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Capability Analysis

Distributed Lethality: The Future of the Helicopter Sea Combat Community

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By Lieutenant Commander Michael S. Silver, USN,  and Lieutenant Commander James J. Moore, USN

With contributions from Lieutenant Commander Loren M. Jacobi, USN, and Lieutenant Robert J. Dalton, USN

Introduction

The future of the Helicopter Sea Combat Community (HSC) community is at risk. HSC, which is made up of both carrier air wing (CVW) and expeditionary (EXP)squadrons that employ MH60S helicopters, struggles with its purpose to the fleet. Platform capabilities fail to keep pace with technological advancements and HSC warfighting relevancy is diminishing. A focused vision, careful risk mitigation, rebalanced mission priorities, and thoughtful platform acquisitions are needed in order to strengthen the fleet and secure the future of the HSC community.

What Does an HSC Vision for 2026 Look Like? 

What is needed is will—the fortitude to recognize that we have to change the way we currently operate. –VADM Thomas Rowden, “Distributed Lethality.”1

The HSC community of 2026 has a renewed focus on maritime employment and a customer-focused concept of operations based on the needs of warfare commanders. This means pivoting to become the maritime mission experts, integrating into a Carrier Strike Group (CSG), Amphibious Ready Group (ARG), or Independent Deployer via the Distributed Lethality (DL) model:  

“Distributed lethality is the condition gained by increasing the offensive power of individual components of the surface force (cruisers, destroyers, littoral combat ships [LCSs], amphibious ships, and logistics ships) and then employing them in dispersed offensive formations.”2

A pivot to distributed lethality requires alignment with warfighting requirements, focused funding along a revised community Roadmap/Flight Plan, and leveraging of existing naval aviation programs of record. The Mid-Life Upgrade (MLU) is a Naval Aviation Enterprise requirement that reviews and improves resources throughout the lifespan of platforms. The forthcoming MH-60S MLU presents a watershed opportunity for the HSC community. It offers the clearest path to match capabilities with warfighting requirements outlined in the CNO’s Design for Maintaining Maritime Superiority while meeting the demands of an environment increasingly shaped by the need for network-enabled technology in constrained budgets.3 Assuming the current Service Life Extension Plan (SLEP) will deliver the first MH-60S in 2028, the MLU opportunities for warfighting upgrades, guided by HSC Roadmaps and aligned with a maritime pivot to DL, will enable the HSC community to provide warfare commanders with the capabilities they require to meet future maritime security challenges.

President Trump is calling for more ships in the Fleet and the Navy’s revised force structure assessment will likely drive an increase in demand for MH-60S missions. Now is the time for the HSC community to make the most of the MLU in order to recast itself in the mold of DL. Doing so will create a future comprised of more powerful, networked platforms combined with innovative tactics that enhance naval warfare capability and support developing requirements generated from national strategy.

Limiting Risk

HSC has assumed an injurious level of risk training to a broad range of specialized warfare competencies. The battle to maintain currency and proficiency in specialized overland missions has increased risk, resulted in mishaps, and has made warfare commanders reluctant to rely on the HSC community for overland personnel recovery (PR), special operations forces (SOF) missions, and direct action (DA) missions. Historical HSC community data reveals that over 50 percent of HSC mishaps occurred during controlled flight into terrain (CFIT), with the majority occurring during training in a degraded visual environment (DVE) or executing unprepared landings (UPLs), resulting in four Class A mishaps, three Class B mishaps, 22 Class C mishaps, and one Class D mishap.4

Compounding this data, the HSC community has relied on Seahawk Weapons and Tactics Instructors (SWTIs) as subject matter experts to teach the most challenging missions, but SWTIs have struggled to maintain minimum flight hour requirements themselves.5 The CNO’s direction to “guide our behaviors and investments, both this year and in the years to come” demands that the community’s plan for the future adheres to responsible risk/benefit analysis. To do so, the HSC community should consider tailoring Defense Readiness Reporting System-Navy (DRRS-N) requirements to focus on maritime missions that contribute to a DL model.6

 Rebalancing Mission Priorities

 Fleet Carrier Air Wing HSC Squadrons maintain 10 primary mission areas and four secondary mission areas encompassing 210 required operational capabilities.7 A visual depiction of HSC missions can be seen in the figure below.

Given constrained resources, the number of specialized mission areas (seen at the top of the figure) is inversely proportional to the ability to perform those missions well. When considering where to allocate future resources, the HSC community must prioritize the maritime domain. The current MH-60S, which makes up 275 of the 555 aircraft in the Navy’s MH-60R/S inventory, lacks adequate sensors, sensor integration, and long-range weapons systems that warfare commanders require. As a result, decision makers mainly rely on the MH-60R to perform anti-surface warfare (ASUW) and anti-submarine warfare (ASW) missions focused on maritime dominance. The HSC community must obtain the systems that warfare commanders desire and focus training on the missions that utilize them. 

According to the Master Aviation Plan (MAP), there will be an increase in HSC employment as more LCS enter the fleet. This will be a major driver for requirements and is consistent with the DL concept. Since USN units are expected to be lethal against a broad range of threats, the HSC community must use existing opportunities to ensure that MH-60S integrated sensors are absolute requirements in order to provide situational awareness for warfare commanders, augment networked targeting platforms, and become a relevant sea control platform.

“The more capable platforms the adversary has to account for, the more thinly distributed his surveillance assets will be and the more diluted will his attack densities become. The more distributed our combat power becomes, the more targets we hold at risk and the higher the costs of defense to the adversary.”8

Rebalanced HSC mission sets should prioritize SAR/LOG/HADR, AMCM, UAS & SSC, and ASUW, while carefully tailoring overland PR/SOF DRRS-N requirements. 

SAR/LOG/HADR. Warfare commanders have historically demanded force-enabling mission sets from the rotary wing community and they will continue to be necessary core competencies operating aboard any surface platform. In addition to supporting daily operations, the HSC community has made significant strategic contributions executing SAR/LOG/HADR mission sets in times of crisis (e.g. tsunami relief operations, non-combatant evacuation operations, etc.). With the Trump administration demanding an increase in fleet size and publicly supporting a 350 ship Navy, it is logical to assume that there will be additional demand for force-enabling missions that require rotary support. The MH-60S is the platform of choice to meet increased demand for these mission sets and the HSC community should position itself accordingly.

