Projectile
A projectile is any object propelled through space by an external force, continuing in motion by its own inertia. In physics, it commonly refers to an object launched into the air or space and thereafter subject primarily to gravity (with other forces like air resistance often negligible in idealized models).[1] This results in projectile motion, a form of two-dimensional motion where the object's path traces a parabolic trajectory.[2] The study of projectiles dates back to early physics, with Galileo Galilei first recognizing the independence of horizontal and vertical components in such motion during the 17th century, which enabled predictions of range for applications like artillery.[2] In projectile motion, the initial velocity is resolved into horizontal and vertical components: the horizontal component remains constant (v₀x = v₀ cos θ₀), while the vertical component undergoes uniform acceleration due to gravity (g ≈ 9.80 m/s² downward).[2] The position equations are x = v₀x t for the horizontal direction and y = v₀y t - (1/2) g t² for the vertical, where v₀y = v₀ sin θ₀ and t is time.[2] Key parameters include the range (R = (v₀² sin 2θ₀)/g), which is the total horizontal distance traveled and maximized at a launch angle of 45° on level ground, and the maximum height (h = (v₀y²)/(2g)), reached when vertical velocity is zero.[2] These principles underpin analyses in fields like ballistics, sports (e.g., throwing a baseball), and engineering, assuming idealized conditions without drag or wind.[2] Real-world scenarios often incorporate air resistance, which complicates the parabolic path, but the basic model provides foundational insights into gravitational effects on launched objects.[3]Fundamentals
Definition
A projectile is an object propelled through space by an initial force, thereafter moving primarily under the influence of gravity and other external forces such as air resistance.[3] In physics, the path followed by such an object is termed projectile motion, which typically involves both horizontal and vertical components affected differently by these forces.[2] Key characteristics of a projectile include its inertia, which governs the constancy of horizontal motion in the absence of drag, and the independence of its trajectory from the propulsion source once launched.[4] Representative examples encompass everyday objects like a thrown stone, a fired bullet, or a released arrow, each exhibiting these traits after the propelling action ceases.[5] A fundamental distinction exists between projectiles and objects in powered flight: projectiles lack sustained propulsion post-launch, unlike rockets or aircraft that rely on continuous thrust from engines.[5] This reliance on initial kinetic energy alone highlights the passive nature of projectile dynamics under gravitational dominance. Essential terminology for projectiles includes mass, which determines inertial response; velocity at launch, denoting the initial speed and direction; range, the total horizontal distance covered; and apex, the maximum height attained in the trajectory.[2][6]Historical Development
The use of projectiles dates back to prehistoric times, when early humans employed thrown stones and spears for hunting. Around 2 million years ago, anatomical adaptations in Homo erectus, such as enhanced shoulder and arm structures, enabled efficient throwing of projectiles, providing a significant advantage in hunting large game and contributing to human survival and evolution.[7] These simple thrown weapons marked the initial harnessing of projectile motion for practical purposes, laying the foundation for more advanced technologies. In ancient civilizations, projectile weapons advanced with mechanical aids. Slings, used in Mesopotamia and Egypt circa 3000 BCE, allowed warriors to hurl stones or clay projectiles with greater velocity and range, as evidenced by archaeological finds of sling ammunition from northern Mesopotamia dating to the sixth millennium BCE and depictions in early Bronze Age contexts.[8] By the 4th century BCE, the Greeks developed the gastraphetes, a hand-held crossbow-like device that used tension to launch bolts, serving as a precursor to larger catapults and revolutionizing siege warfare during conflicts like the siege of Motya in 397 BCE.[9] Medieval innovations further transformed projectiles through mechanical and chemical means. Crossbows, originating in China by the 5th century BCE but widely adopted in European warfare by the 11th century CE, provided accurate, powerful shots independent of the user's strength, influencing battles such as the Crusades.[10] Concurrently, gunpowder—developed in China during the 9th century CE—was initially used in incendiary projectiles like fire arrows and bombs by the 10th century, spreading to Europe by the 13th century and leading to early cannons in the 14th century, which dramatically increased destructive range in sieges like those of the Hundred Years' War.