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| A significant challenge is how to navigate autonomously by unmanned vehicles in environments with limited or no access to localization data. Autonomous navigation without GNSS is a complex and rapidly evolving technology area that has the potential to revolutionize many industries and applications. Key technologies and methods for navigation that lack GNSS information include inertial navigation systems (INS), vision-based localization, | A significant challenge is how to navigate autonomously by unmanned vehicles in environments with limited or no access to localization data. Autonomous navigation without GNSS is a complex and rapidly evolving technology area that has the potential to revolutionize many industries and applications. Key technologies and methods for navigation that lack GNSS information include inertial navigation systems (INS), vision-based localization, | ||
| - | In recent decades, much research and technology has been developed for various autonomous systems, including airborne, ground-based, | + | In recent decades, much research and technology has been developed for various autonomous systems, including airborne, ground-based, |
| - | <figure Ref.Unmanned vehicles domain classification> | + | <figure Ref.Unmanned_vehicles_domain_classification> |
| - | {{ : | + | {{ : |
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| Domain-specific challenges in the autonomy of vehicles include several technical, safety, regulatory, and ethical issues unique to different operational environments. Key challenges are: | Domain-specific challenges in the autonomy of vehicles include several technical, safety, regulatory, and ethical issues unique to different operational environments. Key challenges are: | ||
| - | * **Sensor Limitations and Perception** | + | * ** Sensor Limitations and Perception ** |
| * Accurate object detection in diverse weather conditions (rain, fog, snow). | * Accurate object detection in diverse weather conditions (rain, fog, snow). | ||
| * Distinguishing between road users like pedestrians, | * Distinguishing between road users like pedestrians, | ||
| * Handling sensor occlusions and blind spots. | * Handling sensor occlusions and blind spots. | ||
| + | * ** Complex and Dynamic Environments** | ||
| + | * Navigating complex urban settings with unpredictable human behavior. | ||
| + | * Managing construction zones, roadworks, and unexpected obstacles. | ||
| + | * Adapting to high traffic density and erratic driver behaviors. | ||
| + | * ** Localization and Mapping ** | ||
| + | * Achieving precise real-time localization in GPS-denied environments (tunnels, urban canyons). | ||
| + | * Maintaining up-to-date high-definition maps amid road changes. | ||
| + | * ** Decision-Making and Planning ** | ||
| + | * Ensuring safe, compliant, and contextually appropriate decisions. | ||
| + | * Handling edge cases like jaywalking pedestrians or unusual vehicle maneuvers. | ||
| + | * ** Communication and Cybersecurity ** | ||
| + | * Secure vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communications. | ||
| + | * Protecting against hacking or malicious cyber-attacks. | ||
| + | * ** Regulatory and Legal Challenges ** | ||
| + | * Navigating diverse legal frameworks across regions. | ||
| + | * Defining liability in accidents involving autonomous vehicles. | ||
| + | * Achieving standardization and interoperability. | ||
| + | * ** Ethical Considerations ** | ||
| + | * Decision-making in unavoidable accident scenarios. | ||
| + | * Privacy concerns related to data collection and sharing. | ||
| + | * ** Infrastructure and Standardization ** | ||
| + | * Lack of uniform infrastructure to support vehicle-to-infrastructure communication. | ||
| + | * Variability in road signage, markings, and infrastructure standards. | ||
| + | * ** Testing, Validation, and Certification ** | ||
| + | * Developing comprehensive testing protocols for safety assurance. | ||
| + | * Validating autonomous systems in all possible scenarios. | ||
| + | * ** Human Factors and User Acceptance ** | ||
| + | * Ensuring passenger trust and understanding of autonomous system limits. | ||
| + | * Managing transition of control between human and automation. | ||
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| + | Solving these domain-specific challenges is crucial for the safe and reliable deployment of autonomous vehicles in the various operational scenarios of our lives. In the following subchapters, | ||
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| + | <WRAP excludefrompdf> | ||
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| + | ===== Social acceptance ===== | ||
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| + | Building public trust in autonomous vehicles will be a huge challenge. In 2025, an online preference survey collected 235 responses from across Europe ((Nisyrios, E., Matthaiou, A., Chau, M.LY. et al. Investigating the preferences for autonomous vehicle use in European road transport: a binary logit model. npj. Sustain. Mobil. Transp. 2, 36 (2025). https:// | ||
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| + | Another considered advantage of introducing autonomous vehicles in public transport would be the reduction of fatal accidents. According to statistics, driver error contributes to 75–90% of all road accidents. Eliminating driver error could significantly reduce fatalities among drivers and passengers. However, critics of this approach point out that automation can only correct some human errors, not eliminate them entirely. However, forecasts regarding increasing access to this technology are optimistic. According to the EU Transport Commissioner, | ||
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| + | <figure Ref.Blees_autonomous_bus> | ||
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| + | ==== Software-defined vehicle ==== | ||
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| + | Software-based vehicle (SV) is a term used to describe, among other things, cars whose parameters and functions are controlled by software. This is the result of the car's ongoing evolution from a purely mechanical product to a software-based electronic device (see Figure {{ref> | ||
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| + | <figure Ref.software-defined_vehicle> | ||
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| + | Today' | ||
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| + | As driver assistance systems become automated and vehicles acquire autonomous driving capabilities, | ||
