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Cooperative Engagement Capability

Cooperative Engagement Capability (CEC) is a real-time and networking system developed by the that integrates unfiltered sensor measurements from radars and other detectors across ships, aircraft, and surface units to enable shared and cooperative fire control in naval battle groups. By distributing raw track data rather than processed information, CEC allows any equipped platform to detect threats and cue weapons on others, optimizing engagement decisions and extending the effective range of air defense systems beyond individual unit capabilities. Conceived in the early 1970s by the () as a technical development effort for the , CEC underwent requirements validation and at-sea experiments in the before entering engineering and manufacturing development in 1995. Initial deployments began in the late 1990s, with full operational capability achieved on Aegis-equipped cruisers and destroyers, marking a shift from stove-piped combat systems to networked warfare that enhances area air defense against saturation missile attacks. The system's hardware includes CEC processors, distributed time reference systems, and communication links that operate at high data rates to support rapid threat response, contributing to improved battlespace awareness and lethality in carrier strike groups. CEC's defining characteristic lies in its causal enhancement of naval force effectiveness through empirical sensor netting, which has been validated in exercises demonstrating reduced engagement timelines and higher probability of kill against airborne threats. While upgrades continue to address evolving threats like hypersonic missiles, the core architecture remains a cornerstone of U.S. integrated air and missile defense, with ongoing investments exceeding hundreds of millions annually to sustain and expand its interoperability.

Overview

Core Functionality and Purpose

The Cooperative Engagement Capability (CEC) is a real-time sensor netting system that integrates and other sensor data across naval platforms to provide high-quality and coordinated fire control. It enables surface ships, aircraft, and Marine Corps land units to share unfiltered sensor measurements associated with target tracks, allowing any participating unit to utilize precise, fire-control-quality data for engagement decisions. This distributed architecture operates without reliance on a central command , permitting decentralized targeting where a threat detected by one platform's sensors can be engaged by another's weapons system. At its core, CEC addresses the limitations of individual platform sensors by fusing data into a composite picture, which enhances detection range, reduces false alarms, and supports rapid response to airborne threats such as and . Participating units exchange raw track data in , enabling cooperative engagement where, for instance, an 's forward cue can guide a ship's launch, thereby extending the effective engagement envelope beyond line-of-sight constraints. This process prioritizes accuracy and timeliness, with data shared at rates sufficient for time-critical targeting in contested environments. The primary purpose of CEC is to bolster battle force anti-air warfare (AAW) capabilities by creating a networked that multiplies force effectiveness against saturation attacks and advanced threats. By enabling distributed lethality—where dispersed units act as an integrated system—it counters peer adversaries' anti-ship missiles and through deeper engagement layers and improved kill chains, without exposing high-value assets to unnecessary risk. This effect is particularly vital in high-end conflicts, where individual sensor horizons limit standalone platform survivability.

Key Technical Features

The Cooperative Engagement Capability (CEC) utilizes a high-capacity Data Distribution System (DDS) employing directional, jam-resistant data links to exchange unfiltered sensor measurements, such as radar tracks, with minimal latency to form a composite tactical picture across networked platforms. These links operate at elevated bandwidths compared to legacy tactical data links, supporting rapid updates of multiple tracks while maintaining resistance to electronic jamming through advanced signal processing and precise gridlocking for sensor alignment. Central to CEC's architecture is the Cooperative Engagement Processor (CEP), which performs local by integrating remote measurements into a single, high-fidelity track file, enabling from distributed sensors to remote shooters and horizontal networking among units. This processor employs to handle high-volume data streams, preserving measurement precision without centralization vulnerabilities. CEC incorporates interoperability standards compatible with existing naval systems, including weapon systems, through modular interfaces that allow incremental upgrades and for legacy feeds. This design supports multi-platform operations by standardizing data protocols for correlation and fire control handoff, reducing errors in dynamic environments. Early evaluations confirmed these features enable engagement timelines compressed to seconds for networked fires, with accuracies yielding hit probabilities exceeding isolated platform baselines in simulated anti-air warfare scenarios.

Development History

Origins and Early Program

The Cooperative Engagement Capability (CEC) emerged as a response to post-Cold War naval air defense challenges, particularly the need for enhanced battlegroup coordination against advanced anti-ship threats like sea-skimming cruise missiles and saturation attacks in littoral environments. Conceived by the in the early 1970s under the Navy's exploratory Battle Group Anti-Air Warfare Coordination (BGAAWC) program, CEC's foundational concepts gained momentum in the 1990s amid exercises and analyses revealing limitations in isolated performance, such as fading and reduced detection ranges due to clutter and . These vulnerabilities underscored the causal necessity for distributed netting to maintain continuous tracking and enable remote engagements without dependence on centralized processing, thereby mitigating risks from swarm tactics or high-speed threats that could overwhelm individual platforms. Initial prototyping and at-sea testing commenced in 1990 with a system prototype aboard , demonstrating basic data sharing among ships and aircraft for composite air pictures. The U.S. Navy formalized CEC as an acquisition program in 1992, allocating funds for engineering development to integrate with fire control, prioritizing real-time track accuracy over legacy link systems like Link 11. By the mid-1990s, development testing expanded to include in September 1993 and broader battlegroup trials in 1994, such as Virginia Capes experiments verifying cued self-defense and remote engagements against simulated targets. These efforts addressed first-principles gaps in force-level coordination exposed in post-Gulf War evaluations, where disjointed command-and-control hindered responses to dynamic threats. A pivotal validation occurred in the summer of 1997 during Initial Operational Testing and Evaluation (IOT&E) on , where CEC networked Aegis-equipped ships, aircraft, and land-based systems via high-bandwidth links to execute cooperative engagements against simulated airborne threats. This demonstration proved the system's ability to fuse disparate sensor data into a shared, fire-control-quality picture, enabling offboard targeting without local visibility and avoiding single-point failures inherent in hierarchical architectures. Concurrent Marine Corps proof-of-concept tests in 1997 integrated CEC with ground radars, further confirming its extensibility to joint operations while highlighting early challenges with systems like the Advanced Combat Direction System. These milestones paved the way for initial operational capability targeting in 1996-1997, emphasizing CEC's role in countering evolving adversary tactics through decentralized, resilient .

