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Wire-guided missile

A wire-guided missile is a type of guided munition that directs its flight path through command signals transmitted via thin, unspooling wires connected between the missile and its launch platform or control station. This guidance method, often implemented as a semi-automatic command to (SACLOS) system, allows an operator to track the target optically while the missile's position is monitored—typically via an beacon—and corrective commands are sent in to steer control surfaces or fins. Wire guidance provides high precision at short to medium ranges, typically up to 3,000–4,000 meters, and is resistant to electronic since it relies on physical wires rather than radio frequencies. The concept of wire guidance emerged during , with developing early examples such as the , which used thin wires up to 4 miles long to relay commands from the launching , achieving a range of about 2,700 yards. Early precision-guided munitions like the radio-guided demonstrated its potential, enabling strikes such as the sinking of the battleship in 1943. Post-war, the technology evolved primarily for anti-tank applications during the , with the French SS-11 (introduced in the mid-1950s) becoming one of the first production wire-guided anti-tank missiles, featuring a two-strand wire link for manual control. The advanced the field with the system, conceived in 1961 and entering service in 1970, which combined tube-launching, optical tracking, and wire data links for reliable hits against armored vehicles. Wire-guided missiles have been widely adopted for ground-based anti-armor roles, with notable systems including the American (a man-portable variant fielded from 1975 to 2001), the European (deployed since 1972), and the Soviet AT-3 Sagger (introduced in the 1960s). These weapons typically employ (HEAT) warheads with penetration capabilities ranging from 400 mm to over 900 mm of rolled homogeneous armor, depending on the model, and can be launched from infantry tripods, vehicles like the M113 or , or helicopters such as the AH-1 Cobra. While effective in line-of-sight engagements and operational in adverse weather, limitations include wire breakage risks, restricted maximum range due to wire spool size (often 3–4 km), and the need for the operator to maintain visual contact, making them vulnerable to . Over 700,000 TOW missiles alone have been produced and used by more than 40 nations in conflicts from (first combat use in 1972) to recent operations in and the .

Fundamentals

Definition and Principles

A wire-guided missile is a type of that directs its flight path through electrical signals transmitted along thin wires that connect the missile to its launch platform, uncoiling progressively as the missile travels. This guidance method falls under the broader category of systems, where corrective instructions are sent from an external controller—either manually operated or semi-automated—to adjust the missile's trajectory in . The wires serve as a direct, physical communication link, enabling precise control without reliance on radio frequencies, which can be susceptible to . The fundamental principle of wire guidance involves maintaining the missile on a line-of-sight (LOS) path to the , typically using techniques adapted for command systems. An or tracks the target visually or optically, while a separate monitors the missile's position relative to that LOS; any deviation generates commands that are encoded and sent via the wires to the missile's control surfaces or thrusters. This closed-loop feedback ensures the missile intercepts the by continuously correcting its course, with signal transmission occurring at rates sufficient for stable flight control. Early systems primarily used wires for electrical , often with strength members to balance conductivity and tensile strength. Key components include the guidance wires themselves, which are typically thin—for variants—to minimize weight and drag while carrying electrical signals. These wires are stored on spools within the missile's tail section, designed to unreel smoothly at speeds matching the missile's , often up to 200 m/s, preventing excessive or breakage during maneuvers. The launch houses the command electronics that generate and transmit these signals, ensuring reliable proportional adjustments for . Operational ranges for wire-guided missiles are inherently limited by the maximum length of the deployable wire, generally spanning 2 to 8 km depending on the system design and wire type, beyond which the connection severs and guidance is lost. Additionally, the requirement necessitates unobstructed visibility between the launch platform, , and target, restricting use to relatively open environments and shorter engagement distances.

