Title: Joint ACCESS
1Joint ACCESS
High Speed Assault Connector
TSSE Design Team
Naval Postgraduate School
December 2, 2004
2(No Transcript)
3TSSE Team
- TSSE Staff
- Prof. Fotis Papoulias
- Prof. Bob Harney
- 2004 Design Team
- LT Timothy King, USNR, ECE
- LT Steven Peace, USN, SEA
- LCDR Paco Perez-Villalonga, ESP, OR
- LT Derek Peterson, USNR, MAE
- LT Rolando Reuse, CHL, MAE
- LT Scott Roberts, USN, MAE
LTjg Kivanc Anil, TUR, MAE LTjg Mehmet Avcu, TUR,
MAE LT Jon Brisar, USN, PHY LTjg Adnen Chaabane,
TUN, IW LTjg Sotirios Dimas, GRC, MAE LT Matt
Harding, USN, MAE
12 Students 6 Countries 6 Departments
4Todays Agenda
Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
5The Request
- A conceptual design for a High Speed Assault
Connector (HSAC) to enhance Joint Expeditionary
Logistics (JELo) flow from the Sea Base to shore - Augment or replace existing connector platforms
- Employment requirement
- Cargo 8000LT of vehicles, troops, and gear
- Distance 200nm from the Sea Base to shore
- Time 10 hours
- Sea state 4
- Interface accept cargo and troops at the Sea
Base and deliver to shore
6The Design Solution
- A system of 12 HSACs that fill all the previous
connector requirements - Each HSAC is multi-mission capable,
self-sustaining, and - Can accommodate embarked troops, cargo, and gear
from FLS and or/CONUS to the Sea Base - Can transit 2000nm _at_20kts (fully loaded) w/40
fuel remaining - Has defensive and offensive combat capabilities
7Introduction
Mission Flexibility
Manning/ Habitability
Summary
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
8Initial Requirements
- SEA-6
- Transport JEB from the Sea Base to shore
- Time limited to a 10 hour period
- Interface with Sea Base, developed ports, and
austere beaches - TSSE Faculty
- Support amphibious operations ashore in addition
to delivering payload - Conduct secondary missions
- Capable of independent operations
9Assumptions
- HSAC will move entire surface component of JEB
- 2 Battalion Landing Teams (BLT)
- HSAC fully loaded prior to employment phase
- HSAC transit protected by the Sea Shield provided
by Sea Base forces - Landing operations will be conducted in reduced
threat environments - Boat lanes will be mine free
10Beachable/Non-Beachable
- Considered two delivery methods
- Beachable
- Non-Beachable (LCAC ferry)
- Conducted feasibility study on both
11Non-Beachable Feasibility
- Pros
- Information readily available
- Few tactical changes required
- Improves effective LCAC range
- Proven, beachable, high-speed connector
- Cons
- Large number of LCACs required
- LCACs approaching end of service life
- Inadequate availability/reliability
- Additional interface in the loop
12Beachable Feasibility
- Analysis of Newport class LST
- 3000LT payload
- 16 ft draft
- Bow ramp and stern gate
- Pros
- Performed similar mission
- Large craft can be made beachable
- Newer technologies will greatly enhance the
capabilities of previously proven designs - Provides a single connector solution
- Cons
- Structural issues for bow ramp/beaching
- Possibly hull form limiting
- Beachable design selected
13Analysis of Alternatives
- Developed 3 Measures of Performance (MOP)
- Analytic Hierarchy Process (AHP) was used to set
the weights - Transport factor 43
- Survivability 43
- Number of ships 50
- Overall ship length 30
- Speed 20
- Mission flexibility 14
- Payload 30
- Draft 30
- Number of ships 20
- Speed 20
- Overall MOP weighted sum of the individual MOPs
14Design of Experiments
- 7 x 9 x 5 Design matrix
- 7 different hull types
- 9 different payloads
- 5 different speeds
- Total of 315 possible designs
- Initial ship characteristics calculated using
software from Maritime Applied Physics
Corporation at MIT
15(No Transcript)
16AoA Score Criteria
- 315 designs were evaluated using TSSE generated
MOPs - 292 designs were eliminated based on these MOP
score criteria - Average MOP lt 0.4 (REJECT)
- (MOPmax MOPmin) gt 0.05 (REJECT)
- Average gt 0.45 or passes tests 1 and 2 (ACCEPT)
- 23 remaining designs were plotted vs. cost to