[11] The Industrial era introduced precision enhancements to firearm projectiles. Rifled barrels, which imparted spin to bullets for improved accuracy and range, became practical with the Minié ball in the 1840s—a conical lead bullet with a hollow base that expanded to engage rifling upon firing, enabling rapid loading in muzzle-loaders and transforming infantry tactics during conflicts like the Crimean War and American Civil War.[12] This innovation paved the way for modern ballistics, emphasizing aerodynamics and velocity in projectile design. In the 20th century, projectiles evolved into sophisticated guided systems. Post-World War II, advancements in rocketry led to guided missiles, building on German V-2 technology, with operational deployments in the late 1950s.[13] Intercontinental ballistic missiles (ICBMs), such as the Soviet R-7 launched in 1957, extended projectile ranges to global scales, integrating nuclear warheads and inertial guidance for strategic deterrence during the Cold War.[14] Following the Cold War, projectile technology advanced with precision-guided munitions. During the 1991 Gulf War, GPS-guided bombs and missiles like the Tomahawk cruise missile demonstrated high accuracy in combat, reducing collateral damage.[15] In the 21st century, hypersonic glide vehicles, capable of speeds exceeding Mach 5, emerged as a new frontier, with systems like Russia's Avangard deployed in 2019 and U.S. tests ongoing as of 2025, enhancing strategic capabilities amid global arms races.[16] Throughout history, projectiles have held profound cultural significance, shaping warfare, hunting, and sports across civilizations. In warfare, they symbolized technological dominance, from Sumerian slingers defending city-states to modern missile arsenals maintaining geopolitical balance.[17] For hunting, prehistoric spears ensured sustenance, evolving into ritualized practices in indigenous cultures. In sports, ancient Olympic javelin throws and medieval archery contests preserved projectile skills as tests of prowess, influencing contemporary events like shot put and baseball pitching.[18]Propulsion
Motive Forces
Motive forces in projectiles refer to the physical mechanisms that impart initial velocity to an object immediately upon launch, converting stored or chemical energy into kinetic energy through rapid force application. These forces act over a brief duration to accelerate the projectile, determining its muzzle velocity and subsequent trajectory influenced by external factors.[19] The primary categories of motive forces include explosive chemical propulsion, elastic energy release, and direct muscular exertion. In explosive chemical propulsion, common in firearms, propellants such as nitrocellulose-based powders undergo rapid combustion, generating high-pressure gases that expand to push the projectile down the barrel. This process converts chemical potential energy into mechanical work, achieving high velocities in milliseconds.[20] Elastic energy propulsion, as seen in bows or slingshots, involves deforming flexible materials like bow limbs or rubber bands to store potential energy, which is then released to accelerate the projectile. For instance, in a bow, drawing the string distorts the limbs, storing elastic potential energy proportional to the square of the deformation, which transfers to the arrow upon release. In slingshot mechanics, for example, stretched elastic bands convert stored potential energy to projectile kinetic energy, though band hysteresis and air resistance during release cause losses.[21] Muscular force, utilized in throwing actions like javelin or baseball pitches, relies on human biomechanics where skeletal muscles generate force through contraction, applying it over the throwing motion to impart velocity.[19] The physics of force application centers on impulse, defined as the product of average force and time duration, which equals the change in linear momentum of the projectile:J = \int F \, dt = \Delta p = m \Delta v
This impulse delivers the initial velocity, with the force often peaking rapidly in explosive or elastic systems.[22] Newton's third law of motion governs the reaction, producing recoil equal in magnitude but opposite in direction to the projectile's momentum, as the expanding gases or released energy propel the launcher backward.[23] Energy considerations highlight the conversion efficiency during launch. The projectile exits with kinetic energy given by
KE = \frac{1}{2} m v^2
where m is mass and v is muzzle velocity, but significant losses occur due to friction along the launch path, heat from incomplete combustion in chemical propellants, and vibrational dissipation in elastic systems, often reducing overall efficiency to 20-40% in firearms.