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| + | ==== Agility in software development ==== | ||
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| + | There are two basic software development methods: the traditional waterfall model and a newer approach called agile, which is key to the automotive industry' | ||
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| + | In the waterfall approach, software development proceeds through distinct, sequential phases. These phases include requirements definition, implementation, | ||
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| + | The agile approach represents a cultural and procedural shift from the linear and sequential waterfall approach. Agile is iterative, collaborative, | ||
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| + | Both waterfall and agile approaches can utilize the V-model for software development, | ||
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| + | ==== Cybersecurity Challenges ==== | ||
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| + | Software-defined vehicles (SDVs) open up enormous opportunities, | ||
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| + | Cybersecurity is a relatively new concept in the automotive industry [1]. While automakers began introducing electronically controlled steering and braking systems into their vehicles, the likelihood of threats increased, connectivity opened the door to significantly greater risks. Direct vehicle connections to the internet are cited as a source of cyber threats, but indirect connections, | ||
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| + | Here are some key areas related to this topic: | ||
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| + | * **Secure updates:** To ensure consumers have access to the most efficient features, today' | ||
| + | * **Safe system boot:** Manufacturers must also ensure secure system boot. Once the vehicle is started, the system must verify the authenticity and integrity of the software. This means the system must ensure that the code was created by the manufacturer and not by an attacker. | ||
| + | * **Secure vehicle network:** As vehicles become increasingly complex and software-defined, | ||
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| + | <figure Ref.Security_layers> | ||
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| + | ==== Advanced connectivity ==== | ||
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| + | As autonomous driving becomes more common, implementing even higher levels of message encryption may become increasingly important. For example, a user could send a message to a vehicle requesting it be picked up from a specific address. This message would be cryptographically signed and delivered securely. New protocols can help with this, even involving multiple clouds if necessary. Furthermore, | ||
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| + | <figure Ref.Safety_tests> | ||
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| + | ==== Radar technologies ==== | ||
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| + | Recent advances in vehicle radar technology will soon lead to a fundamental increase in radar capabilities, | ||
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| + | There are two primary ways to improve ADAS system perception. We can either improve how the system interprets sensor data using machine learning, or improve the quality and accuracy of real-world sensor data. Combining these approaches creates a synergistic effect, creating a reliable model of the environment that vehicles can use to make intelligent driving decisions. While machine learning is constantly evolving, so is radar sensor technology. One specific technology is the use of 3D air-waveguide technology in radar antennas to capture more precise signals and increase range. In automotive radar systems, 3D air-waveguide antennas help efficiently scan the surrounding area with radar signals and receive weak echoes from the surrounding environment with low loss. By reducing losses in the transmitted and received signal, air-waveguide antennas enable the use of a more sensitive sensor while maintaining the same small physical radar footprint. | ||
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| + | ==== An alternative to self-parking ==== | ||
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| + | Radars with advanced 3D air-waveguide antenna technology could support a high-resolution perception mode, enabling self-parking. Early implementations of self-parking systems rely on ultrasonic sensors to measure the width of parking spaces. This often means the vehicle must drive past the space to determine if it is the right size before backing into it. With ambient perception software that utilizes improved radar, the vehicle would be able to determine the space' | ||
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| + | By utilizing advanced antenna technology, high-speed data transmission support, and enhanced software, Aptiv’s seventh-generation radar family provides an excellent foundation for building the next generation of automated driving vehicles. | ||
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| + | <figure Ref.ADAS_Gen_6_platform_from_Aptiv> | ||
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| + | At the same time, in the case of high-speed NOA radars, the detection range of the traditional radar is only 210 meters when traveling at high speed, while the detection range of the precise 4D radar reaches 280 meters (the parameters of some manufacturers even exceed 300 meters), which allows for earlier identification of targets, thereby solving the problem of the rigid requirement for forward perception. | ||
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| + | Currently, brands such as Ideal, Changan, and Weilai are leading the widespread adoption of 4D radars. Among them, all Weilai NT3 platform models will be equipped with 4D radars as standard, with a maximum detection range of up to 370 meters. Furthermore, | ||
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| + | Moreover, according to Huawei, the distributed architecture further improves performance. Its detection capabilities surpass those of existing 4D millimeter-wave radars, its high-confidence detection range in rainy and foggy conditions has been increased by 60%, and the detection latency of frontal and side targets has been reduced by 40%. | ||
