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In motorsports, the fastest lap is the quickest lap run during a race. In some racing series, like NASCAR, the fastest lap awards championship points for a driver or team. In Formula One and MotoGP no point is awarded for the fastest lap.

Formula One

[edit]
Main article: List of Formula One drivers who set a fastest lap

In Formula One, 141 different drivers have made fastest race laps. Michael Schumacher holds the record for the highest number of fastest laps with 77, followed by Lewis Hamilton with 68. Since 2007, the DHL Fastest Lap Award is given to the driver with the most fastest laps in a season.[1]

Between 1950-1959 and 2019-2024, an extra point was given to the driver who recorded the fastest lap during a race.[2] Between 2019 and 2024, the point could only be awarded if the driver achieving the fastest lap finished the race in 10th position or better.[3] The point has been discontinued for the 2025 season.[4]

Fastest laps are often set during the final laps of a race. Lap times often decrease as tracks get "rubbered in" and fuel weights go down as a race progresses.

Top ten drivers in Formula One history with the most fastest laps

[edit]
Bold Driver has competed in the 2025 season
Driver Fastest laps
1 Germany Michael Schumacher 77
2 United Kingdom Lewis Hamilton 68
3 Finland Kimi Räikkönen 46
4 France Alain Prost 41
5 Germany Sebastian Vettel 38
6 Netherlands Max Verstappen 36
7 United Kingdom Nigel Mansell 30
8 United Kingdom Jim Clark 28
9 Spain Fernando Alonso 26
10 Finland Mika Häkkinen 25
Source:[5]

Formula One performance hybrid racecar

[edit]

In recent studies the LeMans endurance project has been reconfiguring Formula One racecars and making them faster by reconfiguring powertrain configurations. These powertrain reconfigurations have drastically been able to cut the time of the fastest lap achievable by Formula One racecars. This team also studied the capabilities of Formula One racecars and studied how to improve the performance of the cars. Ultimately they designed a powertrain configuration that cut the fastest lap time achievable by a standard Formula One racecar by over 20 seconds.[6]

Formula One aerodynamics studies

[edit]

A researcher at Durham University studied the aerodynamic effects on Formula One racecars and how to make them more efficient and ultimately faster. A Formula One racecar's lap time advantage is the result of the cornering performance of the vehicle. If the tyres can have more grip there would be more friction and less slippage which would allow the car to go faster through corners, and subsequently decrease the time it takes to complete a lap. Also if the powertrain had more power and if the car experienced less drag then it could achieve a faster lap time.[7]

NASCAR

[edit]

In NASCAR, drivers in all three premier series (Cup, Xfinity and Truck) will have a chance to earn the Xfinity Fastest Lap Award. The award is given to the driver with the fastest lap in a race.[8]

Grand Prix motorcycle racing

[edit]
See also: List of 500cc/MotoGP riders who set a fastest lap

In Grand Prix motorcycle racing, which includes the 80cc, 125cc, 250cc, 350cc, 500cc, Moto3, Moto2 and MotoGP classes, Giacomo Agostini holds the record for the most fastest laps with 117, Valentino Rossi is second with 96 fastest laps and Marc Márquez is third with 88.

Top ten riders in Grand Prix motorcycle racing with the most fastest laps

[edit]
Bold Rider still competing in Grand Prix motorcycle racing as of the 2025 season
Rider Fastest laps
1 Italy Giacomo Agostini 117
2 Italy Valentino Rossi 96
3 Spain Marc Márquez 88
4 Spain Ángel Nieto 81
5 United Kingdom Mike Hailwood 79
6 Spain Dani Pedrosa 64
7 Australia Mick Doohan 46
8 Italy Max Biaggi 42
9 Spain Jorge Lorenzo 37
10 United Kingdom Phil Read 36
Source:[9]

Autocross

[edit]

Autocross is a competition normally conducted by a single vehicle and driver on an open paved surface where the driver races against the clock while trying to achieve the fastest lap possible. In autocross drivers can learn how to achieve a faster lap through studying data of their vehicles.[10] This data can be collected by many various systems and analyzed to produce faster more aerodynamic vehicles.

