Time,
redefined.

Computing astronomical data into 3D Timestamps

Retrograde Observatory Artwork

The World's First Temporal Computation Infrastructure

Proprietary algorithms that transforms astronomical data into 3D timestamps

Astronomical Computation

Ephemeris Processing • Precision Maintenance • Geographic Adjustment

Algorithmic Transformation

Core Innovation • Coordinate Systems • Multi-Format Generation

Computational Architecture

Stateless Processing • Real-Time Computation • Caching Strategy

The Infrastructure Stack

Layer 1: Astronomical Data Foundation

Data Sources

  • JPL Horizons: 49 solar system objects (planets, moons, major asteroids)
  • SIMBAD: 60+ stellar objects
  • Total availability: 109+ celestial bodies

Data Quality

  • Ephemeris-quality positional accuracy
  • NASA/ESA standard precision (±0.01 arc-seconds)
  • Real-time query capability
  • Geographic adjustment for observer location

Data Processing

  • Positional retrieval from authoritative sources
  • Observer-relative calculations
  • Temporal moment specification
  • Geographic coordinate transformation

Layer 2: Temporal Computation Engine

Algorithmic Core

Proprietary algorithms that compute astronomical positions into temporal coordinates. The transformation is deterministic—identical input produces identical output.

Computation Process

  • Input: Celestial body positions, observer location, temporal parameters
  • Processing: Algorithmic transformation through proprietary computation
  • Output: 3D temporal coordinates in multiple representations

Coordinate Generation

  • Cartesian form: scale_X, scale_Y, scale_Z
  • Spherical form: radial_Location, polar_Angle, azimuthal_Angle
  • Geometric metrics: area, volume, distance, angular measurements

Performance Characteristics

  • Computation latency: <50ms p95
  • Deterministic output: reproducible results
  • Scalable architecture: horizontal scaling capable
  • Real-time processing: suitable for live applications

Layer 3: API Infrastructure

Access Method

RESTful API endpoints providing programmatic access to temporal computation.

Request Structure

JSON-based configuration specifying astronomical parameters, observer location, temporal reference points, and celestial body selection.

Response Structure

JSON-formatted 3D timestamp data with multiple representational formats and computational metadata.

Infrastructure Design

  • Stateless: No server-side state storage
  • Distributed: Geographic distribution capable
  • Cached: Common queries cached for performance
  • Authenticated: API key-based access control

Layer 4: Interpretation Frameworks

Framework Layer

Optional interpretation systems that apply domain-specific logic to raw 3D timestamp data.

9-Calendar Framework

Pre-built interpretation system consisting of nine distinct temporal frameworks, each based on specific celestial configurations. Applies observational logic to translate computational output into framework-specific temporal intelligence.

Custom Framework Capability

Infrastructure supports development of custom interpretation layers. Raw 3D timestamp data can be processed through user-defined logic for domain-specific temporal intelligence.

3D Timestamps

You are the Universe. Now Visualize it!

{
"success": true,
"results": {
"canopus": {
"celestialBody": "Canopus",
"bodyType": "star",
"scale_X": -0.9110307297365807, Click to learn more
"scale_Y": 10.319706847706392, Click to learn more
"scale_Z": 0, Click to learn more
"radial_Location": 10.35984200715062, Click to learn more
"polar_Angle": 95.04503134428379, Click to learn more
"azimuthal_Angle": 90 Click to learn more
}
}
}

Click on any coordinate value to understand celestial body's journey in your universe

{
"success": true,
"service": "Celestial Location",
"results": {
"Moon": {
"celestialBody": "Moon", Click to learn more
"bodyType": "satellite", Click to learn more
"temporal_location": 66.57129000027166, Click to learn more
"temporal_distance": 538.2507637994006, Click to learn more
"inter_body_distances": { Click to learn more
"Mars": 103.31,
"Sirius": 132.34
}
}
}
}

Click on any field to understand the celestial body's temporal position and journey

