AUTONEWS

New lidar system maps location, speed and material properties in a single measurement

Researchers have developed a new kind of lidar system that simultaneously measures the location, speed and material properties of objects in a scene. This type of information could be useful for applications such as robotics, autonomous driving and remote sensing.

Lidar uses laser pulses to measure distances and create highly detailed 3D maps of objects and terrain. However, most commercial lidar systems, such as the ones used in autonomous cars, primarily measure distance.

Researchers from the University of Toronto and telecommunications firm Ciena Corporation have developed a prototype lidar system capable of simultaneously measuring distance, velocity, and surface material properties within a single scan. Published in Optica, the technology addresses a critical limitation in conventional lidar, which typically captures only spatial coordinates and, in some cases, speed. By integrating a commercially available coherent optical modem as both transmitter and receiver, the system leverages the frequency, phase, amplitude, and polarization states of 1,550-nanometer laser pulses to extract multidimensional data.

Unlike traditional time-of-flight lidar, this new architecture analyzes how light polarization shifts upon reflecting off targets. This approach enables millimeter-accurate ranging, Doppler velocimetry, and polarimetric material characterization without requiring multiple scanning passes. The team developed specialized computational models and algorithms to disentangle internal optical distortions and environmental noise, allowing the system to maintain performance in challenging conditions such as high ambient light, fog, rain, or dust. Experimental demonstrations successfully distinguished between static and dynamic objects, resolved surface textures through polarization speckle patterns, and identified material differences between artificial and real vegetation.

Dongyu Du, lead researcher at the University of Toronto, noted that while the prototype currently operates in controlled settings, the underlying methodology significantly advances machine perception. The system operates at eye-safe power levels and recovers detailed physical characteristics from scattered light, making it particularly valuable for autonomous vehicles, industrial inspection, and robotics operating in degraded visibility. The research team is now focused on upgrading hardware readout bandwidth, streamlining data acquisition, and optimizing transfer speeds to support real-time tracking of continuously moving scenes. This innovation marks a pivotal step toward deploying robust, multi-parameter sensing platforms capable of navigating complex, dynamic environments with greater reliability and safety.

“Although some emerging lidar technologies can also measure velocity, real-world perception often requires understanding an object's surface as well,” said Dongyu Du from the University of Toronto in Canada. “Our new system uses a single measurement at each scanned point to capture millimeter-accurate distance, velocity and surface material while using eye-safe laser power.”

In Optica, Optica Publishing Group’s journal for high-impact research, the researchers from the University of Toronto and network technology company Ciena Corporation describe their new lidar system, which combines new analysis methods with a standard telecommunications device that enables sensing of distance, velocity and surface material by capturing polarization information.

The new lidar system can simultaneously measure the location, speed and material properties (polarization) of objects in a scene, which could be useful for autonomous driving. Credit: Dongyu Du, University of Toronto

“Although this work is still at the research-prototype stage, it points toward future sensing systems that could help machines understand the physical world more reliably,”

 said Du. “This could lead to safer autonomous vehicles, more capable robots, better industrial inspection and sensing systems that work in poor visibility caused by glare, fog, or heavy rain.”

Adapting telecom technology for lidar...The new work grew out of a collaboration between research groups at the University of Toronto and Ciena Corporation, which have been exploring how a device called a coherent optical modem could be adapted for lidar. These mass-produced modems can simultaneously measure many different properties of light, including its frequency, polarization, phase and amplitude.

“Coherent optical modems are used to send internet traffic through cities and even across continents by encoding information into light,” said Du. “As a result, they can control and measure light with very high speed and precision, come in compact form factors and naturally solve many of the same sensing challenges encountered with lidar.”

The researchers developed a lidar system that uses a coherent optical modem as the transmitter and receiver. This made it possible to send and detect multiple properties of light with extremely high speed and precision and, thus, extract far more information from each measurement than is possible with a conventional lidar system.

