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Type 26 Frigate build expected to begin in 2017

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BAE have confirmed that they expect the Type 26 Frigate build will begin in Glasgow in 2017.


Anne Healey, BAE General Manager (Group Business Development Canada) said, referring to a BAE bid to sell the Type 26 in Canada:

“The Type 26 Global Combat Ship is the world’s newest and most advanced surface combatant design.

We are planning to cut steel in 2017, which is ideal timing for the CSC programme; being 3 years ahead of the Canadian program.”

More information on the reception of the BAE bid to sell the Type 26 in Canada can be found here.

This ties in with a recent parliamentary briefing paper detailing the upcoming National Shipbuilding Strategy which estimated that the Type 26 Frigate will not begin until April 2017 at the earliest.

While the planned 2017 start date is well known in the defence industry and other relevant circles, it’s the first time BAE have said this at this at a high level.

Manufacturing of the Type 26 Frigate was initially expected to start in 2016, confirmation of when the work will begin has still to be announced officially but we’re told that it’s anticipated that the steel will be cut for the first Type 26 in Q4 of 2017, this is backed up by a briefing paper and is no industry secret.

According to the Briefing Paper:

“The Government has yet to agree a manufacturing date with BAE Systems. The programme is currently at the Demonstration stage. This was extended in March 2016 for a year with a £472 million contract.

Manufacturing of the Type 26 was expected to begin around the middle of the decade and even in early 2015 the MOD was giving a date of 2016, with the first in class to enter service in 2022 in time to begin replacing the Type 23’s.

Manufacturing will not begin before summer 2017.

The programme moved from the assessment to the demonstration phase in April 2016. The demonstration phase was then extended until June 2017 with the signing of a 472 million contract in March 2016.

The MoD says a fixed date for the start of manufacture won’t be committed to until Main Gate. This is not expected to occur until the end of the demonstration phase. So far £1.8bn has been committed to the Type 26 programme.

BAE Systems is working on the assumption that the initial order will be for three hulls.”

RUSI analyst Peter Roberts suggests the reason for the continued delay to the build is not for design reasons but because the Type 26 budget is underfunded by around £750m this year.

type_26.png
Despite alarming headlines, the Type 26 frigates have not been cancelled or “indefinitely postponed”. Unions have also insisted that there will be no redundancies as a result of uncertainty over the Type 26 build timetable on the Clyde.

Duncan McPhee from Unite said the contract was still guaranteed.

“There is guarantees. The main issue is the timetable, which is causing us the real problems and that has to be sorted out as soon as possible.”

Mr McPhee also added that BAE bosses were in negotiations with officials at the MoD to resolve the Type 26 Frigate build timetable issues:

“It means for jobs that we have the workforce geared up for this programme and that workforce will remain.

It means that we are going to have to do a lot of things between the company and moving different work packages about, keeping people at Rosyth maybe for longer working on the aircraft carriers, maybe having to transfer people down to Barrow for the submarine programme so we will keep the jobs.”

Peter Roberts, Senior Research Fellow for Sea Power and Maritime Studies at RUSI has said referring to the commitment of the government to the Clyde:

“There is going to be a commitment, we see that from the government, of continued shipbuilding orders.”

A MoD spokesperson said:

“The Government is committed to building ships on the Clyde and to the Type 26 programme. over the next decade, we will spend around £8 billion on Royal Navy warship.

As set out in the Strategic Defence and Security Review, we will build two new offshore patrol vessels on The Clyde, maintaining Scottish shipbuilding capability ahead of the start of the Type 26 build.

We will also consult with industry and trade unions as part of the national shipbuilding strategy, which will set the UK shipbuilding industry on a sustainable footing for the future.”

The SNP and others had said that any reduction in the number of Type 26 frigates being built on the Clyde would be a “betrayal” of the workforce.

All will be built in Scotland.

https://ukdefencejournal.org.uk/typ...B&utm_medium=FacebookPage&utm_campaign=social
 
. . . . .
They wanted partners to make it cheaper at first,even offered it to my country.
I know. Several other western countries seem to be interested in this design.
However, notwithstanding, they should have gone ahead and build it in with the current cost. when built and inducted, many more countries will eventually order these advance warship. Build it and they will buy(especially when it's an advanced design/equipment).
 
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I know. Several other western countries seem to be interested in this design.
However, notwithstanding, they should have gone ahead and build it in with the current cost. when built and inducted, many more countries will eventually order these advance warship. Build it and they will buy(especially when it's an advanced design/equipment).
The Type 45 is one of the best,if not the best,i wish we had a couple of those.
 
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What are we India? We don't have many choices but to build our own.
But I don't think that will be too expensive per se(giving the capabilities of the Type 23(not 25) we will soon be retiring come mid/end of 2020s. They still carry a very formidable firepower/capabilities.
So other developing countries will do well to purchase then whem at discounted prices they are decommissioned.

The Type 45 is one of the best,if not the best,i wish we had a couple of those.
To be honest, it's too advanced and EXPENSIVE even for a big country like Turkey to operate(it's still the only warship in the world apart from U.S Zumwalt to use electric propulsion system for example). Even the Saudis found it too expensive to buy(over $1.5billion dollars a piece).:cheesy:
 
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RS30005_Type-26-lpr-1021x580.webp

BAE have confirmed that they expect the Type 26 Frigate build will begin in Glasgow in 2017.


Anne Healey, BAE General Manager (Group Business Development Canada) said, referring to a BAE bid to sell the Type 26 in Canada:

“The Type 26 Global Combat Ship is the world’s newest and most advanced surface combatant design.

We are planning to cut steel in 2017, which is ideal timing for the CSC programme; being 3 years ahead of the Canadian program.”

More information on the reception of the BAE bid to sell the Type 26 in Canada can be found here.

This ties in with a recent parliamentary briefing paper detailing the upcoming National Shipbuilding Strategy which estimated that the Type 26 Frigate will not begin until April 2017 at the earliest.

While the planned 2017 start date is well known in the defence industry and other relevant circles, it’s the first time BAE have said this at this at a high level.

Manufacturing of the Type 26 Frigate was initially expected to start in 2016, confirmation of when the work will begin has still to be announced officially but we’re told that it’s anticipated that the steel will be cut for the first Type 26 in Q4 of 2017, this is backed up by a briefing paper and is no industry secret.

According to the Briefing Paper:

“The Government has yet to agree a manufacturing date with BAE Systems. The programme is currently at the Demonstration stage. This was extended in March 2016 for a year with a £472 million contract.

Manufacturing of the Type 26 was expected to begin around the middle of the decade and even in early 2015 the MOD was giving a date of 2016, with the first in class to enter service in 2022 in time to begin replacing the Type 23’s.

Manufacturing will not begin before summer 2017.

The programme moved from the assessment to the demonstration phase in April 2016. The demonstration phase was then extended until June 2017 with the signing of a 472 million contract in March 2016.

The MoD says a fixed date for the start of manufacture won’t be committed to until Main Gate. This is not expected to occur until the end of the demonstration phase. So far £1.8bn has been committed to the Type 26 programme.

BAE Systems is working on the assumption that the initial order will be for three hulls.”

RUSI analyst Peter Roberts suggests the reason for the continued delay to the build is not for design reasons but because the Type 26 budget is underfunded by around £750m this year.

type_26.png
Despite alarming headlines, the Type 26 frigates have not been cancelled or “indefinitely postponed”. Unions have also insisted that there will be no redundancies as a result of uncertainty over the Type 26 build timetable on the Clyde.

Duncan McPhee from Unite said the contract was still guaranteed.

“There is guarantees. The main issue is the timetable, which is causing us the real problems and that has to be sorted out as soon as possible.”

Mr McPhee also added that BAE bosses were in negotiations with officials at the MoD to resolve the Type 26 Frigate build timetable issues:

“It means for jobs that we have the workforce geared up for this programme and that workforce will remain.