determine the optimum design
17AoA MOP vs Hull Type
18AoA MOP vs Cost
Better
19Sensitivity Analysis
- Same 3 Measures of Performance (MOP)
- Transport factor 33
- Survivability 33
- Mission flexibility 33
Trimaran
Better
20Beachable Trimaran
- Beachable design
- Smallest average draft (17ft)
- Greatest number of retained alternatives
- Highest overall MOP among hull types
- For each speed
- For each payload
- Highest overall MOP for one of the lowest costs
- Only cheaper alternatives were HYSWAS and a point
solution monohull, both with deep drafts
21Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
22Cargo Requirements
- Transport surface components of 2 Battalion
Landing Teams
- 204 Humvee
- 98 EFV
- 21 M1A2
- 4 AVB
- 2 AVLB
- 8 M9ACE
- 2 M88A2
- 16 ITV
- 10 Avengers
- 38 MTVR
- 12 LW155
- 16 M105
- 6 MK155
- 34 M101
- 2 M149
- 2 M116
- 2 AN/TPQ
- 8 4K Forklifts
- 4 Contact trucks
- A total of 546 vehicles delivered in first 10
hours
23Cargo Distribution
- One BLT can be transported on 6 ships
- Provides for mission scalability
- Provided greater load-out flexibility
- Vessel load-outs
- Load-outs fell below maximum payload
- Maximum design payload 800 LT
- Heaviest load-out 693 LT
- Average load-out 663LT
24Cargo Distribution
- Distribution of (1) BLT aboard (6) HSAC
25Cargo Interfaces
- Stern gate/ramp
- Cargo decks
- Flight deck elevator
- Bow ramp
26Stern gate
- Allows interface with Sea Base and pier via
Mediterranean mooring - Hydraulically operated
- 120 degree range of motion from vertical to
partial submersion - Supports deployment/recovery of EFV
- Can be accomplished with current RO-RO technology
27Stern Gate Loading
28Stern Gate EFV Deployment
29Cargo Layout
- Upper and lower cargo deck
- Heaviest equipment stored on lower deck and
centerline of upper deck - M1A2, EFV, ABV, M88ACE, AVLB
- Lower deck access from stern gate and bow ramp
- Upper deck access from forward and aft fixed
ramps - Ventilation system on both decks will handle
removing vehicle exhaust from the ship
30Cargo Layout
31Flight Deck Elevator
- Flight deck supports CH-53X, MV-22, and SH-60R
- Hangar for 1 SH-60R
- Elevator provides access to flight deck from
cargo decks - Allows vertical replenishment of oversized and
palletized supplies - Allows vertical delivery of vehicles/equipment
from cargo decks to shore - Supports use of upper cargo deck as hangar for
multiple SH-60R (BLT not embarked)
32Cargo Layout
33Bow Doors
- 5m x 6.2m opening in bow
- Facilitates ramp deployment and vehicle offload
- Doors constructed from composite materials
- High strength, low weight
- Hydraulically actuated
- Eliminates hinges
- Reduces the amount travel required for opening
- Watertight door aft of bow doors ensures
watertight integrity - Armored to provide protection during landing ops
34Bow Doors
35Bow Ramp
- Sectional floating causeways
- Maximum deployed length 35m
- (8) 5m x 5m x 1.6m sections
- Allows variable deployment length
- Supports maximum load of (2) M1A2 Tanks
- Stored below lower cargo deck
- Mechanical deployment and recovery
- Deployment/recovery rate .2 m/s
- Maximum length deployment 3min
36Bow Ramp
37Bow Ramp
38Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
39Hull Form Trimaran
- Pros
- Low resistance
- Large deck area in upper decks
- Enhanced stability
- Cons
- Little information available higher risk
- Less space in lower decks
- Limited bow ramp width
40Trimaran Feasibility
- Existing or projected trimarans
- Length/beam ratio 13 - 15
- Froude number 0.4 0.5
- Payload 30 - 40 displacement
- Overall length 140 - 160m
http//www.gomeralive.de/fred-olsen.4021.0.html
41Alternative Center Hull Forms
- Hull form A
- Lowest wave resistance
- Deepest draft
- Hull form B
- Minimal wetted surface
- Intermediate draft
- Intermediate beam
- Hull form C
- Greatest wave resistance
- Lowest draft
42Selected Hull Form
- Wetted surface 4300m2
- Length 149m
- Beam 13m
- L/B 11.5
- Froude number .51
- Draft 4.5m
43Draft Constraint
- Slope 130
- Parabolic keel line
- Reduced forward draft
44Calculations
