The Stealthiest Ship Ever Built

The US military is building its entire force structure around the concept of information which includes data collection, surveillance, networks, etc.  In other words, the military is assuming – or, at least, working towards the goal of – perfect battlefield awareness, believing that will make up for vast, self-inflicted shortcomings in firepower.  Setting the lunacy of that assumption aside, the implication is that the US believes that all will be known and seen on the battlefield.  Accepting that premise for the sake of analysis and discussion, we must also assume that the Chinese will have the same degree of total vision and situational awareness.

 

What, then, does that suggest about the survivability of naval forces?  It’s obvious, isn’t it?  Only the most stealthy platforms will be able to evade detection for any useful time period.  Unfortunately, none of our current naval surface ships come remotely close to that level of stealth.  In order for a ship to survive on the future naval battlefield, it will need to have maximum stealth across the entire electromagnetic spectrum and beyond.  With that in mind, why don’t we have a bit of fun and see if we can come up with a conceptual design for a future ship – it doesn’t matter what type – that is the stealthiest possible given our current level of technology? 

 

Before we go any further, we need to briefly review what stealth is. 

 

While most people associate the term ‘stealth’ with radar signature, the term actually encompasses much more.  The definition of stealth is the ability to evade detection.  That evasion can include measures such as reduced radar signature, reduced infrared signature, reduced acoustic signature, altered visible signature (camouflage), the use of multi-spectral obscurants, decoys (chaff, flares, emitters), electronic warfare, tactics (avenues of approach, use of weather), etc.  It should be noted that some of these do not have to be part of the ‘hiding’ platform’s capabilities but can be provided by other platforms in support of the ‘hider’.  For example, an F-18G Growler electronic warfare aircraft can provide stealth cover for other ships or aircraft by using its EW/jamming capabilities to reduce the likelihood of detection of the ‘hiding’ platforms.

 

Of course, having organic stealth measures helps, too!

 

So, understanding everything that goes into making a platform – a ship, in this case – stealthy, let’s see if we can conceptually design the ultimate stealth surface ship, just for fun.  What would it look like?  What characteristics would it have?  What unique aspects would be incorporated into this design that are not currently common? 

 

For this exercise, we’ll only consider the organic stealth measures and ignore the off-board measures from other platforms.  Thus, we’ll concern ourselves with size, radar signature, acoustic signature, infrared signature, optical visibility, electromagnetic emissions, obscurants, decoys, electronic warfare, and wake suppression.  Some of these factors are pretty obvious so, for the sake of brevity, I won’t belabor them.

 

Size – The most basic – and almost universally ignored – aspect of ship stealth is size.  Simple size.  All else being equal, a smaller ship is harder to detect than a larger ship.  A smaller ship naturally has smaller signatures across the electromagnetic spectrum.  This is a fundamental truth that the Navy has totally ignored as it continues to produce ever larger ships.  The WWII Fletcher class destroyer was 376 ft long versus a Flt IIa Burke class destroyer which is 509 ft long.  A WWII Atlanta class cruiser was 541 ft long versus a Zumwalt class cruiser (the Navy misleadingly calls it a ‘destroyer’) which is 610 ft long.  The Brooke class FFG was 414 ft long which was followed by the larger Perry class FFG which was 453 ft long which was followed by the still larger Constellation class FFG which is 496 ft long.

 

One of the largest drivers of ship size is the Navy’s obsession with helicopters.  The Navy believes that every ship must have a helicopter with its attendant flight deck, hangar, magazines, maintenance shops, additional crew, etc. which make up a third of a ship’s length and superstructure.  No ship should have a helicopter unless it is absolutely required for the execution of its primary mission.  For example, an AAW escort has no need for a helo which instantly reduces the ship’s size by a third – a nice chunk of ‘instant stealth’!

 

Included in size considerations is the superstructure.  Superstructures have grown enormously since the ships of WWII (see, “Ship Superstructures”).  Every square foot of superstructure area and every cubic foot of superstructure volume increases the ship’s various signatures.

 

The obvious conclusion is that our stealthy ship must have the smallest hull size and smallest superstructure possible, consistent with its mission requirements (CONOPS).

