Motorized bicycle
A motorized bicycle is a pedal-equipped bicycle augmented with an auxiliary motor—typically a small two-stroke or four-stroke internal combustion engine or an electric motor—coupled to a transmission for propulsion assistance or unassisted operation, retaining core bicycle components like frame, pedals, and chain drive.[1] These vehicles originated in the mid-19th century with steam-powered prototypes, such as Sylvester H. Roper's 1869 velocipede in the United States, and advanced with gasoline engines around 1901, enabling feats like George A. Wyman's 1903 transcontinental ride on a 200 cc, 1.5-horsepower model from San Francisco to New York City.[2] Distinguished from standard bicycles by motorized power and from mopeds by mandatory pedals, lower typical outputs (2-3 horsepower for gas models), and speeds capped around 20-25 mph, motorized bicycles emphasize fuel efficiency (100-150 miles per gallon for gas variants) and affordability, though varying regulations often hinge on power and speed thresholds rather than inherent design differences.[1] Post-World War II models like the American Whizzer and French VéloSoleX exemplified widespread adoption for economical urban mobility, bridging human-powered cycling and full motorcycles amid causal trade-offs in safety from bicycle-like vulnerability at elevated velocities.[2]Definition and Terminology
Core Definition and Classifications
A motorized bicycle is a pedal-equipped bicycle augmented with an auxiliary motor, either gasoline-powered internal combustion engine or electric, to supplement or replace human pedaling for propulsion. This configuration maintains the bicycle's lightweight frame and two-wheeled design while adding mechanical assistance, typically limited to low power outputs to preserve maneuverability and legal bicycle status in many regions. The motor engages via mechanisms such as friction drive against the tire, chain or belt transmission to the drivetrain, or direct wheel hub integration, enabling speeds beyond unaided pedaling without fully supplanting manual input.[3][4] Classifications of motorized bicycles primarily revolve around power source, assistance mode, and regulatory categories, which vary by jurisdiction but often hinge on empirical metrics like maximum speed, motor wattage or displacement, and pedal functionality. Gasoline-powered variants typically feature two-stroke or four-stroke engines with displacements under 80 cubic centimeters (cc), producing 1-5 horsepower, and rely on a fuel tank of 0.5-2 liters for ranges of 50-100 kilometers per tank. Electric models use battery-powered motors rated 250-1000 watts, with lithium-ion packs offering 20-100 kilometer ranges depending on capacity (e.g., 36-48 volt, 10-20 amp-hour batteries). Assistance modes distinguish pedal-assist systems, where the motor activates only during pedaling (often with torque or cadence sensors), from throttle-only controls that allow propulsion independent of pedals, the latter more common in gasoline setups for simplicity.[5][6] In the United States, electric motorized bicycles are standardized into three classes under guidelines adopted by most states since 2015, based on top assisted speed and control type:| Class | Description | Max Speed | Motor Power Limit |
|---|---|---|---|
| Class 1 | Pedal-assist only; motor disengages at speed limit | 20 mph (32 km/h) | 750 W (1 hp) |
| Class 2 | Throttle-assisted or pedal-assist; motor disengages at speed limit | 20 mph (32 km/h) | 750 W (1 hp) |
| Class 3 | Pedal-assist only; higher speed for capable riders | 28 mph (45 km/h) | 750 W (1 hp) |
Terminology Variations and Distinctions
A motorized bicycle is defined as a pedal-equipped bicycle augmented with an auxiliary motor—typically a small internal combustion engine displacing under 50 cubic centimeters or an electric motor rated at or below 750 watts—that provides propulsion assistance or independent drive, while retaining the core bicycle frame, wheels, and functional pedals for human-powered operation.[8] This contrasts with unassisted bicycles under standards like those from the International Organization for Standardization (ISO 4210), which exclude any motor integration.[9] Terminology variations include "motor-assisted bicycle," emphasizing the auxiliary role of the motor, and "power bicycle," a historical term for early 20th-century friction-drive models where the engine supplements rather than supplants pedaling. In electric contexts, "pedelec" specifies systems delivering motor torque proportional to pedal cadence, ceasing assistance above speeds like 25 km/h (15.5 mph) per European standards, distinct from throttle-equipped "S-pedelecs" that permit higher speeds up to 45 km/h (28 mph).[10] Gas-powered variants may be termed "cyclemotors" in older British usage, referring to clip-on engines like the Mitchell Power Pak from 1933, which attached via friction to the front tire. These terms highlight engineering emphases: auxiliary assistance preserves bicycle classification for lighter regulation, whereas full-motor reliance shifts toward vehicle status. Key distinctions arise from legal and functional criteria. Unlike mopeds, which derive etymologically from "motorized pedal" but often feature purpose-built frames, non-essential pedals, automatic transmissions, and engine limits of 50cc or 4 horsepower with top speeds under 30 mph (48 km/h), motorized bicycles prioritize convertible bicycle bases with operational pedals integral to primary propulsion.[11] [12] For instance, U.S. state laws like California's classify mopeds as motorized bicycles meeting specific low-power thresholds but require registration if exceeding bicycle exemptions, whereas DIY motorized conversions on standard bikes may evade moped rules if pedals remain primary below speed caps. Motorcycles, by contrast, lack pedals, employ engines over 50cc, and demand full licensing due to higher speeds exceeding 40 mph (64 km/h) and structural reinforcements absent in bicycle-derived designs.[8] Electric motorized bicycles further diverge via U.S. federal classifications under 15 U.S.C. § 2085: Class 1 offers pedal-assist only up to 20 mph (32 km/h); Class 2 adds throttle control to the same limit; Class 3 extends pedal-assist to 28 mph (45 km/h), all with motors under 750 watts, exempting them from motor vehicle regulations if pedals function.[13] Exceeding these—such as throttled electrics over 750 watts—reclassifies as mopeds or motorcycles, imposing helmets, licensing, and insurance, as causal dynamics of higher power demand enhanced safety controls to mitigate crash risks from inadequate bicycle braking at elevated velocities. Jurisdictional variance persists: European directives cap "light mopeds" at 4 kW electric power, blurring lines with high-end motorized bicycles.[14] These distinctions ensure regulatory alignment with empirical performance data, prioritizing pedal retention to affirm human oversight in propulsion.Historical Development
Early Concepts and Pre-20th Century Attempts