- Hydrostatics
- Cross curves
- Tankage
- Stability
- Damaged stability
45Structure
46Reality Check
47Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
48Electric Drive
- Pros
- Increased flexibility over mechanical drive
- Long drive train not required
- Prime movers location not restricted
- Power available for other uses
- Increased fuel efficiency
- Cons
- Not proven
- Electric drive selected
49Resistance Calculations
50Power Requirements
- Combat systems and other electric loads 2 MW
- Propulsion
Speed (kts) Power (MW)
10.95 0.88
16.43 3.29
21.91 10.37
27.39 16.31
32.86 26.35
38.34 40.35
43.82 58.25
Total power for 43 knots 60 MW
51Propulsion AoA
- Propulsion plant alternatives
- Conventional steam
- Nuclear steam
- Fuel cells
- Diesels
- Gas turbines
- Gas turbines selected
- Power/weight
- SFC
- Efficiency
- Reliable, proven technology
52Prime Mover AoA
- Prime mover alternatives
- ICR WR21
- LM1600
- LM2500
- LM2500
- MT30 Trent
- (2) LM2500 selected
- High power/weight
- Low volume
- High power
- Low SFC
53MT30 vs. LM2500
54Propulsor AoA
- Propeller alternatives
- Propeller
- Conventional waterjet
- Bird-Johnson AWJ21
- AWJ21 selected
- High efficiency at high speeds
- Efficient at low speeds also
- Reduced cavitation
- Reduced size and weight
- Station-keeping
55Bird-Johnson AWJ21
Propulsor AWJ21
Source http//www.rolls-royce.com/marine/download
s/pdf/propulsion/birdawj21.pdf
56Propulsor AWJ21
Source http//www.rolls-royce.com/marine/download
s/pdf/propulsion/birdawj21.pdf
57Propulsion Motor AoA
- Propulsion motor alternatives
- Conventional motors
- HTS AC synchronous motors
- DC super conducting homo-polar motors
- HTS AC synchronous motor selected
- Smaller size
- Lighter weight
- Acceptabletechnologicalrisk
Source Email with Matthew OConner, Sales
Manager, American Superconductor Corporation,
November 18, 2004
58Engine Room Layouts
59Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
60Electric Power System
- 2 LM2500
- Produce required underway power
- 58MW for propulsion
- 2MW for C/S and hotel loads
- 1 Allison AG9140
- Produces in port power
- Available for backup power
61Electric Distribution
- Port starboard AC buses
- 13.8kV
- Drive the HTS AC synchronous motors
- Power port starboard DC buses
- DC Zonal distribution
- Port starboard DC busses
- 1100V DC
- 6 Zones
62Electric Distribution
DC Zone 1
SSCM
Motor Controller for Bow Ramp
PS
PS
SSCM
Allison AG9140
63DC Zonal
- Simplified fault isolation
- Generator frequency decoupled from distribution
equipment - Survivability
64DC Zones
Zone 6Superstructure
Zone 2CSER 1
Zone 4ER 2
Zone 5 Aft ER
Zone 1Bow Ramp
Zone 3ER 1
65Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat System
Cargo
Damage Control
Hull
Electrical
Propulsion
66Installed Damage Control Systems
- Systems installed
- FM200
- CO2
- Water mist
- AFFF
- Spaces of high importance
- Flight deck
- Cargo decks
- Machinery spaces
67HSAC Fire Main
68Damaged Stability
- Damage extension
- 3 Forward double bottom
- ½ Side hull
69Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
70Threat Engagement Zones
- Open ocean to 25 miles from off-load zone
- 25 miles to 1 mile from off-load zone
- Less than 1 mile from off-load zone
Transit Zone
Loading Zone
Unloading Zone
Beach
- Small Boats
- Aircraft
- Missiles
- Small Arms
- Missiles
- Aircraft
- Small Boats
- Submarines
- Hostile
- Missiles
- Small Arms
- Aircraft
1nm
200 25 nm
25 1 nm
71Defense Perimeters
72Outer Layer
- Highly reliable on effective Sea Shield
protection - Advantage of distributed multiple platforms for a
combined blanket of protection for increased
survivability - Cooperative Engagement Capability (CEC)
- Multi-Function Radar (MFR)
73Cooperative Engagement Capability
- System of hardware and software that allows the
sharing of radar data on targets among ships. - Each ship uses identical data processing
algorithms resident in its cooperative engagement
processor (CEP), resulting in each ship having
essentially the same display of track information
on aircraft and missiles.
