This week in print, media, and in person, the Navy's Surface Force Leadership debuted what appears to be something of a "grand unifying theory" of Surface Warfare (my understanding, not theirs) that describes the direction that Surface Warfare will take in the decades to come--Distributed Lethality. It is notable because of the impact that a significant shift in operational mindset will have on the organize, train, and equip functions of the Service. Additionally, it appears to recognize both the changed strategic/operational environment and the ongoing fiscal morass. Fundamentally, Distributed Lethality is an argument that the surface force can play a more effective role in warfighting by creating planning and targeting problems for adversaries who would have to account for more a more threatening fleet architecture more widely arrayed, thereby holding a larger number of value targets at risk. Based on the Proceedings article above, the speeches made by VADM Tom Rowden (Commander Naval Surface Forces) and RADM Pete Fanta (OPNAV N96), I've cobbled together what I understand to be a set of principles of Distributed Lethality.
1. Warfare based. I think it would be improper to place Distributed Lethality in anything other than a war-fighting or war-deterring context. This is not a scheme for peacetime presence/Phase 0 operations. It will of course, influence fleet training approaches, and it will also create new opportunities for engagement with allies, as we seek to integrate their estimable capabilities into the Hunter-Killer Surface Action Groups (SAG).
2. Generational. VADM Rowden used this word in his speech, and my sense is that it has several meanings. First, that this is not going to be an overnight implementation, that the desired impact on fleet operations, architecture, and resourcing will take a number of years to accomplish. Questions from the audience at SNA seemed to focus mainly on a snapshot view of the affordability of what the surface leadership is suggesting, while the answers implied that the time horizons involved are multiple POM cycles long. Another meaning of "generational" is with respect to developing Surface Warfare Officers (SWOs) who will be capable of fighting this new concept, in which additional operational risk is accepted, operations are carried out in distributed, autonomous formations that will likely be subject to communications network disruptions.
3. Economical. Increasing unit lethality is at the heart of Distributed Lethality, and elegant solutions will be bypassed in favor of off-the shelf weapon and sensor enhancements. Opportunistic, short turn around enhancements will be favored over long-lead time acquisitions. Re-use of hardware from decommissioning ships to fill gaps in the operational fleet will be considered.
4. Platform agnostic. The surface leaders seem to be suggesting that at the very least, deep consideration should be given to increasing the lethality of EVERY naval vessel, to include the Amphibious force and the combat logistics force.
5. Autonomy. A fully networked fleet is of course, the preferred operational condition, but the Surface Force appears to be suggesting that the Hunter-Killer SAGs must be trained and equipped for operations in a network denied environment. This clearly raises the need for organic, persistent, overhead ISR/Comms relay within the surface force
6. Calculated Risk. Capitalizing on investments in IAMD and ASW (specifically the Multi-Function Towed Array and the SQQ-89 (V) 15 processor), the Surface Force is asserting that it can operate within an acceptable margin of risk without the protective blanket of the Carrier Air Wing, at least in some operational scenarios. Clearly, solving the ongoing offensive SUW problem is the long pole in this tent. Convincing analysts within the Pentagon to consider the power of these dispersed forces must be high on the list of early objectives for concept development.
I am sure there are many more, but these are a few that occurred to me this morning.
Bryan McGrath
Thursday, January 15, 2024
The Surface Navy’s Concept for Offensive SAG Operations
The surface
Navy’s own vision for expanding its offensive capacity is captured in an
article by VADM Thomas Rowden (Commander Naval Surface Forces), RADM Peter
Gumataotao (Commander Naval Surface Force Atlantic), and RADM Peter Fanta (Director,
Surface Warfare OPNAV N96) in
this month’s Proceedings. Generally
speaking, the article’s messages are consistent with the surface Navy’s efforts
over the past few years to refocus its procurement, concept development, and
training efforts around the warfare competencies that underpin sea control. As
I noted on Tuesday, its working
definition of sea control is also excellent.
Many of the article’s ideas echo or expand upon those proposed by Bryan Clark in his CSBA monograph. Some of my observations will accordingly be similar to those I made in my post yesterday.
Well expressed. The use of SAGs in these ways can affect more than just the adversary’s defenses—however the latter are defined. It can affect the overall positioning, employment, and operational priorities of his maritime forces writ large. In other words, it can shape the adversary’s overall operational conduct in a war. It may also be able to contribute to peacetime deterrence by encouraging an opponent’s political and military leaders to perceive that a war would likely not be quick or cheap.
…the shift to the offensive responds to the development of increasingly capable A2/AD weapons and sensors designed specifically to deny U.S. naval forces the freedom of maneuver necessary to project power. (Pg.19)
Too often we fixate on the weapons of maritime warfare. I therefore appreciate the mention of sensors here (and by implication, the methods by which those sensors disseminate their data throughout a force), as without those systems the weapons cannot be effectively employed. It must be appreciated that the two sides’ scouting and anti-scouting efforts prior to a naval clash will often be a dominant factor in deciding which side emerges victorious.
…it is important to remember that as our interests lay thousands of miles from our own coastlines, sea-based power projection is both our main competitive advantage and an absolute necessity to retain influence and to exercise global leadership. Adversaries who counter this advantage diminish the deterrent value of forward-deployed forces and negatively impact the assurances we provide to friends and allies. A shift to the offensive is necessary to “spread the playing field,” providing a more complex targeting problem while creating more favorable conditions to project power where required. (Pg. 19)
Also well stated. Sea-based power projection is often interpreted to be synonymous with land-attack strike or expeditionary force insertion. Both are indeed forms of power projection, but they are not the only ones. Any means by which some form of national power is projected ashore from the sea qualifies, whether it is the mere presence of flagged combatants in nearby waters to convey national interests (and influence other countries’ leaders’ decision-making), the use of portcalls for diplomatic ends, the conduct of information operations (such as the broadcasting of messages into a territory, or interference with some of the territory’s communications systems), or the protection/interdiction of a country’s maritime commercial activities in order to affect that country’s economic health—just to name a few. All of the above are strategically useful—and sometimes crucial—tools for a maritime power.
