Are you soft enough for the job? The future of soft skills in technology
Think you can get away with merely having great ‘hard’ skills in a technical job? Think again. The evidence is adding up: soft skills are becoming increasingly important in the workplace. Thanks to accelerating technology, tasks that require hard skills are declining, making soft skills key differentiators for job candidates. Oxbridge Academy, a South African-based online college even goes so far as to claim that hard skills are useless without soft skills . “While [technical skills] are the skills you’ll list on your CV, today’s employers seek more than this,” they explain. Another article relates, “It won’t matter how well you understand CSS or can fix a pipe if no one can relate to you”. In a 2017 report , Deloitte Access Economics predicted that “soft skill intensive occupations will account for two-thirds of all jobs by 2030, compared to half of all jobs in 2000. The number of jobs in soft-skill intensive occupations is expected to grow at 2.5 times the rate of jobs in other occupations.” They cited technology, globalization, and demographic shifts that will change how businesses compete as reasons for this increase.
Calculated risks and dedication paves path toward IEEE Fellowship
High honor conferred to Anthony Yen, as one of many achievements in a long career driven toward realizing the volume introduction of EUV lithography; important lessons for eager engineering graduates looking to chart a path toward success The first ASML executive to earn the prestigious title of IEEE Fellow, Anthony (Tony) Yen spent more than 30 years driving toward the creation of ever-smaller integrated circuits.
ASML’s decade-long, dogged pursuit of EUV as the next-generation lithography technology was vindicated in early 2017, when ASML reported customers had placed big batches of orders for EUV systems. Billions of euros worth of orders for EUV systems silenced the skeptics who for years had claimed EUV would never be used to manufacture chips.
The era of ‘Things’ is coming and our industry is enabling it
In today’s connected world, semiconductor chips can help save energy in a smart thermostat for your home, are helping you drive your car , and can reliably monitor your heart rate with your watch . The ‘Internet of Things’ is expected to connect anywhere from 50 to 200 billion such devices by 2020. Toni Mesquida Küsters (Senior Director Product Marketing DUV at ASML) explains how these new applications of chip technology are enabled by mature lithography systems. The legendary inventor Nikola Tesla might have predicted the rise of the Internet of Things (IoT) in 1926 when he said, “When wireless is perfectly applied the whole earth will be converted into a huge brain , which in fact it is, all things being particles of a real and rhythmic whole.”
A paradigm shift in the semiconductor industry: Pattern fidelity
Ever denser chips and growing manufacturing complexity drive the need for pattern fidelity and a new class of metrology tools that detect patterning issues at the most advanced memory and logic nodes. Along with ASML’s third quarter 2017 financial results released today , the company announced the shipment of a first-of-its-kind pattern fidelity metrology tool jointly developed with newly acquired Hermes Microvision Inc. (HMI). This will enable chip makers to accelerate yield learning curves and drive higher productivity.
Knowing how to code is not enough for career success
Software development skills are in demand, as any quick scan of online job boards will confirm. But the people doing the hiring have an important piece of advice: knowing how to code isn’t enough for long-term career success. The developer skill set is changing. “Software engineering is about abstraction and structure,” says Jan Friso Groote , professor in Computer Science at the Eindhoven University of Technology (TU/e). “The real problem of software is that it is so immensely complex that if it is not well structured, it becomes unmaintainable.”
When debugging a complex manufacturing process, machine learning and data mining can uncover hidden causal relationships, dramatically shortening the search for root causes Can you determine what is causing a problem in a complex manufacturing process without attempting to understand the process itself?
Having demonstrated a throughput of 125 wafers per hour, EUV lithography moves closer to high-volume manufacturing ASML’s EUV lithography team in Veldhoven has demonstrated the throughput specification of 125 wafers per hour (wph) on an NXE:3400B system. Having already proven the other performance specifications for EUV , including imaging quality, overlay and focus, throughput was the final key spec that needed to be demonstrated.
Connecting formal and legacy systems without a single line of code
Congratulations, you’re at the forefront of computer science by using model-driven software with formal methods that mathematically prove your software designs. But unless you’re building something from scratch, you also have millions of lines of legacy code that are developed the traditional way. And your new formal designs need to interact with that legacy code — without breaking anything. That means writing adapters for your formal systems to communicate with the legacy systems, as well as anti-corruption patterns to protect the formal systems from unexpected behavior of the legacy systems.