Guidance Mechanism

In wire-guided missiles, the guidance mechanism relies on a system where the operator or automated tracker maintains the missile's alignment with the (LOS) to the . The process begins with the operator using optical sights or sensors mounted on the launcher to simultaneously track both the and the missile's position during flight. Deviations from the desired LOS are calculated in , either manually by the operator or semi-automatically by the , which generates steering commands for and yaw adjustments. These commands are converted into electrical impulses and transmitted to the missile via trailing wires, where onboard receivers interpret the signals to actuate surfaces, such as aerodynamic fins or nozzles, ensuring the missile corrects its trajectory toward the . The wires themselves serve as the primary communication link, typically consisting of thin, lightweight strands in early electrical systems that carry analog signals for basic command pulses. These electrical wires are spooled within the and pay out progressively as it travels, maintaining a continuous connection to the launcher despite the 's speed and maneuvers. Some advanced configurations employ fiber-optic cables, enabling with significantly higher —often exceeding 200 MB/s—to support bidirectional communication, including real-time video feeds from -borne sensors back to the . This upgrade allows for enhanced precision and resistance to environmental interference, though the core command principle remains analogous. Control methods vary by system sophistication, primarily encompassing manual command to line-of-sight (MCLOS), where the directly issues proportional steering corrections based on visual tracking of the relative to the ; semi-automatic command to line-of-sight (SACLOS), in which the launcher automatically computes and transmits deviation corrections while the only maintains the sight on the ; and closed-loop variants that infer the 's position through auxiliary means, such as beacons on the tail, to refine command accuracy without constant visual confirmation. These methods ensure the remains on the LOS until impact, with signals updating at rates sufficient for stable flight . Technical challenges in this mechanism include preventing wire breakage, which can occur due to aerodynamic stresses or sharp maneuvers, often mitigated by using ultra-thin, high-tensile materials and optimized payout mechanisms to minimize tangling or snapping. Signal attenuation over distance poses another issue in electrical wire systems, degrading command fidelity beyond a few kilometers and limiting , whereas fiber optics largely circumvent this through low-loss transmission. Finally, integration with missile servos demands precise synchronization, as actuators must respond rapidly to impulses without introducing delays or nonlinearities like , which could destabilize the unstable common in such designs.

Historical Development

Early Concepts and Prototypes

The concept of wire guidance for projectiles originated in the late 19th century with the Brennan torpedo, invented by Australian engineer Louis Brennan and adopted by the British Royal Navy in the 1880s and early 1900s as a shore-based defense weapon. This electrically controlled underwater projectile used two contra-rotating propellers driven by differential wire tension from a shore station, allowing steering over distances up to 2,000 yards at speeds of 20-30 knots, marking the first practical application of wire-guided propulsion for naval ordnance. In , began experimenting with wire guidance for aerial bombs to enhance precision against naval targets, building on radio-control prototypes amid concerns over signal jamming. These efforts culminated in the Ruhrstahl X-1 , developed from 1938 under Max Otto Kramer, which initially used radio guidance but incorporated wire-link variants with trailing spools to transmit control signals directly from the launch aircraft, achieving drops from altitudes up to 20,000 feet. During , wire guidance advanced significantly in German prototypes, with Professor leading the development of the series starting in 1940 at Henschel Flugzeugwerke. The Hs 293B variant, tested in 1943-1944, employed a wire-guidance system using up to 12 kilometers of thin cable unreeled from wingtip spools to counter Allied , enabling line-of-sight control via audio-frequency signals for anti-shipping strikes, though it saw limited trials without combat deployment. Concurrently, the , initiated in summer 1943 under Kramer's team, represented a pioneering wire-guided effort against bombers, featuring 0.009-inch wires up to four miles long spooled on wingtips to relay commands from the launching fighter, such as the Me 262. Approximately 25 prototypes were tested by , demonstrating effective control at speeds over 500 mph, but production halted due to the war's end. Key challenges included wire spool reliability under high-speed aerodynamic stresses, where tension and unreeling could cause breaks or tangles, limiting practical range and complicating recovery mechanisms. Following Germany's surrender in , Allied forces captured prototypes like the X-4 and Hs 293, along with technical documents and engineers, which informed early post-war guidance programs in the United States and , though widespread adoption of wire-guided systems did not occur until the amid ongoing reliability issues.

