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‘Backrooms’ Director Kane Parsons Says Using AI ‘Defeats the Purpose’ of Filmmaking: ‘I Get No Enjoyment From Using Those Tools’

“Backrooms” director Kane Parsons recently sounded off on AI in filmmaking during a recent interview with The Australian. The 20-year-old filmmaker said that he was “in the same boat as most well-adjusted people,” and does not want to see the technology take over Hollywood. “If I could snap my fingers and make generative AI disappear […]

IEEE Spectrum

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Make a Soft Digital Clock Tick With Millifluidics

Electrons are great. We use them to move vehicles, illuminate cities, and, of course, compute. But computation is not confined to the world of electronics. And shifting to alternative nonelectronic realms can unlock unique advantages: Photonic chips, for instance, process information with light while generating little heat. Another compelling alternative is fluidics, which uses pressurized gases or liquids to build logic circuits. Pioneered in the 1960s but sidelined by microchips, the field reemerged in the 1990s as “microfluidics.” This approach aims to shrink laboratories onto a single chip by creating microscopic fluid channels with integrated micropneumatic control systems. Today, there is a second fluidic revival, this time in the domain of soft robotics. Scaling microfluidic designs up to the millimeter-scale range (millifluidics) enables the higher flow rates necessary to drive robotic actuators. These robots exploit the nonlinear behaviors of soft materials to create lifelike motion and safer interactions, often utilizing pressurized air. By building systems that “think” with the same air that powers them, we can drastically reduce the need for bulky electronic-to-pneumatic interfaces. This is the focus of my Soiboi Studio robotics lab. With millifluidic logic, I have steadily scaled the complexity of my designs. What began with a simple oscillator has most recently evolved into a clock featuring a soft, four-digit, seven-segment display. What Is Millifluidics? Building on microfluidics research from the early 2000s and recent developments from the Grover Lab at the University of California, Riverside, I’ve developed millifluidic devices using standard 3D printing and silicone casting. The basic architecture is simple: A flexible membrane is sandwiched between rigid layers embedded with networks of air channels. Just as electronics rely on differing voltage potentials, these fluidic circuits operate on the pressure difference between atmospheric pressure (logical 0) and a near-vacuum at around −60 kilopascals of relative pressure (logical 1). Using negative pressure means the membrane is pulled into openings. This creates robust seals that allow me to replicate electronic building blocks. A cast silicone membrane forms the face of the clock [top], while behind it sits 3D-printed millifluidic blocks [middle rows]. An Arduino Uno controls driver boards that operate solenoids, which are connected to valves that are attached to a vacuum pump [bottom row].James Provost While fluidic resistors are easily realized by adjusting the channel geometry, the heart of the system is a valve that mimics a metal-oxide-semiconductor field-effect transistor, or MOSFET. This vacuum “transistor” features a flow layer with two chambers (the source and drain) divided by a central valve seat and a control layer containing a cavity (the gate). A membrane runs between the control and flow layers and normally prevents airflow between the source and drain chambers. To switch the transistor on, a vacuum is applied to the gate chamber, sucking the membrane into the cavity and lifting it off the seat. This opens a path for airflow, equivalent to closing an electric circuit. By adding a small aperture to the membrane, I created a check valve—the fluidic equivalent of a diode. By combining transistors and resistive “pull-down” channels, I can build a full suite of logic gates. The original microfluidic designs that inspired me were fabricated from etched glass and milled acrylic. Adapting them for a standard 3D printer required reengineering the logic elements and mastering two critical fabrication techniques. First, I need airtight prints, yet printed plastic is notoriously porous. By printing at elevated temperatures, slow speeds, and slight overextrusion, I was able to fill microscopic gaps. When you’re using transparent filament, there’s a handy visual indicator: The more transparent the plastic appears, the lower its porosity. Second, I used glass for my print bed. By printing the upper and lower chambers directly against this bed, I got the interface surface to become mirror smooth. This finish is essential for creating reliable, airtight seals. A 0.3-millimeter silicone membrane is placed between the layers and secured with screws. How Does the Soft Clock Work? The clockface is a cast silicone membrane. Each digit segment is formed by a small underlying cavity. When air is evacuated from this cavity, the membrane is sucked inward to create a concave hollow; when atmospheric pressure is restored, the silicone pops back flush with the surface. The result is a mesmerizing, organic motion. The “brain” of the clock is an Arduino Uno, while the fluidics significantly reduce the hardware footprint. A four-digit, seven-segment display with two separator dots would require 29 solenoid valves to control directly. My clock needs just 11 valves. A pneumatic transistor is off when its upper control chamber is at atmospheric pressure [top]. When air is removed from the control chamber, it lifts a membrane, which allows air to flow between lower flow chambers and turns the transistor on [bottom]. James Provost To understand how it works, consider a standard electronic four-digit, seven-segment LED display. This also uses 11 pins to drive its digits. (In clockface displays, an additional pin is required to drive the separator dots.) Every digit is connected to a shared data bus with seven lines, one per segment. The four control lines select individual digits. Only one digit is illuminated at time, and strobing the digits at least 50 times per second creates the illusion that all four are simultaneously illuminated. Such high-speed switching is not possible with air. Instead, I rely on memory. Each segment acts like a capacitor: By evacuating its cavity (logic 1), you “charge” the segment; by restoring atmospheric pressure (logic 0), you discharge it. Hence, each digit acts as an independent 7-bit memory. If the system is sufficiently airtight, the segments maintain their state for several seconds. Like the electronic display, the system utilizes a seven-line data bus. Each line connects to a solenoid valve that provides either vacuum or atmospheric pressure. To selectively address the individual digits, I placed a fluidic transistor between each segment and its data line. All the transistors’ control inputs for a given digit are combined into one “write enable” line connected to its own solenoid valve. Activating this valve allows me to write data into the corresponding digit’s memory. The clock updates one digit per second, meaning a full cycle across the face takes 4 seconds. This cycle also drives the separator dots: A set of fluidic diodes connects the enable lines to the dots’ cavities. Consequently, as each digit is addressed, the dots pulse automatically. This display is more than a clock; it is a soft robot that happens to tell time. By offloading computation to the same air that powers movement, the clock approaches a new class of machines that are simpler, lighter, and more integrated. I’m now developing a guide for getting started with vacuum-powered logic and may release a refined version of this clock in the future. Watching the silicone skin morph serves as a fascinating reminder that not all logic needs silicon; sometimes, all you need is flexible silicone and a flow of air. This article appears in the June 2026 print issue as “The Soft Clock.”

