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Third Arm Weapon Interface System
Third Arm Weapon Interface System
Third Arm Weapon Interface System
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The Third Arm Weapon Interface System (TAWIS), or Third Arm, is a passive, stabilizing device developed by the US Army Research Laboratory (ARL) in 2016 to redistributes the weight of heavy firearms to make them easier to hold and carry. It weighs less than 1.8 kg (4 pounds), and consists of a mechanical appendage made out of carbon fiber composite that has one end attached to a carbon fiber plate that fits inside an armor plate pocket and the other end attached to a Picatinny rail on top of the gun.[1] It was designed to permit more accurate use of heavier weapons and reduce fatigue by displacing the weight of the weapon from the arms to the torso, and to mitigate weapon recoil.[2] As of 2018, the Third Arm is a prototype and is still in the testing phase of its development.[3]

History

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The development of the Third Arm began in 2015 as a collaborative effort in ARL’s Human Research and Engineering Directorate (HRED) and Weapons & Research Materials Directorate (WMRD).[4] The project was an attempt to improve the marksmanship of soldiers by finding ways that would make the use of heavier, more lethal firearms and larger bullets easier to manage.[2][5]

The first prototype of was built in 2016 and first unveiled to the public in March 2017 at the Association of the United States Army (AUSA) conference in Huntsville, Alabama. A pilot study was conducted in summer 2017, where the prototype was tested with six soldiers who wore electromyography sensors that recorded muscle activity with and without the Third Arm.[6] The results indicated that the device improved shooting accuracy and lessened muscle fatigue. A second prototype was constructed based on the soldiers’ feedback. Changes included the mounting location, the addition of an extendable hinge plate that adhered to different body types, and refinements to the design that made it easier for the wearer to dive into the prone shooting position.[7]

Applications

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The Third Arm can be used to completely take off the weight of heavy firearms such as the 7.5 kg (17-pound) M249 light machine gun or the 12.5 kg (27.6-pound) M240B general-purpose machine gun from the holder’s arms.[3] By supporting the weapon’s weight, soldiers are capable of operating the firearm with one hand, leaving the other hand free for another task.[1] It can be used to carry a breaching saw or a shield instead of a firearm.[2] Testing has shown that the Third Arm provides immediate stabilization during movement, allowing for improved marksmanship.[8]

See also

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References

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Third Arm Weapon Interface System

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from Grokipedia
The Third Arm Weapon Interface System (TAWIS), commonly referred to as the Third Arm, is a passive, unpowered wearable apparatus designed to stabilize heavy firearms by redistributing their weight from a soldier's arms to the torso, thereby reducing fatigue and enhancing marksmanship accuracy during extended use. Developed by engineers at the U.S. Army Research Laboratory (ARL) at , , the device originated as a prototype in 2016 to address the physical burdens faced by soldiers carrying crew-served weapons such as the M249 (approximately 18 pounds) and the M240B (approximately 27 pounds). The system attaches to a soldier's tactical vest via PALS or an armor plate pocket on one end and to the firearm's on the other, utilizing a flexible hinge assembly and a mechanism with integrated springs to provide adjustable support and multiple for natural movement, including transitions to prone positions. Constructed from lightweight carbon-fiber composites and polymer components, the entire device weighs less than four pounds, ensuring minimal added burden while counterbalancing recoil forces and enabling single-handed operation of otherwise two-person weapons. Initial live-fire testing conducted by ARL in demonstrated improved stability and accuracy, with pilot studies showing soldiers achieving better aim under sustained fire; a larger evaluation was planned for to incorporate feedback for refinements, such as adaptations for heavier systems. The design, ed in 2019 by inventors including William J. Green and Daniel M. Baechle, emphasizes modularity to accommodate various user sizes and configurations, aligning with broader U.S. efforts to integrate exoskeleton-like technologies for enhancing soldier lethality and endurance in scenarios. A 2020 evaluation of the during live-fire scenarios confirmed reductions in upper extremity fatigue and improvements in shot accuracy (by approximately 0.9 inches), though issues with mobility during prone transitions and user comfort (e.g., ) were noted, requiring further design refinements; as of 2020, the Third Arm remained in stages with no confirmed widespread field deployment reported.

