Technology Solutions

At Graviton, our Technology Solutions is built around a transformative vision -the Software Defined Satellite (SDSat) paradigm. This approach redefines the boundaries of satellite system architecture by abstracting traditionally hardware-locked functionalities into flexible, software-configurable layers. At the heart of this vision is a modular, AI-native onboard computing and control platform that enables satellites to learn, adapt, and self-optimize in orbit, unlocking unprecedented levels of autonomy, agility, and mission longevity

Precision control | AI adaptation | Scalable

Attitude Determination & Control Systems

A software-defined, precision-engineered ADCS platform built to empower next-generation space missions with adaptability, autonomy, and accuracy.

Key Features

Software Defined ADCS Architecture

Implementing tradition hardware centric functionalities into software

In-Orbit Software Updates

Enables feature upgrades and optimizations post-deployment

Modular & Scalable Design

From basic attitude control to high-precision deep-space missions

High Precision Pointing

High-accuracy stabilization with efficient control tuning

Compute-Intensive Platform

Executes real-time, advanced control algorithms in orbit

Power-Optimized Operation

Intelligent resource management for long-duration missions

Adaptive & Configurable

Supports evolving mission profiles with minimal hardware changes

Fault-Tolerant System

Ensures operational continuity and autonomous fallback modes

Graviton’s software-defined ADCS powers a wide spectrum of mission profiles

Earth Observation

High-resolution imaging, SAR, multispectral/hyperspectral payloads requiring precise pointing and agile slewing.

Communication Satellites (LEO/MEO)

Stable nadir tracking, dynamic orientation for beam alignment, power-optimized control for extended life.

Deep-Space & Interplanetary Missions

Long-duration autonomy,

fault-tolerant navigation, trajectory correction with minimal ground intervention.

Constellations &  Formation Flying

Coordinated control for

multi-satellite systems,

inter-satellite alignment, rendezvous & docking maneuvers.

Making Satellites Think

Onboard
Computers

A mission-adaptive onboard computing platform with a modular flight software stack — delivering AI-native autonomy, deterministic control, and reconfigurable in-orbit logic for the next era of Software-Defined Satellites

Key Features

Cognitive Compute Architecture

Integrates high-performance cores with AI/ML acceleration engines and secure enclave computing

Real-Time Mission Kernel

Deterministic, mixed-criticality task execution with time-triggered scheduling and redundancy management

AI-Enabled Inference at the Edge

Supports in-flight learning, anomaly detection, and intelligent reconfiguration

Digital Twin Engine

Real-time mirrored state space model for prediction and optimization

Health Monitoring & Fault Management

Real-time diagnostics, watchdogs, fault injection recovery, and safe mode fallback

In-Orbit Reconfigurability

Modify control parameters, logic paths, and mission software without physical access

Secure Update Pipeline

Dual-image firmware with rollback, encrypted patching, and signed update validation

Sensor/Actuator Drivers & HAL

Abstraction layers for onboard devices supporting I²C, SPI, CAN, UART, and SpaceWire

Graviton's Cognitive Core engineered to support wide range of missions

Autonomous Earth Observation

In-orbit decision-making for image capture, compression, and transmission. Real-time onboard analytics with ML inference for event-based imaging. Region-of-interest targeting via integrated ADCS coordination.Autonomous Earth Observation

Adaptive  Communication Satellites

Software-defined routing and link management based on channel conditions. Onboard protocol stack reconfiguration with over-the-air updates. Real-time link health analysis and adaptive modulation selection.

Deep-Space Science Missions

Fault-tolerant onboard intelligence for extended autonomous operation. Onboard reconfiguration of mission objectives via scriptable FSW modules, intelligent anomaly detection, and mission state transitions without ground input.

Modular In-Orbit Technology Demonstrators

Enabling validation of new payloads, algorithms, or control strategies (e.g., BULSE). In-orbit code deployment and rollback for rapid experimentation.

Managing Data | Enabling Discovery

Payload Data
Handling Unit

A high-compute platform built to interface with advanced payloads — enabling reliable, high-throughput data processing, buffering, and transmission for next-generation space missions.

Key Features

High-Throughput Architecture

Designed to support raw data ingestion from high-data-rate payloads such as SAR, multispectral, and video imagers

GPU/FPGA-Enabled Compute Platform

Delivers parallelized processing support for custom user applications and sensor interfacing

In-Orbit Application Update Support

Enables reconfiguration and deployment of user software stacks or logic controllers

Modular Design

Built with scalable form factor for Nanosats to 300+ kg platforms

Embedded Mass Storage

Non-volatile, high-capacity memory for lossless mission data retention and prioritized downlinking

Flexible Interface Options

Compatible with Space Wire, LVDS, Ethernet, and redundant serial buses for payload data routing

Hardware Abstraction Layer (HAL)

Simplifies payload integration and ensures electrical/software interface consistency across mission variants

What Sets Graviton Apart

AI-Native
Architecture

From the compute layer to the mission software — enabling real-time learning, anomaly detection, and onboard autonomy.

Software-Defined
Spacecraft Philosophy

Graviton's subsystems are architected for dynamic mission evolution. In-orbit updates and modular hardware make your spacecraft as agile as your software.

In-Orbit
Reconfigurability

Whether it's flight logic, data handling behavior, or control loops — every system supports secure reprogramming, modular upgrades, and rollback-protected firmware management.

Edge-Ready
Performance

High-throughput, low-SWaP compute platforms designed for real-time execution, hardware acceleration (GPU/FPGA), and deterministic control.

Integrated Systems
Thinking

Tightly coupled OBC, ADCS, and PDHU units with shared design principles, interface abstraction, and architectural harmony — reducing integration time and increasing mission reliability.

Scalable Across
Mission Classes

From Nanosats to 330+ kg platforms, our subsystems are modular, stackable, and power-aware — delivering high performance without overengineering.

Join us on the journey

Be a part of the journey where every idea has a launch potential.
Think beyond Sky. Build beyond limits.

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