Netweb Technologies jumps 15%, hits fresh 52-week high after rating upgrade

Shares of Netweb Technologies surged over 15% on Friday to hit their fresh 52-week high of Rs 4,680 on the NSE amid high volumes. The stock extended its gaining streak for the third session in a row, rising 21% in this period.The rally comes on the back of a ratings upgrade by CRISIL Ratings Limited. The company's Long-term rating has been upgraded to 'Crisil A+ / Stable'; while short-term rating reaffirmed to Crisil A1. Netweb offers computing solutions with fully integrated design and manufacturing capabilities. Its HCS offering comprises HPC, Private cloud and (HCI), AI systems and enterprise workstations, High performance storage (HPS) and Data Centre ServersCrisil Ratings believes NTIL will continue to benefit from the extensive experience of its promoters and established relationships with clients.The rating agency has also listed a slew of factors that will likely aid its growth. Among them are sustained revenue growth to over Rs 4,000 crore, with diversification across the end users earning steady operating margin at 13-14%, leading to higher-than-expected net cash accruals. Efficient working capital management leading to moderate dependence on debt and sustenance of healthy financial risk profile and liquidity will be another trigger according to CRISIL.It has also highlighted caveats that include the likelihood of decline in revenue below Rs 2,000 crores or fall in operating margin to below 11%, could lead to lower-than-expected net cash accrual. Meanwhile large, debt-funded capex or substantial increase in the working capital requirement, thus weakening the financial risk profile and liquidity.CRISIL shares have been market laggards, falling over 8% in 2026 while extending its decline to 24% over the past 12 months.Netweb Technologies reported Q4FY26 revenue from operations at Rs 774 crore, growing 87% year-on-year. Its operating EBITDA for Q4FY26 stood at Rs 97 crore while the adjusted operating EBITDA for Q4FY26 was Rs 102 crore, up 72% YoY, with a margin of 13.2%.(Disclaimer: Recommendations, suggestions, views and opinions given by the experts are their own. These do not represent the views of Economic Times)