Post-War Advancements and Proliferation

Following , wire-guided missiles transitioned from experimental prototypes to production systems, with significant breakthroughs occurring in the . The French , developed by , became the first wire-guided (ATGM) to enter production, achieving operational service with the in 1955. This system employed manual command to line-of-sight (MCLOS) guidance, where operators visually tracked the missile via a , marking a pivotal advancement in portable anti-armor weaponry. Building on this, the British Vickers , developed by , entered service in 1958 as one of the earliest infantry-portable wire-guided ATGMs, designed for manpack use and capable of being launched from ground or vehicle platforms. These early systems demonstrated the feasibility of wire guidance for tactical applications, influencing subsequent designs. The 1960s and 1970s saw rapid proliferation of wire-guided missiles amid Cold War tensions, as both superpowers and their allies prioritized anti-tank capabilities. The Soviet Union introduced the 9M14 Malyutka (NATO: AT-3 Sagger) in 1963, the first man-portable ATGM in its arsenal, which utilized MCLOS guidance and quickly became one of the most produced ATGMs globally due to its simplicity and export potential. In the United States, the BGM-71 TOW entered service in 1970, replacing earlier systems like the SS.10 and offering improved reliability through its semi-automatic command to line-of-sight (SACLOS) guidance, where the operator only needed to keep the sight on the target while the system automatically adjusted the missile's path. Europe followed with the MILAN, a joint French-German project initiated by Euromissile in 1972, which also adopted SACLOS for enhanced accuracy and was rapidly adopted by NATO forces. Key conflicts highlighted the operational impact of these weapons during this era. In the , wire-guided missiles like the TOW saw limited deployment, primarily from helicopters starting in May 1972, with only 162 combat firings recorded before the ceasefire, constrained by terrain, lack of armored targets, and technical limitations such as wire length restricting effective range to about 3 km. In contrast, the 1973 showcased their devastating effectiveness against armor; Egyptian and Syrian forces, using Soviet-supplied Malyutka missiles, destroyed approximately 150 of Israel's 300 tanks in the within the first three days, compelling Israeli adaptations in tactics and underscoring the shift from tank dominance to guided missile threats in Arab-Israeli conflicts. This period also witnessed a boom in arms exports to nations, driven by superpower competition. The aggressively marketed the Malyutka to allies like , , , and various African and Asian countries, enabling its widespread adoption in proxy conflicts and bolstering influence. Western systems, including the TOW and , were exported to U.S. and European partners in the and , further disseminating wire-guided technology. Technological advancements in the 1970s reduced operator skill requirements and extended operational s. The adoption of SACLOS, exemplified by the TOW, allowed for more precise guidance with less manual intervention, improving hit probabilities in dynamic conditions. Concurrently, improvements in wire and materials enabled range extensions to 4-8 km in later variants, such as enhanced TOW models, overcoming earlier limitations of 2-3 km and facilitating deeper strikes against armored formations.

Types and Examples

Anti-Tank Guided Missiles

Anti-tank guided missiles (ATGMs) are wire-guided systems primarily designed for or vehicle-launched anti-armor operations, utilizing shaped-charge warheads to penetrate armor while emphasizing portability and line-of-sight () accuracy for effective engagement. These missiles employ () warheads that create a focused of molten metal upon impact, capable of defeating armored vehicles at ranges typically up to several kilometers. The guidance relies on manual or semi-automatic command to line-of-sight (MCLOS or SACLOS) principles, where operators track the target through optical sights and transmit corrections via thin wires spooled from the missile. Key examples of wire-guided ATGMs include the Soviet , introduced in the 1960s as a vehicle-mounted system weighing about 22.5 kg, with a range of 2 km and a flight speed of 90-110 m/s, launched from a joystick-controlled setup for use. The U.S. , fielded in the 1970s, offered a range of up to 2 km in its improved variants, achieving speeds around 200 m/s via a two-stage solid-fuel and a 140 mm warhead, making it shoulder-fired by a single operator. The British , developed in the 1960s for vehicle mounting, featured a unique delayed launch capability from enclosed positions and a range exceeding 4 km at 185 m/s, using thrust-vectoring for sharp trajectory adjustments post-launch. Operational tactics for wire-guided ATGMs involve firing from concealed positions to maintain while minimizing exposure, with operators selecting elevated or open vantage points for clear target tracking. Wire management is critical in varied , as the spooled or fiber-optic guidance wires—up to several kilometers long—must avoid snags on or obstacles to prevent signal loss or deviation. In combat, such as the brief but effective use of the U.S. during the 1991 , these systems destroyed numerous Iraqi armored vehicles from defensive positions, highlighting their role in ambushes. The TOW system remains in production as of 2025, with the U.S. Army awarding a $271 million contract to for additional missiles to meet global demand. Variants of wire-guided ATGMs differ in launch methods, including tube-launched configurations like the TOW and for portable, disposable firing, versus rail-launched setups on vehicles such as the on the FV438 carrier for rapid reloading. Many integrate with advanced fire-control systems, incorporating sights and stabilized optics to enhance night and adverse-weather targeting accuracy.