74MFR
- Multi-Function Radar
- Essentially the SPY-3 radar currently in
development - 3D system capable of both air and surface
detection and tracking - Fire control radar and missile control through
mid-course guidance and terminal homing - Optimized for the littoral environment
- Superior clutter rejection
75MFR
Source TSSE 2003 Final Report
76Middle Layer
- Evolved Sea Sparrow Missile (ESSM)
- Electronic Warfare (EW) suite
- Electro-Optical (EO) System
77Missiles
- Primary Mission Self Defense
- Secondary Mission Cargo Transfer Protection
- An AOA was conducted for a selection of short
range missiles that can engage - Large spectrum of anti-ship cruise missiles
- Surface threats
- Aircraft (to include low slow flyer)
Source http//www.fas.org/man/index.html
78Missiles AOA
10
Joint vision concept 10
8
Maneuverability 15
Overall MOP
Cost 10
6
Quantity 20
4
Size 5
Range Min 20
2
Range Max 20
0
ESSM
RAM
SM-2
79Missiles ESSM
- Very capable against low observable highly
maneuverable missiles - Adequate range for middle layer defense
- Max range 30 nm
- Min range 1400m
- Flight corrections via radar and midcourse
uplinks - MK 48 Mod0 VLS launcher was a perfect fit for
placement within trimaran side hulls - Number deployed 32 (16 port / 16 stbd)
80EW Suite (AN/SLY-2(V))
- Advanced Integrated Electronic Warfare System
- Navys next generation shipboard E.W. system that
supports the Joint Vision 2010 concept of
full-dimensional protection - Designed for layered and coordinated
countermeasures in the littoral environment - Provide final layer of self-protection against
air threat leakers and ASCMs for individual ships
- Electronic Support (ES)
- Increased tactical awareness
- Early threat detection
- Advanced on board RF and IR countermeasures
81EO System
- Thermal Imaging Sensor System II
- High-resolution Thermal Imaging Sensor (TIS)
- Two Charged Coupled Devices (CCDs) daylight
imaging Television Sensors (TVS) - Eye-Safe Laser Range Finder (ESLRF)
- Automatic Video Tracker (AVT) that is
- capable of tracking up to two targets within
- the TISS field of view
Source http//www.drs.com/products/index.cfm?gID
21productID295
82Inner Layer
- 57mm Bofors Gun
- (4)Twin M240 Machine Gun Mounts
- (2) High Power Microwave Active Denial System
(HPMADS)
83Main Gun
- Primary Mission Anti-surface defense
- Secondary Mission Beach landing fire support
- An AoA was conducted comparing gun firing rate,
weight, and range
Gun Trade Off Analysis
7
6
Overall MOP
5
Firing Rate 40
4
Weight 30
3
Range 30
2
1
0
5in
57mm
76mm
84Main Gun Bofors 57mm
- 120 magazine capacity
- (3) 40 round cassettes
- 8 second automated change out between cassettes
- 220 rounds per minute firing rate
- 5nm effective range
Sourcehttp//www.sfu.ca/casr/101-navgun2.htm
Sourcehttp//www.sfu.ca/casr/101-navgun2.htm
85Crew Served Twin M240s
- (2) M240Cs per mount
- 750/950 rpm (operator selectable)
- 7.62 ammunition capability
- 3725m maximum range
- Common weapon to U.S. Army and Marine Corps
Sourcehttp//www.fnmfg.com/products/m240/m240main
.htm
86HPMADS
- High Power Microwave Active Denial System
- ADS is a non-lethal, counter-personnel directed
energy weapon - Effective against both small boats and enemy
personnel ashore - Similar range to small arms fire
- Project in development
- Air Force C-130
- Marine/Army Humvee
87Threat Matrix
Aircraft
UAV
SAM
ASCM
Shore Fire
Small Boats
Mines
MFR EO System EW Suite HPMDS ESSM 57mm Gun Twin M240
Passive Detection Soft Kill
Detection
Hard Kill
88System Summary
89RCS Calculation
- Empirical method
- POFACETS software
- XPATCH software