The system works by illuminating a target with a laser beam that is randomly modulated at extremely fast speeds — tens of billions of times per second — in two orthogonal polarization channels. While conventional lidar systems measure the time delay between when light is emitted and when it returns to calculate distance, the new system also measures how the polarization properties of light change after interacting with the target surface, making it possible to recover distance, velocity and material properties.

(a) A moving model vehicle, a speed-limit sign, an artificial plant and a real plant, mimicking a simplified

roadside environment with both static and dynamic objects.

(b) The reconstructed depth map localizes the spatial layout of the vehicle, sign and surrounding vegetation.

(c) It doesn’t resolve the sign lettering because the sign has nearly uniform albedo at the modem wavelength of 1550 nm.

The polarization map (d) reveals material-sensitive details not resolved by depth or intensity, including the sign text and the difference between artificial and real vegetation.

The reconstructed Doppler velocity map (f) identifies the moving vehicle and separates it from the static background. Credit: Dongyu Du, University of Toronto

Extracting the lidar signal...The researchers also developed a new way to make sense of the measurements, which are difficult to recover and are degraded by noise and unavoidable distortions induced by the lidar system’s internal optics.

“Previous systems lacked the computational tools to separate out the signal of interest from the internal distortions,” said Du. “We developed a new polarization-aware model of how light propagates through our system and interacts with the scene, along with algorithms that can disentangle all of these effects to produce clean estimates of distance, velocity and material properties.”

To test the system, the researchers first compared its depth and velocity measurements to those obtained with other lidar processing methods using controlled scenes with static and moving objects. The new method outperformed existing techniques on both fronts, particularly in challenging low-signal regions where other approaches struggled with noise. They also showed that the system works reliably under strong ambient light, which can cause other polarimetric lidar systems to fail.

The researchers then showed that the lidar system could recover surface material properties of everyday materials, including metals, plastics and objects with varying surface roughness. They also measured polarization speckle — an interference pattern created by laser light — and demonstrated that these patterns carry information about surface roughness, thereby providing a means to characterize materials at fine scales.

Finally, the researchers demonstrated that the polarization information obtained with the system can be helpful for imaging through scattering media with optical thickness up to 4.76. This capability could be useful for imaging in conditions where visibility is limited by fog, rain or dust.

The researchers are now working to improve the system’s hardware readout bandwidth, streaming acquisition and data transfer to enable more direct and faster capture of continuously evolving dynamic scenes.

Source: optica.org

AUTONEWS

New Dacia Spring(Renault Kwid)?

Dacia announces the launch of the second generation of its 100% electric city car.

Manufactured in Europe, the new Spring opens a new chapter for the brand, while building on the continuity of a model that has become a reference model.

Launched in 2021, the Spring has already won over nearly 210,000 customers across Europe, confirming the relevance of simple, affordable and practical electric mobility.

True to the spirit of Dacia, the new Spring retains the essential elements: a 100% electric powertrain, four real seats and a real trunk.

A universal and instantly recognizable name, Spring evokes the spring season — a symbol of renewal and positive energy. With the new Spring, Dacia continues to pursue a clear ambition: to pave the way for electric vehicles accessible to all.

The origin of the name of the new Dacia Spring...The new Spring embodies the positive energy of renewal and marks the beginning of a new story, continuing on from the Spring model, with which it shares much more than just its name: the same DNA - the DNA of a small, reliable and practical all-electric car, which continues to pave the way for electric vehicles accessible to all.

A legacy with over 210,000 customers...Since its launch in 2021, the Dacia Spring has won over nearly 210,000 customers across Europe. A number that confirms the relevance of a clear proposition: simple, accessible and practical electric mobility.

Dacia, founded in 1968 and relaunched by the Renault Group in 2004, has the best quality/price ratio in its DNA. Its models have become market benchmarks. The Sandero has been the best-selling car for private European customers every year since 2017, and the best-selling car in Europe across all channels in 2024 and 2025. The Spring is the extension of this philosophy to the urban electric segment.

