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Quantum Computing
and Blockchain:
Facts and Myths
Prof. Ahmed Banafa
Quantum Computing and Blockchain :
Facts and Myths
Prof. Ahmed Banafa
IoT-Blockchain-AI Expert | Faculty | Author | Keynote Speaker
Continuing Studies –Stanford
College of Engineering- San Jose State University CA, USA
Prof. Ahmed Banafa has extensive research work with
focus on IoT, Blockchain, cybersecurity and AI. He
served as a faculty at well-known universities and
colleges.
He is the recipient of several awards, including
Distinguished Tenured Staff Award, Instructor of the
the year and Certificate of Honor from the City and
County of San Francisco.
He was named as No.1 tech voice to follow by LinkedIn
LinkedIn (with 38k+ followers ), featured in Forbes,
Forbes, IEEE-IoT and MIT Technology Review, with
with frequent appearances on ABC, CBS, NBC, BBC and
and Fox TV and Radio stations.
He studied Electrical Engineering at Lehigh University,
University, Cybersecurity at Harvard University, and
and Digital Transformation at MIT .
Prof. Ahmed Banafa
SJSU Annual Author &
Artist Award for 2019
Jan 2020
• The biggest danger to Blockchain networks from quantum computing
is its ability to break traditional encryption [3].
• Google sent shock waves around the internet when it was claimed,
had built a quantum computer able to solve formerly impossible
mathematical calculations–with some fearing crypto industry could
be at risk [7].
• Google states that its experiment is the first experimental challenge
against the extended Church-Turing thesis — also known as
computability thesis — which claims that traditional computers can
effectively carry out any “reasonable” model of computation
• What is Quantum Computing?
• Quantum computing is the area of study focused on developing
computer technology based on the principles of quantum theory.
• The quantum computer, following the laws of quantum physics,
would gain enormous processing power through the ability to be in
multiple states, and to perform tasks using all possible permutations
simultaneously [5].
• A Comparison of Classical and Quantum Computing
• Classical computing relies, at its ultimate level, on principles
expressed by Boolean algebra. Data must be processed in an
exclusive binary state at any point in time or bits.
• While the time that each transistor or capacitor need be either in 0 or
1 before switching states is now measurable in billionths of a second,
there is still a limit as to how quickly these devices can be made to
switch state.
• As we progress to smaller and faster circuits, we begin to reach the
physical limits of materials and the threshold for classical laws of
physics to apply.
• Beyond this, the quantum world takes over.
• In a quantum computer, a number of elemental particles such as
electrons or photons can be used with either their charge or
polarization acting as a representation of 0 and/or 1.
• Each of these particles is known as a quantum bit, or qubit, the
nature and behavior of these particles form the basis of quantum
computing [5].
• Quantum Superposition and Entanglement
• The two most relevant aspects of quantum physics are the principles
of superposition and entanglement.
• Superposition: Think of a qubit as an electron in a magnetic field.
• The electron's spin may be either in alignment with the field, which is
known as a spin-up state, or opposite to the field, which is known as a
spin-down state.
• According to quantum law, the particle enters a superposition of
states, in which it behaves as if it were in both states simultaneously.
Each qubit utilized could take a superposition of both 0 and 1.
• Entanglement: Particles that have interacted at some point retain a
type of connection and can be entangled with each other in pairs, in a
process known as correlation.
• Knowing the spin state of one entangled particle - up or down - allows
one to know that the spin of its mate is in the opposite direction.
• Quantum entanglement allows qubits that are separated by
incredible distances to interact with each other instantaneously (not
limited to the speed of light).
• No matter how great the distance between the correlated particles,
they will remain entangled as long as they are isolated. Taken
together, quantum superposition and entanglement create an
enormously enhanced computing power.
• Where a 2-bit register in an ordinary computer can store only one of
four binary configurations (00, 01, 10, or 11) at any given time, a 2-
qubit register in a quantum computer can store all four numbers
simultaneously, because each qubit represents two values.
• If more qubits are added, the increased capacity is expanded
exponentially [5].