The earliest practical attempts to motorize bicycles occurred in the mid-19th century with steam engines attached to velocipedes, the precursors to modern bicycles. Sylvester H. Roper of Roxbury, Massachusetts, constructed one of the first such devices around 1867–1869, featuring a small steam engine mounted on a wooden velocipede frame with pedals.[2] This steam velocipede reportedly achieved speeds of up to 40 miles per hour but was limited by its heavy boiler, frequent need for water refills, and risk of explosion.[2] In France, similar experiments took place concurrently, with Louis-Guillaume Perreaux adapting a steam engine to Pierre Michaux's velocipede design by 1869, creating a two-wheeled steam vehicle capable of brief powered runs.[15] These devices prioritized propulsion over pedaling, though pedals remained for starting or emergencies, highlighting the conceptual shift toward mechanical assistance amid the limitations of human power alone. Later in the century, Lucius D. Copeland developed a steam-powered version of the American Star Bicycle in 1884, demonstrated at the first Arizona State Fair, where it featured a rear-mounted engine on the distinctive large-front-wheel frame.[16] This model reached speeds up to 40 mph in paced racing applications but suffered from operational complexities like constant stoking and poor reliability on uneven terrain.[17] Toward the 1890s, electric propulsion emerged as an alternative, with Ogden Bolton Jr. patenting a battery-powered rear hub motor for bicycles in 1895, though practical implementations remained rare due to heavy lead-acid batteries and limited range.[18] These pre-20th century efforts underscored the engineering challenges of integrating compact power sources with lightweight frames, often resulting in prototypes that were more novelty than viable transport.[19]20th Century Commercialization and Challenges
Commercial production of motorized bicycles gained momentum in the United States during the late 1930s with the introduction of clip-on engine kits, such as those from the Whizzer Motor Company, founded in 1939 as Breene-Taylor Engineering in Los Angeles.[20] These kits allowed users to attach small two-stroke engines, typically producing 1 to 2 horsepower, to standard bicycles, enabling speeds up to 30-40 mph with pedal assistance.[21] Post-World War II demand surged due to gasoline rationing and economic constraints, leading Whizzer to sell thousands of units annually by the late 1940s, often marketed through bicycle dealers like Schwinn under models such as the Pacemaker.[22] Production peaked in the 1950s before declining amid rising automobile affordability and stricter safety regulations. In Europe, France emerged as a hub for motorized bicycle innovation, with the VéloSolex debuting in 1946 from the Solex carburetor manufacturer.[23] Featuring a unique roller-driven 49cc two-stroke engine mounted above the front wheel, the VéloSolex emphasized simplicity, fuel efficiency (up to 100 mpg), and ease of pedaling without clutches or gears.[24] Over 7 million units were produced through the 20th century, finding popularity among urban commuters and exported to over 75 countries, bolstered by its lightweight design (around 65 pounds) and low operating costs.[23] Niche models like the French Derny, introduced in the 1930s for cycle racing pacing, utilized rear-mounted engines up to 98cc for tandem or solo use in velodrome events, though commercial sales remained limited to sporting applications until the 1950s.[25] Despite initial success, commercialization faced significant technical challenges, including engine reliability issues from vibration-induced failures in clip-on designs and friction drives prone to slippage in wet conditions.[26] Maintenance demands were high, with frequent carburetor clogging, spark plug fouling, and the need for two-stroke oil mixing, deterring widespread adoption beyond enthusiasts.[27] Market competition intensified from inexpensive automobiles and purpose-built mopeds like the Vespa scooter, which offered enclosed bodies and better weather protection, eroding the motorized bicycle's niche by the 1960s.[28] Regulatory hurdles further complicated growth, as varying classifications—sometimes as bicycles exempt from licensing, other times requiring motorcycle registration—created legal ambiguities and insurance barriers.[29] Safety concerns, including inadequate braking at motorized speeds and instability from added weight, prompted bans or restrictions in several jurisdictions, contributing to Whizzer's cessation of production in 1965.[20] Economic factors, such as rising fuel costs juxtaposed with improving mass transit, also limited scalability, though wartime fuel shortages had temporarily boosted demand.[26]21st Century Revival with Electrification
The 21st century witnessed a resurgence of motorized bicycles primarily through electric propulsion systems, evolving from marginal gasoline-engine attachments to widely adopted pedal-assist e-bikes. This revival stemmed from improvements in lightweight lithium-ion batteries and brushless DC motors, which addressed prior limitations in weight, range, and reliability that had constrained earlier models. By the early 2000s, these technologies enabled practical e-bikes capable of 20-50 km ranges on single charges, fostering commercial viability in markets prioritizing low-emission transport.[30][31] Market expansion accelerated in Europe and Asia during the 2000s, with China emerging as a production hub due to government subsidies for electric two-wheelers amid urban congestion and air quality concerns. Sales in the European Union benefited from classification standards like EN 15194, designating compliant e-bikes as regular bicycles exempt from motor vehicle licensing if limited to 250 W power and 25 km/h assisted speed. In the United States, similar regulatory frameworks under federal guidelines allowed e-bikes up to 750 W without registration in many states, spurring adoption for commuting and recreation. By the mid-2010s, global e-bike shipments exceeded 30 million units annually, reflecting demand driven by rising fuel costs and health initiatives promoting assisted cycling.[32][33] The 2020s further amplified this trend amid climate policies and post-pandemic shifts toward active transport, with e-bike revenue growing from $43.59 billion in 2023 to projected $148.70 billion by 2032 at a compound annual growth rate of approximately 17%. Advancements in torque sensors and integrated controllers enhanced natural pedaling feel, while modular battery designs extended usability for diverse terrains. Despite challenges like supply chain disruptions for rare-earth motor components, empirical data from user surveys indicate e-bikes increase cycling participation by 3-5 times compared to conventional bikes, supporting causal links to reduced urban emissions where adoption rates exceed 10% of bicycle sales.[34][35]Design and Engineering
Structural and Mechanical Components
