I Will Contact Lord Sidious

STAR WARS EPISODE I: The Phantom Menace 00:03:52

5/5 April 30, 2025

Quick-Look Intel Drop (5 articles, 5 take-aways)

Cargo Drones for Island Hopping Logistics – Defense One • Piasecki just bought Kaman’s KARGO program: trailer-portable, vertical-lift drone that hauls 500 lbs hundreds of nautical miles (or 1,000 lbs for ~100 nm). • Marines want medium-range unmanned lift to free up manned helos and keep small units resupplied across the Pacific. Payload spec may stretch to 1,400 lbs, autonomy will grow via software. • Commercial demand (mining, oil) makes the business case real; modular design keeps upgrade costs down.

The M10 Booker—When Requirements Eat Their Young – Defense One • Started as a “light, airdroppable tank” for the 82nd Airborne; requirements creep killed that. Now 42 tons—too heavy for Fort Campbell’s bridges, single-load only in a C-17. • Locked into 1990-era SINCGARS radios, no autonomy option, and a mandatory 504-vehicle buy to dodge a cost review. • Army leadership is considering cutting losses once three pilot vehicles finish testing; a lighter, tech-ready M1A3 may back-fill the need. New oversight gate forces programs to prove practicality within 120 days or die.

Autonomous Low-Profile Vessels (“Narco-Subs”) Join 12th Marine Littoral Regiment – Sandboxx News • Okinawa-based 12th MLR is experimenting with Leidos-built ALPVs: five-ton payload, 2,000 nm range, surface-skimming silhouette, fully autonomous or waypoint-driven. • Mission: covert sustainment of dispersed littoral teams under Force Design 2030—think sneaky pallet runs, not torpedoes. • Marines are validating reliability and CONOPS; commander wants more hulls once data proves the logistics ROI.

ExDECS Microwave Cannon Targets Drone Swarms – Army Recognition • Epirus delivered its Expeditionary Directed Energy Counter-Swarm system to the USMC for field eval: solid-state GaN emitters, truck/trailer mount, software-defined waveforms. • One pulse fries circuits on multiple UAVs at ~$0.05 per shot—non-kinetic Phalanx. Integrates with CAC2S and open APIs. • Part of a family (Leonidas Pod, IFPC-HPM, etc.) already doing Army trials; extended-range variant (10 km) in the queue. Fits Marine EABO doctrine: lightweight, mobile, low-signature air defense.

F-47: Mach-2-Plus Stealth Racer – Warrior Maven • Public hints peg Boeing/USAF’s future F-47 at ≥ Mach 2 while retaining low observability—beating legacy speed-vs-stealth trade-offs. • Unknown thermal-management tricks could tame IR bloom; surpasses F-35’s Mach 1.6 and matches/edges F-22’s Mach 2.25. • Raw speed is only half the dogfight—expect advanced sensors, off-boresight weapons, and high thrust-to-weight to round out the air-dominance package.

That’s the landscape: unmanned movers, microwave zappers, requirement misfires, stealth speed demons, and the perpetual race to keep small, distributed forces fed and lethal.

Add-On Intel: DoD Axes “Women, Peace & Security” Program

• Defense Secretary Pete Hegseth killed the UN-aligned Women, Peace & Security (WPS) initiative inside the Pentagon, calling it a “woke, divisive social-justice program” that distracts from war-fighting. • WPS dates back to the 2017 Women, Peace & Security Act—signed by Trump and championed by Ivanka Trump, Kristi Noem, Marco Rubio, and Jeanne Shaheen—to boost female participation in peacekeeping, mediation, and military roles. • Critics (Shaheen, former Marine combat-pilot Amy McGrath) say the move is short-sighted, arguing WPS enjoys senior-leader support and yields strategic advantages by adding women to conflict-resolution efforts. • Hegseth claims troops “hate” the program and vows to zero it out in the next budget, framing the cut as part of a wider rollback of federal diversity initiatives. • Cost data for WPS inside DoD hasn’t been disclosed; Hegseth says the Biden team “weaponized” the effort but offers no specifics.

Semiconductor Components Company

When a semiconductor is composed of small crystals of crystalline compounds, it is referred to as a microcrystalline or amorphous semiconductor material. Strictly speaking, a semiconductor is not a component but a material that has a conductivity between that of conductors and insulators. Semiconductors are important because they can be constructed to conduct electricity better than other materials, a fact which makes them perfect for many applications. The unique properties of semiconductors position them in between high-conducting materials like copper or aluminum and nonconductors like rubber or glass. Most commonly made out of silicon, germanium and gallium arsenide, semiconducting hardware either allows a free-flowing current or repels it completely - semiconductor components.

Exposing a semiconductor to light can produce electron hole pairs, which increases the number of free carriers and thereby the conductivity. Compound semiconductor diodes are also being used to generate light, light-emitting diodes and laser diodes. Semiconductors are materials that conduct electricity well enough to be used in transistors and other electronic devices, but not quite as well as metal.  Semiconductors are used to build virtually every electronic device and have applications across most relevant sectors, such as automotive, home electronics, communications equipment and enterprise systems. In other words, if you want to enhance conductivity, you need to add more electrons, or more holes anything to create an unequal number of either instance - EMC Solution.

