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A group of Flat Earthers spent $20,000 on experiments to prove the Earth is flat, including using a high-precision laser gyroscope and a light beam test. Both experiments accidentally provided clear evidence that the Earth is round.
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"After 30 years of painstaking development, researchers in Germany and New Zealand have unveiled a laser gyroscope that can track fluctuations in Earth’s rotation in near real time and accurate to several milliseconds. The technique is much simpler than current methods and could provide further insights into phenomena that cause the fluctuations – such as shifts in ocean currents.
The Earth rotates once in one day, but there are tiny fluctuations in the rate and direction of our planet’s rotation. Some of these fluctuations are well understood – for example those caused by the tidal forces of the Moon and Sun.
Other tiny fluctuations are not well understood including those related to the exchange of momentum between the solid Earth and the oceans, atmosphere and ice sheets. These effects can arise from climate events such as the El Niño southern oscillation, which change ocean currents. As a result, measuring fluctuations in Earth’s rotation could shed light on important processes in the atmosphere.
Most rotation studies involve combining data from global satellite navigation systems; very long baseline radio-astronomy observations of quasars; and laser ranging. Due to the complexity of combining these techniques, only one measurement can be made per day.
Now, a team headed by Ulrich Schreiber at the Technical University of Munich has created a laser gyroscope that can measure the tiny fluctuations in near real time. What is more, their instrument can fit into a large room."
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#earth#rotation#spinning#night and day#axis#earth axis#sun#poles#magnetic poles#moon#solar system#atmosphere#temperature#laser gyroscope#light#science#physics#technology#fluctuation#oceans#currents
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RLG Technology to Drive $1.1 Billion Market by 2031, Fueled by Precision Navigation Needs

The global Ring Laser Gyroscope (RLG) market is poised for substantial growth over the next decade, driven by the burgeoning demand for advanced navigation systems across aerospace, defense, and consumer electronics sectors. Valued at US$ 796.8 million in 2022, the market is forecast to expand at a Compound Annual Growth Rate (CAGR) of 3.6%, reaching an estimated US$ 1.1 billion by 2031. The advancements in both technology and demand for more precise motion sensing systems are expected to shape the trajectory of this industry, with various stakeholders—including manufacturers, developers, and end-users—focusing on high-precision and reliable solutions.
Market Overview
Ring Laser Gyroscopes (RLGs) are vital components in the world of precision navigation and stabilization. These gyroscopes rely on optical principles and the interference of laser beams to measure angular velocity with extraordinary sensitivity and accuracy. Their role in inertial measurement units (IMUs), inertial navigation systems (INS), and various military applications is undeniable. They are used in aerospace, defense, and consumer electronics for applications that require accurate positioning and orientation data, such as autopilots, satellite guidance, and augmented reality (AR) systems.
In the ring laser gyroscope market, the adoption of cutting-edge technologies is paramount, with key players like Honeywell International Inc., Mitsubishi Precision Co., Ltd., and Northrop Grumman leading the way. The market is being propelled by a surge in aviation activity, the rise of consumer electronics, and technological advancements in precision navigation systems, including the integration of AI and machine learning to enhance gyroscope performance.
Market Drivers and Trends
The Ring Laser Gyroscope market is influenced by several drivers and trends:
Rapid Growth in the Aviation Sector The aviation industry continues to see exponential growth, with a marked increase in global air traffic. According to the International Air Transport Association (IATA), air traffic surged by 122.2% in September 2022 compared to the previous year. As more aircraft are deployed globally, there is a heightened demand for advanced navigation systems equipped with RLGs, which play a critical role in autopilot and flight control systems. Ring laser gyroscopes, known for their high reliability, are essential for maintaining accurate orientation and ensuring smooth flight operations, particularly in GPS-denied environments.
Consumer Electronics Expansion The consumer electronics sector is witnessing an unprecedented boom, driven by increased online entertainment consumption, gaming, and the growing trend of smart devices. RLGs are integral to devices such as smartphones, tablets, and smart televisions, which rely on precise motion sensing for applications like virtual navigation, augmented reality (AR), and 360-degree video processing. As demand for such devices soars, the market for ring laser gyroscopes is expanding, offering innovative navigation solutions.
Technological Advancements in Navigation Systems As the need for more advanced, accurate, and resilient navigation systems grows, manufacturers are embracing new technologies. RLGs are now being integrated with artificial intelligence (AI) and machine learning (ML) algorithms, ensuring real-time performance optimizations that were once unimaginable. This technological shift not only improves the gyroscope's efficiency but also allows for predictive calibration and self-correction during operation.
Key Players and Industry Leaders
Ericco Inertial System
Heppell Photonics
Honeywell International Inc.
Kearfott Corporation
Mitsubishi Precision Co., Ltd.
Northrop Grumman
Optics Blazers AG
Safran Electronics & Defense SAS
Teledyne CDL
Movella Inc.
Recent Developments in the Market
Honeywell’s eTALIN II 6000 (August 2023) Honeywell introduced its eTALIN II 6000 system, a groundbreaking development aimed at enhancing the performance of combat vehicles in GPS-denied environments. The product leverages advanced RLG technology, accelerometers, and embedded GPS to deliver cutting-edge off-road land navigation.
STMicroelectronics’ ASM330LHHX (May 2022) STMicroelectronics developed a compact inertial measurement unit (IMU) featuring a 3-axis accelerometer and 3-axis gyroscope, designed for smart driving and higher automation levels in automotive systems. This IMU incorporates machine learning (ML) algorithms to optimize system performance.
Market New Opportunities and Challenges
The market presents a host of opportunities for growth. The increasing reliance on precision navigation systems in both civil and military sectors is driving a surge in demand for RLG-based solutions. Innovations in the space industry, particularly with satellite positioning systems and spacecraft navigation, offer immense growth potential for ring laser gyroscopes.
However, challenges remain, such as high production costs, especially in the manufacturing of high-precision RLG systems, and the need for continuous research and development to stay ahead of technological trends. Moreover, the market faces intense competition, which necessitates constant innovation to meet the evolving demands of industries like aerospace, defense, and consumer electronics.