• Difficulties with Quantum Computers
• Interference - During the computation phase of a quantum
calculation, the slightest disturbance in a quantum system (say a stray
photon or wave of EM radiation) causes the quantum computation to
collapse, a process known as de-coherence.
• A quantum computer must be totally isolated from all external
interference during the computation phase.
• Error correction - Given the nature of quantum computing, error
correction is ultra-critical - even a single error in a calculation can
cause the validity of the entire computation to collapse.
• Output observance - Closely related to the above two, retrieving
output data after a quantum calculation is complete risks corrupting
the data.
• What is Quantum Supremacy ?
• According to the Financial Times, Google claims to have successfully
built the world’s most powerful quantum computer [7].
• What that means, according to Google’s researchers, is that
calculations that normally take more than 10,000 years to perform,
its computer was able to do in about 200 seconds, and potentially
mean Blockchain, and the encryption that underpins it, could be
broken.
• Asymmetric cryptography used in crypto relies on key pairs, namely a
private and public key.
• Public keys can be calculated from their private counterpart, but not
the other way around.
• This is due to the impossibility of certain mathematical problems.
• Quantum computers are more efficient in accomplishing this by
magnitudes, and if the calculation is done the other way then the
whole scheme breaks [3].
• It would appear Google is still some way away from building a
quantum computer that could be a threat to Blockchain cryptography
or other encryption.
• "Google's supercomputer currently has 53 qubits," said Dragos Ilie, a
quantum computing and encryption researcher at Imperial College
London.
• "In order to have any effect on bitcoin or most other financial systems
it would take at least about 1500 qubits and the system must allow
for the entanglement of all of them," Ilie said.
• Meanwhile, scaling quantum computers is "a huge challenge,"
according to Ilie [1].
• Blockchain networks including Bitcoin’s architecture relies on two
algorithms: Elliptic Curve Digital Signature Algorithm (ECDSA) for
digital signatures and SHA-256 as a hash function.
• A quantum computer could use Shor’s algorithm [8] to get your
private from your public key, but the most optimistic scientific
estimates say that even if this were possible, it won’t happen during
this decade.
• “A 160 bit elliptic curve cryptographic key could be broken on a
quantum computer using around 1000 qubits while factoring the
security-wise equivalent 1024 bit RSA modulus would require about
2000 qubits”.
• By comparison, Google's measly 53 qubits are still no match for this
kind of cryptography. According to research paper on the matter
published by Cornell University.
• But that isn’t to say that there’s no cause for alarm.
• While the native encryption algorithms used by Blockchain’s
applications are safe for now, the fact is that the rate of
advancements in quantum technology is increasing, and that could, in
time, pose a threat.
• "We expect their computational power will continue to grow at a
double exponential rate," Google researchers.
• Quantum Cryptography?
• Quantum cryptography uses physics to develop a cryptosystem
completely secure against being compromised without knowledge of
the sender or the receiver of the messages.
• The word quantum itself refers to the most fundamental behavior of
the smallest particles of matter and energy.
• Quantum cryptography is different from traditional cryptographic
systems in that it relies more on physics, rather than mathematics, as
a key aspect of its security model.
• Essentially, quantum cryptography is based on the usage of individual
particles/waves of light (photon) and their intrinsic quantum
properties to develop an unbreakable cryptosystem (because it is
impossible to measure the quantum state of any system without
disturbing that system.)
• Quantum cryptography uses photons to transmit a key. Once the key
is transmitted, coding and encoding using the normal secret-key
method can take place.
• But how does a photon become a key? How do you attach
information to a photon's spin?
• This is where binary code comes into play.
• Each type of a photon's spin represents one piece of information --
usually a 1 or a 0, for binary code.
• This code uses strings of 1s and 0s to create a coherent message.
• For example, 11100100110 could correspond with h-e-l-l-o. So a
binary code can be assigned to each photon -- for example, a photon
that has a vertical spin ( | ) can be assigned a 1.
• “If you build it correctly, no hacker can hack the system.
• The question is what it means to build it correctly,” said physicist
Renato Renner from the Institute of Theoretical Physics in Zurich.
• Regular, non-quantum encryption can work in a variety of ways but
generally a message is scrambled and can only be unscrambled using
a secret key.
