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Gun laying

Gun laying is the process of aiming an artillery piece, such as a gun, howitzer, or mortar, on land, at sea, or in the air, against surface or aerial targets by applying the required range, azimuth, and elevation settings to align the weapon with the intended target.^[1] This essential gunnery technique ensures accurate fire direction and has evolved from manual sighting methods to sophisticated instrumental and automated systems.^[2] Historically, gun laying originated in the 16th century with basic tools like the gunner's quadrant, invented around 1545 by Niccolò Tartaglia, which used a plumb bob and a graduated scale divided into 12 equal parts (each 7.5°) along a 90° arc to set elevation angles for range estimation.^[3]^[4] Early aiming involved direct visual sighting over the barrel or using simple dispart sights from 1610 to align the bore, often supplemented by handspikes for elevation adjustments and picks to measure alignment.^[3] By the 18th and 19th centuries, advancements included fixed rear sights, tangent sights for higher elevations, and trunnion sights, with telescopic sights emerging mid-19th century to enable indirect fire based on officer-calculated data rather than direct observation.^[3] During World War II, British and Allied artillery relied on dial sights for parallel orientation and reciprocal laying to align batteries, combining elevation setting with azimuth orientation relative to a known reference line.^[5] In modern field artillery, gun laying employs both direct and indirect methods to orient weapons on the azimuth of fire, using instruments like the M2A2 aiming circle for precise angle measurement in mils and the M2 compass for magnetic orientation when survey data is unavailable.^[6] Direct laying uses visible aiming points at least 1,500 meters away, while indirect laying depends on survey controls, GPS via the Precision Lightweight GPS Receiver (PLGR), or the Gun Laying and Positioning System (GLPS), which integrates laser rangefinders for enhanced accuracy in GPS-denied environments.^[6] These techniques, including reciprocal laying for parallel alignment and orienting angles derived from hasty surveys, support rapid battery setup and precise indirect fire missions.^[6]

Fundamentals

Definition and Principles

Gun laying is the process of precisely aligning an artillery piece, such as a gun or howitzer, by adjusting its horizontal traverse, known as azimuth, and vertical elevation to direct projectiles toward a target. Azimuth involves orienting the weapon in the horizontal plane relative to a reference direction, typically measured in mils or degrees from a north reference or line of sight, while elevation sets the barrel's angle above the horizontal to achieve the desired range and impact point. This alignment ensures the bore axis points accurately, enabling effective fire support in both land and naval contexts.^[6]^[5] Ballistic trajectories describe the curved path a projectile follows under the influence of external forces, distinguishing between direct fire, where the target is visible along a near-line-of-sight path using low-angle trajectories for shorter ranges, and indirect fire, which employs high-angle trajectories to arc projectiles over obstacles or terrain for targets beyond line of sight. Low-angle fire approximates a flatter path suitable for visible engagements, while high-angle fire, often exceeding 45 degrees elevation, allows for longer ranges and defilade positioning but requires precise calculations to clear intervening features. These modes are fundamental to artillery employment, with indirect fire being the primary method for field artillery to deliver suppressive or destructive effects from concealed positions.^[7] Key principles of gun laying account for environmental and physical factors affecting projectile motion, including gravity, which imparts a downward acceleration of approximately 9.81 m/s², causing the trajectory to arc; wind, which induces lateral drift and range variations depending on direction and speed; air density, which influences aerodynamic drag and thus reduces velocity and range in denser atmospheres; and the Coriolis effect, arising from Earth's rotation, which deflects projectiles to the right in the Northern Hemisphere, necessitating corrections for long-range shots. A basic approximation for the maximum range R in a flat trajectory under vacuum conditions (ignoring drag) is given by

R = \frac{v^2 \sin(2\theta)}{g}

where v is the muzzle velocity, \theta is the elevation angle, and g is gravitational acceleration; this equation highlights the optimal elevation of 45 degrees for maximum range but requires adjustments for real-world drag and meteorological effects to maintain accuracy.^[8]^[7] Gun laying principles apply differently to fixed platforms, such as emplaced coastal batteries offering inherent stability for precise, repeated adjustments, and mobile platforms, like towed or self-propelled artillery, which demand additional stabilization to mitigate movement-induced errors during setup. Effective gun laying is crucial for achieving first-round accuracy, minimizing adjustments and enabling rapid response in dynamic combat scenarios by integrating these factors into firing data computations.^[7]

Gun Mounts and Recoil Systems

Gun carriages support artillery pieces and enable adjustments for gun laying, with designs providing stability for accurate alignment. Early wooden frames with trunnions allowed basic elevation control, while later wheeled and split-trail carriages improved mobility and firing stability, as seen in 20th-century developments like the U.S. 75 mm gun M1916. Modern self-propelled mounts integrate with motorized chassis for rapid deployment. Recoil mechanisms absorb the energy from firing to keep the gun in position, preserving sight alignment and laying accuracy without repositioning after each shot. Hydro-pneumatic systems, using a hydraulic cylinder with fluid connected to a pneumatic chamber, compress during recoil and return the barrel to battery. The French 75 mm Canon de 75 modèle 1897 introduced an effective hydro-pneumatic recoil system in 1897, using a glycerin-water mixture as the hydraulic fluid, which enabled sustained firing rates up to around 20 rounds per minute—far higher than predecessors without such mechanisms, which required manual repositioning after shots. Traverse and elevation mechanisms facilitate precise angular adjustments for gun laying, evolving from manual hand cranks in early towed systems—such as screw-type or rack-and-pinion designs on the M101 howitzer—to powered hydraulic or electric drives in self-propelled artillery like the M109. Hand cranks, often via handwheels, provide fine control for horizontal traverse (up to 853 mils or approximately 48°) and vertical elevation in lighter field pieces. Hydraulic variants, using cylinders or motors, support broader ranges in modern mounts, with typical capabilities including 60° traverse for stability during indirect fire and elevations from -5° to +45° to accommodate varied terrains and trajectories.