They are typically used as amplifiers and oscillators in high-frequency microwave electronic devices. The main advantage of a semiconductor is its ability to control the flow of electrical current electrical charges. The conductors lack this ability as they allow current to flow in both directions. Now let us talk about the important category of material for our discussion i.e. the semiconductors. We use these discrete components in power devices, compactness optical sensors, and light emitters. In addition, they have an extensive range of current and voltage handling capabilities. For more information, please visit our site https://www.westek.com.au/

Cosmic Interface: Technologies to Tap into the Reservoir Universe's Computational Fabric

Developing technologies to interact with the computational subsystems of the "Reservoir Universe" would be profoundly transformative, potentially providing unprecedented insights into the universe's inner workings. Here are some speculative technologies and methodologies that could be envisioned to interface with these computational nodes:

1. Quantum Information Decoders

Purpose: Decode the information processed by the computational subsystems of the universe.

Operation:

Quantum Entanglement: Leverage quantum entanglement to link with the subsystems.

Quantum Sensors: Use highly sensitive quantum sensors to detect subtle changes in quantum field amplitudes.

Decoding Algorithms: Develop algorithms that can interpret the encoded data streams into meaningful information.

2. Gravitational Wave Analyzers

Purpose: Detect and interpret data embedded in gravitational waves.

Operation:

Network of Detectors: Deploy a global network of gravitational wave detectors, like LIGO, VIRGO, and KAGRA, but more sensitive.

Waveform Analysis Algorithms: Utilize machine learning algorithms to identify patterns and extract computational data.

Feedback Mapping: Map the gravitational wave feedback loops to understand the computational processes of spacetime curvature.

3. Cosmic Neutrino Networks

Purpose: Use neutrinos as messengers to probe computational nodes.

Operation:

Neutrino Emitters and Receivers: Create devices capable of emitting and detecting neutrinos at extremely high precision.

Neutrino Field Analysis: Analyze how neutrinos interact with different subsystems, revealing computational processes.

Interference Patterns: Study interference patterns to map the structure of computational networks.

4. Spacetime Curvature Probes

Purpose: Measure and manipulate the local curvature of spacetime to interact with computational nodes.

Operation:

Micro-Gravity Sensors: Develop ultra-sensitive sensors to detect minute changes in spacetime curvature.

Localized Curvature Manipulation: Use high-energy particle colliders or gravitational lensing to alter local spacetime curvature.

Curvature Mapping Algorithms: Create algorithms that translate curvature changes into computational data.

5. Quantum Field Manipulators

Purpose: Directly manipulate quantum fields to interact with computational subsystems.

Operation:

Field Generators: Design devices that can generate controlled quantum fields.

Field Interaction Analysis: Analyze how the generated fields interact with cosmic quantum fields.

Quantum State Alteration: Modify the quantum probabilities to influence computational outputs.

6. Cosmic Neural Networks

Purpose: Create AI systems that model and interface with the computational fabric.

Operation:

Neural Network Architecture: Develop neural network architectures that mimic the hypothesized cosmic computational nodes.

Training on Cosmic Data: Train these networks using real cosmic data from telescopes, particle detectors, and gravitational wave observatories.

Pattern Recognition: Recognize patterns in cosmic data that might reveal computational structures.

7. Information Entropy Analyzers

Purpose: Measure the entropy changes in cosmic information processing.

Operation:

Entropy Sensors: Build sensors that detect changes in cosmic microwave background (CMB) radiation or cosmic rays.

Entropy Mapping Algorithms: Use machine learning to map entropy variations across different cosmic regions.

Subsystem Identification: Identify computational subsystems based on entropy changes.

8. Multidimensional Signal Processors

Purpose: Detect and analyze signals from higher-dimensional spaces.

Operation:

Dimensional Probes: Construct probes capable of detecting multidimensional signals based on string theory or M-theory frameworks.

Signal Interpretation Algorithms: Develop algorithms to interpret these signals into meaningful computational data.

Higher-Dimensional Mapping: Map out the structure of higher-dimensional computational networks.

9. Virtual Reality Interfaces

Purpose: Create immersive environments to visualize and interact with the computational fabric.

Operation:

Cosmic Data Visualization: Use virtual reality (VR) to visualize cosmic data from computational nodes.

Interactive Simulations: Build simulations that allow users to explore and manipulate the computational subsystems.

Feedback Mechanisms: Provide real-time feedback based on changes in the cosmic computational network.

Conclusion

Interfacing with the computational fabric of the universe would require a multidisciplinary approach, combining quantum mechanics, information theory, cosmology, and advanced computing. Although speculative, these technologies offer a glimpse into how humanity might one day unlock the secrets of the Reservoir Universe and gain a deeper understanding of the cosmos and our place within it.

Once again Deflecting complete mental health breakdown entirely by reading C-3po information. Hanging on by a fucking thread here BUT did you know according to the star wars visual dictionary he may be able to see in infrared. Than again they can't agree with themselves which part of his head is the audioreceptors so.

Oh, and every single source I've seen so far including two out of three schematics from this book (I'm working on tracking inconsistencies and changes in the info of artoo and threepio between different editions rn) list the funny little round thing on top of his head as a Microwave Sensor/Emitter - listen I have no idea why the ever loving fuck would it be that, but it is- except the Phantom Menace bare-form schematic here lists the bump THAT version of him has as a balance gyro??? Did you. Remove the balance gyro to put in a fucking microwave. Is it on top. Why do you have a microwave, anything.

Anyways Artoo deeto is the love of my life no complaints there.

Hi Aubrey and readers! Happy Fab Friday! This week I'm writing in with an excerpt from a response to a writing prompt that I've been working on!