AMCM. According to the Naval Aviation Vision 2016-2025, “effective mine warfare is a key tenet of the Navy’s anti-access/area-denial (A2AD) strategy, and AMCM plays an important role in executing that strategy,” yet the HSC community has fundamentally marginalized and underdeveloped this important capability.9 Already a Navy program of record, focusing on AMCM will address a significant challenge to U.S. maritime superiority. The MH-53E brings significant capability to heavy-lift contingency logistics requirements, while being a proven AMCM platform. With several MH-60S AMCM systems failing to meet requirements, a heavy lift replacement like the MH-53K would provide a baseline for LOG and AMCM missions. The MH-60S and unmanned HSC platforms like Fire Scout need to augment AMCM capabilities as soon as possible in order to counter this powerful asymmetric threat and contribute to the success of DL.   

UAS & SSC. HSC is the first Naval Aviation community to significantly develop and integrate unmanned systems, which purports to be a force multiplier in DL operations. Becoming UAS experts positions the HSC community to become leaders in the SSC mission, providing greater range, sensor capability, and distributed lethality than manned rotary-wing assets, while simultaneously reducing human risk, cost, and impact to routine events such as CVN cyclic operations. Currently, UAS is a secondary requirement on FRS and Expeditionary squadrons. Flight crews and maintainers are required to maintain separate currency and qualification on diverse platforms. Unmanned systems are integral to the future of warfare and the HSC community should explore resourcing commands and crews that are devoted to unmanned platforms.

MAYPORT, Fla. (Aug. 3, 2011) Two MQ-8B Fire Scout unmanned air vehicles are aboard the guided-missile frigate USS Halyburton (FFG 40) for an offload at Naval Station (NS) Mayport. (U.S. Navy photo by Mass Communication Specialist 2nd Class Gary Granger Jr./Released)

ASUW. Whether operating as part of a CSG, ARG, or Independent Deployers; offensive and defensive anti-surface capabilities offer warfare commanders a wide range of options while simultaneously adding complexity to the calculus of potential maritime adversaries. An HSC DL model can protect a high value unit (HVU), hold enemies at risk at range with a wide variety of unguided or precision guided munitions, and employ the MH-60S in conjunction with the MH-60R when required, all in the interest of defending Sea Lines of Communication and ensuring maritime security and superiority.

PR/SOF. Despite an increased focus on overwater missions, overland mission capability must still exist organically within the Navy Rotary Wing community. Overland capability must be maintained in a resource-constrained environment while implementing ways to mitigate risk. This could be accomplished by carefully tailoring training requirements for specific AORs beyond the current HSC Seahawk Weapons and Tactics Program 3502.6. Commands that are not projected to operate overland while deployed should be expected and even encouraged to report “yellow” or “red” in DRRS-N, reducing the risk associated with specialized overland mission sets and freeing up resources for other mission areas. This will permit the HSC community to “demonstrate predictable excellence in the execution of our maritime missions” and increase tactical relevance by seeking missions that are desired by warfare commanders.

BAHRAIN (April 25, 2012) Mass Communication Specialist 1st Class Shane Tuck, assigned to the underwater photo team of Expeditionary Combat Camera, climbs a ladder into an SH60 Sea Hawk helicopter during cast and recovery training with Explosive Ordnance Disposal Mobile Unit (EODMU) (U.S. Navy Photo by Mass Communication Specialist 1st Class Jayme Pastoric/Released)

While accepting some risk in the overland power-projection/PR missions, the HSC community needs to link squadrons to relevant NSW and other SOF units to be the customer of choice when doing SOF missions in the maritime domain. Missions should be trained to and executed on a sound risk/reward level to give SOF the reach needed to execute their effects from traditional and non-traditional surface platforms. A ship takedown executed from a Military Sealift Command (MSC) ship or LCS may be an emerging counter terrorism requirement in the globalized threat domain.

Technology/Acquisitions Recommendations

DoN budget challenges (Columbia-class SSBN, shipbuilding, TACAIR Inventory Management, etc.) will continue to pressure naval rotary wing funding. The MH-60 Service Life Assessment Plan (SLAP), beginning in FY17 and transitioning into SLEP in the early 2020s, provides a unique opportunity to incorporate key mission upgrades and capabilities in conjunction with MH-60 MLU. While MLU is still unfunded and currently outside the Future Years Defense Plan (FYDP), the HSC community should work with OPNAV N98 and the Naval Aviation Enterprise (NAE) to support upgraded MH-60S capabilities that enhance Fleet DL.

Obtain RADAR capability. The HSC community is the aviation asset for LCS, but it has virtually no networked sensor capability. In a distributed threat environment, the MH-60S needs to be able to contribute additional sensor information to decision makers and shooters. The logical solution is a phased planar array RADAR, which gives HSC the ability to positive hostile identify (PHID) at range and use RADAR designation for the Joint Air to Ground Missile (JAGM). An LCS based SAG needs air-based sensor coverage, all-weather PHID capability, and the ability to hold the enemy at risk, at range. JAGM Block III (another Navy program of record), will virtually double the range of the HELLFIRE missile. Due to limitations of the current MH-60S MTS sensor at long ranges in humid overwater environments, the HSC community will face significant limitations in utilizing JAGM at ranges beyond legacy HELLFIRE capabilities. The MH-60R, with RADAR-based designation capability will be able to utilize the full range envelope of JAGM. Until this gap is bridged, only the 280 MH-60R helicopters out of the Navy’s 555 MH-60R/S inventory will be able to leverage the full capability of this weapon. Obtaining RADAR imaging and designation will enable the MH-60S to integrate into the overwater joint fires world of DL.  

Approve the MH-60S “Torpedo Truck” concept for the Pacific Fleet. The “Torpedo Truck” concept multiplies warfighting effectiveness for any battle group by permitting HSC platforms to carry torpedoes that can be employed in conjunction with an MH-60R. Time on station is primarily determined by fuel load and aircraft weight limitations necessitate a choice of either additional fuel or expendables such as torpedoes. Outfitting an MH-60S “shooter” platform with torpedoes permits an MH-60R platform to take off with more fuel (instead of torpedoes) and remain on-station as the “designator” for longer periods of time. The MH-60S “Torpedo Truck” significantly increases ASW warfighting capability (particularly on LCS) and enhances DL. Additionally, to bring ASW capability to a broad range of Independent Deployers, the “Torpedo Truck” directly supports DL requirements. No matter what the ASW threat, a threat submarine needs to be close in to launch a torpedo against a ship. The DL concept applied to ASW in a non-traditional LCS SAG is only possible with the ability to employ organic weapons that can hold the enemy at risk, at range. The “Torpedo Truck” concept has already been endorsed by Carrier Air Wing FIVE (CVW 5) and requires further review from higher Pacific Fleet echelons. Commander DESRON 15, Commander NAWDC, Commander CTF 70, and Commander SEVENTH Fleet should consider generating an urgent operational needs statement based on current and projected submarine threats, and work with OPNAV for immediate approval.11

Obtain Ku-band HAWKLINK capability. The HSC community needs to connect HAWKLINK to warfighting requirements as they are currently written. HAWKLINK permits full motion multi-spectral targeting sensor (MTS) video feeds that are demanded by warfare commanders who desire real-time evaluation of potential ASUW threats. Additionally, the “Torpedo Truck” concept could drive the ASW requirement for HAWKLINK (in SEVENTH Fleet in particular). It is not possible to have pervasive, wide-area sensor coverage over the entire Pacific. It is possible, however, to use distributed sensors to localize threats in the form of ship-based towed arrays, submarine-based networking, and P-8 buoy brickwork. Having HSC detachment-based, LCS-organic capability to launch weapons allows networked sensor systems to continue search and localization without coming off-station to launch a weapon for both ASUW and ASW missions. 

