SPECIFICATIONS OF U.S.S. LEXINGTON
Primary Function:
Federation Dreadnought class Vessel designed for long-term missions, exploration, and combat operations. Upgraded in weaponry and defense systems, allowing it to excel in both combat and extended deep-space missions
Dimensions & Mass:
Length: 1,041.5 meters
Width: 385.32 meters
Height: 165.74 meters
Mass: 7,127,200 metric tons
Decks: 47, equipped with modified life support systems for extended missions.
Crew:
Operational Crew: 900 members. The modified control systems and automation allow the ship to operate efficiently with a smaller crew than standard Odyssey-class ships.
Standard Crew: 2,100 members.
Maximum Crew: 15 700 (Evacuation Limit)
Propulsion Systems:
1x Yoyodyne 47C M/ARC warp core: Enhanced energy stability and efficiency during extended high-warp travel, thanks to significant innovations.
2x Keenser/Pegg Heavy Impulse Engines: Improved impulse engines designed for higher maneuverability and faster acceleration during combat.
2x Inline Flux Secondary Impulse Engines: Secondary engines optimized using Federation designs, providing backup propulsion in case of damage to primary systems.
Sensor Systems:
12 DYN-90 Multi-band Linear Sensors: Advanced multi-frequency sensors enabling precise detection and analysis of enemy ships over long distances.
4 Omniwave Passive Sensor Matrices: High-sensitivity passive sensor arrays, upgraded with Terran blueprints for enhanced detection of low-frequency energy signatures.
1 JAWS Active Directional Sensor Array: A directional sensor array focusing on analyzing enemy shields and weapons, facilitating their deactivation or weakening during combat.
Weaponry:
21 MK XV Radiolytic Phaser Arrays: The ship is equipped with advanced radiolytic phaser arrays, offering a wider range of effectiveness and increased destructive power. Modifications from Daystrom station enhance their efficiency against enemy shields and inner systems.
14 Variable Payload Torpedo Launchers: Capable of launching a wide variety of torpedoes (Darkmatter, photon, and Quantum), making the ship highly versatile in combat scenarios. Advanced projectile enhancements allow faster reloading and higher firing rates.
Defensive Systems:
Adaptive Regenerative Shields: The ship features regenerative shields that adapt to various attack types, including kinetic and energy weapons. Modified by adapted Borg technology, these shields shorten regeneration time under heavy fire.
Reinforced Duranium-Tritanium Hull Armor: Advanced multilayer armor composed of high-density duranium, tritanium, and neutronium weave. Integrated nanostructures automatically seal microfractures and redistribute impact stress across the hull.
Tactical Capabilities:
Holographic Combat Tactics: An enhanced holographic system allows real-time tactical simulation, improving crew response times in battle. Additionally, the system can deploy holographic personnel for combat tasks.
Countermeasures Interference: Based on Terran technology, the ship is equipped with systems that can disrupt enemy targeting systems, making it harder for adversaries to lock onto the Lexington's shields and hull.
Aquarius class Escort: Warp-capable auxiliary support vessel with advanced combat capabilities
Saucer Separation: As a part of emergency evacuation protocols or multi-vector combat capabilities
Aft hangar bay: Variable hangar bay equipped with type 14 shuttles
MULTI-DIRECTIONAL TACTICAL WEAPONS PLATFORM (MDTWP): A structurally integrated weapons platform delivering independent multi-vector phaser and torpedo fire to cover blind spots and support the ship's main batteries.
SPINAL PHASER LANCE (SPL-X): A heavy ventral phaser mounted along the ship's central spine, designed for precise medium-range strikes against heavily shielded targets.
