Engineering Quantum Technologies Group (Radar, Compass, Network, Quantum Computer and Nano-Satellite)

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey
Quantum nano satellites
One of TÜBİTAK BİLGEM's first publications on quantum nano satellites

An application was made on January 6, 2020 for the article to be accepted. This shows that 1 or 1.5 years have passed since the project. An important point for the history of quantum satellite project in Turkey
 
Last edited:

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey
Brief history of quantum radars. In the article released on September 25, 2020, it is stated that Quantum radars cannot yet overcome stealth technologies.
 

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey

Quantum Entanglement Drones​


Quantum Entanglement Drones: We are now on the verge of the dawn of a new age. Technological development and scientific studies do not slow down. We have a lot of data to move forward. Drones are one of the leading inventions that are at the forefront of the subject and the technologies that shape our future. Now, drones have begun to be used for the development of quantum technology. One of the drones' new missions was the transmission of a quantum signal in a one kilometer orbit. It also successfully completed this. Two different drones were used in the experiment. Their task would be to produce and distribute photon pairs in structures belonging to quantum communication systems. The trial was successful. Quantum Entanglement Drones were once again tested, and this communication was groundbreaking according to scientists.

Broadcast waves from cell phones, radio stations and Wi-Fi centers are full of information. These waves can transmit quantum encrypted messages to our computers in the future.

The trial was made between two ground stations located 1 km from each other. Two different drones are used for this. With this experiment, it will be possible to establish a quantum network on our residential areas. The fact that drones are mobile will also allow us to reach a very flexible structure.

In an environment where communication is secure on the Internet and cyber attacks are experienced so intensely, data security becomes more and more important every passing minute. Especially the fact that bank employees now work from their homes makes data security incredibly important in this regard. Quantum communication system promises secure communication to the technology world.

What is Quantum Entanglement?​

It is planned to use particles that have a quantum-mechanical relationship in the quantum communication system. Thanks to entangled photons, encrypted messages will be able to travel securely from one place to another.

One of the most widely used systems among the communication systems we are in is fiber optic infrastructures. However, in fiber optic cabling systems, most of the photons have scattering problems before they reach the target. In a sense, we have the trouble of encountering weak signals. Thanks to Quantum Entanglement and Drones, the first steps of a completely different era are before us.

A photon can be sent to the users with the structures consisting of quantum pairs, that is, quantum bits. The loss of entanglement of photons can also create a unique security advantage in terms of cybersecurity. In other words, communication will stop from time to time, which will reduce leakage to communication lines.

Just as the Chinese provided quantum communication in 2018, when quantum data is sent via the atmosphere, problems such as scattering will not be too much, data communication will be more effective. This trial in 2018 took place between China and Austria.

The current record in a fiber optic based quantum encryption is also a record of 421 km.

Ref: https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.121.190502

However, the disadvantage is that communication satellites are expensive for now and their adaptation to changing demands also puts the cost elements forward.

Small drones carrying optical equipment can also provide a flexible solution that can connect multiple users in a quantum network.

Scientists also inform that when communication is required, drones will be used depending on time and location and fixed base stations can be avoided. It is also a fact that existing communication systems also harm the ecosystem.
Studies on Quantum Communication systems continue in various parts of the world. We should also say that drones were used in these studies. In early 2020, Chinese scientists produced data using an 8-bladed drone.

One of the infrared photon pairs produced in this experiment was directed to a ground station named Alice and the other to another ground station named Bob.

e7_1.png


The data of the incoming photons were also collected with a 26mm diameter telescope. We of course also state that the telescope is naturally a telescope with a photon detector.

Diffraction is the leading phenomenon that adversely affects data health in optical communication systems. If the aperture of the telescopes that collect them during the propagation of the photons and as a result of their progress is less than the aperture of the transmitted wave, it will reduce the chance of data collection. In order to eliminate this negativity, a gap of 200 meters between two stations was chosen.

The distance between the drones, that is, between Alice and Bob, was a total distance of 1 km, with the drones of 200 meters and the ground stations 400 meters. The main reason for using two different drones was to separate the stations from each other and to make the experiment more unique and to transfer the data to the other telescope by focusing it.

In the experiment, the Alice detector recorded about a quarter of the photons that came to it, while the Bob detector was recording about four percent of the photons sent to it.

The team performed a different version of the Bell's Inequality test by comparing the photon polarizations taken in Alice and Bob.

Let's talk a little bit about the Bell inequality test. It is a well-known physics experiment designed to test the theory of quantum mechanics in relation to Albert Einstein's concept of local realism.

The theorem is usually proven by considering a quantum system made up of two entangled qubits with original tests as was done on photons.