Other Applications

Wire-guided missiles have found applications in , particularly in designed for anti-submarine and anti-surface ship roles. The U.S. Navy's Mk 48 ADCAP, introduced in the 1980s as an upgrade to the original Mk 48 from 1972, is a heavyweight that employs wire guidance via thin wires spooled out from the launching to enable real-time control during the initial phase of flight. This system allows operators to steer the toward detected threats, such as submarines, before it transitions to autonomous acoustic homing. Similarly, Russia's UGST (Universal Heavyweight ), entering service around 2002, incorporates wire guidance in its combined control system, supporting both anti-submarine and anti-ship missions with a . The wire provides a for course corrections, enhancing accuracy against maneuvering targets. In aerial applications, wire guidance appeared in early experimental air-to-air missiles. The German Ruhrstahl X-4, developed during World War II starting in 1943, was a pioneering wire-guided air-to-air weapon intended for use against Allied bombers, with control signals transmitted over spooled wires up to several kilometers long. Pilots visually tracked and steered it using a joystick, marking an early shift toward standoff engagements in the air domain. For surface-to-surface roles, the Australian-developed Malkara missile from the 1950s served as a heavy wire-guided system adaptable beyond initial anti-armor concepts, including potential integration with vehicular launchers for extended-range strikes. In modern contexts, wire guidance has seen niche adaptations in unmanned systems, such as fiber-optic-linked drones for precision strikes immune to electronic jamming, though primarily in tactical military scenarios rather than widespread training platforms. Underwater wire guidance presents unique adaptations for homing on submerged targets like , where the wire maintains a continuous command link from the launch platform to counter evasive maneuvers. However, this introduces challenges from hydrodynamic drag on the trailing wire, which increases in water currents and can affect the 's speed and stability, often necessitating streamlined designs or fairings to mitigate forces. The Torped 613, introduced in the , exemplifies a wire-guided heavyweight optimized for such naval environments, using a two-way over insulated wire for passive feedback during anti-submarine operations. Non-military prototypes have explored wire guidance in target drones for testing and systems, providing reliable, tethered flight paths in controlled ranges.

Operational Characteristics

Advantages

Wire-guided missiles exhibit strong resistance to jamming because they transmit guidance signals through a physical wire rather than radio frequencies, rendering them immune to electronic countermeasures such as jamming. This design eliminates detectable electromagnetic emissions during flight, allowing operations in environments saturated with enemy capabilities. The direct wired link enables real-time operator adjustments, providing superior precision and control in semi-automatic command to line-of-sight (SACLOS) systems, where the automatically maintains alignment with the under manual oversight. This results in high hit probabilities, often reaching up to 90% against stationary or moving s within line-of-sight ranges, minimizing through targeted engagements. Compared to laser- or radar-guided alternatives, wire-guided systems employ simpler , reducing complexity and production costs while maintaining reliability without reliance on advanced or power-intensive components. Their cost-effectiveness supports widespread deployment in resource-constrained forces, offering a potent anti-armor capability at a fraction of the expense of more sophisticated guidance technologies. Tactically, wire-guided missiles operate effectively in GPS-denied or contested environments, as their guidance depends solely on optical tracking and wired commands rather than signals, ensuring functionality amid disruptions to global navigation systems. This independence, combined with semi-automated features that reduce operator workload compared to manual command systems, provides precision in open line-of-sight engagements.

Limitations

Wire-guided missiles are constrained by the physical length of their guidance wires, which limits effective engagement ranges to approximately 4 kilometers in representative systems such as the . This restriction precludes their use against targets at longer distances, as the wire spools—each containing up to 3,750 meters of thin wire—cannot extend further without compromising guidance integrity. The spools contribute additional weight to the missile, with total launch weights reaching 22.9 kg for variants like the TOW 2B, impacting portability and launcher design. The system's reliance on exposed guidance wires introduces significant vulnerabilities, as the wires can snag on obstacles, break during payout, or be severed by or environmental hazards such as power lines crossing the flight path. Continuous line-of-sight () is essential for the operator to track the via optical sights until , rendering the weapon ineffective in cluttered environments like urban areas or dense forests where foliage, structures, or other obstructions block visibility. Adverse weather further exacerbates these issues, with rain, fog, or moisture condensing on optics to obscure targeting, while extreme cold can produce that hinders tracking and follow-on shots. Operational response times are slowed by missile velocities typically ranging from 100 to 300 m/s, resulting in flight durations of 10 to 40 seconds depending on range, which provides maneuvering targets more opportunity to evade compared to higher-speed guidance alternatives. In semi-automatic command to line-of-sight (SACLOS) modes, the operator must maintain steady crosshair alignment on the target throughout the trajectory, potentially leading to fatigue during extended engagements or in high-stress conditions where multiple firings are required. Hit probabilities decline with distance and operator skill, dropping to as low as 7.5% for inexperienced gunners at 3,500 meters due to these tracking demands. Logistically, the single-use wires embedded in each missile contribute to the overall expendable nature of the munition. Environmental sensitivities compound operational challenges, with and aerodynamic forces causing flight path fluctuations, particularly at longer ranges, and potentially disrupting smooth wire payout from the spools. Some modern variants, such as (RF-guided) TOW systems, mitigate wire breakage risks but introduce potential vulnerability to .

