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Privacy
CyberCrime Cyberhackers CyberThreat Cybesecurity GNSS GPS GPS Spoofing Privacy

GPS Spoofing Emerges as a Serious Risk for Civil and Military Applications

 


The growing reliance on satellite-based navigation systems by modern aviation has raised serious concerns among global aviation authorities about the threat to the integrity of these systems that are emerging. As one such threat, GPS spoofing, is rapidly gaining attention for its potential to undermine the safety and reliability of aircraft operations, it is quickly gaining attention.

Global Navigation Satellite System (GNSS) spoofing, which is the act of transmitting counterfeit signals to confuse receivers of GNSS signals, has become an increasingly serious concern for aviation safety worldwide, including in India. As a result of this interference, the accuracy of aircraft navigation systems is compromised, as it compromises critical data related to location, navigation, and time. As a result, the risk of operational and security failures is significant. 

Several recent media articles have brought a renewed focus on the threat of GPS spoofing, which has become increasingly prevalent in recent years, along with its potential catastrophic impact on a variety of critical systems and infrastructure, most notably the aviation industry. There is a growing concern in this area because the incidence of spoofing incidents is on the rise in areas close to national borders, a region where the threat is particularly high.

An area of concern that has been raised in public discourse as well as parliamentary debate is the vicinity of the Amritsar border, which has drawn a significant amount of attention from the public. With an increasing prevalence of spoofing activities occurring in this strategically sensitive zone, there have been significant concerns raised about aircraft operating in the region's vulnerability, as well as the broader implications for national security and cross-border aviation safety that result from this activity. 

There is an ongoing disruption of GNSS signals in this area that is threatening not only the integrity of navigation systems, but it requires immediate policy attention, interagency coordination, and robust mitigation measures to be implemented. There is a report issued by OPS Group in September 2024 that illustrates the extent of the problem in South Asia. 

The report states that northwest New Delhi area and Lahore, Pakistan are experiencing an increased amount of spoofing activity, as evidenced by the report. The region was ranked ninth globally for the number of spoofing incidents between July 15 and August 15, 2024, with 316 aircraft being affected within the period. According to the findings of this study, enhanced monitoring, reporting mechanisms, and countermeasures are necessary to mitigate the risks that can arise from manipulating GPS signals within high-traffic air corridors. 

In GPS spoofing, also called GPS simulation or GPS spoofing, counterfeit signals are sent to satellite-based navigation systems to fool GPS receivers. This can cause GPS receivers to become deceived. By using this technique, the receiver can calculate an inaccurate location, which compromises the reliability of the data it provides. 

As a foundational component of a range of critical applications - including aviation navigation, maritime operations, autonomous systems, logistics, and time synchronisation across financial and communication networks - GPS technology serves as the basis for these applications. As a result, such interference would have profound implications for the community. It used to be considered a theoretical vulnerability for GPS spoofing, but today it has become a more practical and increasingly accessible threat that is becoming increasingly prevalent.

The advancement in technology, along with the availability of open-source software and hardware that can generate fake GPS signals at a very low cost, has significantly lowered the barrier to potential attackers being able to exploit the technology. There has been a considerable evolution in the world of cyber security, and this has created an environment in which not just governments, military institutions, but also commercial industries and individuals face serious operational and safety risks as a result of this.

Due to this, GPS spoofing has now become a broader cybersecurity concern that demands coordinated global attention and response rather than simply being an isolated incident. GPS spoofing refers to the practice of transmitting counterfeit satellite signals to mislead navigation systems into miscalculating their true position, velocity, and timing. A GPS jam is an interference in satellite communication that completely overpowers signals. 

In contrast, GPS spoofing works more subtly. In addition to subtly inserting false data that is often indistinguishable from genuine signals, this method also raises operational risk and makes detection more difficult. As a result of this deceptive nature, aviation systems, which rely heavily on satellite-based navigational data as a major component, are at serious risk. Since the GNSS signals originate from satellites positioned more than 20,000 kilometres above the Earth's surface, they are particularly susceptible to spoofing. 