Historical Development

Early Methods and Aids

In the 15th and 16th centuries, artillery evolved from cumbersome bombards to more mobile field pieces mounted on wheeled carriages or wagons, enabling deployment in battles and sieges across Europe.^[9] These early guns, often cast in bronze or iron, were aimed using rudimentary notch-and-post sights, where gunners visually aligned a rear notch with a front post blade to point the barrel toward the target. Such simple devices provided only coarse directional control, as the guns lacked mechanisms for precise traversal or elevation beyond manual adjustments with handspikes and wedges.^[9] A significant advancement came with Niccolò Tartaglia's invention of the gunner's quadrant around 1537, detailed in his treatise Nova Scientia.^[10] This brass instrument, featuring a right-angled frame with a pivoting arm and plumb line, was inserted into the gun's muzzle to measure the elevation angle directly, allowing gunners to set the barrel for desired ranges based on empirical ballistic knowledge.^[11] Tartaglia's quadrant marked a shift toward mathematical precision in gunnery, influencing artillery practices during sieges where accurate elevation was critical for battering fortifications over varying distances.^[12] Further progress in the early 17th century included William Eldred's development of range tables from 1613 to 1622, derived from systematic firing trials at Dover Castle.^[13] As Master Gunner, Eldred documented elevation angles and powder charges needed to achieve specific ranges for various cannon types, publishing these in his 1646 work The Gunners Glasse.^[13] These tables provided gunners with practical references, reducing reliance on guesswork and improving consistency in field and siege operations.^[14] By the mid-18th century, Benjamin Robins introduced the ballistic pendulum in 1742, a device that captured projectiles in a suspended block to measure muzzle velocity through the resulting swing.^[15] Described in his New Principles of Gunnery, this apparatus enabled the first accurate quantification of bullet speeds—often exceeding 1,000 feet per second for musket balls—facilitating experimental validation of ballistic theories and gun performance.^[15] Robins' invention played a pivotal role in early ballistics research, highlighting air resistance and velocity decay over distance.^[16] Early gun laying techniques involved manual alignment, with gunners using quadrants or protractors to set elevation while traversing the piece by eye or with levers. In sieges, quadrants were routinely employed to adjust for terrain and target height, as seen in 16th-century campaigns where they helped calibrate fire against walls.^[12] However, these methods suffered from inherent limitations in accuracy, primarily due to the lack of rangefinding tools; distances were estimated visually or via pacing, leading to wide dispersion patterns and frequent ranging shots.^[17] Without velocity measurements or standardized powder, trajectories varied unpredictably, often requiring massed batteries to compensate for individual gun errors.^[9]

19th-Century Innovations

The 19th century witnessed a pivotal transition in gun laying from manual, line-of-sight methods to more industrialized approaches, enabled by innovations in artillery design that extended effective ranges and improved firing rates. In the 1850s, Sir William Armstrong developed breech-loading rifled guns, which incorporated polygonal rifling and a coiled wrought-iron construction for enhanced durability and precision, allowing ranges up to 5 miles with greater accuracy than smoothbore muzzle-loaders.^[9] These guns, first demonstrated in 1859, marked a shift toward modern artillery by facilitating faster reloading and reducing crew exposure during fire. Building on this, in the late 1870s, Russian artillery designer Vladimir Baranovsky introduced quick-firing guns, including 2.5-inch field pieces with integrated recoil mechanisms and unitary cartridges, achieving firing rates of up to five rounds per minute and laying the groundwork for mobile, sustained barrages.^[18] Advancements in rangefinding further refined gun laying by providing objective distance measurements essential for longer-range engagements. Captain Henry S. Watkins of the British Royal Artillery patented a depression range finder in 1876, a telescopic instrument mounted on a stable base that calculated target range through the angle of depression from a known elevation, initially applied in coastal defenses to overcome visibility limitations.^[19] Complementing this, in 1891, the Scottish firm Barr & Stroud developed an early optical rangefinder based on stereoscopic principles, utilizing twin eyepieces to exploit parallax for distance estimation up to 10,000 yards, which the Admiralty adopted in 1892 for naval gunnery trials and later land applications.^[20] These devices shifted gun laying from estimation to measurement, enabling adjustments for elevation and bearing with reduced error. The origins of indirect fire, allowing guns to engage targets beyond direct line of sight, emerged as a response to entrenched warfare and improved projectile stability. In 1882, Russian Lieutenant Colonel K.G. Guk published Indirect Fire for Field Artillery, outlining practical techniques for laying guns from concealed positions using forward observers to relay bearings and ranges via aiming points, a method formalized in subsequent Russian artillery manuals.^[18] Around 1890, German artillery engineers invented the Richtfläche, a rotatable open sight mounted parallel to the gun barrel that aligned with map-derived azimuth lines for precise orientation in indirect laying, integrating topographic data to compensate for terrain obscuration.^[5] These innovations saw combat application during the Second Boer War, where on October 26, 1899, at the Battle of Elandslaagte, British forces employed Guk-inspired indirect fire techniques with 15-pounder guns to suppress Boer positions from cover, marking one of the earliest wartime uses and highlighting the tactical advantages of concealed laying over exposed direct fire.^[21] Concurrently, the introduction of tangent sights—graduated rear elevations calibrated for range, first standardized in British service by 1851—paired with emerging telescopic sights in the late 19th century enhanced direct and indirect aiming precision, as seen in updated field gun designs that incorporated optical magnification for finer bore alignment.^[22]

20th-Century Advancements

The 20th century marked a pivotal era in gun laying, driven by the demands of mechanized warfare during the World Wars, where mechanical predictors and early computational aids addressed the challenges of engaging fast-moving targets at extended ranges. Following the Boer War (1899–1902), indirect artillery fire—allowing guns to engage targets without direct line of sight—was standardized in British doctrine, relying on map-based ranging and forward observers to enhance tactical flexibility against entrenched positions.^[23]^[24] This shift laid the groundwork for more sophisticated systems, building briefly on 19th-century rangefinder foundations by integrating predictive mechanics for dynamic battlefields.^[25] During World War I, naval gun laying advanced through the independent efforts of British inventors Arthur Pollen and Frederic Dreyer, who developed early mechanical fire control systems incorporating gyroscopic stabilization to compensate for ship roll and pitch while tracking enemy vessels.^[26]^[27] Pollen's Argo Clock, for instance, used gyros to maintain accurate rate-of-change data for range and bearing, enabling continuous solutions without manual recalibration.^[27] For anti-aircraft defense, the Barr & Stroud UB2 height finder emerged as a key tool, featuring a 7-foot optical base operated by three personnel to measure aircraft altitudes up to 20,000 feet in clear skies via stereoscopic triangulation.^[28] In the interwar period and World War II, mechanical analog computers revolutionized trajectory solving for gun laying, automating calculations for ballistic arcs, wind deflection, and target evasion. The Vickers Predictor AA No. 1, introduced in 1925, exemplified this progress as an electromechanical analog device that integrated optical tracking data to forecast aircraft positions, producing real-time elevation and azimuth solutions for anti-aircraft guns.^[29]^[30] These predictors explicitly accounted for target motion—such as speed and course changes—and shell time-of-flight, typically 10–15 seconds for medium-caliber rounds, by solving differential equations through geared mechanisms to aim shells at future intercept points.^[31]^[32] By the war's end, such systems were standard in Allied forces, with U.S. adaptations like the Rangekeeper Mark 1 enhancing naval accuracy against surface and air threats.^[27] Post-World War II advancements in the early 1950s integrated radar into predictor frameworks, transforming gun laying for all-weather operations. The U.S. Navy's Mark 56 Gun Fire Control System, operational by the mid-1950s, paired the AN/SPG-35 radar tracker with a Mark 42 ballistic computer to automate targeting for 3-inch and 5-inch dual-purpose guns, providing precise range, bearing, and lead angle data even in low visibility.^[33] In coastal artillery, depression position finders advanced position determination through vertical triangulation from elevated observation posts, solving the geometric triangle of known battery height, angular depression to the target, and sea-level baseline to compute accurate firing data for long-range engagements.^[34]^[35] These innovations, peaking before the digital era, emphasized mechanical reliability and predictive precision for complex scenarios like anti-aircraft barrages and naval duels.