Modern Applications

Current Military Systems

The BGM-71 TOW-2B, an upgraded variant of the original wire-guided anti-tank missile introduced in the , remains a cornerstone of U.S. and allied inventories, with recent production contracts ensuring its availability through 2050 and beyond. In 2025, the U.S. Army awarded a $271.4 million contract to produce 2,000 TOW-2B missiles, incorporating obsolescence and safety enhancements while maintaining the optically tracked, wire- or RF-guided system for precision targeting up to 4.5 km. Over 13,000 TOW missiles have been supplied to since 2022 as of November 2025, where they continue to be employed against armored vehicles in ongoing operations. The ER, a extended-range wire-guided missile developed in the , extends operational reach to 3 km while retaining the semi-automatic command-to-line-of-sight guidance via wire, and it is actively exported and integrated into forces across more than 40 countries as of 2025. has bolstered support to with MILAN deliveries in 2025, alongside armored vehicles, highlighting its role in enhancing anti-tank capabilities in high-intensity conflicts. The system pairs with digital firing posts for improved ergonomics and night operations via compatible thermal sights. In recent , wire-guided missiles like the TOW have proven effective against non-state actors, notably in operations against in and during the , where U.S.-supplied systems enabled precise strikes on armored targets from concealed positions. Modern adaptations include integration with unmanned systems, such as launching drones from TOW-compatible tubes on platforms like the , which extends line-of-sight targeting in drone-contested environments. Globally, wire-guided anti-tank missiles maintain inventories exceeding 700,000 units, predominantly TOW systems distributed to over 40 nations, with variants adding to widespread adoption in and former countries through ongoing training programs. Emphasis on operator training in these alliances underscores their continued reliability in maneuvers. Upgrades to wire-guided systems incorporate for enhanced command transmission over wires, reducing noise and improving accuracy in jammed environments, as seen in TOW's evolved guidance electronics. Compatibility with advanced night-vision and thermal imaging sights further extends operational utility, allowing effective engagement in low-visibility conditions without altering the core wire-based architecture.

Emerging Technologies and Alternatives

Recent advancements in wire guidance technology have focused on fiber-optic systems, which offer significant improvements over traditional metallic wires by providing higher data rates and enabling real-time to operators. These enhancements allow for more precise and target during flight, addressing limitations such as susceptibility to electronic countermeasures () through non-emitting, immune transmission. Similarly, the Spike-LR2 employs a fiber-optic for electro-optical guidance, permitting mid-flight retargeting and video reception, which extends effective ranges to 5.5 km in fiber-optic mode and enhances operator without exposing the launcher to detection. These systems also facilitate lighter cabling, enabling longer operational distances and integration into portable platforms, as seen in ongoing developments like Serbia's ALAS missile family. Shifts toward and guidance mechanisms are reducing reliance on physical tethers, combining wire or fiber-optic elements with non-line-of-sight (NLOS) capabilities to mitigate traditional constraints like line-of-sight requirements and wire snags. beam-riding systems, for example, direct missiles along a modulated beam toward the target, eliminating the need for trailing wires while maintaining semi-active homing for strikes, as demonstrated in various tactical guided munitions that achieve ranges beyond 5 km without physical connections. The US missile, introduced in the 1990s, exemplifies the transition to infrared , where the seeker autonomously locks onto targets post-launch, allowing operators to seek cover immediately and avoiding the vulnerabilities of wire deployment altogether. approaches, such as those in the family, blend fiber-optic control with options, providing flexibility for either man-in-the-loop adjustments via video feed or autonomous operation, thereby extending versatility in contested environments. Looking ahead, (AI) integration promises to further evolve guidance paradigms by assisting targeting and reducing dependence on continuous line-of-sight, potentially rendering pure wire systems obsolete in drone-saturated battlefields. AI-enhanced seekers enable real-time , adaptive , and autonomous decision-making, allowing missiles to process environmental data and adjust paths independently, as projected in analyses of next-generation systems where AI could improve hit probabilities by over 70% in dynamic scenarios. Systems like MBDA's Orchestrike leverage AI-driven datalinks for missile coordination, facilitating swarm-like behaviors that minimize human intervention and address wire-related hazards through wireless alternatives. efforts are exploring retractable spools and multi-mode hybrids to enhance reliability, with trends indicating broader adoption of AI to counter evolving threats like and unmanned aerial systems.