마디, 식약처 임상시험계획 승인…국내 첫 PROCOVA 적용

임상시험 시뮬레이션 스타트업 마디(대표 김성환)는 자체 개발한 AI(인공지능) 예후모델과 PROCOVA(Prognostic Covariate Adjustment) 기반 통계 설계를 적용한 연구자 주도 의약품 임상시험계획이 식품의약품안전처(이하 식약처) 승인을 받았다고 27일 밝혔다. 회사 측은 AI 예후모델과 PROCOVA 방법론을 결합한 임상시험계획이 식약처 승인을 받은 것은 이번이 처음이라고 했다. 업체에 따르면 PROCOVA는 AI가 생성한 환자별 예후 점수를 임상시험 통계 분석의 공변량으로 활용하는 방법론이다. 2022년 유럽의약품청(EMA)이 2상·3상 임상시험의 1차 분석 방법으로 공식 인정했으며, 미국 식품의약국(FDA)도 현행 공변량 보정 가이던스에 부합한다고 확인했다. 임상시험의 통계적 검정력을 높여 필요한 환자 수를 줄이고 모집 기간을 단축하는 효과가 있다....

IEEE TryEngineering OnCampus Program Expands to 7 Universities

The OnCampus program, administered by IEEE Educational Activities, last year expanded its engineering experiences from two to seven universities. Part of TryEngineering, the program is held at universities around the world, offering preuniversity students hands-on opportunities to solve engineering problems. The IEEE Innovation Committee provided funding for the additional locations. New participating institutions The electrical engineering and computing faculty at the University of Zagreb, in Croatia, hosted a two-day program in June. Twenty-five children ages 10 to 14 participated in lectures and workshops on artificial intelligence, computer science, robotics, and astronomy. Tomislav Jagušt, an IEEE senior member and the chair of the IEEE preuniversity coordinating committee, led the program. In September the Arab Academy for Science, Technology, and Maritime Transport’s engineering college held a two-day session at its Abu Kir, Egypt, campus. Fifty students participated in hands-on activities on Ohm’s law, radio communications, and circuit building. They also learned from professors about engineering careers and job opportunities. Also in September, the Majan University College, in Muscat, Oman, hosted 40 high school students who competed in six challenges to design and build circuits. These include an IoT design and an LED brightness control using a potentiometer, a three-terminal, manually adjustable resistor that functions as a variable voltage divider. The program also highlighted AI and quantum computing technologies and introduced students to job opportunities in the fields. The workshop transformed curiosity into creation, empowering students with technical skills and confidence in emerging technologies. In November at the Universiti Malaysia Perlis, in Arau, 50 students explored the fundamentals of quantum computational intelligence and AI through hands-on activities and interactive simulations. IEEE Senior Member Mohd Hafiz Ismail, a professor of electronic engineering and technology, gave an introduction about quantum computing intelligence technology. The Hellenic Robotics Center of Excellence at the National Technical University of Athens hosted a two-day session in December. Twenty-five students explored robotics and AI through hands-on design challenges such as TryEngineering’s AI and machine learning methods. They also toured the university’s research facilities. Hong Kong and Greek universities participate again The City University and St. Francis University in Hong Kong, and the University of Ioannina, Arta campus, Greece, participated in the program for a second year. Under the leadership of IEEE Senior Member Paulina Chan and volunteers from the IEEE Hong Kong Section, the City and St. Francis universities jointly held the program in July. They welcomed 55 students ages 12 to 18 from 41 schools. The students attended tutorials on foundational concepts and theories of AI. They worked in small teams on projects using AI-generated images, voice, and music manipulations. They were coached by students from St. Francis