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Formula One car

A car is a single-seater, open-cockpit, open-wheel automobile designed solely for high-speed competitions on closed circuits in the FIA , propelled by a hybrid power unit and governed by stringent technical regulations to ensure , , and fairness. These cars represent the pinnacle of , combining a 1.6-liter, 90-degree V6 turbocharged with energy systems (ERS) that deliver a combined output of approximately 1,000 horsepower, enabling from 0 to 100 km/h in approximately 2.6 seconds and top speeds exceeding 350 km/h. The power unit includes motor generator units (MGU-K for and MGU-H for ), an energy store with a maximum voltage of 1,000 V, and control electronics managed by an FIA-standard (), all while adhering to limits of 110 kg per and a maximum of 100 kg/h using a sustainable petrol blend containing at least 10% advanced . are a defining feature, with regulated bodywork—including front and rear wings, floor edges, and diffusers—optimized for and minimal , constructed from composites and aluminum alloys to achieve a minimum of 798 kg (including the driver but excluding ). Safety is integral to the design, featuring a carbon fiber survival cell, frontal and side impact structures, roll hoops, and anti-intrusion panels, alongside systems like the HANS device and fire suppression to protect the driver during high-risk maneuvers. The chassis dimensions are precisely controlled, with a maximum width of 2,000 mm, overall length typically up to 5,500 mm, height limited to 950 mm (excluding cameras and roll structures), and wheelbase of 3,600 mm, using 18-inch wheels and an eight-speed semi-automatic rear-wheel-drive transmission without traction control. Teams must use standardized components for certain parts, such as brakes and electronics, while innovating within categories like listed team components (LTC) and open source components (OSC), fostering technological advancement under FIA homologation valid through 2025. The 2025 season uses the final iteration of the hybrid power units introduced in 2014, prior to significant changes in 2026.

History

Origins and early development

The (FIA), through its Commission Sportive Internationale, formalized in 1946 as the premier specification for racing, building on pre-war voiturette classes that emphasized 1.5-liter supercharged engines alongside larger naturally aspirated options up to 4.5 liters. These rules aimed to standardize post-World War II competition, accommodating both supercharged and unsupercharged powerplants to bridge historical designs with emerging technologies, and the first event under this formula was the . The inaugural Formula One World Championship race took place at Silverstone Circuit on 13 May 1950, where Alfa Romeo's Type 158—powered by a 1.5-liter supercharged delivering approximately 400 horsepower—secured victory for driver , establishing early dominance through its pre-war derived engineering. The 158 exemplified the era's focus on high-revving superchargers for power, with twin Roots-type blowers enabling outputs far exceeding contemporaries while adhering to the 1.5-liter displacement limit. Early Formula One chassis designs relied on robust ladder frames constructed from steel tubing, featuring exposed wheels for simplicity and ease of maintenance, while basic aerodynamics involved streamlined bodywork to minimize drag without complex appendages. These configurations prioritized engine integration and driver visibility over rigidity, often resulting in lightweight yet flexible structures weighing around 700 kilograms. Key innovations emerged rapidly, including the debut of disc brakes in Formula One by the BRM Type 15 in late 1951. Fuel injection systems also appeared in the 1950s, with introducing mechanical direct injection on the W196 in 1954 to enhance efficiency and power delivery over carburetors. This car further incorporated desmodromic valves—adapted from road car and aviation technology—for precise high-rpm control without traditional springs, influencing subsequent designs like the production 300 SL.

Technological evolution

The technological evolution of Formula One cars from the 1970s onward has been profoundly shaped by regulatory changes aimed at enhancing , , and spectacle, leading to iterative advancements in , materials, and powertrains. In the late 1960s and early 1970s, ground-hugging emerged as a pivotal innovation, with Colin Chapman's introducing inverted wings and wedge-shaped designs in 1970 to generate while minimizing drag, drawing inspiration from earlier concepts like the sports cars. This approach revolutionized cornering speeds by exploiting the under the car body, though it prompted early regulatory scrutiny to curb extreme designs. By the mid-1970s, these aerodynamic principles had become foundational, enabling cars to achieve higher grip levels without excessive mechanical complexity. The 1980s marked a dual shift in chassis construction and propulsion systems, driven by the pursuit of lighter, stiffer structures and immense power outputs. The MP4/1 in 1981 pioneered the use of a full carbon fiber , replacing traditional aluminum honeycombs and reducing weight by approximately 20% while enhancing torsional rigidity to better withstand high-speed impacts. Concurrently, turbocharged 1.5-liter engines dominated, delivering over 1,000 horsepower in qualifying trim through unrestricted boost pressures, as seen in and units that propelled teams like Williams and to dominance. However, concerns over costs, safety, and drivability led the FIA to ban turbos after the 1988 season, ushering in naturally aspirated V10 and V8 engines from 1989 that emphasized reliability and broader power bands. The hybrid era began in 2014 with the introduction of 1.6-liter V6 turbocharged power units incorporating motor generator units (MGU-K for kinetic energy recovery and MGU-H for heat recovery), which boosted overall efficiency to over 50% while maintaining competitive outputs around 1,000 horsepower in race conditions. This shift, mandated by FIA regulations to promote sustainability, integrated electric boost seamlessly with internal combustion, transforming energy management strategies. In 2022, ground effect aerodynamics were revived through underfloor Venturi tunnels to improve overtaking by reducing dirty air, resulting in closer racing as evidenced by multiple lead changes in early-season grands prix. For 2025, the FIA introduced driver cooling systems, including vests and ventilation to be used when a heat hazard is declared for ambient temperatures of 31°C or above, to mitigate heat stress, alongside expanded testing opportunities—up to two days per team—to foster talent development without disrupting race driver schedules. Looking ahead, the 2026 regulations preview a balanced 50/50 split between electric and thermal power, reintroducing active for adjustable , and mandating 100% sustainable fuels derived from non-food sources to align with goals by 2030. These changes aim to make cars lighter (by 30 kg) and more agile, fostering equitable competition across manufacturers.