It means that we are going to have to do a lot of things between the company and moving different work packages about, keeping people at Rosyth maybe for longer working on the aircraft carriers, maybe having to transfer people down to Barrow for the submarine programme so we will keep the jobs.”

Peter Roberts, Senior Research Fellow for Sea Power and Maritime Studies at RUSI has said referring to the commitment of the government to the Clyde:

“There is going to be a commitment, we see that from the government, of continued shipbuilding orders.”

A MoD spokesperson said:

“The Government is committed to building ships on the Clyde and to the Type 26 programme. over the next decade, we will spend around £8 billion on Royal Navy warship.

As set out in the Strategic Defence and Security Review, we will build two new offshore patrol vessels on The Clyde, maintaining Scottish shipbuilding capability ahead of the start of the Type 26 build.

We will also consult with industry and trade unions as part of the national shipbuilding strategy, which will set the UK shipbuilding industry on a sustainable footing for the future.”

The SNP and others had said that any reduction in the number of Type 26 frigates being built on the Clyde would be a “betrayal” of the workforce.

All will be built in Scotland.

https://ukdefencejournal.org.uk/typ...B&utm_medium=FacebookPage&utm_campaign=social

Compared to similar shps around the world what it offer better in terms of capabilities and price?

But I don't think that will be too expensive per se(giving the capabilities of the Type 23(not 25) we will soon be retiring come mid/end of 2020s. They still carry a very formidable firepower/capabilities.
So other developing countries will do well to purchase then whem at discounted prices they are decommissioned.


To be honest, it's too advanced and EXPENSIVE even for a big country like Turkey to operate(it's still the only warship in the world apart from U.S Zumwalt to use electric propulsion system for example). Even the Saudis found it too expensive to buy(over $1.5billion dollars a piece).:cheesy:

The is very expensive. :o:
 
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The is very expensive. :o:
Yes indeed, the Type cost almost £1.1billion to build, which was equivalent to about $1.5 billion. To make up for the cost, they do pack considerable firepower and capabilities. For example our National Audit Office reported that, during an "intensive attack", a single Type 45 could simultaneously track, engage and destroy more targets than five Type 42(the destroyers that preceded the Type 45 in the Royal navy) destroyers operating together.:agree: A couple of Type 45 and an astute sub can probably take care of a mid size power's entire naval fleet. :D

Compared to similar shps around the world what it offer better in terms of capabilities and price?
They will hardly have any peer in their class, judging by its multi role capabilities and anti submarine potential.
This is a very longggg read but a worthy one of you want to understand the Type 26 Global combat frigate in details. so i will post it in full for you. lol

De-Risking the Type 26
The most sensible part of the whole programme is its attitude to technology risk. Whether this is wholly intentional, or merely a happy by-product of Type 23 obsolescence and timing issues is for others to argue, but the fact remains, Type 26 has a relatively low level of technology risk.

Most of the major systems have been, or will be, de-risked on Type 23, with perhaps a few on the QE Carriers. There are no major sensors or weapons being developed to form part of the design, and the power/propulsion design is well proven.

From an old Royal Navy publication (page 120);

To reduce programme risk, and in keeping with the principles of through-life capability management, there is a drive to maximise pull-through from the Queen Elizabeth-class aircraft carriers, Type 45 destroyers and ongoing Type 23 capability sustainment/upgrades, in an effort to both reduce risk and capitalise on previous investment, and/or existing system inventory. So while the Type 45 is characterised by approximately 80 per cent new to service equipment and 20 per cent reuse, these percentages will be effectively reversed for Type 26
The air defence system, gas turbine, countermeasures, helicopter handling, combat management system, medium calibre gun, sonars and even the chip fryers will be in service on ships other than Type 26 GCS before they are in service on the Type 26 GCS.

Without a shadow of doubt, this is a good thing.

There is of course, design and engineering challenges, but at least, there are no major systems to develop in parallel.

Some of the physical systems from Type 23 may be transferred to under construction Type 26’s, depending one would assume, on crossovers between out of service, build and in-service schedules.

The Type 23 has been continually upgraded but the most recent package of improvements has been defined as the Type 23 Capability Sustainment Programme (CSP), this from a presentation at RUSI in 2012 shows the intended scope of the CSP.

FireShot-Capture-45-https___www.rusi_.org_downloads_assets_1100_b_Chris_Richards.pdf.jpg


The slide above is merely an indicator but it provides a good overview of the planned upgrades.

Combined with a number of equipment obsolescence changes improve the life of the hull and superstructure, the CSP has started to be incorporated into the existing Type 23 fleet, the first being HMS Argyle.

Babcock-HMS-Argyll-in-dock_Babcock_15122-D-67-e1445718256563-1120x565.jpg


This Life Extension (LIFEX) to HMS Argyl that started in June this year will not only add the ARTISAN radar and Sea Ceptor missile system but also such seemingly mundane improvements as a chilled water ring main and new paint.

General Issues and Costs
The weight and size of Type 26 has changed, and possibly will continue to change until the detailed design is frozen and steel cut.

This original baseline was reportedly 141m long, displacing 6,850 tonnes and costing an estimated £500m each.

As part of the ongoing cost/capability trade-offs, it was repeatedly reported that this cost was undesirable to the MoD and capabilities (and size) pared down to achieve a target cost of £250 million to £350 million each.

The displacement was reduced to 5,400 tonnes and the ship dimensions, 148m length with a beam of 19m. Sharp-eyed readers will note that the length had actually increased from the baseline.

Cast your mind back to the history of Type 26 and the C1 (Versatile Surface Combatant) was expected to displace about 6,000 tonnes and the C2 (Medium Vessel Derivative), 4-5,000 tonnes.

The latest from BAE is that the ship will be 149.9 metres in length, have a maximum beam of 20.8 metres and a displacement of 6,900 tonnes, not a million miles away from the original baseline.

Funny that!

There seems to be some concern about the changing size and displacement of Type 26 but this is simply reflective of its desired capabilities and equipment fit and the realities of current regulations and standards, to coin a phrase, it is what it is.

Type-26-Type-23-Size-Comparison-1120x549.jpg


Top speed is 26+ knots and endurance has been reported at 60 days against a range of 7,000 nautical miles at 15 knots.

In line with contemporary ship construction methods, there has and will be a great deal of thought and effort put into ease of upgrade, reflecting the likelihood of major systems change over the life cycle of the ships. Blown fibre optic cable, block construction, COTS computing hardware and prefabricated internal fixtures like accommodation spaces are just a few of the features that are designed to keep construction and refit costs down.

Clean lines, faceted construction and carefully chosen materials are designed to reduce the ships electromagnetic signature although there are of course obvious limitations in this regard.

There will be EIGHT Type 26 Global Combat Ships.

Final cost remains to be published but a summary from the previous post shows costs to date.

  • Prior to 2008; £17 million on various FSC studies
  • 2008; £4 million to BAE to investigate the 155mm TMF
  • 2009; £3.4 million to BAE for initial design work
  • 2010; £127 million to BAE for the Assessment Phase on the programme
  • 2014; £1.9 million to McKinsey for cost review support
  • 2015; £859 million to BAE for the Demonstration Phase of the programme
  • 2015; £1.8 million to £10 million for Financial Consultancy Services
  • 2016; £472 million to BAE for a Demonstration Phase extension
  • 2016; £183 million to BAE for three main guns and one trainer
Some of these cannot be attributed directly to Type 26, obviously, but they are useful indicators.

Equipment
The Type 26 Global Combat Ship (GCS), or Frigate, is designed to fulfil a variety of missions but the main one is combat operations, at a high tempo and against a peer enemy.

Admiral Sir Philip Jones described Type 26 well;

The distinction is that the Type 26 is a high-end anti-submarine warfare frigate, and it is deliberately designed to be so. Its design enables it to provide high-end protection both to our continuous at-sea deterrent forces and to our future carrier strike groups, and it is deliberately designed to be resilient, noise-quietened and highly effective in countering peer and near-peer threats in the anti-submarine warfare environment.
A summary of what we know, with one or two guesses;

Power and Propulsion
Anti-Submarine Warfare (ASW) requirements influence the hull design and means of propulsion.

