AUTONEWS

Self‑driving cars struggle to see at night or in fog—but imitating the human brain can make them safe

Picture this: you're driving on a mountain road, when you suddenly hit a thick patch of fog. You respond instinctively. Your vision sharpens, and you narrow your eyes to make out the shape of any oncoming cars.

Human beings handle these quick changes very well, but if it were a self-driving car—at least one with a current artificial intelligence (AI) system behind the wheel—things could easily end in disaster.

Today's AI vision systems are extremely accurate when visibility is good. On a clear, sunny day a self-driving car can recognize pedestrians, road signs and other vehicles with precision. However, they are extremely vulnerable to environmental changes. If it rains, or gets dark or foggy, standard AI systems become blind, incapable of detecting obstacles that a human driver would spot with ease.

Our research at the University of Valencia proposes a possible solution: instead of exposing AI models to millions of images of every possible road condition, we decided to imitate biology. But biologically speaking, why can humans see so well under such a wide range of conditions?

The brain's 'volume control'...In our brains, neurons do not work alone. They use a truly fascinating form of adaptation that neuroscientists call divisive normalization.

To understand this (without getting into mathematics), we can picture it as an automated "volume control" system, with neurons working in a team. Let's say one neuron is looking at a very dark area of the field of vision, such as a black car at night. The neighboring neurons turn up the "volume" of this weak signal, amplifying the small details to make them more visible.

If we look at a bright light, the same thing happens in reverse. The brain turns down the volume to prevent us from being dazzled.

This mechanism is what allows us to adapt and see clearly in a very wide range of conditions. But in the search for speed and accuracy, modern AI systems have neglected this biological inspiration.

AI in the driving simulator...In our study, we processed images using some of the most widely used AI models, adding layers to simulate the brain's "volume control" mechanism. In basic terms, we forced their neurons to communicate with one another and adapt to their environment, just as our own brains do.

We wanted to see if imitating biology would make cars safer. To do this, we submitted both standard AI models and our brain-inspired modification to a series of tests. Using databases from real driving in European cities, night driving images from Switzerland, and several different virtual driving simulators, we were able to compare responses to difference levels of fog, darkness and light variation.

The results showed that imitating our own brains worked. After being trained, the two types of AI models could drive perfectly well, but once fog and darkness came into the equation, the unmodified one began to fail. It lost the ability to distinguish cars from buildings, and even from the road itself.

The AI system that was equipped with our brain-inspired mechanism, on the other hand, was robust. Even in fog or complete darkness, it performed more than 20% better than its unaltered counterpart.

We analyzed, from the inside, how this new system perceived the world and found that it was doing exactly what we expected. It was capturing and enhancing the details of vehicles hidden in the fog that would otherwise be invisible. As a result, its performance became more stable in the face of changing weather conditions.

Learning from nature...Getting society as a whole to trust AI poses major challenges, and the safety of passengers and pedestrians in self-driving cars is a major aspect of this. It is not enough for smart systems to work under ideal conditions. We need them to be completely safe in the real world, and to safeguard the lives of all road users in all weather conditions.

Our research shows that the key to making artificial intelligence safer, more robust and more adaptable may be closer than it seems. There is no need for more powerful computers or vastly greater amounts of data. Sometimes, all we need is to look at the millions of years of evolution that have shaped our own brains.

In many cases, nature has already solved some of the problems that artificial intelligence faces today. We just need to learn from it.

Why do some sensors in autonomous cars fail in certain conditions, like fog or low light, and what's being done to improve them?

To an autonomous car's laser sensors, heavy fog acts like millions of tiny prisms, creating terrifying "ghost" obstacles that can effectively blind the vehicle.

The core issue lies in the physics of how different sensors gather data. Here is why the three primary autonomous vehicle sensors struggle in certain conditions:

Cameras function much like the human eye, relying entirely on the visible light spectrum. In low light, there simply are not enough photons to create a clear image. In fog or heavy snow, suspended water droplets physically block the lens and scatter the incoming light, causing a whiteout effect that drastically reduces visibility.