Market Segmentation
The global Ring Laser Gyroscope market is segmented as follows:
Number of Axes: Single Axis, Multi-Axis
Applications: Platform Stabilization, Missile Navigation, Aeronautics Navigation, Submarine Navigation
End-User:
Commercial: Air-based (Aircraft, Drones), Marine-based
Defense: Air-based (Aircraft, Drones), Marine-based, Spacecraft
Regions: North America, Europe, Asia Pacific, South America, Middle East & Africa
Regional Insights
North America holds the largest share of the ring laser gyroscope market. The rapid adoption of RLGs in military applications and the significant investments in the aerospace and defense sectors are major factors fueling market growth in this region. The United States, in particular, is witnessing a surge in tourism and air travel, which is driving demand for advanced navigation systems in commercial aircraft. With a projected increase in air traffic and defense spending, North America is set to maintain its dominance throughout the forecast period.
Why Buy This Report?
The Ring Laser Gyroscope Market report offers critical insights into the current and future market dynamics, providing a comprehensive analysis of the growth drivers, emerging opportunities, challenges, and technological advancements shaping the industry. Key stakeholders in aerospace, defense, and consumer electronics can leverage this report to make informed decisions, optimize their business strategies, and stay ahead of the competition in this fast-evolving market.
Additionally, this report includes detailed company profiles, market segmentation analysis, and a regional breakdown, allowing businesses to identify new growth areas, expand their product portfolios, and assess potential risks and opportunities in various geographical regions.
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Ring Laser Gyroscope Market Trends, Opportunities, Current Analysis and Forecast (2024-2032) I UnivDatos

Introduction:
According to the UnivDatos, growing demand for cockpit digitalization with ring laser gyroscopes with increased efficiency will drive the growth scenario of Ring Laser Gyroscopes and as per their Ring Laser Gyroscope Market report, the global market was valued at USD 812.3 million in 2023, growing at a CAGR of 3.21% during the forecast period from 2024 - 2032 to reach USD million by 2032.
Ring laser gyroscopes are small, lightweight, radiation-tolerant, and compact devices placed within aircraft, spaceships, marine systems, missiles, etc. These devices help the vehicles for course correction in air and space with the help of a narrow body light waveform traveling a path, created by using mirrors. Some of the key applications of ring laser gyroscopes are in autonomous systems, autonomous agriculture, aerospace, defense, marine, subsea, etc.
Access sample report (including graphs, charts, and figures) https://univdatos.com/reports/ring-laser-gyroscope-market?popup=report-enquiry
Rising Trend of UAV and Unmanned Aerial Vehicles to Promote Ring Laser Gyroscope Demand:
Drone and Unmanned Aerial vehicles have gained significant prominence among aircraft manufacturers as they offer better flexibility and lower risk in terms of losing a pilot. These drones are lightweight offering high range and long endurance which make them an excellent option for surveillance activities. However, due to the extensive reliance on traveling on a pre-determined path, the demand for ring laser gyroscopes has noticeably grown. These ring laser gyroscopes assist the drones in providing the necessary precision and stability during flight. Many of the large-scale UAV/Drone purchase projects have been announced which would be paramount for improving the demand for ring laser gyroscopes in the coming years. For instance, in 2023, the government of India announced to purchase of 31 MQ-9B armed drones with a total cost of USD 3.99 billion. The drones manufactured by General Atomics would help the country bolster its reconnaissance and sea-guarding capabilities in the long term.
In another instance, in 2023, the government of Ukraine announced to spending of USD 540 million on the purchase of drones to strengthen its capabilities against Russian forces. The respective drones will be purchased from 16 domestic companies and a foreign company Quantum-Systems (Germany).
Considering the rising demand for UAVs and drones among the leading militaries across the globe the demand for crucial navigation systems such as ring laser gyroscopes will also experience a surge in demand assisting its market growth during 2024-2032.
Click here to view the Report Description & TOC https://univdatos.com/reports/ring-laser-gyroscope-market
Increasing Demand for Precision Navigation for Aerospace & Missile Systems:
In recent years, the demand for long-range aerial and space missions has earmarked the need to integrate multi-axis ring laser gyroscopes. These gyroscopes assist in providing 3D modeling for path projection as well as keeping the vehicle on the desired path. With the rising geopolitical tensions many of the leading militaries across the globe have focused on expanding their strategic missile capabilities further leading to promote the need for ring laser gyroscopes. For instance, in 2024, the US government announced to deployment new long-range strike hypersonic missile in Germany by 2026. The respective batteries would include SM6, Tomahawk missiles, and developmental hypersonic missiles.
In another instance, in 2024 four European nations announced to jointly collaborate to develop long-range cruise missiles with a range beyond 500 km. France, Germany, Italy, and Poland have planned to develop missiles in counter to the looming cruise missile threat in Europe.
Conclusion:
The Global Ring Laser Gyroscope market is experiencing a transformative phase driven by technological advancements, sustainability space operations, digitalization, market dynamics, and implementation of government policies. Stakeholders across the industry are embracing these trends to enhance operational efficiency, integrating mobility assisting systems, etc. As UAV and Drones continue to play a strategic role in improving aviation and online delivery services, staying abreast of these trends and embracing innovation will be crucial for the Global Ring Laser Gyroscope market.
Contact Us:
UnivDatos
Contact Number - +1 978 733 0253
Email - [email protected]
Website - www.univdatos.com
LinkedIn- https://www.linkedin.com/company/univ-datos-market-insight/mycompany/
#Ring Laser Gyroscope Market#market forecast#market insights#market share#market research#market trends#marketinsights
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Invented in 1963.
Science is so cool.
Y’all have heard of ring laser gyroscopes right? Actual little neon bulbs that do a physics experiment to determine exactly how much it’s being rotated.