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 known as “hunter-killer SAGs.” It is the motive force behind offensive sea control. Both parts of the definition are critical; raising the lethality of the force but operating it the same way sub-optimizes the investment. Operating hunter-killer SAGs without a resulting increase in offensive power creates unacceptable risk. (Pg. 20)
This is absolutely correct, though I’m not sure what to make of the reference to increasing the offensive power of logistics ships. As I noted yesterday, there are legal considerations that might limit the types of combat tasks that ships partially manned by civilian mariners could perform. A better means of increasing logistics ships’ offensive power would be to provide them (and the combatants they support) with capabilities supporting at-sea Vertical Launcher reload. Either way, I’d be extremely hesitant to include logistics ships in SAGs operating deep within a contested zone. Replenishment ships have high campaign-value; the loss of just one could drastically suppress SAG or carrier battleforce operations in a theater for some time. Therefore, underway replenishments should not occur in areas where the possibility of adversary attack is high enough to place logistics ships and the combatants they are servicing at undue risk.
Hunter-killer SAGs seize maritime-operations areas for subsequent activities (including power projection), perform screening operations for larger formations, and hold adversary land targets at risk. Additionally, by distributing power across a larger number of more geographically spaced units, adversary targeting is complicated and attack density is diluted. Hunter-killer SAGS are capable of defending themselves against air and missile attack, and extend that protection to expeditionary forces conducting offensive operations of their own. These hunter-killer SAGs will be networked and integrated to support complex operations even when not supported by the carrier air wing and land-based patrol aircraft. (Pg.20-21)
Excellently stated; this nicely dovetails with the topics I discussed in my commentary yesterday on Bryan’s monograph.
Many of the article’s ideas echo or expand upon those proposed by Bryan Clark in his CSBA monograph. Some of my observations will accordingly be similar to those I made in my post yesterday.
First, I want
to comment on several impressive statements made in the article.
Increasing surface-force
lethality—particularly in our offensive weapons and the concept of
operations for surface action groups (SAGs)—will provide more strike
options to joint-force commanders, provide another method to seize the
initiative, and add battlespace complexity to an adversary’s calculus.
The
objective is to cause the adversary to shift his own defenses to counter our
thrusts. He will be forced to allocate critical and limited resources across a
larger set of defended targets, thereby improving our operational advantage to
exploit adversary forces. (Pg. 19)
Well expressed. The use of SAGs in these ways can affect more than just the adversary’s defenses—however the latter are defined. It can affect the overall positioning, employment, and operational priorities of his maritime forces writ large. In other words, it can shape the adversary’s overall operational conduct in a war. It may also be able to contribute to peacetime deterrence by encouraging an opponent’s political and military leaders to perceive that a war would likely not be quick or cheap.
…the shift to the offensive responds to the development of increasingly capable A2/AD weapons and sensors designed specifically to deny U.S. naval forces the freedom of maneuver necessary to project power. (Pg.19)
Too often we fixate on the weapons of maritime warfare. I therefore appreciate the mention of sensors here (and by implication, the methods by which those sensors disseminate their data throughout a force), as without those systems the weapons cannot be effectively employed. It must be appreciated that the two sides’ scouting and anti-scouting efforts prior to a naval clash will often be a dominant factor in deciding which side emerges victorious.
…it is important to remember that as our interests lay thousands of miles from our own coastlines, sea-based power projection is both our main competitive advantage and an absolute necessity to retain influence and to exercise global leadership. Adversaries who counter this advantage diminish the deterrent value of forward-deployed forces and negatively impact the assurances we provide to friends and allies. A shift to the offensive is necessary to “spread the playing field,” providing a more complex targeting problem while creating more favorable conditions to project power where required. (Pg. 19)
Also well stated. Sea-based power projection is often interpreted to be synonymous with land-attack strike or expeditionary force insertion. Both are indeed forms of power projection, but they are not the only ones. Any means by which some form of national power is projected ashore from the sea qualifies, whether it is the mere presence of flagged combatants in nearby waters to convey national interests (and influence other countries’ leaders’ decision-making), the use of portcalls for diplomatic ends, the conduct of information operations (such as the broadcasting of messages into a territory, or interference with some of the territory’s communications systems), or the protection/interdiction of a country’s maritime commercial activities in order to affect that country’s economic health—just to name a few. All of the above are strategically useful—and sometimes crucial—tools for a maritime power.
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 known as “hunter-killer SAGs.” It is the motive force behind offensive sea control. Both parts of the definition are critical; raising the lethality of the force but operating it the same way sub-optimizes the investment. Operating hunter-killer SAGs without a resulting increase in offensive power creates unacceptable risk. (Pg. 20)
This is absolutely correct, though I’m not sure what to make of the reference to increasing the offensive power of logistics ships. As I noted yesterday, there are legal considerations that might limit the types of combat tasks that ships partially manned by civilian mariners could perform. A better means of increasing logistics ships’ offensive power would be to provide them (and the combatants they support) with capabilities supporting at-sea Vertical Launcher reload. Either way, I’d be extremely hesitant to include logistics ships in SAGs operating deep within a contested zone. Replenishment ships have high campaign-value; the loss of just one could drastically suppress SAG or carrier battleforce operations in a theater for some time. Therefore, underway replenishments should not occur in areas where the possibility of adversary attack is high enough to place logistics ships and the combatants they are servicing at undue risk.