LiDAR (Light Detection and Ranging) creates a high-resolution 3D map of the world by bouncing rapid pulses of near-infrared laser light off objects. However, dense fog, heavy rain, or falling snowflakes act like millions of tiny prisms. The laser beams hit these water particles and scatter before reaching their target. This creates false positive "ghost" obstacles in the vehicle's software and severely limits the sensor's functional range.

Radar relies on radio waves, which easily pass through fog, rain, and pitch darkness without scattering. While highly reliable in bad weather, traditional automotive radar has notoriously low resolution. It can detect that a solid object is ahead, but it struggles to classify what it is—making it difficult to distinguish a stopped fire truck from a harmless overhead street sign.

To overcome these physical limitations, engineers are developing a combination of advanced hardware and sophisticated software:

Sensor Fusion: Modern autonomous systems cross-reference data from all three sensor types simultaneously. If the camera and LiDAR are blinded by fog, but the radar detects a dense, stationary mass ahead, the vehicle's computer knows to prioritize the radar data and initiate braking.

4D Imaging Radar: This next-generation radar uses multiple antennas to provide a high-resolution point cloud. It can measure the height, width, depth, and relative speed of objects with enough clarity to distinguish a pedestrian from a parked car, all while remaining immune to weather and lighting conditions.

Thermal Imaging (FIR): Far-infrared cameras are increasingly being integrated into sensor suites. Instead of relying on visible light, they detect heat signatures. This allows the vehicle to clearly highlight a warm pedestrian or an animal crossing the road in absolute darkness or thick fog.

Algorithmic De-noising: Machine learning models are being trained specifically on bad-weather data. These algorithms learn the specific geometric patterns of LiDAR scattering caused by rain and snow, allowing the software to digitally filter out the precipitation and reveal the true obstacles hidden behind it.

Provided by The Conversation

 

JEEP

Refreshed Jeep Avenger 2026: Compact freedom in evolution

From the very beginning, the Jeep Avenger has been the symbol of the compact SUV that combines style, functionality and capability. Now, in 2026, a new version arrives – refreshed, more technologically advanced and available in more powertrains than ever. In addition, the brand celebrates its 85th anniversary with a special edition that brings unique details and exclusive design.

This Avenger remains true to the philosophy of “design to function”.

* The heptagonal grille is now illuminated by LED backlighting, inspired by the Compass model.

* 360° protection is improved with new bumpers, while the 4xe version gets red vertical details and the Jeep Shield.

* New 17” and 18” aluminum wheels are available, as well as two fresh colors – Forest and Bamboo.

The interior has been significantly improved: softer door materials, a padded lower part of the dashboard and new seats in the Altitude and Summit versions. Of particular note is the Selec-Terrain control, now clearly marked and rubberized for ease of use.

Technology: safety and comfort...The Avenger is equipped with LED matrix lights that automatically adjust the beam of light and reduce driver fatigue. In addition, a 360° camera makes parking easier and protects the vehicle from minor damage.

Standard equipment includes:

* Full-LED lights,

* automatic high beams,

* keyless start,

* automatic climate control.

The infotainment system with a 10.25-inch screen offers wireless Android Auto and Apple CarPlay, while the Jeep Mobile application allows vehicle control via smartphone.

Special Edition: 85 Years of Jeep...For the anniversary, Jeep has prepared the 85th Anniversary Edition.

Outside: gold details on the bumpers and wheels, a tartan sticker on the hood and the "85 Years of Adventure" logo.

Inside: tartan upholstery with gold stitching and ambient lighting.

Equipment: LED matrix headlights, 360° camera and exclusive design elements.

This edition is intended for fans of the brand, but also for drivers who want to stand out from the crowd.

More than 270,000 orders have been received to date, of which 60% are for the electrified version. The Avenger is the best-selling SUV in Italy and one of the leaders in the European B-SUV segment. It is particularly interesting that it attracts 35% more women and 35% more drivers under 40 compared to the brand's average.

The new Jeep Avenger is not just a refresh of the existing model - it is an evolution that combines tradition and innovation. With a carefully selected range of powertrains, advanced technology and a special edition for the brand's 85th anniversary, the Avenger confirms its status as one of the most important models in the European SUV market.