The ability to tow a large sonar array, a low acoustic signature hull and ability to carry out ‘sprint and drift’ manoeuvres are essential to anti-submarine warfare. In the future, there may be technological developments such as offboard unmanned netted sensor swarms that change the requirements in the lifetime of Type 26, but for now, the Type 23 concept is still relevant and still, therefore, the design route chosen.

The propulsion and power configuration is COmbined Diesel eLectric Or Gas (CODLOG), sometimes called CODELOG, from Rolls Royce;

A CODELOG (Combined Diesel Electric or Gas Turbine) configuration is to be deployed in the Type 26 Global Combat Ship. The diesel gensets supply electric power for on-board systems and for vessel propulsion in cruising mode. The Rolls-Royce gas turbine will be switched in for high-speed propulsion whenever needed. The propulsion concept is ideally suited for the mission profiles of the future combat ships. For naval applications, the MTU gensets have double-resilient mounting systems and are housed within acoustic enclosures. This creates a propulsion system with an extremely low level of acoustic emissions, making the ship very difficult to locate.
The important difference between Type 26 and other similar vessels is the Or (O) instead of And (A) in CODELAG. Two presentations and papers that describe the differences can be found here and here.

For high speeds, the gas turbine drives the twin shafts through a splitting gearbox and then a reduction gearbox.

At lower speeds, where low noise is absolutely critical, the turbine and associated gearboxes are shut down and the shafts driven by General Electric Power Conversion induction motors. The motor speed is controlled by adjusting its frequency through another GE Power Conversion product, the MV3000 marine converter. Unlike the Type 23, that uses changes in DC voltage, the Type 26 will change the fixed AC supply to DC and then adjust the waveform supplied to the motor using a technique called Pulse Width Modulation (PWM). The MV3000 at the heart of the system is widely used in the marine industry and so support issues with unique equipment should be reduced, although for use in naval applications shock protection and noise reduction are key changes.

Commenting on the contract award, Mark Dannatt, GE Naval Systems Lead said;

Reducing radiated noise from the motor makes it exceptionally quiet, which is obviously very important for naval operations. GE is on the cutting edge with this proven, robust technology. It will allow the Royal Navy to operate more efficiently, cost-effectively and safely. Drawing on our extensive experience over decades in the electrical power conversion systems industry, we are moving to provide the latest in motor and drive technology that is at the forefront of operational efficiency
Rolls Royce will supply a single 36-40 MW MT30 Gas Turbine for each Type 26 GCS, the same as fitted to the QE Class carriers.

MT-30-Type-26-1120x406.jpg


The diesel generators will be from MTU, the same Type 20V 4000 M53B as used on the German F125 Frigates. Each ship will have four of them in a double resilient acoustic enclosure.

MTU_genset_20V4000-1-1120x487.jpg



In August 2015, the MoD awarded a £68 million contract to Rolls Royce for the provision of 48 MTU 12V 4000 M53B gensets, training and logistics support. Twelve Type 23’s will get four of the 1,650kW systems each. Although not identical to the 20V 4000 M53B gensets planned for the Type 26 one wonders if there is a high degree of commonality that will enable some rework and transfer?

(if you want a double decker infographic that the MoD seems keen on at the minute, click here)

David Brown Gear Systems will provide the reduction gearboxes and a load test rig, DCNS the shaft lines and, making an assumption, Rolls Royce, the propellor.

Type-26-Propulsion-1120x250.jpg


The image of engineering beauty on the right is a Type 23 fixed pitch propellor in the National Maritime Museum.

Although no details have been released on the propellor for the Type 26 GCS, the low noise fixed pitch propellers as fitted to the Type 23 can run on a diesel-powered electric drive at about 90 RPM or 13 to 17 knots. The slow rotation speed and fixed pitch propellers are used to lower the onset cavitation and radiated noise that might interfere with the sonar systems.

Finally, WR Davis will provide the engine uptakes and down takes.

Computing and Communications
The primary interface between the ships equipment and its crew will be the combat management system and this will likely be the latest iteration of the Outfit DNA(2)/CMS-1 from BAE.

In January 2011, BAE was awarded a £47m contract to support the combat management systems aboard the Type 23 Frigates and RFA Argus.

A good description of what a CMS does can be found at BAE;

The CMS assists a ship’s command in detecting and countering threats to the ship and any surrounding forces by managing all relevant external and internal information provided by the ship’s radars. It integrates this information with the activities of the anti-air weapons systems as well as other sensors and weapons.
The press release describes the Joint Support Solution which is a wider commercial framework incorporating the same systems on Type 45, CVF and future ships. In March 2012 year, BAE was awarded another related contract, in conjunction with QinetiQ. The £45m award covered specialist test, integration and approval of naval combat management systems and this, or at least a future extension/variant, will likely include work on the Type 26 programme.

BAE-DNA2-Combat-Management-System.jpg


The Surface Ship Combat Systems (SSCS) DNA system has had a difficult introduction into service. Originating in the Surface Ship Command System (SSSC) programme it was selected in 1989 after another advanced combat management system had failed. Does anyone remember Token Ring or IEE802.5, DNA(1) used this with fibre optic networking and combined such cutting edge systems as 3.2Gb storage arrays, Pentium processors and colour displays!

The Type 45 command and combat system is an evolved derivative of the DNA(1) system with elements from other programmes and run over a fast Ethernet network. It wasn’t until 2010 that the first Type 23, HMS Montrose, put to sea with the upgraded DNA(2) system, 4 years after the initial contract award to BAE that would also see the same system being deployed on future surface vessels and another variant for submarines. A significant feature of DNA(2) is that it is based on commercial hardware and software.

The Type 26 GCS will have a common computing infrastructure that makes use of open architecture systems for ease of technology insertion and change management.

BAE will be introducing a shared computing environment based on modern blade server architecture and operating systems virtualisation on Type 23 and this will be transferred to the Type 26. Given the rapid rate of development in computing equipment and long timescales between design and introduction of the Type 26 GCS this kind of technology, mundane and ordinary in the civilian world, will allow the ships computing environment to avoid obsolescence issues that limit effectiveness and drive up support costs as manufacturers struggle to find stocks of Intel 486 processors, for example.

The pace of change in IT equipment seems as rapid as ever and in a decades time when the Type 26 GCS is in service the computing power on offer in the open market will no doubt be hugely different than that today. Data growth is a key issue and by enabling the use of commercial hardware, opportunities to exploit this increasing amount of data can be realised at reasonable costs. Future unmanned systems will no doubt add to this data growth and the Type 26 must be ready for it.

Aish Technologies provide blade server enclosures, displays and consoles to the Royal Navy.

Type-26-Display-Console-and-Blade-Server-Enclosure-1120x311.jpg



Rohde & Schwarz will provide an integrated internal and external communication systems based on its NAVICS IP switching system that has been especially hardened to protect against physical and cyber disruption. i.Safe ATEX Smartphones with a graphical user interface will be employed to provide ‘man on the move’ communications and fixed terminal provided as required throughout the ship.
 
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Type-26-NAVICS-and-Terminals-1120x450.jpg




Software Defined M3SR (series 4100 and 4400) VHF/UHF and HF transceivers will provide external radio communications, making use of an R&S designed mast and a range ofsupporting ancillaries such as terminals, filters, power supplies and racks.

Type-26-Software-Defined-Radio-1120x343.jpg


In addition to the announced HF/VHF/UHF radios, the Type 26 GCS will most likely be fitted with the full complement of SHF satellite communication systems, IFF, underwater telephone, 3G, GSM, LTE and Link 11, 14 and 16 JTIDS. It might even get Link 22.