References

  1. [1]
    BGM-71 M-220 Tube-launched, Optically tracked, Wire-guided ...
    Mar 5, 2019 · It can be fired by infantrymen using a tripod, as well from vehicles and helicopters, and can launch 3 missiles in 90 seconds. It is primarily ...
  2. [2]
    TOW - Redstone Arsenal Historical Information
    TOW is a tube-launched, optically tracked, wire data link auto-guided missile, named to capture its main defining features.<|control11|><|separator|>
  3. [3]
    TOW 2 Wire-Guided Anti-Tank Missile - Army Technology
    Mar 15, 2022 · The BGM-71 tube-launched, optically tracked, wire-guided (TOW) heavy anti-tank missile weapon system is produced by Raytheon Systems.<|control11|><|separator|>
  4. [4]
    Ruhrstahl X-4 Air-to-Air Missile - Air Force Museum
    The X-4 was an early air-to-air missile, guided by fighter pilots, with a 2,700 yard range, 560 mph max speed, and a 44 lbs warhead.
  5. [5]
    German "Fritz X" Guided Bomb - Air Force Museum
    The "Fritz X" was a 3,450-pound armor-piercing bomb with radio control, later wire-guided, used to sink the Italian battleship Roma.
  6. [6]
    SS-10/MGM-21 / SS-ll/AGM-22 / SS-12 Anti-tank Missile
    Jun 30, 2021 · The SS-11 missile, a French antitank development of the aid-1950's, incorporates a two-strand wire guidance link that was unwound from the ...
  7. [7]
    M47 Dragon American Anti-Tank Guided Missile (ATGM)
    Oct 30, 2024 · The M47 Dragon is an American shoulder-fired, man-portable anti-tank guided missile, phased out of US service in 2001, but still used by other ...
  8. [8]
    [PDF] The TOW Missile— Precise and Powerful
    The TOW is a Tube-launched, Optically-tracked, Wire-guided anti-armor missile, effective against tanks, vehicles, and various targets, and is the world's ...
  9. [9]
    [PDF] Introduction to Precision Guided Munitions, A Handbook ... - DTIC
    This volume contains general tutorial information on smart weaporis(precisicn guided munitions and guided missiles), how they work, what goes into their ...
  10. [10]
    Chapter 15 Guidance and Control - Military Analysis Network
    A relatively new type of command guidance by wire is now operational in some short-range antitank-type weapons. These systems use an optical sight for tracking ...
  11. [11]
    FM 3-23.24 Chapter 1 - GlobalSecurity.org
    (1) The daysight generates signals that travel by wire to the missile control system. The missile control system fires the appropriate rocket thrusters to keep ...
  12. [12]
    Polyphem Fibre-Optic-Guided Missile System - Army Technology
    Feb 15, 2001 · Polyphem has a range up to 60km and uses infrared imaging for high precision targeting by day and night against mobile or fixed targets. The ...
  13. [13]
    None
    ### Summary of Enhanced Fiber Optic Guided Missile (EFOG-M) System
  14. [14]
    Fibre Optic Guided Missiles (EFOG-M, Polyphem, and others)
    May 19, 2023 · Individual missiles were 1.94m long, with a diameter of 0.7m and a wingspan of 1.14m, weighing 51kg. ... The fiber optic wire is jam-proof ...
  15. [15]
    [PDF] Overview of Missile Flight Control Systems - Johns Hopkins APL
    An inertial measurement unit (IMU) measures the missile translational accelera- tion and angular velocity. The outputs of the IMU are combined with the guidance ...
  16. [16]
    A Brief History of Remote Weapons: From Mines to Robot Dogs
    May 3, 2022 · Among the earliest guided weapons were torpedoes, such as that developed by John Louis Lay in 1872. ... wire-guided antitank weapon to bombard ...
  17. [17]
    The Birth of Guided Missiles | Proceedings - U.S. Naval Institute
    World's First Guided Missile: On 14 September 1938, an N2C-2 drone, starting from an altitude of 8,000 feet, was placed in a guided dive of 45° toward the ship ...
  18. [18]
    Missile, Air-to-Surface, Henschel Hs 293 A-1
    To prevent jamming, a wire-guided version using the "Dortmund/Duisburg" guidance system was developed under the designation Hs 293B, but eventually all the ...Missing: variants | Show results with:variants
  19. [19]
    [PDF] The Development of Precision Guided Bombs - DTIC
    To overcome this hazard, Professor Herbert Wagner designed and developed the Henschel Hs-293 (Fig 1) 12 The Hs-293 was a glide bomb resembling a small plane ...
  20. [20]
    Missile, Air-to-Air, Ruhrstahl X-4 | National Air and Space Museum