Procure MH-53K Heavy-Lift and AMCM capabilities. CSG logistics requirements are immense when operating continuous flight operations, particularly during a contingency that prevents or delays pulling into port. Sea basing for this environment without heavy lift support remains untested with smaller platforms like the MH-60S. With the growing asymmetric mine threat and unproven/failed MCM technology for smaller platforms, a heavy-lift replacement for the Helicopter Sea Combat HM squadrons would provide a sound baseline for both MCM and LOG warfighter capability while the MH-60S and Fire Scout augment via a more distributed model.

Conclusion

Now is the time to chart the future of the HSC community. Dogged adherence to the current HSC model may have negative implications for HSC aircrews and will likely result in the same warfighting triviality that has frustrated the community for years. However, if the HSC community is confident enough in its vision to adjust course and take advantage of existing opportunities with a renewed focus on maritime missions and well-planned, achievable warfighting enhancements that strengthen Fleet DL, it can and will be dedicated to safely executing mission sets that warfare commanders demand on a regular basis.

Michael Silver is a Lieutenant Commander in the U.S. Navy and an MH-60S pilot with more than 2,600 flight hours. He most recently served as the Operations Officer for Helicopter Sea Combat Squadron Twelve as part of Carrier Air Wing Five, based in Atsugi, Japan.

Jake Moore is a Lieutenant Commander in the U.S. Navy and an MH-60S pilot with more than 2,800 flight hours. He most recently served as the Maintenance Officer for Helicopter Sea Combat Squadron Twelve as part of Carrier Air Wing Five, based in Atsugi, Japan.

The opinions expressed above are those of the authors and do not necessarily reflect the views of the Department of Defense or the U.S. Navy.

References

1. VADM Thomas Rowden, RADM Peter Gumataotao, and RADM Peter Fanta, U.S. Navy, “Distributed Lethality,” Proceedings Magazine, Jan 2015 Vol. 141/1/1,343, pp. 4

2. “Distributed Lethality,” pp. 1                            

3. ADM John M. Richardson, U.S. Navy, A Design for Maintaining Maritime Superiority 1.0, 2016

4. FY11-FY16 HSC Community Mishap Data

5. HSC Weapon School SWTIs struggled to maintain a tactical hard deck of 10 flight hours per pilot per month during FY16

6. CNO ADM John M. Richardson, A Design for Maintaining Maritime Superiority 1.0, 2016, pp. 4

7. OPNAV Instruction C3501.384, 17 May 2011

8. “Distributed Lethality,” pp. 1

9. VADM Mike Shoemaker, U.S. Navy, LtGen Jon Davis, U.S. Marine Corps, VADM Paul Grosklags, U.S. Navy, RADM Michael Manazir, U.S. Navy, RADM Nancy Norton, U.S. Navy, Naval Aviation Vision 2016-2025, pp. 44

10. CAPT B. G. Reynolds and CAPT M. S. Leavitt, U.S. Navy, 2016 HSC Strategy, 11 Jul 2016

11. CDR Jeffrey Holzer, U.S. Navy, MH-60S Torpedo Truck Point Paper, 18 Sep 2014

Featured Image: PACIFIC OCEAN (April 30, 2013) An MH-60S Sea Hawk helicopter from Helicopter Sea Combat Squadron (HSC) 21approaches the flight deck of the amphibious transport dock ship USS New Orleans (LPD 18) during night flight operations. (U.S. Navy photo by Mass Communication Specialist 2nd Class Gary Granger Jr./Released

Capability Analysis

The Age of the Strike Carrier is Over

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By LT X

The age of the strike carrier is over. As the United States enters an era where the potential for modern great-power war is increasing dramatically in Eurasia, a return to the traditional roles of the aircraft carrier is required to maintain maritime access. Carrier-borne over-land strike warfare has not proved decisive in previous conflicts in heavily contested air defense environments, and will not prove so in the future. In the potential high-end conflicts of the twenty-first century, the likely utility of carrier-based land strike is largely non-existent. Thankfully, the traditional carrier aviation roles of maritime interdiction and fleet air defense remain highly valuable in wars against modern navies, but are precisely the roles, missions, and tactics sacrificed for sea based over-land strikes over the past sixty years. Regaining this capability will require a modest investment in existing and developing systems and capabilities and should be the force’s, the service’s and the nation’s highest objective in the coming years.

Aircraft Carriers in Over-Land Strike

American carrier airpower received its combat indoctrination in the Pacific War. However, pollution of the history of that campaign by naval aviation and airpower enthusiasts caused the lessons of that war to ossify over time. During Fleet Admiral Chester W. Nimitz’s campaign aircraft carriers and their air wings almost exclusively provided maritime interdiction and fleet air defense. There are three major exceptions to this rule; Doolittle’s raid, the offloading of the Enterprise air group to Henderson Field during the Solomon Islands operation, and the strikes against the Japanese redoubts and the home islands late in the war. Additionally, carrier air forces provided strikes to Marine landings and naval aviation supported the Army landings of MacArthur’s campaign, most famously at Leyte. Admiral Kinkaid’s light carriers supported much of this effort, as well as Vice Admiral William F. Halsey’s and Raymond Spruance’s fast carrier task forces of Third and Fifth Fleets. 

Doolittle’s raid, a strategic success due to its propaganda value, did not obtain any operational or theater-strategic gain, provided no notable hindrance to the Japanese war effort, and was conducted with US Army Air Corps (USAAC) B-25 Mitchell aircraft. Only the USAAC aircraft possessed the combination of ordnance load, endurance, and thrust to make the adventure over the Japanese home islands possible, even as a publicity stunt.

