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Grazing fire

Grazing fire is a core technique in military machine gun gunnery, defined as fire where the center of the cone of fire does not rise more than one meter above the ground, ensuring projectiles travel approximately parallel to the terrain. This low-trajectory method is achievable over level or uniformly sloping ground up to a maximum effective range of 600 meters and is considered the most effective form of direct fire for suppressing enemy infantry. In practice, grazing fire is employed primarily in defensive operations, such as along a unit's final protective line (FPL), where machine guns are positioned to interlock fires and cover the frontage while minimizing exposure through defilade. Gunners achieve it by setting rear sights to 600 meters, aiming at an estimated point on the FPL, and adjusting based on tracer observation or squad walkthroughs to identify and account for —areas where fire cannot reach due to terrain irregularities. Weapons like the M240 series are ideal for this technique, as they allow precise control to "search downward" by lowering the muzzle, preventing enemies from crawling underneath the fire envelope. The advantages of grazing fire lie in its ability to deliver continuous, devastating suppression that canalizes enemy movements and denies advances, often using paired guns separated by about 35 meters for overlapping coverage. It contrasts with , which occurs over high or irregular where the cone of fire rises above one meter, reducing effectiveness against ground-level targets. Proper implementation requires detailed planning, including range cards to record fire limits, ensuring maximum lethality in combat scenarios.

Definition and Fundamentals

Definition

Grazing fire is defined by as fire approximately parallel to the ground where the centre of the cone of fire does not rise above 1 from the ground. The provides an equivalent definition: fire approximately parallel to the ground where the center of the cone of fire does not rise above one meter from the ground. This firing technique utilizes a low-angle that skims the ground surface, thereby maximizing casualty infliction on exposed enemy troops by keeping projectiles in close proximity to the terrain. On level or uniformly sloping terrain, grazing fire achieves maximum effectiveness up to approximately 600 meters. Effective implementation of grazing fire necessitates machine guns or automatic weapons capable of sustained to ensure the required volume and dispersion within the cone of . It relies on foundational knowledge of trajectories to orient parallel to the ground, without requiring advanced ballistic calculations.

Cone of Fire and

The of fire describes the diverging, elliptical pattern formed by the trajectories of bullets fired in a burst from a , originating narrow at the muzzle and expanding with distance due to inherent factors such as barrel vibration, inconsistencies, and minor aiming errors. In this , the pattern typically maintains a consistent width of about 2 mils, ensuring that the spread remains predictable across ranges. For grazing fire specifically, the center axis of the is positioned to stay no more than 1 meter above the ground, creating a continuous that sweeps low over the to engage targets effectively. The trajectory of bullets in grazing fire follows a relatively flat, low-angle path that remains nearly straight for the initial 300 meters before gradually curving due to , in contrast to the steeper parabolic arcs produced in elevated or . This configuration relies on minimal elevation—typically near —to compensate for bullet drop, with the maximum grazing range approximated as the point where the projectile's descent matches the height of the weapon's muzzle above the ground, often reaching 600 meters for standard 7.62 mm machine guns such as the M240 on level or uniformly sloping terrain. Heavier machine guns, like the .50 M2, can extend this to around 700 meters under similar conditions by leveraging their flatter trajectories and higher velocities. Dispersion within the cone of fire manifests on the ground or target as the beat zone, an elliptical area of concentrated impacts where approximately 85 percent of rounds land, with its length decreasing and width increasing as range extends due to the steeper angle of bullet fall and the widening pattern. Key factors influencing the beat zone include the fire rate, which determines round density—higher rates like 650–950 rounds per minute for the M240 fill the zone more densely—and terrain slope, where downward inclines elongate the zone while upward slopes shorten it. Only the central portion of this zone is considered fully effective for suppression, emphasizing the need to align it with likely enemy positions.