SECTION 1 – PROPULSION SYSTEMS
1.1 MAIN WARP PROPULSION
Type: Yoyodyne 47C M/ARC (Matter/Antimatter Reaction Core)
Version: Series 7A, upgraded with advanced stabilization oscillator fields for finer warp field control during rapid velocity changes
Max Safe Warp Factor: Warp 9.5
Emergency Maximum Warp: Warp 9.994 (limited to 6 hours)
Average Chamber Output: 5.3 million terawatts at full load
Stabilizer Matrix: Six triaxial Lambda‑C magnetic nodes maintain core alignment at high warp
Primary Intermix Ratio: 10:1 (deuterium: antideuterium) with adaptive auto-calibration for optimal matter-antimatter efficiency
Antimeson Storage: Vacuum-isolated neutron glass reactors (class XV-Ω), based on containment breakthroughs from Excelsior II class research
Regulation: Multi-vector warp plasma distribution with six F/B plasma injectors
Redundancy: Omega-class dual "side-core" grids ensure warp capability if the main core is compromised
1.2 IMPULSE SYSTEM
Primary Engines
Manufacturer: Keenser/Pegg Systems, renowned manufacturers of advanced starship propulsion systems with a long-standing tradition of EPS network integration.
Model: HIE-16T Heavy Impulse Engines (two units installed in the stardrive section).
Output: Each engine delivers a continuous output of 450 gigawatts, smoothly controlled and distributed through the ship's EPS (Electro-Plasma System) network.
Design: The Heavy Impulse Engines are engineered for high reliability and rapid response to command inputs from the captain and automated navigation systems.
Function: Provide primary subwarp propulsion with high maneuverability both in space and atmospheric conditions, optimized for sustained operations and intense combat scenarios.
Secondary Impulse Array
Type: Inline Flux Impulse Array (Starfleet Type-9G), a modern modular impulse engine system located on the ventral hull and backup units on deck 9.
Placement: Ventral (underside) hull placement ensures better thrust distribution and finer control during maneuvers. Backup units on deck 9 provide immediate redundancy in the event of a primary engine failure.
Output:
Continuous output of up to 210 GW for standard operations,
Overload capacity of 390 GW during emergency maneuvers or rapid escape.
Modifications: The secondary system is enhanced with Terran subroutines, special software modules that improve performance in strong gravitational fields near planets or stars. This allows:
Increased thrust efficiency within gravity wells,
Optimized fuel and energy consumption during gravity-affected maneuvers,
Faster response to trajectory and speed adjustments in challenging gravitational environments.
RCS — Reaction Control System
Purpose: Precision orientation and low-speed maneuvering in space and atmosphere; critical for docking, combat positioning, and stabilization after main drive damage.
Configuration: 12 primary thrusters (up to 2.5 MN pulsed thrust each) + 6 auxiliary ion modules (0.5–5 kN continuous).
Propulsion Type: Hybrid radiolytic–ion system; radiolytic deuterium gas for rapid response, ion jets for fine control.
Power & Supply: Fed from warp reactor loop; redundant power routing.
Control Integration: Linked to helm and tactical computers with adaptive predictive control algorithms.
Redundancy: N-1 thruster redundancy, automatic fault isolation, and failover to ion modules.
Emergency Modes: "Safe-Burst" for rapid separation; "Failsoft" low-power mode for system preservation.
Protection: Composite nozzle shutters, thermal shielding, and self-cleaning blow-out cycles.
Special Feature: Vector-adjustable, retractable nozzles for improved thrust efficiency and evasive maneuvering.
Additional Note: Type-9G arrays share design heritage with impulse systems used on the USS Defiant, optimized for sudden power surges
1.3 POWER DISTRIBUTION
EPS Network: Trilinear duranium-carbonit tubing with 92 delta-redundant relay nodes, ensuring resilient power routing even under battle damage
Backup Loops: Sectorized for each major compartment; prevents single-point failures from crippling entire ship sections.
Control System: LCARS 6.5-E with real-time energy flow mapping
Warp Plasma Injection: Dual 5-A injectors with safety interlocks; automatic magnetic shutdown if intermix variance exceeds 3.4%
SECTION 2 – SENSOR & NAVIGATION SYSTEMS
Fully integrated advanced sensor, analytics, and Gen‑3 computer grid with brand new Federation hybrid interface.