Technological Components

Sighting and Ranging Devices

Optical sights have been fundamental to gun laying since the 19th century, evolving from simple mechanical devices to more advanced optical systems. Early tangent sights, resembling oversized rifle sights with an acorn-shaped foresight and adjustable notched rearsight, were primarily used for direct fire in artillery, allowing gunners to align the barrel visually with visible targets.^[5] These gave way to telescopic sights, which magnified the target for improved precision in both direct and indirect laying, particularly in naval and field artillery applications by the early 20th century. Panoramic telescopes, such as those mounted on howitzers, enabled indirect laying by allowing gunners to sight on reference points while the gun barrel was oriented according to calculated azimuths, providing a wider field of view without direct target visibility. This evolution culminated in stereoscopic rangefinders integrated into sights, which used binocular vision to estimate range by fusing two slightly offset images, enhancing accuracy for anti-aircraft and coastal guns before World War II.^[36] Rangefinders, critical for measuring target distance in gun laying, relied heavily on optical coincidence principles in early designs. Coincidence rangefinders, such as those produced by Barr & Stroud starting in the 1890s, operated by aligning two separate images of the target through a single eyepiece or dual views, with the base length of the instrument determining resolution; for instance, their nine-foot models achieved ranges up to 10,000 yards with typical errors around 1-2% under ideal conditions.^[37] These devices were widely adopted in British naval and artillery systems, offering portability via tripod mounting and superior performance over earlier depression rangefinders for surface targets. By the mid-20th century, early electronic rangefinders emerged, including pulse-based laser models developed in the 1960s using ruby lasers, which measured distance by timing light pulse reflections and provided accuracies of about ±2-3 meters at 3.5 kilometers, though limitations like atmospheric interference restricted practical errors to around ±1% at longer ranges such as 10 kilometers.^[38] For anti-aircraft defenses, height finders specialized in vertical ranging to determine aerial target altitudes, integrating directly with gun elevation controls. The Barr & Stroud UB2, introduced in the early 20th century, was a prominent coincidence-type height/range finder with a 7-foot optical base, mounted on a tripod for mobile use and capable of measuring aircraft heights up to 20,000 feet by triangulating slant range and angle of elevation.^[39] These devices fed data into mechanical predictors or elevation mechanisms, allowing rapid adjustment of gun barrels to intercept fast-moving targets, though operator skill was essential to mitigate errors from motion or visibility.^[40] Key concepts in sighting devices include parallax-free alignment and their distinct roles in direct versus indirect laying. Parallax-free sighting, achieved through precise optical collimation in telescopic and panoramic systems, ensures the line of sight remains coincident with the gun bore regardless of eye position, minimizing aiming errors in dynamic conditions like shipboard use. In direct laying, sights like tangents or basic telescopes allowed gunners to point the weapon straight at visible targets, ideal for close-range engagements. Conversely, in indirect laying—prevalent for howitzers and long-range guns—devices such as panoramic sights facilitated orientation via external references or computed data, decoupling the sight line from the target for fire beyond line-of-sight.^[41]

Analog Fire Control Systems

Analog fire control systems were mechanical and electromechanical devices designed to process range, bearing, and environmental data from sighting instruments to generate precise firing solutions for artillery and naval guns. These systems, dominant from the early 20th century until the mid-1940s, relied on physical components like gears, cams, and differentials to perform continuous analog computations, solving complex ballistic trajectories without electronic processing.^[27] They integrated inputs such as target range, own-ship motion, wind drift, and projectile time-of-flight to adjust gun elevation and azimuth, enabling accurate hits against surface or aerial targets.^[42] Mechanical calculators formed the core of these systems, using gear-based mechanisms to solve trajectory equations iteratively. A prominent example was the Dreyer Fire Control Table, employed by the Royal Navy during World War I, which functioned as an analog computer accepting inputs for range, bearing, wind velocity, and ship speed to compute deflection and elevation angles.^[43] This table employed differential gears to account for relative motion and ballistic corrections, transmitting solutions to gun turrets via electrical follow-up signals. Similar gear-driven devices, such as the U.S. Navy's Mark 1 Fire Control Computer introduced in the 1930s, incorporated shafts and pinion gears to model projectile paths under varying conditions like temperature and air density.^[42] For anti-aircraft applications, predictors specialized in tracking fast-moving targets by forecasting future positions. The Vickers Mk III Anti-Aircraft Predictor, an analog computer used by British forces, plotted aircraft course, speed, and altitude to generate lead angles, compensating for projectile time-of-flight.^[30] The lead angle was computed approximately as \text{lead} = \frac{\text{target speed} \times \text{time-of-flight}}{\text{range}}, where time-of-flight derived from range and muzzle velocity; this equation, implemented via cam profiles, allowed guns to aim ahead of the target's line-of-sight.^[44] Such devices used servo-motors to update predictions in real-time, enhancing hit probabilities against maneuvering aircraft. Integration with gun mounts occurred through follow-up systems, where computed solutions drove remote control mechanisms on the turrets. In the U.S. Navy's Mark 37 Gun Fire Control System (GFCS), introduced during World War II, analog computers linked directors to mounts via gyro-stabilized servos, automatically adjusting for ship roll and target motion while applying corrections for parallax and drift.^[45] These systems employed differential analyzers—networks of cams and integrating wheels—to handle nonlinear ballistic effects, ensuring synchronized elevation and training of multiple guns.^[27] By the war's end, such integrations had significantly improved naval gunnery accuracy, with the Mark 37 enabling effective control of 5-inch dual-purpose batteries against both surface and air threats.^[46]