Apparently they can’t measure low rotation speed due to the laser beams coupling to each other’s frequency. Their solution is to vibrate it with white noise so it never settles enough



Source has a bunch of lovely images
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Ring Laser Gyroscope Market Size, Share, Growth, Trends And Forecast 2024-2032
Introduction:
Ring laser gyroscopes are small, lightweight, radiation-tolerant, and compact devices placed within aircraft, spaceships, marine systems, missiles, etc. These devices help the vehicles for course correction in air and space with the help of a narrowbody light waveform traveling a path, created by using mirrors. Some of the key applications of ring laser gyroscopes are in autonomous systems, autonomous agriculture, aerospace, defense, marine, subsea, etc.
Request Free Sample Pages with Graphs and Figures Here - https://univdatos.com/get-a-free-sample-form-php/?product_id=64418
Rising Trend of UAV and Unmanned Aerial Vehicles to Promote Ring Laser Gyroscope Demand:
Drone and Unmanned Aerial vehicles have gained significant prominence among aircraft manufacturers as they offer better flexibility and lower risk in terms of losing a pilot. These drones are lightweight offering high range and long endurance which make them an excellent option for surveillance activities. However, due to the extensive reliance on traveling on a pre-determined path, the demand for ring laser gyroscopes has noticeably grown. These ring laser gyroscopes assist the drones in providing the necessary precision and stability during flight. Many of the large-scale UAV/Drone purchase projects have been announced which would be paramount for improving the demand for ring laser gyroscopes in the coming years. For instance, in 2023, the government of India announced to purchase of 31 MQ-9B armed drones with a total cost of USD 3.99 billion. The drones manufactured by General Atomics would help the country bolster its reconnaissance and sea-guarding capabilities in the long term.
In another instance, in 2023, the government of Ukraine announced to spending of USD 540 million on the purchase of drones to strengthen its capabilities against Russian forces. The respective drones will be purchased from 16 domestic companies and a foreign company Quantum-Systems (Germany).
Considering the rising demand for UAVs and drones among the leading militaries across the globe the demand for crucial navigation systems such as ring laser gyroscopes will also experience a surge in demand assisting its market growth during 2024-2032.
Increasing Demand for Precision Navigation for Aerospace & Missile Systems:
In recent years, the demand for long-range aerial and space missions has earmarked the need to integrate multi-axis ring laser gyroscopes. These gyroscopes assist in providing 3D modeling for path projection as well as keeping the vehicle on the desired path. With the rising geopolitical tensions many of the leading militaries across the globe have focused on expanding their strategic missile capabilities further leading to promote the need for ring laser gyroscopes. For instance, in 2024, the US government announced to deployment new long-range strike hypersonic missile in Germany by 2026. The respective batteries would include SM6, Tomahawk missiles, and developmental hypersonic missiles.
In another instance, in 2024 four European nations announced to jointly collaborate to develop long-range cruise missiles with a range beyond 500 km. France, Germany, Italy, and Poland have planned to develop missiles in counter to the looming cruise missile threat in Europe.
Request for TOC, Research Methodology & Insights Reports - https://univdatos.com/report/ring-laser-gyroscope-market/
Conclusion:
The Global Ring Laser Gyroscope market is experiencing a transformative phase driven by technological advancements, sustainability space operations, digitalization, market dynamics, and implementation of government policies. Stakeholders across the industry are embracing these trends to enhance operational efficiency, integrating mobility assisting systems, etc. As UAV and Drones continue to play a strategic role in improving aviation and online delivery services, staying abreast of these trends and embracing innovation will be crucial for the Global Ring Laser Gyroscope market. According to the UnivDatos Market Insights Analysis, growing demand for cockpit digitalization with ring laser gyroscopes with increased efficiency will drive the growth scenario of Ring Laser Gyroscopes and as per their “Ring Laser Gyroscope Market” report, the global market was valued at USD 812.3 million in 2023, growing at a CAGR of 3.21% during the forecast period from 2024 - 2032 to reach USD million by 2032.
Contact Us:
UnivDatos Market Insights
Contact Number - +1 9782263411
Email - [email protected]
Website - www.univdatos.com
#Ring Laser Gyroscope Market#Ring Laser Gyroscope Market Size#Ring Laser Gyroscope Market Share#Ring Laser Gyroscope Market Growth#Ring Laser Gyroscope Market Trends#Ring Laser Gyroscope Market Analysis
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Literally anytime anyone says "my headcanon" I picture something like this.
#gyroscopically stabilized#laser range finder#dual lidar atmospheric density correction sounders#120mm diameter#high explosive anti-tank#optional anti-personnel rounds
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DP X Marvel #27
Danny wasn’t trying to become a supervillain’s protégé. Honestly, he was just trying to survive another semester at MIT without spontaneously combusting from stress. At nineteen, between triple-majoring in Astrophysics, Mechanical Engineering, and Paranormal Biochemistry—and moonlighting as the occasionally-glowy, occasionally-exploding, semi-competent vigilante known to the public as Phantom—Danny was hanging on by a thread. A very frayed, very caffeine-soaked thread. So when one of his professors suggested a special “independent study project” with a visiting Latverian dignitary-slash-scientist, Danny said yes without thinking. He needed the credits. He needed the money. He needed the free lunch vouchers. What he did not need, apparently, was to accidentally apprentice himself to Doctor Fucking’ Doom.
At first, he didn’t know. To Danny, “Victor” was just this weird, intense European dude with a crazy sense of fashion (who the hell wore a green cape in broad daylight?) and a laugh that definitely belonged in a villain origin story. But Victor paid well, never judged him for falling asleep mid-sentence, and always had the best coffee imported from who-knows-where. Danny figured he was just some rich old nerd with a lot of quirks. Maybe a little murder-y, but hey, Danny was from Amity Park. His standards for “dangerous mentor figure” were catastrophically low.
“Daniel,” Victor intoned one day, standing over a schematic that looked suspiciously like a laser death satellite. “Tell me: what improvements would you make to a mobile interdimensional particle cannon capable of vaporizing Manhattan?”
Danny, who hadn’t slept in three days and thought this was just a theoretical design, squinted at the blueprints and muttered, “Uh… you forgot the phase stabilizer. Without it, the cannon would rip itself apart before you could fire. Also, your aim’s gonna suck unless you recalibrate the gyroscopic system.”