2.1 NAVIGATIONAL DEFLECTOR
Primary System: Type-XI Long-Range Deflector Array
Power Draw: 4.1 GW continuous (up to 7.3 GW in hazard mode)
Deflector Dish Material: Trilithium-bonded duranium alloy
Harmonic Phase Shifting for micro-debris evasion
Integrated with forward sensors for predictive pathing
Auto-alignment with warp field vector for efficiency
2.2 SENSOR POLARIZATION & ANALYSIS
Model: DYN-90 Multi-Band Linear Sensor Grid (12 nodes)
Frequency range: 0.0005 Hz–230 THz
Range: 13.2 AU
Detects subspace anomalies, graviton waves, tachyons, tetryons
Phase-vector filtering separates cloaked ships from background noise
2.3 PASSIVE SENSING
Type: Omniwave Passive Sensor Matrix (4 units)
Adapted from ISS Lexington plans: low-frequency scatter analysis
Sensitivity: ±0.00001 meV (sub-quantum pulses)
Interface with tactical board and bridge consoles showing "ghost signature" levels
2.4 JAWS – ACTIVE DIRECTIONAL SENSOR
Name: JAWS (Joint Analysis Weapon Scanner)
Mounted under the forward shield of the hull
Range: 5.2 AU (tactical), 13.2 AU (long-range)
Tracks 8 ships simultaneously, 32 weapon channels
"Pulse Lock" analyzes shield frequencies and suggests phaser tuning
2.5 SUPPORT SENSORS & TOOLS
XI-A subspace probes with spectrometer, EM, and molecular scanners
Tactical holographic simulator predicts enemy maneuvers
Optical triangulation links to an astronomical database for locating without subspace buoys
2.6 PRIMARY NAVIGATION ARRAY
System: Starfleet NAVCOM-S Mk XII
Control Interface: LCARS 8.4 integrated helm with spatial inertial feedback
Inertial Tracking Core: Quad-gyro quantum frame stabilizer
Real-Time Course Correction: 15ms reaction latency
Subspace Drift Compensation Module: Auto-adjusts warp trajectory drift under stellar mass influence
Integrated with stellar cartography and deflector harmonics
Failsafe Mode: Auto-return to last known safe vector if primary navigation fails
2.7 ASTROMETRICS LABORATORY
Module: Daystrom Series-VIII Astrometric Core
Display: 360° Holographic Stellar Projection Dome (30m dia)
Database: Over 5.1 billion stellar objects cataloged
Computation Core: Shared with main computer grid (QX-4 co-processor access)
Functions:
Gravitational mapping
Subspace lane prediction
Singularity drift analysis
Exotic particle tracking (e.g. tetryons, omicron radiation)
Crew Interface: Touchless gestural system + voice neural tagging
Lab Staff: 6 primary officers + 1 Holographic assistant
SECTION 3 – WEAPON SYSTEMS
Lexington-class weapons platform using radiolytic phasers and advanced torpedo systems.
3.1 MK XV RADIOLYTIC PHASER ARRAY
21 phaser strips (fore, sides, aft); Daystrom build with advanced Subsystems Synthesis
Output: 18-24 GW per strip (standard discharge)
30-35 GW per strip (Focused beam)
Firing modes: pulsed, continuous, precision impulse
Range: up to 5.8 km (optimal), 10 km (max)
Adaptive phase-tuning, 22% faster charge, nanotech self-repair
Phase-Resonance Modulation disperses fire to cover blind spots
3.2 VARIABLY-LOADED TORPEDO SYSTEM (14× Mark 38‑V)
Launchers carry: Dark-Matter, Photon, and Quantum torpedoes
Projectile speeds: Warp 8.1 (Darkmatter), Warp 6.9 (Photon), Warp 7.7 (Quantum )
Total ammo: 480 (30 per launcher)
Reload time: 3.6 s via EM catapult and robotic service module
Special warheads: EMP, plasma overload, nanovirus infiltration
Integrated with JAWS and LCARS; auto trajectory correction for subspace perturbations
Variable firemodes : Standard (1-3 torpedoes per cycle)
Full spread (6-12 torpedoes per cycle)
3.3 FIRE CONTROL & TACTICAL AUTOMATION (AICS)
LCARS 6.5-T coordinates all phasers and torpedo launchers
Real-time 3D hit/collision simulations, "Fire Override" emergency mode
Adaptive Interference Countermeasure System neutralizes enemy jamming
Adaptive stealth targeting compensates for cloaking
3.4 INTEGRATED WEAPON DOWNSYSTEM (PAWOS)
Phased Array Weapon Optimization Suite targets critical points, improving penetration and energy efficiency (~18%)
3.5 SUPPORT WEAPONS
Federation Type II Phaser pistol with bio-sync reach
Federation Type III-C Phaser Rifle
3.6 MULTI-DIRECTIONAL TACTICAL WEAPONS PLATFORM (MDTWP)
An integrated structural weapons platform positioned between the warp nacelles and tied directly into the vessel's secondary structural spine. The system is warp-field harmonized to prevent subspace interference during sustained combat operations.