 

 

Radar Signature – This is the commonly understood measure of stealth and needs little further discussion other than to note that a truly minimized radar signature requires that there be no protruding objects such as railings, sensor domes, antennae, line handling equipment, platforms and supports, cabling, electrical junction boxes, firefighting plumbing, etc., all of which our current ships have in abundance.  Our conceptual starting point, in this respect, is the Swedish Visby which is nearly as free of protruding items as possible (see, “Ship Stealth and Visby”).

 

Visby - Note the relative lack of protruding objects

Acoustic Signature – Arguably, the most lethal threat to ships is the submarine and the main means of detection that a submarine uses is acoustic sensors.  Our ship must be as quiet as possible.  Every known acoustic suppression method must be used, including isolation and rafting of internal machinery, selection of inherently quiet machinery, Prairie-Masker, vibration dampening, cavitation suppression, etc.  Silence must take priority over speed.  The powertrain and propulsion must be the quietest possible.  We cannot use massive noise beacons like water jets.  I do not have detailed acoustic data about propulsion pods but I suspect they may be a good choice since they eliminate the use of long, large, noisy propeller shafts and combining gear.  I also do not have acoustic data on turbines versus, say, diesel engines.

 

The point is that the propulsion system must be selected for reduced sound rather than maximum power or speed, again, consistent with mission requirements.  This would be a radical departure from current ship design.

 

Infrared Signature - Ideally, our ship should have a temperature identical to the surrounding ambient air and water.  One of the major IR sources is, of course, the hot exhaust from the commonly used turbine engines.  If we can’t find a better choice than turbines, we need to, at least, suppress the heat of the exhaust by discharging the heated air through a water mist or exhausting the air into the water[4] or very near the waterline in a water-cooled discharge.

 

The rest of the hull and superstructure gets hot from internal heat sources and heat absorption from the sun.  The hull and superstructure need a cooling system similar to the Nuclear/Biological/Chemical (NBC) washdown system.  In this case, instead of washing away radioactive particles, the washdown would serve to cool the ship’s skin and reduce the IR signature.

 

Optical Visibility – Many weapons use optical sensing for target identification, terminal guidance, and impact point selection.  We must reduce or alter our optical signature as much as possible by reducing ship and superstructure size and by applying camouflage to break up or alter the ship’s outline.  Interestingly, early WWII Gato submarines had relatively large superstructures which, in combat, were quickly cut down to reduce their visible detectability.  We must follow this example.  The least detectable superstructure is no superstructure.  While that may not be totally achievable, it is the goal we must strive for.  We must ruthlessly eliminate any non-combat compartment in the ship.  This means no ship’s post office, no gym, no crew lounge, no chapel, no lawyer’s office, etc.  This is a ship of war not a cruise ship.  Every non-combat space that can be eliminated allows us to reduce the size of the superstructure.  I guarantee that every sailor will gladly choose survival in combat over a coffee bar or video game lounge.

 

An intriguing area for research is the use of adaptive electrochromic coatings/paint that can alter their color, reflectance, and other properties depending on temperature, light and light angles, and electrical state.  To the best of my limited knowledge, these are not available for field use but they should be aggressively pursued as near term research projects.[3]

 

Electromagnetic Emissions – This is our old friend, EMCON.  This is well understood and, until very recently, totally ignored by the Navy.  I won’t belabor this further other than to emphasize that our conceptual ship cannot have any stray emissions and must be designed to operate without active emissions to the maximum extent possible.  This means emphasizing passive detection and tracking of targets versus active.  To the maximum extent possible, fire control must utilize passive sensing.  Every piece of equipment on the ship must have a verified EMCON mode of operation.  It goes without saying that cell phones, video games, or any other personal electric device must be banned.

 

Obscurants – ‘Smoke’ has been developed that can provide multi-spectral interference (concealment) and can be deployed as any other shipboard decoy canister.

 

Decoys – This is a vastly under-emphasized aspect of stealth.  Not to belabor the obvious but decoys mimic a real target in hopes that an attacking weapon will be fooled into selecting the decoy instead of the real ship.  Decoys can take many forms from simple emitters that broadcast the real ship’s radar frequencies to persistent, floating, radar reflecting, multi-faceted ‘igloos’. 

