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PRISM

Flight proven, electro-optical payloads for precision space observation.

OVERVIEW

The optical edge in space

Engineered for precision in the most demanding operational environments, the PRISM series of electro-optical sensors seamlessly integrates high-performance optics with advanced onboard processing to deliver real-time, mission-critical intelligence across dynamic orbital environments.

KEY FEATURES

High-speed,
low-light precision

Ultra-fast, low f-number optics enable high-resolution imaging even in low-light and dynamic environments.

Short exposure times reduce blur and distortion, making it ideal for fast-moving or faint objects.

    ADVANTAGES

    Beyond the specs

    End-to-End Assurance

    End-to-End Assurance

    We handle all of design, assembly, testing, and integration to ensure system-level performance and sovereign control.

    Flight Heritage

    Flight Heritage

    Validated in orbit and trusted by international agencies for operational reliability.

    Modular Design

    Modular Design

    Customised to mission-specific requirements for scalable performance and adaptability.

    APPLICATIONS

    PRISM in action

    From surveillance to servicing, Prism is purpose-built for data-rich operations across all orbital regimes and mission profiles.

    RSO Detection & Tracking

    RSO Cataloguing

    Missile Detection

    Orbital ISR

    Object Characterisation

    Autonomous Navigation

    RPO Imaging

    INNOVATION HUB

    Innovation in focus

    Thermospheric Density Forecasting using AI/ML

    One of the primary challenges in sustainable Low Earth Orbit (LEO) satellite operations is the accurate forecasting of thermospheric neutral densities, which exhibit significant variability with the solar cycle and during geomagnetic storms. Extreme space weather events, such as the Gannon storm of May 2024, can severely destabilize satellite orbits and potentially cause premature re-entry. Traditional forecasting approaches face inherent trade-offs: empirical models offer computational efficiency but limited accuracy, while physics-based models provide higher accuracy at the cost of computational intensity. This whitepaper describes Digantara’s proprietary Space Weather (SWx) solution, a novel AI-driven methodology that leverages machine learning techniques to identify complex relationships between space weather drivers and thermospheric densities. Digantara’s Thermospheric Density Forecasting Model utilizes a comprehensive training dataset spanning 24 years of density measurements derived from actual satellite observations, supplemented with synthetic data to enhance model robustness and coverage. The report presents the results of a testing framework performed at the company to assess the accuracy of the Thermospheric Density Forecasting Model.

    Robust Orbit Determination and Propagation Tool

    This whitepaper explores Digantara's robust pipeline for Initial Orbit Determination (IOD), Orbit Propagation (OP), and ephemeris generation. Central to these capabilities is our proprietary tool, OrEng, which plays a critical role in accurately identifying, tracking, and predicting Resident Space Objects (RSOs) in orbit. The whitepaper also presents a case study conducted at the company to assess the precision and accuracy of OrEng. For this study, the satellite Sentinel-3A (NORAD ID: 41335) was selected. The outcomes from OrEng, including state estimates and covariance, were compared with truth datasets obtained from the International Laser Ranging Service (ILRS).

    Multi-perspective Multi-modal PoL Characterization of LEO Objects

    The Pattern of Life (PoL) characterization of a satellite in Low Earth Orbit (LEO) is an intricate process demanding high fidelity data and robust data processing techniques. The solution to this complicated problem demands a methodology based on multiple perspectives and the ability to process, synthesize and correlate data from multiple sources of varying fidelity. Towards this objective, the current research proposes a dynamic and robust methodology to precisely characterize and synthesize PoL of satellites based on a multi-perspective multi-modal analysis, involving many aspects of a Space Domain Awareness (SDA) technological chain.

    Innovation in focus