The inherent weakness of these signals makes them particularly susceptible to spoofing. As a result of spoofed signals that are often transmitted from ground sources at higher intensity, onboard systems like the Flight Management System (FMS), Automatic Dependent Surveillance Systems (ADS-B/ADS-C), and Ground Proximity Warning Systems can override legitimate signals that are received by the Flight Management System. 

It is possible for aircraft to deviate from intended flight paths due to such manipulation, to misrepresent their location to air traffic controllers, or to encounter terrain hazards that were unforeseen—all of which compromise flight safety. There has been a significant advance in the use of spoofing beyond theoretical scenarios, and it is now recognized as an effective tool for both electronic warfare as well as asymmetric warfare. As a result, both state and non-state actors around the world have tapped into this technological resource to gain tactical advantages. 

According to reports during the Russian-Ukraine conflict, Russian forces employed advanced systems, such as the Krasukha-4 and Tirada-2, to spoof GNSS signals, effectively disorienting enemy drones, aircraft and missiles. An earlier example of this could be Iran's use of spoofing techniques in 2011 to take down an RQ-170 Sentinel drone controlled by the United States. The same thing happened during the Nagorno-Karabakh conflict between Azerbaijan and Armenia. 

The Azerbaijan government used extensive electronic warfare measures, such as GNSS spoofing, to disable the radar and air defense infrastructures of Armenia, which allowed Turkey and Israeli drones to operate almost with impunity during the conflict. As a result of these cases, I believe the strategic utility of spoofing in modern conflict scenarios has been reinforced, demonstrating its status as a credible and sophisticated threat to national and international security systems worldwide. 

To deal with GPS spoofing, a proactive and multi-pronged approach must be taken that includes technological safeguards, robust policy frameworks, as well as an increase in awareness initiatives. As the use of satellite-based navigation continues to increase, it is becoming increasingly important that stakeholders, such as governments, aviation authorities, and technology companies, invest in developing and implementing advanced anti-spoofing mechanisms to prevent this from happening.

There are several ways in which counterfeit signals can be detected and rejected in real time, including signal authentication protocols, anomaly detection algorithms, and secure hardware configurations, based on these protocols. Furthermore, user awareness has a significant impact on the success of counterfeit signals. Operators and organisations should develop a comprehensive knowledge of their GPS infrastructure and be aware of any unusual behaviours that could indicate spoofing attempts by tracking their GPS infrastructure. 

By regularly training employees, conducting system audits, and adhering to best practices in cybersecurity, businesses are significantly more likely to resist such attacks. Legal and ethical considerations are also critical to addressing GPS spoofing in many jurisdictions. The transmission of false navigation signals has the potential to carry severe penalties in many jurisdictions. To avoid unintended disruptions, GPS signal simulations must comply with regulatory standards and ethical norms, regardless of whether they are used for research, testing, or training purposes. 

Furthermore, keeping up with emerging technologies as well as rapidly evolving threat landscapes is essential. A reliable cybersecurity solution can serve as a critical line of defence when it is integrated with comprehensive security platforms, such as advanced threat detection software. GPS spoofing continues to grow in prominence, so it will be essential to coordinate an effort focused on vigilance, innovation, and accountability to safeguard the integrity of global navigation systems, as well as the many sectors that depend on them, in the future.
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Technology
Border Security Force CyberCrime Cyberhackers Cybersecurity Cyberthreats GPS Technology

Rising GPS Interference Threatens Global Aviation and Border Security

 


A recent report by OPS Group, a global aviation safety network, has highlighted a sharp rise in GPS interference across several global conflict zones, including India’s borders with Pakistan and Myanmar. This interference poses significant risks to passenger aircraft flying over these regions, raising serious safety concerns.

Causes of GPS Interference

According to the September report, the increase in GPS interference near borders stems from enhanced security measures and the widespread use of drones for illicit activities. These factors have contributed to the rise of “spoofing,” a cyberattack technique where false GPS signals are transmitted to deceive navigation systems. By manipulating GPS signals, spoofing can create false positions, speeds, or altitudes, leading to impaired navigation accuracy and potential aviation incidents.