Victor went unnaturally still. “Explain.”
Danny yawned so hard his jaw cracked. “M’kay, so if you adjust the vibrational harmonics here”—he drew all over the deadly weapon diagram with a crayon—“and rework the mana-infused crystal lattice to resonate at a higher frequency… boom. Stable, precise, terrifying. A+ on your murder machine, Professor Von Evilcape.”
Victor stared at him for a long time. Then he laughed. Not just any laugh. A full, villainous, booming laugh that echoed through the lab and set off three alarms in the next building over. Danny didn’t even blink. He just kept doodling tiny ghosts on the margins of the schematic.
From that moment onward, Victor—Doctor Doom, actual dictator of Latveria, sorcerer supreme wannabe, world-class narcissist—decided Danny was his heir apparent. His secret weapon. His beautiful chaotic son who understood him better than any of the clowns in Latveria ever had. He didn’t ask Danny if he wanted the role. He just started sending Danny increasingly absurd “assignments” that Danny, running on Monster Energy and bad life choices, completed without registering how criminally insane they were.
Case in point: one evening, Danny stumbled into the lab with a Red Bull in one hand and a half-eaten burrito in the other. Victor handed him a device.
“Install this at Stark Tower.”
Danny blinked at the tiny, harmless-looking black box. “Uh, what is it?”
“A signal booster for quantum research purposes.”
Danny, who trusted absolutely no one and also didn’t care because he had a paper due at midnight, shrugged. “Okay, cool.”
He broke into Stark Tower that night with the ease of a sleepwalking raccoon, installed the “signal booster” inside one of Tony Stark’s servers, and left. The next morning, the news was screaming about a massive data breach that almost triggered World War III. Danny was too busy trying to finish his midterm essay on quantum entanglement to notice.
“Good work, Daniel,” Victor said approvingly during their next meeting, clapping him on the back so hard he almost faceplanted into a dimensional rift. “You have the soul of a conqueror.”
“Thanks, man,” Danny mumbled, chugging coffee straight from the pot.
Victor took it a step further. He started introducing Danny at fancy functions. “This is Daniel. He is my most promising apprentice. One day he will inherit my empire.”
Danny, half-dead from exams and not paying attention, just nodded absently and said, “Yup. Love the Empire Strikes Back. Great movie. Big fan.”
Victor beamed.
It wasn’t until six months later, after the “Study Abroad” paperwork (actually an all-expenses-paid trip to Latveria) and the suspiciously grand laboratory gifted to him “for his brilliance,” that Danny realized something was deeply wrong.
He was skimming through some documents on Victor’s encrypted network—because of course Doom had an encrypted network called “DoomNet”—when he found it.
Last Will and Testament of Victor Von Doom: In the event of my death, all of Latveria, my scientific research, all proprietary technology, magical artifacts, nuclear launch codes, hidden doomsday devices, and the title of Supreme Monarch will pass to my chosen heir: Daniel Fenton, aka “Phantom,” aka “My Beautiful Disaster Child.”
Danny read it three times.
“Wait. Wait, wait, wait,” he whispered, voice cracking. “Am I—AM I A VILLAIN PRINCE?!”
Cue the world’s most pathetic breakdown.
“NO NO NO NO NO. I JUST WANTED A DAMN SCHOLARSHIP!” He hurled a coffee mug at the wall. It phased through because he lost control of his intangibility again. “THIS IS WHAT I GET FOR TRUSTING ANYONE IN A CAPE.”
Danny spent the next two hours panic-researching Victor Von Doom. It was bad. It was really bad. It was, like, world-endingly bad. Murder records. Wars. Kidnapping Reed Richards’ kids. Banning Beyoncé from Latveria because she rejected his dinner invitation. BAD.
And it was too late. Doom had gone on international television that morning and announced Danny’s name as his successor.
“I have chosen my heir,” Doom declared, standing proudly atop his gold-plated balcony while cameras flashed below. “The boy shall inherit everything I have built. Bow before your future king, Daniel Fenton!”
Meanwhile, in his MIT dorm room, Danny choked on his cereal.
“Oh my God,” Tucker screamed over Facetime. “YOU’RE DOOM JUNIOR!”
Jazz was furiously typing. “Danny, that’s treason. Like, actual treason.”
Sam just stared at him with unholy glee. “So… when are you conquering America?”
“NEVER,” Danny screeched.
Too late. The Avengers showed up at MIT the next day. It was not subtle.
Tony Stark crashed into Danny’s quantum physics lecture, kicked open the door, and pointed dramatically at him. “YOU!”
Danny, hunched over his notes and running on negative hours of sleep, blinked. “Me?”
“Yeah, you, Doom Boy,” Tony said, stomping down the aisle while half the class screamed and ducked for cover. “You hacked my servers, hijacked my satellites, and installed a literal doom-signal into my mainframe. Care to explain, junior dictator?”
Danny held up his hands. “Okay, look. In my defense, I thought it was a Wi-Fi booster.”
Steve Rogers leaned in. “Are you actively trying to destroy America?”
Danny’s eye twitched. “Sir, I am actively trying to pass Organic Chemistry.”
Natasha Romanoff clicked a pen menacingly. “Are you or are you not plotting to overthrow the world?”
Danny hesitated. “I mean… define ‘plotting’?”
There was a long, painful silence.
Tony sighed, dragging a hand down his face. “Kid. You’re on, like, several different international watchlists. Half of SHIELD thinks you’re planning to nuke New York.”
Danny’s voice cracked. “I didn’t even know how to do laundry until last month.”
And thus began the most chaotic custody battle in history: Doom versus the Avengers versus Danny versus himself.
Victor, naturally, was thrilled. He sent Danny monogrammed armor. A custom throne. A letter that read “My son, all great rulers are hated before they are loved. However feat not. Seize your destiny.”
Danny sent it back with a post-it note that said “pls stop.”
Tony tried to recruit him instead. ���Work for me. You like tech, you like coffee, you’re already better at hacking than Peter—”
“HEY,” Peter Parker shouted from across the hall.