Major Milestones and Initial Deployments

The Cooperative Engagement Capability (CEC) achieved its first critical at-sea experiment with a in , demonstrating the feasibility of among naval platforms. This testing laid the groundwork for integrating unfiltered track measurements across distributed s, enabling cooperative targeting without reliance on centralized command structures. In 1992, CEC transitioned to a formal U.S. Navy acquisition program, marking the shift from research to structured development. An initial trial deployment followed from October 1994 to March 1995 with the Sixth Fleet in the Mediterranean, validating networked operations under operational constraints despite test limitations. Milestone II approval for engineering and manufacturing development occurred in May 1995, following early operational assessments of the airborne component. Initial operational capability, with all test limitations removed, was attained in 1996, enabling limited battle group integration for enhanced anti-air warfare through shared radar tracks and fire control quality data. By the early , airborne variants received approval for limited production in 2002-2003 to support further at-sea testing and training, including integration with platforms like the E-2C Hawkeye 2000, which incorporated CEC for improved and coordination. In December 2002, USS conducted at-sea testing of CEC alongside Mountain Top systems, focusing on cooperative intercepts with SM-2 missiles to validate networked fire control in dynamic scenarios. Exercises such as the Fleet Battle Experiment series in the late 1990s and early 2000s empirically demonstrated CEC's enhancement of battle force air defense, with shared allowing platforms to engage threats beyond individual detection ranges, thereby expanding the effective engagement envelope across the group. By 2010, progressive integrations with surface combatants, E-2 Hawkeye aircraft, and select F/A-18 variants achieved fuller battle group netting, permitting seamless data relay for distributed lethality without compromising track accuracy or latency. These milestones prioritized measurable improvements in detection-to-engagement timelines over concerns regarding potential escalation dynamics in peer conflicts.

Technical Architecture

Sensor Networking and Data Fusion

The Cooperative Engagement Capability (CEC) sensor networking distributes unfiltered measurements—such as range, bearing, elevation, and Doppler—from radar and Identification Friend or Foe (IFF) sensors across networked platforms, including ships and aircraft, to form a shared battlespace picture. This raw data sharing preserves measurement precision and timeliness, unlike processed track exchanges that can introduce errors or delays. The Data Distribution System (DDS) supports this by employing directional beamforming, frequency-hopping spread-spectrum, and high-bandwidth links for secure, jam-resistant transmission of Associated Measurement Reports (AMRs). Data fusion occurs within the Cooperative Engagement Processor (CEP) at each node, where local and remote inputs are statistically combined into composite tracks, weighted by individual accuracies to enhance overall precision. Algorithms, including variants, handle track filtering, state prediction, and fusion of time-delayed measurements from distributed s, enabling stable estimates even for maneuvering targets at low update rates. procedures align disparate sensor frames across the network, ensuring consistent track numbering and correlation to minimize association errors in dense threat environments. Cesium-based achieves sub-microsecond timing, supporting low-latency updates critical for operations. The architecture distributes processing across nodes, with each CEP maintaining a local copy of the fused picture derived from shared AMRs, thereby eliminating single points of failure and enabling automatic data rerouting around disruptions. This resilience, combined with via notifications and of redundant reports, sustains high quality under constraints. Multi-sensor validation in the composite reduces false positives by cross-correlating measurements before declaration, facilitating accurate cueing for engagements at extended ranges, such as beyond local horizons using elevated data—up to 30-40 miles for updates.

Integrated Fire Control Mechanisms

The Cooperative Engagement Capability (CEC) integrates fire control by processing shared raw sensor measurements—such as , bearing, , and Doppler—through the Cooperative Engagement Processor (CEP) to generate composite tracks with fire-control quality precision sufficient for weapon engagement. These tracks derive intercept vectors and guidance solutions from remote sensors, enabling platforms to compute firing solutions without local detection of the target. Unlike surveillance systems that provide only detection cues, CEC's mechanisms emphasize actionable output by weighting measurements statistically based on sensor accuracy, ensuring the composite data supports midcourse guidance and terminal homing for missiles. A core mechanism involves broadcasting high-fidelity pointing data via associated measurement reports (AMRs), which deliver precise cueing information to non-sensor-equipped platforms, allowing them to achieve kill-chain closure through engage-on-remote launches. This offboard targeting capability permits surface effectors to utilize data from networked units for vertical cueing, where radars provide and data to cue vertical launch systems before horizon-limited local acquisition. Compatibility extends to weapons like the SM-2 missile and NATO Sea Sparrow, with remote data enabling extended-range intercepts by supporting coordinated guidance across units. By exchanging unfiltered measurements rather than pre-fused tracks, CEC preserves measurement fidelity for superior engagement quality, distinguishing its fire control focus from input-oriented . For instance, an E-2C aircraft's can cue a surface ship like the USS Anzio for composite tracking and launch, enhancing response times and depth-of-fire in anti-air warfare scenarios. This real-time integration, facilitated by the Data Distribution System (DDS), supports decision cycles with integrated fire-control solutions across the network.

Operational Deployment

Integration in US Naval Systems

The Cooperative Engagement Capability (CEC) has been integrated into Arleigh Burke-class (DDG-51) destroyers since the Flight IIA variant, beginning with (DDG-79) commissioned in 1999, enabling these platforms to share real-time sensor tracks with other networked units for cooperative targeting. This integration extended to aircraft carriers, with CEC processors installed on Nimitz-class (CVN-68) and later Ford-class carriers to facilitate battlespace-wide from shipboard and airborne sensors. By the early , CEC became a baseline capability on these core surface combatants, allowing upgrades to legacy fleets without full hardware overhauls, primarily through evolutionary software releases that enhanced track correlation and engagement handoff. CEC's interoperability with the on equipped destroyers and cruisers automates threat prioritization by fusing local data with remote sensor inputs, permitting a single platform to engage targets detected by distant units via precise fire control solutions. This embedding supports seamless retrofits, as seen in Block upgrades from AN/USG-2 to USG-2A and 2B variants, which refine data processing algorithms and expand compatibility with evolving baselines for improved anti-air warfare responsiveness. Such networked architectures yield superior kill webs over isolated legacy systems, where individual ships relied solely on organic sensors limited by horizon constraints and track quality degradation. By the mid-2010s, CEC equipped the majority of Aegis-equipped surface combatants, including over 60 destroyers and Ticonderoga-class cruisers, alongside carriers, forming resilient data-sharing grids that distribute targeting loads across the fleet. These integrations prioritize baseline enhancements for fleet-wide coherence, with ongoing Block upgrades ensuring adaptability to new threats through modular hardware insertions and software spirals without disrupting operational tempos.

