Backchanneling Quantum Bit (Qubit) 'Shuffling': Quantum Bit (Qubit) 'Shuffling' as Added Security by Slipstreaming Q-Morse
Title | Backchanneling Quantum Bit (Qubit) 'Shuffling': Quantum Bit (Qubit) 'Shuffling' as Added Security by Slipstreaming Q-Morse |
Publication Type | Conference Paper |
Year of Publication | 2016 |
Authors | Ronczka, J. |
Conference Name | 2016 3rd Asia-Pacific World Congress on Computer Science and Engineering (APWC on CSE) |
Keywords | backchanneling quantum bit shuffling, backchanneling qubit shuffling, Backchannelling, backchannelling quantum Morse code, blockchain ledger history, blockchain security, Ciphers, codes, communication security, containment wave, Cypher, digital signature algorithm, DSA, ECDSA, elliptic curve digital signature algorithm, Entanglement, Internet of Things, Morse, predicted-expected sender-receiver properties, pubcrawl, public key cryptography, Quantum bit (Qubit), quantum computing, quantum cryptography, quantum cyphers, Quantum entanglement, random radicals, Resiliency, Rivest-Shamir-Adleman, RSA, Scalability, Sensors, Shuffling, slipstreaming Q-Morse code |
Abstract | A fresh look at the way secure communications is currently being done has been undertaken as a consequence of the large hacking's that have taken place recently. A plausible option maybe a return to the future via Morse code using how a quantum bit (Qubit) reacts when entangled to suggest a cypher. This quantum cyphers uses multiple properties of unique entities that have many random radicals which makes hacking more difficult that traditional 'Rivest-Shamir-Adleman' (RSA), 'Digital Signature Algorithm' (DSA) or 'Elliptic Curve Digital Signature Algorithm' (ECDSA). Additional security is likely by Backchannelling (slipstreaming) Quantum Morse code (Q-Morse) keys composed of living and non-living entities. This means Blockchain ledger history (forwards-backwards) is audited during an active session. Verification keys are Backchannelling (slipstreaming) during the session (e.g. train driver must incrementally activate a switch otherwise the train stops) using predicted-expected sender-receiver properties as well as their past history of disconformities to random radicals encountered. In summary, Quantum Morse code (Q-Morse) plausibly is the enabler to additional security by Backchannelling (slipstreaming) during a communications session. |
URL | https://ieeexplore.ieee.org/document/7941948/ |
DOI | 10.1109/APWC-on-CSE.2016.028 |
Citation Key | ronczka_backchanneling_2016 |
- random radicals
- predicted-expected sender-receiver properties
- pubcrawl
- public key cryptography
- Quantum bit (Qubit)
- quantum computing
- quantum cryptography
- quantum cyphers
- Quantum entanglement
- Morse
- Resiliency
- Rivest-Shamir-Adleman
- RSA
- Scalability
- sensors
- Shuffling
- slipstreaming Q-Morse code
- containment wave
- backchanneling qubit shuffling
- Backchannelling
- backchannelling quantum Morse code
- blockchain ledger history
- blockchain security
- Ciphers
- codes
- communication security
- backchanneling quantum bit shuffling
- Cypher
- digital signature algorithm
- DSA
- ECDSA
- elliptic curve digital signature algorithm
- Entanglement
- Internet of Things