Development History

Origins and Initial Concept

The development of the Third Arm Weapon Interface System (TAWIS) was initiated by the US Army Research Laboratory (ARL) in late 2015, stemming directly from feedback highlighting the physical burdens of carrying heavy weapons during dismounted operations. ARL engineers identified persistent challenges in effectiveness, where overloaded gear and weaponry led to rapid onset of , diminished marksmanship accuracy, and operational limitations that often necessitated two-person teams for sustained . This initiative was part of broader efforts within ARL's Human Research and Engineering Directorate to enhance lethality through innovative human-machine interfaces. At its core, the initial concept envisioned a passive mechanical device that would redistribute weight from the soldier's arms to the torso, drawing inspiration from technologies but deliberately simplified to avoid powered components and ensure lightweight, low-maintenance usability in field conditions. The design targeted weapons such as the , which weighs nearly 28 pounds unloaded and exacerbates arm strain during prolonged aiming and firing, thereby reducing and improving stability without requiring additional energy sources. This approach aimed to enable single-soldier operation of crew-served weapons, addressing feedback from operational scenarios where such limitations compromised mission agility and endurance. Key early contributors included a team of ARL mechanical engineers, notably Dan Baechle, who focused on prototyping human augmentation solutions tailored to needs. Their work emphasized iterative ideation based on biomechanical principles to create an intuitive interface that integrated seamlessly with existing , prioritizing practicality over complexity. These foundational efforts laid the groundwork for subsequent prototyping phases starting in 2016.

Prototyping and Key Milestones

The development of the Third Arm Weapon Interface System began with the construction of initial prototypes in 2016 by researchers at the U.S. Army Research Laboratory (ARL), focusing on a lightweight, passive support device to redistribute weapon weight from soldiers' arms to their torso. These early prototypes weighed under 4 pounds and were designed for compatibility with crew-served weapons such as the M240B machine gun, enabling single-soldier operation by providing stabilization without powered assistance. In 2017, a key milestone was achieved through initial hands-on trials conducted with six soldiers at , , where the prototype demonstrated feasibility for reducing upper-body fatigue during sustained weapon handling and improved marksmanship stability. These trials validated the device's potential for dismounted use, building on the core concept of offloading weight to enhance lethality. The prototype was publicly unveiled at the Association of the United States Army (AUSA) Global Force Symposium in March 2017, marking an early showcase of its design. By 2018, the project advanced with the filing of U.S. Patent Application US16/002,420 on June 7, 2018, which was granted as US10393476B2 on August 27, 2019, describing a wearable apparatus that attaches to tactical vests for stabilization using carbon-fiber composites. Spring 2018 saw expansion of testing to a broader group of soldiers across Army units, incorporating feedback to refine the prototype's adjustability and . This phase involved close collaboration with ARL's Human Research and Engineering Directorate (HRED), which provided expertise in human-systems integration to assess soldier performance impacts. Following these milestones, no major public updates on the Third Arm system have been reported after , as of November 2025.

Design and Components

Structural Features

The Third Arm Interface System (TAWIS), also known as the Third Arm, features a wearable, passive mechanical apparatus designed to stabilize firearms by attaching to a soldier's tactical vest and supporting the externally. The core structure consists of a base mount integrated with the vest, an articulated arm assembly, and a distal interface, enabling the device to function as an external limb for load-bearing without powered components. The base attachment mechanism secures to the soldier's plate carrier or tactical vest, typically at the shoulder or chest level, using a carbon-fiber insert that fits into the posterior pocket of systems like the CRYE Precision Jumpable Plate Carrier. This mount employs a finger plate that slides into and is locked by a face plate, or alternatively, a pocket plate connected via a U-shaped bracket, allowing for stable fixation while permitting the arm to articulate away from the body. A rear hinge assembly, comprising multiple interchangeable hinge plates, supports approximately 360-degree rotation for aiming flexibility, with configurations adjustable for left- or right-handed use. The arm structure includes pivoting joints and a system for multi-axis movement, featuring pins, bearings, and tension elements such as elastic bands or coil springs to facilitate smooth operation. Adjustability is achieved through telescoping segments in the middle carbon-fiber link, secured by pins for length variation, and additional height tuning via hex nuts on a threaded pintle mount, accommodating different user body sizes and types. The distal end incorporates a "Q-arm" component with a quick-release rail clamp that attaches to the weapon's near its , using a bearing and top plate for secure, releasable cradling. Ergonomic considerations include at contact points to minimize chafing during extended use, though evaluations note potential discomfort from asymmetry. When stowed, the device collapses compactly against the vest for mobility, with an extended configuration to support sustained firing positions, such as prone or standing, while maintaining a total system weight under 4 pounds for minimal added burden. Composite materials contribute to this lightweight profile without compromising structural integrity (as of ).