NIFC-CA and Battle Force Applications

The Naval Integrated Fire Control-Counter Air (NIFC-CA) capability, operationalized in the early , extends the Cooperative Engagement Capability (CEC) by fusing real-time tracks from distributed sensors across naval assets, enabling cooperative targeting and engagement beyond line-of-sight horizons. CEC serves as the foundational data distribution network within NIFC-CA, allowing platforms such as Aegis-equipped destroyers to receive precise fire control-quality data from offboard sources, including airborne assets, for guiding weapons like the Standard Missile-6 (SM-6) against threats not locally illuminated. This integration shifts tactical operations from isolated platform defenses to a synchronized battle force architecture, where sensor cueing from distant nodes—such as the F-35's (MADL)—facilitates over-the-horizon intercepts without requiring continuous local radar lock-on. In battle force applications, NIFC-CA enhances collective defense against advanced air threats, including ballistic missiles and swarming drones, by distributing CEC-derived tracks to multiple firing units for layered engagements. For instance, during live-fire demonstrations, F-35 sensor data cued SM-6 launches from surface ships, achieving successful intercepts of surrogate targets at extended ranges exceeding 100 nautical miles. The system supports multi-domain kill chains, where unmanned platforms like the MQ-4C Triton provide persistent wide-area surveillance feeds into the CEC network, cueing effectors across carrier strike groups for time-sensitive targeting of hypersonic or low-observable threats. Empirical tests, such as the 2016 F-35 integration trial, validated this by demonstrating seamless via CEC and Link-16 gateways, enabling a single track to support simultaneous fires from disparate units. Fleet exercises underscore NIFC-CA's operational maturity in battle force scenarios, with the Pacific Dragon 2018 event integrating CEC for coordinated intercepts of simulated anti-ship ballistic missiles over the Pacific, involving ships and E-2D Hawkeye aircraft in a networked environment spanning hundreds of miles. These demonstrations revealed quantitative edges in engagement timelines, reducing response times by fusing offboard cues that bypass individual platform sensor limitations, thus enabling preemptive kills against salvos that would overwhelm standalone defenses. By prioritizing network-distributed fire control over legacy platform-centric models, NIFC-CA empirically amplifies battle force lethality, as evidenced by at-sea trials where CEC-enabled retargeting mid-flight defeated maneuvering targets, countering narratives that undervalue such qualitative multipliers in peer conflicts.

International Adoption

Australia

Australia adopted the Cooperative Engagement Capability (CEC) as the first non-U.S. nation, integrating the system into its three Hobart-class air warfare destroyers to enable real-time sensor data sharing and fire control coordination with allied forces, particularly the U.S. Navy. This capability, transferred via bilateral arrangements, allows Australian vessels to fuse radar tracks from multiple platforms, enhancing detection and engagement of air and missile threats in networked operations. Initial testing in April 2018 validated CEC's functionality on HMAS Hobart, the lead ship of the class, demonstrating effective data fusion that improved the Royal Australian Navy's (RAN) ability to defeat incoming air threats through integrated combat systems. A pivotal at-sea demonstration occurred in November 2018 off , where HMAS Hobart and the U.S. Navy's successfully exchanged tracking and fire control data via CEC links, confirming between the RAN's Aegis-equipped destroyers and U.S. Arleigh Burke-class vessels. This exercise represented the first such cross-national validation of CEC, enabling shared and coordinated targeting without reliance on voice communications. Subsequent operations, including a December 2020 exercise involving all three Hobart-class destroyers, further showcased CEC's role in multi-ship , supporting joint RAN-U.S. Navy maneuvers that strengthen bilateral deterrence in the by empirically verifying enhanced alliance responsiveness to regional threats.

Japan

The (JMSDF) integrated the Cooperative Engagement Capability (CEC) into its -equipped Maya-class destroyers, marking the first such adoption in the JMSDF fleet to enhance real-time sensor data sharing for networked operations. The decision to incorporate CEC occurred during the mid-2010s as part of upgrades to the Baseline 9 combat system, developed in cooperation with the to align JMSDF platforms with U.S. interoperability standards. This variant emphasizes adaptations for Japan's geographic constraints, prioritizing seamless across distributed sensors to support defense of the archipelago against threats, particularly from . The lead ship, JS Maya (DDG-179), was commissioned on March 19, 2020, following sea trials that validated its BMD enhancements, including CEC-enabled track sharing for improved missile cueing and engagement coordination. Subsequent vessels in the class, such as JS Haguro (DDG-180), followed suit, outfitting the fleet with CEC to integrate surveillance data with U.S. and allied assets for layered air and architectures. Unlike broader U.S. applications focused on open-ocean battle networks, Japan's implementation tailors CEC to archipelago-specific scenarios, fusing ship-based radars with ground-based systems like the PAC-3 for multi-layered interception against DPRK launches. CEC's role in JMSDF operations has been demonstrated in joint U.S.-Japan exercises, where it facilitates shared targeting for anti-missile engagements, bolstering deterrence amid North Korea's advancing missile arsenal, including hypersonic and multiple independently targetable reentry vehicle (MIRV) technologies. This integration differs from U.S.-centric uses by prioritizing defensive depth over offensive projection, aligning with Japan's constitutional limits on military roles while enhancing collective defense under the U.S.-Japan alliance.

India

In May 2019, the conducted its first successful cooperative engagement firing test using Medium-Range Surface-to-Air Missiles (MRSAM) from Kolkata-class destroyers and INS Chennai during a live missile exercise. This demonstration validated networked for distributed and fire control, marking the service's initial achievement of wide-area air defense through asset distribution across platforms. The system's architecture draws from the missile network, integrated with EL/M-2248 MF-STAR radars on the Kolkata-class vessels, enabling secure, jam-resistant data links for track sharing and coordinated intercepts. This integration supports cooperative targeting without direct line-of-sight between sensors and effectors, enhancing responsiveness to aerial threats. By September 2025, the had outfitted 10 warships with this capability, achieving the second-highest fleet integration globally after the and addressing deficiencies in real-time networked engagements relative to adversaries such as China's . These developments reflect indigenous adaptations through the (DRDO) and partnerships, prioritizing operational autonomy in contested maritime environments.