Autonews

HYUNDAI

Hyundai Mobis: Hyundai's new modular electric powertrain

Hyundai Mobis has developed a new generation of electric powertrain that can tackle one of the main obstacles to the expansion of electric vehicles: cost. By integrating various components into a more compact and standardized assembly, the technology promises to reduce production costs, simplify repairs, and pave the way for more affordable models in the future.

The new system delivers 160 kW, equivalent to 215 hp, and combines an electric motor, inverter, and reduction gear in a single housing. This is the second integrated assembly developed internally by Hyundai Mobis, following a 250 kW version. The company is also preparing a third 120 kW configuration, aimed at compact and more affordable vehicles.

The major difference lies in the standardization of components. Instead of designing each system in isolation, Hyundai Mobis has started using interchangeable elements between different powertrains. Stator, inverter, and power module can be shared between various vehicles, reducing costs, speeding up production, and simplifying the industrial process.

The company also incorporated structural improvements, including a new cooling system and more efficient power semiconductors. According to Hyundai Mobis, the result is a system with 16% higher specific power than comparable solutions, while the total volume has been reduced by almost 20%.

Hyundai Mobis, the parts and engineering division of Hyundai Motor Group, has unveiled an integrated 160 kW (218 hp) electric powertrain for the automotive industry in general, not just its own brands.

The PE system is the EV equivalent of an internal combustion powertrain, comprising motor, inverter and reduction gear. Hyundai Mobis previously built such systems to customer designs, but has now developed its own component-level intellectual property, allowing it to propose proprietary models to OEMs. Some overseas customers have shown early interest, the company said.

A core element of the engineering work is standardisation and modularisation of key parts, including the stator, inverter and power semiconductor module. Compared with bespoke per-vehicle development, the platform-style approach is positioned as more efficient as EV model counts grow. Hyundai Mobis said specific power has improved by about 16% and overall system volume has fallen by nearly 20%, with new cooling technology applied to the motor and a power module designed for higher energy efficiency.

The 160 kW unit, equivalent to 215 hp, is described as suitable for most EVs currently in mass production, with twin-axle deployments doubling output. The development extends Hyundai Mobis’ electrification portfolio from battery systems into drive systems.

The system combines an electric motor, inverter, and gearbox in a single structure that is approximately 20% more compact than similar systems, with a 16% higher specific power density. The platform was designed as the basis for the group's expansion to 22 to 36 electric models by 2030.

The 160 kW power output is sufficient for a mid-size electric sedan or crossover. But more important than the power itself is the engineering approach. Hyundai Mobis has standardized the starter motor, inverter, and power modules so that they can be used at different powertrain levels. It's a kind of interchangeable parts strategy for electric motors. The company claims that improved cooling and more efficient power semiconductors are responsible for the smaller size and higher power density.

The system also supports all-wheel-drive configurations with two motors, with one unit on each axle, which would effectively double the total power in high-performance models.

The 160 kW unit sits in the middle of a three-tier offering. A high-performance 250 kW (340 hp) version is planned for 2025, while a 120 kW (163 hp) variant for compact cars is planned for the first half of 2026. These are designed to cater to everything from small hatchbacks to large SUVs, utilizing common tooling and parts – a significant way to reduce the cost of producing electric vehicles.

Hyundai Mobis is also offering the platform to companies outside its own group. Mercedes-Benz and Stellantis are already confirmed customers for Mobis' battery systems, and the supplier is also seeking contracts with other automakers for its motor lineup. A battery factory is being built in Spain in partnership with the Volkswagen Group.

In practice, this means that future generations of Hyundai, Kia, and Genesis vehicles will be able to use more compact, efficient, and cheaper-to-produce drive systems. As many electric models adopt two motors, one on each axle, this architecture can also be applied to high-performance vehicles more easily.

Hyundai Mobis has developed a 160-kW Power Electric (PE) system intended for passenger electric vehicles (EVs), expanding its lineup of integrated electric drive systems.