See also

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References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Fastest lap

View on Grokipedia
from Grokipedia
In , particularly (F1), the fastest lap refers to the single lap completed in the shortest time by any driver during the race. This metric captures the peak pace of a driver and car under race conditions, influenced by factors such as tire wear, fuel load, track traffic, and strategic pit stops, distinguishing it from pre-race qualifying times. The fastest lap has long been a celebrated in F1, with one such lap recorded per race since the championship's inception in 1950, though its formal recognition evolved over time. From 2019 to 2024, the FIA awarded an extra point to the driver achieving the fastest lap, but only if they classified in the top ten at the race finish; this incentive was removed for the 2025 season to refocus on overall race and reduce artificial late-race risks. Independently, the Fastest Lap Award—introduced in 2007—honors the driver who secures the most fastest laps across the season, emphasizing consistent speed and has been won by notable figures like and . Beyond points and awards, the fastest lap serves as a benchmark for technological and driver skill advancements. In broader contexts, such as racing or other FIA-sanctioned series like , the concept similarly denotes the minimum lap time in an event, often tied to bonus points or accolades under series-specific rules.

General Concepts

Definition and Measurement

In , the fastest lap refers to the single quickest timed circuit completed by a during a race, measured from the start-finish line to the same point after traversing the full track length. This metric captures the peak performance of a or under race conditions, excluding any practice or test sessions unless specified by the . The lap time is calculated by recording the elapsed duration for one complete loop, ensuring consistency across all competitors on the same circuit. Measurement of the fastest lap relies on advanced electronic timing systems to achieve high precision. Modern series, such as and MotoGP, employ transponders mounted on vehicles that communicate with trackside beacons to log split times at designated points, culminating in a total lap duration accurate to 0.001 seconds. Onboard and GPS systems further enhance data collection by providing real-time synchronization and redundancy, allowing officials to verify times against multiple sources. These technologies, mandated by international regulations, minimize and ensure tamper-proof recording. Variations in fastest lap measurement occur across disciplines due to differences in track design and event formats. Shorter circuits, like Monaco's 3.337 km layout, typically produce lower absolute times compared to longer tracks such as Spa-Francorchamps at 7.004 km, influencing strategic approaches but not the core timing method. A key distinction exists between the race fastest lap—set during competitive racing—and the qualifying pole time, which is the quickest single lap in a dedicated session but may not count toward race awards in all series. Circuit-specific factors, such as weather or periods, can affect eligibility, but the fundamental measurement remains standardized. The evolution of fastest lap timing has progressed from rudimentary methods to sophisticated automation. In the early , officials used manual stopwatches to approximate lap times during events like the , often leading to inaccuracies of several seconds. By the 1950s, photoelectric cells and basic electronic timers were introduced in major series, improving reliability. The widespread adoption of automated systems in the 1990s, driven by organizations like the FIA, revolutionized precision, enabling the sub-millisecond accuracy seen today.

Significance in Motorsport

The fastest lap serves as a key indicator of peak performance for both driver and car during a race, highlighting the optimal combination of speed, handling, and strategy under varying conditions. In several motorsport series, it carries strategic value through bonus points awarded to the driver and team, such as the one point granted in Formula 1 from 2019 to 2024 for the fastest lap if the driver finished in the top 10—a rule that added a tactical layer by incentivizing late-race pushes or defensive maneuvers to deny rivals. Similarly, NASCAR introduced a bonus point for the fastest lap in all national series starting in 2025, rewarding outright pace regardless of finishing position and influencing points standings in close championships. Setting the fastest lap often provides a psychological boost to drivers, enhancing morale and confidence that can translate into sustained competitive momentum during the race. This prestige influences battles, as the associated points can tip tight standings; for instance, analysis of past F1 seasons shows the bonus point could have altered outcomes in 2010, 2012, and 2016 if retroactively applied. In competitive scenarios, drivers have defied to chase it, creating added race intrigue and occasionally contributing to victories through heightened focus and risk-taking in the closing stages. Racing teams leverage fastest lap data extensively in post-race analysis to evaluate overall performance, dissecting telemetry such as braking points and acceleration to refine driver techniques and car setups. This information aids in optimizing vehicle configurations for future events, including adjustments to and management based on track-specific conditions. While the fastest correlates strongly with a team's race pace, it does not guarantee victory, as factors like pit strategy and traffic can override single-lap brilliance. Beyond the track, the fastest lap symbolizes engineering excellence, representing the pinnacle of vehicle design and in motorsport. Manufacturers often highlight lap records in to showcase advancements, drawing significant media and fan interest that amplifies the event's excitement and underscores the sport's technical allure.