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It took maybe an hour before I saw anyone. Unfortunately, they were a corpse. The man was dressed as a woodsman, with almost laughably primitive work clothes. His face still had a pained expression showing through the dark tangled facial hair. If I had to guess I would say the fabric was hand spun, given the lack of any signs of advanced industry here. A lumberjack’s axe lay propped up against a tree nearby. Looking over the body, it was clear that he had died messily, with wounds that bled enough to leave the ground tinted red and slightly mushy underneath. I checked him anyway. The body was still warm, but no pulse.

I put my helmet back on and had one hand on my rifle while I flipped through the various sensor modes. Nothing was around. Or if it was it had stealth tech better than my armor could track. So, I detached my entrenching tool – basically a bladed shovel that folds up, but everything needs an official name I guess – and I got to work. The armor servos made it light work, and I quickly had a shallow grave dug before me. I did my best to gently lift the man into it. I’m no priest, and I didn’t know him, so I simply said a short prayer under my breath and hoped it would suffice.

Another hour or so of walking, and I finally got to the village. From here, seeing it sitting in the clearing between river and tree line, it looked like something out of a storybook. And like many villages in storybooks where a stranger comes to town (don’t ask me it just seems to be a law of the universe when it comes to storybook towns) it was under attack.

Well, maybe attack was a bit too harsh of a descriptor. There was a group of armed rabble standing in front of a group of what appeared to be townsfolk. They were all humanoid, but with startling variation that I had only really seen spring from the more heavily gene-modded folks, and this world didn’t look like it would have had anything close to even a primitive genetics lab. The armed folks were a mix of stock humans, burly green and grey humanoids, and a few scattered scaled humanoids. The townsfolk were a more diverse mix, but still predominately human. Or stock human. Normal looking is what I’m getting at. I used the built-in scope of my rifle to observe more closely, and without the choking noise of a warzone, my armor’s autosenses were able to pick up the conversation as though it were happening a room over.

“Now now, you guys know the drill. Hand over the money, and we’ll leave in peace.” said the lead bandit, a sneer in his voice.

And older man looked distressed and pleaded. “We already paid this month’s fee and we can’t afford more!”

“Nonsense, you get all those rich caravanners coming through here. You think I’ll swallow this swill about being dirt poor?” the bandit said, contempt dripping from his voice.

“The Baron of Skystead rode here not a week ago to demand we pay taxes to him! We gave what we could, and we have nothing to spare now!” the old man sounded nearly hysterical.

Alright, that was enough of that.

I sighted the lead bandit in my scope, adjusted a couple settings, and squeezed the trigger. The pulse rifle’s emitter glowed with heat for a second, and a whip-crack sounded as the coherent beam of light heated the air around it. The multi-phase lance struck true, faster than any of the bandits could react, and the leader’s chest suddenly looked like a combination of a grilled hunk of steak and what happens when you microwave a ripe fruit for too long. The crude hide armor had burned off, ablated by the millisecond-staggered pulses of violent light before flesh charred and burned. He died instantly, only a faint gurgle escaping his throat.

The rest of the bandits reacted, drawing blades, cudgels and bringing spearheads down. I sprinted downhill. I sighted in again, armor servos stabilizing my arms, and fired, causing the bandit who first moved to accost the townsfolk, one of the greenskinned bandits, to die in a similar fashion to the leader. This put some hesitancy in them, and from the glimpses I took it seemed like some of the civilians fled.

Even with the assistance of my armor, it took more time than I would have preferred to actually get close to the town and the bandits. A few more potshots scored a couple more kills, until they began to flee. At this point I was close enough that they could hear me, and so with amplification of my voice through my helmet I shouted at them “Don’t come back unless you want more you bastards!”

submitted by @aurelianpen

I'm ready to read 500 pages of this in one setting!!! The writing!!! The tension!!! The dialogue!!!! The action!!! *chef's kiss*!!!! FANTASTIC job!!!!!

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counterpoint on 5g.  need to do more research

added article below:

5g And Lies

[Comments enabled]

I hate liars and sensationalist horsecrap.

The first part of that piece contains two lies:

1) 5g will lead to "massive" increases in RF exposure and 2) 5g means that there will be a high-power transmitter every few houses in distance.

Utter nonsense.

First, no firm can pay for said high-power transmitters in that density, never will be able to, nor will they be able to handle the backhaul requirements.  Such pipe-dream nonsense can only take place in a world where nobody has a calculator to run costs.

Second, the more dense your transmitters are the lower power level they must use or you get unacceptable interference that destroys the performance of the system as a whole.  WiFi is a great example; it's damn near everywhere, there are a dozen or more hotspots visible in many urban areas -- hell, there are a few visible from my house (other than mine personally.)  Indeed most of us have an intentional RF emitter in our home providing WiFi services to our computers, phones, tablets, TVs and similar.  The maximum allowed in the US is 1 watt.  Your cell handset has a maximum allowable is 600mw (but often runs much less, since the cell site tells it what power level to use to avoid interference with neighboring cells.)

Now you can run a higher effectively radiated power in some cases, but with the exception of a point-to-point link it's sort of stupid to do so, since using a directional antenna defeats the point of being able to walk around and have a steady signal.  At best you can "squash" the output pattern (and typically get a 3db gain by doing so) so you're not blasting signal both straight up and down (which does you no good, obviously.)

--

Look folks, there's a difference between ionizing and non-ionizing radiation.  It's quite-profound and yet most people simply don't understand it.  You can get a nasty burn from non-ionizing radiation (indeed that's how a microwave oven cooks food!) because the heating is not absorbed and transmitted from the top tissues (e.g. skin) of your body inward; rather, it is absorbed at an inverse-square relationship at the distance from the emitting source, which means that for the most part it heats evenly.  So if you get an RF burn on your arm, for example, it "cooks" your arm all the way through at once.  That is what makes it dangerous (and is why RF injuries are very slow to heal.)

