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Asymmetric Collaborative Counter Swarm

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ARM26BX04-NV008SBIR / STTR

Contract Overview

Solicitation details, issuing organization, response deadlines, documents, and interested companies for this government contract opportunity.

AI Contract Overview

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The contract seeks the development of AI-driven software algorithms capable of enabling a swarm of Group 1 or Group 2 unmanned aerial systems to collectively defend against a numerically superior enemy drone swarm, moving beyond traditional one-to-one interception models. Each friendly UAS must operate autonomously under severe size, weight, power, and cost constraints, with a total onboard compute payload under two pounds, and must be able to coordinate with neighboring friendly platforms using active communication in permissive network conditions to share real-time enemy tracking data and collaboratively plan engagements. In the absence of reliable communications, the system must degrade gracefully, relying on passive coordination methods to still achieve effective swarm behavior. Individual UAS platforms must be capable of neutralizing multiple enemy drones within a ten-meter radius using either kinetic or non-kinetic effectors, with the overarching goal of reducing the enemy swarm’s combat effectiveness to a fraction of its original strength, contingent on the initial asymmetry between friendly and enemy forces. The technology must be implemented as a software suite that can be integrated onto existing off-the-shelf or custom-built UAS platforms without requiring new hardware design or manufacturing. The AI must continuously make decentralized, real-time decisions that optimize swarm tactics such as target prioritization, cooperative engagement, and resource allocation, adapting dynamically to battlefield conditions. While perfect destruction of the enemy swarm is ideal, success is measured by the system’s ability to significantly reduce enemy combat power even under extreme numerical disadvantages, with performance targets defined by an asymmetry-based curve that scales effectiveness against initial enemy-to-friendly ratios. The effort is focused entirely on algorithmic innovation and integration, not platform development, and is issued as a Small Business Set-Aside under the SBIR/STTR program by the United States Army, with the goal of advancing next-generation counter-swarm capabilities through distributed, resilient, and adaptive AI.

General Info

AI algorithms enable small UAS swarms to autonomously defeat larger enemy drone swarms under strict size, power, and communication constraints.

Agency

Department of Defense → United States ArmyView Agency

NAICS

541512 - Computer Systems Design ServicesView NAICS

Place of Performance

Not specified

Set-Aside

SBA

Documents

(0)

No documents available

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Timeline

PhaseSolicitation
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Organization & Contact Information

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AgencyDepartment of Defense → United States Army
ContactsNo contacts available
OfficeUS
Organization / Agency
Department of Defense → United States Army
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Office AddressUS
ContactsNo contact information available

Full Description

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Develop and integrate distributed Artificial Intelligence (AI) technology that can collaboratively control a multi-agent Group 1 or Group 2 Unmanned Aerial System (UAS) swarm to defend an area against a numerically superior attacking enemy swarm. The vast majority of counter-UAS systems are optimized for a 1 vs 1 scenario, in which the interceptor UAS seeks to destroy, degrade, disable, or capture a single enemy UAS. This approach typically relies on a sensor package and kinetic or non-kinetic effector optimized to degrade/destroy a single enemy UAS of a specific class (size, range, speed, etc.). To defend an area against a numerically superior enemy swarm, individual UAS platforms must collaborate to determine the optimal strategy for many individual 1 vs N scenarios. Individual UAS platforms must demonstrate the ability to target a cluster of enemy platforms through AI algorithms and active or passive inter-drone communication for targeting information from other friendly platform perspectives. The UAS platform employed can be an off-the-shelf OEM or custom-built. Key system attributes include: • Must be able to collaborate across a homogeneous set of Group 1 or Group 2 UAS platforms to actively inform each friendly platform (given permissive network environment) of enemy UAS location, velocity, track, etc. • Must be able to execute algorithms under extreme SWaP-C constraints with a total compute payload under 2 lbs. • Must be able to passively collaborate and achieve similar, but degraded performance within a non-permissive network/communications environment. • A single UAS platform must demonstrate the ability to degrade/destroy N enemy UAS within a range of 10 meters through either kinetic or non-kinetic effectors. • Friendly UAS swarm must be able to severely degrade the combat power of the enemy to a fraction of X% of its original size. • Although 100% degradation of the enemy swarm is ideal, depending on the degree of asymmetry, it may not be realistic. Therefore, a target final enemy combat power goal is achieved from the degree of enemy/friendly asymmetry. As shown in Figure 1, in a scenario where there is no initial asymmetry and our 1 v 1 capabilities are superior, the enemy should retain 0% of its original combat power. However, if that enemy/friendly initial combat power ratio were 4/1, final enemy combat power might be 75% of its original. The ideal curve is one in which final enemy combat power is 0% regardless of the initial asymmetric combat power advantages the enemy possesses. This effort is not designed to create, design, or deliver a new UAS platform as the end item. Rather, it is meant to develop technology that will leverage the existing capabilities of OEM drone platforms or, if necessary, custom-built drones by the performer. The key deliverable is a suite of AI and other software algorithms that continuously plan and take optimal actions in a decentralized manner. The algorithms run on each individual UAS platform, take advantage of active communications with other friendly platforms when operating in a permissive network environment, but can still operate under a denied or degraded network environment by communicating passively.

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in 12 months

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N/A
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