Launch Methods
Manual methods of launching projectiles represent some of the earliest human innovations for extending throwing range and force. Throwing by hand involves direct propulsion of objects like stones or spears using arm strength, a technique dating back to prehistoric times for hunting and combat. Slings, consisting of a pouch attached to cords, amplify velocity by whirling the projectile overhead before release, enabling ranges up to 100 meters with lead or stone ammunition, as used by ancient warriors such as the Balearic slingers in Roman armies. Atlatls, or spear-throwers, are lever-like tools with a hooked end that extends the thrower's arm, increasing dart speed by up to 20 meters per second compared to unaided throws; originating around 17,000 years ago in Upper Paleolithic Europe and widely adopted in ancient American cultures for big-game hunting.[24][25][24] Mechanical devices evolved to harness stored elastic or torsional energy for greater power and precision. Bows use tension in a curved limb to propel arrows via a drawn string, with composite designs from ancient Egypt and Asia achieving draw weights over 50 pounds for effective ranges exceeding 200 meters. Crossbows mechanize this by employing a trigger and prod to hold tension, allowing aimed shots without constant strength; developed in China around 500 BCE and refined in medieval Europe for siege and hunting. Catapults, prominent in ancient warfare, include tension-based gastraphetes—early Greek crossbow-like launchers—and torsion types like the Roman ballista, which twisted sinew skeins to hurl bolts or stones up to 400 meters, providing covering fire during assaults. Firearms and artillery advanced launch methods through chemical propulsion, primarily via gunpowder explosives. Muzzle-loading muskets, introduced in the 16th century, required pouring powder and ramrod insertion from the barrel's front, followed by a bullet, enabling infantry fire but limiting rates to two or three shots per minute. Breech-loading rifles, emerging in the mid-19th century, allowed cartridge insertion from the rear via hinged or sliding blocks, improving reload speed to 10-15 rounds per minute and accuracy through rifled bores. Howitzers, short-barreled artillery pieces developed in the 17th century, employ elevated trajectories for indirect fire, often using sabot systems—plastic or metal bases that seal the bore and center smaller projectiles—for compatibility with various calibers and enhanced velocity.[26][27][28] Modern systems incorporate electromagnetic and pneumatic principles for specialized applications. Railguns utilize Lorentz forces from high-current rails to accelerate conductive projectiles to hypersonic speeds, such as Mach 7, as demonstrated in prototypes including U.S. Navy efforts from 2005 to 2021; although the U.S. program was canceled in 2021, developments continue internationally, including Japanese ship-based tests as of 2025.[29][30] Pneumatic launchers compress air or gas to propel non-lethal rounds like rubber bullets or bean bags, used in crowd control to achieve muzzle energies around 100 joules while minimizing penetration risks. Safety and design factors in launchers prioritize reliability and projectile stability. Barrel rifling, helical grooves cut into the bore, imparts spin to bullets at rates of 1:10 to 1:12 twists per inch, providing gyroscopic stabilization for ranges over 500 meters. Loading mechanisms, such as bolt actions or semi-automatic gas systems, ensure secure chambering and ejection, reducing misfires through interlocking components and pressure vents.[31][32]Types
Unguided Projectiles
Unguided projectiles are objects propelled by an initial velocity that follow a predetermined ballistic trajectory without any active control, guidance, or course correction mechanisms during flight. They rely solely on the physics of their launch conditions, such as muzzle velocity, angle, and environmental factors, to reach their target. Common examples include bullets fired from rifled firearms, arrows launched from bows, and cannonballs from smoothbore artillery, all of which exhibit free-flight behavior after propulsion.[33][34] Design features of unguided projectiles prioritize aerodynamic efficiency and stability to optimize range and accuracy under ballistic constraints. Many incorporate streamlined shapes, such as the ogive nose on bullets, which reduces aerodynamic drag and maintains velocity. Stability is often achieved through spin imparted by rifling—spiral grooves inside the barrel that rotate the projectile at rates up to 200,000 revolutions per minute—or by attached stabilizing fins on larger munitions like artillery shells. These elements ensure the projectile maintains a consistent orientation without external intervention.