The frame forms the core structural component of a motorized bicycle, typically constructed from high-tensile steel to withstand the vibrations, torque, and additional weight introduced by the engine, which can exceed 10-15 pounds for common 66cc units.[36] Steel provides superior resilience against fatigue from engine operation and road impacts compared to aluminum, which risks cracking under sustained dynamic loads from internal combustion motors.[36] [37] Diamond-shaped frames with adequate clearance between the seat tube and down tube are standard, often requiring modifications such as drilled ports for u-bolts and brackets to mount the engine and fuel tank while preserving structural integrity and avoiding irreversible welding.[38] Mechanical elements include the front fork for steering, usually rigid or with basic suspension in modern adaptations, and handlebars equipped with grips and stem for control.[39] The drivetrain comprises a standard bottom bracket, crankset with pedals, and chain connecting to a rear sprocket or multi-speed cassette, enabling human-powered propulsion alongside motor assistance.[39] Brakes, often mechanical caliper or V-brake systems acting on the rims, must handle decelerations from speeds reaching 30 mph, with some builds incorporating disc brakes for improved modulation under load.[40] Wheels feature 26-inch diameter rims with 36 spokes for durability, paired with tires such as 26x2.125-inch profiles offering traction and stability on varied terrain.[41] Seat posts and saddles remain conventional, adjustable for rider ergonomics, while the rear dropout is reinforced to accommodate chain tensioners and motor drive alignment.[42] These components collectively ensure the bicycle's mechanical reliability, with steel construction prioritizing longevity over weight savings in engine-equipped setups.[36]Integration of Propulsion Systems
Propulsion systems in motorized bicycles are integrated through mechanical mounting of engines or motors to the frame and power transmission mechanisms that link to the wheels or pedals. For internal combustion engines, common in add-on kits like 66cc or 80cc two-stroke units, the engine is typically bolted to the bicycle's down tube or chainstay using custom brackets, ensuring alignment for chain drive where a sprocket on the engine connects to the rear wheel via an extended or dedicated chain.[43] This method leverages the bicycle's existing drivetrain, allowing throttle-independent operation or pedal-assist, though it requires precise tensioning to prevent slippage or wear. Friction drive systems, prevalent in early designs such as the VéloSolex, mount the engine above the front wheel with a rubber roller pressing against the tire to transfer torque directly, avoiding chain modifications and enabling simpler retrofitting on various frames.[44] These systems offer quiet operation and easy installation but suffer efficiency losses from tire slippage, particularly in wet conditions, and accelerate tire wear.[45] Electric propulsion integration favors hub motors embedded in the front or rear wheel, where the motor replaces the hub to directly drive the wheel without intermediary transmission, reducing mechanical complexity and maintenance needs like chain lubrication.[46] Rear hub motors provide better traction for acceleration, while front hubs lighten rear weight for handling, though they may affect steering stability under power.[47] Geared hub variants use planetary gears for higher torque at low speeds, contrasting direct-drive hubs that offer regenerative braking potential but higher unsprung weight.[48] Mid-drive electric motors mount at the bottom bracket, coupling to the crank and utilizing the bicycle's gears for torque multiplication, which enhances hill-climbing efficiency and distributes load across the frame more evenly than hub systems.[49] This integration synchronizes motor assistance with pedaling cadence via sensors, promoting natural biomechanics, but it stresses the chain and requires compatible derailleurs.[44] Battery packs are typically secured to the frame's top tube or downtube, with wiring routed to controllers for throttle or pedal-assist modes, ensuring electrical isolation from mechanical components.[50] Hybrid approaches combining combustion and electric elements remain experimental, often facing challenges in weight distribution and control synchronization.[51]Controls, Ergonomics, and Modifications
Motorized bicycles typically employ bicycle-derived controls adapted for engine operation, featuring a twist-grip or thumb-actuated throttle on the right handlebar to regulate engine speed, often integrated with a kill switch for emergency shutdown.[52] [53] Dual brake levers on the handlebars control front and rear caliper or disc brakes via cables, with the right lever usually handling the rear brake and the left the front to mimic motorcycle conventions and reduce front-wheel lockup risk under powered deceleration.[54] [55] Pedals remain standard for initial engine starting in friction-drive or chain-driven gas models, though electric variants may prioritize throttle-only or pedal-assist modes without mandatory pedaling.[56] Ergonomics prioritize an upright riding posture similar to standard bicycles, with handlebars positioned to allow slightly bent elbows and a back angle of approximately 45 degrees for reduced strain during extended operation, though added motor weight shifts the center of gravity rearward, potentially increasing fatigue on unmodified frames.[57] Riders maintain a straight back, loose hand grip, and knees bent less than 90 degrees to the pedals, but motorized setups often demand firmer handlebar control due to higher speeds up to 30-50 mph, exacerbating vibration from small-displacement engines.[58] Comfort is further influenced by saddle height and grip design; ergonomic rubber or gel-padded grips mitigate hand numbness from prolonged throttle use, while electric models allow lower saddle positions for less leg extension compared to pedal-focused bicycles.[59] Common modifications enhance control precision and ergonomic suitability, such as upgrading to thumb throttles for smoother cable action without twisting stress, or installing disc brakes for superior stopping power on higher-speed builds exceeding stock 20 mph limits.[53] [60] Seat upgrades to cushioned saddles with backrests improve long-ride comfort by distributing weight and reducing pressure points, while replacing pedals with fixed foot pegs enables a motorcycle-like stance for non-pedaling operation, alleviating knee strain at sustained speeds.[61] [62] Performance-oriented changes like expansion chamber exhausts or larger carburetors indirectly affect ergonomics by increasing power delivery, necessitating reinforced handlebars to counter torque-induced steering inputs.[63] [60] These alterations, often performed by enthusiasts, prioritize durability over stock bicycle components rated for unpowered use.Power Sources
Internal Combustion Engines
Internal combustion engines (ICE) for motorized bicycles predominantly consist of small-displacement gasoline-powered units, either two-stroke or four-stroke designs, typically ranging from 49cc to 100cc in capacity.[64] These engines are mounted via friction drive against the rear tire or chain drive to the rear wheel, delivering power outputs of 1.5 to 5 horsepower depending on displacement and tuning.[65] Two-stroke engines dominate modern aftermarket kits due to their simplicity, lighter weight, and higher power-to-weight ratio, achieving one power stroke per crankshaft revolution compared to two revolutions in four-strokes.[66] Two-stroke engines, often cloned from designs like the Honda Dio or Chinese replicas, require fuel-oil premixing at ratios such as 16:1 to 32:1 for lubrication, producing speeds of 20-35 mph on flat terrain with a 180-pound rider.[65] Common variants include 49cc units yielding approximately 1.5-2 hp and 80cc models up to 3-4 hp, with top speeds exceeding 40 mph in tuned configurations.[67] However, they generate higher emissions of hydrocarbons and particulate matter due to incomplete combustion and oil burning, contributing to environmental concerns in urban use.