Modern Developments

Digital and Computerized Systems

The transition to digital and computerized systems in gun laying began in the late 20th century, marking a shift from analog mechanical devices to electronic computing for real-time ballistic calculations and aiming adjustments.^[47] This evolution was driven by advancements in microprocessors, which enabled faster processing of complex variables such as projectile trajectory, environmental factors, and target motion, surpassing the limitations of earlier electromechanical systems.^[48] In the 1990s, microprocessor-based digital sights were introduced, automating elevation and traverse adjustments through integrated sensors and computational algorithms.^[47] These systems replaced manual plotting with electronic interfaces, allowing for precise gun orientation based on input data like range and bearing, often achieving sub-milliradian accuracy in automated modes.^[48] Modern ballistic computers form the core of these systems, employing software that solves full exterior ballistics equations via numerical integration to account for drag, wind effects, Coriolis forces, and other influences on projectile flight.^[48] These computers interface with GPS for accurate position and orientation data, enabling rapid fire solutions without extensive manual surveys.^[47] For instance, the U.S. Army's M119A3 howitzer, introduced in 2013 with a digital fire control system, incorporates on-board ballistic computation and inertial navigation for self-location and auto gun pointing, reducing setup time to 2-3 minutes from 10 minutes.^[49]^[50] Post-1990s advancements include automated muzzle velocity radars, which measure projectile exit speed in real-time to refine ballistic models and correct for variables like propellant temperature or barrel wear.^[51] Systems like Weibel's MVRS, introduced in 1988, integrate with fire control computers to provide continuous velocity feedback, improving first-round hit probabilities in dynamic environments.^[51]^[52] As of 2025, the U.S. Army's Next Generation Command and Control (NGC2) prototype integrates AI-aided target recognition to enhance automated gun laying in artillery systems.^[53]

Sensor Integration and Automation

Modern sensor integration in gun laying systems has advanced significantly, incorporating laser rangefinders for precise distance measurement to targets, often integrated into fire control units on artillery platforms. These devices, such as the Lightweight Laser Designator Rangefinder (LLDR) AN/PED-1, provide highly accurate target coordinates compatible with GPS-guided munitions, enabling rapid adjustments in dynamic environments.^[54] Doppler radars complement this by measuring projectile muzzle velocity, essential for ballistic corrections; systems like the Weibel Scientific muzzle velocity radar use X-band continuous wave Doppler technology to achieve measurements from 30 to 3,000 meters per second with motion compensation for naval and land applications.^[55] Additionally, GPS-aided inertial navigation systems (INS), such as Safran's Geonyx Land, ensure accurate platform orientation and pointing for artillery mounts, allowing self-contained operation on vehicles or turrets regardless of mounting angle.^[56] Automation in gun laying leverages machine learning (ML) for target tracking and predictive aiming, building on digital computational frameworks to process sensor data in real time. The U.S. Army's Shrike prototype, for instance, employs computer vision and ML on unmanned aerial systems (UAS) to detect threats, geolocate them, and recommend firing corrections, improving accuracy by 50% over standard Expert Infantryman Badge benchmarks while reducing time to effective fire by 80%.^[57] In predictive aiming, AI algorithms analyze environmental factors like wind and terrain to optimize trajectories, as seen in systems that cut sensor-to-shooter processing times by up to 70% and enhance identification precision.^[58] Recent conflicts, such as the Ukraine war since 2022, demonstrate drone-integrated systems where AI-enabled UAS provide real-time targeting data to artillery units, outpacing traditional methods and reshaping fire support by fusing video feeds with gun laying computations for strikes up to 40 km deep.^[59] Networked systems further enable data fusion from diverse sources, including UAVs and satellites, to support automated gun laying. The AN/TPQ-53 counter-battery radar, a solid-state phased array system, detects and locates enemy indirect fire in 90-degree sectors up to 60 km or in 360-degree sectors up to 20 km, integrating with fire control networks to cue responsive counterfire and share data via systems like the U.S. Army's Forward Area Air Defense Command and Control (FAAD C2).^[60]^[61] In Ukraine, this approach mirrors networked operations where Delta software fuses inputs from NATO-compatible sensors and UAS, allowing artillery to receive fused target data from multiple platforms for automated adjustments.^[62] Such fusion reduces latency in threat response, with sensor networks stitching tracks from UAVs to create unified battlespace pictures for gun laying. Post-2020 discussions highlight ethical considerations in autonomous fire control, particularly around meaningful human oversight in lethal autonomous weapons systems (LAWS). Concerns include accountability for AI decisions in targeting, potential violations of international humanitarian law, and the risk of reduced human agency leading to unintended escalations, prompting calls for regulations ensuring human control in critical loops.^[63] These issues underscore the need for ethical frameworks in integrating AI into gun laying to balance operational gains with humanitarian principles.^[64]