and Imperial College London. The participants presented their projects to judges, teachers, and parents. The students also visited a nearby semiconductor equipment manufacturer to learn about technology careers from engineers working there. The results of a post-program survey showed strong satisfaction with OnCampus, with nearly 75 percent of participants giving it a rating of 4 or higher out of 5. “I enjoyed getting to know about deep learning and its application,” one student participant said. “The content of the activity matched my interest, and I gained new knowledge.” “OnCampus is led by a strong team with lots of experts in the field,” another said. “It’s a rare chance for students to use software, learn about the theory behind how deep learning works, and get a glance at future possibilities.” The University of Ioannina hosted the program in Arta in July with support from IEEE Senior Member Stamatis Dragoumanos and IEEE members Nikos Giannakeas and Eleftheria Kallinikou. Nearly 50 students, ages 12 to 16, attended the seven-day event, supported by 17 instructors and six volunteers from the university’s IEEE student branch. The students learned about AI, augmented reality, microchip design, microcontrollers, and 3D printing. They also attended presentations by engineers from the industry. To give the students exposure to real-world engineering, they visited two hydroelectric power plants and a green data center. At the end of the program, students presented their projects and showcased the technical skills they had developed. Those involved in the TryEngineering OnCampus program are proud of the impactful experiences students have gained. The opportunities are possible because universities open their doors, share their expertise, and invest in the next generation of innovators. The University of Zagreb, the Arab Academy for Science, Technology, and Maritime Transport, the Majan University College, and The City University and St. Francis University will be participating again this year. To learn how you can bring the OnCampus program to your educational institution, send a request to tryengineering@ieee.org.

IEEE Spectrum

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Mattress Firm Coupons: Save up to $600

‘Backrooms’ Director Kane Parsons Says Using AI ‘Defeats the Purpose’ of Filmmaking: ‘I Get No Enjoyment From Using Those Tools’

Layla Sleep Coupon: Save Up to $600 in June 2026

How the middle-class should adjust to AI economy

Make a Soft Digital Clock Tick With Millifluidics

Okta's revenue surged as agentic AI stoked demand for identity security tools

Netweb Technologies jumps 15%, hits fresh 52-week high after rating upgrade

The AI data center race is getting way more complicated

마디, 식약처 임상시험계획 승인…국내 첫 PROCOVA 적용

IEEE TryEngineering OnCampus Program Expands to 7 Universities

The Herman Miller Coyl Standing Desk Is Built Just for Gamers

뉴스

타임라인 키워드

Mattress Firm Coupons: Save up to $600

‘Backrooms’ Director Kane Parsons Says Using AI ‘Defeats the Purpose’ of Filmmaking: ‘I Get No Enjoyment From Using Those Tools’

Layla Sleep Coupon: Save Up to $600 in June 2026

How the middle-class should adjust to AI economy

Make a Soft Digital Clock Tick With Millifluidics

Okta's revenue surged as agentic AI stoked demand for identity security tools

Netweb Technologies jumps 15%, hits fresh 52-week high after rating upgrade

The AI data center race is getting way more complicated

마디, 식약처 임상시험계획 승인…국내 첫 PROCOVA 적용

IEEE TryEngineering OnCampus Program Expands to 7 Universities

The Herman Miller Coyl Standing Desk Is Built Just for Gamers