References - Wikipedia

[1] Crawford, K. (2021). _Atlas of AI: Power, Politics, and the Planetary Costs of Artificial Intelligence_. Yale University Press. [2] Liang, P. and Bommasani, R. and Lee, T. and Tsipras, D. and Soylu, D. and Yasunaga, M. and others (2022). Holistic evaluation of language models. _arXiv preprint arXiv:2211.09110_. [3] Sabt, M. and Achemlal, M. and Bouabdallah, A. (2015). Trusted execution environment: What it is, and what it is not. In _2015 IEEE Trustcom/BigDataSE/ISPA_ (Vol. 1, pp. 57--64). [4] Sasson, E. B. and Chiesa, A. and Garman, C. and Green, M. and Miers, I. and Tromer, E. and Virza, M. (2014). Zerocash: Decentralized anonymous payments from Bitcoin. In _2014 IEEE Symposium on Security and Privacy_ (pp. 459--474). [5] Bommasani, R. and Hudson, D. A. and Adeli, E. and Altman, R. and Arora, S. and von Arx, S. and others (2021). On the opportunities and risks of foundation models. _arXiv preprint arXiv:2108.07258_. [6] Mohassel, P. and Zhang, Y. (2017). SecureML: A system for scalable privacy-preserving machine learning. In _2017 IEEE Symposium on Security and Privacy (SP)_ (pp. 19--38). [7] Narayanan, A. and Bonneau, J. and Felten, E. and Miller, A. and Goldfeder, S. (2016). _Bitcoin and Cryptocurrency Technologies: A Comprehensive Introduction_. Princeton University Press. [8] Goldwasser, S. and Micali, S. and Rackoff, C. (1985). The knowledge complexity of interactive proof-systems. In _Proceedings of the Seventeenth Annual ACM Symposium on Theory of Computing_ (pp. 291--304). [9] Reitwiessner, C. (2016). zk-SNARKs: A practical introduction. _Ethereum Blog_. [10] Gentry, C. (2009). Fully homomorphic encryption using ideal lattices. In _Proceedings of the Forty-First Annual ACM Symposium on Theory of Computing_ (pp. 169--178). [11] Acar, A. and Aksu, H. and Uluagac, A. S. and Conti, M. (2018). A survey on homomorphic encryption schemes: Theory and implementation. _ACM Computing Surveys (CSUR)_, 51(4), 1--35. [12] Benet, J. (2014). IPFS - Content Addressed, Versioned, P2P File System. _arXiv preprint arXiv:1407.3561_. [13] Protocol Labs (2017). _Filecoin: A Decentralized Storage Network_. [14] Buchman, E. (2016). _Tendermint: Byzantine Fault Tolerance in the Age of Blockchains_. Master's thesis, University of Guelph. [15] Cosmos (2023). _Cosmos SDK Documentation_. [16] McConaghy, T. and Marques, R. and Muller, A. and De Jonghe, D. and McConaghy, T. and McMullen, G. and Allison, I. (2017). _Ocean Protocol: A Decentralized Data Exchange Protocol_. [17] Russell, S. (2019). _Human Compatible: Artificial Intelligence and the Problem of Control_. Viking. [18] Merkle, R. C. (1988). A digital signature based on a conventional encryption function. In _Advances in Cryptology --- CRYPTO '87_ (pp. 369--378). Springer. [19] Wood, G. (2014). _Ethereum: A Secure Decentralised Generalised Transaction Ledger_. Ethereum Yellow Paper. [20] Johnson, D. and Menezes, A. and Vanstone, S. (2001). The Elliptic Curve Digital Signature Algorithm (ECDSA). _International Journal of Information Security_, 1(1), 36--63. [21] Bernstein, D. J. and Duif, N. and Lange, T. and Schwabe, P. and Yang, B. Y. (2012). High-speed high-security signatures. _Journal of Cryptographic Engineering_, 2(2), 77--89. [22] Dziembowski, S. and Faust, S. and Kolmogorov, V. and Pietrzak, K. (2015). Proofs of Space. In _Advances in Cryptology --- CRYPTO 2015_ (pp. 585--605). Springer. [23] Ben-Sasson, E. and Bentov, I. and Horesh, Y. and Riabzev, M. (2018). Scalable, transparent, and post-quantum secure computational integrity. _Cryptology ePrint Archive, Report 2018/046_. [24] Ben-Sasson, E. and Chiesa, A. and Garman, C. and Green, M. and Miers, I. and Tromer, E. and