SpaceOps Platform - Digital Engineering & Simulation

Mission Control Dashboard

State-of-the-art digital engineering platform for space systems

🌍

Orbital Mechanics

Design and simulate satellite orbits with real-time delta-V calculations

LEO • MEO • GEO • HEO

📡

SATCOM Systems

Configure end-to-end satellite communication links and RF analysis

Link Budget • RF Planning

🎛️

Mission Operations

Monitor spacecraft health and manage real-time operations

TM/TC • Monitoring

🧠

AI Optimization

Intelligent recommendations for mission planning and optimization

ML • Optimization

Active Missions

12

Ground Stations

8

Link Quality

98.5%

System Health

Nominal

Orbital Mechanics Simulator

Design, analyze, and simulate satellite orbits and trajectories

Orbit Type

Semi-major Axis (km)

Eccentricity

Inclination (degrees)

TLE Data Input

Period: ---

Velocity: ---

Altitude: ---

SATCOM System Configurator

Design and analyze satellite communication systems

RF Configuration

Frequency Band

Transmit Power (dBW)

Antenna Gain (dBi)

Modulation

Link Budget

EIRP: 65 dBW

Free Space Loss: 162 dB

Rx Power: -97 dBW

Link Margin: 12 dB

Mission Operations Center

Monitor spacecraft health and manage mission operations

Telemetry Status

Power (W): 1247 Nominal

Temperature (°C): 22.5 Normal

Battery (%): 98 Charging

Signal Strength: -85 dBm Good

Command & Control

SOP Builder

AI-Driven Optimization

Intelligent recommendations and automated optimization

Mission Recommendations

🎯

Orbital Optimization

Recommend increasing inclination to 55° for improved coverage

Confidence: 94%

📡

SATCOM Enhancement

Switch to X-band for 23% improvement in data throughput

Confidence: 87%

⚡

Power Optimization

Adjust solar panel orientation for 15% power increase

Confidence: 91%

AI Assistant

Hello! I can help you optimize your mission parameters, analyze system performance, and suggest improvements. What would you like to work on?

Interactive Training Labs

Guided learning modules for space systems engineering

Orbital Mechanics Fundamentals

75% Complete

Learn the principles of orbital mechanics, Kepler's laws, and orbit determination.

SATCOM Link Planning

45% Complete

Master satellite communication system design and link budget analysis.

Mission Operations

20% Complete

Learn spacecraft operations, telemetry monitoring, and anomaly resolution.

Ground Segment Operations

0% Complete

Understand ground station operations, tracking, and data processing.

Virtual Laboratory

Regulatory Compliance Engine

Ensure compliance with international space regulations

ESA ECSS Standards Compliance

ECSS-E-ST-10-04C: Space Environment Compliant

ECSS-E-ST-20: Electrical and Electronic Compliant

ECSS-E-ST-32: Structural Design Review Required

ECSS-E-ST-40: Software Non-Compliant

Multi-Scenario Comparison

Compare different mission configurations side-by-side

Scenario A: LEO Earth Observation

Altitude: 500 km Inclination: 98° X-band: 8.4 GHz

Scenario B: GEO Communications

Altitude: 35,786 km Inclination: 0° Ku-band: 14/12 GHz

Parameter	Scenario A	Scenario B	Difference
Orbital Period	94.5 min	24 hours	+1345 min
Coverage Area	2,200 km²	42,000,000 km²	+19,090x
Data Rate	150 Mbps	500 Mbps	+233%
Link Budget	12 dB	8 dB	-4 dB