Regulations and safety

Technical regulations

The technical regulations for Formula One cars are governed by the (FIA), with the 2025 Formula 1 Technical Regulations issued on December 11, 2024, setting the standards for car design, performance, and development. These rules aim to ensure safety, fairness, and sustainability while promoting close racing, mandating a 1.6-liter V6 turbocharged power unit configuration. The power unit includes an limited to 16,000 rpm, a Motor Generator Unit-Kinetic (MGU-K) capped at 120 kW and 50,000 rpm, and a Motor Generator Unit-Heat (MGU-H) limited to 125,000 rpm, with fuel flow restricted to a maximum of 100 kg/h above 10,000 rpm. Fuel must consist of petrol with a minimum (RON+MON)/2 of 87, oxygen content no greater than 3.45% by weight, and at least 10% advanced sustainable by mass. Car dimensions are strictly defined to balance agility and stability, with a maximum wheelbase of 3,600 mm measured between the front and rear axle centerlines, and a maximum overall width of 2,000 mm excluding tires, rims, and wheel covers. The minimum weight of the car, including the driver in racing apparel but excluding , is 798 , with an additional 5 kg allowance during heat hazard conditions. These parameters influence and handling, requiring teams to integrate crash structures without compromising the overall limits. Aerodynamic development is constrained through limits on (CFD) and testing, allocated based on the previous season's Constructors' Championship performance to level the playing field—top-performing teams receive fewer resources, such as 70% of baseline allowances for leading teams. For 2025, the baseline includes 320 runs and 2,000 CFD events per aerodynamic testing period at 60% scale, with adjustments like a mid-season reset to reflect updated standings. Teams must classify aerodynamic components as listed (LTC), standard supply (), team-restricted (TRC), or open supply (OSC), prohibiting sharing in shared facilities. A financial cost cap of $135 million base for , adjusted for and $1.8 million per beyond 21 (effective approximately $145 million for the 24-race ), caps operational expenditures excluding salaries, engines, and certain costs, encouraging standardized parts like brake drums to control expenses. Testing is further restricted to limit private running, with no more than three days of pre-season testing and prohibitions on unscheduled track sessions, while mandatory FP1 sessions have been expanded (doubled to four per team across the season) to aid without favoring established teams. Looking ahead, the 2026 regulations preview lighter and more agile cars, reducing the minimum weight to 768 kg including the driver, narrowing the maximum width to 1,900 mm, and shortening the to 3,400 mm for improved maneuverability. Power units will eliminate the MGU-H, relying solely on a more powerful MGU-K delivering up to 350 kW from a battery-focused system, with a 50:50 split between electrical and combustion power to enhance . These changes, detailed in the June 24, 2024, issue of the 2026 Technical Regulations, prioritize reduced environmental impact and closer competition.

Safety features and standards

Safety in Formula One is paramount, with cars incorporating mandatory protective features designed to mitigate crash risks and enhance driver survivability. Central to cockpit protection is the Halo device, introduced by the FIA in as a titanium tubular structure mounted above the driver's head to shield against debris and overhead impacts. Constructed from high-strength laminate, the Halo weighs approximately and is tested to withstand vertical loads up to 12 tons, equivalent to forces exceeding 12g for the car's mass, ensuring it remains intact during severe collisions. Impact-absorbing structures form another critical layer of defense, with front and rear components engineered to dissipate crash energy and prevent intrusion into the survival cell. The front impact structure undergoes dynamic testing involving a 900 kg trolley at 17 m/s, designed to absorb approximately 130 kJ of kinetic energy while limiting deceleration to protect the driver, and must resist loads up to 220 kN to avoid chassis deformation. Similarly, the rear impact structure is tested with a 900 kg object at 11 m/s, capping deceleration at 25g, to handle rear-end collisions effectively. Complementing these, side intrusion panels, extended in 2015 to cover the cockpit rim and fuel cell area, utilize Zylon and composite laminates to absorb lateral forces, tested per FIA procedures to prevent penetration during oblique side impacts. These panels, integrated into the carbon-fiber monocoque chassis, enhance overall structural resilience without compromising the lightweight design essential for performance. Driver restraint systems further bolster survival chances by minimizing injury during high-g forces. The Head and Neck Support (HANS) device, mandatory since 2003, tethers the helmet to the shoulder belts, restricting excessive head movement in crashes and reducing risks, as evidenced by its role in incidents like Robert Kubica's 2007 collision. Paired with it are six-point harnesses conforming to FIA Standard 8853-2016, which secure the driver across the torso, shoulders, and pelvis with quick-release mechanisms for rapid extraction. Fuel system safety prevents post-crash fires, a historical concern in motorsport. F1 cars use a single rubber bladder fuel tank compliant with FIA FT5-1999 standards, foam-filled to suppress fuel surge and explosion risks during impacts, containing up to 110 kg of fuel at low pressure (maximum 1.0 barG) with integrated pressure relief. Self-sealing breakaway valves on all fuel lines ensure disconnection under crash loads without leakage, separating at less than 50% of the system's ultimate strength to maintain containment. The tank's positioning within the survival cell, shielded by impact structures, isolates it from the driver and engine components. For the 2025 season, updates address emerging physiological risks, including heat stress in extreme conditions. cooling kits, now permitted with scoops up to 3000 mm² and side apertures up to 750 mm² each, integrate into the car's design to circulate air without aerodynamic penalties, included in a 5 kg "heat hazard" mass allowance for safety gear. Stricter weight regulations for personal equipment ensure these systems do not exceed limits, maintaining balance while prioritizing endurance. On-track protocols complement these hardware features, with the Virtual Safety Car (VSC) and medical car designed for swift response enabled by standardized car layouts. The VSC, deployed since , enforces a fixed delta time for all cars during incidents, allowing marshals access without full neutralization, while the medical car—driven by an experienced professional—follows the field, its positioning informed by F1 cars' consistent dimensions for unobstructed track intervention. These measures, tied to the cars' predictable structural profiles, facilitate rapid medical extraction and hazard mitigation.