France

France maintains a limited and exploratory posture toward the U.S. Cooperative Engagement Capability (CEC), prioritizing interoperability testing within frameworks over full system adoption. In the , French naval forces participated in cooperative trials emphasizing data sharing protocols, particularly involving the carrier strike group, to assess track fusion with allied sensors during multinational exercises. These efforts focused on establishing compatible standards for sensor netting, enabling partial exchange of air contact data without integrating core CEC hardware or software into French platforms. A notable demonstration occurred in September 2019, when the validated indigenous cooperative engagement functions through the Veille Coopérative Navale system. During live-fire trials off the coast of , the frigate FS Jean Bart fired an Aster-30 missile using radar tracks provided by the destroyer FS Forbin, marking the first such surface-to-surface cooperative targeting in Europe. This capability, embedded within the Principal Anti-Air Missile System (), allows for offboard cueing and fused sensor pictures among French vessels but remains distinct from U.S. CEC, relying on datalinks augmented by national modifications rather than dedicated CEC processors. Strategically, France's approach bolsters NATO-compatible deterrence in European theaters, as evidenced by 's integration into exercises like the 2022 Mediterranean operations alongside U.S. and Italian forces, where shared tactical awareness enhanced collective air defense. However, it trails the depth of U.S. CEC deployments due to France's commitment to sovereign systems like , which emphasize missile integration and domestic radar suites (e.g., Herakles) over reliance on American networked fire control. This independence limits scalability in joint operations but preserves operational autonomy amid divergent procurement priorities.

Modernization and Upgrades

Post-2020 Enhancements

Following the intensification of great power competition, particularly with and , the U.S. Navy has pursued evolutionary software and increments to the Cooperative Engagement Capability (CEC) to enhance its role in joint all-domain operations. These upgrades emphasize real-time for a unified track picture across distributed platforms, supporting cueing beyond traditional naval air defense into broader cross-domain architectures akin to (JADC2). In 2022, CEC system sustainment and production efforts were aligned explicitly with JADC2 requirements, enabling high-fidelity and fire control by netting sensors from air, surface, and allied assets. Key post-2020 developments include upgraded CEC variants for expanded compatibility, such as the USG-2B for Aegis-equipped cruisers, destroyers, and carriers, and the USG-3B for E-2D Advanced Hawkeye aircraft, which facilitate deeper integration and faster reaction times against airborne threats. The USG-4B variant extends CEC to Marine Corps ground-mobile networks via the Composite Tracking Network, allowing cooperative engagement from littoral positions. These enhancements, in operational evaluations, improve depth-of-fire and intercept ranges by distributing track data instantaneously, addressing attacks through layered, networked defenses rather than isolated capabilities. In December 2023, the Navy's conducted follow-on operational test and evaluation (FOT&E) of CEC integrations, verifying sustained performance in simulated high-threat environments, including conditions where the system's C-band data links demonstrated inherent resistance. This testing confirmed CEC's ability to maintain track continuity and identification accuracy under , with the networked architecture allocating fires battle-force wide to counter saturation threats effectively. Such capabilities position CEC as a foundational element for JADC2, bridging naval sensors with systems like Integrated Battle Command System (IBCS) for multi-domain cueing.

Recent Contracts and Future Capabilities

In January 2025, , an RTX business unit, received a follow-on U.S. valued at up to $904 million over five years to act as the design agent for the Cooperative Engagement Capability (CEC) system. This award builds on prior efforts to advance CEC's engineering, with specific emphases on boosting between platforms and expanding sensor integration for in networked environments. The supports by addressing hardware constraints and enabling broader incorporation of diverse sensors, thereby enhancing the system's role in distributed operations. The Department of Defense's Modernized Selected Acquisition Report (MSAR) for CEC, dated December 31, 2023 and released in October 2024, outlines funding priorities for fiscal years 2023 through 2025 centered on evolutionary increments. These include and beyond upgrades, such as software enhancements for advanced fire control and hardware modifications to handle increased data throughput, aimed at sustaining CEC's integration with evolving naval architectures. The reports highlight investments in cryptographic updates and higher-bandwidth links to mitigate obsolescence while preparing for integration with next-generation effectors. Looking ahead, CEC's development trajectory emphasizes augmented lethality through refined weapon cueing and multi-domain coordination, with Increment II delivering hardware-software overhauls from legacy versions to enable precise engagements against dynamic threats. These upgrades are positioned to support hypersonic by facilitating rapid sensor-to-shooter loops across battle networks, including Aegis-equipped platforms, though full realization depends on parallel interceptor advancements. By 2030, sustained is anticipated to yield scalable capacity expansions via modular architectures, prioritizing resilience in contested electromagnetic spectra without specified quantitative targets in current assessments.

Vulnerabilities and Countermeasures

Electronic Warfare Threats

The Cooperative Engagement Capability (CEC) relies on high-bandwidth, line-of-sight wireless data links to fuse and distribute sensor tracks in , rendering it susceptible to (EW) that overwhelms these links with noise or interference. analyses have highlighted this since the early 2010s, noting that directed-energy weapons or high-power microwave systems could disrupt the system's ability to maintain coherent track pictures across networked assets. Spoofing attacks, which inject false data into the links, further risk corrupting shared , as the system's emphasis on rapid, automated fusion prioritizes speed over extensive validation of incoming signals. Adversary capabilities exacerbate these risks, with Chinese EW strategies explicitly targeting CEC's links to blunt US carrier strike group coordination. A 2024 Chinese military report outlined plans to use integrated jamming platforms to degrade radar-sensor accuracy and disrupt CEC data fusion, potentially isolating platforms and reducing cooperative engagement effectiveness in contested environments. Similarly, Russian systems like the Khibiny EW pods, deployed on aircraft such as Su-34s, have been assessed in simulations as capable of jamming naval radar networks that feed into CEC, though real-world impacts remain unverified beyond disputed Black Sea incidents involving Aegis systems. These threats are not absolute—CEC's directional antennas and frequency-hopping provide some resilience—but they underscore limits to the system's touted invulnerability against peer-level EW, particularly in high-intensity scenarios where link degradation could cascade into fragmented fire control.

Defensive Strategies and Resilience

The Cooperative Engagement Capability (CEC) integrates redundancies in its architecture to enhance resilience against disruptions, primarily through a distributed that fuses unfiltered track data from multiple platforms, including ships and , thereby avoiding dependence on centralized processing. This distribution enables participating units to maintain even if specific links or nodes are compromised, as the system dynamically reallocates contributions from surviving elements to sustain the common tactical picture. Engineering countermeasures in CEC include anti-jamming resistance in its RF data distribution links, which employ techniques to preserve under , alongside fallback protocols that prioritize local inputs for fire control when networked sharing is degraded. Doctrinal strategies emphasize adaptive operations, such as positioning distributed nodes to exploit line-of-sight redundancies and employing directional Ku-band transmissions that inherently limit vulnerability to wide-area by concentrating energy. Operational testing and exercises have validated these features, demonstrating CEC's capacity to support air defense engagements amid simulated threats by leveraging the networked to compensate for localized degradations. Recent program emphases, including 2025 investments, continue to prioritize such enhancements to evolving tactics.