Hunter-killer SAGs seize maritime-operations areas for subsequent activities (including power projection), perform screening operations for larger formations, and hold adversary land targets at risk. Additionally, by distributing power across a larger number of more geographically spaced units, adversary targeting is complicated and attack density is diluted. Hunter-killer SAGS are capable of defending themselves against air and missile attack, and extend that protection to expeditionary forces conducting offensive operations of their own. These hunter-killer SAGs will be networked and integrated to support complex operations even when not supported by the carrier air wing and land-based patrol aircraft. (Pg.20-21)
Excellently stated; this nicely dovetails with the topics I discussed in my commentary yesterday on Bryan’s monograph.
The article next
outlines a scenario in which a SAG is tasked with reconnoitering a small
isolated island with airfield facilities that can be used as a short-term
Forward Operating Base (FOB) for Marine Corps F-35Bs. Several enemy surface
combatants and one enemy submarine are described as operating nearby. The SAG’s
capabilities for locating and destroying these threats are then listed. All
fine and good, but it nevertheless begs the question of the SAG’s combat endurance
based on its ordnance inventories. If all the adversary can throw at the SAG
during the entirety of this operation is what’s explicitly listed in the
scenario, then the SAG probably has enough ordnance to carry through. If the
adversary can reorient other forces (including aircraft and long-range
missiles, which are not directly mentioned in the scenario) to repeatedly attack
the SAG or the FOB upon realizing what the SAG is doing within the time scale
of the operation, however, then there needs to be some thought about how to
address the SAG’s ordnance depletion. In other words, the Joint Force Maritime
Component Commander overseeing the SAG’s operation would face the question of
how long the SAG could sustain local superiority above some minimum margin
fully on its own. This leads into my observations yesterday about the
possibility that a SAG might need sea control support from external forces at
one or more points during an operation within a contested zone.
The article
follows by alluding to a desire to increase the amphibious fleet’s offensive
clout:
There is a strong argument to add offensive capability
to the amphibious fleet, creating within it yet another planning nightmare for
an adversary, who would face expeditionary forces packing organic offensive
surface-to-surface missiles and land-attack capabilities. Adding offensive
firepower to the amphibious force does not relieve the surface force from its
role of protection, nor does it mean that the primary mission of those
ships—projecting Marine Corps power ashore—must be compromised. It does mean,
however, that we should think differently about these ships and consider the
power of adding additional capability to them. (Pg. 22)
I’d be very
curious to know what is meant here by surface-to-surface missiles, and whether
they are to be employed by the amphibious warships or by their embarked Marines
once ashore.
A bit later,
the article reiterates Bryan Clark’s call for a new, long-ranged anti-submarine
weapon that can disrupt attacks by adversary submarines out to at least 50
nautical miles. This is a sorely-needed capability, and I am glad to see it is
receiving serious attention.
After that, the
article discusses how SAG command and control would need to be exercised under
cyber-electromagnetic opposition:
An important aspect of distributed lethality is the
ability to confidently conduct dispersed operations apart from centralized
command-and-control networks. Local combat-information networks are essential
to achieving localized battlespace awareness. Those networks need to be more
capable than those existing today and must be persistent in a satellite-denied
or jamming-intensive environment. Whether current vertical-takeoff unmanned
aerial systems have the persistence necessary to support dispersed offensive
operations remains to be seen, but the potential for them to augment networking
and information-sharing should be examined. The ability of hunter-killer SAGs
to launch and recover fixed-wing or partially fixed-wing UAVs will be pivotal
to employing UAVs in this role…
…We anticipate the electromagnetic spectrum to be challenged as a part of
an adversary’s A2/AD tactics. Where we do not have equipment to counter and
continue networking in such an environment, we must field such as part of the
development of our next generation of ships and backfit that capability to
existing ships. (Pg. 23)
The authors appear to be
referring to operations
on interior lines of networking, with SAG-organic unmanned aircraft of
varying kinds being used as ‘middleman’ data relays between the surface
combatants. This is an excellent idea, as the use of highly-directional
line-of-sight communications paths within this kind of relay network would make
an adversary’s ability to detect, jam, or otherwise exploit those communications
extraordinarily difficult. However, the selected text seems to imply that the
primary means supporting operations under cyber-electromagnetic opposition are
technological. Improved sensors and analytical tools for monitoring the
electromagnetic environment surrounding a SAG’s operating area, not to mention
improved communications systems, are certainly central. All the same, doctrine
and training are irreplaceable means for filling in the capability gaps;
technology alone will not be sufficient. Command
by negation doctrine based upon mission-type orders will be necessary for SAGs
to operate under C2-degraded conditions. So will frequent and realistic training
to prepare crews for these types of conditions. The development and
institution of the requisite doctrine, tactics, and training does not need
to—and must not—wait until the next generation of ships enter the fleet. Much can
be done along these lines using the warships and systems we already have.
The views
expressed herein are solely those of the author and are presented in his
personal capacity. They do not reflect the official positions of Systems Planning
and Analysis, and to the author’s knowledge do not reflect the policies or
positions of the U.S. Department of Defense, any U.S. armed service, or any
other U.S. Government agency.
Wednesday, January 14, 2024
The CSBA Monograph on U.S. Navy Surface Forces
Over the
holiday I read Bryan
Clark’s study on reinvigorating U.S. Navy’s surface forces’ abilities to
perform sea control tasks. His commendable work casts a light on surface Navy
issues that generally don’t receive much attention from the think tank
community—and certainly not at such high levels of detail and fluency.
Sea Control, Campaign Design, and the
Carrier-Surface Combatant Relationship
Bryan asserts
that the Navy’s surface combatants must possess some capacity for attaining and
then holding sea control (e.g., a temporary local margin of naval superiority) on
their own in a notional major conflict because large-deck carriers’ air wings
might not be available to contribute. I strongly agree, but my reasoning is
different.
The Airborne Early Warning Caveat
The greatest
challenge facing SAGs operating without external air support would be their
ability to detect and engage adversary platforms (or inbound threat weapons) at
the most tactically advantageous distances. As I’ve previously noted, AEW
is crucial to gaining and then holding sea control under intense opposition.