The Type 45 satellite communications were designed and installed by BAE, Thales and EADS Astrium, the latter responsible for the Satellite Communication Onboard Terminal (SCOT) 3 equipment. Type 23 satellite fit also uses SCOT equipment so it is possible, Type 26 will use the same.

Type-26-GCS-SCOT-Satellite-1120x537.jpg


Data sheets for SCOT Patrol and SCOT Mission, here and here.

Civilian systems such as Iridium or Inmarsat are also likely to be fitted.

Radar, ESM and Electro-Optical Sensors
The main radar will be the BAE Type 997 ARTISAN 3D system.

Now being fitted to the type 23 frigates, Advanced Radar Target Indication Situational Awareness and Navigation (ARTISAN) is an advanced medium range 3D radar with a high level of resistance to jamming, providing air surveillance, target identification and air traffic management services. The ARTISAN antenna weighs in at about 700kg the systems as a whole, developed at a cost of over £100m



HMS_Argyll_Type_997_Radar_MOD_45156530.jpg




Actual capabilities remain classified but it is reportedly capable of tracking in excess of 800 objects at a range of 200km.

There are also a couple of smaller and less sophisticated systems from Kelvin Hughes used on the Type 23 Frigate. The Kelvin Hughes Type 1007 and now Type 1008 is used for surface warning and navigation. Both are considered legacy equipment and so less likely to be transferred from the Type 23, instead the Kelvin Hughes Sharpeye digital radar systems will probably be used for navigation, obstacle avoidance and helicopter flight operations support.

Kelvin-Hughes-Sharpeye-1120x370.jpg


There are plans for the Type 23 to receive a navigation radar upgrade and if this happens, again, the systems may be a straight transfer. The Type 45 Destroyers use a Raytheon navigation radar system so without further clarification the choice remains unclear.

Lockheed Martin were awarded a £44m contract for navigation radars across multiple Royal navy platforms in 2016, with Kelvin Hughes as a key sub-contractor, the Vigilance radar software from LM combining with Kelvin Hughes radar. Cambridge Pixel’s software modules for radar scan conversion, target tracking and radar fusion will be used as part of the Vigilance system.

In May 2012, Thales announced the award of an earlier contract to upgrade the Royal Navy major surface fleet with their Fully Digital Radar Electronic Support Measures (RESM) as part of the UAT Mod 2 programme.

Under the terms of the new contract – the UAT MOD 2.1 & 2.3, advanced technology will be now be introduced to the UAT RESM equipments fitted across the RN surface fleet and associated land-based training equipments.
The technology provides excellent system performance in the modern dense radar environment. This enables the ship to operate in all operational maritime theatres, including the littoral environment, and provides the RN with world leading electronic warfare support and emitter identification technology. By digitising the RF signal at the antenna, the majority of the receiver functionality is implemented using software and firmware algorithms. The system is therefore easily upgraded and new signal analysis tools are easily introduced, keeping the RESM capability current in a rapidly evolving operational environment.

The approach also maximises the use of commercial off-the-shelf hardware, making the RESM significantly more reliable, easier to maintain and lowers the total cost of ownership.

In a nutshell, they detect, locate, classify and report signals intelligence data in real time, overall, a very advanced system.

Cooperative Engagement Capability now seems to be firmly off the agenda, if one looks at the images below, on the left is an older image of Type 26 with the CEC panels (the square ones) and the latest image on the right, without. Incidentally, the pyramidal shapes arranged around the mast are the ESM receivers described above.

Type-26-Mast.jpg


The Sharpeye navigation radar and SCOT satellite radomes can also be seen.

The shapes at the base of the mast that look like beer barrels are electro-optical sensors, the Ultra Electronics SERIES 2500 EO System that are standard equipment fit on Type 45 Destroyers.

Ultra-Series-2500-EO-System-1120x354.jpg


The stabilised sensor is called the Electro-Optical Director (EOD) and this is linked to a system console called the platform Control Cubicle (PCC). The system can be cued manually or automatically (including from radar and other systems), track moving objects with its long range TV and Infra-Red sensors, perform target identification and provide ballistic fire control information for the ships gunnery equipment.

HGH Infrared Systems manufacture panoramic thermal imaging systems, working in a QinetiQ led project they will supply their Spynel-M products for integration with the Compact Combat System (C2S) that will combine a Kelvin Hughes SharpEye radar and a Chess Dynamics Sea Eagle. The system is primarily designed to counter the small fast inshore attack craft (FIACs) threat. Information from the three sensors and AIS data is integrated with the Enhanced Situation Awareness From Existing Sensors (ESAFES) fusion engine and presented to a single display and cueing information provided to on deck automatic weapons via an Ethernet link. Although this is only a research project this kind of technology might find its way onto Type 26 GCS.



 
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Acoustic Sensors
The hull mounted Ferranti/Thomson Sintra Type 2050 sonar on Type 23’s has a long and complex history with many changes of ownership but the base product is now part of the Thales UMS 4110 family and utilises much of the processing and display console systems as the CAPTAS 4 or 2087.

From Jane’s;

Sonar 2050 is the medium-range, medium-frequency hull-mounted attack sonar for the Royal Navy fitted to the Type 42 destroyers and Type 23 and Type 22 frigates. It is the successor to Sonar 2016 and is compatible with both bow and keel variants of the Sonar 2016 array
In February 2014, Thales received 5-year support contract for the thirteen Sonar 2050 on Type 23 Frigates and then strangely, Ultra received a £27 million contract in December 2014 for the Sonar 2050 Technology Refresh Programme that will upgrade and support for ten years, 2050 sonar systems on eight Type 23 Frigates.

sonar-2050-dome-handling-pr.jpg


Whether the Type 2050’s will be transferred to the Type 26 or a new purchase of the UMS 4110 (or another type), is not yet known.

In addition to the Sonar 2050’s, eight of the Type 23 Frigates are fitted with the very sophisticated Sonar 2087 Variable Depth Sonar (Thales CAPTAS 4) that is designed to detect submarines at ranges greater than they can launch attacks.

Sonar 2087 can be operated ‘hands-free’ up to Sea State 6 and to a depth of 250m, a very important aspect of the system capability and one that has a clear origin in Cold War North Atlantic NATO missions. In addition to the processing, displays and handling equipment, the core components are two towed items, the towed body and towed array, one active, one passive, that can be deployed at variable depths.



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Detection in shallow waters is a problem because underwater obstacles might prevent the safe deployment of long towed arrays, fresh/sea water mixes, tidal impacts on water conditions, unpredictable and variable salinity/temperature, reflections from the sea bed and underwater obstacles and even concerns about underwater wildlife may limit the use of low-frequency devices.

Ambient and directional noise from man-made and natural sources also confuses the overall acoustic picture. Because of the smaller areas involved accurate seabed surveys and sediment analysis, sometimes called Rapid Environmental Assessments, can be used for ASW. This kind of technology and processes are more often used for survey and mine countermeasures but research continues at a pace and one capability may very well utilise another.

We might see the kinds of USV’s now routinely used for covert survey and seabed analysis carried onboard a Type 26 GCS in the future. Other promising research avenues include exploiting so-called ‘non-cooperative’ sound sources of opportunity, other ships that just happen to be in the area for example. The returns from these can be passively received into the detection and analysis software, cunning eh?

It is likely that the Sonar 2087’s will be a direct transfer from Type 23 to Type 26.

Anti-Air Missile Systems
Providing self (and possible small area) defence against aircraft and anti-ship missiles will be the Sea Ceptor system.

Sea Ceptor was previously known as Future Local Area Air Defence System – Maritime (FLAADS(M)). The MBDA Common Anti-Air Modular Missile or CAMM is one of the core UK Complex Weapons programmes that is intended to replace the Sea Wolf Block 2, ASRAAM and Rapier FSC missile systems in service with the Royal Navy, Royal Air Force and Royal Artillery respectively under the Future Local Area Air Defence System (FLAADS) requirement.