Current Dacia Spring: technical specifications...The Dacia Spring for sale comes in two engine versions, both sharing the same battery and the same urban use philosophy. It is a small, light and efficient car, designed for those who travel mainly in the city.

Engine and battery...The Spring is available with two power levels. The entry-level version is equipped with a 45 hp (33 kW) engine with 125 Nm of torque. The more powerful version increases to 65 hp (48 kW) and maintains the same urban use profile. Both versions share the same 26.8 kWh lithium-ion battery, with a homologated range of 225 km WLTP.

Charging...In alternating current, the Spring accepts charging up to 7.4 kW AC, completing a charge from 20 to 100% in approximately 5 hours. The 65 hp version includes fast charging in direct current up to 30 kW DC, allowing you to reset the battery from 20 to 80% in about 56 minutes.

Dimensions and habitability...The Dacia Spring is a small car on the outside, but functional on the inside. It measures 3.70 m in length, 1.58 m in width and 1.49 m in height, with a wheelbase of 2.74 m. The trunk has a capacity of 308 liters, which can expand to 1,004 liters with the rear seats folded down.

Equipment and technology...The interior includes a 10.1-inch touchscreen with Apple CarPlay and Android Auto, a 7-inch digital instrument panel, and connectivity with the My Dacia app. The Spring also includes the V2L (Vehicle-to-Load) system, which allows you to use the car's battery to power external devices via a 220V outlet.

MERCEDES-BENZ

Incredibly cheap kilometer: Mercedes e-Actros 10 euros/100 km

In an exclusive test for Vrele Gume, for the first time in the region, we are testing the capabilities of an electric truck in real operating conditions. The Mercedes eActros took on the task of distributing Rosa water, and the result exceeded expectations – the record for economy on the given transport route was broken.

During the test, we analyze the actual energy consumption, range under load, performance in everyday operation and total operating costs. In addition to the truck itself, we also check the charging infrastructure – how long does charging take, how much does it cost and whether the charging network is ready for the electrification of heavy transport.

This is not a laboratory experiment but a real work task in which the Mercedes eActros performs the job it was designed for every day. Can electric trucks replace diesel in regional transport and what future awaits us on the roads?

Achieving a cost of around €10 per 100 km with the Mercedes-Benz eActros is entirely feasible, provided the vehicle is charged with low-cost business electricity tariffs (around €0.08 to €0.10 per kWh). The actual energy consumption of the electric truck directly validates this estimate, generating massive savings when compared to conventional diesel.

1. Understanding consumption calculation...To understand how this €10/100 km figure is supported, it is necessary to analyze the vehicle's energy efficiency under real transport conditions:

Real Average Consumption: In long-distance European tests with a full load of 40 tons, the eActros 600 recorded an average of 103 kWh per 100 km.

Required kWh Price: For these 103 kWh to cost exactly €10, the price of energy needs to be €0.097 per kWh.

This electricity tariff value is standard for industries and fleet operators in Europe who charge trucks slowly in their own garages (Overnight Charging) or use long-term subsidized renewable energy contracts.

2. Direct comparison: electric vs. diesel...The great commercial advantage of the eActros becomes evident when we put the operating cost side by side with an equivalent traditional model from Mercedes-Benz Trucks:

Criterion	Mercedes-Benz eActros (Electric)	Standard Heavy Truck (Diesel)
Fuel consumption p/100 km	~100 kWh	~26 to 30 Liters
Average Unit Price	€0.10 per kWh (Business Deposit)	€1.60 per Liter (Diesel pump)
Cost per 100 km	~€10,00	~€41,60 a €48,00

3. Factors that alter this cost...Although the €10/100 km mark is perfectly attainable, the actual cost fluctuates based on three crucial variables:

Charging Infrastructure: If the driver needs to use public high-power fast chargers (Megawatt Charging), the price per kWh can rise to €0.40 - €0.60, increasing the cost to €40 to €60 per 100 km.