Shipboard sensor ranges are limited by their height of eye relative to the
earth’s curvature; an inbound air threat flying beneath or beyond this coverage
will not be detected in the absence of offboard sensor support. It should also
be pointed out that carrier-organic AEW is presently central to maximizing the effective
range of the shipboard SM-6 interceptor missile via the Navy Integrated Fire
Control-Counter Air (NIFC-CA) concept. While it would be possible for Air Force
or allied AEW aircraft to support U.S. Navy SAGs, I am aware of no plans to
develop capabilities for integrating either in NIFC-CA. Nor are there any plans
I’m aware of to install the large aperture AEW radars necessary for
long-range/wide-area surveillance on unmanned aircraft.[i]
All of this drastically affects a surface combatant’s ability to engage an
adversary aircraft before the latter can launch its own missiles.
Engagement Depth, Ordnance Inventories, and Targeting
Confidence
Bryan correctly
notes that shorter-range defensive weapons tend to be more affordable-per-engagement
than longer-range defensive weapons, and that the latter tend to take up more
shipboard space than the former. He consequently argues that by concentrating defensive
firepower in a single inner layer with a roughly 30 miles radius, each surface
combatant not only gains more favorable cost-per-salvo ratios relative to the
adversary’s inbound weapons but also gains more opportunities to engage the adversary’s
‘archer’ aircraft with SM-6 before they can fire their ‘arrows.’
--Updated 8:43PM 1/14/15 to clarify why longer-ranged interceptors might be needed by a SAG if the separation between its units is increased, and to delete a typo in the beginning of the 'Other Thoughts' subsection--
Bryan’s core argument
is that the surface Navy is disproportionately organized and armed for reactive
defense, and that this implicitly contradicts the maxim that the
side that effectively employs its offensive weaponry first in naval battle is
generally victorious. He also observes that the primary weapons the surface
Navy uses for defense are often at a sizable cost-per-engagement disadvantage
to the offensive weapons they counter. These considerations lead him to suggest
the surface Navy should cede defensive depth against an adversary’s inbound weapons
in exchange for a combination of increased offensive armaments capacity and
increased inner-layer defensive density. By doing so, he argues, the surface
Navy would be better able to disrupt or destroy adversary platforms before the
latter could attack effectively, and any weapons the adversary did succeed in
launching would have to contend with a deep (and cost-per-engagement
advantageous) arsenal of multiple overlapping short/medium-range defensive
systems.
Bryan addresses
quite a number of topics including fleet doctrine, top-level requirements for
weapons, ideal characteristics for the LCS-derived Small Surface Combatant, and
potential uses of U.S. Coast Guard and Military Sealift Command (MSC) ships to
shoulder more of the overseas maritime security cooperation task load. Since
several of his ideas relate closely to subjects I wrote about last fall, I will
focus my commentary accordingly.
Sea Control, Campaign Design, and the
Carrier-Surface Combatant Relationship
Bryan asserts
that the Navy’s surface combatants must possess some capacity for attaining and
then holding sea control (e.g., a temporary local margin of naval superiority) on
their own in a notional major conflict because large-deck carriers’ air wings
might not be available to contribute. I strongly agree, but my reasoning is
different.
Bryan suggests the
carriers’ unavailability might result from their being engaged in power
projection operations elsewhere in theater. It seems unlikely, though, that
conditions could be shaped to allow carrier battleforces to operate deep within
a contested zone at a tolerable degree of risk relatively early in a conflict against
a strong adversary. This would be especially true if the contested zone’s inner
sections were adjacent to the adversary’s own borders. Furthermore, it normally
takes a minimum of two carriers on scene to conduct sustained land-attack operations
in even a lesser contingency, let alone to conduct operations of any kind inside
a contested zone. Given that the presently-programmed 30-year carrier force
structure means deployments of a single carrier within a given region will be
the norm unless a crisis erupts, and given that the time lag for a second
carrier to arrive on the periphery of a contested zone from elsewhere could be
measured in weeks, there is a considerable chance that insufficient carriers
would be on hand to perform early-phase land-attack strike tasks. For these
reasons, the largest share of these early-phase tasks deep inside the contested
zone would likely be allocated to missile-armed submarines and land-based
long-range aircraft. Not only would these platforms be less vulnerable in such
areas to the adversary’s attacks than carriers, but they would also be
comparatively more available for this tasking.
Unlike the case
with early-phase deep power projection, however, a battleforce containing a
single carrier could contribute immensely to
protecting situationally prioritized segments of the sea and air lines of
communication that are necessary for U.S. military access to the combat
theater as well as for embattled allies’ economic sustenance. A single-carrier
battleforce operating from the contested zone’s periphery could similarly
provide support to operations by Surface Action Groups (SAG) or other friendly forces
further forward on a periodic basis. These would arguably be the most
important—and in some cases, irreplaceable—roles for carriers during the early
phases of a major maritime war.
This is where
the doctrinal changes and capability enhancements Bryan recommends come into
play. The in-theater carrier shortage means that mission-tailored U.S. Navy SAGs
must be able to operate at some distance inside a contested zone for multi-day
periods with limited to no external air support at a tolerable degree of risk.
These operations might be offensive sweeps to draw out and then destroy
adversary maritime forces. They might be reconnaissance missions or raids against
adversary forward operating bases or expeditionary lodgments. They might be
missions to provide friendly forces on the ‘frontline’ with supporting fires or
defensive coverage. They might be convoy escort missions supporting the flow of
supplies and reinforcements to these forces, or perhaps the flow of economic
and basic humanitarian goods to embattled allied populations. They might even
be operations to induce the adversary to react in ways that other friendly
forces could then exploit.
The extent to
which surface forces could perform any of these tasks at a particular distance inside
a contested zone for a particular length of time would be determined by the
margin of temporary local superiority they could sustain under such
circumstances. It should be clear that the deeper an operating area might lie
within the contested zone (and the closer that area was to the adversary’s
homeland), the harder it would be for any SAG to persist in operating there.