• The trick is to make sure that whomever you’re trying to hide your
communication from doesn’t get their hands on your secret key.
• Cracking the private key in a modern crypto system would generally
require figuring out the factors of a number that is the product of
two insanely huge prime numbers.
• The numbers are chosen to be so large that, with the given processing
power of computers, it would take longer than the lifetime of the
universe for an algorithm to factor their product.
• Encryption techniques have their vulnerabilities.
• Certain products – called weak keys – happen to be easier to factor
than others.
• Also, Moore’s Law continually ups the processing power of our
computers.
• Even more importantly, mathematicians are constantly developing
new algorithms that allow for easier factorization.
• Quantum cryptography avoids all these issues.
• Here, the key is encrypted into a series of photons that get passed
between two parties trying to share secret information.
• The Heisenberg Uncertainty Principle dictates that an adversary can’t
look at these photons without changing or destroying them.
• “In this case, it doesn’t matter what technology the adversary has,
they’ll never be able to break the laws of physics,” said physicist
Richard Hughes of Los Alamos National Laboratory in New Mexico,
who works on quantum cryptography [6].
References:
• [1] https://www.forbes.com/sites/billybambrough/2019/10/02/could-google-be-
about-to-break-bitcoin/#1d78c5373329
• [2] https://decrypt.co/9642/what-google-quantum-computer-means-for-bitcoin/
• [3] https://www.coindesk.com/how-should-crypto-prepare-for-googles-quantum-
supremacy?
• [4] https://www.ccn.com/google-quantum-bitcoin/
• [5] https://www.linkedin.com/pulse/20140503185010-246665791-quantum-
computing/
• [6] https://www.linkedin.com/pulse/20140608053056-246665791-
understanding-quantum-cryptography/
• [7] https://ai.googleblog.com/2019/10/quantum-supremacy-using-
programmable.html
• [8] https://qudev.phys.ethz.ch/static/content/QSIT15/Shors%20Algorithm.pdf
Thank you!
https://www.linkedin.com/in/ahmedbanafa (38k followers)
@BanafaAhmed

More Related Content

Quantum Computing and Blockchain: Facts and Myths

  • 1. Quantum Computing and Blockchain: Facts and Myths Prof. Ahmed Banafa
  • 2. Quantum Computing and Blockchain : Facts and Myths Prof. Ahmed Banafa IoT-Blockchain-AI Expert | Faculty | Author | Keynote Speaker Continuing Studies –Stanford College of Engineering- San Jose State University CA, USA
  • 3. Prof. Ahmed Banafa has extensive research work with focus on IoT, Blockchain, cybersecurity and AI. He served as a faculty at well-known universities and colleges. He is the recipient of several awards, including Distinguished Tenured Staff Award, Instructor of the the year and Certificate of Honor from the City and County of San Francisco. He was named as No.1 tech voice to follow by LinkedIn LinkedIn (with 38k+ followers ), featured in Forbes, Forbes, IEEE-IoT and MIT Technology Review, with with frequent appearances on ABC, CBS, NBC, BBC and and Fox TV and Radio stations. He studied Electrical Engineering at Lehigh University, University, Cybersecurity at Harvard University, and and Digital Transformation at MIT . Prof. Ahmed Banafa
  • 4. SJSU Annual Author & Artist Award for 2019
  • 6. • The biggest danger to Blockchain networks from quantum computing is its ability to break traditional encryption [3].
  • 7. • Google sent shock waves around the internet when it was claimed, had built a quantum computer able to solve formerly impossible mathematical calculations–with some fearing crypto industry could be at risk [7].
  • 8. • Google states that its experiment is the first experimental challenge against the extended Church-Turing thesis — also known as computability thesis — which claims that traditional computers can effectively carry out any “reasonable” model of computation
  • 9. • What is Quantum Computing? • Quantum computing is the area of study focused on developing computer technology based on the principles of quantum theory. • The quantum computer, following the laws of quantum physics, would gain enormous processing power through the ability to be in multiple states, and to perform tasks using all possible permutations simultaneously [5].
  • 10. • A Comparison of Classical and Quantum Computing • Classical computing relies, at its ultimate level, on principles expressed by Boolean algebra. Data must be processed in an exclusive binary state at any point in time or bits.