It is intended to maximise commonality across all three services in order to minimise logistic and support costs. FLAADS(M) for Maritime, FLAADS(L) for Land and FLAADS(A) for Air were all intended to be delivered with the Common Anti-Air Modular Missile. The modular design is also intended to facilitate lower the cost of through life incremental upgrades.

MBDA describe it as;

FLAADS(M) provides a true 360° air defence capability for naval forces out to ranges greater than 25km against the future air threat. Requiring no dedicated tracker/illuminator radars, CAMM can be cued by ship target indication data to provide high levels of protection in open ocean and littoral environments. It can also be used against surface targets. The weapon system, which incorporates a 2-way data-link capability to CAMM missiles in flight, is intended for vessels of corvette size or larger, for either new ships or as a retrofit. It will provide self and consort defence whilst operating with 2-D and 3-D radars and has an architectural design to allow integration within a variety of combat systems. CAMM can operate from SYLVER and Mk41 family launchers utilising features such as folding missile fins to maximise packing density. For smaller ships, a simple bespoke quad-pack launcher (occupying the same space as a Seawolf canister) will be available. The introduction of “soft launch” techniques reduces system mass and eases installation. MBDA has taken a Through Life approach in developing the CAMM solution. New weapon system architectures that reduce customer costs by removing expensive components are now possible. MBDA’s PAAMS (Principal Anti-Air Missile System) naval self, local and fleet area defence weapon system has now established a preferred architectural approach to air defence. FLAADS(M) follows this approach by re-using software and substituting new low cost components.
The missile itself takes a great deal from ASRAAM but it is not a surface launched ASRAAM with a new name. Common components include the very low signature rocket motor from Roxel, the warhead and proximity fuse from Thales. The seeker and open architecture electronics backbone are new, the latter is called Programmable Open Technology for Upgradable Systems or PrOTeUS and uses an IEEE 1394 Firewire bus technology as a starting point.

Sea Ceptor differs from Sea Wolf in a number of respects but the most significant is the elimination of a requirement for dedicated fire control radar. By removing this reliance on fire control radars, the data link and two-way active radar homing seeker is designed to overcome saturation attacks and has the additional benefit of removing a piece of equipment from the support chain.

Although range will, of course, be classified MBDA declare it as ‘in excess of 25km’, which in any case is better than Sea Wolf and Rapier but then it should be, at 99kg it is nearly 20kg heavier than Sea Wolf and over 50Kg heavier than Rapier.

The Common Data Link (CDL) is the small ‘black box’ that sits on top of the mast, especially clear in pictures of FLAADS(L) although it doesn’t necessarily have to use the two-way data link to the launch vehicle, so, it could take mid-course corrections from any number of suitably equipped land or air platforms and then switch to active homing when it gets close enough. The original launch platform could have even moved by the time the missile hits. Type 23 frigates will be fitted with two CDL’s.

It is reported that each missile in its sealed canister will have a shelf life of ten years and although MBDA claims it can be quad packed in either a SYLVER or Mk 41 launcher current images suggest they will be installed on Type 26 in a bespoke low-cost launcher. The soft vertical launch system that ejects the missile to a height of about 30m using an enclosed gas piston before a small a thruster fires to orientate the missile with the target location. This method is safer, removes the need to manage hot gas efflux in the launch silo and ensure all of the main rocket motor fuel is used for arriving at the target.



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Read more on Sea Ceptor here.

The location and configuration of the Sea Ceptor silos have been subject to a great deal of debate and speculation. Models and CGI’s have variously shown multiple locations and silo numbers and whilst the settled opinion seems to be a physically diverse arrangement with one silo block behind the gun and another adjacent to the funnel, 24 missiles in each location, the final arrangement remains subject to confirmation.

The Sea Ceptor missile can also be quad packed inside a Mk41 cell and MBDA have indicated it may have some anti-surface capability.

Surface and Land Attack Missiles
The first design iteration of Type 26 showed amidships Harpoon launchers but they have disappeared in the latest version.

It has been stated that Type 26 GCS will be fitted with a Lockheed Martin Mk41 Vertical Launch System (VLS), current imagery suggests 3 modules, a total of 24 cells. Like the SYLVER VLS fitted to the Type 45, the Mk41 provides a compact means of storing and launching vertically launched missiles, and specifically, a means of managing the hot exhaust. The rocket exhaust is directed into a chamber and then vented upwards through an aperture to the surface. It is available in a number of different lengths, the longest referred to as ‘Strike Length’, at 7.6m long.



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All good, the Mk41 is a widely used system with many options for filling it.

Filling it, though, is an interesting problem because the Royal Navy has nothing in service or nothing in pre-assessment phase listed by the National Audit Office that could be deployed to make use of the capability.

This leads to a couple of obvious conclusions, new toys will be announced soon, or it is simply a future-proofing exercise with an aspiration to fill them, the filling will be subject to all the usual programme steps.

A post-Libya Jane’s Defence Weekly reported on a Royal Navy lessons learned document in which the two major shortcomings were a lack of precision land attack capability and organic unmanned ISR.

It quoted Colonel Pierson RM, the Deputy Director of NATO Operations in Libya;

It was evident that the Libya campaign showed the need for precision fires, [perhaps the Lockheed Martin] Guided Multiple Rocket Launch System (GMLRS), from the sea base, deep into enemy littoral territory.
Is the Mk 41 there to satisfy the Land Attack or Anti-Ship role, or both?

Because there is no space provision for the in service Harpoon and the likelihood that the Royal Navy Harpoon missiles will be out of service by the time Type 26 hits the water the Royal Navy is likely to be in a position where it has no heavyweight anti-ship missile and must rely on either helicopter launched Sea Venom missiles or perhaps, torpedoes.

There are a few of obvious contenders for the Anti-Surface Warfare and Land Attack requirement if indeed that is the requirement.

Tomahawk

With uncertainty over the future of submarine launched Tomahawk cruise missiles it would make sense to hedge against future risk by ensuring Type 26 can launch the Tomahawk. Think Defence readers will be familiar with the general capabilities of the venerable and relatively low-cost Raytheon Tomahawk but there have been a number of recent developments from Raytheon that make it an interesting choice.

In April 2014, Raytheon announced their intent to test a new multi mode seeker for the Tomahawk;

Completion of this test and last year’s passive seeker test will demonstrate that Tomahawk can hit moving targets on land and at sea. Raytheon is working to quickly and affordably modernize this already advanced weapon for naval warfighters
This new seeker is intended to deliver greater precision and and alternative options for both land AND sea targets. The enhancement programme will also upgrade the communications and warhead. The Block IV missile has a two data link. In October 2015, the planned test was completed and the missile hit a moving target at sea after receiving targeting data from an aircraft.

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In January 2016, Raytheon conducted a captive flight test of an active mode seeker that will provide an ability to attack moving targets at sea and on land.

A recent contract award saw Raytheon deliver 144 Tactical Tomahawk Black IV all-up missiles to the USA for $122 million.

There is still a lot of life left in Tomahawk.

With a range in excess of 1,000 miles, a Type 26 GCS with a Block IV enhanced Tomahawk would provide a powerful and flexible capability against land and sea targets.

SCALP

Although SCALP would have to be integrated with the Mk41, with the UK the likely lone customer for such a combination, SCALP would provide at least some measure of commonality with the MBDA Storm Shadow stand-off cruise missile currently being integrated onto the Typhoon. More specifically, the maritime version is called Missile de Croisière Naval (naval cruise missile) or MdCN, currently carried by French FREMM frigates.



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Not sure this is a realistic contender but included for completeness.