Strategic Impact and Assessment

Proven Effectiveness in Operations and Exercises

The Cooperative Engagement Capability (CEC) has demonstrated enhanced and fire control integration in multinational exercises, such as Valiant Shield 2022, where it supported (JADC2) operations across U.S. Navy, , and allied units, enabling the detection, tracking, targeting, and simulated engagement of hostile air and surface threats through real-time sensor . This capability allowed participating platforms to leverage distributed sensors for coordinated responses, outperforming siloed systems by distributing targeting quality track data instantaneously among networked assets. In operational deployments since 2003 on Aegis-equipped surface combatants and E-2 aircraft, CEC has contributed to battle force anti-air warfare by fusing measurements from multiple platforms, permitting offboard engagements where sensors on one unit cue weapons on another, thereby extending effective engagement envelopes beyond individual platform limits. Department of Defense operational test evaluations have affirmed its suitability for sharing in contested environments, supporting intercepts and defensive maneuvers without reliance on voice communications. Demonstrations, including satellite-linked extensions tested in , have shown CEC expanding coverage by thousands of square miles, facilitating networked kills at ranges exceeding 200 nautical miles through precise track correlation and fire control handoff. Comparative analyses indicate CEC-equipped forces achieve 2-4 times higher throughput in target engagement cycles versus non-networked equivalents, as measured in system-of-systems simulations emphasizing causal links between and kinetic outcomes. These metrics underscore CEC's role in enabling distributed lethality, deterring peer adversaries by compressing decision timelines in high-threat scenarios.

Criticisms, Costs, and Strategic Debates

The Cooperative Engagement Capability (CEC) program has encountered persistent challenges related to cost overruns and acquisition delays, as documented in multiple () assessments. A 1995 Department of Defense Hotline audit revealed ineffective management practices in CEC development, including inadequate oversight of and risks of slippage. Early reviews in the late highlighted potential funding shortfalls tied to spectrum allocation issues, prompting recommendations for budgetary adjustments to avoid program disruptions. By 2006, deficiencies had necessitated revisions to award-fee structures, contributing to billions in overall Department of Defense acquisition incentives amid broader program inefficiencies. More recent evaluations, such as those from 2012 and 2013, noted that critical CEC testing milestones remained incomplete, delaying full integration with naval platforms and exacerbating lifecycle cost projections. Lifecycle costs for CEC, encompassing development, procurement, and sustainment, have shown growth in operating and support expenses, with the Department of Defense identifying increases exceeding initial estimates as of 2022. Selected Acquisition Reports from 2019 and 2023 underscore the program's ACAT classification, reflecting substantial investments in hardware like planar array antennas, with production requests extending through FY 2030 amid efforts to mitigate prior execution imbalances. Critics, including analysts, have argued that such overruns stem from underestimation of integration complexities with legacy systems, though officials maintain that preserved high-value assets through enhanced yield a favorable relative to unmitigated threats. Strategic debates center on CEC's heavy reliance on networked data sharing, which introduces dependencies vulnerable to disruptions that could fracture the "kill chain" process of detection, tracking, and engagement. Adversaries with advanced capabilities, such as those pursued by peer competitors, pose risks to CEC's track , potentially rendering distributed platforms ineffective if communication links fail, as noted in analyses of anti-access/area-denial environments. Some defense commentators question whether over-investment in CEC's centralized architecture diverts resources from alternatives like distributed lethality, which prioritizes autonomous unit engagements to reduce single points of failure, though empirical assessments favor CEC's retention and upgrades for maintaining edge in peer-level anti-air warfare scenarios. Proponents counter that CEC's paradigm is indispensable for scaling horizons against attacks, outweighing risks through layered redundancies, despite GAO-flagged schedule risks in upgrades like those for positioning, , and timing integration.