Virza, M. (2014). Zerocash: Decentralized anonymous payments from Bitcoin. In _2014 IEEE Symposium on Security and Privacy_ (pp. 459--474). [25] Maymounkov, P. and Mazieres, D. (2002). Kademlia: A peer-to-peer information system based on the XOR metric. In _Proceedings of the 1st International Workshop on Peer-to-Peer Systems (IPTPS)_ (pp. 53--65). Springer. [26] Seagate (2023). _Hard Drive Power Consumption_. [27] Cambridge Bitcoin Electricity Consumption Index (2023). [28] Reed, I. S. and Solomon, G. (1960). Polynomial codes over certain finite fields. _Journal of the Society for Industrial and Applied Mathematics_, 8(2), 300--304. [29] Pinata (2023). _Pinata Documentation_. [30] Groth, J. (2016). On the size of pairing-based non-interactive arguments. In _Advances in Cryptology --- EUROCRYPT 2016_ (pp. 305--326). Springer. [31] Tendermint Team (2023). _Tendermint Performance Benchmarks_. [32] Groth, J. (2016). On the size of pairing-based non-interactive arguments. In _Advances in Cryptology --- EUROCRYPT 2016_ (pp. 305--326). Springer. [33] IPFS Documentation (2023). _Measuring the IPFS Network_. [34] Benet, J. (2014). _IPFS Whitepaper: Content Addressed, Versioned, P2P File System_. [35] Peertechz Publications (2023). Assessment of energy storage technologies for case studies with increased renewable energy penetration. _Peertechz Publications_. [36] Kosba, A. and others (2020). zk-SNARKs for deep learning. In _Conference on Cryptographic Hardware and Embedded Systems (CHES 2020)_ (pp. 1--20). Springer. [37] Wahby, R. S. and others (2022). Efficient zero-knowledge proofs for neural networks. _Cryptology ePrint Archive, Report 2022/123_. [38] Bootle, J. and others (2016). Efficient zero-knowledge proofs for arithmetic circuits. In _Advances in Cryptology --- EUROCRYPT 2016_ (pp. 1--25). Springer. [39] Ben-Sasson, E. and others (2019). On the concrete efficiency of zk-SNARKs. _Cryptology ePrint Archive, Report 2019/456_. [40] Chen, Y. and others (2021). Decentralized storage: Principles, systems, and the road ahead. _IEEE Transactions on Cloud Computing_, 9(3), 456--467. [41] StarkWare (2022). _zk-Rollups: A Comprehensive Overview_. StarkWare Industries. [42] Optimism Team (2023). _Decentralized Rollup Operators: Design and Analysis_. Optimism Documentation. [43] Matter Labs (2023). _zkSync: Scaling Ethereum with zk-Rollups_. zkSync Whitepaper. [44] Ben-Sasson, E. and others (2019). On the concrete efficiency of zk-SNARKs. _Cryptology ePrint Archive, Report 2019/457_. [45] Micali, S. (1994). CS proofs. In _Foundations of Computer Science_ (pp. 436--453). [46] Bunz, B. and others (2020). Bulletproofs: Short proofs for confidential transactions. In _IEEE Symposium on Security and Privacy_ (pp. 123--145). [47] Chiesa, A. and others (2019). Marlin: Preprocessing zkSNARKs with universal SRS. _Cryptology ePrint Archive, Report 2019/1047_. [48] Haas, A. and others (2017). Bringing the web up to speed with WebAssembly. In _PLDI 2017_. [49] Valiant, P. (2008). Incrementally verifiable computation. In _FOCS 2008_ (pp. 567--576). [50] Ethereum Foundation (2023). _Ethereum Precompiled Contracts_. [51] Strassen, V. (1969). Gaussian elimination is not optimal. _Numerische Mathematik_, 13(4), 354--356. [52] Albrecht, M. R. and others (2018). Implementing RLWE-based schemes using an RSA co-processor. _Transactions on Cryptographic Hardware and Embedded Systems_, 2018(1), 169--208. [53] Ben-Sasson, E. and others (2020). AuroraLight: Improved prover efficiency and SRS size in a Sonic-like system. _Cryptology ePrint Archive, Report 2020/1357_. [54] Ames, S. and Hazay, C. and Ishai, Y. and Venkitasubramaniam, M. (2017). Ligero: Lightweight sublinear arguments without a trusted setup. In _Proceedings of the 2017 ACM SIGSAC Conference on Computer and Communications Security_ (pp. 2087--2104). [55] Bootle, J. and others (2020). Efficient zero-knowledge proof systems. In _Handbook of Financial Cryptography and Security_ (pp. 37--62). [56] Wahby, R. S. and others (2020). Doubly-efficient zkSNARKs without trusted setup. In _IEEE Symposium on Security and Privacy (SP)_ (pp. 921--938). [57] Groth, J. and others (2018). Updatable and universal common reference strings with applications to zk-SNARKs. In _Advances in Cryptology --- CRYPTO 2018_ (pp. 698--728). Springer. [58] Chiesa, A. and others (2021). Proof-carrying data from accumulation schemes. _Cryptology ePrint Archive, Report 2021/1215_. [59] Bowe, S. and others (2019). Halo: Recursive proof composition without a trusted setup. _Cryptology ePrint Archive, Report 2019/1021_. [60] Gabizon, A. and Williamson, Z. J. and Ciobotaru, O. (2019). PLONK: Permutations over Lagrange-bases for oecumenical noninteractive arguments of knowledge. _Cryptology ePrint Archive, Report 2019/953_. [61] Boneh, D. and others (2020). Halo Infinite: Proof-carrying data from additive polynomial commitments. _Cryptology ePrint Archive, Report 2020/1536_. [62] Tendermint Team (2023). _Tendermint Documentation_. [63] Cosmos (2023). _Cosmos SDK Documentation_. [64] Wood, G. (2014). _Ethereum: A Secure Decentralised Generalised Transaction Ledger_. Ethereum Yellow Paper. [65] Haas, A. and others (2017). Bringing the web up to speed with WebAssembly. In _PLDI 2017_. [66] Circom Team (2023). _Circom Documentation_. [67] ZoKrates Team (2023). _ZoKrates Documentation_. [68] Merkle, R. C. (1988). A digital signature based on a conventional encryption function. In _Advances in Cryptology --- CRYPTO '87_. Springer. [69] Groth, J. (2016). On the size of pairing-based non-interactive arguments. _EUROCRYPT 2016_. [70] Ben-Sasson, E. and others (2018). Scalable, transparent, and post-quantum secure computational integrity. _Cryptology ePrint Archive, Report 2018/046_. [71] Johnson, D. and Menezes, A. and Vanstone, S. (2001). The Elliptic Curve Digital Signature Algorithm (ECDSA). _International Journal of Information Security_, 1(1), 36--63. [72] Bernstein, D. J. and others (2012). High-speed high-security signatures. _Journal of Cryptographic Engineering_, 2(2), 77--89. [73] Gentry, C. (2009). Fully homomorphic encryption using ideal lattices. _Proceedings of the Forty-First Annual ACM Symposium on Theory of Computing_, 169--178. [74] Albrecht, M. R. and others (2019). Poseidon: A new hash function for zero-knowledge proof systems. _Cryptology ePrint Archive, Report 2019/458_. [75] Chiesa, A. and others (2019). Marlin: Preprocessing zkSNARKs with universal SRS. _Cryptology ePrint Archive, Report 2019/1047_. [76] Cadwalladr, C. and Graham-Harrison, E. (2018). Revealed: 50 million Facebook profiles harvested for Cambridge Analytica in major data breach. _The Guardian_. [77] Goldwasser, S. and Micali, S. (1982). _Journal of Computer and System Sciences_. [78] Nakamoto, S. (2008). _Bitcoin Whitepaper_. [79] Miller, A. and others (2014). _IEEE Symposium on Security and Privacy_. [80] Wood, G. (2014). _Ethereum Yellow Paper_. [81] Ethereum Foundation (2023). _Ethereum.org_. [82] Starkware (2022). _StarkNet Documentation_. [83] Vogelsteller, F. and Buterin, V. (2015). ERC-20 EIP. [84] Buterin, V. (2017). _Ethereum Blog_. [85] Buterin, V. (2017). _Ethereum Whitepaper_. [86] Antonopoulos, A. M. and Wood, G. (2018). _Mastering Ethereum_. [87] Benet, J. (2014). _arXiv:1407.3561_. [88] Ben-Sasson, E. and others (2014). _USENIX Security Symposium_. [89] Groth, J. (2016). _EUROCRYPT_. [90] Daemen, J. and Rijmen, V. (2002). Springer. [91] Protocol