[35][36][37] The simplicity of unguided projectiles offers key advantages, including low manufacturing costs and ease of production, which enable their use in large quantities for area suppression or mass fire effects in combat. For instance, their lack of complex electronics reduces unit costs to a fraction of guided alternatives while maintaining reliability in harsh conditions. However, these projectiles suffer from disadvantages such as highly predictable trajectories that are vulnerable to crosswinds, gravity, and drag, resulting in accuracy degradation—often exceeding 100 meters circular error probable at extended ranges for artillery. This predictability limits their effectiveness against moving or hardened targets without precise initial aiming.[33] Historically, unguided projectiles like smooth lead balls fired from muskets formed the backbone of infantry engagements from the 17th to 19th centuries, providing reliable short-range lethality despite inherent inaccuracies. In modern warfare, they continue to play vital roles, such as depleted uranium penetrators in tank main gun rounds for the M1 Abrams, which leverage high density and velocity to defeat armored vehicles at ranges up to 3 kilometers. Artillery applications, including unguided 155mm shells, support both suppressive fire and precision strikes when integrated with advanced fire control systems.[38][39] Unguided projectiles encompass subtypes tailored to specific effects, such as kinetic energy penetrators that prioritize raw momentum for armor defeat and high-explosive shells designed for fragmentation and blast upon detonation. Kinetic energy penetrators, often constructed from dense materials like depleted uranium alloys with yield strengths around 140 ksi, achieve penetration through sheer velocity and self-sharpening during impact. In contrast, high-explosive variants, exemplified by the 155mm M107 shell filled with TNT or similar energetics, deliver area damage via controlled explosion after fuse initiation. Unlike guided projectiles that employ active corrections, unguided subtypes adhere strictly to ballistic paths determined at launch.[33][39][40]Guided Projectiles
Guided projectiles incorporate onboard or external systems to actively correct their trajectory during flight, enabling precise targeting compared to unguided variants that follow ballistic paths without intervention. These systems use sensors to detect deviations from the intended path and actuators to make real-time adjustments, such as through aerodynamic fins or thrust vectoring, thereby minimizing errors caused by wind, gravity, or launch imperfections.[41] The primary guidance principles include inertial navigation, which relies on gyroscopes and accelerometers to track acceleration and maintain orientation without external references; global positioning system (GPS) guidance, which uses satellite signals for real-time position updates; and laser homing, where a ground-based laser illuminates the target, and the projectile's seeker detects the reflected beam to home in. Inertial systems provide autonomous operation but accumulate errors over long distances, while GPS offers high accuracy in open environments but is vulnerable to signal disruption; laser homing excels in terminal phases for stationary targets but requires line-of-sight designation. These principles often combine in hybrid systems to enhance reliability across flight phases.[41][42] Development of guided projectiles traces back to World War II with early radio-command systems like the German Henschel Hs 293 glide bomb, which used operator control via joystick to steer toward ships, marking a shift from purely ballistic weapons. The V-1 "buzz bomb," deployed in 1944, represented an initial cruise-style projectile with a basic gyroscopic autopilot for straight-line flight and a preset odometer for cutoff, though its accuracy was limited due to lack of active correction. Post-war advancements accelerated during the Cold War, leading to sophisticated munitions by the 2000s, such as GPS-enhanced artillery shells that integrate inertial backups for jammed environments.[43][44] Key components of guided projectiles include seekers for target detection—such as infrared, radar, or laser sensors that acquire and track signatures; actuators, including servo-driven fins or canards for steering and thrust mechanisms for propulsion adjustments; and integrated warheads tailored for precision strikes to reduce collateral damage. Design challenges focus on achieving jamming resistance, particularly for GPS-dependent systems, where electronic countermeasures can degrade signals, prompting innovations like anti-jam antennas and inertial fallbacks to maintain functionality in contested airspace.