Topography and Driving: The eActros' regenerative braking system can recover up to 25% of the energy used on descents or in urban areas, optimizing overall fuel consumption.

Load and Aerodynamics: Driving with the 40-44 ton limit in harsh winter climates pushes consumption to around 140 kWh/100 km, increasing costs proportionally.

Conclusion...The eActros fulfills the objective of delivering cheap energy at €10 per 100 km , reducing operational fuel costs by up to 75% compared to diesel. The vehicle's financial return depends directly on focusing refueling on the company's own low-cost internal electricity grid.

 

Autonews

GM

2027 Chevrolet Silverado 1500

The next-generation 2027 Chevrolet Silverado 1500 debuts with new 5.7-liter and 6.6-liter V8 engines, a redesigned exterior, advanced digital displays and expanded off-road options.

Chevrolet has announced significant improvements in power, design, technology and off-road capabilities for the new Silverado 1500. The new Silverado 1500 is expected to go on sale later this year.

At the heart of the Silverado 1500 is an expanded powertrain lineup led by 5.7-liter and 6.6-liter V8 engines. Chevrolet says the new Silverado offers the most powerful naturally aspirated V8 engine in its class, reinforcing the brand's long-standing commitment to V8 truck performance.

The lineup will continue to include four powertrain choices, including an improved 2.7-liter TurboMax engine, now paired with a 10-speed transmission, as well as a Duramax 3.0-liter turbo-diesel engine.

The exterior of the new Chevrolet Silverado 1500 has been completely redesigned with a bolder front end, a stronger stance, new LED headlights and taillights, and more distinctive trim-specific styling.

Inside, every 2027 Silverado 1500 features a new digital cockpit with a standard 16.3-inch center display and a 12.2-inch driver information center. Higher-end models, such as the ZR2 and High Country, add an 11.5-inch passenger display, a head-up display, and a rearview mirror with camera, creating more than 60 inches of available digital viewing space. Available dual wireless charging and a reconfigurable Multi-Flex center console add more everyday convenience.

The 2027 Silverado 1500 lineup includes seven trim levels: Work Truck, Custom, Silverado, Custom Trail Boss, Trail Boss, ZR2 and High Country.

Off-road buyers have more choices than ever before. The ZR2 becomes the most off-road-capable Silverado ZR2 yet, with 35-inch tires, a 2-inch (50 mm) raised suspension, front and rear electronic differential locks, Multimatic DSSV shocks and the available ZR2 Bizon package developed with AEV (American Expedition Vehicles).

70 years of V8 excellence...We introduced our first V8 engine in 1955. Every generation since has built on the legacy and pride that came before it. Today, our American-assembled,* reimagined-from-the-ground-up 5.7L and 6.6L V8s stand ready to fuel our most powerful Silverado ever.

Our lineup of four hardworking engines includes the upgraded TurboMax and the class-exclusive* Duramax 3.0L Turbo-Diesel along with the next-generation 5.7L and 6.6L V8s. Engineered for serious work, these V8 engines create the most capable and refined Silverado 1500 powertrain lineup ever, with improved power and torque.

Stronger Powertrain Lineup with Next-Generation 5.7L and 6.6L V8s...At the heart of the new Silverado 1500 is its most capable and refined powertrain lineup ever, led by available next-generation 5.7L and 6.6L V8 engines. Building on Chevrolet’s performance legacy — including the recently announced Corvette LS6 6.7L V8 — these new engines will be assembled by the skilled teams at GM’s Flint Engine Operations, Tonawanda Propulsion3, and St. Catharines Propulsion plants.