 

Similar to electronic warfare, the Navy has given relatively little attention to decoy research and development.  Current decoys are very basic and limited.  What is needed is a decoy that simulates radar, infrared, and visible emission characteristics of the host ship and has a useful degree of persistence.

 

We also need suitable doctrine and tactics for the employment of decoys.  For example, the current tiny handful of decoys embarked on ships is woefully insufficient for a high end naval battle.  We need to be capable of dispersing hundreds of decoys, not a handful.  Let an enemy weapon find the literal one-in-a-hundred signal that is the real ship.

 

Insert photo: Decoy 1.jpg  -multi-faceted radar reflector

 

Electronic Warfare (EW) – Despite the fact that historical data shows that EW is far and away the most effective defensive technique, the Navy has virtually ignored EW for decades.  Even the SEWIP modernization program barely pays lip service to the role that EW should play.

 

We need powerful emitters for jamming, false signal injection, cyber attacks, etc. and the entire electronic warfare system must be tied into the Aegis combat system so that it acts in a coordinated fashion.

 

Wake – Our enemies have wake homing torpedoes and no truly stealthy ship would be without wake suppression measures.  Unfortunately, wake suppression is technically challenging and I’m not sure if any practical measures have been fielded.  The Navy has a patent on a wake suppression technique using ultrasonics to reduce/remove the microbubbles in the ship’s wake which are what allow a wake to be sensed and tracked.[1]  Another patent describes a means of reducing wake vorticity (turbulence) by siphoning off the boundary layer of water along the hull.[2]

 

 

Design

 

Having come to an understanding of the various factors that impact stealth, we can now conceptualize a maximum stealth ship design.

 

The ship will be as small as possible with only a minimal superstructure – think a slanted, stealth version of a WWII Fletcher class destroyer superstructure, maybe less.  All surfaces, hull and superstructure, will be fairly sharply angled and will be completely smooth with no protruding pieces of equipment.  The ship will, externally, appear to have no equipment or weapons and items that are necessary for ship handling operations will be fully retractable in one way or another. 

 

Sensors will be either embedded flat panels or retractable with an emphasis on passive sensors providing complete and continuous hemispherical coverage with multitudes of redundant and overlapping sensors.  Even navigation radar will be omitted.  Instead, infrared and electro-optical sensors will provide navigational information.  This may force us to become actual sailors again but that’s not a bad thing, is it?  Radar use will be limited to active weapons employment and even that will be minimized.

 

Weapons will be retractable in various ways.  Even the ubiquitous Mk41 VLS will be modified with a completely flat cover instead of a multitude of separate hatches, each with its own several-sided radar reflecting surfaces. 

 

Except for specific ASW vessels, there would be no helo facilities. 

 

UNREP gear will be fully retractable.

 

This ship will require a complete revision in combat operating procedures.  The overwhelming emphasis will be on passive sensors and greatly reduced communications (none, during combat).  Admirals will have to trust the ship captains to understand their mission intent and then leave them free to execute as they deem best.  The constant verbal diarrhea gushing forth from today’s ships will be a thing of the past.  This ship will operate unseen and unheard.

 

Nothing will be allowed on the ship that does not have a verified, shielded, EMCON operating mode.  The ship will not emit a single stray electron.

 

The ship will embrace bad weather, seeking it out and using it tactically for whatever degree of cover it can provide.

 

The ship will be constantly passively ‘sniffing’ the electromagnetic spectrum for its situational awareness instead of depending on the brute force of radar.  The crew and ship’s systems will be constantly a hair’s breadth from active combat.  Combat systems will have a full auto mode which will be the standard mode in a combat zone.  There won’t be time for human reactions.

 

The ship will be built for war, not cruising.  Silent.  Unseen.  Stealthy.

 

 

 

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[1]https://patents.google.com/patent/US5787048A/en

 

[2] https://patents.justia.com/patent/5222455

 

[3]https://gardnerlaboratories.com/2013/11/22/chemistry-corner-more-color-changing-paint-byk/

 

[4]Discharge into the water will increase the backpressure on the exhaust flow thereby reducing propulsion system performance.  This is an example of prioritizing stealth over speed.