To counter these threats, technologies like the Inertial Reference System (IRS) provide an alternative to GPS by calculating positions independently. The IRS offers similar accuracy and is unaffected by signal disruptions, making it a valuable backup for navigation systems in high-risk zones.

India has implemented GPS jamming technologies along its border with Pakistan to enhance security and combat drone-based smuggling operations. These drones, often used to transport narcotics, weapons, and counterfeit currency, have become a growing concern. Reports indicate that GPS interference in the region has reached levels of 10%, significantly hindering illegal drone activity. The Border Security Force (BSF) has recovered a range of contraband, including narcotics and small arms, thanks to these efforts.

Drone activity has surged in recent years, particularly along the India-Pakistan border. In Punjab alone, sightings increased from 48 in 2020 to 267 in 2022, accounting for over 83% of reported drone activities along this border. The eastern border has also seen a rise in drone use for smuggling gold, exotic wildlife, and other contraband from Myanmar and Bangladesh. While effective against drones, GPS jamming can inadvertently impact civilian navigation systems, affecting vehicle and aircraft operations in the vicinity.

Global Aviation Safety Concerns

The issue of GPS interference extends beyond border security and affects global aviation. During this year’s 14th Air Navigation Conference held by the International Civil Aviation Organization (ICAO) in Montreal, delegates addressed the growing risks posed by interference with the Global Navigation Satellite System (GNSS). Such disruptions can compromise the accuracy of aircraft positioning and navigation systems, raising safety concerns.

To mitigate these risks, the conference proposed measures such as enhanced communication between stakeholders, improved information-sharing mechanisms, and the establishment of a global contingency plan for GNSS signal outages. These initiatives aim to reduce the impact of GPS interference on aviation safety and ensure continuity in navigation services.

The rising prevalence of GPS interference underscores the need for robust countermeasures and international collaboration. While advancements in jamming technologies and alternative navigation systems address immediate threats, a long-term strategy focused on securing navigation infrastructure and mitigating interference is essential for safeguarding both national security and global aviation operations.

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Technology
Android Cyberattacks CyberCrime Cyberhackers Cybersecurity Cyberthreats Google GPS Technology

Improving GPS Technology with Insights from Android Phones

 


The effect of navigation apps drifting off course may be caused by a region 50-200 miles overhead called the ionosphere, which is a region of the Earth’s atmosphere that is responsible for such drifts. There are various levels of free electrons in this layer that, under certain conditions, can be extremely concentrated, thereby slowing down the processing of GPS signals when they are travelling between satellites and devices. 

A delay, like a delay that would occur from navigating through a crowded city street without being able to get to your place of work on time, is a major contributor to navigation system errors. As reported in Nature this week, a team of Google researchers demonstrated they had been able to use GPS signal measurements collected from millions of anonymous Android mobile devices to map the ionosphere by using GPS data from those devices. 

There are several reasons why a single mobile device signal cannot tell researchers so much about the ionosphere with only one device, but this problem is minimized when there are many other devices to compare with. Finally, the researchers have been able to use the vast network of Android phones to map out the ionosphere in an extremely precise way, matching or exceeding the accuracy of monitoring stations, using the huge network of Android phones. This technique was far more accurate in areas like India and Central Africa, compared to the accuracy of listening stations alone, where the Android technique was used. 

The total electron content (TEC) referred to as ionospheric traffic is a measure of the number of electrons in the ionosphere used within a cellular telephone network. Satellites and ground stations are used to measure this amount of electrons in the ionosphere. These detection tools are indeed effective, but they are also relatively expensive and difficult to build and maintain, which means that they are not used as commonly in developing regions of the world. 

The fact that monitoring stations are not accessible equally leads to disparities in the accuracy of the global ionospheric maps. However, Google researchers did not address one issue. They chose to use something that more than half of the world's population already possessed: mobile phones. In an interview with Popular Science, Google researcher Brian Williams discussed how changes in the ionosphere have been hindering GPS capabilities when working on Android products.