There has been some concept work from MBDA on the Perseus missile as a potential Storm Shadow/SCALP replacement (SPEAR CAP 5), whilst undoubtedly an impressive concept, the appetite for funding its development seems low. MBDA have also proposed their Hoplite family of missiles for the land attack role, also FLEXIS and STRATUS

As Anglo-French cooperation deepens in the complex weapon portfolio, these studies may well be taken forward into a more formal joint UK/French programme to replace Storm Shadow/SCALP and Harpoon/Exocet. France seems unlikely to adopt Mk41 and the UK will not be putting SYLVER on Type 26 which complicates matter somewhat, at the very least, increasing integration costs



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Although there has been little news on the possibility of UK-France joint development the 2016 Summit did describe an intent to co-develop a joint concept phase for the Future Cruise/Anti-Ship Weapon (FC/ASW) programme.

Storm Shadow will be subject to a Mid-Life Refurbishment (MLR) that will meet the SPEAR Capability 4 requirement, with a currently planned start date of 2017. This will take Storm Shadow to it’s planned out of service period of around 2030, when it will be replaced with the SPEAR Capability 5 system, nominally, the UK/France Future Cruise and Anti-Ship Weapon (FCASW) / Futur Missile Antinavire/Futur Missile de Croisière (FMAN/FMC).

A three-year Concept Phase contract will possibly be awarded to the end of 2016 for FCASW.

The conundrum here is that if this FCASW missile is developed for a Storm Shadow and Harpoon/SCAL-EG replacement, what silos will it be integrated with?

It seems unlikely France will invest in Mk41 and unless Type 26 is fitted with SYLVER, the missile will need to be integrated to with both VLS

Joint/Naval Strike Missile

The Naval Strike Missile from Kongsberg is an anti-ship and land attack missile. It will be integrated onto the F35 as the Joint Strike Missile so commonality benefits could be realised if we chose to purchase it for the F35’s, unlikely, but it is an option. With a 150km range the NSM weighs 400Kg with a 125kg warhead and can attack a mix of land and surface targets, click here to read about its development path.

The NSM has been criticised by some because it is not hypersonic but I think that is misplaced, the NSM has taken a reasonable line with regards to balancing capabilities against cost and development time, the seeker is reportedly very advanced and low its signature is a valuable feature when faced with a plethora of anti-missile weapons. It would be a great addition to the RN and RAF armoury but whether it would find a place in the equipment programme with the Complex Weapons initiative commercial complications are another matter.

Most images of the NSM show it being launched from an inclined box launcher but there has been some interest from Kongsberg in JSM Mk41 integration, details are scarce, the best at navy Recognition here.

Integrating JSM with a Mk41 VLS would offer a modern and highly capable missile that would provide some commonality if the UK chose to equip it’s F-35B’s in the future, although smaller and shorter ranged than Tomahawk, it would be useful if both were available.

Long Range Anti-Shipping Missile (LRASM)

Whilst a development of Tomahawk is clearly the low-risk choice the new kid on the block is the Long Range Anti-Shipping Missile (LRASM) from Lockheed Martin. It is described as;

LRASM is a precision-guided anti-ship standoff missile leveraging off of the successful JASSM-ER heritage, and is designed to meet the needs of U.S. Navy and Air Force warfighters. Armed with a penetrator and blast fragmentation warhead, LRASM employs precision routing and guidance, day or night in all weather conditions. The missile employs a multi-modal sensor suite, weapon data link, and enhanced digital anti-jam Global Positioning System to detect and destroy specific targets within a group of numerous ships at sea. LRASM will also employ enhanced survivability features to penetrate advanced integrated air defense systems. The combination of range, survivability and lethality ensures mission success. LRASM technology will reduce dependence on ISR platforms, network links, and GPS navigation in aggressive electronic warfare environments. The routing and guidance capabilities of LRASM allows it to safely navigate to the enemy area, where the weapon can use gross target cueing data to find and destroy its pre-determined target in denied environments. Precision lethality against surface targets ensures LRASM will become an important addition to the warfighter’s arsenal.
BAE are responsible for the sensor system.

Clearly, it is focussed on the anti-shipping Harpoon replacement role, not land attack.



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Where Tomahawk is the low-risk option and likely cheaper, LRASM provides a more survivable option against enemy forces that have the ability to shoot down cruise missiles, a classic trade-off. If it is integrated onto the F-35 by the USA then there will be two anti-ship missile options, the LRASM and JSM. Whilst neither have the range and punch of Tomahawk, both would be much more survivable, LRASM comes ready for Mk41, JSM doesn’t, that said, JSM has demonstrable capability against land targets, LRASM doesn’t, yet.

It has been reported that the LRASM is also being developed in a topside launcher.

Decisions decisions, but first, let’s see the budget!

Vertically launched torpedoes are also available for the Mk 41 VLS and MBDA have suggested Mk41 could be used for SPEAR Capability 3

Land and surface attack missiles remain an area of uncertainty for Type 26. There is a danger that the Type 26 VLS will be filled with nothing but fresh air, a somewhat embarrassing development. This even places under doubt the likelihood of Type 26 being fitted with a VLS at all.

Guns
The new images show both M2 and Dillon Aerospace M134 Miniguns (Mk44) in 12.7mm and 7.62mm calibres respectively. Given that GPMG and the M3M will be fitted to Wildcat and Merlin it would make sense if the M3M were available on simple pintle mounts as well as the M134 minigun.
 
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Fitted to both the Type 45 and Type 23 are MSI 30mm automatic cannon systems and 20mm Phalanx Close-in Weapon System (CIWS), again, these feature in the latest graphics of Type 26

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The MSI mounts have a long heritage with the first designs being introduced in the early eighties with the 30mm RARDEN cannon. In the mid-eighties, the Royal Navy selected the Oerlikon 30 mm KCB to replace all existing 20mm and 40mm automatic cannons as a post-Falklands lessons learned exercise. First entering service in 1988 they have been continually refined and the latest version is the DS 30B Mk2 equipped with offboard sensors, the ATK 30mm Bushmaster Mk44 cannon (instead of the Oerlikon) and Seahawk fire control systems that are replacing all previous versions on Type 23 by 2014 in a £15m contract with MSI.

It is officially called the Automated Small Calibre Gun (ASCG)



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This presentation from DSTL provides some background information on inner layer defence against fast attack craft and similar vessels.

There has been some discussion about swapping the Bushmaster Mk44 for the 40mm CTA cannon that will be installed on the Army’s FRES and Warrior vehicles. Normally, I am all for ruthless commonality and would think this is generally a good idea, not least because of the extra punch, and sharing of support costs as the Mk44 is unique to the RN in the British armed forces, but swapping would not be simple or cheap. The weapon, fire control and each ammunition nature would need to be certified for naval use in a highly complex EM environment, the fire control system modified and the mount completely changed to accommodate the CTA’s unusual feed mechanism. ATK also manufacture an air bursting nature, the PABM-T, should that be deemed worthwhile and negates one of the stated advantages of the CTA cannon. If commonality were a driver then we might also look at the M230LF used on the Apache attack helicopter.

Extra cost for marginal benefit, so not sure it would be worth it.

The Raytheon Phalanx is a multi-barrel close in weapon system primarily for use against anti-ship missiles although it retains some capability against surface targets.







UK Phalanx has been variously upgraded, used on trailer mounts for C-RAM in Iraq and Afghanistan and converted back to the maritime role. The latest version is the 1B that upgrades a number of components and adds a visual cueing and tracking system for use against surface targets. In addition to providing the 1B upgrade, Babcock has a ten-year support contract for the 36 Phalanx systems, based on providing availability of the systems throughout their life on board ship.

On Type 26 GCS, the Phalanx position has changed with each graphic and the latest version shows them in the same position as on Type 45, one on each side.

Many think the 20mm Phalanx only has marginal effectiveness against the latest generation of anti-ship missiles but it does provide valuable assurance and as part of a layered defence, seems like a sensible inclusion.

It also provides an upgrade path to directed energy weapons, the Raytheon Defender for example uses the Phalanx mount but replaces and/or augments the gun with a high energy solid state laser. The US Navy is engaged across a number of demonstration programmes for laser weapons and in October 2015, awarded a contract to Northrop Grumman Solid State High Power Laser Weapon System Demonstrator (LWSD) program. The Royal Navy and DSTL has initiated a number of exploratory programmes to start looking at the potential for laser weapons. A trip to Red Bull by Admiral George Zambellas to look at F1 Motorsport Kinetic Energy Recovery Systems (KERS) gives us a clue to what is perhaps the greatest challenge, energy storage, not generation.