Chassis and structure

Monocoque and materials

The core structural framework of a Formula One car is the , serving as the survival cell that provides rigidity and lightness while integrating key components. Constructed primarily from (CFRP) composites, the monocoque uses PAN-based with a not exceeding 550 GPa, offering a high strength-to-weight ratio where the fiber tensile strength reaches approximately 3.5 GPa. This material is five times lighter than yet provides comparable stiffness, enabling the structure to handle extreme aerodynamic and dynamic loads without excessive mass. The encompasses the , engine bay, and in a single continuous bonded unit, with the survival cell designed to transfer and power unit loads through specified fixings and studs. It undergoes rigorous structural validation, including frontal impact testing at a of at least 15 m/s to ensure integrity under high deceleration, with peak deceleration not exceeding 60g for more than 3 ms. Advanced materials enhance the monocoque's performance, incorporating fibers like for side intrusion panels to provide impact resistance, and aluminum cores sandwiched between carbon skins for superior absorption and . These cores, varying in thickness based on load requirements, form multi-layer sandwich panels that optimize for handling. Manufacturing involves hand layup of carbon fiber sheets impregnated with , followed by curing in an under elevated pressure and temperature to achieve void-free consolidation and precise shapes optimized via (CFD). transfer molding is also employed for certain sections to ensure uniform distribution and structural uniformity. Under the regulations, the overall car weight will be reduced by 30 kg to 768 kg, aiming to lower costs while maintaining and standards.

Dimensions and weight distribution

Formula One cars are subject to strict dimensional regulations set by the Fédération Internationale de l'Automobile (FIA) to ensure safety, fairness, and performance consistency. The maximum width is limited to 2000 mm, while the maximum height is 950 mm, excluding certain protrusions like the roll hoop. There is no explicit maximum length, but practical constraints from aerodynamic and chassis rules result in typical overall lengths of approximately 5200–5400 mm. The wheelbase, measured as the maximum distance between the front and rear wheel centers, is capped at 3600 mm, with teams optimizing it around 3550–3600 mm to balance stability in high-speed corners with agile handling influenced by aerodynamic demands. Weight distribution is critically regulated to promote equitable competition and optimal , with a minimum of 800 kg for the including the but excluding as of the 2025 season (following an increase from 798 kg due to the minimum weight rising to 82 kg). This includes a minimum weight of 82 kg (with equipment), achieved through adjustable placed strategically near the center of to fine-tune balance without compromising structural integrity. Regulations mandate a minimum of 44.6% of the total on the front and 53.9% on the rear during key sessions like qualifying, encouraging teams to target an ideal bias of around 45% front and 55% rear for superior traction and cornering response. The center of height is kept low at approximately 450 mm above the ground, facilitated by the monocoque's design and floor-mounted components, which lowers the overall profile and enhances stability under lateral loads. Looking ahead to 2026, the FIA plans further refinements to make cars more nimble, reducing the minimum mass by 30 kg to 768 kg while shortening the wheelbase to a maximum of 3400 mm and narrowing the overall width to 1900 mm. These changes aim to improve racing closeness by enhancing maneuverability, with continued emphasis on low center of gravity and precise ballast placement to maintain the targeted weight distribution. Ballast must be fixed securely, with a density exceeding 8000 kg/m³, and positioned within designated cockpit volumes to meet the driver minimum without altering the car's fundamental balance.