Formula One

Historical Development

The concept of the fastest lap emerged as a key metric in the inaugural World Championship season of , where it was awarded an additional championship point to recognize outright pace alongside finishing positions. This bonus incentivized drivers to push for maximum speed even late in races, with setting the first official fastest lap at an average speed of 151.300 km/h during the at , contributing to his victory and eventual title win. Through the and into the , the award remained a championship factor until its removal after 1959, as rear-engine designs and improving tire technology gradually shaved seconds off lap records, though outright speeds were constrained by mechanical limitations and rudimentary aerodynamics. The marked a transformative shift with the advent of ground-effect , pioneered by type 78 car in 1977, which generated via underbody venturi tunnels to enhance cornering speeds without excessive drag. This innovation, refined in the of 1978, reduced average times by approximately three seconds at key circuits compared to prior years, as teams like Ferrari and adapted similar designs, elevating the pursuit of fastest laps amid rising safety concerns from higher cornering forces. The late also saw the introduction of turbocharged engines, starting with Renault's RS01 at the , which delivered bursts of over 500 horsepower and progressively faster qualifying and race laps through the , though reliability issues often limited their full exploitation in race conditions. By the 1990s, regulatory changes further influenced fastest lap dynamics, including the permanent introduction of the in 1993 at the , which bunched the field and enabled more controlled, aggressive stints post-deployment to chase records. The ban on refueling, implemented for the 2010 season to enhance safety and curb costs, eliminated lightweight early-race strategies, shifting emphasis to sustained pace over full fuel loads and altering when drivers could realistically set competitive fastest laps. Tire regulations evolved concurrently, with Pirelli's multi-compound mandate from promoting varied degradation profiles that rewarded precise management for optimal lap times on softer, faster rubber during key windows. In the modern era, the (DRS), debuted in 2011, permitted rear-wing flap activation in designated zones to boost straight-line speeds by up to 10-12 km/h, facilitating faster overall laps in scenarios while raising average race paces. The 2014 shift to 1.6-liter V6 turbo-hybrid power units integrated energy recovery systems, delivering over 900 horsepower with efficient deployment modes that sustained high lap speeds, though initial narrower tires kept times comparable to the V8 era before aerodynamic refinements accelerated records. These developments, alongside ongoing tire compound innovations, have continually redefined the balance between raw speed and strategic timing in setting fastest laps.

All-Time Records and Leaders

In , the all-time records for fastest laps are tallied exclusively from Grands Prix, where the official fastest lap is the quickest time set during the race by any driver, regardless of finishing position. These records highlight drivers' ability to extract peak performance under race conditions, often on fresher tires toward the end of the event. As of the 2025 season, maintains the outright lead, a testament to his consistency across two dominant eras with Benetton and Ferrari. The following table lists the top ten drivers by total fastest laps achieved in championship races:
RankDriverTotal Fastest LapsPrimary Teams Involved
177Benetton, Ferrari
268, Mercedes, Ferrari
346, Ferrari, Lotus
441, Williams,
538, Ferrari
635
730Williams, Ferrari
828Lotus
926, , Ferrari
1025
These figures reflect cumulative achievements through the 2025 , with notable additions in recent years; for instance, secured one more in 2025 (Singapore), while and each claimed several, including Norris's at . Circuit-specific lap records evolve with track resurfacing, configuration changes, and technological advancements, often being broken multiple times per decade. For example, at , the 2020 race fastest lap of 1:22.746 by was surpassed in the 2025 when set 1:20.901 aboard a . The Spa-Francorchamps race lap record stands at 1:44.701 by Sergio Pérez in 2024, improving on prior benchmarks like Daniel Ricciardo's 1:47.483 from 2020; these shifts underscore how even historic venues like (current record: 1:27.097 by , 2020) see incremental improvements. Among teams, Ferrari demonstrates unparalleled dominance, accumulating over 200 fastest laps across its history, far surpassing rivals like Mercedes (113 as of 2023, with additions in 2024-2025 via Hamilton and Leclerc). This longevity stems from the team's consistent competitiveness since 1950. Seasonal highs further illustrate peaks in performance; the 2004 and 2008 seasons saw drivers claim 10 fastest laps each (Schumacher and Räikkönen, respectively), while 2021's expanded 22-race calendar featured intense competition, with Mercedes and Red Bull together securing 18 of them amid tire management strategies that favored late-race pushes. In 2025, McLaren led the DHL Fastest Lap Award tally with contributions from Norris and Piastri across multiple rounds, reflecting the team's resurgence. Notably, Max Verstappen set the outright fastest qualifying lap in F1 history at the 2025 Italian Grand Prix with a time of 1:18.792.