Applications

Land-Based Artillery

In land-based artillery, gun laying primarily supports indirect fire, where the weapon's line of sight to the target is obscured, requiring precise calculations to direct projectiles over obstacles onto distant or hidden targets. This process begins with map plotting to establish the gun-target line (GTL), using tools like the Range-Deflection Protractor (RDP) and M17/M19 plotting boards to determine target grid coordinates, azimuth, and range from the firing position. Forward observers (FOs), positioned closer to the front lines, play a crucial role by detecting targets, transmitting call-for-fire messages with location data (via grid, polar, or shift methods), and adjusting fire based on observed impacts relative to the GTL. Once data reaches the fire direction center (FDC), it computes firing solutions, converting chart deflections to four-digit commands for azimuth dials and quadrant elevations using Graphical Firing Tables (GFTs) or Tabular Firing Tables (TFTs), which account for range, site (vertical interval between gun and target), and drift. The gunner then lays the piece by aligning the panoramic telescope to the azimuth of fire and setting the elevation dial, ensuring the howitzer points along the computed GTL for accurate delivery.^[65] Mobile systems like the M109 Paladin self-propelled howitzer integrate automated gun laying to enhance rapid deployment and survivability in dynamic battlefield conditions. Equipped with digital fire control systems, the M109A7 variant uses onboard computers to automate targeting, navigation, and laying processes, allowing crews to receive fire missions, compute azimuth and elevation, and lay the gun without manual plotting in many scenarios. This automation supports counter-battery roles, where the system quickly identifies and engages enemy artillery positions using integrated data from radars or observers. For instance, during fire missions, the Paladin can emplace, lay, and fire within minutes, then displace to avoid retaliation, leveraging its tracked mobility for repositioning over varied terrain.^[66]^[67] Historical applications of gun laying in land-based artillery include World War II creeping barrages, where coordinated indirect fire supported infantry advances by progressively shifting the barrage line forward at a controlled rate, typically 50-100 meters every few minutes, to suppress defenders ahead of assaulting troops. In the Battle of Cassino, for example, U.S. artillery provided a creeping barrage on 15 February 1944, with every piece on the front targeting the town to cover advancing forces, requiring precise laying adjustments to maintain the moving curtain of fire without endangering friendly units.^[68] Modern tactics build on this with GPS-assisted "shoot-and-scoot" operations, where systems like the M109 use satellite navigation to refine position data for laying, enabling fires within under 60 seconds of halting, followed by immediate relocation to evade counter-battery detection. This approach, emphasized in U.S. Army doctrine, minimizes exposure in high-threat environments by integrating GPS for accurate self-location and rapid computational laying.^[69] Terrain poses significant challenges to gun laying accuracy in land-based artillery, as uneven ground displaces individual guns from the ideal parallel alignment, distorting the sheaf (burst pattern) and reducing effectiveness on targets. For instance, in hilly or forested areas, guns may vary in elevation by several meters, altering muzzle velocities and trajectories, which can shift impacts by tens of meters without correction. To mitigate this, terrain gun position corrections (TGPCs) are applied using survey data or plotting boards like the M17 to adjust azimuth, elevation, and fuze settings for each piece, ensuring the sheaf remains converged within a 400-meter-wide by 200-meter-deep box relative to the center of sector. Hasty TGPCs, based on estimated displacements, provide quick fixes in mobile operations but are less precise than full surveys, highlighting the need for rapid terrain analysis to maintain lethality in restricted environments.^[70]

Naval and Coastal Systems

In naval fire control systems, turret mounts enabled remote power control of guns, allowing centralized operation from director towers that elevated spotting accuracy by coordinating multiple batteries against surface targets. These directors, often mounted on masts or superstructures, incorporated telescopic sights and rangefinders to track enemy ships, transmitting elevation and bearing data electrically to the turrets for synchronized firing.^[71] By World War I, such systems had evolved to include plotting rooms where operators calculated ballistic solutions, compensating for factors like wind and projectile drift to achieve ranges exceeding 20,000 yards.^[71] A primary challenge in naval gun laying was correcting for ship motion, including roll, pitch, and yaw, which tilted gun trunnions and disrupted the line of sight. Gyroscopic stabilizers addressed this by maintaining a stable vertical reference; for instance, the U.S. Navy's Stable Vertical device, paired with the Mark 1 fire control computer, used a high-speed gyroscope spinning at 12,000 RPM to detect and transmit tilt corrections via electrical signals, enabling accurate pointing even in rough seas.^[72] These gyros reduced errors from ocean-induced movements, with the system achieving vertical alignment in under five minutes on battleships and cruisers.^[72] One seminal advancement was Arthur Pollen's Argo system, introduced during World War I, which incorporated gyro-stabilized rangefinders for roll compensation and automated target prediction. The Argo Clock, a mechanical analog computer, integrated range, bearing, and own-ship course data to compute firing solutions independently of steering changes, while the gyrocompass-stabilized rangefinder (based on the Barr and Stroud FQ 2 model) minimized operator input by countering ship yaw and roll.^[73] Deployed on select Royal Navy dreadnoughts and battlecruisers, it enhanced long-range accuracy against maneuvering targets, though partial adoption limited its fleet-wide impact.^[73] Coastal defense systems adapted gun laying for fixed emplacements, emphasizing stability over mobility and using depression rangefinders to measure downward angles to sea-level targets beyond the horizon. These rangefinders, often integrated into battery command posts, allowed precise elevation settings for guns mounted in concrete casemates, with fire directed from elevated observation points.^[74] During World War II, German Atlantic Wall batteries exemplified this, featuring large-caliber guns such as 210 mm pieces at Crisbecq Battery in fortified positions along the Normandy coast, where rangefinder data fed into analog predictors for salvo fire against approaching naval forces.^[74] Modern naval systems increasingly employ hybrid missile-gun configurations, integrating rapid-fire guns with missile launchers under unified fire control to counter diverse threats like anti-ship missiles. For example, close-in weapon systems such as the Phalanx use 20mm guns alongside radar-guided interceptors, with Aegis combat systems providing overarching sensor fusion for seamless target allocation and engagement.^[75] These setups prioritize layered defense, where guns handle short-range intercepts and missiles extend coverage, all stabilized by advanced gyro-inertial units to mitigate platform motion.^[75]