When the Enterprise disembarked her air group to Henderson Field, her aircraft provided valued support to the Marines fighting their way across Guadalcanal and to American naval forces fighting for sea control in Iron Bottom Sound. During the campaign, the major value of those aircraft remained air defense and anti-surface warfare. The Enterprise air group made combat air patrols, searched Iron Bottom Sound during daylight, and engaged any Japanese ships unfortunate enough to find themselves in range in daylight. The Enterprise air group’s combat air patrols made daylight resupply of Japanese Army units impossible, a sea control, anti-surface warfare capability. While the air group could not provide enough firepower accurately enough to dig the Japanese out of the jungle by themselves, it successfully isolated the battlespace to allow the Marines to do their work as it controlled the approaches to Iron Bottom Sound.  

After Midway and the Solomon Islands campaigns, American carrier air power did begin to conduct some overland strike, mostly in the form of raids on enemy bases, but the fast carrier task forces remained focused on fleet air defense and anti-surface warfare. This alludes to the fact that, despite its ailing naval forces, Japan’s air and surface units still represented a potential threat to the American war after 1942. This was true as long as they possessed the capability to conduct a highly destructive strike against American fleets. 

Leyte Gulf totally destroyed this capability and thereafter American carriers began wholehearted support of major fleet landings. However, in these endeavors they posted a mixed record, being unable to provide enough ordnance precisely enough to make the Marines’ tasks much easier as they tried to advance over hard volcanic rock on Iwo Jima and the difficult terrain and defense in depth on Okinawa. Indeed, in these campaigns, American carrier air power’s signature achievement proved the destruction of the Japanese super-battleship, not any air-to-ground ordnance delivery.

The history of the Second World War has been polluted by naval aviation, claiming the conflict as the age of the aircraft carrier. This stands almost no historical scrutiny. The campaign hung in the balance in the Solomons as much as Midway or Coral Sea, with no U.S. carriers available.  Moreover, battleships proved highly useful throughout the war with their extensive anti-air armament and state-of-the-art radars providing close-in air defense for task forces. The Pacific War’s history is much more nuanced than naval aviation enthusiasts give credit for, and at its conclusion, not the carrier but the aircraft carrier task force proved to be the central weapon of war, with naval aviation posting meager results in ground support or strategic land strike.

What commonly became known as the “strike” aircraft carrier (CVA) was, in fact, the atomic carrier. In a memorandum as assistant Chief of Naval Operations for guided missiles, Rear Admiral Daniel V. Gallery opined that the U.S. Navy could strike more flexibly, as effectively, and at less cost than land-based, atomic-armed bombers requiring local bases to launch their fighter escorts. Gallery’s motivation was at least partially parochial. The newly-formed U.S. Air Force was, at the time, attempting to cultivate a monopoly on nuclear strike planning. In the era as the only nuclear superpower, it seemed nuclear delivery would prove the best option for continued longevity of the U.S. Navy’s fleet. In this effort, the Navy reconfigured attack carrier air wings to deliver Navy special weapons. This reconfiguration was the first time a carrier air wing was doctrinally tooled for ground attack and strategic strike, vice the sea control disciplines of fleet air defense and anti-surface warfare. Over time, this strike carrier became the norm. Rather than provide value to the fleet, misperceptions of the efficacy of land attack caused the platform’s gradual devolution from a system that provided capability to the task force to a platform that sucked capability from it. With its air wing largely servicing land targets, the strike carrier now required the very anti-surface, anti-submarine, and anti-air capabilities it used to augment, to allow more substantial (although increasingly less effective) overland raids.

This strike configuration premiered during the Korean War. The Peninsula lacked a sophisticated air defense or early-warning system and communist forces only contested air superiority in MiG Alley on the western Sino-Korean border. Therefore, naval and Marine aircraft operating off of carriers did produce notable results in ground support. However, given the limited nature of the conflict, the austere environment of the peninsula, and the technical lack of sophistication of Chinese and Korean forces, it is hard to determine the overall effect of carrier air power. At any rate, whatever the tactical, operational, or strategic limitations imposed, the conflict ended inconclusively, whatever naval aviation’s record.

https://gfycat.com/ThankfulChubbyBullfrog

Aircraft launch off USS Valley Forge during the Korean War (Naval History and Heritage Command)

Likewise, the utility of the attack aircraft carrier proved mixed over Vietnam. During the Vietnam War, the communist North enjoyed competing Chinese and Russian military (as well as diplomatic and political) support. The Soviets provided a totally linked and integrated air defense network around vital areas including Hanoi and Haiphong Harbor, the two most strategic areas. This air defense system proved too dense and advanced for American carrier-launched aircraft to reliably penetrate and deliver ordnance. Indeed, during Operation LINEBACKER II, only B-52Ds with their improved Electronic Countermeasure (ECM) packages, proved able to operate in the zones. This represented a failure of American carrier air power. If the multiple aircraft carriers operating in the Gulf of Tonkin could not reliably penetrate North Vietnamese air defenses, what chance did they have off the Kola Peninsula or the Baltic?

Despite an air defense network similar to that installed over Hanoi, U.S. Naval Aviation contributed, but did not prove decisive in Desert Shield and Desert Storm. While fixed-wing, fast moving aviation assets provided impressive combat support, it took US Air Force F-117 Nighthawks, cruise missiles, and Air Force delivered precision munitions to penetrate the Iraqi air defense screen. Naval air forces proved totally unprepared for the precision munitions revolution, lacking laser target designators on the A-6s and A-7s that still formed the mainstays of the fleet. Instead, most naval aviation delivered Mk 80 series unguided weapons instead of the Paveway series carried by a small but growing section of Air Force platforms, including the Nighthawk. This made them incapable of delivering ordnance to targets with high risk of collateral damage and precluded many targets in Iraqi population areas, limiting the force’s contributions to the campaign to tactical and some operational strikes.

In the Balkan wars and later in Iraq and Afghanistan, American naval aviation never again faced an integrated air defense system. High hard decks precluded the efficacy of man portable surface-to-air rounds and obsolete mobile systems made air defense suppression a forgone conclusion rather than an aspirational goal in the early 2000s. Naval aircraft, belatedly modernized to take full advantage of the precision munitions revolution, delivered substantial amounts of ordnance in these conflicts, complementing American land-based air power. However, the aircraft lacked on station time and payload, showcasing a service preference for multi-role fighter-bombers with limited range vice the ultra-long range fighter and attack aircraft required for intercept and long-range anti-surface warfare. However, confronted with a total lack of modern air defense systems, they, like the Air Force, reigned supreme.

Never in its history has American naval aviation confronted a state-of-the-art, integrated air defense system and provided effective, strategic ordnance. Hypothetically, at times during the Cold War, American strike-configured carriers might have done so, but an era of fiber-optically interlinked, multi-frequency, phased array air defense systems totally precludes such operations. Moreover, naval aviation assets lacked the range to strike strategic targets deep in mainland China and central Russia, limited to around 1,000nm inland.