Power unit

Internal combustion engine

The (ICE) in a Formula One power unit is a 1.6-liter, 90-degree V6 turbocharged unit, featuring six of equal capacity with circular bores and two inlet and two exhaust valves per . This configuration, introduced in , emphasizes high efficiency and compactness, with the engine revving up to a maximum of 15,000 rpm under normal operating conditions. The employs a single-stage and exhaust on a common shaft, spinning up to 125,000 rpm, to boost performance while adhering to strict fuel flow limits of 100 kg/h above 10,500 rpm. Thermal power output from the ICE reaches approximately 550-560 kW, achieved through optimized and precise control, contributing the majority of the power unit's propulsion before integration with elements. Fuel delivery occurs via direct injection, with one per operating at a maximum of 500 bar, supplied by a high-pressure pump and rail system, ensuring efficient without upstream or downstream injectors relative to the valves. and lift profiles are prohibited to maintain parity, but turbo response is enhanced through anti-lag systems, which manage boost via adjustments and exhaust valve control during off-throttle conditions. Since 2022, the engines have run on E10 sustainable fuel, comprising 90% fossil-derived components and 10% advanced from non-food sources, with a full transition to 100% sustainable fuels mandated for to align with net-zero goals. Fuel properties are tightly regulated, including a minimum 10% content, maximum oxygen of 3.45 wt%, and low levels under 10 mg/kg, to promote clean and thermal efficiencies exceeding 50%. Cooling systems are critical for sustaining high outputs, utilizing charge air intercoolers to reduce intake temperatures post-compression, alongside dedicated and circuits with pumps and heat exchangers. These prevent except in , with header tanks capped at 3.75 barG via relief valves, and systems dissipating heat from bearings and pistons; brake liquid cooling remains forbidden. Exhaust is managed through the turbo setup to minimize losses, supporting overall management without delving into electrical . Development of the has been standardized and frozen since the 2022 homologation, prohibiting specification upgrades through 2025 to redirect resources toward the regulations, with only minor reliability or safety modifications allowed. All ten teams utilize engines from four manufacturers: (powering McLaren, Williams, , ), Ferrari (Ferrari, Haas), (), and Honda-derived units via (, ), ensuring controlled under FIA oversight via a standard . This freeze maintains parity while the integrates seamlessly with components for total power delivery exceeding 1,000 hp.

Hybrid systems and energy recovery

The hybrid systems in power units integrate electrical components with the to recover and deploy energy, enhancing performance and efficiency since their introduction in 2014. These systems, part of the Energy Recovery System (ERS), primarily consist of the Motor Generator Unit-Kinetic (MGU-K) and the Motor Generator Unit-Heat (MGU-H), which harvest kinetic and thermal energy respectively, storing it in a pack known as the Energy Store (ES). The MGU-K recovers generated during braking, converting it into at a maximum rate of 120 kW, with a peak of 200 and rotational speed up to 50,000 rpm; this is stored in the for later deployment. Deployment from the MGU-K provides an additional boost of up to 120 kW (approximately 160 ), enabling drivers to activate ERS modes such as Hotlap for qualifying optimization or for overtaking maneuvers, with a maximum deployment of 4 MJ per lap. The minimum mass for the MGU-K is 7 kg, and it connects directly to the without transmission components. The MGU-H, linked to the , recovers from the exhaust gases to generate , which powers the and the MGU-K, while also spinning up the to eliminate turbo lag; it operates at a maximum rotational speed of 125,000 rpm with a minimum of 4 . This unit has no fixed power limit but is constrained by thermal and design factors, contributing to the overall system's ability to recover up to 2 per lap via the MGU-K. The , a lithium-ion Energy Store with a capacity supporting 4 deployment, weighs between 20 and 25 , operates at a maximum voltage of 1,000 V, and recharges primarily during braking phases for strategic usage. Together, these components enable the 2025 power unit to achieve a total output of approximately 1,000 horsepower, combining the internal combustion engine's power with electrical contributions, while maintaining a exceeding 50%—among the highest for any internal combustion-based system. Looking ahead, the 2026 regulations will phase out the MGU-H to simplify the power unit and reduce costs, boosting the MGU-K to 350 kW while emphasizing and deployment to deliver nearly 50% of the total power electrically, resulting in overall outputs exceeding current levels despite a reduced contribution of 400 kW.

Drivetrain

Transmission and gearbox

The in a Formula One car serves as the critical link between the power unit and the driven wheels, efficiently transferring while enabling rapid gear changes to optimize and top speed. It consists of a semi-automatic sequential gearbox, assembly, and driveline components, all designed for and strict performance constraints under FIA regulations. The gearbox is an 8-speed semi-automatic sequential unit, electronically controlled and homologated since with no major changes permitted through the season, ensuring among teams. Gear shifts are initiated manually by the driver using paddle shifters on the , achieving change times under 50 milliseconds through hydraulic actuation and seamless dog-ring engagement, far below the FIA-mandated maximum of 200 milliseconds for upshifts and 300 milliseconds for downshifts. This system eliminates the need for a traditional pedal during , allowing drivers to keep both hands on the wheel for over 3,000 shifts per . Mounted longitudinally behind the power unit in a carbon-fiber composite casing, the gearbox features a primary input concentric with the and a parallel secondary , with the final drive positioned within precise tolerances to minimize and packaging. Gear ratios are fixed for each and homologated at the season's start by the FIA, preventing mid-season alterations and tailored to track characteristics like Monaco's tight corners or Monza's long straights. The driveline incorporates a to enhance traction by distributing torque between rear wheels, integrated within the gearbox cassette for compactness. The is a multi-plate with carbon-fiber plates for high thermal resistance and low mass, electronically actuated via a steering-wheel paddle in a pull-type configuration. Engagement occurs in approximately 0.1 seconds, enabling precise control during starts through a dual-paddle system where drivers modulate slip to match power unit without automated aids. This manual launch procedure, supported by rev-matching and anti-stall features, replaces banned electronic launch control systems and demands significant driver skill for optimal getaway. Under 2025 regulations, the transmission remains unchanged from 2022 specifications, maintaining the 8-speed limit and freeze.