Designed to provide multi-vector coverage and eliminate dorsal and aft blind zones not fully covered by the primary phaser arrays.
🔹 Torpedo Configuration
Total of 6 integrated launch tubes:
2× Forward launch tubes
2× Aft launch tubes
1× Port lateral tube
1× Starboard lateral tube
Fully compatible with Mark 38-V ordnance (see Section 3.2).
Synchronized with the main torpedo magazine.
Firing Modes:
Vector Pair (forward or aft synchronized launch)
Lateral Intercept Mode (side defensive engagement)
Omni-Spread (up to 6 torpedoes per cycle)
Staggered Defensive Pattern (sequential 360° coverage)
Reload cycle: 4.1 s (independent EM feed system)
Independent magazine capacity: 72 torpedoes
🔹 Phaser Coverage:
4× Medium Radiolytic Phaser Emitters (segmented arrays)
2× Point-defense micro arrays
Output:
22–28 GW per emitter
Optimized for overlap with primary MK XV phaser arrays
Effective range: 6 km
Maximum range: 9 km
Primary Function:
Upper hemisphere defense
Interception of strike craft and drones
Shield-pressure support during coordinated assaults
3.6.1 TACTICAL WEAPONS CONTROL CENTER (TWCC)
A dedicated combat operations center integrated within the secondary hull directly beneath the MDTWP structure.
Functions as:
Auxiliary tactical bridge
Localized fire-control nexus
Autonomous combat command node in the event of primary bridge compromise
🔹 Capabilities:
Independent control of MDTWP
Local shield-frequency modulation
Real-time target prioritization
Redundant integration with AICS
Crew Complement:
1× Tactical Command Officer
2× Weapons Systems Specialists
1× Targeting Analyst
In emergency configuration, TWCC can assume full shipwide weapons control authority.
3.7 SPINAL PHASER LANCE (SPL-X)
A ventrally mounted heavy axial phaser emitter installed beneath the primary saucer along the reinforced central structural spine.
🔹 Output:
210 GW standard discharge
320 GW short-duration amplified pulse (max 2.5 s)
🔹 Range:
10 km effective
15 km maximum
Optimized for medium-range heavy engagement, not long-range artillery operations.
🔹 Operational Constraints:
Requires direct axial alignment (±8° targeting tolerance)
Cannot be fired in warp field
Recharge cycle: 60 seconds
Thermal stabilization period after amplified pulse: 15 seconds
🔹 Primary Role:
Heavy shield penetration
Precision strikes against structural or power-distribution nodes
SECTION 4 – DEFENSE & SHIELD SYSTEMS
Next-gen defense combining adaptive shields, metaphasic armor, and advanced anti-tracking tech
4.1 MARK XV ADAPTIVE REGENERATIVE SHIELDS
Regenerates in 0.6 s (vs 1.8 s baseline) with Borg nano-repair tech
Standard capacity: 3.2 TJ; Overcharge: 5.5 TJ for 15 s
Frequency: 1 GHz–10 THz; anti-subspace field reduces enemy sensor range
Phase-Sync mode fuses shield with metaphasic armor
4.2 REINFORCED DURANIUM-TRITANIUM ARMOR PLATING MK XII
Advanced multilayer nanocomposite armor developed by the Daystrom Institute, composed of reinforced duranium-tritanium alloy with embedded neutronium mesh and structural integrity field coupling.
