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Structured Review

Kaggle Inc bitcoin historical blockchain dataset
Schematic overview of the QCG-ST framework, showing how <t>blockchain</t> data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.
Bitcoin Historical Blockchain Dataset, supplied by Kaggle Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/historical+bitcoin+price+dataset/pmc12453740-151-1-12?v=Kaggle+Inc
Average 86 stars, based on 1 article reviews
bitcoin historical blockchain dataset - by Bioz Stars, 2026-07
86/100 stars

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Article Title: A novel framework for secure cryptocurrency transactions using quantum crypto guard

Journal: PeerJ Computer Science

doi: 10.7717/peerj-cs.3030

Schematic overview of the QCG-ST framework, showing how blockchain data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.
Figure Legend Snippet: Schematic overview of the QCG-ST framework, showing how blockchain data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.

Techniques Used: Biomarker Discovery

The hashed time‐lock contract (HTLC) steps for an atomic swap, party A first generates a random secret and its cryptographic hash (Step 1, “Hash Generation”). Next, both party A and party B use that hash in separate HTLCs to lock their respective assets on their own blockchains (Step 2, “Asset Locking”). Once both assets are securely locked under the hash condition, party A reveals the preimage (the original secret) to party B on the second blockchain (Step 3, “Secret Reveal”). Finally, party B uses the revealed secret to satisfy the hash lock on party A’s chain and claim the locked asset (Step 4, “Asset Claim”). Throughout this sequence, the hash lock ensures that each party can only claim the counterparty’s asset after the secret is disclosed, while a built‐in time lock guarantees that, if the swap does not complete within a specified timeframe, each party can reclaim their own locked asset.
Figure Legend Snippet: The hashed time‐lock contract (HTLC) steps for an atomic swap, party A first generates a random secret and its cryptographic hash (Step 1, “Hash Generation”). Next, both party A and party B use that hash in separate HTLCs to lock their respective assets on their own blockchains (Step 2, “Asset Locking”). Once both assets are securely locked under the hash condition, party A reveals the preimage (the original secret) to party B on the second blockchain (Step 3, “Secret Reveal”). Finally, party B uses the revealed secret to satisfy the hash lock on party A’s chain and claim the locked asset (Step 4, “Asset Claim”). Throughout this sequence, the hash lock ensures that each party can only claim the counterparty’s asset after the secret is disclosed, while a built‐in time lock guarantees that, if the swap does not complete within a specified timeframe, each party can reclaim their own locked asset.

Techniques Used: Sequencing



Similar Products

86
Kaggle Inc bitcoin historical blockchain dataset
Schematic overview of the QCG-ST framework, showing how <t>blockchain</t> data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.
Bitcoin Historical Blockchain Dataset, supplied by Kaggle Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/historical+bitcoin+price+dataset/pmc12453740-151-1-12?v=Kaggle+Inc
Average 86 stars, based on 1 article reviews
bitcoin historical blockchain dataset - by Bioz Stars, 2026-07
86/100 stars
  Buy from Supplier

86
Kaggle Inc bitcoin historical dataset
Schematic overview of the QCG-ST framework, showing how <t>blockchain</t> data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.
Bitcoin Historical Dataset, supplied by Kaggle Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/historical+bitcoin+price+dataset/pmc12453740-41-9-14?v=Kaggle+Inc
Average 86 stars, based on 1 article reviews
bitcoin historical dataset - by Bioz Stars, 2026-07
86/100 stars
  Buy from Supplier

86
Kaggle Inc historical bitcoin price dataset
Schematic overview of the QCG-ST framework, showing how <t>blockchain</t> data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.
Historical Bitcoin Price Dataset, supplied by Kaggle Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/historical+bitcoin+price+dataset/10__54105_slash_ijef__b1429__04021124-104-25-31?v=Kaggle+Inc
Average 86 stars, based on 1 article reviews
historical bitcoin price dataset - by Bioz Stars, 2026-07
86/100 stars
  Buy from Supplier

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Schematic overview of the QCG-ST framework, showing how blockchain data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.

Journal: PeerJ Computer Science

Article Title: A novel framework for secure cryptocurrency transactions using quantum crypto guard

doi: 10.7717/peerj-cs.3030

Figure Lengend Snippet: Schematic overview of the QCG-ST framework, showing how blockchain data flow from collection through Ring-LWE lattice encryption, transaction creation, PoS-based consensus, hashed-time-lock verification, and zero-knowledge proof validation to produce quan.

Article Snippet: The Bitcoin Historical Blockchain Dataset, which can be accessed for free on Kaggle, has been used to create the dataset for this study.

Techniques: Biomarker Discovery

The hashed time‐lock contract (HTLC) steps for an atomic swap, party A first generates a random secret and its cryptographic hash (Step 1, “Hash Generation”). Next, both party A and party B use that hash in separate HTLCs to lock their respective assets on their own blockchains (Step 2, “Asset Locking”). Once both assets are securely locked under the hash condition, party A reveals the preimage (the original secret) to party B on the second blockchain (Step 3, “Secret Reveal”). Finally, party B uses the revealed secret to satisfy the hash lock on party A’s chain and claim the locked asset (Step 4, “Asset Claim”). Throughout this sequence, the hash lock ensures that each party can only claim the counterparty’s asset after the secret is disclosed, while a built‐in time lock guarantees that, if the swap does not complete within a specified timeframe, each party can reclaim their own locked asset.

Journal: PeerJ Computer Science

Article Title: A novel framework for secure cryptocurrency transactions using quantum crypto guard

doi: 10.7717/peerj-cs.3030

Figure Lengend Snippet: The hashed time‐lock contract (HTLC) steps for an atomic swap, party A first generates a random secret and its cryptographic hash (Step 1, “Hash Generation”). Next, both party A and party B use that hash in separate HTLCs to lock their respective assets on their own blockchains (Step 2, “Asset Locking”). Once both assets are securely locked under the hash condition, party A reveals the preimage (the original secret) to party B on the second blockchain (Step 3, “Secret Reveal”). Finally, party B uses the revealed secret to satisfy the hash lock on party A’s chain and claim the locked asset (Step 4, “Asset Claim”). Throughout this sequence, the hash lock ensures that each party can only claim the counterparty’s asset after the secret is disclosed, while a built‐in time lock guarantees that, if the swap does not complete within a specified timeframe, each party can reclaim their own locked asset.

Article Snippet: The Bitcoin Historical Blockchain Dataset, which can be accessed for free on Kaggle, has been used to create the dataset for this study.

Techniques: Sequencing