Clutch and differential

The in a Formula One car is a lightweight, multi-plate dry utilizing carbon-carbon composite friction plates for superior heat dissipation and rapid engagement under high loads exceeding 1,000 . This design, typically comprising 4-6 plates, enables precise modulation during standing starts and low-speed maneuvers, with the entire assembly weighing under 1.5 . It is hydraulically actuated via a pull-type paddle on the , with electronic control integrated into the FIA Standard . To enhance safety and reliability, an anti-stall system integrated into the automatically intervenes if engine speed drops critically, fully disengaging within 10 seconds and initiating an engine shutdown to prevent uncontrolled movement in accidents. This software-controlled feature activates only on high driver input demand (>95% pedal) and remains disengaged until manual reset, ensuring compliance with survival cell access protocols. integrates seamlessly with the rear-mounted semi-automatic sequential gearbox, facilitating quick shifts without driver intervention beyond initial actuation. The is a mechanical limited-slip type, adjustable via preload and ramp angles to manage distribution between the rear s, preventing excessive under . Adjustable preload applies constant bias to both s even off-, while ramp angles determine progressive locking on-, enabling up to 80% lock for superior corner-exit traction by transferring power to the outer with . Adjustments are made via preload (constant bias ) and ramp angles (progressive locking under ), set before each event. This setup optimizes stability without relying on prohibited active yaw or traction control systems, as electronic inputs are limited to position via the FIA . Torque vectoring occurs passively through differential bias, directing more torque to the faster-rotating outer wheel during cornering to reduce understeer and enhance turn-in response, thereby improving overall handling stability on varied track surfaces. Durability is mandated by requiring the gearbox assembly—including clutch and differential—to endure at least six consecutive events (practice, qualifying, and race) before replacement, with unauthorized changes resulting in a five-place grid penalty to promote reliability and cost control. The 2026 regulations maintain an 8-speed gearbox with a minimum driveline mass of 22 kg and require steel driveshafts, supporting overall chassis weight reductions.

Aerodynamics

Wing assemblies

Wing assemblies in Formula One cars are critical aerodynamic components that generate to enhance and , primarily through the front and rear wings. These structures are meticulously designed to balance and , influencing the car's overall on the . The wings interact with to create high-pressure differences, directing air efficiently while complying with strict dimensional and material regulations set by the FIA. The front wing typically features a three-element , consisting of a main and two flaps, which allows for precise management of over the car's . Endplates at the outer edges of the wing direct high-pressure air away from the wheels and toward the sides of the car, reducing and optimizing to downstream components. This configuration generates approximately 30% of the total on an F1 car, significantly contributing to front-end grip during cornering. The rear wing employs a multi-element setup, with up to four profiles arranged in two closed sections per FIA regulations, to maximize at the rear axle for balanced handling. The uppermost flap integrates the (DRS), which opens by a maximum of 85 mm when activated, creating a slot gap that reduces drag by 20-25% at speeds exceeding 250 km/h. This adjustment allows pursuing drivers to gain straight-line speed for maneuvers within designated zones. Adjustments to flaps are limited to maintain fairness, particularly during conditions after qualifying, where only the front can be tweaked using existing parts to fine-tune aerodynamic without altering other bodywork. The rear 's DRS flap, mandatory on all cars since its introduction in 2011, is electronically controlled via the and deactivates automatically outside activation zones or below the speed threshold. These restrictions ensure competitive equity while permitting strategic adaptations. Wings are constructed primarily from carbon fiber composites, selected for their high strength-to-weight ratio and ability to withstand extreme aerodynamic loads. To prevent unfair advantages from excessive flexibility, the FIA enforces rigorous compliance tests on wing profiles, including deflection limits under specified loads—for instance, a maximum 5 mm vertical deflection for front wing flaps under 60 N and 7 mm horizontal for rear wing flaps under 500 N. These static tests verify that wings maintain their designed shape during dynamic track conditions. Looking ahead to 2026, active will introduce movable front and rear wings with rotation systems, replacing the to enable driver-controlled adjustments in zones for enhanced race dynamics. These systems, including X-mode actuators, will allow rear wing flap opening in a low-drag configuration while maintaining fail-safes to the high-downforce position, promoting more agile and efficient management.

Underbody and ground effects

The underbody of a Formula One car, particularly since the 2022 technical regulations, relies heavily on ground effect aerodynamics to generate downforce through low-pressure suction created by accelerating airflow beneath the vehicle. This design reintroduces Venturi tunnels integrated into the floor, which narrow the airflow path to increase velocity and reduce pressure, drawing the car toward the track surface. The floor structure, defined by a reference plane starting 650mm forward of the front wheel axis and extending rearward, forms these tunnels with strict dimensional limits, including a maximum floor width of 2000mm and edge radii not exceeding 100mm. In practice, these underbody elements can contribute up to 60% of the car's total downforce while producing minimal drag compared to wings. At the rear, the diffuser plays a critical role in managing the expanding airflow from the Venturi tunnels, featuring a multi-vane to optimize exhaust and recover efficiently. The diffuser's design is constrained by regulations, including a maximum height of 150mm at the and an exit width narrowed to 750mm from previous eras, ensuring controlled expansion without excessive turbulence. Up to four vanes per side help seal the low-pressure region, enhancing suction while adhering to flexibility tests that limit deflection under aerodynamic loads. Sidepods and bargeboards direct high-pressure air around the Venturi channels, minimizing interference and feeding clean flow to the underbody for optimal performance. These components, positioned forward of the floor edges, create vortices that seal the tunnels against ground proximity losses. Compliance with ground clearance is enforced via plank wear checks on a 10mm-thick wooden assembly spanning 1030mm longitudinally. The plank, measured at six points for no more than 1mm wear post-race, prevents teams from running excessively low setups that could amplify ground effects unsafely; titanium skid blocks embedded within it limit total area to 24,000mm². Early 2022 implementations of these effect designs led to porpoising, an oscillatory bouncing from aerodynamic sensitivity to variations, prompting FIA interventions. To mitigate this, 2023 regulations banned excessive flexibility—termed "flexi-floors"—by raising edges 15mm, increasing diffuser throat height by 10mm, and imposing stricter deflection limits (maximum 2mm under 5000N load). These changes reduced porpoising risks while preserving core effect principles, as confirmed by post-season technical directives. Looking ahead, the 2026 regulations will simplify underbody designs to promote closer racing, narrowing maximum floor width by 150mm and introducing in-washing wheel configurations with wake control boards on sidepods to clean airflow and reduce dirty air wakes. This shift aims for less aggressive Venturi profiles, balancing with improved following capabilities without fully abandoning ground effects.