Bryan is thus absolutely correct in that the more offensive and defensive
capacity that can be packed into existing surface combatants, the longer on the
margins they would be able to operate more or less on their own at some
distance inside a contested zone before their ordnance depletion reached the point
that their margin of local superiority—and thus staying power—was all but gone.
These considerations combined with the availability of carriers and other
maritime forces to support SAG operations as deemed necessary would shape the
sequence in which individual maritime operations were conducted a U.S.
campaign. Precursor or parallel operations by other forces accordingly might be
required to pave the way for a SAG’s operation.
This would not
change dramatically as reinforcement carriers arrived in theater. Some would
likely be tasked with extending greater protection over intra-theater maritime
lines of communication. Others might be used to take
on some share of Joint power projection tasks as submarines’ and long-range air
forces’ standoff-range strike missile inventories became depleted. It
should be noted, though, that these power projection operations could not be
performed unless
the carriers and their surface combatant escorts had already obtained the
requisite sea control. As a matter of fact, a carrier battleforce’s
tactical actions to seize and retain sea control could be just as consequential
in a campaign context as the power projection tasks they might support. For
instance, if a carrier battleforce could sustain a certain margin of temporary
local superiority when clashing with the adversary’s maritime forces, its
ability to inflict outsized damage or losses on the latter while absorbing
tolerable damage or losses of its own would help erode the adversary’s probable
advantages in the overall theater conventional military balance as well as arrest
the adversary’s campaign progress. Likewise, the adversary’s allocation of
maritime forces to fight a carrier battleforce (and any friendly forces
supporting it) might result in fewer adversary forces available for operations
elsewhere in theater during some period; this could be exploited by other
friendly forces including independently-operating SAGs. The use of carriers in
any of these ways should of course be governed by calculated
risk, and precursor/parallel operations by other elements of the Joint
force would very likely be necessary or desirable to create particularly
advantageous margins of temporary local superiority.
The Airborne Early Warning Caveat
The greatest
challenge facing SAGs operating without external air support would be their
ability to detect and engage adversary platforms (or inbound threat weapons) at
the most tactically advantageous distances. As I’ve previously noted, AEW
is crucial to gaining and then holding sea control under intense opposition.
Shipboard sensor ranges are limited by their height of eye relative to the
earth’s curvature; an inbound air threat flying beneath or beyond this coverage
will not be detected in the absence of offboard sensor support. It should also
be pointed out that carrier-organic AEW is presently central to maximizing the effective
range of the shipboard SM-6 interceptor missile via the Navy Integrated Fire
Control-Counter Air (NIFC-CA) concept. While it would be possible for Air Force
or allied AEW aircraft to support U.S. Navy SAGs, I am aware of no plans to
develop capabilities for integrating either in NIFC-CA. Nor are there any plans
I’m aware of to install the large aperture AEW radars necessary for
long-range/wide-area surveillance on unmanned aircraft.[i]
All of this drastically affects a surface combatant’s ability to engage an
adversary aircraft before the latter can launch its own missiles.
SAGs can
mitigate this somewhat by positioning their combatants so that the group’s
fused sensor picture provides expanded coverage as well as engagement depth. Not
all of these combatants need to employ their active sensors; it is perfectly
valid for some to only search using passive sensors depending upon the tactical
situation. Nevertheless, actively radiating SAG units expose themselves to
counterdetection and targeting by adversary platforms operating outside the
SAG’s sensor coverage. The same would also be true for the use of a SAG’s
helicopters to perform AEW against inbound sea-skimming ASCMs, as the
helicopters’ necessary proximity to SAG units to perform this task would cue
the adversary’s reconnaissance and possibly targeting efforts. The risk that a
SAG’s active sensor usage poses may remain entirely tolerable if the SAG
possesses a sizable margin of temporary local superiority against the
adversary’s forces. As this margin decreases, though, tactical (and
operational) risk increases. Below some threshold margin, it very simply may
not be possible for a SAG to operate at acceptable risk in some area for some
span of time without carrier/land-based large AEW aircraft support. This
further highlights the importance of a campaign’s operational sequence,
particularly with respect to the role of precursor/parallel operations in
helping a SAG gain and hold sea control.
Engagement Depth, Ordnance Inventories, and Targeting
Confidence
Bryan correctly
notes that shorter-range defensive weapons tend to be more affordable-per-engagement
than longer-range defensive weapons, and that the latter tend to take up more
shipboard space than the former. He consequently argues that by concentrating defensive
firepower in a single inner layer with a roughly 30 miles radius, each surface
combatant not only gains more favorable cost-per-salvo ratios relative to the
adversary’s inbound weapons but also gains more opportunities to engage the adversary’s
‘archer’ aircraft with SM-6 before they can fire their ‘arrows.’
The implication
here is that surface combatants are most likely to detect inbound Anti-Ship
Cruise Missiles (ASCM) at the shipboard radar horizon. This is certainly true
for sea-skimming ASCMs to a considerable degree, but not all ASCMs are pure sea-skimmers.