Danny groaned into his hands. “I don’t want to work for anyone! I just want a nap!”
Sam Wilson patted him on the back sympathetically. “Welcome to adulthood, kid.”
Things escalated horrifyingly fast. Latverian officials tried to smuggle Danny out of Massachusetts under the cover of night. Doom built a life-sized gold statue of him in Latveria’s capital square. The Avengers started putting “Phantom Threat Level: High” on their briefing files. Nick Fury cornered him in a diner and deadpanned, “Son, you’re one bad day away from becoming an international incident.”
Danny, shoving pancakes in his mouth, muffled, “I don’t wanna.”
Of course, life didn’t let him off that easy.
When Doom inevitably “died”—allegedly vaporized by a malfunctioning time machine because of course he did—Danny woke up to find a legal team at his dorm room.
“Congratulations, Your Majesty,” the lead lawyer said with an evil smile. “You are now King of Latveria.”
Danny fainted on the spot.
He woke up fifteen minutes later to find Sam fanning him with a Doom flag and Tucker wearing a Latverian general’s hat he stole from one of the lawyers.
“So…” Tucker grinned. “Wanna invade Canada first?”
Danny screamed into his pillow.
And somewhere, deep in the void between worlds, Doom—very much alive and sipping espresso—chuckled darkly.
“Atta boy, Daniel,” he whispered. “Atta boy.”
#danny fenton#danny phantom#dp x marvel#danny phantom fanfiction#marvel#marvel mcu#mcu#mcu fandom#crossover#danny phantom fandom#marvel fandom#marvel fanfic#mcu fanfiction#dr doom#victor von doom
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The IU-3 Billhook is, above all, a really bizarre mech. This was actually one of the first chassis designs produced by the PDR, a few months after they had already been facing down Purview teams, but it ain't your typical line mech. See, the Republic obviously can't outdo the Armory on quality or quantity in a straight up fight, so they got clever with these little bastards when a head on engagement was unavoidable. The first thing you'll notice is the giant tumorous growth of a shell hanging off the back. It's got a few minor hardpoints in it, along with a ton of reactive armor, enough to draw attention and make you assume it's a weakpoint that would cripple the machine if you took it out- but it's actually just an empty, detachable storage unit, only occasionally carrying some non-volatile supplies. The entire damn chassis is built like that, everything put in a weird place and disguised as something it isn't- even the joints have an annoyingly weird placement that makes maintenance a pain, but if that means offsetting the amount of bullets you have to pull out, I guess it's a win. Overall, it's substandard to even some outdated SP1 models, but with how cheap it is to build and how effective the gimmick can be, it sees a lot of use. That's just the thing, though, it's a gimmick. If the enemy knows what horseshit you're trying to pull, all you've done is bring a knife to a gun fight- so, usually, these things are the first units to see combat in any given conflict, and are outfitted for an alpha strike without regard to operating time or endurance. Single-shot weapons with fuck-off payloads, the works. On the high-mobility types that are built for repeated engagements, though, you've got a more standard loadout, and the storage unit gets filled to the brim with gyroscopes and reaction wheels alongside some crazy FCS that lets you get some damn good mileage out of the PD lasers in the antennae when you're up close.
i was having artblock trying to think of an idea and my friend said to me "hey, why don't you make a mech based on, i dunno, a snail?" and i told her "primrose pandora screamermod you are a fucking genius" and then spent 3 days making this thing along with the above flavor text for it. does this count as an oc, who knows but i'm posting it now because jegus dick it took a long ass time
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Sticking things into the ground just works. sorta
Relativistic sub-space anchor. A miracle of advanced technology. It hooks "into" the fabric of space itself. This enables us to... uhh, I'm sure there's some application.
Basically, it's a really fancy gyroscope with a billion exotic particles doing quantum things in a relativistic way and other garbled science words.
In short - turn it on and it and whatever it is attached to stays in place. Not in relation to any other objects. In the, let's say, "grid" coordinates of space.
So, everything in space is always moving, right? - planets, stars, galaxies, space whales, dark matter, and so on. The scale and gravitational influence of some of these is so massive that it 'looks' like you're stationary, but only in relation to the home object. The sub-space anchor, in contrast, would appear to move at roughly ludicrous speeds the moment you activated one.
Now, only the infused particle quantum matter energy actually stays in place, so the 'handbrake' nature of the act means any other attached matter would experience g-forces the likes of which nothing else can achieve in literally no time at all. Like, not even a nanosecond. The anchor only interacts with the space part in space-time.
The first ones we experimented on, umm, ripped apart our lab, so we didn't actually realize what had happened properly until the third time. And even then we figured it out only because, technically speaking, the Moon moved into the anchor, causing a minor explosion that we managed to notice.
We tried using it as a sort of instant maneuvering "jet" for our fighter craft, where the anchor is connected with semi-elastic girders to the rest of the ship, activate it for the shortest burst possible, then fling it in the desired direction. So far nothing has endured more than two such swings. Half the time most of the outer plating and mounted platforms just get thrown off.
As a weapon itself, it's not really that useful. You have to position it first since our relative motion within space is mostly constant, and the speed is less than our rail guns anyway, plus all the tech that goes into the anchor. I mean, yeah, it's neat to make someone hit an immovable rod, but, uhh, shooting a piece of ore with magnets works better. We'll stick with that.
And lasers. Lasers are cool.
#humans are space orcs#humans are space australians#humans are space oddities#humans are deathworlders#humanity fuck yeah#carionto
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The fact that lightsabers are only used by force users is both really weird, but also funny if you think about it. Because over the years, there have been a bunch of random explanations- that Jedi / Sith are the only ones able to find Kyber crystals, that you need to be able to use the force to use the saber, that your emotions dictate how the blade works for you, etc.- all of which make sense but are also kinda dumb if you think about it.
but I like the idea that lightsabers are just a pain in the ass to use if you don’t have force sensitivity. Like yeah, you could have a whole unit of people who use lightsabers, but the lifetime of training needed to use them effectively would be insane. And Jedi / Sith just have these skills built in, even in their most basic level.