    To prevent jamming, guidance was by wires running between the missile and launch aircraft, rather than by radio. Slated for use on the Me 262 jet fighter, the X ...
  21. [21]
    The transfer and exploitation of German air-to-air rocket and guided ...
    Aug 10, 2020 · The transfer and exploitation of German air-to-air rocket and guided missile technology by the Western Allies after World War II · Abstract.Missing: wire | Show results with:wire
  22. [22]
    Swingfire - GlobalSecurity.org
    Jun 9, 2013 · Swingfire is an anti-tank missile which owes its development to the Vigilant and Orange William projects. Swingfire used Thrust Vectored Control ...
  23. [23]
    [PDF] THE COMBAT USE OF ANTITANK GUIDED MISSILES (PTURS) IN ...
    For PTURS with distant control, control points are selected and prepared for the operators in locations with good conditions for the observation of enemy tank.
  24. [24]
    BGM-71 / M-220 TOW - History - GlobalSecurity.org
    The TOW was one of the earliest missile systems to arrive in SWA because of the large Iraqi armored threat it was deployed with some of the first units in ...
  25. [25]
    MK-48 Torpedo
    Dec 12, 1998 · Wire guided and passive/active acoustic homing. Warhead, 650 lbs (292.5 kg) high explosive. Date Deployed, 1972 1988 ADCAP. Unit Cost, $2.5 ...
  26. [26]
    Mk.48 ADCAP Heavy Weight Torpedo Attack Submarine SSN Navy
    Mk. 48 and Mk. 48 ADCAP torpedoes can be guided from a submarine by wires attached to the torpedo. They can also use their own active or passive sensors to ...
  27. [27]
    Guide-to-heavyweight-533mm-torpedoes - H I Sutton - Covert Shores
    Mar 20, 2020 · Mk-48 ADCAP, US​​ The Mk-48 was one of the first western torpedoes designed to counter extra-fast deep diving submarines such as the Alfa Class. ...
  28. [28]
    Missile, Air-to-Air, Ruhrstahl X-4 | Smithsonian Institution
    The X-4 was a small wire-guided, air-to-air missile designed as a standoff weapon against heavily armed Allied bombers. It was slated for use with the Me ...
  29. [29]
    FV4010 & Malkara - Tank Encyclopedia
    Aug 18, 2018 · The development of the Malkara missile, a heavy anti-tank wire-guided weapon system, began in 1952 at the Government Aircraft Factory (GAF) in ...Missing: applications | Show results with:applications
  30. [30]
    Russia's Unjammable, Wired Drones Likely Aren't End-All Game ...
    Aug 31, 2024 · The fiber-optic, wired drones may resist signal jamming, but they are likely just the latest adaptation in a fast-moving drone arms race.<|separator|>
  31. [31]
    Porpoise_1000 - H I Sutton
    May 14, 2017 · The Type-613 is a wire-guided and passive homing ... Swedish submarines hold the record for multiple simultaneous wire-guided torpedo ...Missing: Torped | Show results with:Torped
  32. [32]
    Mine action with underwater wire-guided robots - SEDI-ATI
    Besides, the drag of the umbilical cable in strong currents has a high impact on the hydrodynamic behavior of the ROV. This “traditional” solution results ...
  33. [33]
    Weapons: Unjammable Wire Controlled UAVs - StrategyPage
    Mar 19, 2024 · March 19, 2024: Russia has introduced a wire controlled UAV in order to have a UAV that is immune to electronic jamming.
  34. [34]
    Saab receives radar, anti-tank contracts - UPI.com
    The Bill 2 is an anti-tank missile system combating long-range targets with wire-guided missile technology that company officials say is immune to jamming.
  35. [35]
    Anti-Tank Guided Missiles - GlobalSecurity.org
    Mar 28, 2023 · The TOW Weapon System includes the ITAS launcher, TOW missiles, and associated tactical training aids/devices. The ITAS is a combat proven TOW ...
  36. [36]
    Bumbar (Bumble Bee) Short-Range Anti-Tank Guided Weapon ...
    Nov 27, 2015 · The short-range weapon system has a hit probability of 90% against moving targets. ... The missile is guided by a thin wire link and ...
  37. [37]
    FM 7-10 Appendix L - GlobalSecurity.org
    Some of the disadvantages of the TOW system are: (a) The missile is wire guided, which restricts firing from elevated positions where power lines cross the ...
  38. [38]
    FM 9-207 Chapter 4 - GlobalSecurity.org
    The principal difficulties with wire-guided missiles, such as the TOW and Dragon, are target acquisition and tracking. Moisture condensing on the eyepiece can ...
  39. [39]
    TOW Wire Guidance: The Engineering Behind Controlling Missiles ...
