Sabtu, 19 Februari 2022
AMNIMARJESLO Glass Door GOVERNMENT 2215 on the 4 TMUs ( 4 Tracker to be Moving Union ) , Look that and Stay that AMSWIPERGLOCK
Evidence , Analasys , Sensor , Interface , Distance and Time , Space and Time in Flying Object , Maneuvers , Motion Sequence Schemes , Probability analysis , Locking Targets Automatically , Calculate Direction Chance , Launch Weapon Trail , Synchronize Tracker and Target , Go to Match , STAR .
Welcome and come on to lets go , we need to study and practical about Evidence to detect fast and undetected flying targets can use 4 TMUs :
1. Moving Radar Active Electronically - Scanned
2. Radio Frequency ( RF ) Jammer
3. Electro Optical Targeting POD ( EO - TGP )
4. Infrared Search and Track ( IR_ST )
Of All That Efficency , Effectiveness , Quality , and the best electronic methods are Block chain that match and integrate .
10.24 : 20 February 2022
( Gen . Mac Tech ( EASID STAR ) )
Case in Bird free Moving to be integrated
Case at Rain , Cloud and Flash
locking objects is by means of electronic techniques that are efficient, effective in quality and understand:
1. The right space and time;
2. the courage to take and decide which electronic key is right;
3. Create and analyze scatter matrix patterns in real time;
4. Work patterns and goals for the future (time ahead), analysis of targets in space and time in the possible motion of space and time. take a look at the concepts of space and time and their possibilities in the EINSTEIN Protocol.
Electronic circuit compilation , Graphing , Elements , Location in one shoot monitoring .
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Crab Tactical ::
Crab is a working animal, working by digging holes on the edge of the water and moving on the water's edge, working individually but still on the edge of the water. Wild but Smart Animal .
The intersection of High Tech and defense
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Today it is more important than ever to keep the supply of processing solutions across the sensor chain trusted and secure. Silicon Valley technology leaders, such as Intel, Xilinx and Nvidia, are making significant investments in our U.S. foundry (or fab) infrastructure to enable the security and supply of microelectronics. But that is only part of the story. It is also necessary to extend the trusted, secure supply chain to companies that adapt this microelectronics technology to the very specific requirements of the aerospace and defense (A&D) industry.
It was May 24, 1844 when Samuel Morse transmitted his famous telegraph message “What hath God wrought” from Washington to Baltimore. Twenty years later, the U.S. Military Telegraph Corps had trained 1,200 operators and strung 4,000 miles of telegraph wire, which increased to over 15,000 miles by the end of the Civil War. While long-distance communication proved a significant advantage for the Union armies, it also opened the door for wiretapping. It was these early experiences that demonstrated the impact of surveillance and set the foundations of electronic warfare (EW).
Over the last century, electronic warfare has had an increasing role in shaping the outcomes of conflicts across the globe; however, few people appreciate its significance and fewer still understand the technology. In this first post of our electronic warfare blog series, we present a brief history of the technology behind electronic warfare. Just as older cars are more intuitive to repair, the early EW systems are easier to understand.
While wire-tapping was used during the Civil War, it wasn’t until the 20th Century that the field of electronic warfare began to mature. By the start of World War I, the need to for rapid communication over long distances became even more critical—leading to significant advances in the emerging field of signal intelligence. Immediately following the declaration of war, the British severed Germany’s undersea cables, forcing them to rely on telegraph and radio—both vulnerable to interception. To protect the content of the transmissions, Germany began expanding on its cryptography capabilities.
During World War II, the use of the electromagnetic spectrum played an even larger role. It was quickly discovered that by flying bombing runs at night, the bomber crews were protected from anti-aircraft fire. However, locating targets at night was no easy feat.
The Lorenz System
Prior to the start of the war, Germany had invested in commercial RF systems to support blind landings at airports with reduced visibility. Called the Lorenz System, it operated by switching a signal between two antenna elements—one pointed slightly more towards the left and the other towards the right. Instead of equal pulse lengths on each antenna element, the switch sent the signal to the right element for a longer period of time—creating a long pulse on the right antenna and a short pulse on the left. As the plane approached the runway, the pilots would hear short tones if they were too far to the left and long tones if they were too far to the right. When they were properly aligned, they would receive both signals and hear a continuous tone.