If the ionosphere were to change shortly, this may undermine GPS capabilities. Aside from contributing to scientific advances, he sees this project as an opportunity to improve accuracy and provide a more useful service to mobile device users regularly.  Rather than considering ionosphere interference with GPS positioning as an obstacle, the right thing to do is to flip the idea and imagine that GPS receiver is an instrument to measure the ionosphere, not as an obstacle," Williams commented.

The ionosphere can be seen in a completely different light by combining the measurements made by millions of phones, as compared to what would otherwise be possible." Thousands of Android phones, already known as 'distributed sensor networks', have become a part of the internet. GPS receivers are integrated into most smartphones to measure radio signals beamed from satellites orbiting approximately 1,200 miles above us in medium Earth orbit (MEO).

A receiver determines your location by calculating the distance from yourself to the satellite and then using the distance to locate you, with an accuracy of approximately 15 feet. The ionosphere acts as a barrier that prevents these signals from travelling normally through space until they reach the Earth. In terms of GPS accuracy errors, many factors contribute to the GPS measurement error, including variables like the season, time of day, and distance from the equator, all of which can affect the quality of the GPS measurement. 

There is usually a correctional model built into most phone receivers that can be used to reduce the estimated error by around half, usually because these receivers provide a correctional model.  Google researchers wanted to see if measurements taken from receivers that are built into Android smartphones could replicate the ionosphere mapping process that takes place in more advanced monitoring stations by combining measurements taken directly from the phone. 

There is no doubt that monitoring stations have a clear advantage over mobile phones in terms of value per pound. The first difference between mobile phones and cellular phones is that cellular phones have much larger antennas. Also, the fact that they sit under clear open skies makes them a much better choice than mobile phones, which are often obscured by urban buildings or the pockets of the user's jeans.

In addition, every single phone has a customized measurement bias that can be off by several microseconds depending on the phone. Even so, there is no denying the fact that the sheer number of phones makes up for what they are lacking in individual complexity.  As well as these very immediate benefits, the Android ionosphere maps are also able to provide other less immediate benefits. According to the researchers, analyzing Android receiving measurements revealed that they could detect a signal of electromagnetic activity that matched a pair of powerful solar storms that had occurred earlier this year. 

According to the researchers, one storm occurred in North America between May 10 and 11, 2024. During the time of the peak activity, the ionosphere of that area was measured by smartphones and it showed a clear spike in activity followed by a quick depletion once again. The study highlights that while monitoring stations detected the storm, phone-based measurements of the ionosphere in regions lacking such stations could provide critical insights into solar storms and geomagnetic activity that might otherwise go unnoticed. This additional data offers a valuable opportunity for scientists to enhance their understanding of these atmospheric phenomena and improve preparation and response strategies for potentially hazardous events.

According to Williams, the ionosphere maps generated using phone-based measurements reveal dynamics in certain locations with a level of detail previously unattainable. This advanced perspective could significantly aid scientific efforts to understand the impact of geomagnetic storms on the ionosphere. By integrating data from mobile devices, researchers can bridge gaps left by traditional monitoring methods, offering a more comprehensive understanding of the ionosphere’s behaviour. This approach not only paves the way for advancements in atmospheric science but also strengthens humanity’s ability to anticipate and mitigate the effects of geomagnetic disturbances, fostering greater resilience against these natural occurrences.
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Technology
GPS Military Quantum Navigation Research Technology

Navigating Without GPS: Quantum Breakthroughs and Their Impact

Navigating Without GPS: Quantum Breakthroughs and Their Impact

From everyday smartphone users to military operations, GPS plays a crucial role in determining precise locations. However, the dependency on GPS comes with its own set of vulnerabilities, including signal disruptions and potential spoofing. Enter the groundbreaking research from Sandia National Laboratories, which promises to revolutionize navigation through quantum technology.

The Quantum Leap in Navigation

Scientists at Sandia National Laboratories have achieved a significant milestone by developing ultra-compact optical chips that power quantum navigation sensors. These sensors utilize atom interferometers, a sophisticated technology that measures the interference patterns of atoms to track position and motion with unparalleled accuracy. Unlike traditional GPS, which relies on satellite signals, quantum navigation sensors operate independently, immune to external disruptions.