The company previously developed a 250-kW PE system for higher-performance EV applications and plans to complete development of a 120-kW version for smaller EV platforms during the first half of this year.

The PE system combines the motor, inverter, and reduction gear into an integrated electric drive unit comparable to the powertrain in an internal combustion vehicle. Hyundai Mobis said it developed the system architecture and key component technologies internally, including the drive motor stator, inverter, and power semiconductor modules.

The company focused on standardizing and modularizing core components so the systems can be adapted across multiple EV platforms rather than developing unique drive systems for each vehicle model. This approach is intended to support scalability and manufacturing efficiency as automakers expand EV lineups.

The 160-kW system produces approximately 215 horsepower and is intended for use in mainstream passenger EVs. Dual-motor configurations using front and rear PE systems could provide higher total output for all-wheel-drive or higher-performance applications.

According to Hyundai Mobis, the system improves specific power, or power output relative to weight, by approximately 16% while reducing overall volume by nearly 20% compared with previous designs. The company attributed the changes to modularized components, revised cooling architecture and updated power semiconductor modules intended to improve efficiency.

Hyundai Mobis previously completed development of a 250-kW PE system intended for higher-output EV applications. The company also plans to introduce a smaller 120-kW version focused on compact EVs and smaller mobility platforms.

With the 120, 160, and 250-kW systems, Hyundai Mobis is building a modular lineup of electric drive systems intended to support a range of passenger EV applications from compact vehicles to higher-performance platforms.

Another potential benefit is in maintenance. The modular design tends to simplify diagnostics and replacements, which can reduce repair time and costs over the vehicle's lifespan.

For the consumer, the most important consequence is direct. By reducing industrial costs and gaining scale, Hyundai creates conditions to offer, in the coming years, more affordable, efficient, and technologically advanced electric cars. In a market where price remains one of the biggest barriers to electrification, this type of advancement often has a much greater impact than the technical specifications suggest.

Hyundai Mobis is rapidly advancing EV powertrain technology, developing 120kW to 250kW Power Electric (PE) systems—integrating motors, inverters, and reduction gears—for global automakers. A key focus is their 160kW, 215-horsepower unit, designed for widespread electric vehicle applications, as well as innovative, high-efficiency "in-wheel" motors for independent, all-wheel control.

Key innovations & technologies(below):

PE systems (E-Powertrain): Hyundai Mobis has developed a 160 kW system suitable for most mass-produced EVs, featuring a 16% improvement in specific power and a 20% reduction in volume compared to previous models.

In-wheel system: This technology places the electric motor directly inside the wheel, enhancing energy efficiency and allowing for independent control of all four wheels.

e-Corner module: Combined with in-wheel motors, this module enables advanced steering capabilities, including 90-degree turning (crabbing) for parallel parking and "zero spins".

Hydrogen fuel cell components: The company is a leader in mass-producing key components for hydrogen-powered vehicles

Details of the 160 kW modular electric propulsion unit developed by Hyundai Mobis.

Integrated Design: The system combines electric motor, inverter, and reduction gear in a single compact housing.

Performance: This unit produces approximately 215 horsepower.

Modularity: The design allows for interchangeable components such as stators and inverters between different powertrains to reduce costs.

Efficiency: Compared to previous designs, this unit is approximately 20% smaller and offers 16% higher power density.

Autonews

AUTONEWS

Smart AI gives electric vehicle batteries 23% longer life—without increasing the charging time

Fast charging shortens the life of vehicle batteries, but is necessary on longer journeys with electric vehicles. Researchers at Chalmers University of Technology, Sweden, have now developed a new AI method that adapts fast charging to the health of the battery. Their study shows that battery life can be increased by almost 23% without extending the charging time. All that is required is an update of the vehicle's software.

When individuals or companies consider acquiring electric vehicles, the possibility of fast charging is an important factor.

"For taxis or heavy vehicles in industry, for example, access to fast charging means a lot, but this is also true for passenger cars. Although private motorists usually charge their electric cars at home, the availability of fast charging outside the home is a crucial factor, as it facilitates commuting and driving over longer distances," says Changfu Zou, professor at the Department of Electrical Engineering at Chalmers.