[41][45] Representative examples illustrate these technologies: the BGM-71 TOW anti-tank missile, initially wire-guided in the 1970s, evolved with laser semi-active variants like the TOW-2B Aero, which use reflected laser beams for terminal guidance and achieve hits within meters of designated points. The Tomahawk cruise missile employs inertial navigation augmented by GPS and terrain contour matching, allowing low-altitude flight over 1,000 kilometers with updates from digital maps to evade defenses. In artillery, the M982 Excalibur 155mm shell uses GPS/inertial guidance with canard actuators, extending range to 40 kilometers while correcting for spin and environmental factors.[46][47] Accuracy improvements are quantified by circular error probable (CEP), the radius within which 50% of projectiles are expected to land; early guided systems like the V-1 had large CEPs, while modern examples such as Excalibur achieve less than 4 meters CEP, and Tomahawk variants reach under 10 meters, dramatically enhancing effectiveness over unguided baselines with CEPs in the hundreds of meters. These metrics underscore the shift toward "smart" munitions that prioritize precision to conserve ammunition and limit unintended impacts.[48][47]Wired Projectiles
Wired projectiles are guided missiles or similar devices connected to their launch platform by thin physical tethers, typically wires or fiber optic cables, which transmit control signals for real-time steering. This command-to-line-of-sight (CLOS) guidance system relies on the operator observing the projectile's position relative to the target through optical or infrared sights and sending corrective commands via the tether, enabling precise adjustments without onboard seekers.[41] The tether uncoils from spools on the projectile and launcher during flight, with signals modulated as electrical pulses in traditional copper wires or light pulses in fiber optics, ensuring low-latency control over distances up to several kilometers.[49] A prominent example is the BGM-71 TOW (Tube-launched, Optically-tracked, Wire-guided) anti-tank missile, developed in the 1960s by Hughes Aircraft and entering U.S. Army service in 1970. The TOW deploys dual copper wires from rear spools, allowing the gunner to track the missile via a stabilized sight unit and issue proportional navigation commands to steer it toward armored targets.[49] Another early system, the MGM-51 Shillelagh, used similar wire guidance for tank-launched applications in the 1960s, while the FGM-77 Dragon portable antitank missile employed wires for infantry use until its retirement in the 2000s.[41] These systems marked the first generation of transistor-based precision-guided munitions, prioritizing simplicity and reliability in battlefield conditions.[41] The primary advantages of wired guidance include high resistance to electronic jamming, as the physical tether avoids radio frequency vulnerabilities, and straightforward implementation requiring minimal onboard electronics for secure, real-time operator control.[41] However, disadvantages are significant: the tether limits range to the wire length, typically 3-4.5 km for systems like the TOW due to aerodynamic drag and spool capacity, and it can restrict maneuverability or snap under stress.[49] Technical specifications often feature wires as thin as 0.1 mm in diameter, wound on lightweight spools deploying at speeds matching the projectile (up to 300 m/s for TOW), with signal modulation using pulse-width techniques for steering vanes or thrusters.[49] Over time, wired systems evolved toward fiber optics for higher bandwidth and reduced weight, enabling video feedback alongside commands. The Enhanced Fiber Optic Guided Missile (EFOG-M), developed by Raytheon in the 1990s under a U.S. Army Advanced Concept Technology Demonstrator program, replaced copper wires with a bidirectional fiber optic datalink, transmitting real-time imagery from an onboard camera for non-line-of-sight targeting up to 15 km.[50] This upgrade addressed bandwidth limitations of electrical wires, supporting advanced imaging while maintaining jam immunity, though EFOG-M did not enter full production.[50] Beyond military applications, wired projectiles appear in non-combat contexts, such as tethered unmanned aerial vehicles (UAVs) for persistent surveillance. These systems use tethers to supply continuous power and data, enabling extended flights for environmental monitoring, traffic incident management, and emergency response without battery constraints.[51] For instance, tethered drones facilitate aerial imagery collection for highway safety assessments, hovering indefinitely via ground-supplied electricity over fiber or conductive cables.[52]Applications