[68] Four-stroke engines, such as those in historical Whizzer kits from the 1940s to 1960s, offer smoother operation, separate lubrication systems, and reduced emissions at the cost of added weight and complexity.[69] The Whizzer H-series, for instance, featured a 161cc flat-twin engine producing about 2.5 hp, enabling speeds around 30 mph while complying with early regulations by requiring pedaling assistance.[70] Modern four-stroke kits, like 100cc horizontal or vertical-cylinder units, deliver 3-4 hp with fuel efficiencies of 100-150 miles per gallon, but their heavier components (up to 25 pounds) demand sturdier bicycle frames to maintain balance and durability.[71] Key engineering considerations include carburetor tuning for altitude and temperature, exhaust expansion chambers for power enhancement in two-strokes, and centrifugal clutches to engage propulsion above idle speeds without stalling.[72] Fuel tanks hold 0.5-1 gallon, providing ranges of 50-100 miles, though vibration and noise levels—often exceeding 80 decibels—necessitate reinforced mounts and user ear protection for prolonged operation.[73] Maintenance involves frequent air filter cleaning, spark plug replacements every 100-200 miles, and valve adjustments in four-strokes to sustain reliability.[68]Electric Motors and Batteries
Electric motors in motorized bicycles, commonly known as e-bikes, primarily consist of brushless DC (BLDC) permanent magnet synchronous motors, which convert electrical energy from the battery into mechanical torque for propulsion. These motors are typically rated for continuous power outputs up to 750 watts to comply with federal regulations in the United States for low-speed electric bicycles, though peak powers can exceed this during short bursts.[74] Torque outputs generally range from 40 to 90 Nm, enabling assistance on inclines, with higher values suited for cargo or hilly terrain.[75] Efficiency levels average 80-90%, minimizing energy loss as heat during operation.[76] The two predominant motor configurations are hub-mounted and mid-drive systems. Hub motors, integrated into the front or rear wheel, are simpler and more cost-effective, often divided into geared hubs—which use planetary gears for amplified low-speed torque—and direct-drive hubs, which offer quieter operation and potential regenerative braking but add unsprung weight affecting handling.[77] Mid-drive motors, positioned at the bottom bracket near the pedals, leverage the bicycle's existing drivetrain gears for variable torque multiplication, providing superior hill-climbing efficiency and a more natural pedaling feel, though they increase chain and gear wear.[78] Mid-drives excel in torque delivery via gear ratios, making them preferable for varied terrain, while hubs suffice for flat urban commuting with less maintenance.[79] Batteries powering these motors are predominantly lithium-ion cells arranged in series-parallel packs, valued for their high energy density (typically 150-250 Wh/kg) and longevity of 500-1000 charge cycles before significant capacity degradation. Common voltages include 36V, 48V, or 52V, with capacities from 10-20 Ah (equivalent to 360-1040 Wh), influencing range: a 500 Wh pack yields approximately 48-97 km under mixed pedaling conditions, varying with rider weight, terrain, and assist level.[80] [81] Higher-voltage systems deliver more power to motors for sustained performance but require compatible controllers. Charging times for a depleted pack range from 3.5 to 6 hours using standard 2-4A chargers, with lithium-ion chemistry allowing daily full charges to 100% without immediate harm, though optimal longevity favors partial discharge cycles.[82] Safety features like battery management systems (BMS) prevent overcharge, over-discharge, and thermal runaway, integral to integration within the frame for protection and weight distribution.[83]Hybrid and Alternative Systems
Hybrid systems for motorized bicycles integrate internal combustion engines with electric motors, leveraging the strengths of each for enhanced torque, efficiency, and range. Electric components deliver instant high torque for starts and inclines, while gas engines provide sustained power for higher speeds, often exceeding 60 mph in custom builds.[84][85] Retailers like BikeBerry offer pre-assembled hybrid models combining 2-stroke or 4-stroke gas engines with electric assist, marketed for versatility in commuting and recreation.[86] One documented hybrid design, the Hybrid Sports Bike, employs a three-mode system—gas for top speed, electric for low-speed torque, and pedals for manual input—aiming to balance fuel economy with performance, though real-world efficiency depends on rider weight, terrain, and battery capacity.[87] DIY enthusiasts have constructed vertical-cylinder hybrids, such as 78cc gas-electric setups, reporting improved hill-climbing via electric augmentation before seamless transition to gas propulsion.[88] These systems typically require custom wiring, dual drivetrains, and controllers to manage power handoff, with battery sizes around 36-48V for electrics paired to 50-80cc gas units.[84] Alternative propulsion systems beyond combustion and batteries include steam and compressed air engines, primarily as experimental or niche projects rather than commercial standards. Steam-powered bicycles, like the Ruscombe Gentleman's Steam Bicycle developed around 2018, use monotube boilers and modern alloys for lightweight operation, achieving short-range travel at low speeds (under 20 mph) via flash-boiler technology that heats water rapidly without heavy reservoirs.[89][90] Other custom steam cycles, such as coal-fired models completed by 2020, incorporate handmade engines but face limitations in startup time (10-15 minutes) and fuel efficiency, rendering them impractical for daily use despite top speeds near 30 mph in optimized prototypes.[91] Compressed air systems propel bicycles by expanding stored pressurized air (typically 100-150 psi) through pneumatic motors or turbines connected to the drivetrain. Inventor Cory Little's 2016 air-powered bicycle uses a custom compressor and tank setup, delivering bursts of power for urban distances up to 5-10 miles per fill, with refilling via stationary pumps rather than onboard generation.[92] DIY variants, often 3D-printed, pair air engines with 3-gallon tanks regulated for controlled release, achieving 15-25 mph but suffering from low energy density—air expands inefficiently compared to fuels, limiting range to minutes without frequent recharges.[93][94] These alternatives highlight engineering ingenuity but underscore causal challenges like poor power-to-weight ratios and refueling logistics, confining them to demonstrations over widespread adoption.[95]Performance Characteristics
Speed, Range, and Efficiency Metrics
Typical top speeds for gas-powered motorized bicycles equipped with 66cc to 80cc two-stroke engines range from 25 to 35 miles per hour (40-56 km/h), influenced by factors such as gearing, rider weight, and terrain; four-stroke variants often achieve slightly lower speeds of 20-30 mph due to reduced power output.[96] [97] Electric motorized bicycles with 500-750W motors commonly reach 20-25 mph (32-40 km/h) under legal class limits in many jurisdictions, with higher-wattage systems (up to 1500W) capable of 28 mph while balancing battery drain.[98] [99] Range for gas models typically spans 50-150 miles per tank (0.5-1 gallon capacity), contingent on fuel mix and load; user-reported data indicates 70-115 miles per gallon (mpg) for mixed conditions, far exceeding automobile efficiency due to low power demands and human pedaling assistance.[100] [96] Electric variants offer 20-50 miles per charge on standard 36-48V batteries, extendable via pedaling; higher speeds reduce range by doubling energy use above 15 mph due to aerodynamic drag.[101] [102]| Power Type | Typical Top Speed (mph) | Range (miles) | Efficiency Metric |
