Interstellar Star Clock — Warp Trip Planner

Warp Trip Planner — Earth → Planet (Buttons 1–5). Engine speed and particles follow the computed curvature, time dilation, and g-force envelope.

Earth is the launch clock. All trips start from Earth’s orbit and ride a CST-locked warp bubble to the chosen planet.

Warp Trip Planner — Earth → Planet (Buttons 1–5)

1 — Target Planet (Earth is launch point)

2 — Warp Drive Factor (1–10)

Bubble shows Go / No-Go based on curvature index, time dilation (γ), and effective g-force.
NO-GO — compute a trip first.

Idle — waiting for you to choose a planet, warp factor, and press “3 — Compute Warp Trip”.

Distance (Earth → planet) —

Coordinate Trip Time (CST) —

Ship Proper Time (warp frame) —

ΔAge (CST − Ship) for this trip —

Speeds —

Curvature Index —

Approx g-force (with inertial dampers) —

Safety Summary —

CST Clock Deck — UTC, CST, Ship Warp Clock & Age Dilation

UTC Atomic

--:--:--

Reference lab time (no gravity correction).

CST (Earth Engine Sync)

--:--:--

Earth surface clock, used as the main CST reference.

Ship Warp Clock

--:--:--

Waiting for first computed trip. During warp, this clock runs slightly slower than CST.

Last Trip Summary

Speed: —

ΔAge last trip: —

Engine View — Mass–Energy Core & Toroidal Shell

Show simplified labels and CST research zones

Warp Telemetry — Streams, Temperatures, Field Shape

Plasma Speed Multiplier

x1.0

Field Radius (Warp Shell)

1.00

Shield Fraction & Stretch

0 / 0

Curvature / Gamma / g-force

0.00

γ = 1.000

0.00 g

Clock & Photons & Magnetics

1.000×

0 /s

0.00

Core & Coolant Temperatures

0 °C

Entanglement Flux & Plasma Shape

0 /s

0 u

Plasma Wave Metric

0.00

Status

Plasma stays subluminal; apparent FTL comes from warp geometry + CST mapping, with E ⇌ m core and hull shell conversion.

Scientific Enhancements for the Interstellar Star Clock & Warp Drive

These equations sit behind the CST clock and warp navigation. They convert poetry into physics while keeping your bold vision intact — time slippage, star coordinates, and energy gradients all feed one unified engine.

1. Time Dilation (Special Relativity)

Δt' = Δt × √(1 - v² / c²)

Clock layer: Used to adjust ship proper time vs CST when plasma streams move at a fraction of c inside the engine.
Navigation: High-velocity segments of a jump arc show reduced proper time; CST keeps the crew anchored to the master cosmic clock.

2. Gravitational Time Dilation (General Relativity)

Δt' = Δt × √(1 - 2GM / (r c²))

Clock layer: Used when the ship operates near stars, planets, or compact objects; CST compensates for slower clocks in deeper wells.
Warp control: The engine avoids curvature regimes where GR plus warp geometry could create unstable CTC-like loops.

3. Star Coordinate Mapping (RA / Dec → 3D)

x = cos(δ) × cos(α), y = cos(δ) × sin(α), z = sin(δ)

Star clock: Anchors each star to a fixed direction on the celestial sphere at a given epoch.
Warp navigation: Converts RA/Dec into a 3D target vector for the FTL jump planner; the CST engine rides curvature along that vector.

4. Sidereal Clock Adjustment

Sidereal Day = 23h 56m 4.1s

Clock layer: The CST clock keeps both solar time and sidereal time; over years, the tiny offset accumulates into real star drift.
Warp navigation: Corrects star positions for drift since J2000 so the RA/Dec map stays aligned over long deep-time jumps.

5. Light-Time Correction

t = d / c

Star clock: Shows how “old” the light is from each star; your constellations become time-delayed snapshots.
Warp comms: Compares conventional light-time to instantaneous entanglement or warp-burst signals in your communication panels.

6. Stefan–Boltzmann Law (Radiative Heat from Coils & Panels)

F = σ T⁴

Engine core: Predicts heat flux from hot coils, plasma chambers, and gradient panels as a function of temperature.
Safety / Shield mix: When radiative flux approaches structural limits, the controller shifts energy from warp geometry into cooling and shielding.
Telemetry: The “Core Temp” and “Coolant Temp” readouts conceptually trace back to this T⁴ scaling.

7. Hamiltonian Operator (Energy of the Warp Field)

Ĥ ψ = E ψ

Field layer: Treats the warp shell and vacuum modes as a quantum system with a Hamiltonian that encodes all energy terms (plasma, EM, vacuum).
Gradient design: By choosing a Hamiltonian with stable eigenmodes, you bias the engine toward field configurations that maintain a smooth bubble.
CST integration: The CST clock can be thought of as following the phase evolution of the warp state vector over long-duration missions.

8. Wave Equation (Propagation of Warp & Shield Fields)

∂²ψ/∂t² = c² ∇²ψ (classical form)

Field geometry: Describes how disturbances in EM, plasma, and vacuum modes propagate through the warp shell.
Gradient control: The controller uses an internal wave model so pulses launched by the coils arrive in phase at the front vs rear shell.
Shield shaping: Radiation and particle shielding are engineered as standing-wave solutions that wrap the hull in a stable harmonic envelope.

Together, these equations let the Interstellar Star Clock do more than tell time: it predicts how time, energy, and geometry interact. Your warp engine sits on top of this clock, using CST to keep energy gradients, curvature, and crew experience in sync. The E ⇌ m zones inside the engine are: (1) the nuclear mass core (m → E) and (2) the hull conversion shell (E → m effective mass around the ship).