For example, some
spend a good portion of their flyout at high altitudes, and a few older types
perform terminal dives on their targets. Shorter-ranged defensive interceptors
can certainly be used against these threats, but it might be desirable to
retain the option of situationally employing longer-ranged interceptor missiles
(though not necessarily SM-6) against them as well. It should also be noted
that an interceptor missile’s ability to intercept any particular inbound
threat is often a factor of the ‘engagement geometry.’ Assuming sufficiently
timely sensor detection and tracking of a given air threat, an interceptor
missile’s effective range against that threat will be closer to its ‘advertised’
maximum range when the threat is headed more-or-less directly towards the interceptor’s
firing unit than when the threat is crossing at a tangential distance to the
firing unit. If SAG units are intended to mutually support each other within an
inner zone defense, this means that the practical separation distance between
those units will be less than the ‘advertised’ maximum reach of their shorter-range
interceptor missiles; Bryan notes as much in his Footnote #51 (Pg 20). Many perfectly
valid SAG tactics allow for minimal to no mutual kinetic defensive support. Greater
separation between a SAG’s combatants might be desirable at other times, though,
in order to expand the volume covered by the SAG’s sensors or to support
concealment tactics. If either of these are the case, and if some degree of mutual kinetic defensive support is desired, then use of a somewhat longer-ranged
interceptor becomes necessary. Lastly, it should be noted that if ‘archer’
aircraft could fire their ‘arrows’ from outside SM-6 range (which is well
within the realm of the possible), SAG defenses would have to cope with a much
larger inbound salvo. The preceding considerations lead me to conclude that Bryan’s
call to rely predominantly on a dense inner zone defense is correct, but that some
number of relatively affordable medium-range interceptors that can reach beyond 30 miles
will still need to be carried in combatants’ vertical launchers for the reasons
I’ve outlined.
Not all inner
zone defenses need to be kinetic, however. Bryan correctly observes that Electronic
Warfare (EW) systems can contribute greatly to defensive effectiveness. He also
correctly observes that the short distances and timeframes involved during
inner zone defense mean that even the most effective of shipboard EW systems
will not allow a surface combatant to refrain from firing interceptor missiles
against a given inbound threat. There are also physics-based limitations on the
jamming techniques a shipboard EW system can employ. The same physics suggests
the value of offboard EW systems, especially in circumstances where their
placement can result in inbound threats never detecting or otherwise locking on
to defended combatants.[ii] With adequate separation between offboard EW
systems and defended combatants, it becomes theoretically possible to cause a
threat ASCM to commit itself early enough towards a harmless direction such
that shipboard interceptor missiles can actually be withheld. Perhaps more
significantly, the intelligent use of offboard EW systems can contribute enormously
to an overall deception and concealment plan that prevents a SAG from being
detected or correctly classified by the adversary in the first place. Consequently,
I would add ship-launched offboard EW systems to Bryan’s list of future
‘ordnance’ that would be useful for expanding the surface Navy’s sea control
capabilities.
All the same,
nothing prevents the adversary from employing similar EW methods to defeat the
surface Navy’s own offensive weapons. An adversary’s effective use of EW in
tandem with other forms of deception could entice surface combatants into
wasting their limited longer-range missile inventories against decoys. As
I wrote last fall, the Navy faced this exact problem during the Cold War. Thus,
from a purely technological perspective (i.e., excluding the non-material
solutions I mentioned in a follow-on
piece), the use of multi-phenomenology sensors (and often visual-range
examination of contacts) is necessary to have high confidence in a long-range
targeting picture. While SAG-organic scouts such as manned helicopters or
unmanned aircraft can perform this role against distant surface contacts, it is
less clear what organic tools a SAG could to perform it against distant air contacts.
Shipboard radars could use non-cooperative
target recognition techniques to perform some air contact classification, but
their doing so could be subject to EW countermeasures by the adversary. Bryan’s
call for improved inner layer defensive density resultantly gains additional
importance, as it would provide a SAG’s only other recourse in the event an
adversary’s deceptions defeat a SAG’s offensive use of ASCMs or SM-6.
In turn, this
reemphasizes my earlier point that the location and length of a SAG operation
within a contested zone must be predicated on its ability to sustain its margin
of local temporary superiority above some threshold. If it cannot do so on its
own, and if the operation in question cannot be delayed until circumstances are
more favorable, then it will either need external air support at some stage (such as for detection and outer-layer visual-range identification of air contacts) or
the theater commander will have to accept the elevated risks.
Other Thoughts
- One of Bryan’s most important observations was
in his Footnote #39 (pg 14). In describing an adversary’s reliance on wide-area
surveillance and data relay systems to cue attacks by Anti-Ship Ballistic
Missiles (ASBM), he suggests that “surface combatants would be more effective
in targeting these enablers, rather than planning to attack mobile ASBM
launchers themselves from 800 - 1,000 nm away.” This is absolutely correct.
What’s more, these surveillance/reconnaissance 'systems of systems' are
likely to be used to cue anti-ship attacks by other platforms such as
submarines and land-based aircraft. Degrading or neutralizing these constituent sensor and
communication systems—however locally or temporarily—using deception,
concealment, or (as feasible) physical attack will be a critical prerequisite
for sea control within a contested zone. Doing so essentially represents a 'mission-kill' against the adversary's ability to perform over-the-horizon targeting. At the campaign-level, these
anti-scouting efforts will be central to rolling back the adversary’s offensive
progress and eroding his military potential in theater. Surface forces will
have major roles to play in this fight, but it will often require contributions
from other Joint combined arms to be successful.
- I agree with Bryan’s three desired design
attributes for future shipboard missile development: offensive capability,
multi-mission usability, and smaller physical size. I would also add wartime
producibility to Bryan’s list.
- I strongly support the Long-Range Anti-Ship Missile (LRASM) concept for all the reasons Bryan articulates. Nevertheless, I believe more analytical attention needs to be paid to how it will be provided with high-confidence targeting cues at distances beyond the range of SAG-embarked aircraft or in hotly opposed areas where the MQ-4C Triton or P-8 Orion might not be risked. The Navy’s Outlaw Shark over-the-horizon targeting experiments of the late 1970s highlighted the extreme difficulties this situation presents, especially if missile cueing depends upon the adversary’s Emissions Control indiscipline.[iii] Visual-range confirmation of a target’s classification may be necessary for employing LRASM with high confidence. This may be a potential major role for the proposed Unmanned Carrier-Launched Airborne Surveillance and Strike (UCLASS) system.