|---|---|---|---|
| Gas (66-80cc) | 25-35 | 50-150 | 70-150 mpg |
| Electric (500-750W) | 20-28 | 20-50 | 15-25 Wh/mile (equiv. ~2000 MPGe) |
Handling, Durability, and Maintenance
The handling of motorized bicycles differs from that of unpowered bicycles primarily due to increased weight from the motor and power source, which ranges from 5-15 kg for typical gas engine kits to 10-25 kg for electric systems including batteries. This added mass raises the moment of inertia, reducing responsiveness in turns and requiring greater rider input for low-speed maneuvers, though it can enhance high-speed stability by lowering the center of gravity.[108] Rear-mounted gas engines or hub motors shift weight distribution rearward, potentially improving traction on acceleration but complicating balance during braking or cornering compared to front-wheel or mid-drive configurations.[109] Mid-drive electric motors, positioned near the bottom bracket, minimize handling deviations from standard bicycles by preserving balanced geometry and pedaling dynamics.[109] Durability in motorized bicycles varies by propulsion type and component quality, with gas-powered models often experiencing accelerated wear on drive chains, sprockets, and spokes due to higher torque loads and vibration from 2-stroke engines operating at 3,000-6,000 RPM. Common failure points include chain tensioners jamming into wheels and clutch pads degrading after 500-1,000 miles of use without upgrades to reinforced parts.[110] Electric variants demonstrate greater longevity in motors, rated for 20,000-50,000 miles or 3-10 years under moderate conditions, though batteries degrade to 60-80% capacity after 500-1,000 charge cycles, influenced by thermal management deficiencies leading to cell imbalance.[111] Frames and tires endure similarly to standard bicycles if constructed from steel or aluminum alloys, but exposure to moisture or impacts can corrode electrical connections or warp lightweight components.[112] Maintenance demands are higher for gas motorized bicycles than electric ones, necessitating weekly checks on fuel lines, air filters, and spark plugs for 2-stroke engines to prevent seizures from improper 40:1 to 50:1 oil-fuel ratios during break-in and operation. Routine tasks include chain lubrication every 100-200 miles, brake pad replacements after 1,000 miles, and engine teardowns for carbon buildup every 500 hours to sustain reliability beyond 1,000 miles.[113] Electric systems require less frequent intervention, focusing on battery charging to 20-80% depth of discharge for longevity, drivetrain cleaning, and spoke tension adjustments quarterly, with professional servicing recommended every 1,000-2,000 miles to inspect motor bearings and wiring for water ingress.[114] Proper storage indoors and avoidance of overloading extend overall service life, mitigating causal factors like vibration-induced fatigue in both types.[115]Usage Patterns and Applications
Commuting, Recreation, and Utility Roles
Motorized bicycles facilitate urban commuting by extending effective range and reducing physical exertion compared to unassisted cycles, often substituting for short automobile trips. Empirical data from e-bike pilot programs indicate an average daily commute distance of 6.9 kilometers on working days, with an 81% usage rate among participants, yielding per-person CO2 reductions of 245 kilograms annually.[116] These vehicles contribute 2.1 additional hours of moderate physical activity per week for users, enhancing overall activity levels without fully supplanting exercise benefits.[117] Cardiovascular improvements, including increased aerobic capacity and better blood sugar control, mirror those from conventional cycling, as riders maintain pedaling involvement.[118] In recreational contexts, motorized bicycles enable leisure exploration over varied terrain, appealing to hobbyists seeking augmented speed without full motorcycle commitment. Gas-powered models, such as those with 66-80cc engines, achieve up to 150 miles per gallon, supporting extended recreational outings with minimal refueling.[119] E-bike variants provide fitness gains comparable to standard bicycles, as commuters and casual riders accrue similar moderate-intensity efforts, though recreational conflicts arise on shared paths due to speed differentials.[120] Usage patterns emphasize enjoyment in non-competitive settings, distinct from high-performance applications. Utility roles encompass errands, light delivery, and cargo hauling, where rear racks or trailers accommodate groceries, tools, or small packages. E-cargo variants reduce fossil-fuel vehicle dependency for shopping and child transport, with studies reporting major capital and emissions savings over cars for urban tasks.[121] In delivery scenarios, these bikes offer zero-emission, low-cost alternatives for community routes, bypassing traffic and parking constraints.[122] Gas equivalents extend utility in areas with limited charging infrastructure, prioritizing fuel efficiency for practical loads like farming or hunting accessories.[123] Overall, 40-50% of motorized bike trips replace car journeys, amplifying accessibility for short-haul needs.[124]User Demographics and Accessibility Benefits
Motorized bicycles attract users across various demographics, including urban commuters, recreational enthusiasts, and individuals seeking low-cost alternatives to automobiles. In North America, surveys of electric bicycle owners reveal a user base predominantly composed of white males from higher-income households, with increasing female adoption compared to traditional cycling.[125] Approximately 35% of electric bicycle users are over 50 years old, reflecting appeal to older adults for practical mobility.[126] Women exhibit higher electric bicycle usage rates than men overall, though this gender gap narrows among older riders and widens among younger ones.[127] Data on gas-powered motorized bicycle riders remains limited, but injury statistics indicate a skew toward younger males, often associated with higher-risk recreational or modified builds.[128] Accessibility benefits are particularly pronounced with electric motorized bicycles, which incorporate pedal-assist systems that mitigate physical limitations by providing proportional motor support to human effort, thereby extending range and reducing fatigue for users with disabilities or age-related mobility challenges.[129] These systems enable independent travel over distances and terrains that would otherwise require excessive exertion, fostering greater autonomy for seniors and those with conditions like arthritis or cardiovascular issues.[130] For instance, electric assistance allows riders to conserve energy for critical maneuvers while maintaining bicycle-like ergonomics, contrasting with full-motor vehicles that may exclude pedal-based control.[131] Gas-powered variants offer throttle-based propulsion that can bypass pedaling entirely, potentially benefiting users unable to generate sustained leg power, though their heavier engines, vibration, and maintenance demands limit suitability for frail or novice users compared to quieter, lighter electric options.[132] Empirical observations from user surveys underscore electric models' role in bridging transportation gaps for physically challenged individuals, replacing car trips and promoting sustained physical activity without overload.[129]Safety and Risk Factors