    Developed by Hughes Aircraft and now produced by Raytheon, the TOW has guided over 700,000 missiles across 50+ nations since 1970. Its secret? A micro-thin wire ...
  40. [40]
    Modernizing and equipping the force (Part 4) | Article - Army.mil
    Dec 30, 2010 · Current TOW missile improvements include a Bunker Buster variant and replacement of the obsolete wire guidance link with one that operates via ...
  41. [41]
    TOW Weapon System | Raytheon - RTX
    The TOW weapon system will be in service with the U.S. military beyond 2050. ... Raytheon Missiles & Defense has delivered more than 700,000 TOW weapon systems to ...
  42. [42]
    U.S. Army expands TOW missile production - Defence Blog
    Sep 23, 2025 · The order includes the TOW Obsolescence and Safety 2B missile variant, ensuring continued capability and safety improvements to the system.
  43. [43]
    U.S. signs $271.4 million RTX contract for TOW 2B missiles amid ...
    Sep 26, 2025 · One of the key areas of current use is Ukraine, where the United States has delivered around 13,000 TOW missiles under its military assistance ...
  44. [44]
    Milan ER - Army Recognition
    Jul 21, 2024 · MILAN ER missile maintains all the performance and operational features of the MILAN family (ergonomics, reliability, accuracy, robustness and ...Description · Technical Data · Specifications
  45. [45]
    France Strengthens Military Support to Ukraine with Milan and ...
    Operated from a lightweight firing post, the MILAN has an effective range of up to 2,000 meters and can be used both day and night thanks to ...
  46. [46]
    The World's Deadliest Anti-Tank Missiles | Army Technology
    Jun 12, 2019 · The MILAN ER missile fired from digital firing post uses the semi-automatic command to line of sight (SACLOS) guidance system to defeat targets.
  47. [47]
    Tactics, Techniques, and Procedures of the Islamic State
    The United States has thus far declined to provide the Peshmerga with tube-launched, optically tracked, wire-guided missiles that would be comparable to French ...
  48. [48]
    Mysterious Weapon Fired From M2 Bradley Fighting Vehicle Identified
    Apr 14, 2025 · The modular drone launched from a TOW missile launcher opens up many possibilities beyond its pairing with the Bradley.
  49. [49]
    Top 10 Anti-Tank Guided Missiles of the World in 2025
    Greece uses 1,200. Additionally, over 40 countries use Milan variants in 2025. However, some phase out for ADT-ER. Overall, it serves global forces. Pros ...
  50. [50]
    [PDF] Missile Communication Links - Johns Hopkins APL
    A narrow frequency spectrum is important to prevent an uplink transmission from interfering with an SM or ESSM that might be receiving uplinks on an adjacent ...Missing: breakage | Show results with:breakage
  51. [51]
    [PDF] Enhanced Fiber Optic Guided Missile - DTIC
    The organization of this thesis includes an introduction and background of the EFOG-M. Chapter II provides general background information, discusses the current ...
  52. [52]
    SPIKE LR2: Anti-Tank Weapon - Rafael
    The EO guidance system with real-time fiber optic data link delivers multiple cutting-edge capabilities including man-in-the-loop retargeting, engagement of ...
  53. [53]
    Spike Anti-Tank Guided Missiles, Israel - Army Technology
    Jun 23, 2023 · Spike-LR is equipped with a fibre-optic data link guidance system, which sends commands to the missile from the launch system and receives, ...
  54. [54]
    Precision-Guided Munitions: Guidance Techniques (Part 1 of 4)
    Apr 28, 2015 · Beam-riding weapons make use of a radar or laser beam for guidance. A narrow radar or laser beam is directed at the target, usually a tank or an ...Missing: alternative | Show results with:alternative
  55. [55]
    Javelin Portable Anti-Tank Missile, US - Army Technology
    Jun 2, 2023 · Unlike laser beam riding or conventional wire or fibre-optic cable guided missiles, Javelin is autonomously guided to the target after launch, ...Missing: alternatives | Show results with:alternatives
  56. [56]
    AI Impact Analysis on the Missile Seekers Industry
    May 12, 2025 · AI is transforming missile seekers into smart, adaptive systems with real-time targeting, sensor fusion, and autonomous decision-making in ...
  57. [57]
    Missile developments in the AI era - Airforce Technology
    Mar 19, 2025 · In the longer term, AI-enhanced missiles will continue to grow in capability and become more autonomous, Boyd stated. Space too will certainly ...