It seems unlikely that Type 26 will be fitted with laser weapons on initial build.

After much speculation and competing bids from Oto Melara/Babcock, the BAE GCS will feature a BAE Mk45 Mod 4 medium calibre gun system.

The Future Maritime Fires Concept Phase completed a few years ago, no doubt lessons from Libya (where HMS Liverpool fired over 200 rounds of 4.5” ammunition) will have played a large part in informing the study. With the cancelling of the BAe 155mm TMF project that used the gun system from the As90 Self Propelled Gun, the choice of a naval gun narrowed.

Question
Julian Lewis (New Forest East, Conservative)

To ask the Secretary of State for Defence what his policy is on the replacement of existing warship guns by ones of 155mm; and if he will make a statement on his policy, with special reference to (a) the future frigate fleet and (b) Type 45 destroyers.

Answer

Peter Luff (Parliamentary Under Secretary of State (Defence Equipment, Support and Technology), Defence; Mid Worcestershire, Conservative)

No decision on the calibre of the new Maritime Indirect Fire System (the new naval gun) has yet been made. This will be taken when work to consider the available options under the Future Maritime Fires Concept Phase is complete in around mid-2012.

The Maritime Fires Concept, of which the Maritime Indirect Fire System (MIFS) is a part, is being delivered in conjunction with the Niteworks Partnership and is expected to be met by a medium calibre gun (MCG). The other part of MFS is the Maritime Indirect Fire Precision Attack (MIFPA) is expected to be delivered using missile systems, potentially Fire Shadow, although the status of the latter would seem to preclude this option going forward.

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Naval Gunfire Support has a great deal of utility and used much more often that many of the more esoteric systems, the Falklands, Iraq and Libya being recent outings; it is much cheaper than using air-delivered munitions if circumstances permit and can use a graduated force model where a well-aimed smoke or illumination round that signals loud and clear the next one will be of the type that goes bang can influence subsequent activity or neutralise threats both on land and at sea.

The existing 115mm/4.5” Mark 8 Mod 1 gun aboard Royal Navy vessels has its origins in the late sixties and has given excellent service but how reliable they are now is apparently an open question. The HE Extended Range round uses base bleed to propel the round to a maximum range of 27.5km and the existing illumination nature is also still available. In order to maintain a sustained rate of fire of 16-20 rounds per minute and accommodate the more powerful ammunition types the barrel is 62 calibres long. It has seen extensive service including action off the Falkland Islands (8,000 rounds), Iraq and Libya.

The Mark 45 Mod 4 from BAE, as used by the US Navy, South Korea, Denmark, Australia and others, is a 5”/127mm system with a 62 calibre barrel and is capable of a rate of fire up to 20 rounds per minute, the magazine will contain 196 rounds.

BAE describe it as;

The 5-inch (127-mm) 62-caliber Mk 45 Mod 4 Naval Gun system is in U.S. Navy and Allied service today, and is ready to significantly enhance Naval Surface Fire Support (NSFS) and overall mission performance. Major upgrades of the Mk 45 Mod 4 include a 62-caliber barrel, strengthened gun and mount subsystems, advanced control system enhancement, and a reduced signature, low maintenance gun shield. The Mk 45 Mod 4 provides NSFS range of more than 20 nautical miles (36 km) with the Navy’s new 5-inch Cargo projectile and an improved propelling charge. Operation and performance of extended-range munitions are tailored for optimal effect and range in unison with the major subsystem upgrades of the Mk 45 Mod 4 Naval Gun.
A large installed base allows development costs of precision, proximity, IR illumination or smoke natures to be spread across many users. Adopting such a widely used system means natures such as IR Illumination are immediately available without expensive development programmes.



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The magazine and palletised handling system will be a new design for the Type 26, taking the existing arrangement and adding improvements derived from the DDG-1000 programme.

Type 26 GCS doesn’t necessarily need the precision guided ammunition straight away, the existing Mk45 Mod 4 will provide a modern, accurate and powerful weapon system in its own right, again, another system much improved over Type 23. However, if there is a requirement for precision and additional range, options exists, albeit ones not yet completely in service in the maritime domain.

There are a couple of options for extended range and precision effects, Raytheon with their Excalibur and BAE, the Multi-Service Standard Guided Projectile.

Raytheon has recently successfully fired their 5″/127mm Excalibur N5 precision guided projectile from a Mk 45 test mount.

From the press release;

Excalibur N5’s range, precision and lethality will revolutionize naval gunfire and increase the offensive firepower of our Navy’s destroyers and cruisers. This demonstration showcases the N5’s maturity as a proven low-risk solution, and is ready for the Navy now. Excalibur N5 can be used to support several critical mission areas including Naval Surface Fire Support, Anti-Surface Warfare (ASuW) and countering Fast Attack Craft (FAC). With the significant amount of re-use from the Army’s Excalibur program, the N5 provides the Navy with an affordable, direct path to employ a critical capability, We continue to build on Excalibur’s unmatched reliability and performance by investing in a fire-and-forget, dual-mode seeker that will vastly improve the 5-inch gun’s current ASuW and counter-FAC capability.
Using technology from the 155mm Excalibur, the company funded N5 may well find its ways onto Type 26, it has a range in excess of 25 nautical miles with the same accuracy of the in service Excalibur 1b. Raytheon are also developing a dual mode seeker allowing the shell to be guided to target by a laser designator.

In competition with Excalibur is the BAE MS-SGP.

This is a rocket assisted projectile with a longer range than Excalibur N5, over 50 nautical miles. The Mk 45 Mod 4 can fire 10 rounds per minute and 3 rounds within 2 seconds for Multiple Round Simultaneous Impact fire missions if needed. Each round weighs 50kg with an explosive content of 16kg.



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The cost of an Excalibur 1B is reported to be $68,000, with a very high degree of commonality between the 155mm and 127mm versions. This opens up the potential for economies of scale between the British Army and Royal Navy for precision fires, even accepting the different calibres.

Raytheon are also developing a millimetric radar guidance systems for N5, specifically for attacking small boats in poor weather without external designation.

Whether the UK takes any of the options and if so, when, is open for discussion, but at least there are relatively low-risk options available, although, as mentioned above, none is yet in full naval service.

Decoys and ECM
Countermeasures are not often discussed but are advancing all the time and many consider them more effective at protecting against anti-ship missiles than CIWS.

The fixed multi-barrel DLH Launcher as part of the Seagnat system is used to launch a variety of decoys that attempt to confuse, lure away and break the lock of incoming anti-ship missiles. In response to radar and other warning devices, they will launch a pattern of decoys controlled by the ALEX system, used in conjunction with ship manoeuvre to protect the ship.

The Royal Navy and other naval forces have a wide range of decoy or soft kill protection systems (not just from Chemring) but whist the rounds themselves have advanced the launchers have not. There has been some press chatter about using the Chemring Centurion trainable launcher but this does not seem to be on the Type 26 GCS imagery.

Active RF Decoy

In 1994 GEC Marconi were awarded an £80m contract to develop their Siren system to fulfil the Royal Navy ‘Outfit DLH’ requirement. It was designed to seduce inbound anti-ship missiles using a launched RF countermeasure (Mk 251 Active Decoy Round) fired from standard 130mm SeaGnat launchers. The system was also to utilise the existing Seagnat launch control systems, 21 ship sets and 720 rounds were obtained with the final cost being in the order of £103m. It did not enter service until 2004, 10 years after contract award, replacing SeaGnat DLB and DLJ(2).