Electric vehicle batteries currently have a life of approximately eight to 15 years, depending on use and charging. Several studies of the European EV market show that consumers who are considering buying an EV are concerned about the limited life of batteries.

The requirement for efficient fast charging is also in conflict with battery health. As such, charging is stressful for the batteries and shortens their life.

Changfu Zou has taken on this challenge with Meng Yuan, Assistant Professor at Victoria University of Wellington, New Zealand, and a former researcher at Chalmers. In the study, they show that it is possible to increase the life of batteries without significantly increasing the charging speed—with the help of artificial intelligence.

Adapting charging to battery health...In the study, the researchers present an AI-based charging strategy that adapts the current during each fast charge to the battery's chemistry and "state of health." The adapted charging extends battery life by around 23% compared to the standard method today. At the same time, the charging time is unaffected, give or take a few seconds.

"We show that it is possible to charge more or less as fast as today, but with significantly less long-term degradation of the battery," says Meng Yuan.

When a battery is charged fast, a large current is forced into the various cells, which causes a greater risk of chemical side reactions, among other things. One of the most problematic is known as lithium plating, in which metallic lithium precipitates on the electrode instead of being stored correctly in the battery's structure.

This can reduce capacity and may also affect safety, as unevenness in the structure of the lithium can, in a worst-case scenario, cause a short circuit.

"The risk of lithium plating increases with the age of the battery. However, the standard methods of charging today use the same current and voltage regardless of whether the battery is new or has been used for years," says Meng Yuan.

                       Meng Yuan and Changfu Zou. Credit: Chalmers University of Technology

Short charging time and less wear and tear...The new, AI-based charging strategy is based on reinforcement learning, in which the right actions are rewarded and thus reinforced. The training environment consisted of a model of one of the most common electric vehicle batteries on the market and a simulation of the parameters that have an impact on both charging time and battery health.

The AI model was trained to adapt the charging according to how charged or discharged the battery was at the time of charging. It also needed to take into account the overall health of the battery, as this is crucial to both capacity and electrochemistry. The result was a charging strategy that both keeps the charging time short and minimizes harmful reactions.

"Our study shows that smart adaptation of the current during charging, taking into account the changing electrochemical state of the battery, can maximize both the performance and the life of the battery," says Changfu Zou.

Easy to implement—but adaptation required...The new charging strategy is both easy and cost-effective to implement, according to the researchers: in principle, it could be implemented through software updates in the vehicle's battery management systems. However, some adaptation is needed for the method to be used generally.

"There are not so many different battery types today, but the method needs to be calibrated for it to be used by everyone. Using transfer learning, we can take advantage of what our AI model has already learned, and thus adapt the AI model to new batteries more quickly," says Changfu Zou.

The next step is to test the method directly on physical batteries. The researchers hope that the AI-based charging strategy will make a significant contribution to the electrification of the transport sector.

"To reduce emissions and transition to a fossil-free society, it is important for people to be prepared to switch to electric vehicles. The possibility of fast charging, combined with an increased battery life, are important driving forces," says Meng Yuan.

"And for the automotive industry, an almost 23% increase in battery life can mean lower warranty costs, better resale value and more efficient use of critical raw materials," says Changfu Zou.

A new artificial intelligence method developed by researchers at Chalmers University of Technology extends electric vehicle (EV) battery lifespans by up to 23 percent without increasing fast-charging times.

The core technology(below):

Reinforcement learning: The algorithm dynamically learns and improves by interacting with a simulated battery environment.

Health-aware charging: The system constantly reads the battery's real-time electrochemical condition and age.

Dynamic current adaptation: Instead of using fixed voltage, it continuously adjusts the power flow during a charging session.

Solved technical hurdles...Traditional chargers apply identical current profiles to both factory-new and heavily aged battery packs. This creates immense stress on older cells, resulting in a hazardous degradation process called lithium plating.

By mitigating this risk, the AI preserves the total energy capacity of the cells over multiple years of operational use. Industry findings published in ScienceDirect emphasize that blending such AI intelligence into existing battery management structures is crucial for mitigating overall cell deterioration.