Empirical Injury Data and Causal Factors
According to the U.S. National Highway Traffic Safety Administration's Fatality Analysis Reporting System (FARS), there were 43 fatalities involving motorized bicycles in traffic crashes in 2021, with a similar figure of 43 reported in 2022, of which only 7 involved collisions solely between motorized bicycles.[133][134] These numbers represent a small fraction of overall pedalcyclist fatalities, which totaled 966 in 2021, but highlight motorized bicycles as a distinct category from human-powered bicycles due to their propulsion systems.[133] Specific injury data for gas-powered motorized bicycles remains limited in national databases, though estimates for pediatric injuries from gas-powered two-wheeled vehicles classified as mopeds—which often encompass motorized bicycles—totaled 23,300 cases requiring emergency department visits from 2011 to 2020, predominantly affecting males.[128] Empirical studies on broader two-wheeled powered vehicles indicate that motorized bicycles contribute to higher injury severity compared to conventional bicycles, primarily due to increased kinetic energy from engine-assisted speeds. For instance, in analyses of U.S. emergency department data, powered two-wheeled vehicles like mopeds accounted for 53.3% of weighted injury cases among such devices from recent years, exceeding shares for electric bicycles at 28.2%, with common injuries including fractures and head trauma.[135] Head and neck injuries occur more frequently in moped and bicycle crashes involving motor vehicles than in unpowered cycling alone, with rates around 35-40% in comparative international data.[136] Key causal factors in motorized bicycle crashes include rider loss of control at elevated speeds enabled by the engine, which exceeds typical bicycle handling capabilities, often exacerbated by inexperience or mechanical failures such as brake or throttle issues.[137] Collisions with motor vehicles account for a significant portion, driven by visibility deficits and failure-to-yield scenarios at intersections or midblock locations, where motorized bicycles' intermediate speeds (typically 20-30 mph) position riders ambiguously between bicycles and motorcycles in traffic flow.[138] Road surface irregularities, including potholes and debris, precipitate single-vehicle falls more readily due to the added weight and power imbalance of motorized setups, contributing to 13-17% of general bicycle-related incidents but amplified in powered variants by reduced stability.[139] Operator factors like impairment or reckless overtaking further elevate risks, as evidenced in crash causation studies attributing 13% of incidents directly to rider error.[140] These patterns underscore that while motorized bicycles enhance mobility, their causal risks stem from mismatched vehicle dynamics in environments designed for either low-speed bicycles or fully regulated motorized traffic.Mitigation Through Design and Operation
Design features in motorized bicycles, such as hydraulic disc brakes, enhance stopping power compared to traditional rim brakes, reducing crash severity in high-speed scenarios by improving modulation and wet-weather performance.[141] Visibility aids like integrated LED headlights, taillights, and reflectors mitigate nighttime collision risks, with studies indicating that illuminated bicycles experience up to 19% fewer frontal impacts from motorists.[142] Frame geometries with lower centers of gravity and reinforced structures address stability issues from added motor weight and torque, minimizing tip-over incidents during acceleration or cornering.[143] Emerging standards for lithium-ion batteries, including overcharge protection and thermal runaway prevention, curb fire hazards, which accounted for 20 reported e-bike incidents in the U.S. in 2023 per CPSC data.[144] Speed-limiting controllers, capping pedal-assist at 20-28 mph depending on class, prevent excessive velocities that elevate injury risks, as empirical reviews show throttle-equipped variants correlate with higher fall rates absent such caps.[145] Operational practices further reduce risks through consistent rider behaviors and upkeep. Helmet usage, mandated for minors in many jurisdictions, lowers head injury probability by approximately 70% in crashes, based on meta-analyses of cycling incidents.[146] Pre-ride inspections of brakes, tires, and fasteners ensure mechanical integrity, averting failures that contribute to 15-20% of single-vehicle e-bike accidents per NTSB micromobility reports.[147] Adhering to traffic laws, including signaling turns and yielding right-of-way, aligns motorized bicycle operation with vehicular norms, with observational data linking non-compliance to 40% of urban cyclist-motorist conflicts.[148] Rider education programs emphasizing hazard anticipation and fatigue management yield measurable safety gains, as European cohort studies report 25% fewer self-reported near-misses among trained e-bike users versus untrained counterparts.[149] Integrated approaches, combining design with operation, amplify effectiveness; for instance, pairing advanced braking with rider training has demonstrated up to 30% reductions in simulated emergency stops failing to avoid obstacles.[150] Maintenance schedules, including battery checks and chain lubrication, prevent degradation that exacerbates handling issues under motor-assisted loads.[151] While empirical data on motorized variants remains sparser than for conventional bicycles, these mitigations address causal factors like speed differentials and visibility deficits, substantiated by CPSC hazard pattern analyses showing collisions and falls as primary e-bike risks amenable to proactive interventions.[145]Controversies and Debates
Regulatory Overreach and Freedom Arguments