Materials and Manufacturing

The Third Arm Weapon Interface System primarily utilizes lightweight composites, such as carbon fiber reinforced polymers, for the arm structure and joints to minimize overall weight while maintaining structural integrity. These materials, including woven carbon fiber (T300) infused with resin, enable the device to weigh less than 4 pounds in its complete configuration. For flexible sections, continuous woven fabric combined with and film provides the necessary and durability. Secondary components incorporate aluminum alloys, such as Al 6061-T6, for high-stress pivots in baseline designs, offering strength in critical load-bearing areas before transitioning to full composite implementations. Tension mechanisms rely on steel coil springs or composite equivalents to support weapon weight redistribution, with options including lightweight polymer springs for enhanced portability. Manufacturing begins with prototyping via machining and molding techniques, such as integrating hinge tabs directly into plates to reduce weight and complexity. For composite parts, vacuum-assisted resin transfer molding (VARTM) followed by autoclave curing allows rapid iteration, achieving up to a 50% weight reduction compared to aluminum-based prototypes. The system is engineered for extreme military environments, with composites demonstrating resistance to repeated loading up to 29 pounds and minimal stiffness degradation after cyclic testing, supporting operations with high-recoil firearms (as of 2020).

Functionality and Operation

Mechanism of Weight Redistribution

The Third Arm Weapon Interface System utilizes a and fulcrum principle implemented through a and hinge assembly to transfer the weight of a from the soldier's arms to their torso, significantly alleviating arm fatigue during sustained aiming and firing. This passive redistribution mechanism attaches to the soldier's tactical vest, channeling the load directly to the core body mass rather than relying on support alone. For instance, when supporting an M240B weighing approximately 27 pounds, the system reduces the effective arm load to zero, enabling prolonged weapon handling without muscular strain. Key components include counterbalanced springs, such as latex elastic bands or coil springs, which preload the linkage to offset weapon weight and absorb impulses by converting linear forces into balanced reactions distributed across the . Dampers integrated into the articulated frame further mitigate sway and oscillations during aiming, ensuring precise alignment by minor perturbations from soldier movement or environmental factors. These elements work in concert to provide a stable platform, akin to a wearable bipod that maintains steady aim for extended durations, thereby enhancing overall marksmanship accuracy without restricting mobility. The system's fully mechanical design eschews electronics or power sources, relying instead on fundamental physics, including Newton's third law, to balance action-reaction forces—such as —symmetrically across the wearer's body for equitable load sharing. This approach supports weapons such as the M240B machine gun (approximately 27 pounds), without active assistance, making it suitable for heavy crew-served systems like the M249 or M240B. The lightweight of the device itself, under 4 pounds, ensures minimal added burden while maximizing force transfer efficiency.

