In the early 1990s, I was lucky enough to get some time on a 60 MeV linear accelerator as part of an undergraduate lab course. Having had this experience, I can feel for the scientists at CERN who have had to make do with their current 13 TeV accelerator, which only manages energies some 200,000 times larger. So, I read with great interest when they announced the publication of the initial design concept for the Future Circular Collider (FCC), which promises collisions nearly an order of magnitude more energetic. The plan, which has been in the works since 2014, includes three proposals for accelerators which would succeed CERN’s current big iron, the LHC.
Want to know what’s on the horizon in high-energy physics?
Continue reading “The Future Circular Collider: Can It Unlock Mysteries Of The Universe?”
Regular readers will have followed our series of posts looking at the issues surrounding reports of drones in proximity to aircraft, and will have noted that we recently asked our community how they would approach the detection and handling of marauding drones in controlled airspace. We are mere amateurs though by comparison to a team with its roots in Delft University of Technology’s Micro Air Vehicle Laboratory, because they have approached the problem through DroneClash, a spectacle best described as akin to a Robot Wars competition for drones. Their website states that “Anything goes, with one exception: no jamming“, and teams will do battle before an audience for a share in a considerable prize fund.
The fun is not however limited to team members. People in the audience will also be able to participate, by being invited to try their luck at bringing down a TinyWhoop that will periodically fly into the arena for a chance at their own prize. The ubiquitous cheap toy drone will be accessible through software, and would-be attackers are invited to register in advance to take a pop at it.
It looks as if DroneClash will be an unmissable event for anyone able to make it to the Netherlands on March 16th. We’ve mentioned it in past years, and we look forward to seeing what comes out of it this year too.
TinyWhoop header image: Dan Lundmark, (CC BY 2.0).
There’s no doubting the wonders that micro-electromechanical systems (MEMS) technology have brought to the world. With MEMS chips, your phone can detect the slightest movement, turning it into a sensitive sensor platform that can almost anticipate what you’re going to do next. Actually, it’s kind of creepy when you think about it.
But before nano-scale MEMS inertial sensing came along, lots of products needed to know their ups from their downs, and many turned to products such as this vibrating piezoelectric gyroscope that [Kerry Wong] found in an old camcorder. The video below shows a teardown of the sensor, huge by MEMS standards but still a marvel of micro-engineering. The device is classified as a Coriolis vibratory gyroscope (CVG) which, as the name implies, uses the Coriolis effect to sense rotation. In this device, [Kerry] found that a long, narrow piezoelectric element spans the long axis of the sensor, suspended from what appears to be four flexible arms. [Kerry] probed the innards of the sensor while powered up and discovered a 22 kHz signal on the piezo element; this vibrates the bar in one plane so that when it rotates, it exerts a force on the support arms that can be detected. Indeed, [Kerry] hooked the output of the sensor to a wonderfully old-school VOM whose needle wiggled with the slightest movement of the sensor.
Sadly, MEMS made this kind of sensor obsolete, but we appreciate the look under the hood. And really, MEMS chips are using the same principle to detect motion, just on a much smaller scale. Want the MEMS basics? [Al] has you covered.
Continue reading “Piezoelectric Gyro Shows How They Rolled Back In The Day”