Industry impact(below):

Software-only deployment: Carmakers can implement this feature directly via over-the-air (OTA) vehicle software updates.

Lower consumer costs: Extended cell health yields significantly better vehicle resale values and reduced warranty expenses.Environmental Sustainability: Enhancing longevity optimizes the raw critical minerals used during original manufacturing.

Provided by Chalmers University of Technology 

RENAULT

Renault 4 JP4x4 Concept

The Renault 4 JP4x4 Concept takes you further. It is more adventurous thanks to its dual 100% electric drive and all-wheel drive, more open thanks to its half-doors and pick-up-inspired appearance, and more daring thanks to its adventurous design.

The Renault 4 JP4x4 Concept has one 100% electric motor on each axle, for better traction and greater versatility on a wide range of terrains.

With 15 mm more ground clearance, shiny fender flares, exclusive 18" JP4 wheels, Goodyear UltraGrip Performance+ 225/55 tyres and an emerald green body, the Renault 4 JP4x4 Concept emphasises its lively and adventurous character.

To maximise its load capacity, the Renault 4 JP4x4 Concept is dedicated to detail: a roof that can also be used as a roof rack, a boot designed to neatly store leisure equipment and a rear door that opens in a pickup style, making loading easier.

A grab handle designed for all types of terrain, a striking detail in a saturated orange colour and a unique "floating" centre console: the interior of the Renault 4 JP4x4 Concept is a bold, refreshing design that invites you to get away from it all.

Adventure in style: the Renault 4 JP4x4 Concept features two special "bucket" seats, inspired by the original JP4 model, for optimal support in all driving conditions. Double upholstery material in terracotta mesh fabric and orange bouclé for timeless elegance.

Silvia dos Santos reflects on the spirit of the Renault 4 JP4x4 Concept. With this new concept vehicle, Renault reinterprets the Renault 4 Plein Air and JP4 into a playful vehicle, a promise of adventure and freedom.

It draws inspiration from the past to reinvent the spirit of the little beach adventurer.

Autonews

TUNNING

Novitec Ferrari Purosangue Esteso

This fully equipped Novitec Purosangue Esteso features a complete widebody conversion, a custom-tuned interior, new wheels and a full Novitec exhaust system — transforming Ferrari’s four-door V12 into something even more emotional, dramatic and distinctive.

The sporty-styled Novitec Esteso version adds six centimeters to the width of the first SUV in the Italian sports car manufacturer’s range, and also stands out with its aerodynamic efficiency, which further optimizes handling stability at high speeds.

The custom-made 22- and 23-inch wheels, developed in collaboration with the American manufacturer Vossen, widen the track and thus make handling even more agile and safe.

Novitec high-performance exhaust systems are available in various versions and extract up to 30 additional horsepower from the 12-cylinder naturally aspirated engine.

The exclusive Novitec interiors can be produced in virtually any color and come in many different designs.

NOVITEC, the world’s leading automotive refinement specialist for the super-powerful cars from Maranello, now makes the Ferrari Purosangue even more exclusive and thrilling. The sportily styled NOVITEC ESTESO widebody version adds six centimeters to the width of the first SUV in the range of the Italian sports car manufacturer and also shines on account of its aerodynamic efficiency, which further optimizes the handling stability at high speeds. 

The precise-fit bodywork components can be ordered made from sportyexposed-structure carbon or from PUR-Rim plastic, which can be painted in vehicle or contrasting color. The tailor-made NOVITEC wheels with diameters of 22 and 23 inches, developed in cooperation with the American manufacturer Vossen, widen the track and thus make the handling even more agile and safer. The NOVITEC high-performance exhaust systems are available in different versions and coax up to 30 more horsepower from the naturally aspirated 12cylinder engine. 