Integration with Soldier Gear and Weapons

The Third Arm Weapon Interface System (TAWIS) integrates with standard gear through attachments compatible with /PALS webbing on tactical vests and plate carriers, utilizing a finger plate for webbing insertion or a pocket plate with U-shaped bracket that slides into armor plate pockets. This design ensures compatibility with the (IOTV) and similar systems, allowing secure mounting without requiring modifications to existing equipment. Adjustable attachment points on the system enable configuration for left- or right-side use, accommodating various builds and loadouts. For weapon interfacing, TAWIS employs a universal Q-arm mechanism with a rotatably pivoting clamp that connects to the on firearms, facilitating the addition of optics and accessories via standard rail adapters. The system supports heavy crew-served weapons such as the M240B and M249 (SAW), as well as precision firearms like sniper rifles, by cradling the weapon to redistribute its weight. It has also been tested with lighter rifles, including variants, though its primary focus is on stabilizing higher-weight platforms. The setup process involves straightforward attachment to the vest, with interchangeable hinge plates allowing ambidextrous positioning that does not impede primary arm mobility or standard handling. Soldiers can don the rapidly by securing the vest mount and aligning the Q-arm to the rail, enabling quick transitions between supported and unsupported firing postures. This integration enhances operational flexibility by permitting single-soldier employment of crew-served weapons traditionally requiring two personnel, such as the M240B, thereby allowing the second operator to perform other duties like security or resupply. By offloading weapon weight to the torso via the vest connection, TAWIS reduces arm fatigue during sustained fire, supporting improved accuracy in dynamic scenarios. Additionally, compatibility is restricted to Picatinny rail-equipped firearms, excluding non-standard or legacy weapons without adapters.

Applications and Testing

Military Applications

The Third Arm Weapon Interface System is primarily intended for support in dismounted operations, enabling individual soldiers to provide sustained fire in urban environments or during patrols without relying on two-person gun teams for heavy weapons such as the M240B . By redistributing the weapon's weight—up to 27 pounds for the M240B—from the arms to the torso via attachment to a tactical vest, the device allows a single operator to maintain stability and accuracy during prolonged engagements, thereby enhancing mobility in close-quarters scenarios. This capability addresses the physical demands of carrying loads exceeding 110 pounds in combat kits, reducing arm fatigue and supporting shoot-on-the-move tactics. In secondary roles, the system facilitates stabilization for extended engagements by providing a passive frame that minimizes muscle activation and forces, allowing for precise aiming over longer durations without compromising posture. It also integrates into squad-level tactics to boost overall firepower, as soldiers can handle heavier-caliber weapons or defensive shields—up to 20 pounds—while freeing one hand for ancillary tasks like breaching barriers or using for corner-shooting. These applications are targeted at dismounted soldiers within U.S. brigades, with potential adaptation for operations due to the device's lightweight profile under four pounds and composite construction. Strategically, the Third Arm enhances soldier lethality by enabling faster through improved weapon stability and reducing physical strain during missions lasting hours or days, which sustains in resource-constrained environments. Within the broader military ecosystem, it complements load-bearing exoskeletons such as the Tactical Assault Light Operator Suit () by focusing exclusively on weapon interfacing, rather than full-body support, to optimize performance in .

Evaluation and Field Trials

Initial evaluations of the Third Arm Weapon Interface System (TAWIS) were conducted by the U.S. Army Research Laboratory (ARL) in a 2017 pilot study involving six soldiers, where sensors measured muscle activity during weapon handling tasks. The study demonstrated reductions in arm fatigue and muscle activation, alongside improvements in shooting accuracy when using heavy weapons such as the M249 . These early tests focused on the device's ability to redistribute weight from the arms to the torso, confirming its potential to mitigate upper extremity strain in sustained firing positions. In 2018-2020, ARL expanded testing to a more comprehensive evaluation with 14 male military participants (average age 35 years, weight 99.6 kg) in live-fire scenarios, including paced, prone, and lateral positions with the MCX rifle (approximately 8 pounds unloaded). Key metrics showed the Third Arm extended endurance hold times from 21.9 seconds to 37.5 seconds in isometric tasks, indicating a significant reduction in deltoid and muscle fatigue (p < 0.05). Accuracy improved modestly in the , with a 0.9-inch reduction in dynamic circular shot grouping (p = 0.01), though no overall significant changes were observed in hit percentages or response times. Post-trial analyses recommended iterative design improvements, such as reducing bulk for better prone mobility and optimizing to minimize back strain, while suggesting further testing with soldiers and heavier payloads. The system advanced to additional prototyping phases in 2018, but as of 2025, no confirmed field deployment has occurred, with ARL continuing refinements for integration. The 2020 report (ARL-TR-9132) provided the most recent detailed evaluation, and no further public testing or deployment has been reported as of November 2025.