90Empirical RCS Calculation
- Based on Skolnik Empirical Method for low grazing
angles - D displacement (kilotons)
- F frequency in GHz
- To account for aspect angle, actual RCS
approximation - will vary between
- - 32dBsm (minima)
- - 53dBsm (for broadside)
91POFACETS RCS Calculation
92XPATCH RCS CALCULATION
- Provide DOD baseline measurements
- Due to distribution limitations, program is being
run by Dr. David Jenn (ECE) - Once available, results will be compared to
previous two methods
93Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
94Ships manning
- Based on reduced manning requirements, the
manning list by department is as follows
Department Officers CPO Enlisted Total
Command 2 0 0 2
Combat System 1 2 9 12
Engineering 2 3 12 17
Operations 2 4 16 22
Medical 0 1 1 2
Supply/Admin 0 0 11 11
7 10 49 66
95Officer Berthing
- USN Berthing
- (1) CO cabin
- (1) XO stateroom
- (4) 2 person staterooms
- Private and shared heads
- USMC Berthing
- (5) 6 person bunkrooms
- Shared heads
96CO Cabin
97USN Officer Stateroom
98CPO/NCO Berthing
- CPO Berthing
- (2) 6 person bunkrooms
- Semi-private heads
- USMC SNCO Berthing
- Assigned one of four USMC berthing compartments
99CPO Berthing
100Enlisted Berthing
- Ships Crew Berthing
- (1) 36 person compartment
- (1) 24 person compartment
- (1) 12 person compartment (Women-at-Sea
determined compartment size) - Three tiers per berth (Sit-up Berth)
- (4) shared heads (one assigned to females)
- Embarked Marine Berthing
- (3) 69 person compartments
- Three tiers per berth (Sit-up Berth)
- (3) shared heads
101Berth Selection
- U.S. Navys Sit-Up Berth
- Improves quality of life
- Allows the occupant to sit upright when not
sleeping - Ample space to read, write, or relax
Source http//www.pms317.navy.mil/tech/qol.asp
102Enlisted Berthing
12 Person Berthing Compartment
103(No Transcript)
104Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
105Secondary Missions
- Special Operations
- Non-combatant Evacuation Operations
- Humanitarian Assistance
- UV Basing and Operations
106Special Operations
- Deployment of wide spectrum equipment
- RHIBs - HMMWV
- SDV - ITV
- All Helos - Multiple UVs
- Cargo deck supports multiple mission modules
- C2
- SCIF
- Medical
107Special Operations
108Humanitarian Assistanceand Evacuation Operations
- High speed
- Capability to operate in austere, degraded and
minor port environments - Interface with the beach
- Ability to carry multi-mission CONEX boxes
109UV Support
- Capability to support multiple UVs
- UAV (Flight Deck)
- USV (Stern Gate)
- UUV (Stern Gate)
- Cargo deck provides space for storage,
maintenance, and mission modules - UV Handling
- Overhead Telescoping Beam
- Cargo deck tractor with trailer
110UV Handling
Source NSWCCD- INCEN- TR- 2003/001
111Introduction
Mission Flexibility
Summary
Manning/ Habitability
Requirements Design
Combat Systems
Cargo
Damage Control
Hull
Electrical
Propulsion
112Weight estimation
Group Name Weight (LT)
100 Hull Structure 1943
200 Propulsion Plant 91
300 Electric Plant 118
400 Command and Surv. 112
500 Auxiliary Systems 302
600 Outfit and Furnishings 159
700 Armament 164
Liquids Storage 1022
6 Margin 235
Payload 820
Total 4966
113Cost estimation
Assuming 12 ship construction and a learning
curve exponent of 0.95
Concept Cost (Mill )
Ship Construction 156
Propulsion and Electric Distribution 230
Cargo Interfaces 10
Combat System 80
Total (For 1 Ship) 476
114Ship Characteristics
- Overall length 149m
- Overall beam 30m
- Maximum draft 4.5m
- Full load displacement 4966LT
- Light ship displacement 3124LT