During the war, this system was modified to use large, high-directivity antennas to transmit long-range, narrow beams. Two systems were built such that the beams could be steered to intersect directly over the target. By following one beam, the pilots listened for the second signal to know when they were over the target and timed the release of bombs. This simple system drastically increased the effectiveness of the night raids over England and made the development of a system to counter the beams a top priority.
Upon discovery of the German system, the British developed a method to interfere with the beams. Using high power transmitters, the British would broadcast the same long-tone pulse signal used by the German system. When this signal was superimposed on the same frequencies, the German aircraft would never hear the steady tone and would be unable to simply follow the beam to their target. Other methods of jamming the German beams involved the use of a BBC transmitter to broadcast a steady tone on the same frequency. This CW signal filled in the breaks between pulses rendering the German system unusable.
As the British began their bombing campaigns over Germany, they too needed a method to locate targets at night. Their approach was a similar system that used two transmitters; each broadcasting a train of pulses. By measuring the time difference between received pulses, the pilots were able to navigate. However, this system was also susceptible to jamming.
The Emergence of Radar
In addition to the jamming of their navigational aids, the British bombers faced a new threat—German fighter pilots that were able to track the British planes using radar. One type of radar encountered by the British was a land-based early warning system that alerted the Germans to an approaching attack and also provided details such as the number of aircraft. Through intercepted radio communications and direct raids on radar installations, the British were able to learn the details of these systems—such as the operational frequencies—that enabled them to develop the technology to combat them.
Instead of simply jamming the radar, the allies developed a system that would receive the radar signals, amplify them, and re-transmit them to the radar receiver. These additional signals were perceived by the radar system as reflections from additional aircraft. Employing this technology, a single aircraft could function as a decoy and pull resources away from other areas. However, these early systems were dependent on the radar frequency, and by using multiple radars with different frequencies, it became much more challenging to deceive them.
To respond to the radars that operated over a wider band of frequencies, the Allies developed a jamming system that would transmit noise in various frequencies across the radar bands. This was effective until the Germans started using additional frequencies for the radar. Instead of jamming the radar itself, the allies discovered they could jam the communication signals between the radar operators and the fighter pilots. By sweeping a receiver over a broad frequency range, the British were able to determine the specific frequency that the Germans were using to communicate then transmit noise on that frequency.
Continued Technology Development
This back-and-forth cycle of inventing new ways to use the electromagnetic spectrum and developing the means to counter these new technologies continued through World War II and the Cold War. Even in the early days it was not sufficient to just have the best technology—in order to stay ahead, the technology required constant updates. Instead of deploying a system that could operate independently for a decade, EW systems required consistent modification to address emerging threats.
Now, over a century and a half after that famous telegraph message, the invisible battle over control of the electromagnetic spectrum continues. The ability to communicate, track objects with radar, and to use GNSS to navigate have become critical to success on the battlefield. Additionally, a major advantage is achieved by disrupting an adversary’s ability to communicate, use radar and use GNSS. With today’s environment of rapid technology growth—such as compact GaN, high speed processing and AI—the battle for EW superiority is at its fasted pace yet.
In the next post in this series on electronic warfare we provide an overview of radar technology before continuing on with posts on electronic support, electronic attack and electronic protection.
Glass Door ( Transpose ) _ Startrek Tech
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10 Star Trek Gadgets That Have Beamed Into Reality
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For the past half-century, Star Trek has offered fans a vision of the future by taking them on a deep voyage into the imagination to explore strange new worlds and seek out new life and civilizations, all while boldly going where no man or woman has gone before.
If there’s one thing that we have learned from these televised trips, it’s that space is filled with so many fictional technological wonders, some of which may have influenced real-world scientific developments, discoveries, and inventions- But is it really Star Trek that has helped to make it so?
Grab a cup of earl grey tea (hot!) from the replicator and join us on The Bridge as we assess the data from Starfleet’s most classified files to identify which technologies, gadgets, and services have beamed into existence after appearing in the science fiction franchise.
1. Communicators
In the fictional universe of Star Trek, the crew of the Starship Enterprise use communicators to contact others, both onboard and off-board the ship. The handheld device allows crew members to contact other starships in orbit, which proves particularly useful when faced with challenging situations.
For years, people have been using real-life communicators, otherwise known as cell phones, to regularly talk to people. Martin Cooper, the man credited with the invention of the first handheld cellular phone in the 1970s, has stated that his prototypes for the device were inspired by the original Star Trek tech.