The product description is;

Siren is an advanced decoy system designed to protect ships from missile threats by luring incoming anti-ship missiles away from their target. Launched from a 130mm decoy launcher it uses a two stage parachute system which slows the decoy round down at a pre-programmed time before deploying a second stage parawing, under which the advanced programmable electronic payload descends to detect and counter the missile threat. The ability of Siren to generate sophisticated jamming waveforms is unique amongst the worlds limited types of naval decoys. The Siren payload contains some of the most up to date RF, digital and analogue electronic circuitry available, enabling the round to quickly detect, identify and track threats to ships. Siren is able to handle multiple threats simultaneously even in dense RF environments.
 
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Siren eventually passed to BAE and then to Selex, a Finmeccanica company. Type 23 Frigates use the Mk 251 Siren so again, a straight transfer to Type 26 GCS might be the most appropriate solution.



A joint UK/French programme called ACCOLADE is investigating advanced RF decoys.

RF and Infra Red Distraction Decoys

In addition to the advanced Mk 251 Siren, the RN Outfit launcher systems can also use RF distraction (chaff) and IR decoys such as the Chemring Mk 216 Mk 1 Mod 1 and Chemring Mk 245 IR. The Royal Navy has replaced the Mk 245 IR round with the Chemring TALOS that uses variable timing and submunitions rather than a single round, called the A2, as in the image below.



Fitted to the Type 45 is the Airborne Systems IDS300 (now called the FDS3) inflatable RF decoy also looks like it will be fitted to Type 26 GCS, the launchers are the horizontal cylindrical devices adjacent to the missile silos.



The FDS3 is a self-inflating octahedral shaped corner reflector that floats on the surface and unlike chaff, is persistent, able to float for 3 hours in sea state 4







It is a simple and low-cost system, in service with many naval forces.

Electronic Countermeasures

Type 23 Frigates are fitted with the Thales Scorpion 2 Radar Electronic Countermeasures system. Taking information from the integrated ESM system it denies enemy forces the use of their radars; aircraft, ship, missiles, fixed or vehicular mounted device



Type 26 GCS imagery suggests a pair of these will be fitted.

There is also a current programme that merges electronic surveillance and countermeasures programmes into a single programme, Maritime Electronic Warfare Programme (MEWP).

As the threat from small UAS increases, systems such as the AUDS C-UAS may well find their way onto future vessels.

Torpedo Defence

Entering service with the Royal Navy in 2004 and replacing the NIXIE system, the Ultra Electronics Surface Ship Torpedo Defence system provides protection against ship or submarine launched torpedoes, again, it would seem the system will be transferred to Type 26 GCS.

The system, now called Sea Sentor, is described as;

The SEA SENTOR™ Surface Ship Torpedo Defense system has been in-service since October 2004, protecting fleets from the increased threat of torpedo attack. With 16 systems delivered to the UK’s Royal Navy, installations on US naval platforms and a recent order by the Turkish Navy, SEA SENTOR™ is the most advanced system available in the market today. The SEA SENTOR™ system utilizes a towed acoustic passive array especially designed for the detection of torpedoes to classify and localize in-water threats. Tactical advice is presented by the system that is specifically geared to the make, model and current operating mode of the detected threats – single or salvo. Detection ranges to initiate successful defeating tactics are achieved in all conditions; whether operating solo in deep water or in-convoy in busy shipping lanes and littoral waters Countermeasure action is automatically performed according to the tactical advice for the towed system elements. Expendable countermeasures are launched by the operator when prompted to do so.
System components are (from Wikipedia);

  • an acoustic passive towed array
  • a towed acoustic countermeasure (flexible)
  • a single-drum winch
  • a processing cabinet
  • 2 display consoles
  • 2 expendable acoustic device launchers (1 port, 1 starboard)
  • 16 expendable acoustic devices (8 in each launcher)
The system is also in service with a number of other nations and active torpedo ‘hard kill’ interceptor is in development.







The lack of lightweight torpedo launchers seems a curious omission from the information released so far.

Aircraft and Unmanned Systems
The flight deck will be of sufficient size to handle large helicopters like Merlin and especially, Chinook. Although not an amphibious assault ship, Chinook compatibility is good for all manner of operations that require heavy lift.

The main embarked aircraft for the ASW variant will be the Merlin HM2, the ‘airborne frigate’

The Merlin HM2 will normally be carried by the Type 26 although the naval Wildcat and CHF Merlin may also be used depending on requirements. The HM2 version on the Merlin is an incredibly powerful and sophisticated system that is combined with the numerous capabilities of the Type 23 to create a formidable team, likely to be transferred to Type 26 GCS.





Lockheed Martin - Merlin Mk2 Helicopter Takes Part In Royal Navy Exercise Deep Blue [1080p]







Merlin can launch the Stingray Lightweight Torpedo and can carry a Minigun or M3M machine gun. Wildcat can also launch Stingray and carry GPMG and M3M but will also be able to carry the Sea Venom (replacing Sea Skua) and Martlet missiles. The two-way datalink equipped Sea Venom is for use against small to medium sized combat vessels and Martlet, small craft and RHIB’s.







The Boeing/Insitu ScanEagle has an interesting history, initially designed to assist tuna fishing fleets it has evolved into a mature, low cost, flexible and highly effective family of vehicles and payloads. After a 2006 trial with HMS Sutherland, the Royal Navy contracted for an extended trial period with Scan Eagle and it has proven to be very valuable during operations in the Gulf. There is also a larger version called the RQ-21 Blackjack, or Integrator.

A number of losses have been experienced and the extended trial has now been terminated.

A number of technology programmes have since been launched including the establishment of 700X NAS that focuses on unmanned aircraft and trials of 3D printed systems from Southampton University in the UK and on HMS Protector in the South Atlantic.





HMCS Toronto deploy Boeing Insitu ScanEagle UAV - Operation Artemis 2013







The RN also let the Rotary Wing Unmanned Air System (RWUAS) Capability Concept Demonstrator (CCD) contract in 2013.

The purpose of this contract was;

to understand whether a multi-role Rotary Wing Unmanned Air System (RWUAS) can provide utility in the Mine Counter Measures (MCM), Hydrography & Meteorology (HM), Offensive Surface Warfare (OSuW) and general Situational Awareness (SA) capability areas.
Further details on the programme were detailed in the contract notification;

A CCD seeks to investigate issues with the use of relatively mature technologies and does not involve significant equipment development or integration. DE&S and Dstl previously conducted a Scoping Study which identified the potential of a small (100 – 1000kg) or medium (1000 – 3000kg) Rotary Wing UAS to deliver the maritime capabilities being sought. The CCD will need to assess platform integration issues and the impact across the Defence Lines of Development (DLoDs) of bringing an RWUAS into service. DE&S intend to progress to the demonstration & analysis phase of the CCD which is expected to involve a package of physical demonstrations of a vertical take-off and landing (VTOL) UAS and specialist sensors, supported by simulation and synthetic environment experiments. Interested parties were advised to note the CCD is not intended as a test of a particular system and does not form part of a current acquisition programme. Rather it will inform future maritime UAS requirements, potentially leading to an acquisition programme in the second decade. DE&S expects the UAS (Vehicle, Control Station & Comms Link) that is offered to be suitably mature (TRL 7 or above) to undertake the demonstration activities with a low probability of delay due to unplanned maintenance or technical issues. Specialist sensors and payload systems at TRL 5 would be acceptable as DE&S recognises that the capabilities being investigated are novel and the technologies may not be mature yet. The CCD is also interested in identifying and assessing future sensor technologies of lower TRLs that are not ready for demonstration but may be suitable for simulation or other activities.
AgustaWestland was selected as the prime contractor for this programme, perhaps unsurprisingly given their position at the centre of the UK Rotary Wing Strategy. It was also interesting to see that Mine Counter Measures (MCM) and Hydrography & Meteorology (HM) were included in the scope of the £2.3 million contract.



AW proposed to use the SW-4 Solo fitted with flight control systems from Thales, the same system also used for trials for the Italian MoD.
 
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