Critics of motorized bicycle regulations argue that governments impose excessive restrictions on low-power internal combustion and electric-assisted variants, equating them to full motorcycles despite empirical evidence of lower speeds and risks, thereby infringing on individual autonomy in transportation choices.[152] For instance, requirements for vehicle registration, operator licensing, and mandatory insurance in numerous U.S. states—such as California's DMV classification of bicycles with engines exceeding 50cc as mopeds—demand compliance costs and bureaucratic hurdles that exceed the causal safety needs for devices typically capped at 20-30 mph. Proponents of deregulation, including libertarian economists, assert that such rules prioritize paternalistic control over personal responsibility, where users accept inherent risks akin to unassisted cycling without necessitating state intervention.[153] These arguments highlight how regulatory frameworks limit freedoms associated with do-it-yourself modifications, such as friction-drive kits for bicycles, which enthusiasts view as extensions of personal property rights rather than vehicular threats warranting oversight.[154] In jurisdictions like New York and New Jersey, recent crackdowns on throttle-equipped e-bikes—including age minimums and speed governors—have been decried as overreach that stifles innovation and access for commuters, with advocacy groups successfully blocking dozens of similar bills in 2025 that would have mandated rider insurance or trail exclusions.[155] Such measures, critics note, create inconsistent enforcement landscapes across states, where a compliant device in one area becomes illegal in another, undermining predictable use and echoing broader concerns over federal preemption failures in micromobility policy.[152] From a first-principles standpoint, opponents contend that risk allocation should rest with operators through civil liability rather than prohibitive licensing, as data on motorized bicycle incidents show injury rates comparable to or lower than standard bicycles when operated responsibly, questioning the necessity of blanket prohibitions on public paths or roads.[154] This perspective attributes regulatory zeal to institutional biases favoring established automotive interests over emergent, low-emission alternatives, with sources like bike industry analyses warning that overregulation hampers equitable mobility gains for non-drivers.[156] While safety advocates counter with calls for accountability, freedom-based critiques emphasize that empirical undercurrents of low accident severity—such as U.S. Consumer Product Safety Commission reports indicating minimal motorized bike involvement in fatalities—do not justify curtailing liberties in device ownership and use.Sports Integrity Issues like Mechanical Doping
Mechanical doping, also known as technological fraud or motor doping, involves the concealed integration of electric motors or other unauthorized propulsion systems into bicycles during events restricted to human-powered performance, thereby artificially enhancing speed and endurance.[157] This practice directly undermines the core principle of cycling competitions, which demand equitable physical exertion among participants, as motors can provide consistent power output exceeding what pedaling alone achieves on climbs or sprints.[158] The Union Cycliste Internationale (UCI) classifies such violations under article 1.3.010 of its regulations, prohibiting any non-human assistance that alters competitive balance.[157] Suspicions of mechanical doping emerged prominently in professional road cycling around 2010, following Swiss rider Fabian Cancellara's dominant solo victory in the Tour of Flanders on March 4, where telemetry data and video footage prompted claims of unnatural acceleration, though no motor was ever confirmed.[159] Similar allegations surfaced in subsequent years, including during the 2014 Tour de France, fueled by anecdotal reports of humming sounds from bikes and inconsistent power outputs from riders, but lacked empirical verification due to rudimentary detection capabilities at the time.[160] These early rumors highlighted vulnerabilities in race oversight, as compact motors—capable of delivering up to 250 watts without detectable weight penalties—could be hidden in bottom brackets or seat tubes, exploiting the low-visibility nature of bike components during high-speed events.[160] The first empirically confirmed instance occurred on January 30, 2016, at the UCI Cyclo-cross World Championships in Zolder, Belgium, where a hidden 250-watt electric motor was discovered in a spare bicycle belonging to Belgian junior rider Femke van den Driessche during post-race inspections.[161] [162] The device, weighing approximately 320 grams and disguised within the frame, was identified via thermal imaging and disassembly, leading to a six-year suspension for van den Driessche, the maximum penalty under UCI rules, and her permanent exclusion from elite competition.[161] This case marked a pivotal shift, prompting the UCI to deploy tablet-based magnetic resonance scanners at major events, which detect anomalies in bike frames indicative of motorized components with over 90% accuracy in controlled tests.[158] Subsequent detections have been rare but underscore persistent risks, including a 2017 amateur disqualification with a five-year ban for a similar hidden motor in a regional race, and amateur cases in 2019 (Stefano Varjas, lifetime ban) and 2020 (Roberto Galleti, three-year ban), often involving commercially available e-bike components repurposed for concealment.[160] Professional pelotons have seen no further verified pro-level incidents as of 2025, yet unconfirmed suspicions endure, exacerbated by the accessibility of stealth motors producing minimal noise and heat signatures below 1 dB and 40°C, respectively.[163] The UCI has intensified countermeasures, including random bike seals, X-ray scans, and AI-assisted telemetry analysis at the 2025 Tour de France, inspecting over 500 bicycles daily to deter what officials describe as an evolving "technological arms race."[164] [158] These integrity challenges extend beyond isolated cheats to systemic threats, as undetected mechanical assistance could erode trust in results, mirroring historical chemical doping scandals that halved spectator interest in the 1990s-2000s.[165] In contexts involving openly motorized bicycles—such as paced training or derny events—the issue manifests differently, with debates over crossover technology enabling easier concealment in pure races, though UCI segregation of motorized classes mitigates direct overlap.[157] Empirical data from UCI audits indicate that while confirmed cases remain under 10 globally since 2016, the potential for widespread adoption, driven by motors costing under €1,000, necessitates ongoing vigilance to preserve cycling's meritocratic foundation.[163]Infrastructure and Coexistence Conflicts
Motorized bicycles, including both internal combustion and electric variants, frequently encounter infrastructure challenges due to their higher speeds—often 20-28 mph (32-45 km/h) for pedal-assisted models—compared to conventional bicycles averaging 10-15 mph (16-24 km/h). This speed differential exacerbates conflicts on shared bike lanes, multi-use paths, and sidewalks originally designed for human-powered cycles and pedestrians, where sudden accelerations and overtaking maneuvers increase collision risks. A study of speed-pedelecs found conflict rates 1.5-2 times higher on bicycle facilities than on car roadways, attributing this to inadequate sight lines, narrow widths, and mixed user speeds that hinder safe passing.[166] Similarly, analyses of shared spaces reveal that e-bike riders' faster trajectories disrupt pedestrian yielding behaviors, leading to near-misses at crossings and intersections.[167][168] Pedestrian-motorized bicycle incidents underscore these tensions, particularly in urban delivery contexts where throttled e-bikes enable rapid stops and starts. In New York City, e-bike-related pedestrian fatalities rose alongside delivery service expansion, with three such deaths reported in 2023 amid bidirectional lane usage and sidewalk encroachments. E-bike riders face elevated fatality risks in motor vehicle collisions—up to 2-3 times higher than traditional cyclists—due to greater mass and velocity, amplifying injury severity upon impact. Gas-powered motorized bicycles compound issues on roads lacking dedicated lanes, as their noise and emissions deter coexistence with pure cyclists, prompting exclusions from bike paths in jurisdictions like New York State, where they fail safety registration standards and are classified as unregistered motorized vehicles.