2. Replicators
In the Star Trek universe, the replicator has a number of functions and purposes, with some proving to be more popular than others. For instance, Captain Jean-Luc Picard frequently uses the machine to order a cup of “Tea, Earl Grey, Hot,” which is then produced from the ship’s reserves.
These days, real-world replicators exist in the form of 3D printers, which build three-dimensional objects from a computer-aided design model. While they might be lacking the capability to deliver the perfect brew, these devices have a range of practical processes in order to manufacture complex objects.
3. Telepresence
Crewmembers aboard the Starship Enterprise are able to access special telepresence technologies that allow one person to connect with another in a way that makes both parties feel as if they are present in the same location, even though they might in fact be separated by time and space.
Since 1966, this invention has become an increasingly common and useful communication tool in real-world scenarios. In particular, Cisco’s telepresence system offers an authentic experience by mirroring the surroundings of multiple users in a videoconference to make it seem like they’re together.
4. Tricorders
The tricorder is another important piece of equipment seen in the Star Trek original series. The multifunctional handheld device can be used to sensor scan an environment or an individual and record data for analysis. In particular, Dr. Leonard “Bones” McCoy often uses it to diagnose and cure patients.
Here on Earth, a number of parallel products have been created to mimic the capabilities of the Star Trek device. For instance, the DNA Lab by QuantuMDx can scan a patient and deliver a diagnosis in 15 minutes, while NASA employs LOCAD to measure organisms at the International Space Station.
5. Universal Translators
While Captain Kirk and his crew planet-hop aboard the Starship Enterprise, the space squad make contact with several different alien races and species, originating from a variety of strange new worlds, so the universal translator is an essential piece of kit to decode these foreign languages.
Today, there are numerous technologies working to achieve the same outcome, though admittedly many have not reached Starfleet’s level quite yet. A lot of companies, however, are making significant progress in developing more advanced software that can translate complex sentences, especially via apps.
6. Hypospray
Hypospray is one of the gadgets that is commonly used in Star Trek because Leonard “Bones” McCoy is a doctor, not a time-waster, and this medical device speeds up the process of administering medicine by injecting it through the skin using a non-invasive transport mechanism.
In reality, jet injectors have been in existence since the 1960s, and though syringes have not yet been phased out, new technology is constantly being developed. MIT engineered a next-generation device that could make a trip to the doctor’s office a less painful experience in the not-too-distant future.
7. Tablet Computers
Personal Access Display Devices, or PADDs, are shown to be in widespread use since at least the 22nd century in the Star Trek universe. The futuristic computer interface is used by space-faring organizations to punch in coordinates for star systems, as well as being a recreational tool aboard the ship.
Over the years, we have witnessed real-world computers evolve into slim-line, touchscreen devices with significant computing power. Apple’s first-generation iPad helped to bring the device further into the mainstream in 2010. Now, many rely on tablet computers for both work and leisure activities.
8. Phasers
In Star Trek, phased array pulsed energy projectiles, aka phasers, are available in a wide range of sizes and styles, ranging from handheld firearms to starship-mounted weapons, which can discharge beams, slice materials, trigger explosions, and, most famously, be set to stun.
In the current world, comparable alternatives have been in use since the 1970s. Tasers and stun guns work on a similar principle to Captain Kirk’s primary weapon, however, these energy weapons have to be activated in close range to the target (the Borg or otherwise) to stop them in their tracks.
9. Tractor Beams
The high-powered tractor beams in Star Trek are often used by starships and space stations to control and physically maneuver objects in deep space, which is particularly useful for towing ships in need of assistance to safety and pushing ships out of dangerous situations.
In real life, optical tweezers operate in a comparable fashion to the graviton beams that commonly appear in the sci-fi genre, though on a much smaller scale. Rather than hauling ships from one location to another, these scientific instruments use laser beams of light to hold and move microscopic objects.
10. Warp Drive
Warp Drive is one of the most iconic technologies used in Star Trek voyages. It works by generating warp fields to envelop the Starship Enterprise in a subspace bubble to distort the spacetime continuum and propel the vessel forward at a velocity that is faster than the speed of light.
Interestingly, NASA has indicated that this completely fictional concept could actually be possible. In recent years, the scientific community has become increasingly excited about the concept of a warp propulsion system, which could provide the blueprints for ultrafast interplanetary travel in the future.
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Transporter and Electronic Glass Door
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hi, its very interesting blog related to Amnimarjeslo glass door government. I have found an interesting projects in this IEEE Projects on embedded systems projects
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