The most common examples relate to systems of particles circulating in spin or polarization. Quantum mechanics allows predictions of correlations that can be observed when the turns or polarizations of these two particles are measured in different directions.

Bell also demonstrated that if a local latent variable theory is applicable, these correlations must also meet certain constraints called Bell inequalities.

According to the results obtained in the experiment, it was confirmed that the photons were entangled. In other words, this experiment excited the whole scientific community in a way.

Now scientists are expanding the scale of the experiment and planning to experiment with multiple drone systems in much larger areas.

Going back to the initial costs of the system, quantum communication systems require special fiber networks or very expensive satellite connections. Considering that drones also add to the cost of these existing systems, it is a fact that there is a long way to go.

Martin Bohmann, a quantum information expert at the Austrian Academy of Sciences, states that one of the advantages of the drone system is that it can be communicated globally, not on the same line with the points to be contacted.

It points to the need to reduce photon transmission losses to make a multi-drone system competitive with other quantum network technologies, but believes such improvements are possible.
EswJvvwW4AUuMLA


A different quantum network experiment was conducted in Germany in the context of aviation applications. With an airplane flying at 290 km / h speed, data transmission was realized at 145 bit/h from a distance of 20 km.
 
Last edited:

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey

Quantum Warfare: Definitions, Overview and Challenges​




I found the graphic's article. They've studied everything about quantum wars in detail. There's even quantum electronic warfare. I've made a series on it myself. I downloaded and reloaded articles that interested me. Note that some articles are not in the main article
 

Zafer

Experienced member
Messages
4,683
Reactions
7 7,389
Nation of residence
Turkey
Nation of origin
Turkey
I have faith that quantum radars will make the invisible visible and we will have them in due time.
 

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey

Noise-Tolerant Object Detection and Ranging Using Quantum Correlations​

Imaging, detection and ranging of objects in the presence of significant background noise is a fundamental challenge in optical sensing. Overcoming the limitations imposed in conventional methods, quantum light sources show higher resistance against noise in a time-correlation-based quantum illumination. Here, we introduce the advantage of using not only time correlations but also polarization correlations in photon pairs in the detection of an object that is embedded in a noisy background. In this direction, a time- and polarization-correlated photon pair source using the spontaneous parametric down-conversion process is exploited. We found that the joint measurement of correlated pairs allows distinguishing the signal from the noise photons and that leads to an improved signal-to-noise ratio. Our comparative study revealed that using polarization correlations in addition to time correlations provides improved noise rejection. Furthermore, we show that polarization correlation allows undoing the detector limitation where high background often leads to detector saturation.


@drkadirdurak
Academician Kadir Durak new article
https://twitter.com/drkadirdurak
 

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey
01.04_4_20231227_2_61861270_96221464.jpg



The first products of ASELSAN's quantum studies appeared

ASELSAN established the Quantum Research Laboratory (KUANTAL) approximately 1 year ago in order to carry out studies in the field of quantum technologies.

KUANTAL, which prepares Turkey for the technologies of the future, is taking firm steps towards becoming the country's first center in this field.

With the projects to be carried out in the laboratory implemented on the TOBB University of Economics and Technology campus, it is aimed to increase Turkey's knowledge and technology readiness level in quantum technologies and transform them into local and national systems through ASELSAN.

The laboratory is aimed to be the only research laboratory in the country and one of the few in the world, in terms of the experimental capabilities and research opportunities it will have.

It is planned to carry out high-impact research and prototype development activities at KUANTAL, with experimental infrastructures and academic collaborations with many universities.

Focusing on the basic technologies in this field, ASELSAN is strengthening its muscles in one of the technologies of the future such as quantum. It is aimed to benefit from the gains here in all technology fields.

While the basic science studies were completed in the laboratory, which constitutes one of the facets of ASELSAN for the civilian field, a series of engineering studies began to be carried out.

Almost all of these studies have application opportunities for all areas in which ASELSAN operates.

In the laboratory, which is in the process of "pre-competitive joint work and cooperation", studies are carried out with researchers and academicians at home and abroad, and with enterprises and companies that have talent in this field.

01.04_4_20231227_2_61861270_96221468.jpg


Higher performance products will be created


Studies are being carried out in the laboratory to develop products that work at higher performance than today using quantum technologies.

There are a number of special test environments in the laboratory for these studies. During the work, "absolute zero" degree conditions are created to minimize the effect of thermal noise. For this purpose, work is carried out at temperatures close to -273 degrees. In the laboratory, studies are carried out on the energy level of the particles that make up light.

Research in the quantum field will enable sensors or devices in existing products to work better. In this way, capabilities in areas such as communication, perception, information systems and cryptology will further increase.

With quantum systems; Structures that cannot be confused, cannot be imitated, and are noticed in case of intervention are achieved. When external eavesdropping and measurement attempts are made, the system is prevented from functioning properly and it is revealed that eavesdropping is taking place.