Thickness: 8–30 cm at critical points
Reduces kinetic impact by 94%, reflects phaser blasts, self-repairs micro-damage
Adds 650 t to hull while maintaining maneuverability
4.3 COUNTERMEASURE INTERFERENCE SYSTEM (CMIS)
Borg technology-inspired suite disrupting enemy targeting and tracking
Active 3D emission scatter, passive spectral masking reduce signature by ~17%
Ghost Protocol hides ship from enemy sensors for up to 20 s (requires shield boost)
4.4 BACKUP DEFENSES
Energy-absorbing fields convert impact energy to heat
Secondary emergency shield grid inside hull
Nano-repair drones fix micro-damage
4.5 SYSTEM INTEGRATION
Linked to main computer for automatic power reallocation
Shields adapt to JAWS sensor data
Tactical Computer dynamically balances offense/defense
SECTION 5 – HOLOGRAPHIC TACTICAL SYSTEM & COUNTERMEASURES
5.1 HOLOGRAPHIC TACTICAL SIMULATOR (HTS)
TRAHE Mk III by Daystrom HoloTech
Real-time 3D 24K projection, 360° view
Gestural/voice interface
Deployable holographic illusions deceive enemies
Processes over 12 million simultaneous inputs
5.2 COUNTERMEASURE SUITE (AEWS)
Active/passive jamming of sensors, radars, targeting
Signal Disruption Matrix emits broadband EM bursts
Phase Jamming Protocol targets guidance frequencies
Subspace Distortion Field disrupts communications
Syncs with CMIS/JAWS, blocking up to 98% of standard targeting
5.3 INTERFACE & CONTROL
LCARS 8.4 tactical consoles
Neuro-adaptive commands by first officer improve response time ~47%
Tactical System "Talon" adjusts tactics in real-time
System can auto-deploy countermeasures
5.4 OPERATIONAL USAGE
Holographic decoys mask movement and duplicate signatures
Coordinates formations with multiple units
Generates false targets to confuse torpedoes/beams
Allows live simulation-based tactic adjustments mid-battle
SECTION 6 – COMMUNICATION AND COMPUTER SYSTEMS
6.1 MAIN COMPUTER GRID
Type: LCARS-X v6.5-E with Starfleet advanced Echo Protocol enhancements
Core: Triple-redundant Isolinear Matrix Mark XII + QX-4 quantum coprocessor
Processing Speed: 640 exaFLOPS (up to 850 exaFLOPS in combat simulations)
Storage Capacity: 1995 TeraQuads
Computer support system "Athena" supports limited autonomy (no command privileges)
Interface: Touch-screen surfaces + neural-hub Beta for authorized crew
Security protocols enable advanced threat recognition and real-time response
6.2 COMMUNICATION SYSTEMS
Primary: Subspace Transceiver Array Mk XII
Range: 8 light years
Data Rate: 5 Tbps
Quantum Encrypted Comms, Tactical Line-of-Sight Comms, Emergency Signal Network
6.3 INTERFACE & NETWORK INFRASTRUCTURE
LCARS 8.4 with voice/gesture/neural input
Redundant multilayer networks with automatic failover
Multi-phase quantum encryption with dynamic protocols
6.4 CYBER SECURITY & SYSTEM INTEGRITY
Adaptive Cyber Defense Grid System "Sentinel" for intrusion response
Continuous attack simulations optimize defenses
Distributed cryptographic nodes verify data integrity
6.5 OPERATIONAL APPLICATIONS
Instant tactical data sharing with fleet units
Secure diplomatic and operational comms
Syncs energy flow with combat demands
Coordinates with holographic and sensor modules
SECTION 7 – HANGAR AND ESCORT SYSTEMS
7.1 REAR HANGAR BAY
Capacity: up to 24 Type 14 Shuttles or 8 Danube Runabouts
Hangar: 320m x 120m x 70m; modulated inert atmosphere
12 robotic arms for handling; instant status diagnostics
Modular power system up to 15 MW for vessel support
7.2 TYPE 14 SHUTTLECRAFT
Type: multi-role shuttle
Dimensions: 18.4 x 7.2 x 5.4 m
Performance: 0.25c impulse max speed
Armament: 2x Mk II Phasers; integrated with main ship tactical systems
Standard Starfleet multi-phase deflector shields.