Historical Development

Origins in Early Machine Gun Use

The Maxim gun, invented by American-born engineer Hiram Stevens Maxim in 1884, represented the first practical fully automatic machine gun and laid the foundation for grazing fire tactics by enabling sustained, high-volume fire along a low, level trajectory ideal for defensive positions. Maxim promoted the weapon as a means to deliver devastating suppressive fire against advancing , emphasizing its ability to replace traditional rifle volleys with continuous bursts that could "mow down" attackers over open ground, thereby shifting emphasis from offensive maneuvers to fortified lines. Early adoption of such tactics occurred in colonial conflicts, where machine guns proved their value in repelling mass charges. In the 1898 during the Anglo-Egyptian reconquest of , British forces under Major-General Horatio Kitchener employed 24 machine guns, including 20 , alongside artillery to unleash sweeping, close-range fire—often at 300 to 500 yards—against the Mahdist forces, totaling approximately 52,000, with waves of charging Dervishes, resulting in over 10,000 enemy casualties while British losses remained minimal at 48 killed. Eyewitness accounts describe the ' bullets creating deadly "streams" that scythed through the attackers across flat terrain, exemplifying the low-trajectory patterns later formalized as grazing fire. By the late 1890s and early 1900s, military tacticians began codifying in manuals as low-angle, skimming fire effective up to 500-600 meters, distinct from higher-trajectory used over obstacles. British doctrinal evolution, influenced by colonial experiences, saw the 1902 Musketry Course abandon rigid in favor of dispersed, covered positions, while the 1911 Course stressed depth engagement and fields to maximize beaten zones along predictable enemy approaches. Pre-World War I European doctrines further refined these concepts, with and theorists distinguishing grazing fire's flat path for direct suppression from plunging fire's arcing delivery for enfilade or overhead support. French writings prioritized direct-fire integration for offensive , while regulations from 1903 onward emphasized flexible infantry-machine gun coordination under Auftragstaktik to achieve fire superiority at 800 meters or less. In the United States, experiments from 1900 to 1914, including tests of , , and Benét-Mercié models at , explored reliability and placement, culminating in the 1913 Field Service Regulations that advocated tactics linking machine guns to for mutual support in defensive and advancing roles.

World War I and II Applications

During , grazing fire became a cornerstone of defensive tactics in , particularly through the use of interlocking fields of fire across no-man's-land to maximize casualties on advancing . German forces prominently employed the MG08 heavy machine gun in fortified nests during the in 1916, where these positions delivered devastating grazing fire that swept open ground within effective ranges of up to 600 meters, contributing to the British Army's staggering 57,470 casualties on July 1 alone, with machine guns accounting for a significant portion of the losses in exposed charges. The flat of the MG08 allowed for effective enfilade coverage, turning assault waves into slaughter as troops emerged from trenches into beaten zones of low-trajectory bullets, though its maximum extended to approximately 2,000 yards for other fire types. British forces adapted grazing fire doctrine post-1915, integrating machine guns into defensive perimeters to create overlapping fields that protected flanks and approaches, a shift formalized in training emphasizing sustained, low-angle fire for area denial. This adoption enhanced static defenses, reducing vulnerability to counterattacks by ensuring continuous suppression of enemy advances within . In the , doctrines continued to evolve; for instance, British experiments with the gun explored mobile applications of grazing fire, while German developments leading to the MG34 emphasized rapid deployment for defensive fire superiority. U.S. standardized grazing fire for the .30-caliber M1919 , as detailed in FM 23-55 (1940), which defined it as fire where the cone's center remains below standing-man height over level or uniformly sloping ground, prioritizing it for defensive engagement due to its superior beaten zone length compared to . In the Pacific theater, U.S. Marines at in 1942 used M1919s to establish grazing fire along jungle approaches and beachheads, as exemplified by John Basilone's defense of Henderson Field, where sections provided interlocking low-trajectory fire to repel nocturnal infantry assaults, inflicting heavy Japanese losses amid close-quarters fighting. European theater applications peaked in during 1944, where German defenders in hedgerows employed enfilade grazing fire from MG42 and MG34 s emplaced at field corners, creating deadly crossfire bands along embankment bases that contributed to a significant portion (often over 50%) of casualties in some assaults through combined direct and indirect effects. This tactical setup forced doctrinal evolution toward integration, with U.S. forces adapting by mounting on to elevate above grazing zones, using engineer-modified "rhinoceros" hedgerow cutters for breakthroughs, and synchronizing tank suppressive fire with maneuvers, which reduced exposure and enabled advances like with fewer than 200 casualties in key phases. Overall, grazing fire proved highly effective against unprotected assaults in these battles—evidenced by high kill rates in open advances—driving this shift and emphasizing coordinated firepower to neutralize machine gun dominance and minimize vulnerabilities.