Modern Aircraft Carrier Utilization in Great Power War

The utility of the STRIKE carrier in great power conflict is over. More accurately, as the previous section highlighted, it never really existed. American strike carriers throughout their history proved incapable of gaining and maintaining access to heavily defended areas and this trend will only grow more severe. China’s Great Wall of air defense on the northern Taiwan Strait will again preclude American carriers from gaining access to strategic areas in mainland China. Russia’s high-value areas are already well defended. China’s continued investment in air defense systems will cause this problem to continue to distribute throughout Asia. Further, a series of anti-access systems fielded by China, but also increasingly by Russia, are pushing U.S. carrier task forces out of range of present naval aircraft.

American planners are hoping, almost as a matter of faith, that an increase in the range of carrier-based aircraft would provide for continued access. This approach is wrong-headed.  First, what land targets would such aircraft service? Perhaps Hainan Dao, or some rocks in the South or East China Sea, hardly a war-winning strategic strike. Second, how will these aircraft gain access in order to deliver the strike? American naval aircraft are too obsolete to deal with any but the most lightly defended of modern targets, and the F-35 will not markedly change this equation.

So let’s give up? Call it a day? Beef up Air Force appropriations? Not even close. American naval air power is the critical capability in the U.S. arsenal in the Western Pacific and the North Atlantic. Instead, force planners should recall why the U.S. built aircraft carriers in the first place, and where they last played a critical strategic role: in anti-surface warfare and fleet air defense. American carrier air power in the Pacific War hinged not on great strikes against the home islands, but rather on massing striking power against Japanese naval surface forces, Japanese air forces, and by protecting the fleet during operations and major landings. This is where naval aviation must again put its efforts.

Air wings at present are much better configured for low-risk ground attack than for operations against other navies. Air operations in the Pacific War required mass, exercising Halsey’s axiom that carrier air power increased at the exponent of the number of carriers engaged. Those operations encompassed large sorties, with hundreds of aircraft in major fleet actions. Over the past twenty-five years these skills have been lost. American carrier forces now exercise in single or dual carrier configurations. In Halsey and Spruance’s era, their fleets swelled into double digit large flattops, with myriad small deck escort carriers providing combat air patrols, anti-submarine forces, and landing support. Additionally, that war featured raids of hundreds of naval aircraft against enemy surface formations. Critics will claim that such mass is no longer required in the precision munitions era but such claims ignore that defense systems have also improved dramatically, making saturation the only sure way to put sophisticated, modern air defense ships out of action. To be clear, this author is not advocating a wholesale return to Nimitz’s fast carrier task force. However, the tactics, techniques, procedures, and training of American carrier air forces are out of touch with a modern, sea-control war, and a single U.S. CVN must be able to generate the mass and firepower necessary to fight in a modern, contested sea environment.

American naval aviation forces have not experienced platforms with the anti-air capabilities of ships as capable as the current generation of Chinese Navy Luyang hulls. U.S. tactics presently involving two or four aircraft sorties are totally inadequate for destroying an AEGIS-equivalent ship. To overwhelm a Chinese, or even an aging Russian surface formation, will likely require dozens of anti-ship cruise missiles. A single carrier must contain the capability to put such a ship (ideally many such ships) out of action, quickly. However, at present such a task requires the bulk of a modern air wing to generate the volume of fire required. This would likely also require a total re-arming of carrier magazines with a focus on sea control weapons and systems lest a CVN run itself out of anti-ship missiles in a few early engagements.

Moreover, distributed lethality requires a distribution of air power. Without fast-moving defensive counter-air formations operating with small surface action groups, American light forces will find themselves extremely vulnerable to attack. Modern surface combatant anti-air weapons range remains about 100nm. Modern air-launched anti-ship cruise missiles regularly feature twice that range and increasingly much greater. Without defensive counter-air formations attached to light surface forces, enemy aircraft will use the haven of range to mass firepower, overwhelming a formation’s air defenses while maintaining relative safety over the horizon. Allowing distributed light forces some measure of defensive counter-air capability will allow those formations to break up air attacks, ideally precluding saturation of U.S. platforms, offset electronic emissions away from the formation to make enemy targeting of the group more difficult, and therefore dramatically increase survivability.

MEDITERRANEAN SEA (July 1, 2016) – An F/A-18F Super Hornet assigned to the Fighting Swordsmen of Strike Fighter Squadron (VFA) 32 launches from the flight deck of the aircraft carrier USS Dwight D. Eisenhower (CVN 69) (Ike).  (U.S. Navy photo by Mass Communication Specialist 3rd Class Anderson W. Branch/Released)

The United States certainly has the capability to maintain the primacy of its carriers, especially in the maritime-dominated Western Pacific. The U.S. must use its large-decks to maximum potential. This includes American large-deck amphibious shipping, in the form of LHDs and LHAs. Such ships’ amphibious capability will likely not add much to the initial phases of great power war when sea control and air superiority are contested. Importantly, small carriers proved highly useful in both Atlantic and Pacific theaters of the Second World War, providing long-range air defenses for convoys and robust anti-submarine capability outside of the range of land-based air power. In the 1960s, the U.S. began using Essex-class carries in an anti-submarine configuration (CVS vice the strike carrier CVA). In fact, USS Intrepid, a CVS-configured carrier, conducted strikes into northern Vietnam off Yankee Station, when it became apparent that PRC submarines did not pose a serious threat to the American Carrier Operating Areas (CVOAs). Likewise, the British prioritized antisubmarine work and limited air defense capability in their Invincible-class light carriers which featured heavily in the Falkland Islands War. American Wasp– and America-class ships, loaded with F-35s, SH-60s, and MV-22s, can provide the same – an air defense, anti-surface, and anti-submarine screen. Operating in the vicinity of a Surface Action Group Operating Area (SAGOA), the large-decks could provide on-station defensive counter-air, visually identify unknown contacts, and augment the ASW aircraft from a SAG to increase the group’s submarine localization and anti-surface strike capacity.