Ionizing radiation, on the other hand, usually doesn't cause heating damage.  But it can cause cancer.  This is why having X-rays (or a CT scan for that matter) without a damn good reason is a bad idea.  Imaging your broken arm to figure out exactly how to set it is worth the (small, but non-zero) risk, and technology has greatly reduced the level of exposure in medical imaging; as an example the modern electronic-sensor dental X-ray machine has an exposure of only about 15% as much as film because the digital sensor is more-sensitive than the film is, and as a result much less X-ray energy is required.

Yet you have probably had "bite wing" X-rays taken on an annual basis since you were a child!  May I note that a huge percentage of the time those are purely speculative -- that is, you don't have a toothache and the hygienist has already cleaned your teeth and physically probed the surfaces for cavities. The dentist has no reason to suspect you need an X-ray but they do find problems -- cracks in the teeth, cavities that are not obvious on physical probing, and bone issues in the jaw.  That exposure is to ionizing radiation -- the sort can and does cause cancer.

How many cancers?  Not many.  But not zero.

Is this a realistic factor when it comes to cellphones?  No.

Does that mean there's no risk?  No, it doesn't, but the magnitude of additional risk over that which you already have and accept as a result of having a microwave in your house, a WiFi hotspot sitting on top of your media center, your TV and stereo having WiFi capabilities and similar makes this a losing argument.

The that cellphone caused my brain cancer argument is interesting but did those people never have a dental X-ray?  How do you isolate out speculative non-ionizing RF as a "cause" when ionizing radiation is in fact where real and known risk comes from?

Never mind the tremendous decrease in radiation exposure over the last 20ish years as tube-style TVs and computer monitors have all but disappeared world-wide.  You see, old-style CRT displays inherently aimed a beam of electrons straight at your head.  That's how those displays worked and it was much worse for color sets.  When you were a kid if you grew up in the age of the "flickering blue parent" you were probably told "don't sit so close"; guess why?  How about that older computer monitor where you had to sit at a foot or so distance away in order to read it?

The glass in CRTs contained lead for the explicit purpose of absorbing as much of it as possible but it didn't get it all.  Those displays are more-or-less all gone now, having long since been replaced with LCDs that don't rely on the acceleration of electrons striking a phosphor to produce an image.

So let's have some perspective, eh, since it's total exposure that matters, you take a fair bit of exposure to ionizing radiation every time you fly (since you're up high enough that you lose a decent amount of the shielding the atmosphere provides from cosmic radiation) and when it comes to ionizing radiation there's been a tremendous decrease in both routine medical and household exposure over the last 30 years or so.

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SMART PACKAGING MARKET 2027 BY TYPE,END USER & GEOGRAPHY

The smart packaging market is expected to reach $43.6 billion by 2027, at a CAGR of 5.2% during the forecast period of 2020 to 2027. The increasing demand for advanced packaging solutions from the food processing & pharmaceutical sector, growing consumer concern for food wastage reduction, and rising demand for smart & functional packaging are the major factors driving the growth of this market. Moreover, the growing E-commerce market and rising industrialization coupled with strong demand for superior logistics and supply chain management are likely to create lucrative opportunities for players operating in this market.

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 The global smart packaging market study presents historical market data in terms of value (2018 and 2019), estimated current data (2020), and forecasts for 2027. The market is segmented on the basis of packaging technology, application, and geography. The study also evaluates industry competitors and analyses the market at the country level.

 Based on packaging technology, the global smart packaging market is segmented into modified atmosphere packaging (MAP), active packaging, and intelligent packaging. In 2020, the modified atmosphere packaging segment commanded the largest share of the smart packaging market. The increasing demand for fresh & high-quality packaged food products is one of the major factors expected to drive this segment. Furthermore, on-the-go lifestyle, shift towards easy-to-handle & convenient packaging, and emerging economies are stimulating the demand for modified atmosphere packaging.

 Based on application, the global smart packaging market is segmented into food & beverages, pharmaceuticals, automotive, personal care, and other applications. The pharmaceuticals segment is expected to grow at the highest CAGR during the forecast period. Factors such as the growing aging population; increasing the integration of barcodes, RFID, and sensors; and technological advancements in the pharmaceutical industry are driving the growth of this segment.

 In 2020, North America commanded the largest share of the smart packaging market. The rising demand for packaged & frozen foods, increased food safety concerns, and changing lifestyles are the major factors driving the North American market. Further, changing government regulations regarding safer food & packaging, growing food wastage, and rising demand for quality packaging are also driving the market for smart packaging in the North American region.

 Key Players

 The report includes a competitive landscape based on an extensive assessment of the key strategic developments adopted by the leading market participants in the smart packaging market over the last four years. The key players operating in the global smart packaging market are 3M (U.S.), Avery Dennison Corporation (U.S.), American Thermal Instruments (U.S.), Temptime Corporation (U.S.), Smartrac N.V. (Netherlands), BASF SE (Germany), Thin Film Electronics ASA (U.S.), Stora Enso (Finland), International Paper (U.S.), Amcor plc (Switzerland), Emerson Electric Co. (U.S.), R.R. Donnelly & Sons (RRD) Company (U.S.), Sealed Air Corporation (U.S.), and Smartglyph Ltd. (U.K.).

