engineering & Design Software Market?
6. What is the market share of the leading vendors in the Global Geotechnical Engineering & Design Software Market?
7. What modes and strategic moves are considered suitable for entering the Global Geotechnical Engineering & Design Software Market?
Market Dynamics
Drivers
Restraints
Opportunities
Challenges
Companies Mentioned
For more information about this report visit https://www.researchandmarkets.com/r/5l0w
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Syntax Expands Vertical Expertise with Center of Excellence for Engineering, Construction, and Operations Sector – Business Wire
MONTREAL--(BUSINESS WIRE)--Syntax, a leading multi-cloud and mission-critical applications managed cloud provider, announced the launch of its global Engineering, Construction, and Operations (EC&O) Center of Excellence.
The newest Center of Excellence will build upon Syntaxs foundational experience and best practices across its global expertise within the industry to develop and implement leading-edge technology solutions that are purpose-built for customers in the engineering, construction, and operations sectors.
We are deeply committed to bringing proven technology solutions to customers in our core industries and our new Industry Centers of Excellence are an investment in accelerating that innovative expertise, says Christian Primeau, Global CEO at Syntax. We believe the Centers of Excellence will enable us to help our customers respond nimbly to challenges and confidently seize opportunities in a world thats changing faster than ever.
The construction and engineering sector is booming as global demand for new housing, commercial and industrial facilities, roads, and other infrastructure has soared. But as opportunities have multiplied, so have the challenges companies face.
The number of projects under construction or slated to be built are straining companies capacity to resource and manage the work. Vast supplier networks must be coordinated, while supply chain uncertainty and expanding lead times continue to drive materials shortages and shipping delays. Soaring inflation is driving material and labor prices up and putting pressure on project costs and margins. Companies struggle to find the talent they need to replace an aging, retiring workforce. Addressing and overcoming these challenges is key to the construction and engineering companies ability to remain resilient and deliver projects profitably in the years to come.
Todays dynamic, challenging environment requires construction and engineering companies to do more with less and find transformational ways to manage their projects, workforces, and businesses more effectively and profitably, says John Hilborn, Head of the EC&O Center of Excellence, and former Construction Industry executive. Embracing and maximizing managed, multi-cloud enterprise resource planning solutions is a powerful way for these companies to be more robust, future-ready, and customer-focused.
As the leader of the new CoE, Hilborn will lead a multi-disciplinary team of professionals from Europe and North America to help firms harness new technologies to gain superior visibility across their enterprises and real-time access to critical financial and operational information. Together, the team will enable leaders to make the right decisions at the right time and capitalize on opportunities as they arise.
We have worked with construction and engineering companies for many years. We understand the challenges they face, and we are committed to helping them overcome these obstacles and achieve profitable growth and long-term success through technology, says Larry Perlov, CEO of Illumiti, a Syntax company. The new EC&O Center of Excellence will serve as an innovation hub, where our subject matter experts will develop the technology solutions that our customers need to keep their projects and businesses running smoothly.
Todays announcement follows the recent launch of Syntaxs global Industry Centers of Excellence. These centers reflect Syntax and Illumitis deep knowledge base and robust capabilities in four key industry segments, including Manufacturing, Engineering, Construction and Operations, Mining and Natural Resources, and Professional Services.
About Syntax:
Syntax provides comprehensive technology solutions and trusted professional, advisory, and application management services to power businesses mission-critical applications in the cloud. With 50 years of experience and 700+ customers around the world, Syntax has deep expertise in implementing and managing multi-ERP deployments in secure private, public, or hybrid environments. Syntax partners with SAP, Oracle, JD Edwards, AWS, Microsoft, and other global technology leaders to ensure customers applications are seamless, secure, and at the forefront of enterprise technology innovation. Learn more about Syntax at http://www.syntax.com.
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