In Sports
In sports, projectiles such as balls, arrows, and implements are propelled through the air under controlled conditions governed by rules that emphasize precision, distance, and safety. Common examples include the javelin throw in track and field, where athletes launch a spear-like implement for maximum distance; pitched baseballs in baseball, which curve or sink due to spin; arrows in archery for target accuracy; driven golf balls for long-distance flight; and soccer balls in free kicks, where aerodynamics influence trajectory. These activities trace back to ancient Olympic events like the discus throw, evolving from static releases to dynamic rotational techniques that enhance performance while incorporating modern safety protocols.[53][54] The javelin, a key projectile in athletics, features standardized specifications for men's competitions: a minimum weight of 800 grams and length between 2.6 and 2.7 meters, typically constructed from composite materials for durability and balance. Throwing mechanics involve a run-up to build speed, followed by a crossover step and explosive release above the shoulder to optimize distance and accuracy, with the implement's center of gravity positioned to promote a stable flight path. The men's world record stands at 98.48 meters, set by Jan Železný in 1996, reflecting advancements from ancient Greek throws to modern training that incorporates rotational momentum. In baseball, the official ball weighs between 142 and 149 grams with a circumference of 9 to 9.25 inches, made from a cork core wrapped in yarn and covered in leather; pitchers apply spin to induce the Magnus effect, causing curveballs to deviate laterally by creating uneven air pressure around the seams.[55][56][57] Archery projectiles, known as arrows, adhere to Olympic rules limiting tip diameters to 9.4 millimeters maximum, with shafts often made of lightweight carbon composites for reduced drag and improved stability during flight. Golf balls must have a diameter of at least 1.680 inches and weigh no more than 45.93 grams, featuring dimpled surfaces to minimize air resistance and promote lift via Bernoulli's principle. In soccer free kicks, players exploit aerodynamics by imparting side spin on the ball—typically weighing 410 to 450 grams—to generate the [Magnus effect](/page/Magnus effect), curving the trajectory unpredictably around defensive walls. The evolution from ancient discus events, where athletes threw from a standstill, to contemporary shot put incorporates full-body spins introduced in the 1970s, boosting distances while safety regulations mandate restricted zones, no gloves (only finger taping allowed), and defect-free implements to prevent injuries.[58][59][54][60][61]In Warfare
Projectiles have played a central role in warfare, serving distinct tactical functions to neutralize threats across various scales. Anti-personnel projectiles, typically unguided bullets fired from small arms such as rifles and machine guns, target individual soldiers to disrupt infantry advances and maintain fire superiority. Anti-armor projectiles, like armor-piercing (AP) rounds, are engineered to penetrate the thick plating of tanks and other armored vehicles, often using kinetic energy from high-velocity impacts to defeat protective layers. Area denial projectiles, including artillery shells that deploy anti-personnel mines or submunitions, create hazardous zones to impede enemy maneuvers and logistics, forcing adversaries into unfavorable positions. Historically, the strategic use of projectiles has shaped pivotal battles and doctrines. During the Battle of Agincourt in 1415, English longbow archers unleashed volleys of arrows—early unguided projectiles—that decimated French cavalry and infantry, leveraging massed fire to overcome numerical inferiority and muddy terrain. In World War I, machine guns firing rapid bursts of bullets transformed trench warfare, pinning down assaults and causing massive casualties, which compelled armies to adopt static defenses and prolonged the stalemate on the Western Front. Modern advancements have enhanced projectile lethality and precision while introducing ethical dilemmas. Cluster munitions, which scatter dozens of smaller projectiles over wide areas for anti-personnel and area denial effects, have been criticized for their indiscriminate nature, high failure rates leaving unexploded ordnance, and disproportionate civilian harm, leading to international bans under the 2008 Convention on Cluster Munitions. Precision-guided munitions, such as laser- or GPS-directed bombs, allow for targeted strikes