 Scope of the report:

Smart Packaging Market, by Packaging Technology

 Oxygen Scavengers

 Moisture Scavengers

 Self-Venting Films

 Ethylene Scavengers &Emitters

 Microwave Susceptors

 Antibacterial Films

 Temperature Control Packaging

 Carbon Dioxide      Scavengers/Emitters

 Ethanol Emitters

 Flavour/Odour Absorbers

 Antioxidants

  Bio Sensors

  Gas Sensors

     2D        Matrix Codes

   Quick        Response Codes

   Augmented        Matrix Codes

  Smart Packaging Market, by Application

Food & Beverages

Pharmaceuticals

Automotive

Personal Care

Others

Smart Packaging Market,by Geography

 U.S.

 Canada

 Germany

 U.K.

 France

 Italy

 Spain

 Rest of Europe

 China

 Japan

 India

 Australia

 South Korea

 Vietnam

 Rest of The Asia Pacific

 Brazil

 Mexico

 Argentina

 Peru

 Rest of Latin America

Key questions answered in the report-

·         Which are the high growth market segments in terms of packaging technology, application, and countries/regions?

 ·         What is the historical market for smart packaging across the globe?

 ·         What are the market forecasts and estimates for the period of 2020-2027?

 ·         What are the major drivers, restraints, and opportunities in the global smart packaging market?

 ·         Who are the major players in the global market and what share of the market do they hold?

 ·         Who are the major players in various countries and what share of the market do they hold?

 ·         How is the competitive landscape in the market?

 Contact Us:

Meticulous Research®

Email- [email protected] Contact Sales- +1-646-781-8004 Connect with us on LinkedIn- https://www.linkedin.com/company/meticulous-research

Elon’s sn10 can land right on earth but not on Mars if its system doesn’t fix gravity related issues while landing and account carbons density. think that there needs to be carbon sensors on it for fuel pressures. In blade runner also the first ppl were not humans they were cyborgs but there will probably be a way to control them with game engine technology like mo cap suits or just send giant wall-e’s and force starlink satellites for controls. The carbon will probably not allow for solar cyborgs so the satellites themselves will have to be floating tree colonies or have to use a method to get rid of it to create oxygen. a few ways could be solar satellites with hvac filters that use graphene batteries to clean the air, giant tube satellites that rotate in the air using the curved baseball effect, and as they spin clean the air - or the rocket itself stays in orbit and is equipped with a plasma engine to move the hvac tubes... so the rocket would probably be the size of 4 starships and it would drop filter tube satellites that could be used to create hurricanes in the sky if they spin together and have propellers in the center by turning them on as a hurricane spins with the center propellor always on. Or the starship sends a hurricane maker to the floor instead so it can only be used once. They will also need to send nasa’s cloud machine or darpa’s tesla sky radiation microwaves that change the weather by breaking the ozone’s layers. probably will send that instead of the hurricane makers cause if you break the ozone then the carbon can escape easiest but the best bet would be a satellite with a microwave emitter that runs off plasma energy and solar aiming down at the planet and maybe a wall-e that creates the hurricane that lets the carbon escape through the broken ozone. If none of this works then just send giant ozone lightbulbs and hook them up to giant batteries so they burn out the carbon and attach lasers and glow in the dark paint so you can see them disappear with time and when the lasers go away then test the o2 and gravity fields with a drop and swing test and get that data off a high FPS camera to compare with on earth. You can also send snoop dogg to test if Mars is habitable.

Fiber laser systems: Space application

Despite the fact that laser technology still needs to be developed, it is considered to be very promising. Optromix is a fast-growing manufacturer of fiber lasers, optical fiber sensors, and optical monitoring systems. The company offers fast turnkey solutions and creates sophisticated fiber laser systems for special purposes. Optromix uses only its own technologies based on the advanced research work and patents of international R&D team and develops a broad variety of high beam quality fiber lasers. If you have any questions or would like to buy a fiber laser system, please contact us at [email protected]

Traveling to other stars is a big human dream; however, it may be necessary to make something small for its achievement. According to a new study, the use of powerful laser systems to launch tiny spacecraft will significantly speed up interstellar flights, and therefore, it will take only one or two decades instead of thousands of years.

Physics and mathematics limit all the impulses. Also, the spacecraft should move incredibly fast to get there in a reasonable amount of time - but this requires a lot of fuel. And the necessary fuel loads will make the spacecraft too heavy.

However, some researchers have found a way out of the current situation - it is necessary to use a solar, laser system or microwave sail. Such a spacecraft will not require any fuel; but in order to provide the necessary acceleration to the big vehicle, people will have to develop a huge orbital laser module, and equip the spacecraft itself with a sail of Texas size.

At the present time, it is real to solve the problem with the help of tiny sailing spacecraft. Space laser system probes that have just one gram weight will be put into the Earth orbit, and then accelerated by a laser beam of high quality. Each probe will be equipped by tiny optical sensors and transmitters to communicate with the Earth. In addition, the system can be developed and improved gradually, since even the use of heavier probes or a less powerful laser beam will allow exploring several distant parts of the solar system.

The system requires the use of a laser module with a power of 50 to 70 gigawatts because it will enable to accelerate the probe with a meter sail to 26% of the speed of light in just ten minutes. Such a space probe will reach Mars orbit in 10 minutes, it will pass the Voyager-1 in three days and arrive in the Alpha Centauri star system in fifteen years.

In order for the idea realization, scientists will have to find a way to focus and very accurately direct the laser beam, as well as develop a tiny and light transmitter so that the space probes can transmit the received data to the Earth.

Nevertheless, it will take almost 10 years to wait for the first probe launch, but now the development is going according to plan and promises the realization of the most ambitious projects. The principle of the laser system operation is the following: the fiber laser will send a signal from Earth into its orbit. The laser beam is captured and converted into kinetic energy, which is used for movement. It sounds like science fiction, but it's actually pretty simple.