[169][169][170] Regulatory responses often prioritize segregation to mitigate risks, with bans on non-pedal-assist motorized bicycles from multi-use trails to prevent erosion of user trust and trail degradation. For instance, New York City's Hudson River Greenway prohibited e-bikes in 2022, citing safety concerns over the sole off-street route for commuters, while Union County, New Jersey, enacted a 2025 executive order barring all motorized vehicles from parks to curb pedestrian hazards. Speed caps—15 mph (24 km/h) on streets—and prohibitions on sidewalk use aim to enforce coexistence, yet enforcement gaps persist, as evidenced by rising e-bike citations in protected lanes. While general bike infrastructure reduces overall cycling injuries by 20-50% through separation from cars, motorized variants necessitate tailored designs like wider paths or velocity limits to avoid displacing slower users.[171][172][173][174][175]Environmental Evaluation
Lifecycle Emissions and Resource Use
Manufacturing emissions for motorized bicycles, whether powered by internal combustion engines (ICE) or electric motors, are dominated by material production, particularly aluminum for frames, which accounts for a significant portion of upfront greenhouse gas (GHG) emissions in lifecycle assessments of similar two-wheeled vehicles.[176] For electric variants, battery production adds approximately 20 kg CO₂-equivalent (CO₂e) emissions per unit, while the motor contributes around 37 kg CO₂e, elevating total manufacturing impacts compared to non-motorized bicycles.[176] ICE models incur lower production emissions from small engines but shift the burden to operational phases through fuel combustion.[177] Operational emissions differ markedly by power source: ICE motorized bicycles release CO₂, nitrogen oxides (NOx), and hydrocarbons directly from exhaust, with upstream fuel extraction and refining amplifying the footprint, though total per-kilometer emissions remain far below automobiles due to efficient small-displacement engines (typically 49 cc or less).[106] Electric models produce near-zero tailpipe emissions, but charging emissions vary with grid carbon intensity; lifecycle studies of shared electric bicycles indicate that operational GHG can constitute a minor fraction of total impacts if electricity derives from renewables, though fossil-heavy grids reduce this advantage.[178] End-of-life disposal adds negligible emissions for both, assuming metal recycling, but electric batteries require specialized handling to recover materials and avoid landfill leaching.[179] Resource consumption highlights trade-offs: Electric motorized bicycles demand lithium, cobalt, nickel, and rare earth elements for batteries and motors, entailing energy-intensive mining with ecological costs including water depletion and habitat loss, though recycling recovers up to 95% of metals like cobalt and nickel, mitigating depletion over multiple cycles.[179] [180] ICE variants primarily utilize abundant steel and aluminum for engines—materials with established high recyclability—but rely on non-renewable petroleum, perpetuating extraction pressures without equivalent critical mineral dependencies.[181] Comprehensive lifecycle assessments remain sparse for traditional ICE motorized bicycles, underscoring a research gap relative to electric counterparts, where production dominates (up to 94% of total GHG in some models) but yields net reductions over extended use.[182][176]Comparative Impacts Versus Cars and Pure Bicycles
Operational greenhouse gas emissions from pure bicycles are zero, as propulsion derives entirely from human effort without combustion or grid electricity; indirect emissions from food production to sustain pedaling equate to 16-50 grams of CO2 equivalent per kilometer, varying by diet.[183] Gasoline-powered motorized bicycles, featuring small-displacement engines with fuel efficiencies often exceeding 100 miles per gallon, generate approximately 85 grams of CO2 per kilometer during operation.[182] [184] Electric motorized bicycles yield even lower operational emissions, typically around 10 grams of CO2 equivalent per kilometer, contingent on the regional electricity mix's carbon intensity.[182] Automobiles emit substantially more: internal combustion passenger cars average 191 grams per kilometer, while battery electric variants range from 128-200 grams depending on grid decarbonization.[182] [185]| Transport Mode | Operational CO2-eq (g/km) | Key Factors |
|---|---|---|
| Pure bicycle | 0 (direct); 16-50 (food) | Human calories; diet-dependent |
| Gasoline motorized bicycle | ~85 | Fuel efficiency 100-160 mpg; small engines |
| Electric motorized bicycle | ~10 | Grid mix; battery efficiency |
| Passenger car (average) | ~191 | Fuel type; vehicle size |
Realistic Net Benefits and Drawbacks
Motorized bicycles, encompassing both internal combustion engine (ICE) and electric variants, yield net environmental benefits primarily when substituting for automobile trips, particularly in urban settings with short distances under 10 kilometers, where lifecycle greenhouse gas emissions can be 90-94% lower than those of gasoline or electric cars.[188][189] This advantage stems from their lower energy consumption—e-bikes require approximately 0.15-0.5 watt-hours per kilometer versus 150-200 for cars—and reduced material intensity, enabling potential systemic emission reductions of 10-23% in passenger transport if e-bikes capture a substantial share of feasible car trips.[190][189] ICE motorized bicycles, while less efficient than e-bikes, still emit far fewer pollutants per passenger-kilometer than cars due to smaller engines (typically 49cc or less), though their two-stroke variants produce higher unburnt hydrocarbons and particulate matter.[177] Key drawbacks arise in manufacturing and operational phases, where e-bikes incur elevated upfront emissions from lithium-ion battery production—estimated at 50-150 kg CO2-equivalent per kilowatt-hour of capacity, involving resource-intensive mining of cobalt, lithium, and nickel—potentially offsetting benefits if usage is low (under 500-1000 km annually) or if they displace pure bicycle trips rather than cars.[191][192] Relative to unassisted bicycles, which emit near-zero operational GHGs and minimal lifecycle impacts (primarily from steel/aluminum frames), motorized variants increase total emissions by 10-30 times due to electrical grid dependency (emitting 13-22 g CO2/km in fossil-heavy grids) and added components like motors and controllers.[185][192] ICE models exacerbate this with tailpipe emissions of CO, NOx, and volatile organics, often unregulated in hobbyist kits, leading to localized air quality degradation without the clean operation of e-bikes.[177]| Aspect | E-Bike Lifecycle Emissions (g CO2/km) | ICE Motorized Bike (g CO2/km) | Conventional Bike (g CO2/km) | Car (Gasoline, g CO2/km) |
|---|---|---|---|---|
| Manufacturing | 50-100 (amortized over 10,000 km) | 20-50 | <5 | 50-80 |
| Operation | 13-22 (grid-dependent) | 100-200 | 0 | 170-250 |
| Total (avg.) | 20-40 | 120-250 | 0.03-0.08 | 200-300 |