Exclusive NOVITEC interiors can be crafted in practically any color and come in many different designs. The NOVITEC designers caused a sensation with their fascinating N-LARGO widebody versions for the extremely powerful cars from Ferrari, Lamborghini and McLaren. The ESTESO widebody for the current Ferrari Purosangue seamlessly joins these ranks, as it gives the SUV a particularly spectacular appearance. All ESTESO widebody elements are designed to be installed based on the plug-and-play principle. Customers who don’t want to have their vehicle widened can have the Purosangue visually enhanced without the ESTESO flares. The components of this bodywork refit come in two different versions. The exposed-structure carbon elements with high-gloss sealed surface finish lend the five-door car full-blooded racing looks. 

Alternatively, the same components are also available made from PUR-Rim plastic if a customer prefers a paint finish in vehicle or contrasting color. Regardless of whichversion a customer chooses, all NOVITEC ESTESO components meet the highest standards in terms of surface quality and precise fit. A width of 2.09 meters: The Purosangue reaches this impressive dimension, and is thus six centimeters wider than the production car, as the result of the installation of the sweeping ESTESO fenders flares at the front and rear axles. The NOVITEC rocker panels give thePurosangue a lower and sleeker visual stance, and create a harmonious transition between the wider wheel wells. 

The front end with the NOVITEC ESTESO spoilers at the left and right and in the center looks even more aggressive. In addition, they increase front-axle downforce at high speeds. The exposed-structure carbon front fascia trim panel, which frames the radiator grille, lends the dynamic looks an even sportier character. To make the front view even more spectacular, the hood of the Purosangue can be upgraded with exposed-structure carbon NOVITEC components. A completely newly designed hood made from this composite material is also available as an alternative. The engine bay can be visually enhanced with an exposed-structure carbon air filter box. Carbon surrounds for the side mirrors and the air outlets in the front fenders can add further upgrading touches.

The exposed-structure carbon diffuser in concert with a rear spoiler and roof-mounted wing made from the same material rounds out the sporty NOVITEC look. Every widebody version also requires a tailor-made tire/wheel combination. Vossen produces three different rim designs exclusively for the German automotive refinement specialist and its NOVITEC ESTESO based on the Ferrari Purosangue. The company uses state-of-the-art forging and machining technologies in their production. The wheels are available in 72 different colors and also offer a choice of brushed or polished surface finishes. 

All three styling variants make optimal use of the newly created space under the rear fender flares. They are mounted in 12Jx23 king-sized format and carry tires of size 315/30 ZR 23. In order to emphasize the wedge shape of the high-performance SUV, the front axle is fitted with rims of size 9.5Jx22 with 255/35 ZR 22 tires. A lower center of gravity optimizes the handling and consequently NOVITEC lowers the ride height of the all-wheel-drive Ferrari by about 25 millimeters with custom sport springs. Even an SUV with a 6.5-liter 12-cylinder engine can never have enough power. In conjunction with special sports catalysts, the NOVITEC high-performance exhaust systemcoaxes 30 additional horsepower from this engine. 

The output of the Purosangue thus increases to 556 kW / 755 hp. The sports exhausts for this model offer a choice between systems with or without integrated sound management in the form of actively controlled butterfly valves in the exhaust. With regard to the material, there is choice between stainless steel and especially light INCONEL, which is also used in Formula 1 racing. The latter is also available in a particularly exclusive version with 999 fine-gold plating. In addition, NOVITEC offers various designs for the four tailpipe tips, which culminate in the particularly exclusive fine-gold plating.

Autonews

WRC

Rally de Portugal 2026 - Neuville wins, organisers fined

Thierry Neuville (Hyundai i20 N Rally1) won the 59th Vodafone Rally de Portugal 2026, the sixth event on the 2026 FIA World Rally Championship calendar.

The result marks redemption for the Neuville and Wydaeghe following their near-win in Croatia four weeks ago, where the crew lost a deserved victory on the final stage. It is Hyundai Motorsport’s 35th win in the FIA WRC.

 Rally de Portugal was a rally of two halves; Thursday and Friday featured dry conditions on the technical gravel stages, but the arrival of rain on Saturday and Sunday brought unpredictability to proceedings.

