On-chain Validation of Tracking Data Messages (TDM) Using Distributed Deep Learning on a Proof of Stake (PoS) Blockchain

Yasir Latif, Anirban Chowdhury, Samya Bagchi
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Abstract

Trustless tracking of Resident Space Objects (RSOs) is crucial for Space Situational Awareness (SSA), especially during adverse situations. The importance of transparent SSA cannot be overstated, as it is vital for ensuring space safety and security. In an era where RSO location information can be easily manipulated, the risk of RSOs being used as weapons is a growing concern. The Tracking Data Message (TDM) is a standardized format for broadcasting RSO observations. However, the varying quality of observations from diverse sensors poses challenges to SSA reliability. While many countries operate space assets, relatively few have SSA capabilities, making it crucial to ensure the accuracy and reliability of the data. Current practices assume complete trust in the transmitting party, leaving SSA capabilities vulnerable to adversarial actions such as spoofing TDMs. This work introduces a trustless mechanism for TDM validation and verification using deep learning over blockchain. By leveraging the trustless nature of blockchain, our approach eliminates the need for a central authority, establishing consensus-based truth. We propose a state-of-the-art, transformer-based orbit propagator that outperforms traditional methods like SGP4, enabling cross-validation of multiple observations for a single RSO. This deep learning-based transformer model can be distributed over a blockchain, allowing interested parties to host a node that contains a part of the distributed deep learning model. Our system comprises decentralised observers and validators within a Proof of Stake (PoS) blockchain. Observers contribute TDM data along with a stake to ensure honesty, while validators run the propagation and validation algorithms. The system rewards observers for contributing verified TDMs and penalizes those submitting unverifiable data.
在权益证明(PoS)区块链上使用分布式深度学习对追踪数据信息(TDM)进行链上验证
对驻留空间物体(RSO)的无信跟踪对于空间态势感知(SSA)至关重要,尤其是在不利情况下。透明空间态势感知的重要性无论如何强调都不为过,因为它对确保空间安全和安保至关重要。在遥感卫星位置信息容易被操纵的时代,遥感卫星被用作武器的风险日益令人担忧。跟踪数据报文(TDM)是一种用于广播 RSO 观测数据的标准化格式。然而,来自不同传感器的观测数据质量参差不齐,给 SSA 的可靠性带来了挑战。虽然许多国家都在运营空间资产,但拥有 SSA 能力的国家相对较少,因此确保数据的准确性和可靠性至关重要。目前的做法是假定对发送方完全信任,从而使 SSA 能力容易受到诸如欺骗 TDM 等敌对行动的影响。这项研究利用区块链上的深度学习,为 TDM 验证和核实引入了一种无信任机制。通过利用区块链的无信任特性,我们的方法消除了对中央机构的需求,建立了基于共识的真相。我们提出了一种最先进的基于变换器的轨道传播器,其性能优于 SGP4 等传统方法,可对单个 RSO 的多个观测值进行交叉验证。这种基于深度学习的变换模型可以通过区块链进行分发,允许相关方托管一个包含部分分布式深度学习模型的节点。我们的系统包括权益证明(PoS)区块链中的去中心化观测者和验证者。观察者贡献 TDM 数据和股权以确保诚实,验证者则运行传播和验证算法。该系统奖励提交已验证 TDM 数据的观察者,惩罚提交不可验证数据的观察者。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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