The laser system modules will be installed at high mountains, and the power of the emitters will be about 100 gigawatts. At the same time, special devices will be launched into orbit that will “catch” the laser beam. Each of them was created specifically for this system and is very different from the conventional space sensor:

its diameter is 13 ft;

the device weight is not more than 0.001 pounds;

the thickness of the device is only 400 atoms.

In fact, the devices are a light haze, so that they can accelerate to 200 million km per hour with the help of a laser system. The space probe's first mission is the studying of Proxima Centauri, and even these ultralight laser module vehicles will be able to reach the destination point only after 25 years.

Light weight is needed not only for quick acceleration but in theory, it will help avoid collisions with asteroids. In this case, a small spacecraft has all the necessary equipment to obtain detailed information about the surrounding space. By the way, the very idea of mini-satellites has already been realized, and in 2017, Indian engineers tested mechanisms of 0,009 pounds, which successfully transmitted data to Earth for the first time.

At the same time, it is believed that future spacecraft will be able to use black holes as powerful launching platforms for studying stars that is one more laser application. A new study involves the emission of laser beams from a spacecraft along the edge of a black hole, which will bend around the latter because of its powerful gravity and return with added energy. After the fact, the spacecraft will “catch” these laser beams, thereby obtaining free energy, which can be used on its acceleration up to the speed of light.

Also, laser modules can be actively used for data transmission in space. So a group of physicists from Switzerland has developed a fiber laser that generates a super-hot laser beam that allows making holes in the clouds. Another laser beam containing the whole information can be directed into such holes.

The laser developed in Geneva allows transmitting 10000 times more information than by radio waves. Until today, the problem was in the clouds and fog that occasionally appeared in the atmosphere, stopped the laser beams and distorted data.

In this case, physicists have developed a laser system that heats the air in the right place to a temperature above 1500 degrees Celsius. As a result, a hole with a diameter of several centimeters is formed in the cloud.

A tunnel made by a laser beam can be maintained for some time while another beam transmits data. Scientists have tested their development on artificial clouds of 1.6 ft, but they contained 10000 times more water per square centimeter than natural clouds. The new method works even if the clouds are in motion.

It is quite possible that in the near future, such laser systems will allow communicating with possible aliens. Astrophysicists have calculated that hypothetical astronomers at Proxima Centravra b - an exoplanet that revolves around a star that is 4.2 years from Earth - would be able to pick up a signal sent using a two-megawatt laser module and an optical telescope with a 115 ft mirror.

The researchers calculated that if you used a powerful laser system and focused its beam using an optical telescope, the infrared radiation of the received signal could reach exoplanets, both rotating around our nearest Proxima Centauri and TRAPPIST-1 planets located at a distance of 40 light years from Earth. According to scientists, such laser beams can be a kind of signs, the light from which extends to distances up to 20 thousand light years.

For example, powerful laser systems developed for the military aims already have needful power. Scientists specify that it will be necessary to install the fiber laser system at high points like powerful telescopes to reduce the noise of the Earth’s atmosphere, which can interfere with signal transmission. It should also be noted that much more powerful telescopes should be used to transmit such a signal.

In addition to these potential fields of laser module application, they are used by NASA to study the ice layer of the Earth. Not so long ago, a NASA satellite was launched to Earth orbit from a California space center to study the state of the Earth’s ice cover.

The mission of an artificial satellite, called ICESat-2, is to provide more accurate information about the influence of global warming on the ice layer by a laser system.

As the name suggests, ICESat-2 is the second version of the satellite. The first spacecraft was launched in 2003 and it carried out a laser module test of the thickness of polar glaciers and sea ice from space for the first time. However, the mission faced technical problems, as a result of which observations were limited to only a couple of months in a year.

Since then, NASA has improved laser technology, making the observation process more reliable and focused. So, the laser beam is divided into six parts - three pairs, so we can see a larger surface of the ice, as well as evaluate the surface slope. The same ground surfaces will be measured every three months, giving us seasonal ice shots. It is possible to understand the processes associated with the reduction of ice in the polar regions due to the data.

The new laser system that weighs half a ton, is one of the largest surface observation tools ever created by NASA. It uses photon counting technology. The probe emits 10 thousand laser pulses per second and the laser module measures every 3 ft as it moves along the ice surface. Also, it should be mentioned that the laser beam cannot melt the ice from a height of 3280 ft. But on a dark night, it is possible to see a green mark in the sky - this is the ICESat-2 satellite flying.

Moreover, laser systems are a possible solution for cleaning space from debris. Thus, an international team of scientists is developing a laser system to deal with space debris. Fiber lasers are expected to protect the space station from collisions with dangerous alien elements. Nevertheless, according to analysts, physicists will have to overcome a number of technological difficulties. In particular, it will be necessary to find a balance between the power and energy intensity of the laser system.

Scientists are developing quite powerful laser modules that can change the orbits of small space debris - up to 0.3 ft in diameter. However, all the electric power generated by the ISS will be required to launch such a laser system, and it will completely leave the station without electricity.

Physicists confirm that space debris will dissolve under the influence of the laser module, forming a cloud of microscopic particles that pose no threat to the ISS covering or any other space equipment. At present, an impressive amount of garbage has accumulated in Earth orbit, but the situation is still far from critical.

At the moment, the scientists propose to use special flying satellites and even special nets that will catch space debris. However, so far all these laser techniques are rather difficult to put into practice. The use of a laser technology that will dissolve parts of space debris seems to be the most realistic.