Suspension and steering

Suspension components

Formula One cars employ a system at all four s, utilizing independent upper and lower wishbones to precisely control movement and maintain contact with the track. This setup is typically configured with either pushrod or pullrod linkages front and rear, where the pushrod design mounts the rod higher on the and lower on the assembly to push against the spring and during compression, while the pullrod variant reverses this orientation to pull the components. Teams select these configurations based on aerodynamic packaging and center-of-gravity optimization; for instance, many opt for pushrod at the front and pullrod at the rear to lower the for better airflow. The geometry of these systems incorporates anti-dive and anti-squat characteristics to minimize changes under braking and acceleration, respectively, by directing forces through the to counteract movement and preserve aerodynamic stability. Anti-dive at the front elevates the instant center to reduce nose dive, while rear anti-squat geometry raises the driveline to limit squat, allowing stiffer setups without excessive variation. Inboard dampers, often supplied by Sachs or Penske, are mounted centrally on the for protection and adjustability, featuring hydraulic systems that allow real-time tuning of and rates via cockpit controls or pit adjustments. A third element, typically a or spring-damper linking the front or rear , provides heave control by decoupling vertical body movement from individual , ensuring consistent platform attitude under varying loads. Kinematic optimization focuses on and curves generated during travel, ensuring the remains optimal through corners by inducing negative gain to counter body roll and adjustments for balanced slip angles. These curves are engineered via pivot points and rocker linkages, simulated to maximize lateral without compromising straight-line . Since the FIA banned systems in 1994—citing safety risks from high cornering speeds and potential failures—F1 relies on passive setups fine-tuned for each track's demands, balancing stiffness for with for bump absorption. Under the 2026 regulations, suspension arms will be narrower to accommodate the slimmer car profile, with overall width reduced by 100 mm to 1900 mm and track widths adjusted accordingly, promoting more agile handling and closer racing.

Steering wheel and controls

The steering wheel in a Formula One car serves as the primary interface between the driver and the vehicle, integrating directional control with a complex array of electronic and mechanical adjustments essential for high-speed . Constructed primarily from carbon fiber for its lightweight strength and durability, the wheel incorporates hundreds of components, including fibreglass, , , and elements, allowing it to withstand extreme forces while remaining compact at approximately 28 cm in diameter. Custom-molded grips, made from varying rubber compounds, provide vibration-dampening and ergonomic fit tailored to each driver's hands, which can be adjusted during the season to optimize comfort and feedback under g-forces exceeding 5g. Modern F1 steering wheels feature over 20 buttons, switches, and dials, transforming the device into a multifunctional command center that enables real-time adjustments without diverting the driver's focus from the . Key controls include the "Strat" switch for managing Energy Recovery System (ERS) modes, such as deploying or harvesting energy from the MGU-K and MGU-H units to optimize power output; a pit limiter that caps speed at 60 km/h (37 mph) during pit lane entry, or 80 km/h (50 mph) at select circuits as per FIA approval; a dedicated () activation to open the rear wing flap for ; and a drink that pumps hydration fluid—typically an electrolyte mix—from a rear-mounted pouch through a tube to the driver's mouth, crucial for maintaining performance in races lasting up to two hours. Rotary dials and scroll knobs allow precise tuning of brake bias, distributing braking force between front and rear axles in increments to suit conditions, and differential settings for distribution across entry, , and exit phases of corners, enhancing traction and stability. A quick-release mechanism, featuring a concentric on the , facilitates rapid attachment and detachment, enabling drivers to enter and exit the in under five seconds during emergencies or qualifying sessions. Power steering in F1 cars employs a system integrated with the car's overall for the and , driven by an engine-powered to provide variable assistance that reduces steering effort without , as mandated by regulations to preserve direct . This setup delivers up to 20 of assistance, allowing drivers to manage the immense —up to 4,000 pounds at high speeds—while maintaining precise and road feel, particularly in low-speed corners where steering loads peak. The , integrated into the steering wheel's central , provides critical through a high-contrast LCD screen and LED arrays, including RPM indicated by 15 color-coded shift lights that illuminate progressively to signal optimal upshift points, current gear position, and sector-specific lap times with comparisons to the driver's best or team target. Additional such as battery charge and ERS status is shown, ensuring drivers can react instantly to performance metrics. For the 2025 season, F1 requires driver cooling systems when a heat hazard is declared by the FIA (typically for ambient temperatures ≥31°C), to combat extreme heat conditions, using a liquid-cooled vest with tubing to circulate cooled fluid, powered by a , increasing the minimum mass by 5 kg (to 805 kg) to accommodate the hardware. This update enhances driver endurance in hot climates, directly influencing steering inputs by reducing physical .