The first products emerged within the scope of ASELSAN's studies on quantum technologies. These include the quantum random number generator and the first quantum integrated circuits.

01.04_4_20231227_2_61861270_96221467.jpg


Stopped brain drain

The laboratory also plays an important role in stopping brain drain and reverse brain drain in an area where trained human resources are quite limited.

KUANTAL enabled quantum researchers from Turkey, who received invitations from different parts of the world, to stay in the country. Some Turkish scientists who have been working in this field abroad thanks to the laboratory have also put returning to the country on their agenda.

ASELSAN aims to contribute to the creation of Turkey's Quantum Strategy Road Map through KUANTAL in the future.

 

nova_jones

New member
Messages
1
Reactions
1
Nation of residence
Pakistan
Nation of origin
Pakistan
Exciting advancements in quantum technology! Looking forward to seeing the innovative solutions these projects will bring.
 

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey


Un-jammable quantum tech takes flight to boost UK’s resilience against hostile actors​


  • In a commercial world-first, quantum navigation tech developed in the UK was successfully tested in flight
  • while GPS jamming is relatively rare and does not directly impact an aircraft’s flight path, quantum systems will provide another layer of security
  • the government has supported the company running the tests, Infleqtion, and their partners from across the country with nearly £8 million as part of its vision to make the UK a leading quantum-enabled economy
In a first-of-its-kind achievement, the UK has successfully completed commercial flight trials of advanced quantum-based navigation systems that cannot be jammed or spoofed by hostile actors.

While GPS jamming is currently relatively rare and does not directly impact an aircraft’s flight path, new quantum-based Positioning, Navigation, and Timing (PNT) systems could, over time, offer one part of a larger solution to providing highly accurate and resilient navigation that complements current satellite systems – which could help ensure that the thousands of flights that take place around the world daily, proceed without disruption.

Infleqtion, a quantum technology firm, in collaboration with aerospace companies BAE Systems and QinetiQ, completed the trials at MoD Boscombe Down in Wiltshire, with Science Minister Andrew Griffith aboard the final test flight on Thursday 9 May.

These tests are the first time that this sort of ground-breaking technology has been tested in the UK on an aircraft in flight, and the first such flights worldwide that have been publicly acknowledged.

Led by Infleqtion and in collaboration with industry and academic partners, this project has received backing of nearly £8 million from the government. This funding, together with the £2.5 billion National Quantum Strategy and the National Quantum Technologies Programme, aims to cement the UK’s position as a leading quantum-enabled economy.

Science Minister Andrew Griffith said:

From passenger flights to shipping, we all depend on navigation systems that are accurate, safe and secure. The scientific research we are supporting here on quantum technology could well provide the resilience to protect our interests.
The fact that this technology has flown for the first time in British skies, is further proof of the UK as one of the world leaders on quantum.
In a series of test flights, the team led by Infleqtion has demonstrated two ground-breaking quantum technologies: the compact Tiqker optical atomic clock and a tightly confined ultra-cold-atom-based quantum system, both aboard QinetiQ’s RJ100 Airborne Technology Demonstrator, a modified aircraft.

The technology being tested on the flight will form part of a Quantum Inertial Navigation System (Q-INS), which has the potential to revolutionise PNT, with the system offering exceptional accuracy and resilience, independent of traditional satellite navigation using GPS.

PNT helps us know our location, navigate, and keep track of time. The cornerstone of modern PNT technology is precision clocks. These ultra-accurate timekeepers are crucial for various applications, and portable production of ultracold atoms is another key piece of the puzzle. Ultracold atoms - atoms that have been cooled to temperatures near absolute zero (the coldest possible temperature) - are ideal for building quantum accelerometers and gyroscopes, which form the heart of a Q-INS.

The test is part of a project funded by UK Research and Innovation (UKRI) specifically focusing on creating quantum sensors to address the UK’s heavy reliance on GNSS/GPS for location, navigation and timing data. This dependence creates a vulnerability, as a single point of failure (like jamming or spoofing GPS signals) could disrupt critical economic, defence, and strategic activities.

The consortium working alongside Infleqtion includes Fraunhofer Centre for Applied Photonics, Alter Technology UK, Caledonian Photonics, Redwave Labs, PA Consulting, BAE Systems, and QinetiQ.