{
"success": true,
"results": {
"7F7F7F": {
"Calendar": "7F7F7F", Click to learn more
"scale_X": -33.497907999999995, Click to learn more
"scale_Y": 8.073973000000002, Click to learn more
"scale_Z": 16.370900000000002, Click to learn more
"radial_Location": 38.148463234987496, Click to learn more
"polar_Angle": 166.44852411769952, Click to learn more
"azimuthal_Angle": 64.5872239227289, Click to learn more
"sphericalCoord_area": 18287.905093226116, Click to learn more
"sphericalCoord_volume": 232551.82503129233, Click to learn more
"sphericalCoord_Distance": 487.3869776772234, Click to learn more
"sphericalCoord_Angular": 50.11083854025346 Click to learn more
}
}
}

Click on any field to understand the calendar's position in temporal space

Welcome the Era of personalised Planetariums

Unleash the experience of XR Astronomy

📍

Temporal Location

Current position on timeline

0255075100
Venus
41.56
Sun
48.25
Jupiter
75.94
Moon
85.29
1D Timeline
🛤

Temporal Distance

Journey traveled through time

Moon
520.60
Jupiter
308.15
Mars
137.73
Venus
126.41
Journey Bars
🏁

Temporal Station

3D spatial coordinate position

Y
Mars 147.99
Mercury 130.16
Sun 121.44
Moon 102.86
Jupiter 61.64
3D Space

Temporal Shift

Inter-body relationship network

151.60 121.17 65.18 Moon Jupiter Mars
Vector Network
AR Mobile Apps
VR Planetariums
Mixed Reality
Gaming Engines

3D Timestamps
X Artificial Intelligence

BMS: The Final Frontier of Astronomy

"calendarId": "crimson-forge", "aspect": "Capacity", "colorHex": "#FF0000", "density": 1.234, "brightness": 0.772, "visibility": 0.784, "rhythmScale": 0.953, "spatialX": 0.922, "spatialY": 0.91, "spatialZ": 0.36, "cohesiveness": 0.958, "wobbleScale": 0.562, "interactionDepth": 0.635, "spatialExtent": 1.117, "responsiveness": 0.772, "verticalBias": 0.012, "rotationalVelocity": 0.976, "magneticPull": 0.417, "auraRadius": 1.848, "harmonyGlow": 1.109, "formSolidity": 0.977, "stageModifier": 0.9
Click a field to explore

Select any field from the BMS response to see its visual meaning and how it controls the 3D energy signature.

Behavioral Modulation Signals transform temporal coordinates into real-time behavioral parameters for AI agents, game characters, and IoT devices. Think of it as "emotional weather" based on celestial positions.

AI Personalities

Give AI agents temporal-based mood, energy, and responsiveness

Game Dynamics

NPCs and environments that evolve with real celestial mechanics

Smart Devices

IoT behavior modulation based on temporal intelligence

3 Steps to Temporal Intelligence

1

Define Your Origin

Birth date, device activation, or any temporal starting point

2

Astronomical Computation

109 celestial bodies processed with ephemeris precision

3

3D Temporal Coordinates

Multi-scale timestamps ready for integration

Try Interactive Demo

Why Developers Choose Retrograde Observatory

Move beyond linear timestamps to multi-dimensional temporal coordinates

Standard Timestamps

  • 1D scalar value
  • Fixed epoch (1970)
  • No personalization
  • Solar cycle only
VS

Temporal Coordinates

  • 3D vector coordinates
  • User-defined origin
  • Personal frameworks
  • 109+ celestial bodies

Just Checkin!

Node
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LAST
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Ready to build time intelligent systems?

Access temporal intelligence infrastructure from 109 celestial bodies

Contact Us

Get in touch with the Retrograde Observatory team

Tick the Cosmos

Lumina I/O

Hello! I'm Lumina I/O, your Temporal Intelligence Advisor. Ask me about time intelligence, calendars, or behavioral signals.