Tyres and braking

Tyres and wheel rims

has been the sole tire supplier for since 2011 and will continue until at least 2027, providing all tires used in the championship. The tires are designed specifically for the series, with 18-inch wheel rims introduced in 2022 to improve aesthetics and handling by reducing sidewall flex. Front tires measure 305 mm in width, while rear tires are 405 mm wide, both with an overall diameter of 720 mm to fit the rim size. For dry conditions, offers six slick compounds labeled C1 through C6, where C1 is the hardest and most durable for high-abrasion tracks, and C6 is the softest for maximum grip on low-wear circuits. selects three of these compounds for each weekend, nominated as hard (white sidewall), medium (yellow), and soft (red), to suit the track characteristics. Each driver receives 13 sets of dry slick tires per standard race weekend, comprising two sets of hards, three mediums, and eight softs, though allocations adjust slightly for sprint weekends to 12 sets total. Regulations require drivers to use at least two different dry compounds during a dry race, promoting strategic variety in stops and tire management. Slick tires feature a smooth treadless surface to maximize and on dry . For wet conditions, tires have a partial tread pattern with shallower grooves covering about 20% of to disperse standing up to 3 mm deep, while full wet tires include deeper, circumferential grooves occupying 29% of to handle heavier rain exceeding 4 mm depth. Each driver gets four sets of s and three sets of full wets per weekend. Tire pressures are closely monitored, with minimum starting pressures set at approximately 23 for rears and 25 for fronts, adjusted per event by based on track data to prevent overheating and ensure safety. Wheel rims, constructed from AZ70 or AZ80 for strength and lightness, must comply with FIA specifications, excluding the . These rims include integrated components like drive pegs, spacers, and sensors, and are fitted with aerodynamic covers. To optimize , teams use electric warmers that heat s to 70-100°C before installation, reducing initial lap time losses from cold rubber. Looking ahead to 2026, the 18-inch rim size will remain unchanged, but tire widths will narrow by 25 mm at the front (to 280 mm) and 30 mm at the rear (to 375 mm) to reduce overall car weight and drag. will emphasize sustainable rubber compounds, incorporating more recycled and bio-based materials to align with Formula One's environmental goals while maintaining performance.

Brake systems

Formula One cars employ advanced carbon-carbon disc brake systems designed for extreme deceleration forces, capable of slowing vehicles from speeds exceeding 300 km/h to a standstill in seconds. The brake discs measure up to 330 mm in diameter for the fronts (typically 328 mm) and up to 280 mm for the rears, with a maximum thickness of 32 mm, constructed from carbon-carbon composite materials that provide superior heat dissipation and structural integrity under high thermal loads. These discs are paired with matching carbon-carbon pads, which generate friction through interleaving layers of to manage heat buildup and prevent fade during prolonged use. The , typically six-piston designs supplied by manufacturers such as or AP Racing, clamp the discs with aluminum housings reinforced for rigidity, ensuring precise modulation of braking force. The system withstands operating temperatures up to 1000°C during intense braking zones, where kinetic energy is rapidly converted to heat; carbon-carbon materials excel here by increasing friction coefficient as temperatures rise, unlike steel brakes that suffer from thermal expansion issues. Brake-by-wire technology, introduced in 2014 to accommodate hybrid energy recovery, controls the rear axle hydraulically via electronic actuators integrated with the engine control unit, allowing dynamic adjustment without a direct mechanical linkage from the pedal. This setup provides ABS-like modulation to prevent wheel lock—full anti-lock braking remains banned under regulations—while maintaining driver feel through a hydraulic front circuit. Cooling is achieved through ducts channeling air from the front wing endplates directly to the brake assemblies, optimizing airflow to dissipate heat without compromising aerodynamic efficiency; teams adjust brake bias electronically, typically distributing 50-65% of force to the front axle for balanced stopping. During braking, the motor generator unit-kinetic (MGU-K) harvests up to 120 kW of electrical energy from the decelerating wheels, supplementing the mechanical braking action. durability is engineered for 300-500 km of track use before replacement, with interleaving in the carbon matrix aiding fade resistance by promoting even heat distribution and minimizing surface glazing. Overall braking performance is ultimately constrained by tire grip limits, where maximum deceleration—often exceeding 5g—is achieved just before the onset of wheel lock.

Electronics

Engine control unit

The Standard Electronic Control Unit (SECU), supplied by McLaren Applied Technologies since 2008 with the supply contract extended by the FIA until 2030, serves as the centralized electronic system managing the Formula One car's power unit operations, ensuring uniformity across all teams through FIA-mandated standardization. This unit processes inputs to regulate critical functions such as fuel injection, limited to a maximum flow of 100 kg/h, ignition timing with one coil and spark plug per cylinder, and turbocharger boost pressure via the Motor Generator Unit for Heat (MGU-H), which maintains a fixed speed ratio up to 125,000 rpm. Communication between the SECU and other vehicle systems occurs over a Controller Area Network (CAN) bus, enabling real-time data exchange for power unit control, energy recovery systems, and transmission management while adhering to FIA-approved wiring protocols. To promote performance parity, the SECU's core is frozen and homologated by the FIA, with identical base software provided to all competitors and limited updates permitted—up to five team applications per season in 2025—requiring submission of for approval. Teams may overlay developed in-house or by third parties atop this standard framework to optimize race strategies, such as energy deployment and shift points, without altering the underlying hardware. Since 2008, traction control has been prohibited through the standardized to emphasize skill, though launch control modes and anti-stall functions remain permitted to prevent shutdowns during starts or low-RPM scenarios. The SECU incorporates advanced diagnostics for real-time fault detection, monitoring hybrid modes including MGU-Kinetic (MGU-K) limits up to 200 Nm and energy store charge deltas, as well as gear shift sequences to ensure compliance and safety. It logs extensive data accessible to the FIA for scrutineering, including readings from driveshafts, and provides unlimited access during events. For the 2026 regulations, the ECU will be updated to integrate of active , such as driver-adjustable front and rear wing flaps, alongside enhanced electric power management with MGU-K output increased to 350 kW, replacing systems like . Data from the SECU is also fed to the display for driver feedback on power unit status.