How Quantum Navigation Works

At the heart of this innovation lies the principle of quantum mechanics. Atom interferometers work by cooling atoms to near absolute zero temperatures, creating a state where they exhibit both particle and wave-like properties. When these atoms are subjected to laser pulses, they form interference patterns that can be precisely measured. By analyzing these patterns, the sensors can precisely determine changes in position and velocity.

The optical chips developed by Sandia National Laboratories are designed to be ultra-compact, making them suitable for integration into various devices and systems. These chips are capable of maintaining the delicate quantum states of atoms, ensuring accurate measurements even in challenging environments.

Applications and Implications

The potential applications of quantum navigation are vast and transformative. One of the most significant advantages is its ability to function in GPS-denied areas. This is particularly crucial for military operations, where GPS signals can be jammed or spoofed by adversaries. Quantum navigation ensures that military personnel and autonomous vehicles can navigate accurately without relying on external signals.

In addition to military applications, quantum navigation holds promise for the commercial sector. Autonomous vehicles, such as drones and self-driving cars, can benefit from this technology by achieving precise navigation in urban environments where GPS signals are often weak or obstructed. Furthermore, quantum navigation can enhance the accuracy of scientific research, particularly in fields like geology and archaeology, where precise location data is essential.

Overcoming Challenges

While the potential of quantum navigation is immense, there are challenges to overcome before it becomes mainstream. One of the primary challenges is the complexity of maintaining quantum states in real-world conditions. The ultra-cold temperatures required for atom interferometers are difficult to achieve and maintain outside of laboratory settings. However, the development of ultra-compact optical chips is a significant step towards addressing this challenge.

Another challenge is the integration of quantum navigation sensors into existing systems. This requires advancements in both hardware and software to ensure seamless compatibility. Researchers are actively developing robust algorithms and interfaces to facilitate the integration process.

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Technology
Cyberattacks CyberCrime CyberThreat GPS Location Quantum Navigation Technology

Quantum Navigation as the Successor to GPS

 


The cause of the recent flight cancellations by Finnair planes flying into Estonia did not have anything to do with mechanical failures or bad weather the cause was the GPS signal not being received by the aircraft. To prevent GPS denial, an aircraft deliberately interferes with the navigation signals that it relies on as part of its navigation. 

The International Air Transport Association (IATA) has been providing maps of areas where GPS is unavailable or unreliable for a long time, and this is not a new phenomenon. Although GPS jamming and spoofing are becoming increasingly powerful weapons of economic and strategic influence around Europe, the Middle East, and Asia, there is growing concern as conflict spreads quickly across these regions.

In some conflict zones, it has been documented that adversarial nations have used false (spoofed) GPS signals to disrupt air transit, shipping, trade, or military logistics and disrupt the daily activities of the nation. There have also been recent talks about anti-satellite weapons, and these discussions have rekindled fears that deliberate actions may be planned to disrupt GPS systems to wreak havoc on the economy. So many aspects of people's lives cannot function without GPS, and they do not even think about it when they do not have it. 

In case of a GPS outage, many online services will not function properly (these rely on GPS-based network synchronization) as well as the in-vehicle Satnav not working. On the other hand, users' mobile phones will not be able to access location-based services. According to studies conducted in the United States and the United Kingdom over the past few years, An analysis by two different academic institutions recently identified that the cost of a temporary outage in economic terms was about $1 billion per day. 

However, the strategic impacts could be even greater, especially during times of war.  As the saying goes, infantry win battles, but logistics win wars, and this is a testament to this assertion. The concept that it would be almost impossible to operate military logistics supply chains without GPS, given the heavy dependence on synchronized communication networks, general command and control, and locating and tracking vehicles and materials, is almost impossible to imagine. 

The entire system relies on GPS-based information and is susceptible to disruptions in any of them at any time. Most of the large military and commercial ships as well as aircraft carry GPS backup systems for steering since it was not long ago that navigation was performed without GPS. At high latitudes and underwater, GPS signals are not always available in all settings-for example, underground and underwater. 