  • 11. • While the time that each transistor or capacitor need be either in 0 or 1 before switching states is now measurable in billionths of a second, there is still a limit as to how quickly these devices can be made to switch state.
  • 12. • As we progress to smaller and faster circuits, we begin to reach the physical limits of materials and the threshold for classical laws of physics to apply.
  • 13. • Beyond this, the quantum world takes over. • In a quantum computer, a number of elemental particles such as electrons or photons can be used with either their charge or polarization acting as a representation of 0 and/or 1.
  • 14. • Each of these particles is known as a quantum bit, or qubit, the nature and behavior of these particles form the basis of quantum computing [5].
  • 15. • Quantum Superposition and Entanglement • The two most relevant aspects of quantum physics are the principles of superposition and entanglement.
  • 16. • Superposition: Think of a qubit as an electron in a magnetic field. • The electron's spin may be either in alignment with the field, which is known as a spin-up state, or opposite to the field, which is known as a spin-down state.
  • 17. • According to quantum law, the particle enters a superposition of states, in which it behaves as if it were in both states simultaneously. Each qubit utilized could take a superposition of both 0 and 1.
  • 18. • Entanglement: Particles that have interacted at some point retain a type of connection and can be entangled with each other in pairs, in a process known as correlation.
  • 19. • Knowing the spin state of one entangled particle - up or down - allows one to know that the spin of its mate is in the opposite direction. • Quantum entanglement allows qubits that are separated by incredible distances to interact with each other instantaneously (not limited to the speed of light).
  • 20. • No matter how great the distance between the correlated particles, they will remain entangled as long as they are isolated. Taken together, quantum superposition and entanglement create an enormously enhanced computing power.
  • 21. • Where a 2-bit register in an ordinary computer can store only one of four binary configurations (00, 01, 10, or 11) at any given time, a 2- qubit register in a quantum computer can store all four numbers simultaneously, because each qubit represents two values. • If more qubits are added, the increased capacity is expanded exponentially [5].
  • 22. • Difficulties with Quantum Computers • Interference - During the computation phase of a quantum calculation, the slightest disturbance in a quantum system (say a stray photon or wave of EM radiation) causes the quantum computation to collapse, a process known as de-coherence. • A quantum computer must be totally isolated from all external interference during the computation phase.
  • 23. • Error correction - Given the nature of quantum computing, error correction is ultra-critical - even a single error in a calculation can cause the validity of the entire computation to collapse. • Output observance - Closely related to the above two, retrieving output data after a quantum calculation is complete risks corrupting the data.
  • 24. • What is Quantum Supremacy ? • According to the Financial Times, Google claims to have successfully built the world’s most powerful quantum computer [7]. • What that means, according to Google’s researchers, is that calculations that normally take more than 10,000 years to perform, its computer was able to do in about 200 seconds, and potentially mean Blockchain, and the encryption that underpins it, could be broken.
  • 25. • Asymmetric cryptography used in crypto relies on key pairs, namely a private and public key. • Public keys can be calculated from their private counterpart, but not the other way around. • This is due to the impossibility of certain mathematical problems. • Quantum computers are more efficient in accomplishing this by magnitudes, and if the calculation is done the other way then the whole scheme breaks [3].
  • 26. • It would appear Google is still some way away from building a quantum computer that could be a threat to Blockchain cryptography or other encryption. • "Google's supercomputer currently has 53 qubits," said Dragos Ilie, a quantum computing and encryption researcher at Imperial College London.
  • 27. • "In order to have any effect on bitcoin or most other financial systems it would take at least about 1500 qubits and the system must allow for the entanglement of all of them," Ilie said. • Meanwhile, scaling quantum computers is "a huge challenge," according to Ilie [1].
  • 28. • Blockchain networks including Bitcoin’s architecture relies on two algorithms: Elliptic Curve Digital Signature Algorithm (ECDSA) for digital signatures and SHA-256 as a hash function.
  • 29. • A quantum computer could use Shor’s algorithm [8] to get your private from your public key, but the most optimistic scientific estimates say that even if this were possible, it won’t happen during this decade.