- Aircraft embarked in combatants will remain the most lethal means for time-sensitive attacks against a nearby adversary submarine in the absence of land-based anti-submarine aircraft support, but as Bryan observes there is a need to buy some time for the embarked aircraft to fly out to the threat. The existing Vertically-Launched Anti-Submarine Rocket (VLA) does not have sufficient range to disrupt attacks by adversary submarines that are solely using their organic sensors to target the protagonist’s battleforce. I therefore strongly agree with Bryan’s recommendation for a new, longer-ranged quick-reaction anti-submarine weapon.
- Bryan is entirely correct that the Navy’s programmed shortfall of Small Surface Combatants (SSC) capable of performing wartime convoy and combat logistics ship escort duties means these tasks would fall on the AEGIS cruiser and destroyer force, which itself would be heavily in demand during a conflict. He is also correct that the SSC shortfall in general is pulling cruisers and destroyers into performing peacetime security cooperation tasks that detract from their combat readiness. I agree with his recommendation that the sea services should find ways to use U.S. Coast Guard and MSC ships to take on some share of peacetime as well as wartime SSC missions. In particular, I think it would be worth examining whether the Coast Guard’s High Endurance Cutters could be outfitted and their crews regularly trained to take on some share of wartime escort duties in low to moderate threat environments (e.g. outside or on the periphery of a contested zone). With respect to MSC ships, though, I would note that their hypothetical combat activities may be constrained by international legal considerations. These need to be fully investigated when developing concepts for how they might be used to take on SSC-type tasks.
- The Navy’s proposed SSC solution is to modify
the two existing LCS variants’ designs so that the FY19 and follow ships
receive permanently-installed anti-submarine and long-range anti-ship
capabilities as well as improved EW capabilities. Bryan reasonably recommended
that they should also receive a medium-range air defense interceptor such as
the Evolved Sea Sparrow Missile (ESSM) that would allow them to protect
escorted units, but this is not part of the proposed program of record. As a
result, wartime convoys approaching a combat zone in which there is a
considerable air (or submarine-launched ASCM) threat will likely need to be
augmented by AEGIS combatants or external tactical air support. This will absolutely
be the case if a convoy must traverse part of a contested zone. Convoy demands
are likely to be high in a war against a great power adversary, and as such the
availability of AEGIS combatants for offensive SAG operations may be limited by
the demands on them for convoy protection.
Tomorrow, I will
examine the surface
Navy’s leadership’s article on SAG concepts in the January Proceedings.
--Updated 8:43PM 1/14/15 to clarify why longer-ranged interceptors might be needed by a SAG if the separation between its units is increased, and to delete a typo in the beginning of the 'Other Thoughts' subsection--
The views expressed herein are
solely those of the author and are presented in his personal capacity. They do
not reflect the official positions of Systems Planning and Analysis, and to the
author’s knowledge do not reflect the policies or positions of the U.S.
Department of Defense, any U.S. armed service, or any other U.S. Government
agency.
[i]
The X-band AN/ZPY-3 radar on the MQ-4C Triton is a surface surveillance and
ship classification sensor. It is not suited for long-range AEW.
[ii]
See 1. Dave Adamy. “EW Against Modern Radars-Part 2: Radar Jamming Techniques.”
Journal of
Electronic Defense 33, No. 1 (January 2010): 44-46; 2.
Thomas W. Kimbrell. “Electronic Warfare in Ship Defense.” Technical Digest,
Naval Surface Warfare Center Dahlgren Division, (September 2004): 85-86; 3.
Craig Payne. Principles of Naval Weapon
Systems. (Annapolis, MD: U.S. Naval Institute Press, 2006), 91-92.
[iii]
See Norman Friedman. Network-Centric
Warfare: How Navies Learned to Fight Smarter Through Three World Wars.
(Annapolis, MD: Naval Institute Press, 2009), 206-210.
Tuesday, January 13, 2024
Is the Carrier as Obsolete as the battleship?
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| Scrapping the battleship ex-USS West Virginia in the 1950's |
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| The former UK carrier Ark Royal being scrapped more recently in Turkey Will US CV's soon follow? |
During last Friday’s great aircraft carrier debate hosted by the Naval Academy Museum, one of the debaters, Dr. Jerry Hendrix, said that the day of the carrier was drawing to a close primarily due to their vulnerability. He further compared the coming demise of the big flattop to that of the battleship. These assertions are at odds with the opinions of many in the history and analysis communities. The battleship had reached its evolutionary limits by the mid 1940’s while the carrier continues to evolve as a platform in the present. The battleship disappeared from the world’s naval inventories at the end of World War 2 for reasons of cost and firepower analysis, not vulnerability. Finally, the carrier has generally been viewed as more vulnerable than the battleships it replaced. Its air wing, rather than the physical platform of the ship, is the source of both its offensive and defensive capabilities. Both Dr Hendrix and his debate partner Bryan McGrath rightly addressed shortfalls in the present carrier air wing.
| Pioneering battleship HMS Devastation (1873) |
| HMS Dreadnought (1906) |
The battleship evolved as a platform, beginning with its first recognizable incarnation, HMS Devastation, which appeared in 1873. Over the next 70 years, as gun size and effectiveness increased, both the armament and the armor required to protect the battleship from such ordnance swelled in both size and cost. Combat ranges increased parallel to these developments. Captain Wayne Hughes suggests that battleship effective gunnery ranges increased a matter of tenfold from 1898 to 1948. Engineering plants grew as well in order to propel the battlewagon at appropriate tactical and operational speeds. These factors combined to gradually increase battleship size. The limited battle experience of the period indicated that bigger guns fired at longer ranges were decisive. Battleship designers responded and the all-big gun HMS Dreadnought of 1906 further accelerated the growth of the platform in order to accommodate more long range ordnance. Further advances such as lighter-weight Krupp armor, turbine engines, and director-firing of naval guns allowed for continued battleship construction at reasonable size and cost through the 1920’s, but by the early 1940’s this process reached the physical and financial limits of effectiveness. Battleship guns of 18 and 20 inch size required hulls in excess of 80,000 tons displacement to mount a tactically useful battery of such weapons. The armor required to provide protection from similar ordnance and the engineering plants necessary to propel these behemoths resulted in warships like the Japanese Yamato class battleships by the early 1940’s.