Resilience over rigidity: how to solve tomorrow's computer problems today #1yrago

My new Locus Magazine column, Wicked Problems: Resilience Through Sensing, proposes a solution the urgent problem we have today of people doing bad stuff with computers. Where once "bad stuff with computers" meant "hacking your server," now it could potentially mean "blocking air-traffic control transmissions" or "programming your self-driving car to kill you."

The traditional regulatory model for solving this kind of problem -- making it technologically difficult to accomplish this badness -- is dead today. Totally inapplicable to computer-driven devices.

But that doesn't mean all bets are off: where before we looked for rigid defenses, today's problems demand resilient ones.

Here’s where their reasoning took them: When the FCC’s stupid plan to sign all the code died, there would still be a problem with devices emitting RF that clobbered the devices you wanted to use. Programmers would make simple errors that would cascade into terrible radio interference, Users would do dumb, unanticipated things with the configurations of their devices. Nearby vacuum cleaners and microwave ovens would take hard knocks that dislodged their shielding and turned them into inaudibly high-pitched radio klaxons. Bad guys – malware authors, griefers, pranksters, and criminals – would deliberately reconfigure devices (theirs and yours, if they could get at them) to do bad radio stuff.

This means that, no matter what, we’ll all need some way to sense and triangulate upon bad radio emitters. The good news is, once we’re all carrying around lots of flexible, cheap SDRs, we’ll be able to do that sensing and triangulation – and the more SDRs we have, the more we’ll need them to sense the broken devices in their vicinity as part of normal troubleshooting. If my radios and your radios and Fred’s radios all agree that there’s Something Bad happening Over There, they can raise a flag for humans to deal with. They can tell their owners, or upload a log-entry to a public ledger of hotspots, or take some other step that will allow humans to intervene. Maybe that takes the form of you filling in a bug report with the FCC’s radio cops; maybe it means you look over in a corner of your kitchen to figure out why your microwave is messing up your house’s network.

This is a great answer, because it treats humans as sensors, not things to be sensed. It distributes intelligence and agency to the edges of the network. It is resilient and flexible, and responds well to intentional and accidental malfunctions.

Wicked Problems: Resilience Through Sensing [Locus Magazine]

https://boingboing.net/2016/01/07/resilience-over-rigidity-how.html

Global Lightning Protection Technologies Market Portrays High-End Demand across Major Geographies during 2018-2028

FactMR will soon publish a fresh research report focusing on the “Lightning Protection Technologies Market” market. The main aim of this assessment would be to provide deeper insight about the “Lightning Protection Technologies Market” sector for the period during Global Lightning Protection Technologies Market Portrays High-End Demand across Major Geographies during 2018-2028. Readers will get to access vital information associated to market size, revenue share and regional outlook, so as to decipher the various projections related to the target market. Furthermore, the contribution of leading market players would surely be investigated and carefully presented.

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The function of the lightning protection system is to protect the structure from mechanical destruction and fire and to prevent injuries and death of people in the buildings or structures. The lightning protection technologies include systems for external lightning protection and internal lightning protection. Functions performed by external lightning systems are safe discharge of lightning current, intercepting direct lightning strikes, and distributing lightning current in the ground. While the internal lightning system prevents sparking in the structure by establishing equipotential bonding.

Three types of new lightning protection technologies are charge transfer system, dissipation array system, and early steamer emitter. Among these, the dissipation array system is only available for commercial purpose. It creates the zone of protection, thereby, protecting the area against the lightning strike.

Lightning Protection Technologies Market: Notable Highlights

Holt Integrated Circuits introduced new ARINC 429 protocol IC, HI-35930 providing lightning protected drop-in for the existing HI-35930 designs. The new design allow customers to add lightning protection to the existing design with minimum expenses.

In 2018, Littlefuse Inc. launched two series of SIDACtor® protection thyristors to protect equipment in the high exposure environment from sever lightning strikes. The new system offers protection against multiple high surge events.

Odisha Disaster Management Authority (ODMA) is focusing on the protection from thunderstorm and lightning. The governing body has decided to install lightning arresting systems in the multipurpose shelter buildings and also support the outdoor lightning alert system. OSDMA in partnership with the Earth Networks has already installed 6 lightning detection sensors in different parts of Odisha.

Browse Full Report with TOC- https://www.factmr.com/report/2764/lightning-protection-technologies-market

Some of the prominent players in the lightning protection technologies market are A. N. Wallis & Co Ltd., Harger, Inc., Alltec Corporation, Fatech Electronic Co., Ltd., AXIS Electrical Components Pvt. Ltd., MTL Instruments Group, NexTek, Inc., Lightning Protection International Pty Ltd., K.M.L.Technology Co., Ltd., Pentair Plc, and DEHN.

Lightning Protection Technologies Market Dynamics

Growth in Smart Homes to Drive Demand in Lightning Protection Technologies Market

With the rise in smart homes installing connected technologies, the risk of an unexpected electrical threat increases. This calls for adequate protection, especially in the multifamily community where the use of smart devices is higher. Smart homes featuring complex energy collection systems including geothermal, and solar panels, home automation is driving the demand for comprehensive lightning protection technologies and systems.

Majority of the smart home owners are focusing on using surge protection devices also known as overvoltage protector that are mostly installed alongside main circuit breaker to detect and stop external surges and protect against surges from lightning strikes. Moreover, with tall structures as the most likely the point of contact in lightning strike, the demand for lightning protection technologies is significantly growing in these structures. With growing demand for lightning protection, manufacturers in the lightning protection technologies market are developing smart surge protectors that allow the users to control devices with an app or through voice control using Google Assistant or Amazon Alexa. More such features are being introduced in lightning protection technologies for smart homes.