It has been found that GPS alternatives depend on signals that can be measured locally (for example, motion or magnetic fields, such as the magnetic field in a compass), meaning that a vessel can navigate even in the absence of GPS or if GPS cannot be trusted at all. Inertial navigation, for example, uses special accelerometers that measure the movement of the vehicle, in a similar way to how one of those in a user's mobile phone can reorient itself when rotated in a certain direction. 

Then, based on the data users notice that the vehicle is moving, and using Newton's laws, users can calculate their likely position after a considerable period. In another technique called "alt-PNT," measurements are made of magnetic and gravitational fields to determine whether the Earth's surface is different from the known variation of these fields. Certainly! Here is the expanded and formalized version of the provided paragraphs. Reliable GPS is approaching its technological limits, and emerging quantum technologies present a promising path forward. 

Ultrastable locally deployed clocks are a key component of these advancements, ensuring that communications networks remain synchronized even during GPS outages. Traditionally, communications networks relied on GPS timing signals for synchronization. However, quantum technology offers a robust alternative. At the core of this technological shift is the fundamental behaviour of atoms. 

Satellite navigation systems depend on signals reflected from space, whereas quantum navigation leverages the precise movement of a single atom tracked under cryogenic conditions. According to New Atlas, a leading science publication, quantum navigation systems operate independently within each vehicle, with measurements taken at the point of use. This method ensures that the signal remains stable and resistant to interception, as noted by Richard Claridge, a physicist at PA Consulting Group. In May, the United Kingdom conducted two distinct quantum navigation tests one aboard a Royal Navy ship and another on a small jet plane. 

Subsequently, in June, London's underground transport system served as a testing ground for this cutting-edge technology. These tests demonstrated that quantum navigation systems are resistant to jamming, underscoring the UK's pioneering role in the future deployment of this technology on a broader scale. Quantum sensors exploit the immutable laws of nature to detect previously inaccessible signals, providing unprecedented sensitivity and stability. 

Consequently, quantum-assured navigation systems offer a reliable defence against GPS outages and enable innovative new missions. The most advanced quantum navigation systems integrate multiple sensors, each detecting unique environmental signals pertinent to navigation. This approach mirrors the technology used in autonomous vehicles, which combines lidar, cameras, ultrasonic detectors, and other sensors to achieve optimal performance. The evolution of navigation begins with an improved generation of quantum inertial navigation. 

However, the capabilities of quantum sensing extend beyond traditional methods by accessing new signals that were previously challenging to detect in real-world environments. As a result, quantum navigation technology represents a significant advancement, ensuring enhanced reliability and opening new possibilities for future applications.
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OnStar Smart Driver
Automobile Car Data Cyber Security Data Brokers data misuse Data Privacy Data Safety Data Stolen EFF GPS OnStar Smart Driver

The Hidden Cost of Connected Cars: Your Driving Data and Insurance

 

Driving to a weekend getaway or a doctor's appointment leaves more than just a memory; it leaves a data trail. Modern cars equipped with internet capabilities, GPS tracking, or services like OnStar, capture your driving history. This data is not just stored—it can be sold to your insurance company. A recent report highlighted how ordinary driving activities generate a data footprint that can be sold to insurers. These data collections often occur through "safe driving" programs installed in your vehicle or connected car apps. Real-time tracking usually begins when you download an app or agree to terms on your car's dashboard screen. 

Car technology has evolved significantly since General Motors introduced OnStar in 1996. From mobile data enhancing navigation to telematics in the 2010s, today’s cars are more connected than ever. This connectivity offers benefits like emergency alerts, maintenance notifications, and software updates. By 2030, it's predicted that over 95% of new cars will have some form of internet connectivity. Manufacturers like General Motors, Kia, Subaru, and Mitsubishi offer services that collect and share your driving data with insurance companies. Insurers purchase this data to analyze your driving habits, influencing your "risk score" and potentially increasing your premiums. 