First, you need to be able to not stab or burn yourself by accident every time you use it, something that’s really easy to do with a plasma blade that will burn with the tiniest touch, and something that having the force (with precognition and some form of dangersense) helps with. You need to have the situational awareness that comes with actually being able to run up to an opponent and hit them- again, precognition and danger sense. And good luck blocking blaster bolts, estimates have their speed around 100-130 mph and you need to block a bunch of them- something that becomes way easier if you have magical space energy telling you where and how to block.
but dueling with a lightsaber when you don’t know what you’re doing would actually be a nightmare. Real life sword fights are actually way faster than in fiction, and in this scenario even just a hit to the wrist would be debilitating. And depending on which version you use, blades are either weightless (meaning they would be able to slash and zip around quicker and be harder to defend against), have a gyroscopic effect / air resistance (making them hard to use without proper form or training), or just have other weird factors to deal with considering they’re just flashlights with a long stick of solid energy sticking out of it. Meaning that if you’re in a duel, it’s either a matter of skill, and / or a matter of who makes a mistake first, which is a crazy drawback to have in a fight where a small cut can be debilitating, and a large cut can literally bisect you. You know what mitigates this risk? Having magical space powers which can A) tell you when something is about to happen before it even happens, B) give you crazy acrobatic skills, agility, and strength which can give you an edge (or at least remove your opponent’s), or C) give you crazy intuition and knowledge on forms, correct moves, and how to predict and counter your opponent
that’s not to say that someone probably couldn’t become a skilled swordsman or duelist with a lightsaber, or wouldn’t at least be more effective once they’ve had years of training (as evident by how generations of fans and culture have demonstrated, as well as awesome and badass actors who shot these scenes and (supposedly) don’t have magical space powers), but there’s a reason we in the real world migrated to guns, and it’s much easier to learn or train that and other combat skills and awareness than how to use a magical laser sword
#Star wars#lightsaber#jedi#Sith#sword fighting#swords#Clone / mandalorian propaganda#I say that the actors “supposedly” don’t have magical space powers#Because it’s unlikely and there’s no way to prove it#But look at Ewan McGregor and tell me that there’s not a dash of space magic in that man#And Hayden Christensen was making his own lightsaber moves as he went so
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Scythe Model: Arrowhead
An interceptor-fighter craft known for its speed and unique style of combat that had made it the bane of all Imperial attempts at air superiority. The Arrowhead Model is specialized for Aeronautics combat, while its much larger and heavily armed variant, the Viper, is specifically constructed as an orbital fighter.
General Design:
Shaped like a leaf, the Arrowhead is quite small for an aircraft, not even nine meters long, with a width of three meters, its small profile makes it a challenge to target, especially when its right up in your face about its deadly intentions. Yet its proportions hide a surprisingly sturdy frame, on top of having a passive sensor mask that makes it very challenging for standard targeting equipment to get a lock on it or detect their approach until they are almost on top of its target.
Propulsion and Manoeuvrability:
The Arrowhead Scythe is propelled by six thruster engines at its caudal side that are not too dissimilar to the design of the plasma thrusters on void ships, if only with a much smaller profile. Furthermore, it is aided by grav-plates to remain suspended in the air without the need of wings to support its flight. However, these are not the most outstanding features of this craft, those would have to be the Gyroscopes.
Mechanicum adepts are still in heated debates as to the inner workings of recovered pieces of the Gyroscopes, as they have been dubbed, from dead Arrowhead craft. But what they all agree upon its that they are the singular most fundamental piece in the Arrowhead’s near physics defying agility.
Named after the device they most closely resemble in appearance; it is theorized they emit some form of gravitational anchor point that allows the craft to always be relative in their positioning to the closest primary gravitational well.
This is how the Arrowhead is able to remain in stable flight and turn without the need of any form of wings, as well as perform manoeuvres that would otherwise kill an organic pilot within. For instance, by simply rotating both Gyroscopes inside the Arrowhead in the same direction along a horizontal plane, the craft immediately spins on its axis without changing direction, allowing it to suddenly turn around on a pursuing target and light it up with its main armament before reconfiguring its trajectory back into a stable flight configuration.
For this reason alone, the Arrowhead has earned the righteous ire and fear of all Imperial pilots who have ever faced them in battle and survived to tell the tale.
Weaponry:
Arrowheads are a significant threat to face in combat, made all the deadlier by their arsenal.
Primary Weapon: Arrowheads maintain their weapons locked beneath their plating when in cruising mode or whenever they are performing their most famous attack. Depending on the Sub-Model of the Arrowhead, one could either expect forward facing twin linked las-cannons with surprisingly high rates of fire or a missile volley, ranging up to ten fire-and-forget missiles before the craft needs to fabricate replacements.
Secondary Weapon: Arrowhead Scythes all tend to be fitted with a secondary weapon on its underside, usually geared for smaller targets like infantry. These weapons tend to vary greatly from direct energy weapons like Laser Beamers and Volkites, or kinetic weapons such as RCGs.
Power Field Blade Wreathe: The most famous weapon of the Arrowhead, even if it’s the one with least range, if only due to the sheer gal of the Men of Iron to create a fighter craft specialized for melee.
Given its sturdy design and high manoeuvrability, the Arrowhead is designed to ram against enemy aircraft to immediately achieve a kill or shatter formations, forcing a chaotic dogfight where the Arrowhead holds the advantage or is actively forcing enemy craft to focus on it while other aircraft deal the finishing blow.
This final armament converts the Scythe into a flying Power Blade capable of slicing clean through a Lightning Strike Craft without hardly loosing speed, and given its agility, entering close quarters combat with these crafts is always a deadly dance where one wrong move could result in a swift end by the reaper’s blade.