Advantages and Limitations

Performance Benefits

The Third Arm Weapon Interface System (TAWIS) provides significant physical benefits by redistributing the weight of heavy weapons, such as the weighing approximately 27 pounds, from the soldier's arms to the torso via a passive mechanical linkage attached to the tactical vest. This offloading mechanism reduces arm fatigue and muscle activation in key upper-body muscles, including the anterior deltoid and , allowing soldiers to sustain weapon handling for longer periods. In a 2019 evaluation study, participants using the Third Arm demonstrated nearly double the endurance time in weapon-holding tasks compared to controls—37.5 seconds versus 21.9 seconds—while reporting lower subjective fatigue levels across paced and lateral movement scenarios. Additionally, the system lowers the risk of repetitive strain injuries by alleviating stress on the arms, with reduced pain severity noted in the deltoids and during prolonged engagements. Tactically, the device enhances soldier effectiveness by enabling more stable aiming and increasing firing accuracy and in dynamic situations. Pilot studies conducted by the U.S. Army Research Laboratory (ARL) in 2017 showed improvements in marksmanship, with shot precision enhanced by up to 0.9 inches in prone firing positions and a 0.52-inch reduction in mean shot radius during paced trials. This stability supports sustained engagement without compromising squad mobility, as the lightweight design—under four pounds—allows for quicker transitions between firing postures compared to bulkier supports. Ergonomically, the Third Arm minimizes and strain by counterbalancing weapon weight through its and assemblies, freeing cognitive resources for threat detection and decision-making rather than constant weapon control. Soldiers in ARL trials reported greater confidence in weapon handling and reduced physical burden on the upper extremities, facilitating focus on operational tasks. Overall, these gains contribute to higher mission effectiveness in high-intensity scenarios by enabling prolonged weapon use and improved lethality without power sources or complex actuation. In comparison to traditional bipods or static mounts, the Third Arm excels in mobile, urban, or close-quarters environments due to its wearable integration, which maintains full while providing consistent support during movement—unlike bipods that require ground contact and limit maneuverability.

Technical Challenges and Constraints

One significant engineering challenge in the Third Arm Weapon Interface System lies in achieving effective weight distribution without introducing new strains on the user's torso. The device redirects the load of heavy weapons—up to 27 pounds for systems like the —from the arms to the soldier's via attachment to the tactical vest, which reduces arm fatigue but initially caused discomfort when mounted on the front of the vest. Engineers addressed this by relocating the mounting point to the back and incorporating an extendable hinge plate to accommodate varying soldier sizes, though optimal positioning still requires user training and adjustments during field use. Durability remains a key constraint, as the current prototype, weighing less than 4 pounds and constructed from carbon-fiber composites, is not yet fully ruggedized for operational environments. It must endure falls, impacts, and rigorous , but early designs showed vulnerabilities in harsh conditions, such as interference with prone firing positions, which have been iteratively improved. The hinge assembly, enabling nearly 360° rotation for flexibility, folds into a compact profile for storage but demands precise engineering to avoid mechanical "dead spots" in the system under repeated stress. Compatibility limitations further complicate deployment, as the system attaches via on tactical vests, which not all configurations possess in sufficient quantity or placement, potentially precluding secure integration. It is optimized for standard weapons like the , M249, and M240B, but may not suit non-standard firearms or all body types without customization, and it introduces minor bulk to the soldier's profile that could affect maneuverability. Additionally, potential conflicts with vest-mounted gear, such as medical kits or magazine pouches, require design refinements to ensure unobstructed access. Development gaps persist in advanced features, with the Third Arm remaining a passive mechanical device without powered actuation or integration with smart as of the latest available assessments in 2020. As of November 2025, no further public updates on the Third Arm's development, deployment, or integration of advanced features have been reported. Future hurdles include scaling the prototype for while reducing costs and maintaining the high-strength, lightweight materials essential for performance, as ongoing testing with small soldier cohorts highlights the need for broader validation before fielding.
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