Anti-Aircraft Defenses

Anti-aircraft gun laying requires precise prediction of fast-moving aerial targets, often involving three-dimensional tracking to determine intercept points and set fuse timings for airburst shells. Anti-aircraft predictors emerged as specialized analog computers during World War II, designed to calculate the future position of an aircraft based on its observed speed, direction, and altitude, thereby enabling guns to fire shells that would explode near the predicted trajectory.^[76] These devices integrated inputs from rangefinders and height finders to solve ballistic equations in real time, accounting for factors like wind and gravity to adjust for lead angles.^[77] Fuse timing mechanisms, often mechanically linked to the predictor, ensured shells detonated at the optimal proximity to the target, maximizing shrapnel effectiveness against aircraft structures.^[78] A prominent example from World War II is the Bofors 40 mm L/60 gun, paired with lead-computing sights such as the M7 or MK51 director, which automated lead calculations for engaging low-flying aircraft at ranges up to 3,000 yards.^[79] These sights used gyro-stabilized optics and mechanical computers to track targets and superimpose a reticle that indicated the required aiming offset, allowing gunners to align the gun barrel ahead of the aircraft's current position.^[79] The system's simplicity and reliability made it a staple for Allied forces, contributing to its widespread adoption on ships and ground emplacements for close-range defense.^[77] Height finders played a critical role in anti-aircraft gun laying by providing accurate elevation data, essential for vertical targeting in three-dimensional airspace. Optical height finders, such as those in the British High Angle Control System (HACS), used stereoscopic viewing to triangulate an aircraft's altitude, feeding this information directly into predictors for precise gun elevation adjustments.^[80] By the mid-20th century, radar-based height finders replaced optical models, offering continuous altitude measurements even in poor visibility, which improved overall targeting accuracy against evasive maneuvers.^[81] In modern anti-aircraft defenses, systems like the Phalanx Close-In Weapon System (CIWS) represent an evolution to fully automated, radar-guided gun laying for close-in threats. The Phalanx uses a search radar to detect incoming missiles or aircraft at ranges under 2 kilometers, then switches to a tracking radar that computes intercept points and controls a 20 mm Gatling gun to fire up to 4,500 rounds per minute.^[82] This integration eliminates manual aiming, allowing rapid response to high-speed targets that evade longer-range defenses.^[83] Following World War II, anti-aircraft defenses shifted toward guided missiles for medium- and long-range engagements due to their superior range and guidance capabilities, but gun systems were retained for close-in protection against low-altitude threats that missiles might miss.^[84] Guns like the Phalanx persist in this role, providing a cost-effective, high-rate-of-fire option for terminal defense.^[82] Key challenges in anti-aircraft gun laying stem from the extreme speeds of aerial targets, often exceeding 500 knots, and their evasion maneuvers, which complicate prediction and require sub-second adjustments to maintain accurate leads.^[85] These factors demand robust predictors and sensors to minimize aiming lag, as even brief delays can result in missed intercepts against agile threats.^[85]