Infleqtion UK President, Dr Timothy Ballance, said:

Our recent trials mark a significant step forward in the development of quantum PNT solutions. The work we have done directly addresses the critical need to reduce our reliance on satellite navigation systems, which are vulnerable to various risks.
The successful flight trials demonstrate the potential of quantum technology in overcoming navigation system challenges, which is an exciting development for future applications in the aerospace industry and beyond.
Henry White, Sensing Technology Lead - BAE Systems, said:

These trials are an important step forward in developing quantum technology that could ultimately offer a significant military advantage. Knowing reliably and precisely when and where any asset and sensor system are, feeds into additional options for platform design and capability. This will play a big role in supporting the development of next generation combat air systems. Working closely with wider industry and experts now, at the early stages of the technology development helps us to shape the solution in a way that ensures the technology can be integrated for military applications.
Simon Galt, Managing Director (Air) at QinetiQ said:

We’re proud to be partnering with BAE Systems and Infleqtion to enable the successful trial of this cutting-edge technology, demonstrating our ability to rapidly and effectively collaborate across the defence ecosystem, combining our quantum expertise with our Airborne Technology Demonstrator jet.
Roger McKinlay, Challenge Director Quantum Technologies at Innovate UK, part of UK Research and Innovation (UKRI), said:

Modern infrastructure is increasingly dependent on highly accurate timing and navigation derived from satellite signals. These flight tests mark the culmination of two excellent projects, funded through UKRI, which Infleqtion has had the vision to create and the deftness in leadership to execute with an outstanding team of collaborators.
The completion of these flight trials marks a significant milestone towards Mission 4 of the UK’s National Quantum Strategy. By 2030, this mission aims to deploy quantum navigation systems on aircraft, providing next-generation accuracy and resilience independent of satellite signals. The successful testing of an optical atomic clock, Infleqtion’s Tiqker, and core elements of a quantum inertial sensor aboard QinetiQ’s RJ100 Airborne Technology Demonstrator represents a breakthrough in airborne quantum technology.

 

Bogeyman 

Experienced member
Professional
Messages
9,192
Reactions
67 31,256
Website
twitter.com
Nation of residence
Turkey
Nation of origin
Turkey

image

UK builds world’s smallest light detector to shrink quantum computers​

Researchers at the University of Bristol in the UK have developed the world’s smallest quantum light detector on a silicon chip. The tiny detector, which is thinner than the width of a human hair, can help scale up quantum technology, a university press release said.
In the 1960s, the field of electronics took a major leap after scientists turned large transistors into small microchips that could be built cheaply. Since the detection of the light signal or quantum bits has been minimized, a similar fate can now be expected for quantum computers.
Current designs of quantum computers are for massive machines that occupy rooms and need freezing temperatures to operate. If, like its binary counterpart, a quantum computer has to be deployed at scale, the device itself needs to be shrunken in size and made easier to switch on and operate.
The research team led by Jonathan Matthews, a university professor and the Director of Quantum Engineering Technology Labs, has taken the first step toward miniaturizing the quantum computer.

Homodyne detectors​

The research team showed first glimpses of its work in 2021 when it linked a photonics chip with an electronics one and increased the speed of quantum light detection. Three years later, they integrated the two components onto a single chip, reducing the detection speed by a factor of 10 and the footprint by a factor of 50.
The quantum light detector integrated into the chip and its circuitry measures 0.0031 inches (80 micrometers) by 0.0086 inches (220 micrometers). For comparison, the average thickness of human hair is 0.0019 inches (50 micrometers).
Matthews added in the press release that the detector is known as a homodyne detector. It is extensively used in quantum optics since it operates at room temperature and in highly sensitive sensors such as gravitational wave detectors.

low-res-1.jpg

Giacomo Ferranti holds the silicon ePIC quantum chip. On the right is a magnified image of the chip. Image credit: University of Bristol

The advantage of the smaller detector is quicker detection of quantum light, which improves the speed of communication within the system and, hence, the overall operational speed of the quantum computer.

Wary about noise​

While smaller and faster sensors are preferable, they are also noise-prone. “The key to measuring quantum light is sensitivity to quantum noise,” said Giacomo Ferranti, a lecturer at the University of Bristol, who was also involved in the work.
“Quantum mechanics is responsible for a minute, fundamental level of noise in all optical systems. The behaviour of this noise reveals information about what kind of quantum light is travelling in the system, it can determine how sensitive an optical sensor can be, and it can be used to mathematically reconstruct quantum states,” Ferranti added in the press release.

In their work, the researchers were keen to demonstrate that shrinking the detector size did not affect its sensitivity to measure quantum states, which they succeeded in doing. Another highlight of the research was developing the chip using an existing commercial foundry, making it easier to roll out at a larger scale.
“While we are incredibly excited by the implications across a range of quantum technology, it is critical that we as a community continue to tackle the challenge of scalable fabrication of quantum technology,” Matthews stated. “Without demonstrating truly scalable fabrication of quantum hardware, the impact and benefits of quantum technology will be delayed and limited.“
The research findings were published in the journal Science Advances.

 

Follow us on social media

Top Bottom