The Silverado 1500 now offers the most powerful naturally-aspirated V8 engine in its class4. Engineered for serious work and confident towing, these next-generation V8s deliver improvements in power and torque giving customers more choice without compromise. These engines underscore Chevrolet’s commitment to offering V8 power for truck customers and build on more than 70 years of V8 know-how and validation that customers can rely on for demanding jobs and everyday life.

“We pushed these engines through an extensive testing and validation process to make sure they deliver the durability, capability and dependability Silverado customers expect,” said Mark Dickens, executive chief engineer. “From tough towing scenarios to the daily demands our customers put on their trucks, these next-generation V8s were engineered and proven to perform in the real world.”

The Trail Boss also gets some serious off-road equipment, including 34-inch tires, a 2-inch (50 mm) factory lift kit and a special off-road hood.

At the top of the lineup, the 2027 Silverado High Country focuses on premium pickup truck comfort. It adds standard 22-inch wheels, a new High Country badging, an exclusive front grille finish, real wood decor, available microfiber materials and the first panoramic sunroof offered in the Silverado.

Chevrolet says pricing and additional availability details will be announced later this year.

Autonews

AUTONEWS

What is the worst automotive trend of today?

The answers that the American magazine Jalopnik tried to get show that drivers are not so much annoyed by engines, performance or fuel consumption as by manufacturers' decisions that make cars more complicated and less practical.

Among the most frequently criticized trends were electric and hidden door handles. Many believe that they represent a solution to a problem that does not exist, while at the same time introducing additional possibilities for malfunctions, especially during winter, when the battery is discharged or impractical after an accident.

The Trend: Flush, pop-out, or purely electronic exterior door handles used for styling and minor aerodynamic gains.

The Backlash: They are highly prone to freezing shut in winter, risk trapping occupants if the car loses battery power during an accident, and solve a problem that never existed.

The Jaecoo J7's recessed door handle is designed to retract and improve aerodynamics

A large number of dissatisfied drivers criticize the disappearance of physical buttons from the vehicle interior. Drivers claim that classic controls are easier to use while driving, while switching almost all functions to the central screen distracts attention from the road.

Large wheels with low-profile tires, which have become standard even for family SUV models, have also been criticized. Although they contribute to a more attractive appearance, drivers point out that they reduce comfort, increase the risk of damage on bad roads and significantly increase the cost of replacing tires.

The Trend: Automakers are building hardware—like heated seats, remote starters, or increased horsepower—directly into the vehicle, but locking them behind monthly or annual digital subscription paywalls.

The Backlash: Consumers find it anti-consumer to pay repeatedly for parts and equipment they already financed and own at the point of sale.

Another unnecessary detail perfectly reflects today's automotive industry, where even useful functions are turned into a tool for brand promotion. Instead of making the area next to the vehicle as well lit as possible for safer entry and exit, the priority becomes the projection of a logo onto the ground, which attracts attention but does not bring real added value to the driver.

This image shows the high-tech interior of a BMW iX3, highlighting the hexagonal steering wheel and digital instrument panel

The worst automotive trend today is the eradication of physical buttons in favor of touchscreen-only interfaces and capacitive touch-sliders. This design prioritizes sleek aesthetics and cost-cutting over driver safety and usability, requiring drivers to take their eyes off the road to perform basic tasks.

Some of the participants in the discussion also warn about the increasingly poor visibility from modern cars due to high side lines and smaller glass surfaces. They believe that drivers should not depend on cameras and sensors to maneuver in situations that they used to solve by looking out the window.

Particularly negative reactions are caused by manufacturers' attempts to charge for certain functions through subscription options (such as a subscription for heated seats), even though the necessary equipment is already installed in the car. Many believe that such a practice could become one of the most hated trends in the automotive industry.

The courtesy light projector on the doors is often considered useless because its function is purely aesthetic. It transforms the vehicle into a light panel, but does not improve safety or practical lighting.