Labs (2017). _Filecoin: A Decentralized Storage Network_. Filecoin Whitepaper. [92] Chainlink Team (2020). _Chainlink Whitepaper: A Decentralized Oracle Network_. [93] Kairouz, P. and others (2021). Advances and open problems in federated learning. _Foundations and Trends in Machine Learning_. [94] McMahan, H. B. and others (2017). Communication-efficient learning of deep networks from decentralized data. In _Proceedings of the 20th International Conference on Artificial Intelligence and Statistics (AISTATS)_. [95] Berghel, H. (2017). Equifax and the latest round of identity theft roulette. _IEEE Computer_, 50(12), 72--76. [96] Chen, T. and others (2017). Understanding Ethereum gas: A comprehensive analysis of transaction costs. _IEEE Transactions on Network and Service Management_. [97] Kalodner, H. and others (2020). zk-Rollups: Scalable privacy-preserving smart contracts. _IACR Cryptology ePrint Archive_. [98] Gennaro, R. and others (2018). Threshold-optimal DSA/ECDSA signatures and an application to Bitcoin wallet security. In _International Conference on Applied Cryptography and Network Security (ACNS)_. [99] Zhang, Q. and others (2022). Optimizing IPFS for large-scale data storage: A performance study. _IEEE International Conference on Blockchain and Cryptocurrency (ICBC)_. [100] _Privacy-Preserving Techniques in Generative AI and Large Language Models_ (2024). MDPI. [101] _Preserving Data Privacy in Machine Learning Systems_ (2024). ScienceDirect. [102] _Privacy-First: A Look at Cutting-Edge Privacy-Enhancing Technologies_ (2024). Velotix. [103] _Data Masking: Protecting Sensitive Information_ (2024). Snowflake. [104] _Privacy-Preserving Technologies: Advancements and Impact on Digital Security_ (2024). GIRA Group. [105] _Advancements in Privacy-Preserving Techniques for Federated Learning: A Machine Learning Perspective_ (2024). ResearchGate. [106] _Privacy-Enhancing Technologies Overview_ (2024). Wikipedia. [107] Parity Technologies (2024). _Substrate: A Modular Framework for Building Blockchains_. [108] Wood, G. and Parity Technologies (2024). _Substrate Developer Hub Documentation_. [109] Stewart, A. and Kokoris-Kogia, E. and Jovanovic, P. and Gasser, L. and Gailly, N. and Khoffi, I. and Ford, B. (2019). BABE: Blind Assignment for Blockchain Extension. _Web3 Foundation Research_. [110] Stewart, A. and Kokoris-Kogia, E. (2020). GRANDPA: A Byzantine Fault Tolerant Finality Gadget. _Web3 Foundation Research_. [111] Parity Technologies (2024). _FRAME: Framework for Runtime Aggregation of Modularized Entities_. [112] Parity Technologies (2024). _EVM Pallet: Ethereum Virtual Machine for Substrate_. [113] Parity Technologies (2024). _Frontier: Ethereum Compatibility Layer for Substrate_. [114] Morrison, D. R. (1968). PATRICIA—Practical Algorithm to Retrieve Information Coded in Alphanumeric. _Journal of the ACM_, 15(4), 514-534. [115] Wood, G. and Parity Technologies (2024). _Cross-Chain Message Passing (XCMP) Protocol_. Polkadot Wiki. [116] Parity Technologies (2024). _Substrate Runtime Events and Dispatch_. [117] Parity Technologies (2024). _Substrate Transaction Weights and Fees_. [118] Parity Technologies (2024). _Substrate Performance Benchmarks and Optimization_. [119] Parity Technologies (2024). _Substrate WASM Runtime Environment_. [120] Parity Technologies (2024). _Substrate Off-chain Workers_. [121] Parity Technologies (2024). _Substrate Custom Pallets for Zero-Knowledge Verification_. [122] Stewart, A. and Kokoris-Kogia, E. (2019). _Randomness Beacon in BABE Consensus_. Web3 Foundation Research. [123] Parity Technologies (2024). _Substrate Assets Pallet and Token Standards_. [124] Parity Technologies (2024). _Substrate Democracy Pallet_.