| IJN Yamato (1943) |
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| HMS Glorious |
The problem, however, with these armored titans was that their ability to deliver sustained ordnance at long range over time had approached an apogee in technological development. Further battleship growth was no longer a cost-effective solution to the problem of mass-delivery or ordnance at range over time. The aircraft carrier that emerged during the First World War offered much more potential to deliver high volumes of ordnance at much longer ranges than the battleship gun. This condition developed as the range and weapon capacity of carrier aircraft increased. Carriers remained vulnerable to surface ship attack, especially before the widespread introduction of radar and in the absence of strong escort. The British carrier HMS Glorious was sunk by the German battleships Scharnhorst and Gneisenau under such conditions in June 1940. Unlike the British, the U.S. and Japanese Navies developed larger, longer-ranged and more capable carrier aircraft. Their efforts were fully developed by 1942, when according to Hughes, the weight of a carrier airstrike was sufficient to destroy capital ships without risking the carrier to counterattack by gunships under cover of darkness. The battleship, by contrast, could not improve beyond the range of its guns. This inefficiency, combined with their large crews and high rate of fuel consumption, made the battleship less desirable as the principal means of large ordnance delivery at sea or against shore-based targets. The revolution in antiaircraft provided by the proximity-fused shell had restored the battleship's survivability against air threats but was not enough to save the big ships from their logistical and financial limitations. When the surviving world navies downsized at the conclusion of the Second World War, the battleships were one of the first platforms to be retired.
The carrier, despite its obvious greater vulnerability, was retained and continued to evolve as an ordnance-delivery system. Like the battleship, the carrier grew in response to technological change and war experience. Before the war, the two prevailing carrier designs were the British closed and armored carrier and the American/Japanese open/unarmored hanger design. The British version accepted a lower number of aircraft in exchange for greater protection of their aircraft from both attack and the elements. The British also expected to fight largely in littoral regions and believed their small carrier air wings would be supplemented by land-based aircraft. The Americans and Japanese, by contrast, expected to fight in the blue water spaces of the Pacific where the relatively warmer weather and absence of land-based aviation support both supported and demanded a carrier with a large, open hangar where its much larger airdrop could warm-up in preparation for launch.
| USS Midway |
The U.S. decided on a combination of these two formulas with the 1945 Midway class carriers. These ships grew substantially compared with the proceeding Essex class in order to support both armor protection for the hangar and a large air group. This need to protect the air group, as well as the advent of nuclear weapons, the fuel economy factor offered by nuclear propulsion and increasing size of jet aircraft rapidly drove increases in carrier size in order to maintain an ideal large air group. Smaller carriers have been considered by the U.S. and other navies since 1945, but most have determined that it is more cost-effective over the long term to take a larger airdrop to sea. The late British naval constructor and historian D.K. Brown said, “it is wasteful to provide all of the workshop and store facilities (on a carrier) for only a few aircraft.” This problem condemned many British small carrier designs until the advent of the Harrier aircraft allowed for a moderately respectable air group to be embarked. While small carriers have continued utility in littoral areas during the 21st century, independent operations without the support of land-based aircraft demand larger carriers with more comprehensive air wings. The British experience in the Falklands Islands campaign of 1982 illustrates both the advantages of sea-based aviation in remote areas, and the limits imposed through the use of smaller carriers with reduced air complements.
Despite increasing physical threats to the carrier as a platform in the last decade, the evolutionary development of the ship remains open and vibrant. Both Dr. Hendrix and Bryan McGrath discussed the limitations of the present, post-Cold War carrier air wing in comparison with its longer-ranged late Cold War counterpart. In the period 1990-2010 there seemed little need for a long range carrier strike aircraft. Most conflicts were associated with areas along the vast Eurasian littoral where land-based air assets were also in support alongside sea-based aviation. An Indo-Pacific conflict with limited land-based air support again demands longer-ranged aircraft operating from carrier decks. Development of a replacement manned or unmanned carrier strike aircraft would restore the carrier’s long range strike potential.
D.K. Brown eminently describes the battleship’s replacement by the carrier. He stated, “it is often said that the battleship died because it was vulnerable. This is incorrect; it was replaced by the fleet carrier which was much more vulnerable. The battleship died because it was far less capable than the carrier of inflicting damage on the enemy.” The carrier needs a similar well-defined successor in order to be similarly superseded as the principal naval platform. This could be the nuclear-powered guided missile submarine (SSGN), but it does not exist in sufficient numbers to equal a carrier’s strike capability. A mass launch of missiles from submerged platforms might also convince a would-be adversary that a nuclear weapon attack is underway. Such a situation could trigger a nuclear response from that opponent. A mass of surface ships has also been proposed as a potential carrier successor, but issues of logistical support necessary to keep a large number of small combatants on station, as well as weather could complicate such an effort. By at least Brown’s standard, the aircraft carrier has yet to be replaced as the principal naval combatant. Other navies seem to accept this condition, as the People’s Republic of China, Russia, France, India, and Great Britain have continued to purchase or build large aircraft carriers. Small carriers are operated by Italy and Spain. Japan and Australia’s new amphibious assault ships have the potential to be carriers. The carrier remains in many ways as vulnerable as it was when first introduced at the end of the First World War. It continues, however, to be an as yet unequaled flexible and re-configurable strike and naval warfare asset. Discussions on the carrier's future should continue, but the platform is by no means obsolete and its vulnerability remains an acceptable risk in light of its many capabilities.
DOD Wants the Marines in Spain
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