American naval forces are only a fraction of the way to recognizing the capabilities the MV-22 provides. At present, the U.S. Navy has only tested MV-22 Osprey tiltrotor aircraft in a Carrier Onboard Delivery (COD) capacity, the CMV-22. However, the aircraft retains substantial potential in anti-submarine warfare and airborne early warning, among other uses. U.S. Navy carrier task forces until the early 2000s incorporated the S-3 Viking aircraft, a high-subsonic anti-submarine jet. These aircraft retired in the early 2000s due to lack of fleet interest in anti-submarine warfare. In the heavily contested North Atlantic or Western Pacific, against foes with modern undersea forces, such a capability once again is required. The MV-22 would expand this capability. While slower, it provides potential marked improvements in range, low-altitude handling, on station time, and sensor payload. Such aircraft would provide a step-increase in surface-force ASW capability, potentially loaded with dipping sonars, sonobouys, and a large number of Mk 54 torpedoes. Further, mounting a high-performance radar on such an aircraft would allow some measure of airborne early warning to small surface units. Combined with point-to-point data links, these aircraft could provide over-the-horizon situational awareness while limiting surface force’s radar transmissions. This would complete the capability of the light-carrier air group described above and substantially increase the lethality of the small satellite surface groups orbiting the aviation ship. Additionally, due to their vertical takeoff and landing capability, the MV-22 could potentially lily pad off smaller ships, particularly the huge flight decks of Independence-class Littoral Combat Ships (LCS) increasing their time aloft forward. While heat management proved frustrating early in the aircraft’s tenure, this issue has been fixed with temporary heat shields which could be staged onboard. The MV-22 provides a cheap method to reconstitute integrated ASW capability and provide survivable, high-speed warning and reconnaissance.

U.S. Naval Aviation must train for saturation raids, publicly. Saturation attacks are a lost art, and likely aviation forces have much to learn. Such attacks will require heavy coordination between aircraft and squadrons, flexing intellectual muscles left dormant since at least the end of the Cold War. Is a saturation attack down one bearing better, with inbound missiles exceeding the target’s sensor capacity in a single direction, or better from multiple vectors or compass points, overloading close-in defenses?  Such questions require at-sea testing. Additionally, such training is an important signal to U.S. maritime adversaries. The fact that U.S. naval aircraft are prepared to destroy high-end platforms, and have the capabilities to do so, emphasizes U.S. resolve in an era and in areas where such capability is in question.

WATERS SURROUNDING THE KOREAN PENINSULA (Oct. 14, 2016) The U.S. Navy’s only forward-deployed aircraft carrier, USS Ronald Reagan (CVN 76), transits waters surrounding the Korean Peninsula during Exercise Invincible Spirit. (U.S. Navy photo by Petty Officer 3rd Class Nathan Burke/Released)

Ultimately, the F-35 has a huge role to play in a reconfigured carrier air wing. Without it, the U.S. Navy will have no answer to the range of proliferating fifth generation fighters it would face in the Barents, Baltic, or China Seas. Joint Strike Fighter’s use is not bombing the Senkakus or trying to break into mainland China’s air defense network. Instead, only the F-35, to include or perhaps even feature the F-35B flown off LHDs and LHAs, can provide the protection of U.S. light forces and the carrier itself with an aircraft capable enough to survive in a modern air war. Forward distribution of the F-35 in support of U.S. light forces will provide a critical capability to those ships operating at the far reaches of U.S. sea control when they confront the J-20 and Su-35, armed with large numbers of long-range anti-ship missiles.

Finally, naval air must expand the capabilities of the legacy and Super Hornet variants of the FA-18 with software upgrades and improved radars and sensors, to help electronics warfare and battlespace awareness functions on the aging airframes to keep pace with F-35. The F-35’s stealth will not be decisive in future conflicts. The frequency agility of modern air defense sensors is just too good. Only the survivability and lethality of the weapons it carries will keep these airframes lethal into the future. Hornets must maintain their capability in the areas of fleet air defense and anti-surface warfare by a refresh of the aircraft’s sensors and systems. This is not to preclude F-35. Without the Joint Strike Fighter, the only fifth generation fighter available, American carrier air forces will be obsolescent by the end of the decade. However, the Hornets will also have to operate in the same environments, and need to be configured to do so.

Conclusion

American naval forces are not a tool for strategic strikes. Instead, they should be used operationally, to provide strategic affects. A great power war will require progressive sea control, as attrition dominates seagoing forces on both sides. At some point, one side or the other will alone maintain the capability to operate in the contested theater. Naval aviation should use its striking capability to advance this attrition-based operational concept as quickly as possible by massing its striking power quickly against targets. Only by eliminating enemy platforms and blinding adversary ISR assets will U.S. forces survive.

In order to do this effectively, U.S. naval air forces must support distributed forces.  The can do so by coordinating with large-deck amphibious shipping to distribute their own lethality, providing defensive counter-air coverage and situational awareness to surface action groups operating on the front line of American naval power. This will free U.S. carrier aviation for anti-surface warfare and local air superiority.

The MV-22 is the great unrecognized platform with almost limitless potential for operational flexibility. With increased sensor loads and weapons, the tiltrotor can deliver long-endurance, low-altitude ASW and high-altitude situational awareness if properly configured. Such sea control capabilities would pay huge dividends in future naval combat.

At its base, this work is about naval aviation in an era of contested sea control. This era will require airborne forces to re-examine the assumptions of the past six decades of naval aviation, retooling the air wing for maritime strike. This will require radically different magazine selections on the carrier, likely some new weapons, including higher-capability anti-ship weapons, and a total retooling of air wing certification and training regimens. Aircraft carriers have a huge role in future wars, but the retooling of their aircraft and their operational concepts must begin now.

LT X is an officer in the United States Navy. Feedback should be directed to [email protected] and will be forwarded to the author.

Featured Image: An aerial view of various aircraft lining the flight decks of the aircraft carrier USS INDEPENDENCE (CV-62), right, and USS MIDWAY (CV-41) moored beside each other in the background at Naval Station Pearl Harbor (Wikimedia Commons)

Capability Analysis

Distributed Lethality and Situational Awareness

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By Richard Mosier

Introduction

The distributed lethality concept represents a distinct change in Surface Navy operations, one that emphasizes the offense, and one that requires the freedom of action only possible under mission orders. Both place heavy reliance on the Surface Action Group (SAG) having information superior to that of the enemy in order to be hard to find and thus avoid attack and achieve the offensive advantage of surprise. This is enabled in large measure by situational awareness: the warfare commanders’ perception of the tactical situation. It is achieved by the continuous collection, correlation, fusion, assimilation and interpretation of information from force organic systems, and nonorganic national, theater, and Navy systems. 

Deconflicting Doctrine

A core element of the distributed lethality concept is that SAG commanders operate under mission orders that allow them the freedom to make tactical decisions, a major change away from the long-standing convention of detailed direction from higher headquarters located ashore or on a CVN with its substantial tactical intelligence decision support capabilities. Consequently, the surface navy has had no driving requirement for the sophisticated Common Tactical Picture (CTP)1 or “plot” capabilities that are now required onboard surface combatants for the situational awareness required for the planning/re-planning, and tactical execution of distributed missions.