Techniques of Employment

Establishing Grazing Fire

Establishing grazing fire begins with careful siting of machine gun positions to ensure the center of the cone of fire remains no more than 1 meter above the ground over level or uniformly sloping terrain, creating a continuous beaten zone that maximizes coverage against personnel targets. Positions are selected to align the weapon with the long axis of the target area, such as along a final protective line (FPL), and to interlock fields of fire with adjacent weapons for comprehensive coverage up to 600 meters. This setup leverages the natural dispersion of the cone of fire to form an impassable barrier without requiring precise aiming at individual targets during bursts. Medium machine guns, such as the M240B, are preferred for establishing grazing fire due to their sustained fire capability and , typically mounted on a like the M122A1 for stability during prolonged engagements. Preparation involves initial zeroing of the weapon at 300 to 700 meters—preferably 500 meters—to compensate for , using 6- to 9-round bursts observed via tracers or impact to adjust the traversing and elevating (T&E) mechanism at 1 per click. Traverse limits are then set based on the terrain profile, employing base stakes or notched aiming stakes to mark the direction of the FPL and sector boundaries, ensuring the gunner can maintain alignment without excessive repositioning. Fire control measures are essential to direct grazing fire effectively, starting with the designation of primary and secondary sectors by the to prioritize the most likely enemy avenues of approach while providing overlapping support. is achieved using aiming stakes for sector limits or the T&E for precise adjustments, with panoramic sights available on some configurations to aid in low-light or obscured conditions. The sustained is maintained at 100 to 200 rounds per minute in 5- to 7-round bursts to preserve barrel life and while ensuring sufficient density within the cone of fire for suppressive effect. Commands—delivered orally, via arm-and-hand signals, or prearranged triggers—control initiation, distribution, and cessation, with range cards documenting sectors and limits for rapid reference.

Adjusting for Terrain and Dead Space

In grazing fire employment, terrain variations necessitate precise adjustments to the weapon's elevation to preserve the 1-meter maximum height of the cone of fire above the ground, ensuring effective coverage over non-uniform surfaces. On sloping ground, such as uphill , the gunner raises the to compensate for the rising surface and prevent the from exceeding the desired height prematurely; for instance, this may involve incremental increases based on the slope's to maintain low-angle fire relative to the incline. Downhill slopes require lowering the muzzle to avoid excessive bullet drop creating unintended . Prior to final positioning, thorough is conducted to map changes, identify potential disruptions, and pre-plan these adjustments, often using tools like rangefinders for accurate profiling of the sector. Dead space consists of terrain features—such as depressions, folds, or ravines—where the bullet trajectory passes more than 1 meter above potential targets or entirely overhead, rendering direct ineffective in those zones. Identification occurs post-setup through practical tests: in the preferred walking method, a member traverses the final protective line (FPL) or principal direction of fire (PDF) while the maintains aim, marking distances where the walker's waist drops below the ; alternatively, tracer rounds are fired and observed from a flank or rear to visualize breaks in the fire envelope. and are annotated on range cards for ongoing reference. Mitigation strategies focus on overlapping coverage and supplementary fires to eliminate vulnerabilities in . Weapons are repositioned or alternated to interlock fields of fire, with guns pushed to flanks where possible to maximize extent while minimizing gaps. Searching fire techniques involve rhythmic elevation adjustments—lowering the muzzle into depressions during bursts—to probe and cover irregularities. For persistent , integration with weapons like mortars or automatic grenade launchers provides plunging trajectories to engage otherwise shielded areas.

Tactical Applications

Defensive Tactics

In defensive operations, grazing fire serves as a primary mechanism for area denial and the protection of fixed positions, particularly through final protective fires (FPF) delivered along perimeters to halt enemy assaults. This technique employs low-trajectory fire that skims the ground, typically pinning attackers at ranges of 200 to 500 meters by creating a dense barrier of projectiles that forces suppression and disrupts advances. fields of grazing fire from multiple weapons further enhance this role, forming "walls of lead" that cover likely enemy avenues of approach and prevent breaches by overlapping sectors without gaps. Integration of grazing fire into broader defensive frameworks emphasizes strategic placement within strongpoints, where typically 1 to 2 machine guns per sector are positioned to maximize coverage of engagement areas and minimize . These weapons are sited to enfilade key terrain features, ensuring mutual support across lines while coordinating with obstacles and indirect fires for layered . In urban settings, grazing fire is adapted by using barriers such as walls, vehicles, or debris to channel enemy forces into designated kill zones, where low-angle trajectories exploit narrow streets and open spaces for effective suppression despite terrain complexities. U.S. Army , as outlined in ATP 3-21.8 (2024), underscores grazing fire's squad-level employment in defensive tactics, recommending its use in battle positions to achieve fire superiority through preplanned FPLs that integrate with fire support plans. This approach has demonstrated effectiveness in simulations and training exercises by significantly reducing enemy penetration rates.