 Neuville and Wydaeghe were within touching distance of the provisional podium after Thursday’s three stages. Although they briefly sat in sixth on Friday morning, they quickly recovered to second by the end of the day. They stayed in touch on the muddy and slippery stages on Saturday and headed into Sunday 21.9 seconds off the lead. A measured approach on Sunday was rewarded when rally leader Sébastien Ogier collected a puncture on SS22, enabling the Belgians to take first place. Neuville and Wydaeghe ended their weekend with a flourish on the Power Stage, narrowly losing out on the fastest time to team-mate Adrien Fourmaux.

 Fourmaux and Alexandre Coria made a strong start to the event, taking the first stage win of the rally and finishing Thursday in second overall. They stormed into the lead of the rally on Friday, but a double puncture on SS8 Góis brought their victory charge to an end. The Frenchmen worked hard to maintain sixth place on Saturday, scoring two stage victories along the way. Super Sunday brought another stage win on an eventful SS22, which saw Fourmaux and Coria promoted to fourth as two Toyota crews hit trouble. A committed final run through the Power Stage confirmed their fifth stage win of the weekend, and third position in the Super Sunday standings.

Thierry Neuville managed to take advantage of the tyre puncture of the then leader Sébastien Ogier (Toyota GR Yaris Rally 1) on the penultimate stage to take the lead in Rally Portugal, managing to cross the finish ramp in first place. This is the first victory celebration for the Hyundai team this year.

The Toyota factory team recorded a double podium in Portugal. Second place was won by Oliver Solberg (Toyota GR Yaris Rally 1), which was Solberg's first podium after his victory in Monte Carlo, while Elfyn Evans (Toyota GR Yaris Rally 1) climbed to the bottom step of the podium in Portugal, taking over the championship lead.

The Hyundai team's potential in Portugal was first demonstrated by Adrien Fourmaux (Hyundai i20 N Rally1), who took the lead on Friday morning, but a mistake in the afternoon program cost him almost half a minute of lost time and that's where his dreams of winning in Portugal disappeared. In the end, he had to settle for fourth place, ahead of Takamoto Katsuta (Toyota GR Yaris Rally 1) and Sebastien Ogier (Toyota GR Yaris Rally 1).

The organizer of the Rally Portugal - Automóvel Club de Portugal (ACP), failed to prevent a serious safety lapse during the competition, which resulted in a fine of 15,000 euros. Namely, during the seventh special stage (Arganil 2 - 18.62 km), two unauthorized vehicles entered the track closed to traffic. First, a tow truck, which was supposed to pick up a damaged vehicle, was taken onto the special stage route due to a driver's error using GPS. The truck passed three military police checkpoints without incident, and when the truck driver saw Elfyn Evans approaching at high speed, he swerved off the track, after which he became ill. 

About half an hour later, the owner of a "towing service" entered the closed speedway in his Mercedes with the aim of helping his employee, which led to the cancellation of the special stage - a red flag was raised. The organiser released the towing service from all its contractual obligations on the spot, but the question remains as to how the unauthorised entry of the vehicle into the special stage was not immediately reported to the competition control. The incident is now the subject of an investigation by the FIA ​​safety committee.

Rally Portugal 2026 - Objective:

1. Neuville Thierry / Wydaeghe Martijn Hyundai i20 N Rally1 3:53:01.7

2. Solberg Oliver / Edmondson Elliott Toyota GR Yaris Rally1 +16.3

3. Evans Elfyn / Martin Scott Toyota GR Yaris Rally1 +29.1

4. Fourmaux Adrien / Coria Alexandre Hyundai i20 N Rally1 +54.8

5. Katsuta Takamoto / Johnston Aaron Toyota GR Yaris Rally1 +1:12.6

6. Ogier Sebastien / Landais Vincent Toyota GR Yaris Rally1 +1:26.6

7. Pajari Sami / Salminen Marko Toyota GR Yaris Rally1 +2:50.9

8. Sordo Dani / Carrera Cándido Hyundai i20 N Rally1 +4:10.0

9. Sesks Mārtiņš / Francis Renārs Ford Puma Rally1 +6:49.2

10. Suninen Teemu / Hussi Janni Toyota GR Yaris Rally2 +11:13.8

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