Technological Factors

Engineering advancements in aerodynamics have been pivotal in enhancing Formula One cars' ability to achieve faster lap times, primarily through innovations that optimize downforce while managing drag. The introduction of ground effect aerodynamics in the 1970s, exemplified by the Lotus 78 and 79 models, revolutionized underbody airflow to generate substantial downforce without relying heavily on wings, leading to significant improvements in cornering speeds and overall lap performance. These designs created low-pressure zones beneath the car, allowing higher speeds through turns and reducing lap times by several seconds on circuits like Monza compared to pre-ground effect eras. Subsequent developments, such as rear diffusers, further amplified this effect by accelerating exhaust airflow under the car to increase downforce, particularly in high-speed sections, enabling lap time gains of up to 0.5 seconds per corner in modern applications. Wing configurations, including front and rear aerofoils, involve critical trade-offs between downforce for grip and drag that limits top speed; teams adjust flap angles and endplate shapes to balance these forces, prioritizing downforce on twisty tracks like Monaco while minimizing drag on straights-heavy layouts like Monza. The evolution of power units has also directly contributed to lap time reductions by providing more efficient and deployable . The shift from naturally aspirated 2.4-liter V8 engines, which produced around 750-800 horsepower, to the 1.6-liter V6 turbocharged hybrid units introduced in marked a major leap, incorporating systems that boost total output beyond 1,000 horsepower. The MGU-K (Motor Generator Unit-Kinetic) component recovers braking and deploys up to 120 kW (approximately 160 horsepower) for about 33 seconds per lap, allowing strategic bursts in zones to shave fractions of seconds off sector times. Energy deployment strategies optimize this by mapping battery discharge to track-specific demands, such as full deployment out of slow corners, ensuring maximum power without exceeding or energy limits, which can yield lap time improvements of 1-2 seconds on energy-intensive circuits. Tire compounds and braking materials have similarly advanced to support sustained high-speed laps under extreme conditions. Since 2011, has supplied with a range of slick compounds (C1 to C6, from hardest to softest), tailored to track surfaces and temperatures, providing varying levels of grip that influence cornering speeds and degradation over a . These compounds, constructed with belts and silica-infused treads, enable precise handling that can reduce times by optimizing traction without excessive wear. Carbon fiber composite , standard since the , offer superior thermal resistance and lighter weight compared to , maintaining consistent stopping power from speeds over 300 km/h with deceleration rates exceeding 5g, thus minimizing time lost in braking zones. Simulations via testing and (CFD) form the backbone of processes that predict and refine lap times before on-track validation. Wind tunnels allow scaled models to be tested at speeds up to 200 km/h, measuring aerodynamic loads to correlate gains with projected lap simulations, often iterating designs hundreds of times per upgrade. complements this by solving Navier-Stokes equations numerically to simulate airflow around full-scale virtual cars, enabling predictions of drag reductions or increases that could translate to 0.1-0.5 second lap improvements per aerodynamic tweak. Teams allocate restricted hours—governed by FIA rules based on championship standings—to these tools, ensuring designs evolve efficiently toward faster laps.