with minimal collateral damage, revolutionizing aerial and artillery operations by enabling one projectile to neutralize high-value assets like command centers. Delivery systems vary by context: handheld launchers like shoulder-fired rocket systems for infantry, vehicle-mounted cannons on tanks for direct anti-armor engagements, and aerial dispensers from aircraft for standoff bombardment. Non-lethal projectiles provide alternatives for scenarios requiring restraint, such as urban operations or crowd control. Rubber bullets, deformable rounds fired from shotguns, deliver blunt force to incapacitate targets at short range without full penetration, while bean bag rounds—fabric pouches filled with pellets—spread impact energy to stun or deter groups, minimizing fatalities in riot suppression.Physics
Equations of Motion
In the ideal case of projectile motion, air resistance and other forces are neglected, allowing the trajectory to be modeled using basic kinematic equations under constant gravitational acceleration. The motion is decomposed into independent horizontal and vertical components, assuming a flat Earth and launch from ground level at initial speed v_0 and angle \theta above the horizontal. In the horizontal direction, there is no acceleration, so the velocity remains constant: v_x = v_0 \cos \theta. The horizontal position as a function of time t is then x = (v_0 \cos \theta) t. Vertically, the acceleration is the constant downward gravitational acceleration g = 9.8 \, \mathrm{m/s^2}, so the velocity is v_y = v_0 \sin \theta - g t. Integrating this acceleration yields the vertical position y = (v_0 \sin \theta) t - \frac{1}{2} g t^2. The time of flight, when y = 0 again, is t = \frac{2 v_0 \sin \theta}{g}, assuming symmetric trajectory. Substituting into the horizontal equation gives the range R = \frac{v_0^2 \sin 2\theta}{g}, which is maximized at \theta = 45^\circ where \sin 2\theta = 1. The maximum height occurs at t = \frac{v_0 \sin \theta}{g}, yielding H = \frac{v_0^2 \sin^2 \theta}{2g}. These derivations rely on the assumptions of negligible air resistance, constant g, and a non-rotating flat Earth, which hold for low-speed, low-altitude projectiles but limit accuracy for longer ranges. In real-world scenarios, air resistance introduces a drag force opposing the motion, typically modeled as \mathbf{F}_d = -\frac{1}{2} \rho v^2 C_d A \hat{v}, where \rho is air density, v is speed, C_d is the drag coefficient, A is cross-sectional area, and \hat{v} is the velocity unit vector. This quadratic drag term couples the horizontal and vertical motions, resulting in nonlinear differential equations: m \frac{d v_x}{dt} = - \frac{1}{2} \rho v^2 C_d A \frac{v_x}{v} and m \frac{d v_y}{dt} = -m g - \frac{1}{2} \rho v^2 C_d A \frac{v_y}{v}, with v = \sqrt{v_x^2 + v_y^2}. Analytical solutions for these equations are generally unavailable, so numerical methods are employed, such as the fourth-order Runge-Kutta algorithm, which iteratively approximates the trajectory by solving the system of ordinary differential equations with small time steps for high accuracy. These models adjust for variable air density and other effects to predict real trajectories more precisely. In applications like artillery, such equations form the basis for computing firing tables, which tabulate elevation angles and ranges for given charges under standard conditions, often using numerical integration to account for drag and incorporate initial velocities from propellants.Typical Speeds
Projectiles exhibit a wide range of initial velocities depending on their launch method and design, typically spanning from tens of meters per second for hand-thrown objects to over a thousand meters per second for high-powered firearms and artillery. Hand-thrown projectiles, such as a baseball pitched by a professional athlete, achieve speeds of approximately 42 m/s (94 mph) as of 2024, while an average adult throw might reach 20-30 m/s. Arrows from a compound bow typically exit at 70-100 m/s (250-300 fps), depending on draw weight and arrow mass. Small arms ammunition varies significantly: a 9mm pistol bullet has a muzzle velocity of about 350 m/s (1,200 fps), while rifle bullets can exceed 900 m/s. Artillery shells from a 155 mm howitzer reach 500-900 m/s at the muzzle.[62][63][64][65]| Projectile Type | Typical Speed (m/s) | Example |
|---|---|---|
| Hand-thrown (e.g., baseball) | 20-42 | Professional pitch: ~42 m/s (94 mph) as of 2024[62] |
| Arrow (archery) | 70-100 | Compound bow: 70-100 m/s[63] |
| Pistol bullet (9mm) | 300-400 | Muzzle velocity: ~350 m/s[64] |
| Rifle bullet | 600-1200 | High-velocity rounds: up to 1,000 m/s[66] |
| Artillery shell | 500-900 | 155 mm howitzer: 500-900 m/s[65] |