Rise in Installation of Lightning Protection Technologies for Telecommunication Towers

With rising urbanization, the demand for connectivity across the globe has increased, thereby, driving the demand for telecommunication towers such as television or radio repeaters, cellular, and microwave communication. The telecommunication towers have emerged as one of the largest users of lightning protection technologies for protection against direct strikes, and to avoid failure of electronic components thus enhancing the installation life.

In recent years, owing to the space constraints, and rising cost of land, rooftop towers are gaining popularity among the mobile network operators and telecom tower companies. Rise in number of smartphone users and subscribers especially in the developing countries, and initiative by governments to connect areas over telecom network is resulting in the growth of telecom towers, this, in turn, is likely to drive adoption of lightning protection technologies. Moreover, mobile operators are also increasingly investing in telecom network infrastructure development.

Stringent Regulations on Lightning Protection to Challenge Lightning Protection Technologies Market Growth

Lightning protection technologies have become important for the safety of critical installations and with a rise in new electrical products and devices. However, many countries have national codes and standards addressing the design and installation of lightning protection technologies. Manufacturers in the lightning protection technologies market also find it difficult to offer same product in different markets due to the difference in the standards. For instance, there is a significant difference between international standards and the US standards for lightning protection. Moreover, there are design guidelines for proper lightning protection system in various countries to ensure better lightning protection technologies and system designs for increased protection.

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About FactMR FactMR is a fast-growing market research firm that offers the most comprehensive suite of syndicated and customized market insights reports. We believe transformative intelligence can educate and inspire businesses to make smarter decisions. We know the limitations of the one-size-fits-all approach; that's why we publish multi-industry global, regional, and country-specific research reports.

Contact Us FactMR 11140 Rockville Pike Suite 400 Rockville, MD 20852 United States Email: [email protected] Web: https://www.factmr.com/ Blog: https://factmrblog.com/ Read Industry News at - https://www.industrynewsanalysis.com/

INO Measure Co., Ltd có khả năng tư vấn mua sắm, sử dụng, lắp đặt và cung cấp các thiết bị đo lường và tự động hoá. Nếu bạn có nhu cầu mua sắm hoặc cần sự hỗ trợ về kỹ thuật cho một thiết bị không được liệt kê ở đây, xin vui lòng liên hệ với chúng tôi.

Vui lòng liên hệ với chúng tôi– chúng tôi sẽ liên hệ lại với khách hàng bằng điện thoại hoặc email.

Lưu ý: Tham khảo ý kiến của nhân viên INO sẽ giúp bạn tiết kiệm được thời gian và chi phí khi cần mua sắm. ​​Với sự tư vấn của chúng tôi, bạn sẽ không gặp khó khăn khi tìm hiểu về đặc tính của sản phẩm cần mua.

Application area

Liquids and bulk solids

The VEGACAP 62 is a point level sensor for use in all areas of industry. The partly insulated probe is suitablle for measurement of bulk solids and liquids. The proven mechanical construction offers high functional safety.

Your benefit

High flexibility through shortenable probe

Long lifetime and low maintenance requirement through robust mechanical construction

Universal use in all products

Technical data

Process-temperature

-50 … 200 °C

Process-pressure

-1 … 64 bar

Version

with screening tube PN1

Standard

Materials,-wetted-parts

PTFE

316L

Alloy 400 (2.4360)

PEEK

Steel C22.8

Threaded-connection

≥ G½, ≥ ½ NPT

Flange-connection

≥ DN25, ≥ 1″

Seal-material

no media contact

Housing-material

Plastic

Aluminium

Stainless steel (precision casting)

Stainless steel (electropolished)

Protection-rating

IP 66/IP 68 (0.2 bar)

IP 66/IP 67

IP 66/IP 68 (1 bar)

Output

Relay (DPDT)

Contactless electronic switch

Transistor (NPN/PNP)

Two-wire

Ambient-temperature

-40 … 80 °C

► Các câu hỏi, thắc mắc, thông tin liên quan đến sản phẩm từ khâu mua sắm, lựa chọn, sử dụng, cài đặt hay thay thế, vui lòng liên hệ với INO team để được hỗ trợ và tư vấn kịp thời.

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Model tương tự:

VEGA Việt Nam Radar sensor for continuous level measurement of liquids VEGAPULS 64 VEGA Việt Nam Its flood-proof IP 68 housing ensures maintenance-free operation. The sensor is operated via the signal cable (HART, Profibus PA or FF) or via Bluetooth. VEGAPULS WL 61 VEGA Việt Nam TDR sensor for continuous level and interface measurement of liquids VEGAFLEX 81 VEGA Việt Nam Radar sensor for continuous level measurement of bulk solids VEGAPULS 69 VEGA Việt Nam TDR sensor for continuous level measurement of bulk solids VEGAFLEX 82 VEGA Việt Nam Ultrasonic sensor for continuous level measurement VEGASON 61 VEGA Việt Nam Radiometric sensor for continuous level measurement FIBERTRAC 31 VEGA Việt Nam Vibrating level switch for liquids VEGASWING 61 VEGA Việt Nam Vibrating level switch for granular bulk solids VEGAVIB 61 VEGA Việt Nam Microwave emitter for level detection of bulk solids and liquids VEGAMIP T61 VEGA Việt Nam Vibrating level switch for powders VEGAWAVE 61

Calibrator http://www.calibrator.vn/nhiet-do-ap-suat-3/6851/