NASCAR

Evolution in Stock Car Racing

The evolution of fastest laps in , particularly within , began in the post-World War II era when competitions transitioned from informal beach and dirt track events to structured racing. In the and , races were primarily held on short dirt s and the Daytona Beach-Road Course, where lap times were rudimentary and often not precisely timed due to limited technology. The introduction of superspeedway racing marked a pivotal shift, with the opening of in 1959 enabling the first official timed laps on a high-banked 2.5-mile paved . Qualifying speeds at the inaugural reached 143.148 mph, set by , establishing a benchmark for precision measurement and highlighting the potential for higher velocities on expansive tracks. From the 1960s through the 1970s, the proliferation of superspeedways like Talladega (opened ) pushed lap speeds higher, with qualifying times exceeding by the late 1970s, driven by unrestricted and aerodynamic advancements. However, safety concerns escalated as speeds approached dangerous levels, culminating in the 1980s with the modern stock car era's focus on regulation. Following Bobby Allison's catastrophic crash at Talladega in May 1987, which tore through catch fencing at over , mandated restrictor plates in 1988 for Daytona and Talladega to cap air intake and limit top speeds to around , fundamentally altering lap dynamics by emphasizing drafting over raw power. The 2013 introduction of the Generation-6 (Gen-6) car further refined lap performance by prioritizing production-based aesthetics and aerodynamic balance, reducing the "aero push" effect that hindered passing on intermediates and ovals. This design, with sleeker bodies and adjusted , enabled more consistent lap times across traffic, though it initially faced criticism for not fully resolving dirty air issues until subsequent packages were tuned. Track-specific evolutions underscore these changes: short ovals like (0.533 miles, high-banked concrete) demand aggressive braking and acceleration, yielding average race lap speeds of 120-130 mph, while intermediates like (1.5 miles) favor sustained high-speed cornering, with qualifying laps often surpassing 190 mph. Overall, average qualifying speeds have risen from approximately 150 mph in the to around 190-200 mph at restrictor-plate tracks as of 2025, reflecting iterative safety and performance tweaks. Rule changes in the amplified strategic emphasis on fastest laps. The adoption of stage racing divided events into three segments, awarding playoff points to the top-10 finishers per stage and incentivizing aggressive pushes for mid-race speed bursts to secure positions before mandatory cautions. Additionally, the prohibition on refueling outside designated pit stops—enforced even under caution—compels teams to balance loads with track position, often leading drivers to conserve early for potential late-race surges but risk slower laps if caught short. These reforms have heightened the tactical importance of fastest laps throughout races, beyond just qualifying or finales.

Notable Records and Drivers

In the , which has tracked performance since its inception in 1949, notable records for fastest laps often emphasize qualifying speeds, as these represent the single quickest timed laps under controlled conditions. holds the all-time record for most pole positions, with 123, showcasing his dominance in achieving the fastest qualifying lap across his career. follows with 22 poles, highlighting his prowess in high-speed setups during the and . These achievements underscore the skill required to consistently post the fastest lap times in qualifying sessions, which set the tone for race strategy on ovals of varying lengths. The all-time fastest qualifying lap remains Bill Elliott's 212.809 mph (44.998 seconds) at in 1987, a benchmark that exemplifies the peak speeds attainable in unrestricted qualifying eras. In race conditions, where drafting and traffic influence speeds, single-lap speeds at have approached 200 mph in points-paying events under pre-restrictor plate eras, though modern records are capped lower. For the specifically, Buddy Baker's 1980 victory stands as the fastest edition by average race speed at 177.602 mph, reflecting optimal conditions on the 2.5-mile superspeedway before modern restrictor plates altered dynamics. Seasonal records for most instances of setting the fastest lap in races have gained prominence with advanced timing data. exemplified consistency in 2007, his championship year, by posting competitive lap times that contributed to 10 wins and multiple track-speed benchmarks, though exact counts predate comprehensive digital tracking. In the modern era, led the 2025 season with 9 fastest race laps, including performances at Martinsville, Charlotte (Coca-Cola 600), , , Dover, , Gateway, Kansas (fall), and Phoenix (fall), aiding his strong championship contention. Hendrick Motorsports has established dominance in speed-related achievements, with drivers accumulating over 200 pole positions collectively and setting numerous track qualifying records. The organization led a record 443 laps in a single race at Martinsville in 2012, often correlating with superior lap pace, and continued this trend under the Next Gen car era starting in 2022. The Next Gen chassis, introduced in 2022, has narrowed lap time gaps across the field—reducing median speed differences by up to 0.45 seconds between top-10 and mid-pack cars—fostering closer competition while maintaining high overall velocities on intermediates and short tracks through 2025. Minor aerodynamic tweaks in 2025 further refined handling without drastically altering peak lap speeds. Key milestones include early sub-20-second laps at short tracks, achieved as far back as the at venues like (0.533 miles), where inaugural 1961 race laps averaged around 18 seconds under primitive conditions. The 2017 introduction of stage racing added incentives for pace, awarding points for stage wins often tied to fast laps. In 2025, NASCAR implemented a bonus point for the overall fastest race lap, granting one additional point in driver and owner standings to encourage aggressive speed throughout each of the 36 points-paying events.