References

  1. [1]
    CEC - Cooperative Engagement Capability - Navy.mil
    Oct 14, 2021 · CEC gives an individual ship the added capability to launch anti-air weapons at threat aircraft or missiles within its engagement envelope based ...
  2. [2]
    [PDF] The Cooperative Engagement Capability* - Johns Hopkins APL
    The approach is a new Cooperative Engagement Capability (CEC) that allows combat systems to share unfiltered sensor measurements data associated with tracks ...
  3. [3]
    [PDF] The Cooperative Engagement Capability (CEC) - DTIC
    Cooperative Engagement Capability (CEC) is a system which promises to transform naval surface warfare to a major extent. An official description of the system ...
  4. [4]
    Cooperative Engagement Quietly Improves - U.S. Naval Institute
    CEC was developed initially in the 1980s by the Johns Hopkins University Applied Physics Lab as a Cold War initiative to strengthen Navy capability against ...
  5. [5]
    Raytheon marks 20 years of Cooperative Engagement Capability ...
    Jan 12, 2016 · With a history of innovation spanning 93 years, Raytheon provides state-of-the-art electronics, mission systems integration and other ...
  6. [6]
    CEC Provides Theater Air Dominance - U.S. Naval Institute
    One such technology is the cooperative engagement capability (CEC). Under engineering and manufacturing development since 1995, CEC is the foundation for ...<|control11|><|separator|>
  7. [7]
    Cooperative Engagement Capability: Enhancing battlefield awareness
    Aug 21, 2025 · CEC is a live data-sharing system that advances battlespace awareness and weapon coordination across the Navy. Through a combination of hardware ...
  8. [8]
    Cooperative Engagement Capability (CEC) - DTIC
    The Cooperative Engagement Capability CEC increases overall Naval Air Defense capabilities by integrating sensors and weapon assets into a single, ...
  9. [9]
    [PDF] Cooperative Engagement Capability (CEC) - Navy - DOT&E
    CEC is a real-time sensor fusion and netting system intended to enhance the situational awareness of equipped units and provide integrated fire control ...
  10. [10]
    [PDF] Cooperative Engagement Capability (CEC)
    This sensor netting system significantly improves Naval Carrier and Expeditionary Strike Group's Area Air. Defense capabilities by extracting and distributing ...
  11. [11]
    US$904m contract to boost US Navy Cooperative Engagement ...
    Jan 31, 2025 · ... Cooperative Engagement Capability. The Cooperative Engagement Capability (CEC) is a cutting-edge system that integrates sensors across ...
  12. [12]
    https://www.dote.osd.mil/Portals/97/pub/reports/FY2023/navy/2023cec.pdf
  13. [13]
    Cooperative Engagement Capability (CEC) Budget - HigherGov
    The Cooperative Engagement Capability (CEC) program, funded under Program Element (PE) 0607658N, is a Navy-led initiative focused on enhancing the ...<|separator|>
  14. [14]
    [PDF] CEC: Sensor Netting with Integrated Fire Control
    May 21, 2015 · The Cooperative Engagement Capability (CEC) is a spin-off from the Battle Group Anti-Air Warfare. Coordination (BGAAWC) program (see the article.
  15. [15]
    https://www.dote.osd.mil/Portals/97/pub/reports/FY2020/navy/2020cec.pdf
  16. [16]
    Cooperative Engagement Capability (CEC) - DTIC
    CEC is a real-time sensor netting system that enables high quality situational awareness and Integrated Fire Control IFC capability, which revolutionizes naval ...
  17. [17]
    [PDF] Cooperative Engagement Capability (CEC)
    Dec 21, 2022 · resistant to jamming and delivers accurate gridlocking between CUs. CEC is comprised of the following: - AN/USG-2/2A/2B: Shipboard ...
  18. [18]
    Cooperative Engagement Capability (CEC) / AN/USG-2(V ...
    Feb 16, 2000 · CEC improves warfighting capability in amphibious operations by enabling cooperating units to allocate radar energy to different areas of the ...Missing: US | Show results with:US<|separator|>
  19. [19]
    [PDF] COOPERATIVE ENGAGEMENT CAPABILITY (CEC)
    Apr 28, 2022 · Mission and Description. The Cooperative Engagement Capability (CEC) acquisition program is an ACAT IC program which is based on the Mission ...
  20. [20]
    [PDF] Navy Cooperative Engagement Architecture. Volume I - DTIC
    Full exploitation of a cooperative engagement capability will require insight into the following operational issues: • Organization by threat type versus ...Missing: protocols | Show results with:protocols
  21. [21]
    [PDF] The Cooperative Engagement Capability (CEC)
    Cooperative Engagement Capability (CEC) enables battle group ships and aircraft to share sensor data at speeds never seen before providing the entire battle ...
  22. [22]
    Naval Systems: Marines Engage Cooperatively | Proceedings
    In a pair of successful proof-of-concept demonstrations, the Marine Corps integrated a Marine air-ground task force's primary air surveillance radar with ...
  23. [23]
    COOPERATIVE ENGAGEMENT CAPABILITY (CEC) - FY98 Activity
    Approval to begin EMD (Milestone II) was granted in May 1995. An additional early operational assessment (OT-1A) of the airborne component of the CEC network ...<|separator|>
  24. [24]
    APL-Developed DoD Capability Approved for Production and ...
    Jun 24, 2002 · The Cooperative Engagement Capability (CEC), originally conceived by The Johns Hopkins University Applied Physics Laboratory (APL) in Laurel ...Missing: origins | Show results with:origins
  25. [25]
    USS Lake Erie (CG 70) history - U.S. Carriers
    From January 23-25, 2003, USS Lake Erie ... December 10, USS Lake Erie moored at Berth 2, Pier 3 on Naval Base San Diego following a seven-month deployment.
  26. [26]
    [PDF] Analysis of Effectiveness of CEC (Cooperative Engagement ... - DTIC
    This thesis develops a methodology to address Cooperative Engagement Capability (CEC) by modifying C2 theory developed by D.M. Schutzer.
  27. [27]
    [PDF] Tracking with Time-Delayed Data in Multisensor Systems - DTIC
    Oct 26, 2024 · Software Requirements Specification (SRS) for the Cooperative Engagement Capability ... The specific means by which these Kalman filter ...
  28. [28]
    [PDF] DDG 51 Arleigh Burke Class Guided Missile Destroyer (DDG 51)
    Beginning with DDG 79, Flight IIA ships introduced new capabilities including Cooperative Engagement Capability (CEC) and a. MK-45 Gun providing improved air ...
  29. [29]
    [PDF] DOT&E FY2024 Annual Report - Navy - CEC
    U.S. variants of CEC have three numeric designators. The “B” designator represents a capability upgrade that occurred within the legacy CEC program. • AN/USG- ...
  30. [30]
    [PDF] Cooperative Engagement Capability (CEC)
    CEC is a real-time, sensor-netting system that enables high-quality situational awareness and integrated fire control capability. • There are four major U.S. ...Missing: early | Show results with:early
  31. [31]
    [PDF] Modernized Selected Acquisition Report (MSAR) Cooperative ...