Current doctrine regarding the allocation of responsibilities for maintaining the Common Tactical Picture CTP or “plot” is fragmented. In accordance with NWP 3-56, Composite Warfare Doctrine, the Surface Warfare Commander (SUWC), ASW Commander (ASWC), and Air Defense Commander (ADC) are responsible for using all available information to maintain a complete geographic plot for their respective warfare areas. NWP 3-56 also assigns to the Information Operations Warfare Commander (IWC2) responsibility for integrating real time Electronic Surveillance (ES) contact reports with indications,3 and warning4 information. NWP 3-13, Information Operations, assigns the IWC responsibility for achieving and maintaining information superiority; establishing and maintaining the CTP through spectrum awareness; and, for integrating real-time ES contact reports with indications and warning information. Further, NWP 3-56 assigns a Common Tactical Picture Manager (CTPM) responsibility for establishing, maintaining, assuring quality of, and disseminating the fused all-source GENSER CTP. NWP 2-01, Intelligence Support to Naval Operations, describes a concept in which the principal role of intelligence in support of warfare commanders is to characterize the threat and classify all threat targets that may enter the detection range of U.S. or coalition naval forces. It states: “Intelligence correlates and fuses all source data, including intentions, to determine the threat, threat direction, and operational characteristics of the threat platform before the threat platform is detected by own forces.” It further states: “Operational and tactical intelligence support is designed to detect, classify, target, and engage all hostile subsurface threats before they reach maximum effective weapons release range.”

When viewed together, NWP 3-56, NWP 3-13, and NWP 2-01 suggest that the Navy needs a concept and coherent allocation of responsibilities for developing and maintaining the CTP, especially as it applies to a SAG operating in EMCON while executing mission orders.

Impetus for Change 

Changes to current Navy doctrine to accommodate the concept of distributed lethality will be driven by at least two factors. First, to achieve the surprise that is essential for distributed lethality mission success, the SAG will have to operate in RF silence to deny the enemy the opportunity to detect the force with passive RF sensors, one of the primary methods for surveillance of large areas to gain initial location and classification of detected units. All communications to the SAG from supporting entities will have to be routed to and disseminated via narrow and wideband satellite broadcasts such as CIBS-M and GBS. In effect, the SAG gets all the shore support while remaining hard to find thereby minimizing risk of attack.

Second, the surface navy will have to develop and field intra-SAG communications that are sufficient to command and control the force and maintain the CTP but covert enough to minimize the probability of detection and location by the enemy.

PACIFIC OCEAN (June 5, 2008) Chief Engineer, Lt. Dave Ryan, evaluates a tactical image in the combat information center of the guided-missile frigate USS Kauffman (FFG 59) during an anti-submarine warfare (ASW) exercise with the Chilean navy. (U.S. Navy photo by Mass Communication Specialist 2nd Class J.T. Bolestridge)

Third, surface combatants have neither the space nor the systems to support the large intelligence presence such as that found on a CVN or other big deck. This suggests that when in EMCON, the SAG will be more heavily dependent on tactical intelligence provided from shore. Some sensor information such as combat information5 cannot be processed ashore into tactical intelligence in time to meet SAG requirements. Therefore, SAG combatants will require dramatically improved capabilities for automatically integrating tactical intelligence, combat information, and organic force sensor information. Given the criticality of time in tactical decision making, automated information correlation and fusion capabilities are essential. However, their output is never perfect or complete so the crew will have to have the skills, knowledge, and abilities to analyze and resolve ambiguities and conflicts.

Conclusion

Distributed lethality depends on being hard to find and securing the element of surprise enabled by superior situational awareness. With the adoption of the distributed lethality concept, it is essential that the concept and doctrine for establishing and maintaining the CTP be reviewed and optimized to assure warfare commanders enjoy the tactical advantage of decision superiority over an adversary. The clear assignment to the shore intelligence structure of responsibility for the accuracy, completeness, and timeliness of tactical intelligence support to the SAG would result in renewed focus on tactical requirements and renewed appreciation of the critical importance of the clock at the tactical level. Moreover, it would drive a new hard- edged fleet focus on the ability of shore-based tactical intelligence support elements to provide this mission-essential support. The clarification of responsibilities onboard ship for maintaining the CTP would serve to focus attention on the ability of those responsible to maintain situation awareness that comports with the realities of the operating environment. As shortfalls and opportunities are identified, the fleet would refine its requirements for the manning, training, and equipping of surface combatants to achieve the information superiority that is the key to mission success. 

As stated by VADM Rowden in the January 2017 Proceedings: “The force we send forward to control the seas must be powerful, hard to find, hard to kill, and lethal. These are the bedrock tenets of distributed lethality…” The concept has gained wide support in the surface navy and is being adopted as a broader Navy operating concept. Rapid progress is being made by the surface navy under the leadership of the surface warfare Type Commands and OPNAV N96. Changes to doctrine to accommodate command control of operations on mission orders are being investigated. Surface forces are being up-gunned to be more lethal. Surface Warfare Officers are being trained and developed as warfare experts for air, surface, and ASW at the Naval Surface and Mine Warfighting Development Center. This beehive of activity is resulting in rapid progress in all warfare areas except for Information Operations.  

Progress in this fourth foundational warfare area remains in limbo, owed in large measure to unaddressed OPNAV and Type Command organizational relationships and responsibilities for manning, training, readiness, equipping and modernization of the fleet for the planning and conduct of Information Operations. In the absence of progress in this warfare area the success of the distributed lethality is at risk against any near-peer nation with a sophisticated ISR capability.

Richard Mosier is a former naval aviator, intelligence analyst at ONI, OSD/DIA SES 4, and systems engineer specializing in Information Warfare. The views express herein are solely those of the author.

Endnotes

1. Common Tactical Picture — An accurate and complete display of relevant tactical data that integrates tactical information from the multi-tactical data link network, ground network, intelligence network, and sensor networks.  Also called CTP. (JP 3-01)

2. IWC in NWP 3-56, NWP 3-13, and as used in this article is the Navy’s abbreviation for Information Operations Warfare Commander.   It shouldn’t be confused with the Navy’s use of the same abbreviation to denote the Navy’s Information Warfare Community.

3. Indications — In intelligence usage, information in various degrees of evaluation, all of which bear on the intention of a potential enemy to adopt or reject a course of action. (JP 1-02)

4. Warning intelligence — Those intelligence activities intended to detect and report time sensitive intelligence information on foreign developments that forewarn of hostile actions or intention against United States entities, partners, or interests (JP 1-02)

5. Combat Information — Unevaluated data, gathered by or provided directly to the tactical commander which, due to its highly perishable nature or the criticality of the situation, cannot be processed into tactical intelligence in time to satisfy the user’s tactical intelligence requirements. (JP 2-01)

Featured Image: ATLANTIC OCEAN (June 27, 2012) Air-Traffic Controller 2nd Class Karina Reid operates the SPN-43 air search radar system while standing approach control aboard the amphibious assault ship USS Wasp (LHD 1). (U.S. Navy photo by Mass Communication Specialist Petty Officer 2nd Class Gretchen M. Albrecht/Released)

Asia-Pacific, Capability Analysis

Bangladesh’s Submarines from China: Implications for Bay of Bengal Security

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This article originally was originally featured by the S. Rajaratnam School Of International Studies and is republished with permission. Read it in its original form here

By Nilanthi Samaranayake

Synopsis

Bangladesh’s acquisition of two submarines from China should not be narrowly viewed through the prism of India-China geopolitics. Rather, it should be understood in a wider context as a milestone by a modernizing naval power in the Bay of Bengal.