Grand Prix Motorcycle Racing

Role in Two-Wheel Competition

In , particularly MotoGP, the concept of the fastest is adapted to the unique dynamics of two-wheeled vehicles, where extreme lean angles—often reaching up to 65 degrees—allow riders to navigate corners at higher speeds by lowering the center of gravity and enabling tighter racing lines that effectively shorten the path taken through turns compared to straighter four-wheeled trajectories. This influences overall times, as the measurement relies on bike-mounted transponders that detect passage over timing loops at the start/finish line, a system standardized in MotoGP since the to provide precise timing to the thousandth of a second across circuits. Strategically, fastest laps in MotoGP carry heightened importance due to the accelerated inherent to two-wheeled , where the narrower and dynamic weight transfer during leans amplify degradation compared to cars. With rates potentially doubling in high-stress corners, riders and teams prioritize compound selection—such as softer slicks for initial grip versus harder options for endurance—to optimize for a single flying lap, often pushing boundaries in the final stages of shorter events. This was notably amplified by the introduction of sprint races in 2023, which limit duration to around 30-40 minutes and reduce overall consumption, allowing competitors to sustain near-qualifying paces longer and frequently set fastest laps toward the conclusion as fresher rubber enables aggressive pushes without the full-race conservation typically required in grand prix events. Circuit-specific challenges further underscore the role of fastest laps in two-wheel competition, with many MotoGP tracks running anti-clockwise—such as , , and —featuring disproportionately more left-hand turns (up to 10 versus 5 rights in some cases), which unevenly stresses the left side of tires and relatively spares the right side, influencing setup choices for balanced wear during lap record attempts. Weather variability exacerbates these demands more acutely than in four-wheeled series, as open-cockpit bikes expose riders to rapid changes in grip from (necessitating wet tire swaps and flag-to-flag procedures), extreme heat (accelerating degradation in 35°C+ conditions), or wind (disrupting without the protective enclosure of ), often turning a single into a high-stakes test of adaptability. The evolution of fastest lap significance traces the technological shift from pre-2002 500cc two-stroke engines, which relied on and rider skill for peak performance without advanced aids, to the 1000cc four-stroke introduced in 2002 (initially at 990cc) and refined to 1000cc by , enabling smoother power delivery and faster times through improved and efficiency. Electronic aids like traction control, banned in the 500cc to preserve but reinstated and regulated in the MotoGP class for safety and competitiveness, have since modulated acceleration out of corners, allowing consistent fastest laps while preventing on high-power machines—though ongoing tweaks, such as the 2025 introduction of stability control, continue to balance innovation with rider involvement.

Leading Riders and Milestones

In the history of the premier class of , dating back to 1949, holds the all-time record for the most fastest laps with 88 as of the end of the 2025 season, achieved across multiple manufacturers including and . ranks second with 75 fastest laps, spanning and Yamaha. ranks third with 70, reflecting his dominance in the and on machines. The top ten all-time leaders in premier-class fastest laps emphasize the sport's evolution, with modern greats such as (46) and (44) from the 1990s-2010s, followed by (37), (30), and (29), showcasing international prowess. These figures are drawn from official FIM-sanctioned events, highlighting riders who consistently pushed lap times during races. Ducati riders have surged in recent years, with adding over 20 since 2022 amid the manufacturer's dominance. Márquez's 2025 Riders' Championship win further bolstered his record. Key milestones trace the progression of speed in the 500cc/MotoGP era. set one of the earliest notable fastest laps in the 500cc class during his 1951 World Championship-winning season on a Norton, contributing to his six career titles and marking a pivotal moment in post-war racing development. In modern times, set the 2024 Mugello race fastest lap of 1:45.770 on a , underscoring track-specific advancements in and . Seasonal achievements further illustrate individual peaks, with tying the record for most fastest laps in a single year at 12 during his undefeated 2014 championship campaign on Repsol Honda, where he won 13 races overall. and also achieved 12 in their dominant seasons (1968 and 2002, respectively). Team-wise, Repsol Honda amassed 195 fastest laps from 1995 to 2021 across riders like Rossi, Márquez, and , solidifying its legacy as the most successful outfit in premier-class history. Post-2023 updates reflect 's hegemony, with the manufacturer securing over 70% of fastest laps in 2024 across its satellite and factory teams, led by Bagnaia and ; this trend continued into 2025, where Márquez's tenure yielded multiple records, including at (1:45.704), challenging Honda's historical totals amid regulatory changes aimed at curbing single-manufacturer dominance.