  • 30. • “A 160 bit elliptic curve cryptographic key could be broken on a quantum computer using around 1000 qubits while factoring the security-wise equivalent 1024 bit RSA modulus would require about 2000 qubits”.
  • 31. • By comparison, Google's measly 53 qubits are still no match for this kind of cryptography. According to research paper on the matter published by Cornell University.
  • 32. • But that isn’t to say that there’s no cause for alarm. • While the native encryption algorithms used by Blockchain’s applications are safe for now, the fact is that the rate of advancements in quantum technology is increasing, and that could, in time, pose a threat. • "We expect their computational power will continue to grow at a double exponential rate," Google researchers.
  • 33. • Quantum Cryptography? • Quantum cryptography uses physics to develop a cryptosystem completely secure against being compromised without knowledge of the sender or the receiver of the messages. • The word quantum itself refers to the most fundamental behavior of the smallest particles of matter and energy.
  • 34. • Quantum cryptography is different from traditional cryptographic systems in that it relies more on physics, rather than mathematics, as a key aspect of its security model.
  • 35. • Essentially, quantum cryptography is based on the usage of individual particles/waves of light (photon) and their intrinsic quantum properties to develop an unbreakable cryptosystem (because it is impossible to measure the quantum state of any system without disturbing that system.)
  • 36. • Quantum cryptography uses photons to transmit a key. Once the key is transmitted, coding and encoding using the normal secret-key method can take place. • But how does a photon become a key? How do you attach information to a photon's spin?
  • 37. • This is where binary code comes into play. • Each type of a photon's spin represents one piece of information -- usually a 1 or a 0, for binary code. • This code uses strings of 1s and 0s to create a coherent message. • For example, 11100100110 could correspond with h-e-l-l-o. So a binary code can be assigned to each photon -- for example, a photon that has a vertical spin ( | ) can be assigned a 1.
  • 38. • “If you build it correctly, no hacker can hack the system. • The question is what it means to build it correctly,” said physicist Renato Renner from the Institute of Theoretical Physics in Zurich.
  • 39. • Regular, non-quantum encryption can work in a variety of ways but generally a message is scrambled and can only be unscrambled using a secret key. • The trick is to make sure that whomever you’re trying to hide your communication from doesn’t get their hands on your secret key.
  • 40. • Cracking the private key in a modern crypto system would generally require figuring out the factors of a number that is the product of two insanely huge prime numbers. • The numbers are chosen to be so large that, with the given processing power of computers, it would take longer than the lifetime of the universe for an algorithm to factor their product.
  • 41. • Encryption techniques have their vulnerabilities. • Certain products – called weak keys – happen to be easier to factor than others. • Also, Moore’s Law continually ups the processing power of our computers. • Even more importantly, mathematicians are constantly developing new algorithms that allow for easier factorization.
  • 42. • Quantum cryptography avoids all these issues. • Here, the key is encrypted into a series of photons that get passed between two parties trying to share secret information. • The Heisenberg Uncertainty Principle dictates that an adversary can’t look at these photons without changing or destroying them.
  • 43. • “In this case, it doesn’t matter what technology the adversary has, they’ll never be able to break the laws of physics,” said physicist Richard Hughes of Los Alamos National Laboratory in New Mexico, who works on quantum cryptography [6].
  • 44. References: • [1] https://www.forbes.com/sites/billybambrough/2019/10/02/could-google-be- about-to-break-bitcoin/#1d78c5373329 • [2] https://decrypt.co/9642/what-google-quantum-computer-means-for-bitcoin/ • [3] https://www.coindesk.com/how-should-crypto-prepare-for-googles-quantum- supremacy? • [4] https://www.ccn.com/google-quantum-bitcoin/ • [5] https://www.linkedin.com/pulse/20140503185010-246665791-quantum- computing/ • [6] https://www.linkedin.com/pulse/20140608053056-246665791- understanding-quantum-cryptography/ • [7] https://ai.googleblog.com/2019/10/quantum-supremacy-using- programmable.html • [8] https://qudev.phys.ethz.ch/static/content/QSIT15/Shors%20Algorithm.pdf