One example is the OnStar Smart Driver program, which collects data and sends it to manufacturers who then sell it to data brokers. These brokers resell the data to various buyers, including insurance companies. Following a critical report, General Motors announced it would stop sharing data with these brokers. Consumers often unknowingly consent to this data collection. Salespeople at dealerships may enroll customers without clear consent, motivated by bonuses. The lengthy and complex “terms and conditions” disclosures further obscure the process, making it hard for consumers to understand what they're agreeing to. Even diligent readers struggle to grasp the full extent of data collection. 

This situation leaves consumers under constant surveillance, with their driving data monetized without their explicit consent. This extends beyond driving, impacting various aspects of daily life. To address these privacy concerns, the Electronic Frontier Foundation (EFF) advocates for comprehensive data privacy legislation with strong data minimization rules and clear, opt-in consent requirements. Such legislation would ensure that only necessary data is collected to provide requested services. For example, while location data might be needed for emergency assistance, additional data should not be collected or sold. 

Consumers need to be aware of how their data is processed and have control over it. Opt-in consent rules are crucial, requiring companies to obtain informed and voluntary permission before processing any data. This consent must be clear and not hidden in lengthy, jargon-filled terms. Currently, consumers often do not control or even know who accesses their data. This lack of transparency and control highlights the need for stronger privacy protections. By enforcing opt-in consent and data minimization, we can better safeguard personal data and maintain privacy.
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Test Flights
GPS GPS Spoofing Quantum Navigation Technology Test Flights

Quantum Navigation Systems: Safeguarding Against GPS Spoofing

Quantum Navigation Systems: Safeguarding Against GPS Spoofing

Britain has achieved a world-first with a series of test flights that show the key technologies of a future quantum navigation system meant to counter one of the most potentially dangerous, yet little discussed, dangers to transportation: GPS jamming and spoofing.

The Threat of GPS Spoofing

GPS has become such an integral part of our lives, with several applications, that it's easy to take them for granted- that is until you drive into a steep mountain valley or densely wooded forest and lose your satellite signal. That can be quite unsettling as the fuel indicator hangs around empty and you have no idea where the next gas station is.

Quantum Navigation

It's worse for ships and aircraft, as they confront not just the danger of an unintentional signal failure, but also active jamming and spoofing. Jamming GPS is the same as jamming radio or radar. It's merely sending a strong transmission that may overpower and drown out the GPS signal. Spoofing, on the other hand, poses a much greater risk. This entails sending out misleading signals to trick a GPS device into thinking it is somewhere else and moving in the wrong direction.

Quantum Navigation in Action

This seems like something from a Bond film, but it's a very real and prevalent threat. As per the European Business Aircraft Association, 49,605 civilian aircraft were the victims of spoofing in 2022 alone, most of which occurred near conflict zones where spoofing is used to misdirect enemy warplanes and drones, though such incidents can occur anywhere.

Once fooled, the crew members become occupied. They lose awareness of the situation. They now have a significantly increased workload as they deal with the situation. It is important to realize that spoofing isn't just about confounding an aircraft crew; air traffic controllers who rely on the aircraft's transponder (which is now incorrect) may also be affected and may be of little service when contacted for location confirmation.

Challenges and Progress

One approach to combat this is to use backup navigation, such as an inertial guiding system. This is effectively an electronic version of dead reckoning, and submarines all over the world employ gyrocompasses and accelerometers to automatically determine the boat's course and position to measure how it turns and accelerates along all three axes.

Applications Beyond Navigation

One approach to combat this is to use backup navigation, such as an inertial guiding system. This is effectively an electronic version of dead reckoning, and submarines all over the world employ gyrocompasses and accelerometers to automatically determine the boat's course and position to measure how it turns and accelerates along all three axes.

If you have a good navigational fix, it's a precious tool, but it's restricted since inaccuracies will creep into the system over time, accumulating and reinforcing one another, perhaps causing the readings to be wrong by miles. This is why submarines must periodically come near to the surface to obtain a new GPS position.

