The red line in this image represents the course the “navigatee” strolled, while the white line with dots shows the path taped by MuWNS. Credit: 2023 Hiroyuki K.M. Tanaka
Innovative technology permits navigation in locations where GPS cant reach.
In a reported global first, researchers from the University of Tokyo have actually utilized superfast, subatomic particles called muons to wirelessly navigate underground. The team used ground stations that spot muons, coordinating them with a subterranean muon-detecting receiver to pinpoint the receivers area in the basement of a six-story building.
Since GPS is ineffective through rock and water, this emerging technology holds pledge for future applications such as search and rescue objectives, keeping an eye on undersea volcanoes, and directing self-governing vehicles in below ground and marine environments.
GPS, the worldwide positioning system, is a well-established navigation tool and uses a comprehensive list of favorable applications, from safer air travel to real-time place mapping. However, it has some constraints. GPS signals are weaker at greater latitudes and can be jammed or spoofed (where a fake signal changes an authentic one). Signals can also be shown off surfaces like walls, disrupted by trees, and cant pass through buildings, rocks, or water.
Muons exist for only 2.2 microseconds (one split second is simply one-millionth of a second), however since they travel at the speed of light in a vacuum (300,000 kilometers per second), they have adequate time to reach Earth from the environment and penetrate deep into the ground. Credit: 2015 Hiroyuki K.M. Tanaka
By comparison, muons have been making headings in the last few years for their ability to assist us look deep inside volcanoes, peek through pyramids, and see inside cyclones. Muons fall continuously and regularly around the world (about 10,000 per square meter per minute) and cant be damaged.
” Cosmic-ray muons fall equally throughout the Earth and constantly take a trip at the same speed despite what matter they traverse, permeating even kilometers of rock,” explained Professor Hiroyuki Tanaka from Muographix at the University of Tokyo. “Now, by utilizing muons, we have actually established a brand-new type of GPS, which we have actually called the muometric positioning system (muPS), which works underground, inside, and underwater.”
It utilizes four muon-detecting recommendation stations aboveground to provide collaborates for a muon-detecting receiver underground. This newest research study uses high-precision quartz clocks to synchronize the ground stations with the receiver. The four parameters supplied by the referral stations plus the synchronized clocks used to determine the muons “time-of-flight” allows the receivers collaborates to be figured out.
According to the scientists, when using MuWNS in an underground or indoor environment, it could accomplish a higher precision compared to radio frequency identification (RFID) and Zigbee innovations, and a much wider range though much lower accuracy than lidar and acoustic navigation. Credit: 2023 Hiroyuki K.M. Tanaka
To check the navigation capability of MuWNS, referral detectors were put on the 6th floor of a building while a “navigatee” took a receiver detector to the basement floor. They slowly paced the passages of the basement while holding the receiver. Instead of browsing in real time, measurements were taken and used to calculate their route and validate the course they had actually taken.
” The current precision of MuWNS is between 2 meters and 25 meters, with a series of as much as 100 meters, depending on the depth and speed of the person walking. This is as excellent as, if not better than, single-point GPS positioning aboveground in metropolitan areas,” said Tanaka. “But it is still far from a practical level. Individuals require one-meter precision, and the secret to this is the time synchronization.”
Improving this system to allow real-time, meter-accurate navigation depends upon time and cash. Preferably, the team wishes to use chip-scale atomic clocks (CSAC): “CSACs are currently commercially readily available and are 2 orders of magnitude much better than the quartz clocks we currently use. Nevertheless, they are too pricey for us to use now. I visualize that they will end up being much less expensive as the worldwide need for CSAC for mobile phones increases,” stated Tanaka.
MuWNS might one day be used to navigate robots working underwater or guide self-governing lorries underground. Aside from the atomic clock, all the other electronic elements of MuWNS can now be miniaturized, so the team hopes that eventually fitting it into hand-held gadgets, like your phone, will be feasible. In emergency scenarios like a structure or mine collapse, this might be a future game changer for search and rescue groups.
Reference: “First navigation with wireless muometric navigation system (MuWNS) in underground and indoor environments” by Hiroyuki K.M. Tanaka, Giuseppe Gallo, Jon Gluyas, Osamu Kamoshida, Domenico Lo Presti, Takashi Shimizu, Sara Steigerwald, Koji. Takano, Yucheng Yang and Yusuke Yokota, 29 May 2023, iScience.DOI: 10.1016/ j.isci.2023.107000.
It uses 4 muon-detecting recommendation stations aboveground to offer coordinates for a muon-detecting receiver underground. The four criteria supplied by the reference stations plus the integrated clocks used to determine the muons “time-of-flight” enables the receivers coordinates to be determined. Rather than navigating in genuine time, measurements were taken and used to compute their route and validate the course they had taken.
Ideally, the group wants to use chip-scale atomic clocks (CSAC): “CSACs are already commercially available and are 2 orders of magnitude better than the quartz clocks we presently use. MuWNS could someday be used to browse robotics working underwater or guide self-governing automobiles underground.