    Oct 4, 2024 · CEC follows an evolutionary acquisition process, delivering capability in increments of hardware and/or software upgrades. This evolutionary ...
  32. [32]
    Navy Expands NIFC-CA To Include F-35,Anti-Surface Weapons
    Jun 22, 2016 · Navy engineers are working to bring new aircraft sensors and new weapons into the Naval Integrated Fire Control-Counter Air (NIFC-CA) architecture.
  33. [33]
    Navy Conducts First Live Fire NIFC-CA Test with F-35
    Sep 13, 2016 · The Navy hosted its first live fire demonstration to successfully test the integration of F-35 with existing Naval Integrated Fire Control-Counter Air (NIFC-CA ...
  34. [34]
    F-35, SM-6 Live Fire Test Points to Expansion in Networked Naval ...
    Sep 13, 2016 · The addition of the MADL to the mix of the program of record links NIFC-CA now uses – like Cooperative Engagement Capability (CEC) and Link-16 – ...Missing: 4C | Show results with:4C
  35. [35]
    [PDF] 2022 Research Compendium - NAVAIR - Navy.mil
    Near-term Fleet Science & Technology focus areas includes: distributed, Live, Virtual and Constructive (LVC) training; adaptive training; human performance ...
  36. [36]
    [PDF] FY 2018 Annual Report - Director Operational Test and Evaluation
    Aug 21, 2019 · • The Navy conducted NIFC-CA FTS At-Sea-04 (AS-04) at the Point ... - During the Pacific Dragon 2018 Navy fleet exercise in. August 2018 ...<|separator|>
  37. [37]
    [PDF] Distributed Kill Chains: Drawing Insights for Mosaic Warfare ... - RAND
    CEC evolved into an. Acquisition Category (ACAT) I acquisition program and has become one of the pillar acquisition programs for the NIFC-CA FTS kill chain.
  38. [38]
    Navy Testing Battle Management Aid on Aircraft Carrier - USNI News
    Nov 26, 2020 · Kilby pointed to NIFC-CA, meant to connect data between ships and aircraft, as a first step in the pursuit of the kind of data network the ...
  39. [39]
    Australia and United States first countries to use Cooperative ...
    Nov 5, 2018 · “Australia is the first country outside the United States with Cooperative Engagement Capability, and so this demonstration marked the first ...Missing: RAN | Show results with:RAN
  40. [40]
    First Australian Aegis Destroyer Integrates with US Navy's ...
    Jan 8, 2019 · The vessel's ability to integrate with US Navy assets via the Co-Operative Engagement Capability (CEC), a US high-end naval networking capability so far made ...
  41. [41]
    Australian Defence Force demonstrates cooperative engagement ...
    Apr 17, 2018 · The Australian Defence Force's ability to defeat enemy air threats has been boosted with the successful testing of the new Cooperative Engagement Capability.
  42. [42]
    RAN tests Cooperative Engagement Capability on new Hobart class ...
    Apr 17, 2018 · The Royal Australian Navy has successfully tested the new Cooperative Engagement Capability (CEC) its new Hobart class destroyers will be equipped with.
  43. [43]
    US Navy and RAN demonstrate cooperative engagement capability
    Nov 8, 2018 · HMAS Hobart established secure data links with the US Arleigh Burke class destroyer USS John Finn and shared tracking and fire control data ...
  44. [44]
    Royal Australian Navy and US Navy Cooperative Engagement ...
    Nov 6, 2018 · The test was conducted between the RAN's new DDG HMAS Hobart and the USN's Arleigh Burke class DDG USS John Finn at the Pacific test range near ...
  45. [45]
    Australian, US Navy test Cooperative Engagement Capability off ...
    Nov 5, 2018 · Australia's first air-warfare destroyer HMAS Hobart teamed up with US Navy destroyer USS John Finn to share tracking and fire control data across the two ships.Missing: RAN | Show results with:RAN<|separator|>
  46. [46]
    Australia's Three Hobart-class Destroyers exercise together for first ...
    Dec 14, 2020 · Minister Price said the cooperative engagement capability allowed shared information and data to be integrated into the ship's Aegis combat ...
  47. [47]
    All three Hobart class in exercise | The Australian Naval Institute
    Dec 20, 2020 · Royal Australian Navy's three Hobart-class destroyers have exercised together for the first time, demonstrating their cooperative-engagement capabilities.<|separator|>
  48. [48]
    Japan commissions its first Maya Class guided missile destroyer
    Mar 24, 2020 · The ship is equipped with the US-developed Cooperative Engagement Capability (CEC) system, which enables the destroyer to act as part of a ...Missing: adoption | Show results with:adoption
  49. [49]
    Japan's New Guided Missile Destroyer to Be Fitted With SM-6 ...
    Sep 5, 2018 · Notably, the improved Atago-class will also be fitted with the so-called cooperative engagement capability (CEC), “a new wide-area integrated ...<|separator|>
  50. [50]
    Japan's Defense Priorities and Implications for the U.S.-Japan Alliance
    Jun 23, 2023 · The United States should approve and facilitate Japanese acquisition of the Cooperative Engagement Capability (CEC) as its sensor network to ...
  51. [51]
    The JMSDF Has Commissioned First Maya-class Destroyer
    Mar 22, 2020 · The ship is equipped with the US-developed Cooperative Engagement Capability (CEC) system, which enables the destroyer to act as part of a ...Missing: adoption | Show results with:adoption<|separator|>
  52. [52]
    Maya class Guided Missile Destroyer DDG JMSDF Haguro
    With this system, these destroyers are equipped with the Cooperative Engagement Capability (CEC) system. This will allow the ship to share surveillance or ...
  53. [53]
    Japan's Strategy to Confront North Korea's Nuclear and Ballistic ...
    Aug 21, 2023 · The Japanese government has now responded to North Korea's nuclear and missile development with a concept centered on the Aegis destroyer.
  54. [54]
    U.S., Japan, South Korea Establish North Korean Missile Warning ...
    Dec 19, 2023 · The United States, Japan, and South Korea announced on Tuesday that they have fully activated a real-time North Korea missile warning system.
  55. [55]
    Indian Navy completes MRSAM first cooperative engagement firing ...
    May 20, 2019 · The Indian Navy successfully completed a first cooperative engagement firing of the Medium-Range Surface INS Kochi Kolkata class destroyer test ...
  56. [56]
    India's Navy Successfully Tests Cooperative Engagement Capability ...
    May 20, 2019 · DRDO last conducted a successful test-firing of a LRSAM from a Kolkata-class guided stealth destroyer in January 2019. Prior to that, the ...
  57. [57]
    Indian Navy tests cooperative engagement capability with MRSAM ...
    May 21, 2019 · These surface to air missiles are fitted onboard the Kolkata-class destroyers and would also be fitted on all future major warships of the ...
  58. [58]
    Indian Navy Demonstrates 'MRSAM 'Cooperative Engagement ...
    May 17, 2019 · The test demonstrated the ability of MRSAM to operate wide-area air defense, distributing assets and control over different platforms and locations.
  59. [59]