Offensive Support

In offensive operations, grazing fire serves a critical suppressive role by establishing fire superiority from positions in covered and concealed , thereby fixing enemy forces and preventing effective return fire or . Machine typically engage at ranges of 400 to 600 meters, delivering controlled bursts of 6 to 10 rounds to degrade enemy observation, movement, and weapons employment, allowing friendly or mechanized elements to advance under protection. This technique maximizes the beaten zone's coverage parallel to the , with the center of the cone of fire maintained less than 1 meter above the surface for optimal effect against prone or low-postured targets. Grazing fire integrates seamlessly into tactics, providing direct support for assaults and vehicular advances, such as those conducted by Fighting Vehicles equipped with coaxial machine guns. In the assault phase, support-by-fire elements initiate grazing fire to suppress objectives, then execute a shift or lift of fires as maneuvering units close on the enemy to avoid or masking. During subsequent consolidation and reorganization, gunners may displace forward to reestablish grazing fire, securing newly gained terrain against counterattacks and enabling exploitation by follow-on forces like armored elements. Despite its effectiveness on relatively level terrain, grazing fire proves less suitable in rough or undulating environments, where and elevation changes cause the to rise unpredictably, reducing coverage and increasing vulnerability to enemy counterfire. In settings, fire's low-angle delivery is often obstructed by structures and , limiting its suppressive utility in close-quarters battles; forces adapt by prioritizing short-range from crew-served weapons or supplementing with indirect fires.

Comparisons to Other Fire Types

Versus Plunging Fire

Plunging fire refers to fire in which the is confined primarily to the beaten zone, occurring when the rises significantly above the ground before descending steeply onto the . This type of fire is characterized by a high-angle , typically resulting from engagements at long ranges beyond the maximum for grazing fire, when firing from to low ground, from low to , or across uneven that causes the projectiles to drop abruptly. Mechanically, the cone of fire in plunging fire impacts in a shorter and wider beaten zone compared to other types, with reduced consistency due to the steeper descent, which limits the overall to the immediate area of impact rather than extending along the flight path. In contrast to grazing fire, which maintains a low where the center of the of rises no more than 1 meter above the ground to maximize in the beaten on open, level terrain, plunging features a pronounced in the path, often exceeding 1 meter and creating a more elliptical impact pattern. Grazing fire is highly lethal against prone troops across a wide frontal area up to approximately 600 meters for light and medium machine guns, as the near-parallel path to the ground ensures continuous threat exposure, whereas plunging sacrifices this broad coverage for the ability to engage targets obscured by terrain rises or beyond line-of-sight, such as on reverse slopes or in defilades, though at the cost of lower accuracy and a more confined effective . Additionally, grazing fire's effectiveness is constrained by visible terrain and that interrupts the low arc, while plunging fire's precision is challenged by wind, changes, and the need for precise range estimation over distances often exceeding 1,000 meters. Selection between grazing and plunging fire depends on terrain, range, and tactical objectives: grazing fire is preferred for frontal assaults or defensive positions on uniformly sloping ground to deny enemy advances through dense, low-level suppression, whereas is employed when overhead cover or elevation differentials necessitate firing over obstacles, such as engaging enemy positions on hill crests or in urban settings from elevated vantage points. Trajectory characteristics further distinguish the two, with grazing fire maintaining a shallow to keep projectiles skimming the surface, compared to plunging fire's steeper descent, which enables beyond-line-of-sight engagement but reduces the zone of instantaneous danger.

Versus Direct and Indirect Fire

Grazing fire differs from primarily in its application and precision. involves point-to-point aiming at specific targets using line-of-sight, such as anti-tank guns or shoulder-launched munitions like the TOW missile, which achieve high accuracy against vehicles or fixed positions by aligning sights directly on the objective. In contrast, grazing fire employs automatic weapons to deliver over an area, with the center of the cone of fire maintained no more than 1 meter above the ground, trading pinpoint precision for sustained volume to pin down dispersed across a beaten zone. This makes grazing fire less suitable for engaging armored vehicles, where 's targeted trajectory is essential for penetration, but highly effective for denying enemy movement in open terrain. Compared to , grazing fire requires uninterrupted visibility of the target area, as it follows a near-horizontal without arcing over obstacles. , such as from mortars or , uses a curved path from defilade positions where the firer cannot see the target, relying on forward observers for adjustments to impact deep or obscured objectives. Grazing fire enables immediate, responsive suppression in close-range engagements, up to 600-700 meters on level ground, whereas 's setup time and delay make it better suited for longer-range or hidden targets beyond direct line-of-sight. As a variant of tailored for automatic weapons like the M240B or , grazing fire integrates into hybrid tactics by combining with indirect support to cover —areas shielded by terrain where the low trajectory cannot reach. U.S. Army in FM 3-21.8 emphasizes grazing fire for final protective lines in close-range defense, preferring it over indirect fire's slower response to halt assaults effectively, while ensuring safety limits like a 350-meter minimum distance from friendly troops.

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