Other Disciplines

Autocross Applications

Autocross events feature single-lap runs on compact courses delineated by traffic cones, typically measuring 0.5 to 1 mile in length and designed to last 40 to 60 seconds per run. Drivers navigate these courses individually in a non-contact format, with the —representing the best individual run time from a series of 4 to 6 attempts—serving as the primary metric for performance evaluation. This structure prioritizes precision maneuvering around obstacles over outright velocity, as courses incorporate tight slaloms, offsets, and sweeps that test vehicle handling limits without exceeding typical highway speeds of 55 to 60 mph. Vehicles are grouped into handicapped classes according to type, modifications, and performance potential, ranging from unmodified street cars in "Street" categories to heavily altered entries in "Modified" classes, with the PAX indexing system applied to equalize competition across disparate setups. Timing occurs with high precision to 0.001 seconds, facilitated by photocell beams or systems at the start and finish lines, ensuring objective measurement of elapsed time while accounting for penalties such as 2-second additions for displaced cones. The fastest lap holds critical importance in by determining class standings, qualifying positions for additional runs or national invitations, and overall event trophies, thereby underscoring driver skill in course memorization and execution over mechanical advantages or prolonged . Unlike multi-lap formats, emphasizes immediate adaptability and control, as drivers receive only a brief walking inspection before runs, fostering rapid learning and minimal reliance on sustained speed. Autocross traces its formalized origins to the Sports Car Club of America (SCCA) in the 1960s, evolving from earlier gymkhana-style time trials into structured "Solo" events by the early , with the inaugural Solo Nationals held in 1973. Digital timing systems, including photocell and early technologies, were widely adopted starting in the 1980s, replacing manual stopwatches to improve accuracy and efficiency in scoring large fields. Championships and records in remain focused on individual best-lap performances per event, without provisions for cumulative lap totals across sessions.

Open-Wheel Series Beyond Formula One

In open-wheel racing beyond , the NTT IndyCar Series stands as a premier North American championship, emphasizing high-speed ovals and technical road courses where fastest laps often exceed 220 mph on superspeedways like . On ovals, drivers achieve blistering pace due to drafting and unrestricted turbo boost, as seen at the , while road courses demand precise cornering with lap times influenced by hybrid energy deployment. For instance, the featured setting the fastest race lap at 226.006 mph on lap 40, highlighting the series' blend of raw speed and strategic fuel management. The , a of since its inception in , has tracked fastest laps officially from , with early races limited by technology to averages around 74 mph but evolving to record-setting bursts like Eddie Cheever's 236.103 mph in 1996. Drivers like exemplify longevity in pursuit of speed, securing 50 pole positions, including four at the Indy 500, through consistent qualifying dominance on ovals and road courses. IndyCar's evolution includes the 1996 split between the Indy Racing League (IRL) and (CART), which ran parallel open-wheel series until CART's bankruptcy in 2003 led to its rebranding as Champ Car, persisting until reunification in 2008 under the IRL banner. This era fragmented talent and innovation but spurred advancements in and engines, culminating in the 2024 introduction of a hybrid system to the 2.2-liter twin-turbocharged V6 power unit, adding up to 60 horsepower via and enabling combined boosts exceeding 120 horsepower with for faster acceleration out of corners. Beyond , the all-electric ABB FIA World Championship races on urban street circuits, where fastest laps prioritize energy efficiency over outright speed, with Gen3 cars reaching top velocities around 200 mph but lap times constrained by battery limits and attack mode boosts. Feeder series like FIA Formula 2 and Formula 3 serve as proving grounds for aspiring open-wheel talents, with Formula 3 lap times typically about 4-5% slower than Formula 2 on shared circuits, emphasizing close racing and overtakes in sprint formats.

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