    Indian Navy Achieves Milestone: 10 Warships Equipped ... - Idrw.org
    Sep 4, 2025 · The Indian Navy's CEC integration builds on the successful 2019 maiden test involving Kolkata-class destroyers INS Kochi and INS Chennai ...
  60. [60]
    Indian Navy successfully conducts Medium Range Surface to Air ...
    May 17, 2019 · Indian Navy successfully conducts Medium Range Surface to Air Missile test. The missile, which has been manufactured by Bharat Dynamics Limited, ...
  61. [61]
    NATO Allies exercise interoperability in the Mediterranean Sea
    Feb 8, 2022 · 6 to 7, 2022. The French carrier Charles de Gaulle's Task Force 473 integrated with the USS Harry S. Truman Carrier Strike Group and Italian ...
  62. [62]
    French Navy Demonstrates its 1st Cooperative Engagement with ...
    Sep 28, 2019 · This capability provides the French Navy a training environment ever more representative of real warfare environment. Veille Coopérative Navale: ...Missing: NATO | Show results with:NATO
  63. [63]
    French Navy Proves Cooperative Engagement Capability in Live Test
    Oct 7, 2019 · The French Navy has, for the first time, proven that it can conduct co-operative missile engagements launching an Aster-30 at a target ...Missing: NATO | Show results with:NATO
  64. [64]
    France - Missile Defense Advocacy Alliance
    France operates its PAAMS (Principal Anti-Air Missile System) jointly with Italy and the UK, deploying Aster 15 short to medium range missiles and Aster 30 ...<|control11|><|separator|>
  65. [65]
    L3Harris to produce and sustain CEC system for US Navy
    Jul 20, 2022 · The system is being developed to support US DoD's Joint All-Domain Command & Control (JADC2) efforts. July 20, 2022.
  66. [66]
    https://www.dote.osd.mil/Portals/97/pub/reports/FY2024/navy/2024cec.pdf?ver=xvG4Dd8XJvvjloP_zbyV_Q%3D%3D
  67. [67]
    How The Army Will Use Its Super Integrated Air Defense System
    Oct 30, 2024 · ... integrate the U.S. Navy's Cooperative Engagement Capability (CEC) to the IBCS Integrated Fire Control Network (IFCN). The joint multi-domain ...
  68. [68]
    RTX's Collins Aerospace awarded Cooperative Engagement ...
    Jan 29, 2025 · Collins Aerospace, an RTX (NYSE: RTX) business, was awarded a follow-on contract with a potential for up to $904 million over five years.
  69. [69]
    RTX's Collins Aerospace awarded Cooperative Engagement ...
    Jan 29, 2025 · PRNewswire/ -- Collins Aerospace, an RTX (NYSE: RTX) business, was awarded a follow-on contract with a potential for up to $904 million over ...
  70. [70]
    Cooperative Engagement Capability development contract for U.S. ...
    Jan 30, 2025 · RTX's Collins Aerospace won a follow-on contract worth up to $904 million over five years to continue development of the US Navy's Cooperative Engagement ...
  71. [71]
    Hypersonic weapon interceptor developments - Euro-sd
    Sep 15, 2025 · Overall, the Aegis system promises to provide a comprehensive and layered engagement capability against HGVs, with the GPI making the first ...
  72. [72]
    China Plans to Blunt U.S. Carrier Groups with Electronic Attack
    Dec 16, 2024 · According to the South China Morning Post, Mo's report highlights a key weakness in the CEC system: its reliance on wireless communication links ...
  73. [73]
    US Forces Untrained, Unready For Russian, Chinese Jamming
    Oct 30, 2019 · Training for electronic warfare threats is too easy, leaving troops dangerously unready for great power conflict.Missing: CEC Khibiny
  74. [74]
    China Releases 'Hit List' of US Naval Targets in Potential Conflict
    Dec 17, 2024 · This will reportedly reduce the detection accuracy of American radars and sensors, thereby diminishing the effectiveness of the CEC system.
  75. [75]
    Russia Claims Its Bomber Jammed U.S. Destroyer | by War Is Boring
    Apr 24, 2014 · “Khibiny is the newest complex for radio-electronic jamming of the enemy,” Russian Radio explained. “They will be installed on all the advanced ...Missing: CEC threats
  76. [76]
    https://www.dote.osd.mil/Portals/97/pub/reports/FY2015/navy/2015cec.pdf
  77. [77]
    Battle Lab supports cross-service JADC2, Valiant Shield exercise
    Jul 28, 2022 · ... Cooperative Engagement Capability, allowing participating units to find, fix, track, target, and engage constructive hostile air and naval ...
  78. [78]
    Battle Lab supports cross-service JADC2, Valiant Shield exercise
    Jul 28, 2022 · ... Cooperative Engagement Capability, allowing participating units to find, fix, track, target, and engage constructive hostile air and naval ...Missing: demonstrations | Show results with:demonstrations
  79. [79]
    Lockheed Martin Demonstrates New Satellite Range Extension ...
    Jan 27, 2003 · ... Cooperative Engagement Capability (CEC) by thousands of square miles. ... fire-control-quality composite track picture that supports ...
  80. [80]
    [PDF] Hotline Complaint on Management of the Cooperative Engagement ...
    Mar 10, 1995 · Cooperative Engagement Capability Program. The CEC Program is an ... fire control, radar picture. A production CBC-configured E-2C ...
  81. [81]
    [PDF] CEC Sale of Federal Spectrum - DTIC
    Nov 13, 1996 · Abstract: In this report, the GAO says that the Navy's Cooperative Engagement Capability, CEC, will run into trouble if more government ...
  82. [82]
    GAO-06-66, Defense Acquisitions: DOD Has Paid Billions in Award ...
    For example, after initial interoperability problems, the Cooperative Engagement Capability program added award-fee criteria to evaluate how well the system ...
  83. [83]
    [PDF] GAO-12-400SP, DEFENSE ACQUISITIONS: Assessments of ...
    Mar 29, 2012 · Cooperative Engagement Capability (CEC) remain to be completed. The CEC is a system that integrates information from multiple sources to ...
  84. [84]
    [PDF] GAO-13-294SP, DEFENSE ACQUISITIONS: Assessments of ...
    Mar 28, 2013 · Cooperative Engagement Capability (CEC), which is critical to that mission, was not ready in time for initial testing. CEC testing will not ...
  85. [85]
    [PDF] DOD Identified Operating and Support Cost Growth but Needs to Impr
    Feb 29, 2024 · Cooperative Engagement Capability (CEC)• ... 11%. Category A estimate percent change, 2018 to 2022. EA-18G Growler ... 19%. Category A estimate ...
  86. [86]
    Kill chain clash: China and US battle for all-domain supremacy
    Dec 19, 2024 · Kill chain clash: China and US battle for all-domain supremacy. China targets US naval sensors to cripple American kill chains as both powers ...
  87. [87]
    The U.S. Navy: More Bang for the Buck | Proceedings
    These were important factors in the buildup for the Gulf War. ... The arsenal ship's missiles would be launched under the cooperative engagement capability ...
  88. [88]
    Watchdog dings Defense Department's alternative PNT programs for ...
    Aug 9, 2022 · For the Cooperative Engagement Capability upgrade, the Navy said it did not plan to assess schedule risk. Instead of conducting a technology ...