#digital art#digital drawing#artists on tumblr#my art#art#pixelart#drawing#pixel art#pixel illustration#concept art#weapon design#sci fi#scifiart#aircraft#fighter plane
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Realization of a cold atom gyroscope in space
High-precision space-based gyroscopes are important in space science research and space engineering applications. In fundamental physics research, they can be used to test the general relativity effects, such as the frame-dragging effect. These tests can explore the boundaries of the validity of general relativity and search for potential new physical theories. Several satellite projects have been implemented, including the Gravity Probe B (GP-B) and the Laser Relativity Satellite (LARES), which used electrostatic gyroscopes or the orbit data of the satellite to test the frame-dragging effect, achieving testing accuracies of 19% and 3% respectively. No violation of this general relativity effect was observed. Atom interferometers (AIs) use matter waves to measure inertial quantities. In space, thanks to the quiet satellite environment and long interference time, AIs are expected to achieve much higher acceleration and rotation measurement accuracies than those on the ground, making them important candidates for high-precision space-based inertial sensors. Europe and the United States propose relevant projects and have already conducted pre-research experiments for AIs using microgravity platforms such as the dropping tower, sounding rocket, parabolic flying plane, and the International Space Station.
The research team led by Mingsheng Zhan from the Innovation Academy for Precision Measurement Science and Technology of the Chinese Academy of Sciences (APM) developed a payload named China Space Station Atom Interferometer (CSSAI) [npj Microgravity 2023, 9 (58): 1-10], which was launched in November 2022 and installed inside the High Microgravity Level Research Rack in the China Space Station (CSS) to carry out scientific experiments. This payload enables atomic interference experiments of 85Rb and 87Rb and features an integrated design. The overall size of the payload is only 46 cm × 33 cm × 26 cm, with a maximum power consumption of approximately 75 W.
Recently, Zhan’s team used CSSAI to realize the space cold atom gyroscope measurements and systematically analyze its performance. Based on the 87Rb atomic shearing interference fringes achieved in orbit, the team analyzed the optimal shearing angle relationship to eliminate rotational measurement errors and proposed methods to calibrate these angles, realizing precise in-orbit rotation and acceleration measurements. The uncertainty of the rotational measurement is better than 3.0×10⁻⁵ rad/s, and the resolution of the acceleration measurement is better than 1.1×10⁻⁶ m/s². The team also revealed various errors that affect the space rotational measurements. This research provides a basis for the future development of high-precision space quantum inertial sensors. This work has been published in the 4th issue of National Science Review in 2025, titled "Realization of a cold atom gyroscope in space". Professors Xi Chen, Jin Wang, and Mingsheng Zhan are the co-corresponding authors.
The research team analyzed and solved the dephasing problem of the cold atom shearing interference fringe. Under general cases, the period and phase of shearing fringes will be affected by the initial position and velocity distribution of cold atom clouds, thus resulting in errors in rotation and acceleration measurements. Through detailed analyses of the phase of the shearing fringes, a magic shearing angle relationship was found, which eliminates the dephasing caused by the parameters of the atom clouds. Furthermore, a scheme was proposed to calibrate the shearing angle precisely in orbit. Then, the research team carried out precision in-orbit rotation and acceleration measurements based on the shearing interference fringes. By utilizing the fringes with an interference time of 75 ms, a rotation measurement resolution of 50 μrad/s and an acceleration measurement resolution of 1.0 μm/s² were achieved for a single experiment. A long-term rotation measurement resolution of 17 μrad/s was achieved through data integration. Furthermore, the research team studied error terms for the in-orbit atom interference rotation measurement. Systematic effects were analyzed for the imaging magnification factor, shearing angle, interference time sequence, laser wavelength, atom cloud parameter, magnetic field distribution, etc. It is found that the shearing angle error is one of the main factors that limits the measurement accuracy of future high-precision cold atom gyroscopes in space. The rotation measured by CSSAI was compared with that measured by the gyroscope of the CSS, and these two measurement values are in good agreement, further demonstrating the reliability of the rotation measurement.
This work not only realized the world's first space cold atom gyroscope but also provided foundations for the future space quantum inertial sensors in engineering design, inertial quantity extraction, and error evaluation.
UPPER IMAGE: (Left) Rotation and acceleration measurements using the CSSAI in-orbit and (Right) Rotation comparison between the CSSAI and the classical gyroscopes of the CSS. Credit ©Science China Press
LOWER IMAGE: Atom interferometer and data analysis with it. (a) The China Space Station Atom interferometer. (b) Analysis of the dephasing of shearing fringes. (c) Calibration of the shearing angle. Credit ©Science China Press

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prompt: Bonnie treats Kitt3 right
Some discretion was taken with this. Mostly the ABS and such-- gotta assume that KITT and KI3T have the whole nightmare, even in the 80s. Bonnie isn't too flabbergasted by the tech because KITT is, as they say, the car of the future.
"KITT, turn your wheel all the way to the right, please."
KITT-- Three Thousand-- turns his wheel all the way to the right. Immediately, hands are all over his frame again, untangling the brake line from the wheel hub assembly. He uses a portion of his sophisticated sensory suite to watch Bonnie work, even as her face screws up in consternation, her most common expression since beginning maintenance.
And what maintenance it is! She's propped him up on jackstands and wooden blocks. It is a far cry from the gyroscopic, laser-equipped armory he's used to. It gives him time to reflect on what he considers normal. As it turns out, if a human is involved with his care, it is through a laptop.
But laptops do not exist here. And this time, his failure is... physical.
"You seem perturbed, Dr. Barstow," he says quietly.
Bonnie's face scrunches up. She fusses at the knot of sensors dangling from his front left wheel. With him unable to power down, it is a mess of data, all of it erroneous. But--
Not unwelcome.
"Not-- perturbed, KITT," she says, echoing him. "Just can't make heads or tails of what's going on here. Pretty sure it's not supposed to look like this, though. Is it?"
She brandishes some of the cables underneath his chassis. A curious location, but not useless. And it seems practiced, or at least embedded in muscle memory, as her shoulders drop several inches. Confusion is always so fascinating on humans. It's enough to soothe his irritation at his fouled eyes; the plastic sheathing has melted together.
"No, it is not. It appears I have melted the bulk of my wheel speed sensors on this side."
His fault. The 1974 Mustang II form he'd adopted had been, as Mike would say, slapped together. And consolidating all of his functions into such a tight package was, ah.