References

[1]
The role of a Gun Layer - Great War Forum
Feb 14, 2019 · Gun laying is the process of aiming an artillery piece, such as a gun, howitzer, or mortar, on land or at sea, against surface or air targets.Missing: definition | Show results with:definition
[2]
Gunnery Laying by the Direct and Indirect Method - DTIC
This bibliography concerns the specific subject of gunnery fire direction known as gun or howitzer laying.Missing: definition | Show results with:definition
[3]
tools - NPS Interpretive Series: Artillery Through the Ages
Sep 11, 2003 · The gunner laid the long arm of the quadrant in the bore of the gun, and the line of the bob against the graduated quarter-circle showed the ...
[4]
LAYIND AND ORIENTING THE GUNS - British Artillery in World War 2
May 10, 2014 · Laying in elevation is a matter of aligning the barrel in the requisite angle from the horizontal plane (tangent) of the earth's surface. The ...
[5]
FM 6-50 Chptr 4 Laying the Battery, Measuring, and Reporting
The gun laying and positioning system (GLPS) supplements the M2A2 aiming circle, and will be the primary instrument used to orient howitzers in cannon units not ...
[6]
[PDF] Tactics, Techniques, and Procedures for the Field Artillery Manual ...
This field manual (FM) explains all aspects of the cannon gunnery problem and presents a practical application of the science of ballistics.
[7]
[PDF] Development of an Artillery Accuracy Model - DTIC
Dec 1, 2006 · In the external ballistics phase, the main forces acting on the projectile are gravity and air resistance. The trajectory of the projectile is ...
[8]
[PDF] Artillery Through the Ages. A Short Illustrated History of Cannon ...
In the dawn of history, war engines were performing the function of artillery (which may be loosely defined as a means of hurling missiles too heavy to be ...
[9]
Gunner's quadrant - Museo Galileo
Date: 17th cent. Materials: brass ... The model from which this example derives is described by Niccolò Tartaglia in Nova scientia (Venice, 1537).
[10]
The Geometry of War: Essay - History of Science Museum
In his text of 1537 inaugurating the 'new science' of artillery, Niccolò Tartaglia described a quadrant which was inserted into the muzzle of the gun.
[11]
EARLY USE OF ARTILLERY - War History - WarHistory.org
Dec 13, 2024 · ... use of the gunner's quadrant, in which the angle of elevation of a gun barrel was measured by inserting one leg of the quadrant into the ...
[12]
[PDF] English Civil War Artillery 1642-51 - Historia Militar
William Eldred, the Master Gunner at Dover Castle, wrote detailed descriptions of the composition of gun carriage parts. The common length of the cheeks was ...
[13]
British Cannon Design 1600 - 1800 - arc .id.au
17th Century cannon styles. During the 1600s orders for guns specified calibre, weight and length, but left the rest up to the skill and discretion of the ...
[14]
Artillery Swings Like a Pendulum... - The Napoleon Series
Robins' most important breakthrough was the invention of the ballistics pendulum, the first scientific instrument for measuring projectile velocity.
[15]
Benjamin Robins on Ballistics - arc .id.au
Robins ballistic pendulum. The ballistic pendulum, shown in Fig 2, consisted of an arm suspended from a frame with a broad iron plate as its swinging mass.
[16]
The Development of Artillery - Gibraltar National Museum
This poor accuracy meant that many cannon had to be used to increase the chances of hitting the target. Another major problem was the basic casting process ...Missing: limitations | Show results with:limitations
[17]
The History of Russian Artillery since the mid 19th century up to 1917
In 1872–1877, he created a whole 'family' of quick-firing guns. He worked out unitary artillery cartridges for the field and mountain cannons designed by him, ...
[18]
Range Finder | National Museum of American History
Henry Watkins, a captain in the Royal Artillery, obtained a British patent for a range finder in 1876. The instrument was soon adopted for service in Britain, ...Missing: depression | Show results with:depression
[19]
Barr and Stroud - Graces Guide
Jan 9, 2025 · 1892 The Admiralty adopted their competitive design for a rangefinder and gave them a contract for an initial six instruments. The mechanical ...Missing: stereoscopic | Show results with:stereoscopic
[20]
[PDF] Counter Battery Fire during the Gallipoli Campaign
• In 1882, Russian Lieutenant Colonel KG Guk publishes: Indirect Fire for Field Artillery / Field Artillery Fire from Covered Positions. • Late 1880's ...Missing: methods | Show results with:methods
[21]
Journal - Field Artillery of the British Army 1860-1960
Dec 4, 1972 · Sighting was also improved, and this was the first equipment to be supplied with a telescopic sight in addition to the usual tangent scale and ...
[22]
BEFORE 1914 - British Artillery in World War 2
May 2, 2015 · Some indirect fire using fairly primitive methods was used during the Boer War, particularly by a few howitzer batteries. Firing from behind ...Missing: standardization | Show results with:standardization
[23]
[PDF] Field Artillery: The Evolution of Indirect Fire Methods
This paper is intended to give a brief history of the evolution of indirect fire and the methods of target acquisition developed for field artillery over ...
[24]
SPIOENKOP: CURTAIN-RAISER TO INDIRECT FIRE by Ken Gillings
Back in 1899, the ordnance most suited for such an operation were the mountain guns of No 4 Mountain Battery, which had been left behind at Frere and were sent ...
[25]
A brief history of the gun - A technological perspective - Academia.edu
The earliest mechanical naval fire control systems were developed around the time of World War I independently by Arthur Pollen31 and Frederic Charles Dreyer32.
[26]
[PDF] The mechanical analog computers of Hannibal Ford and ... - MIT
Ford's answer to the merchant ship problem was the Computer Mark 6 -used with Gun Directors Mark 52 and 53. Although only about the size of a large wheel of ...Missing: laying | Show results with:laying
[27]
[PDF] About British searchlight units and anti-aircraft artillery during the ...
The range finder (the instrument closest to the viewer) is probably a Barr & Stroud UB2 type. Kent, 1976. No. 7 in a contemporaneous series of postcards ...
[28]
HACS: A Debacle or Just-in-Time? - NavWeaps
Feb 28, 2021 · Land-based AA (Vickers, Sperry or ARL predictors) was easier because the director and guns were planed-off level, and were static; measured ...
[29]
Vickers No.1 anti-aircraft predictor - Powerhouse Collection
The Vickers Mk III Anti-Aircraft Predictor is an analogue computer designed for plotting the current position, course and speed of incoming aircraft.
[30]
[PDF] sperry.pdf - MIT
Opera- tors enter an estimated “time of flight” for the shell when they first begin tracking. The predictor uses this estimate to perform its initial ...
[31]
Filtering Noise for Antiaircraft Gunfire Control - Oxford Academic
Nov 23, 2023 · Key to successful elimination of a target was the ability to predict its trajectory several seconds in advance.<|control11|><|separator|>
[32]
Gunnery Vol2 Gun Fire Control System Mark 56
The radar antenna is mounted on the director, and all radar indicators are in the control room. The system is operated by a crew of four men, including the ...Missing: US 1950s
[33]
Coast Artillery: Fire Control
Aug 5, 2022 · The triangle was solved mechanically by the observation instrument called a depression position finder (DPF). This system required but one ...Missing: advancements | Show results with:advancements
[34]
Evolution of Major-Caliber U.S. Coastal Defense Guns, 1888-1945
inventions of several officers. Special instruments were invented, including the vertical base line depres sion position finder. Telescopic sights were intro.Missing: advancements | Show results with:advancements
[35]
Rangefinders | Artillery Museum
WWII German Rangefinders. Before radar and other means, these stereoscope and coincidence rangefinders were part of the fire control systems for artillery.
[36]
Barr and Stroud Rangefinders - The Dreadnought Project
Dec 17, 2021 · The first Barr and Stroud instruments were developed in the 1890s in response to a call for rangetaking equipment meeting novel and somewhat ...Missing: 1891 | Show results with:1891
[37]
Laser radar: historical prospective—from the East to the West
A range up to 3.5 km was measured with the accuracy of 2 to 3 m. In 1963 to 1964, laser-based rangefinders were developed using ruby and gallium arsenide in ...
[38]
Can Fuse Settings Be Related to Time? - Great War Forum
Jan 16, 2010 · Instead the Height/Range Finder (HRF) was introduced. This was a Barr & Stroud UB2 coincident optical rangefinder with a 7 ft optical base ...<|separator|>
[39]
The Height & Range Finder - Battlefront Malta
Two instruments became commonplace to both Light and Heavy anti-aircraft positions, the 'height and range finder' and the 'predictor'.Missing: UB2 | Show results with:UB2
[40]
SIGHTS AND LAYING - British Artillery in World War 2