- GM 7m
- Maximum speed 43kts
- SHP 78,000hp
- Cruise range 2600nm _at_ 34kts
- 1 Dedicated SH-60R hangar
- Crew compliment 66
115Mission Capability
- Maximum payload 800LT
- 260 Troops and gear
- 2040m2 of cargo area
- 47 vehicles in a typical BLT loadout
- 72 Humvees
- Onload time (ideal conditions) 4 hours
- Offload time (ideal conditions) 2 hours
116Conclusion
- TSSE acknowledges that we were unable to perform
a thorough analysis on all technical issues that
exist with every ship design - TSSE believes that to achieve the HSAC mission
displacement craft such as the Joint ACCESS need
to be researched
117(No Transcript)
118Questions ?
119Ship Armament
- (32) Evolved Sea Sparrow Missiles
- (1) 57 mm Boforors Gun
- (2) High Power Microwave Active Denial System
- (4) M240C Machine Gun Mounts
- Electronic Warfare Suite
120Back-Up Slides
- Ship Characteristics Requirements
- Cargo/Interface Requirements
- Combat Systems Requirements
- MIT
- Design Elimination
- Cooperative Engagement Capability
121Ship Characteristics Reqs
- Endurance for minimum one round trip from sea
base to beach at full load and full speed - Able to interface with developed and undeveloped
ports, harbors and beaches to transfer cargo - Able to interface with Sea Base and current Naval
assets - Must meet mission requirements at Sea State 5
- Able to transit 2000nm in less than 8 days in sea
state 5 (wave height 8-12 ft) without
replenishment - Able to operate in shallow water without
degradation in performance - Able to Replenish-at-Sea (RAS)
- Full accommodations required for embarked crew
- Fuel and support rotary wing aircraft supporting
amphibious operations both day and night - Minimal manning
- Able to transit 2000nm in less than 10 days in up
to sea state 8 (wave height 25-40ft) without
replenishment
122Cargo/Interface Reqs
- The HSAC System of Systems must provide minimum
lift capacity of 7,963 tons (including EFV
transport). - The HSAC System of Systems must provide minimum
deck area of 98,163 square feet (including EFV
transport). - The HSAC must be capable of offloading cargo to
beach and/or unimproved pier. - The HSAC must be capable of interfacing with LPD,
LHA, LHD, LSD, and MPF(F) class ships. - The HSAC cargo area must be dimensioned to a
minimum height requirement to handle and store a
standard 20ton TEU (8'6") - THE HSAC must be capable of providing interfaces
and services to payload (i.e. electrical power,
data-link, fueling)
123Combat Systems Reqs
- Defend against/destroy small (less than 200ft
long), high speed (in excess of 40kts) surface
craft - Detect, track, and destroy up to 8 simultaneous
leaker missiles - Sustain hostile small caliber fire
- Provide suppressive fire for amphibious forces
- Communicate with U.S. and coalition forces via
both secure and unsecure channels - Provide a data link capability
- Collect, process, display, evaluate and
disseminate tactical information - Conduct evasive torpedo maneuvers
- Employ ASW countermeasures
- Detect, track, and identify UAV, low slow flyers,
attack aircraft - Provide Naval Surface Fire Support (NSFS) for
amphibious forces - Detect, track, and identify surface threats to
the horizon - Provide for surface defense of Area of Assault
(AOA) - Defend against and engage hostile UAVs and low
slow flyers (less than 200kts) - Conduct Electronic Protection Operations
- Deconflict potentially hostile craft from
friendly and neutral shipping - Detect and avoid underwater mines
- Fuel and support rotary wing aircraft both day
and night
124(No Transcript)
125Elimination of Designs