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Unjammable Navigation System
Airborne Trial Cyberattacks CyberCrime CyberThreat GPS Smartphones Technology Unjammable Navigation System

Unjammable Navigation System Successfully Tested in Airborne Trial

 


The government, which helped fund the research, said it was the first test of its kind that was publicly acknowledged by the government, which may pave the way for a GPS backup system that is unjammable in the future. A new type of navigation system has been developed in response to the GPS, which is based on satellites. However, the new system uses quantum technology, which refers to technology that uses the properties of matter on a very small scale to achieve its purpose. 

As the minister for science and technology Andrew Griffith said, the test flights provided "further proof of the UK as a world leader in quantum computing". GPS has become a critical part of the military, aircraft, ships, and road vehicles, as well as smartphones, which use it to locate their locations. Despite this, satellite signals are capable of being jammed, or spoofed, so that the location data given by the satellites is misleading. 

There has been a problem with the GPS signal on an RAF plane, which was carrying the UK Defence Secretary Grant Shapps when it was close to Russian territory in March. Earlier this year, the Finnish airline, Finnair, had to temporarily suspend daily flights to Tartu, the second-largest city in Estonia, after two of the aircraft suffered GPS interference. In recent years, the government has been accused of disrupting satellite navigation systems that affect thousands of civilian flights. Many military technologies, such as drones and missiles, use GPS technology. 

Nevertheless, GPS jamming can also be carried out at a small scale, by a few individuals who drive vehicles equipped with GPS trackers for their employers. A GPS satellite receives signals from space, but the satellite emits much less power than the headlights of a car, which can be easily jammed. It is based on a group of atoms that are kept at -273C temperature, almost as cold as it can get. Since these atoms are carried on the plane themselves, they cannot be interfered with by spoofing or jamming because they are carried on the aircraft themselves. 

It is intended that these atoms are used to measure the direction in which the plane is pointing and its acceleration. The combination of these factors can be used to accurately determine the location of the plane. Because quantum systems are regarded as very small particles, they are often referred to as quantum systems. It is extremely difficult to work on such a scale on the ground because of the size of atoms - about a million atoms wide - and the atoms are so small that they seem mind-bogglingly small. 

It was demonstrated in the flight that these atoms could be utilized in such a limited environment as an aircraft and that it would present a challenge in general. According to the government, this is the first flight in the UK using this type of technology, as well as the first flight in the world that has been publicly acknowledged by the government. According to the government, it is the first flight of such technology in the world. 

An aerospace company, BAE Systems and QinetiQ worked with quantum tech firm Inflexion to conduct the trials earlier this month. While quantum technology is rather small in terms of its scale, at present the equipment itself is quite large in terms of its size. For that reason, Henry White, one of the members of the BAE Systems team that worked on the project, believes the first application of the new technology could be aboard ships, "where there is a little bit more space", as he said. Nevertheless, he stated to the BBC that he was confident it would be as small as a shoebox by the time it is developed, and a thousand times more accurate than any comparable system within five to ten years. 

Shipping has been under threat of attack by satellite navigation systems, which have been regarded as a threat to shipping safety. It is primarily intended as a backup for GPS according to Mr. White, but he sees it as more than that. An excellent way to tell the time using GPS signals is to use the signals from GPS satellites as they provide extremely accurate timekeeping. A quantum clock was also taken on board the test flight to see if it could be used as a backup if GPS was blocked during the flight. 

There is no doubt that quantum clocks are extremely accurate, as Mr White pointed out in the lab. An extremely accurate means of telling the time with the help of GPS signals can also be used by using satellite signals. Additionally, as part of the test flight, a quantum clock was carried on board to see if it would prove useful as a backup in the event GPS became unavailable. The best quantum clocks, according to Mr White, can be extremely accurate and have been tested in the lab. Mr. White regards the recent test as a significant milestone in the development of unjammable navigation technology. 

However, he acknowledges that it will take a considerable amount of time before this technology can be actively deployed. Similarly, Ken Munro, representing Pen Test Partners, a cybersecurity firm specializing in aviation, described the test as a substantial step forward. Nevertheless, he cautioned that it would likely be 10 to 20 years before this technology sees practical implementation in commercial aviation within the United Kingdom.
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