The basic procedure, explained in 'The Basics of Gunnery', was to orient the dial sights so that the guns of a battery were parallel in their zero line. This ...
[41]
https://nigelef.tripod.com/sights.htm
[42]
Dreyer Fire Control Table - The Dreadnought Project
Mar 25, 2025 · The Dreyer Fire Control Table was the Royal Navy's highest-level Fire Control instrument during World War I. ... Captain F. C. Dreyer's Fire ...Overview · Dreyer Table as CPU in a Ship... · Installation of Dreyer Fire...
[43]
Fire Control Formulas from World War 1 - Math Encounters Blog
Nov 23, 2013 · The book's Appendix contains a one-page summary of the fire control formulas that were solved by the analog computers used on the Dreadnoughts.
[44]
HyperWar: Gun Fire Control System Mark 37 Operating System
The standby condition of the Gun Fire Control System Mk 37 is its condition when targets are expected momentarily, but with no specific targets yet known. It is ...Missing: analog | Show results with:analog
[45]
History and Technology - Fire Control Systems in WWII - NavWeaps
Dec 11, 2017 · The Japanese, as in much of their naval technology, used the same methodology as their British mentors and used a "follow the pointer" system ...
[46]
Digital Gunfire - Armada International
Jan 23, 2018 · Digitisation is changing the way fire control of artillery is performed. Guns are becoming more responsive and arguably less reliant on a complex supporting ...
[47]
[PDF] History of Fire Control and the Application of Implementing ...
What is Fire Control? Acquisition of the target and the implementation of the functions necessary to maximize the effects on target. The functions.Missing: late | Show results with:late
[48]
M119A3 Howitzer - JPEO A&A - Army.mil
Digital Fire Control System (DFCS) to increase capabilities; Upgraded fixed recoil and Suspension Lock Out System (SLOS) can fire top charge at all angles ...
[49]
M119A2 howitzer upgrade to provide quicker firepower - Army.mil
The upgraded M119A2 will be equipped with a digital fire control system that includes an inertial navigation unit, guided-precision system technology and other ...
[50]
Tactical Muzzle Velocity Radar - Armada International
May 17, 2021 · Weibel's Muzzle Velocity Radar Systems (MVRS) were introduced in 1992, and has since then been in service with some 30 countries and on more ...Missing: automated 1990s
[51]
Lightweight Laser Designator Rangefinder (LLDR), AN/PED-1, 1A ...
The LLDR 2H provides highly accurate target coordinates to allow the Soldier to call for fire with precision GPS guided munitions. A Modification of in Service ...Missing: modern | Show results with:modern
[52]
Muzzle velocity measurement: Naval gun MVRS - Weibel Scientific
Muzzle velocity is measured using a radar system with FFT, digital signal processing, and motion compensation, measuring from 30 to 3,000 meters per second.
[53]
Geonyx™ Land: Inertial Navigation, Geolocation & Artillery Pointing
Geonyx™ is the most compact INS for its class of performance and can be mounted on any orientation on vehicles, turrets and artillery weapons. Hemispherical ...Missing: GPS | Show results with:GPS
[54]
AI Eye in the Sky Improves Artillery Fire Missions
The Shrike prototype merges machine-learning threat recognition and location capability with off-the-shelf unmanned aerial systems to augment artillery ...Missing: tracking predictive
[55]
Enhancing Tactical Level Targeting With Artificial Intelligence
Mar 1, 2024 · AI-driven targeting systems can revolutionize precision, accuracy and sensor-to-shooter capabilities, elevating the effectiveness and efficiency ...
[56]
Ukraine's AI drones are reshaping modern warfare as precision ...
Oct 24, 2025 · As soon as Ukrainian forces were able to strike 30–40km behind enemy lines, Russian artillery fire dropped off as the networks essential for it ...
[57]
AN/TPQ-53 Radar System | Lockheed Martin
The solid-state phased array AN/TPQ-53 radar system, or, Q-53, detects, classifies, tracks and determines the location of enemy indirect fire in either 360 or ...
[58]
Does Ukraine Already Have Functional CJADC2 Technology? - CSIS
Dec 11, 2024 · Ukraine has succeeded in integrating software from the United States' and NATO's weapons and command-and-control systems directly into Delta.
[59]
Lethal autonomous weapon systems (LAWS): meaningful human ...
Oct 28, 2025 · This article is concerned with three key ethical issues that arise from the use in military combat of Lethal Autonomous Weapons Systems (LAWS).
[60]
Full article: The ethical legitimacy of autonomous Weapons systems
ABSTRACT. Recent advancements in artificial intelligence have intensified debates on deploying Autonomous Weapons Systems (AWS) in warfare.
[61]
[PDF] TC 3-09.81 Field Artillery Manual Cannon Gunnery - U.S. Army
Apr 13, 2016
[62]
[PDF] Potential for Army Integration of Autonomous Systems by ...
Sep 1, 2019 · systems, such as the M109. Paladin, include comput- er software to help auto- mate the targeting process. Additionally, these systems are being ...
[63]
[PDF] TTP for the Field Artillery Cannon Gunnery - GlobalSecurity.org
This publication is designed primarily for the cannon battery. It is a how-to-train manual intended to provide general guidance to the commander and his ...Missing: dials | Show results with:dials
[64]
[PDF] ARTILLERY STRONG: Modernizing the Field Artiller for the 21st ...
This book covers modernizing the field artillery for the 21st century, from the Gulf War through the first two decades of the 21st century, including new ...
[65]
FM 6-40 Chptr 12 Terrain Gun Position Corrections and Special ...
Terrain gun position corrections will provide an acceptable effect on the target provided the firing unit's position is within a box 400 meters wide and 200 ...
[66]
Evolution of Naval Weapons - Naval History and Heritage Command
Apr 1, 2021 · To improve accuracy of fire, the fuze-setter was added to the other instruments of an anti-aircraft fire control set. This was a device with ...
[67]
Roll, Pitch and Yaw - Fire Control Problems and Mark 1/1A Solutions
Dec 11, 2017 · Movement of the ship due to roll pitch and yaw tilt the trunnions, which then causes the gun to be incorrectly pointed in the line of fire.Missing: laying challenges
[68]
Argo Aim Corrector - The Dreadnought Project
The Argo Aim Correction System was a family of devices intended to fully address the problem of engaging one moving ship at great range from another.Missing: WWI | Show results with:WWI
[69]
[PDF] Naval Gunfire Support of Amphibious Operations - DTIC
At Normandy, the German Navy, responsible for coastal defense of the Atlantic wall, had erected an impressive system of coastal defense batteries with guns.
[70]
Close-in Weapons Systems: The last line of defense
Sep 24, 2025 · Features include rapid-fire guns or missile launchers and advanced fire-control systems, often integrated with broader combat systems like Aegis ...
[71]
[PDF] A Short Operational History of Ground-Based Air Defense - DTIC
time, electric predictors were also used.19. Luftwaffe bombing attacks on Britain trailed off in 1941, as the Soviet campaign began to dominate German ...
[72]
[PDF] A Short Operational History of Ground-Based Air Defense - GovInfo
Three-inch antiaircraft battery of the 62d Coast Artillery trained at approaching plane of the 33d Pursuit Squadron,. Mitchel Field, New York, August 1941. 3.7- ...
[73]
[PDF] UNCLASSIFIED AD NUMBER CLASSIFICATION CHANGES TO ...
The present report concerns the use of statistical methods of prediction, particularly as applied to the control of anti-aircraft fire of large caliber at ...
[74]
40-mm Automatic Gun M1 (AA)-TM 9-252 - Part 4a
(5) When using these sights, the traversing and elevating hand cranks must be engaged (pushed in) and the oil gears of the remote control system must be ...
[75]
The British High Angle Control System (HACS) - NavWeaps
Dec 11, 2017 · The Mark 37 was the best heavy-AA fire control system of the war and the Royal Navy considered it to be far superior to any of their own HACS ...
[76]
Operational Characteristics of Radar Classified by Tactical Application
Mark 3 With 3'x12' Antenna on Mark 38 Director. DESCRIPTION: Medium wave fire control for main batteries. Type "A" range indication and pip-matching for train.Missing: 1950s | Show results with:1950s
[77]
MK 15 - Phalanx Close-In Weapon System (CIWS) - Navy.mil
Sep 20, 2021 · Primary Function: Fast-reaction, detect-thru-engage, radar guided 20-millimeter gun weapon system. Contractor: Raytheon Systems Company ( ...
[78]
Phalanx Weapon System | Raytheon - RTX
The Phalanx weapon system is a rapid-fire, computer-controlled, radar-guided gun that can defeat anti-ship missiles and other close-in threats on land and at ...
[79]
U.S. Navy Missile Defense: The Transition From Guns to Missiles
Sep 26, 2012 · The U.S. Navy began transitioning from guns to missiles in the 1950s due to the diminishing effectiveness of guns against aircraft and missiles.
[80]
The Exterior Ballistic Problem Of The Anti-Aircraft Gun | Proceedings
The problem of firing against aircraft is not an easy one; the difficulties of hitting a moving target on the water are sufficiently great.