7.3 AQUARIUS CLASS ESCORT VESSEL
Role: support warship/dropship
Dimensions: 160 x 55 m
Propulsion: Yoyodyne Compact Warp Core (Warp 9.8)
Armament: 4x Mk XII Phaser Turrets, 2x Torpedo Launchers
Defenses: Metaphasic Armor, adaptive shields
7.4 SAUCER SEPARATION SYSTEM
Purpose: emergency evacuation/tactical reconfiguration
Vibrational separators with subspace harmonic resonators
Recombination: automatic locks with high-speed precision
Sections fully autonomous for 72 hours
7.5 LOGISTICS & SUPPORT SYSTEMS
Autonomous Hangar Operations for maintenance/deployment (support system)
Robotic repair stations with nanobot modules
Vacuum Transit Tubes for rapid material transfer
14x Auxilary Maintanance & Repair Work Bee craft
SECTION 8 – ENVIRONMENT AND LIFE SUPPORT
8.1 ATMOSPHERIC CONTROL SYSTEM (ACS)
Atmosphere: 21% O2, 78% N2, trace gases
Pressure: 101.3 kPa; adaptive regulation
Multi-stage nano-catalytic filtration
CO₂ regeneration via Sabatier reactions
Emergency isolation for 120-hour survival
8.2 WATER RECYCLING SYSTEM
Daily capacity: 120,000 L
Ultrafiltration + UV + electrolytic cleaning
20% stored in cryogenic tanks for emergencies
8.3 GRAVITY FIELDS
Inertial generators with ±0.01g precision
Gravity adjustable 0.1g–1.2g
Rehab sections prevent atrophy
8.4 FOOD SUPPLIES & PRODUCTION
Hydroponic farms + Mk XV replicators
Emergency food stores for 3 months
8.5 MEDICAL & HEALTH SYSTEMS
Sickbay with bioregenerative stations, nanobot surgery
Emergency MedPods in multiple ship zones
Betazoid counselor monitor crew emotional state
EMH MK IV with enhanced memory packets for longer usage
8.6 RANDOM & CRISIS LIFE SUPPORT
Isolation chambers with sealed atmospheres
Autonomous emergency life pods for 96-hour survival
Environmental sensors monitor conditions for toxins, temp, humidity
SECTION 9 – FIELD INTERFACE & TRANSPORT SYSTEMS
9.1 TRACTOR EMITTERS
Emitter Type: Graviton Beam Projectors Mk VIII
Total Units: 6 (2 fore, 2 aft, 2 dorsal)
Maximum Pull: 1.2 million metric tons at 300 meters
Tether Mode: Stabilizes docked or damaged vessels
Micro-Pulse Mode for cargo precision manipulation
9.2 PERSONAL TRANSPORTERS
Model: Federation Mk VI Pattern Buffer Array
Total Units: 8 main transporter rooms + 4 auxiliary stations
Pad Capacity: 8 persons
Emergency Buffer Time: 60 sec
Heisenberg Compensators: Dual-redundant for precision
Bio-Filter Suite with quantum pathogen screening
Range: Up to 40,000 km planetary; 75,000 km orbital
Neural-lock fallback system in case of pattern distortion
9.3 CARGO TRANSPORTERS
Configuration: Multipoint Freight Transit Grid (MFTG)
Total Units: 6 dedicated cargo transporter bays
Pad Configs: Modular 4x4m & 6x6m platforms
Auto-Mass Calibration: Handles up to 80 tons per cycle
Cold Transport Mode: Maintains cryo/stasis integrity
EPS-linked redundancy for nonstop logistics
Integrated with HangarOps system for priority routing