Sensors and data systems

Modern Formula One cars are equipped with approximately 300 sensors that monitor a wide array of performance parameters during race weekends as of 2025. These include accelerometers to measure g-forces experienced by the car, gauges on components to assess structural loads, and GPS units for precise mapping and positioning. Additional sensors track temperatures and s to optimize and , aerodynamic loads on wings and bodywork via and measurements, and fuel usage through flow meters to ensure . The data collected by these sensors is transmitted wirelessly to the pit wall at a rate of approximately 2 Mbps, enabling by engineers. This stream includes critical metrics such as tire conditions, aerodynamic performance, and fuel consumption, allowing teams to make immediate adjustments to car setup or . Onboard, an integrated captures this information for deeper post-session review, with systems like McLaren Applied's ATLAS handling over 1,000 channels at sampling rates up to 1,000 Hz to preserve high-fidelity records. The FIA mandates standardized data logging through the ECU to ensure compliance with technical regulations, requiring cars to record at least two hours and fifteen minutes of per session without interruption. Teams supplement this with proprietary to refine and aerodynamic setups, processing the raw feeds into actionable insights for gains. For 2025, regulations have expanded participation in free practice sessions to two per car, doubling the track time and associated data logging opportunities during testing to support and team evaluation. inputs are briefly processed by the ECU for basic control functions before full transmission.

Performance

Power and speed capabilities

Modern Formula One cars in 2025 are equipped with hybrid power units that deliver a total output of approximately 1,000 horsepower (746 kW), combining the internal combustion engine's roughly 700 horsepower with contributions from the Energy Recovery System (ERS), which adds up to 160 horsepower during peak deployment. This power enables straight-line performance that pushes the limits of , with top speeds routinely exceeding 360 km/h on long straights like those at , where the 2025 record reached 365 km/h set by . Acceleration is equally impressive, with cars achieving 0-100 km/h in about 2.6 seconds and 0-300 km/h in approximately 7-8 seconds, aided by the low-drag configuration activated by the (DRS), which opens the rear wing to reduce aerodynamic resistance. The DRS mode lowers the from around 0.9 in high-downforce race trim to approximately 0.7, allowing for quicker straight-line bursts while maintaining overall efficiency. Fuel efficiency remains a critical factor under the 110 kg race fuel limit, enabling cars to cover typical Grand Prix distances of about 305 km on that allocation, equivalent to roughly 2.77 km per kg of fuel. Looking ahead to 2026 regulations, power output is projected to stay similar at around 1,000 horsepower, but with a 30 kg reduction in minimum car weight to 768 kg, potentially enhancing further.

Handling and track performance

Formula One cars exhibit exceptional handling on circuits, characterized by their ability to generate high lateral g-forces during cornering, often exceeding 5g at the apex of demanding turns such as Suzuka's Turn One or Spa's Eau Rouge. These forces arise from the integration of aerodynamic downforce, tire grip, and suspension tuning, pushing drivers sideways with intensity equivalent to several times their body weight. Teams fine-tune the car's aerodynamic balance—primarily through front and rear wing adjustments—to manage oversteer (rear-end sliding) or understeer (front-end pushing), ensuring neutral handling that optimizes cornering speed and stability. This balance is critical, as an imbalance can lead to loss of control, with aero setups often biased toward slight understeer for high-speed stability. Braking performance further enhances track capability, allowing cars to decelerate from 100 km/h to 0 in approximately 15-20 meters while entering corners at speeds over 250 km/h, such as the approach to Silverstone's Copse or 's Lesmo curves. This rapid slowdown, achieved through carbon-ceramic brakes and aero-assisted deceleration, enables precise into turns, where weight distribution aids in maintaining balance by shifting load forward for better front grip. Overall lap times reflect these dynamics, with pole positions like the 1:19.555 set by at in 2021 serving as benchmarks influenced by track surface evolution—such as resurfacing that increases grip over sessions—and regulatory changes like tire compounds or aero restrictions. Setup configurations involve key trade-offs tailored to circuit demands, with high-downforce packages—featuring larger wings and diffusers—deployed at tight, low-speed tracks like to maximize cornering grip, often at the expense of straight-line speed. In contrast, low-downforce setups prevail at high-speed venues like Spa-Francorchamps, prioritizing reduced drag for faster sectors while accepting marginally lower cornering limits. is evaluated through sector times, which isolate handling in specific portions, allowing teams to quantify trade-offs like a 0.2-0.5 second gain in twisty sectors versus losses on straights. The reintroduction of ground-effect aerodynamics in 2022 marked a significant evolution in handling, aiming to enhance close racing by reducing dirty air sensitivity and improving following distances to under one second. However, initial implementations triggered porpoising—a bouncing that caused rapid fluctuations in and load—reducing during braking and direction changes, particularly on high-speed straights where cars could jump up to 40 mm at 300 km/h. By 2023-2025, regulatory tweaks like height limits and team adaptations mitigated these issues, restoring consistent and enabling more aggressive overtaking without excessive performance loss.

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