LED courtesy light projector with the Maybach logo

Interestingly, most drivers do not criticize electrification or modern drive technologies. Instead, drivers often resent trends that they see as putting marketing and visual appeal ahead of functionality.

The conclusion is pretty clear. Many drivers want cars that are simple, reliable, and practical for everyday use, even if that means fewer screens, fewer lighting effects, and fewer "futuristic" features. The auto industry may be moving toward a digital future, but a segment of buyers clearly still value common sense.

The industry-wide shift toward digital-everything creates multiple problems for drivers:

Distraction: Adjusting the air conditioning or tuning the radio requires navigating through multiple menus, which increases the risk of accidents.

Capacitive Frustrations: Many touch-sliders (like those used for volume or temperature) lack backlighting, making them nearly impossible to use at night.

System Lag: Unlike a physical knob that responds instantly, touchscreens can freeze, lag, or require multiple taps to register an input.

Other widely disliked industry trends include:Pop-Out Door Handles: Electric or hidden door handles that can fail to open during a collision or leave you stranded when a car battery dies.

Automotive Subscriptions: Paying a recurring monthly fee for features that are already physically built into the car (like heated seats or remote start).

Oversized Wheels & Thin Tires: Putting low-profile tires on family SUVs, which drastically reduces ride comfort and makes the wheels highly susceptible to pothole damage.

TUNNING

Mansory Lamborghini Urus with 1085 HP

From the German tuning house Mansory comes another modified Lamborghini Urus, in this case the plug-in hybrid Urus SE.

Here, Mansory has primarily provided carbon fiber elements (front spoiler, air vents, a set of sills, elements on the C-pillar, rear diffuser, rear roof spoiler...).

Then there’s the rear of Mansory’s Urus SE, rocking a huge wing that looks like it was lifted from a JDM special of the early 2000s. Other updates include a small lip spoiler and a radical new diffuser, complete with new quad tailpipes.

Of course, no Mansory product would be complete without some serious performance upgrades. As standard, the Urus SE’s 4.0-liter twin-turbocharged V8 and electric motor combine to produce 789 hp and 701 lb-ft (950 Nm) of torque. That fell short of Mansory’s ambitions, even on a build it calls soft.

Through a series of undisclosed upgrades, the tuning brand has bumped power to 1,085 hp and 922 lb-ft (1,250 Nm) of torque. No one needs hypercar-level power in an SUV, but these changes at least help ensure the SE’s performance matches its new looks.

Also available are a sports exhaust system, wheels up to 24 inches and a modified suspension, as well as a refined interior (at the client's request).

The plug-in hybrid drive (4.0 liter twin-turbo V8 engine and electric motor) now has a total of 1085 HP and 1250 Nm

The price is not stated in the short news.

Autonews

AUTONEWS

How do jet fuel changes actually affect airfares?

As concerns grow over global fuel supplies and the cost of flying, new research from the University of Adelaide shows the relationship between jet fuel prices and airfares is not as simple as passengers might think. The study found that different types of jet fuel price shocks have very different effects on Australian domestic airfares, with some shocks leading to higher ticket prices, some having little effect, and others pushing fares in different directions across fare classes.

Published in Research in Transportation Economics, the study examined business-class, restricted-economy and best-discount airfares in Australia, and found the source of the fuel price shock matters more than the price movement alone.

"Not all fuel price shocks are economically harmful in the same way. The source of the shock matters greatly," said Professor of Aviation Shane Zhang from the University of Adelaide's College of Engineering and Information Technology.

"At first glance, it may seem that fuel price increases can be easily passed on to consumers through higher fares. In reality, the relationship is more complex.

"Airfare adjustments are shaped not only by rising input costs, but also by airline pricing strategies, passenger behavior, competitive pressures and consumer sensitivity to price."

Jet fuel is one of the airline industry's biggest costs, typically accounting for 25% to 40% of total operating expenses. In Australia, where about 90% of jet fuel is imported, understanding how airfares respond to fuel price shocks is particularly important.