Commentary

The impending arrival of two Chinese-origin submarines to Bangladesh together with China’s planned construction of submarines for Pakistan, has contributed to the perception among some observers that China is attempting to encircle India and reinforced concerns about a Chinese “string of pearls.”

Yet Bangladesh’s acquisition of two Ming-class submarines should not be narrowly viewed through this geopolitical prism. Rather, it should be seen in the broader context of the country’s force modernisation, which has important implications for Bay of Bengal security. In fact, Bangladesh’s development of its naval capabilities may contribute as a force multiplier to Indian security initiatives in the Bay of Bengal rather than being a potential threat to regional stability.

Rising Navy

Bangladesh’s latest acquisition has its origins in Prime Minister Sheikh Hasina’s assumption of power in 2009 and Dhaka’s announced Forces Goal 2030. Under this project, Bangladesh has sought to augment its naval capabilities in “three dimensions,” going beyond solely surface platforms to include a naval aviation wing and undersea leg. Though an ambitious endeavor at the time, by 2011, Bangladesh had established a naval aviation wing by acquiring Italian helicopters and later German maritime patrol craft.

The navy has also expanded its surface fleet through Chinese and U.S. origin platforms. Refurbished submarines from China appear to have been the most competitively priced option to fulfill the third leg of Forces Goal 2030. The announcement about the transfer should be no surprise given that Bangladeshi media and military officers have openly discussed progress toward this goal over the past few years.

Furthermore, Bangladesh is one of a number of countries in the region that are expanding their fleets with sub-surface platforms. Through this force modernisation project, Bangladesh is seeking to be self-reliant and gain prestige for its military, as do many countries with growing economies.

Unsung Contributor to Maritime Security

At the same time that Bangladesh is augmenting its naval capabilities, it is increasing its contributions to maritime security in the Bay of Bengal and beyond. Since 2010, it has deployed two ships to the UN Maritime Task Force off Lebanon. Moreover, having long been a recipient of disaster relief, Bangladesh now seeks to become a provider of such aid. In the past three years, the Bangladesh Navy delivered relief to Sri Lanka after deadly landslides in May, to Maldives after a water crisis in 2014, and to the Philippines after Typhoon Haiyan in 2013.

Bangladesh also seeks a leadership role in advancing international maritime institutions and legal norms. The Bangladesh Navy is currently chairing the Indian Ocean Naval Symposium (IONS) until 2018. Previously led by the Royal Australian Navy, IONS convenes regional stakeholders to discuss opportunities for cooperation.

At their meeting in January, naval representatives from 30 countries gathered in Dhaka, including the first appearance by a four-star U.S. Navy admiral. Finally, after long-standing maritime disputes with Myanmar and India, Bangladesh opted to use the tools of international arbitration. As a result, the three countries helped affirm the importance of international law in the Indian Ocean.

India: Much to do with Bangladesh

The idea of Chinese sailors training the Bangladesh Navy on submarines in the Bay of Bengal is understandably disconcerting to Indian policymakers. India’s minister of defence recently paid a historic visit to Dhaka to upgrade defence ties, likely aiming to neutralise a long-term Chinese training presence in Bangladesh. Although India’s ability to provide Bangladesh with training on Chinese-origin submarines will be limited, it is an opportune moment for India and Bangladesh to deepen minimal naval cooperation.

Strikingly, neither neighbor engages in bilateral naval exercises or annual navy staff talks; this is a clear area for growth. Both sides make occasional port calls to the other country, the navy chiefs visit each other, and the Bangladesh Navy participates in the Indian Navy’s multinational MILAN maneuvers and in its training schools. The lack of deeper naval interactions may be due to the countries’ maritime boundary dispute, which was not resolved until 2014. A bilateral agreement in 2015 between Sheikh Hasina and Narendra Modi achieved cooperation between the two coast guards, yet not the navies.

As a result of the submarines’ impending arrival, India will be able to seize on this opening to advance naval cooperation, including on this platform. The two nations can develop mechanisms for water-space management and information-sharing in the Bay of Bengal. While Bangladesh will need to train on the submarines for years to develop requisite expertise, it can use this platform to monitor movements and communications as other navies have done.

This will augment maritime domain awareness and may deter criminal activity, including threats posed by Islamist militants. For its part, India houses two military commands in the Bay of Bengal and has a growing anti-submarine warfare capability. Bangladesh’s additional coverage of the maritime domain would supplement efforts to ensure regional stability.

India could also transfer or sell maritime platforms to Bangladesh as it has done for several Indian Ocean countries. As New Delhi tries to increase its indigenous defence industry under the “Made in India” initiative, Indian shipyards, including in nearby Kolkata, could similarly build ships and aircraft for the Bangladesh Navy and Coast Guard.

Way Forward

The delivery of two Chinese submarines to Bangladesh—likely in January or February, according to media reports—represents a milestone by a smaller South Asian country that is modernising its naval forces. Moreover, Bangladesh’s clear contributions to maritime security in the Bay of Bengal and beyond should be encouraged.

India is notably pursuing cooperation on submarines with the United States; it may also find a partner in the undersea domain closer to home. Relations between Dhaka and New Delhi have been growing, especially since Prime Minister Modi’s historic visit in 2015. Bangladesh leader Sheikh Hasina’s upcoming visit would be a good opportunity to lay the foundation for deeper, regular naval cooperation that reduces India’s threat perceptions and develops mechanisms for greater maritime domain awareness. Bangladesh’s evolving naval capabilities and role in advancing international naval operations, forums, and norms can bolster regional maritime security and stability.

Nilanthi Samaranayake is a strategic studies analyst at CNA, a non-profit research and analysis organisation in the Washington, D.C., area. The views expressed are solely those of the author and not of any organisation with which she is affiliated. She contributed this to RSIS Commentary.

Featured Image: Capt. Mohammad Nazmul Karim Kislu leads a formation from the Bangladesh navy during the transfer and decommissioning ceremony of the Coast Guard Cutter Jarvis held on Coast Guard Island, Thursday May 23, 2013. (U.S. Coast Guard photo by Petty Officer 2nd Class Pamela J. Boehland)