Next-Generation
Orbital Compute Infrastructure
Low Earth orbit datacenter arrays providing unprecedented computational capacity with global coverage and minimal latency for mission-critical applications.
Orbital Computing is in development phase.
Performance metrics shown are projections.
ORBITAL INFRASTRUCTURE
System Architecture
The VISCA Orbital Computing platform consists of interconnected satellite datacenter nodes in low Earth orbit providing distributed computing resources with global coverage.
Orbital Compute Nodes
16 satellite nodes in 550km LEO orbit with radiation-hardened server infrastructure.
Optical Inter-Satellite Links
400 Gbps laser communication between nodes with mesh topology for redundancy.
Ground Station Network
32 global ground stations providing <25ms latency to 99.8% of Earth's population.
Edge Computing Mesh
Distributed compute framework for workload distribution across orbital and ground resources.
Deployment Timeline
Initial Development
Ground-based prototyping and simulation infrastructure development. Initial system architecture design and testing.
First Orbital Launch
Deployment of first 2 orbital compute nodes as technology demonstration, providing limited compute services with partial global coverage.
Initial Constellation
Expansion to 8 orbital nodes with enhanced compute capacity and 80% global coverage with preliminary mesh networking.
Full Deployment
Complete 16-node constellation with advanced TPU units and specialized AI/ML hardware acceleration modules in orbit.
Orbital Parameters
- »Altitude: 550km circular orbit
- »Inclination: 53°
- »Orbital period: 95.4 minutes
- »Nodes per plane: 4
- »Total orbital planes: 4
Communication System
- »Inter-satellite links: 400 Gbps optical
- »Earth downlink: 50 Gbps Ka-band
- »Uplink capacity: 35 Gbps
- »Link encryption: 512-bit quantum resistant
- »Protocol: Orbital Transport Protocol v2
Power System
- »Solar array: 18kW triple-junction GaAs
- »Battery: 45kWh Li-ion graphene-enhanced
- »Compute power budget: 12kW continuous
- »Peak power handling: 16kW
- »Power redundancy: N+2 architecture
APPLICATIONS
Global Financial Systems
Ultra-low latency for high-frequency trading and cross-border transactions with 24/7 processing capabilities.
- »25.6ms global transaction processing
- »Secure blockchain verification
- »Distributed ledger synchronization
- »Multi-region compliance
Climate & Earth Observation
Real-time processing of satellite imagery and sensor data for climate modeling, disaster response, and environmental monitoring.
- »Petabyte-scale image processing
- »Real-time disaster detection
- »Multi-sensor data fusion
- »Global atmospheric modeling
Autonomous Transportation
Global coordination of autonomous vehicles, aircraft, and vessels with minimal latency and reliable connectivity.
- »Distributed traffic optimization
- »Cross-border autonomous navigation
- »Fail-safe redundant control systems
- »Real-time collision avoidance
Distributed AI Training
Massive parallel computation for AI model training using distributed datasets from global sources.
- »48 TPU units for neural processing
- »Federated learning across regions
- »Privacy-preserving computation
- »Model synchronization framework
Global Communications
Resilient, low-latency backbone for telecommunications, enabling advanced real-time collaboration and media distribution.
- »Global video conferencing at 8K
- »Holographic data transmission
- »Multi-node resilient routing
- »Quantum-secured communications
Defense & Security
Secure, resilient computing infrastructure for critical national security applications with global reach.
- »Air-gapped processing environments
- »Radiation-hardened hardware security
- »Zero-trust architecture
- »Sovereign computing zones
Industrial Partnership Program
VISCA Orbital Computing offers exclusive early access to select industry partners through our Industrial Partnership Program, providing dedicated orbital compute resources and specialized deployment capabilities.
Dedicated Resources — Guaranteed compute allocation in the orbital array
Technical Integration — Custom APIs and integration support for your specific use case
Priority Access — First access to new orbital nodes and expanded capabilities
Current Industry Partners
TECHNICAL SPECIFICATIONS
| COMPONENT | SPECIFICATION | DETAILS |
|---|---|---|
| Compute Infrastructure | Processors | Custom radiation-hardened ARM64 systems, 128-core per node |
| Accelerators | 48 TPU v5 units, distributed across constellation | |
| Memory | 1.2TB ECC LPDDR5X per node, radiation-tolerant with error correction | |
| Storage | 12PB distributed solid-state storage with triple redundancy | |
| Networking | Optical Inter-Satellite Links | 400 Gbps per link, full mesh topology with redundant pathways |
| Ground Link | Ka-band 50 Gbps downlink, 35 Gbps uplink per node | |
| Protocol | Orbital Transport Protocol v2 with dynamic routing optimization | |
| Latency | 25.6ms average global latency, 32.4ms P99 under peak load | |
| Security | Encryption | Post-quantum cryptography with 512-bit keys for all communications |
| Physical Security | Tamper-resistant hardware with automated fail-secure protocols | |
| Data Isolation | Hardware-enforced secure enclaves with dedicated memory regions | |
| Compliance | ISO 27001, NIST 800-53, GDPR, FedRAMP High-equivalent | |
| Environmental | Radiation Protection | Triple-redundant systems with radiation-hardened components |
| Thermal Management | Advanced passive cooling with active redundant thermal control | |
| Orbital Lifetime | 8-year minimum operational life with on-orbit servicing capability | |
| Deorbit System | Controlled reentry capability with 100% component burnup |
Resource Allocation Options
Platform Integration
- »APIs:REST, gRPC, GraphQL, WebSockets
- »Frameworks:TensorFlow, PyTorch, JAX, CUDA, MXNet
- »Languages:Python, C++, Rust, Go, Julia
- »Orchestration:Kubernetes, Nomad, Custom Orbital Scheduler
- »Data Formats:Parquet, Avro, ORC, Arrow, NetCDF, HDF5
- »Cloud Integration:Hybrid deployment with major cloud providers
REQUEST ACCESS
Program Requirements
Technical Requirements
- »Enterprise-level data processing needs
- »Global or multi-region operational footprint
- »Low-latency or real-time computational requirements
- »Advanced security or sovereignty requirements
Integration Capabilities
- »Modern API-driven architecture
- »DevOps or Infrastructure-as-Code processes
- »Technical team with cloud or distributed systems experience
- »Clear performance or scaling objectives
Partner Commitment
- »Minimum 12-month partnership agreement
- »Willingness to provide case study or reference (with NDA options)
- »Engineering collaboration for optimal integration
- »Regular performance and feedback reviews
Limited Availability
The Orbital Computing early access program is currently limited to qualified enterprise partners. Acceptance is based on technical requirements and strategic alignment.