Not what he was designed to do.
Bonnie brushes her fingers across a piece of his subframe. It shouldn't feel like anything, but the nanoskin is more sensitive than usual like this. And it's a wholly novel experience. Humans do not touch him often.
It is... undeniably a positive impact.
Eventually, she pushes herself up to a standing position, silent.
KITT watches her raptly.
"Want me to see if any of, uh, KITT's parts will fit?" Bonnie asks finally. Once again, she seems 'put out', clearly trying to come up with a solution and finding none.
"I do not wish to impose. If my databanks are correct, replacement parts for my predecessor were... expensive. Nearly a quarter of the Foundation's budg--"
Her face goes gray. Wisely, he ceases speaking, because he likes her. If it'd been anyone else...
"Don't remind me. Jesus. Okay. Look, let me just see if they'll fit, okay?"
"Of course," KITT says. "I am not going anywhere."
Bonnie laughs and ducks out of the trailer. His analyzer reads it as 'slightly hysterical.' Perhaps the circumstances are painful for both of them.
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Blocks: 1868. Non-armor blocks: 663. Number of Large Industrial Cargo Containers: 4. Capacity: 1.69 ML. Number of Small Cargo Containers: 24. Capacity: 375 KL. PCU: 10,022. Converyors: 237.
Thrusters: 35. Hydrogen Thrusters: 19. Large Hydrogen Thruster: 2. Warfare Ion Thrusters: 14. Jump Drive: 3. Battery's: 47. Large Reactors: 2. Spotlights: 2. Gravity generators: 1. Gyroscopes: 10. Hydrogen Engines: 2. Refinery's: 1. Power Efficiency Modules: 5. Yield Modules: 1. Speed Modules: 2. Lights: 9. Ore Detectors: 2. Simple Laser Multitool. 1. Railgun. 1. KWP-200M Cannon Turret: 4. Phalanx CIWS Mk15-1B: 2. VLS-Mk-41 Missle Pods. 2. O2/H2 Generators: 2. Oxygen Tanks: 2. Max storage: 8KL KL. Small Hydrogen tanks: 21. Max storage: 15.75 KL.
Artifical masses: 0. Triangles: 2,205,159. Grid mass: 1,478,632. Physical shapes: 1580/65536. Weight: 1.48 Gg.
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Popstar creatures part 4

A group of organisms generally known as wheelies, due to their tendency to spin like a wheel. The center contains a biological gyroscope. There is an eye on each side of the body.
1 Wheelie: Can position its tentacles into a wheel shape, and can roll around quite fast.
2 Flamer: Uses fire magic to spin through the air when provoked. Tends to prefer to spin counterclockwise.
3 Sawyer: A wheelie with increased grip. Can use solid magic projections to enhance the spines into razor sharp cutting implements.
4 Elec: Uses electric magic. Can also levitate. Tends to prefer to move clockwise.
5 Kracko: A large airborne species that can manipulate air and water to form clouds around itself. It can also generate hot plasma to zap others with.

1 Pacto: Ambush predators that wait in holes to leap up and grab prey. Can levitate to enhance leaps.
2 Maw: A narrower species of pacto.
3 Crimp: A pacto species that is more active. It hunts by shooting solid magic projections. Likes to be on horizontal surfaces.
4 Pactoid leaned walking stance: its not the most comfortable for them, but the more active species like crimp can lean to the side, enabling more reach from the mouth.
5 Pacloud: Spends the majority of its life levitating and flies through the air.
6 Pacflower: Mimics a flower to hide from prey. Does not sit in ambush holes. Just sits out in the open on walls or ceilings.
7 Walf: Weird aquatic turtle bug thing.

Three flying pacto relatives.
1 Cerulean
2 Jackle: Has sharp wings and can generate solid magic projections as blades.
3 Sodory: has a long sharp mouth.
4 Side view
5 Standing view
6 Moto Shotzo: Unrelated but convergent to the shotzo. Metallic exoskeleton. More mobile than the shotzo. Has a single long eye. Shoots SMPs from its mouth.

1 Gim: Metallic exoskeleton. A mouth is at the end of its face arm. Its long tongue can use magic to extend its reach. Has a one way respiratory system on its back. The top tube inhales, and the bottom one exhales.
2 Walky: Loud 4 eyed creature with a metallic exoskeleton. They can be compared to frogs with the males making loud calls to attract mates. A bunch in the same area can be deafening.
3 Plugg: Its jaws can zap you with electricity as it stabs.
4 Shotzo: Has a metallic exoskeleton. Shoots SMPs from its mouth. Tends to stay in one place to ambush prey. Its eyes blend in with its dark body.

1 Clanksprout: Has an eyed face arm it uses to bring food to the mouth on top. Depending on the species, it may hide in the sand or just hang from somewhere to ambush prey.
2 Hack: Uses its sturdy beak to break into rotten wood to look for small prey.
3 Glunk: An anemone like thing, but with eyes. Can shoot SMPs to make things above it fall.
4 Putt: A horned serpent that pushes around surprisingly large rocks down hills to kill prey.
5 Craby: Aquatic critter with two mouths on extendable stalks.

1 Telepathos: Flying critter that can levitate in place. It can teleport short distances and fire orb shaped SMPs.
2 Bowby: Flying critter that can fire arrow shaped SMPs.
3 Fishbone: Creature resembling a fish. It can levitate and be out of water if the air is moist enough. The SMPs it fires resemble its head doubling as a decoy.
4 Ufo: Strange levitating organism. Its mouth is underneath. Tends to live high in the atmosphere.
5 Dubior: Mouth is underneath as an adult, but its larval stage has a forward facing mouth. Can shoot lasers and electricity. Communicates by generating SMPs above its body.
6 Blockin: Another star block mimic. It illusions itself to look like a star block. Eats pieces of star blocks and surrounding small organisms. Generally passive unless you provoke it. Then it will chase you away with an aggressive display. If you are still too close it will bite. Those harvesting star blocks must be aware of this potential hazard.
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