Analyzing Australian domestic airfare data from the Bureau of Infrastructure and Transport Research Economics, the study separated jet fuel price shocks into three categories: supply shocks, aggregate demand shocks and jet fuel-specific demand shocks.

Fuel supply shocks, which can be caused by events such as wars, natural disasters or disrupted supply chains, were found to have little direct impact on domestic ticket prices.

"This was one of the more surprising findings," said Dr. Yifei Cai from the University of Adelaide's College of Engineering and Information Technology.

"Many people would expect airlines to immediately pass fuel cost increases on to passengers, but our results suggest airlines can often smooth these effects through fuel hedging, long-term supply contracts and other operational strategies."

By contrast, aggregate demand shocks, which are usually linked to periods of economic growth, were found to increase business-class and restricted-economy fares.

"When economic conditions are stronger, travel demand tends to increase, particularly among business travelers," Professor Zhang said. "That gives airlines more room to raise prices in these fare classes."

The third category, jet fuel-specific demand shocks, had more complex effects. These shocks can occur when market participants begin buying or hoarding oil because of fears about future shortages, geopolitical risks or climate-related disruption.

The research found these shocks can reduce business-class fares in the short term, as uncertainty dampens corporate travel budgets, while increasing discount fares as more travelers seek cheaper tickets.

"Oil-specific demand shocks are particularly destabilizing because they can trigger sharp price increases without corresponding changes in actual supply or global demand," Dr. Cai said. "Overall, the findings highlight that airfare responses are shaped not only by fuel costs, but also by passenger behavior and broader macroeconomic conditions."

The findings are especially relevant amid current global concerns about fuel supply and aviation costs.

"In the current context, fuel market disruption can act in more than one way," Professor Zhang explained. "On one hand, it can be understood as a supply shock, where the physical flow of oil or refined products is constrained. Our research suggests these supply shocks do not necessarily lead to immediate domestic airfare increases, because airlines may be able to absorb them.

"At the same time, uncertainty can create an oil-specific demand shock, where buyers respond to fears of future shortages. That can be more destabilizing for aviation markets and may lead to very different fare responses across domestic and international routes."

Dr. Cai said the findings could help passengers better understand why airfare changes are often uneven and not always directly tied to fuel price movements, while for airlines, the results highlight the importance of flexible pricing strategies and fuel risk management.

The findings also have implications for future discussions around aviation fuel policy, carbon pricing and the transition to sustainable aviation fuel.

Jet fuel changes directly affect airfares because fuel accounts for up to 30% of airline operating costs. When fuel prices spike, airlines pass the burden onto consumers by raising base ticket prices, adding explicit fuel surcharges, reducing the number of cheap discount seats, and cutting less profitable flight routes.

Higher Ticket Prices & Surcharges: Airlines—especially on long-haul and international routes—often add explicit fuel surcharges to the ticket price or raise the overall base fare. For instance, recent geopolitical shocks have driven a surge in global fuel costs, causing some transcontinental and international ticket prices to spike.

Reduced Supply of Cheap Seats: Rather than raising every ticket evenly, carriers use dynamic pricing algorithms to limit the availability of basic economy and discounted seats, pushing travelers into slightly more expensive main economy classes.

Route Cuts and Cancellations: If fuel costs remain stubbornly high, airlines may park less fuel-efficient aircraft or cancel routes with lower profit margins to save money.

The "Rocket and Feather" Effect: Airfares rise rapidly when fuel prices spike, but rarely drop at the same pace when fuel costs go back down (often called asymmetric price transmission). Airlines often delay lowering fares while waiting to ensure fuel price drops are permanent.

Fuel Hedging: Some airlines lock in fuel prices months or even years in advance to protect against sudden market changes. This means a sudden spike in crude oil prices might not hit your ticket price immediately, but will likely be factored in once those hedges expire.

Provided by University of Adelaide