Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Operational Meaning of Min- and Max-Entropy Christian Schaffner – CWI Amsterdam, NL joint work with Robert König – Caltech Renato Renner – ETH Zürich,

Published byAnissa Johnston Modified over 9 years ago

Similar presentations

Presentation on theme: "The Operational Meaning of Min- and Max-Entropy Christian Schaffner – CWI Amsterdam, NL joint work with Robert König – Caltech Renato Renner – ETH Zürich,"— Presentation transcript:

1 The Operational Meaning of Min- and Max-Entropy Christian Schaffner – CWI Amsterdam, NL joint work with Robert König – Caltech Renato Renner – ETH Zürich, Switzerland TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: A AAA A A A A A A AA A A A A A http://arxiv.org/abs/0807.1338

2 2 /34 Agenda Shannon / von Neumann Entropy Min- and Max-Entropies Operational Meaning Conclusion

3 3 /34 Information Theory quantify the acquisition, transmission, storage of data often used: Shannon entropy Example: data compression minimal encoding length: [Shannon]: for iid

4 4 /34 quantum setting: finite-dimensional Hilbert spaces classical-quantum setting: classical setting: Notation

5 5 /34 Operational Interpretation of Shannon Entropy data compression of a source: transmission rate of a channel: secret-key rate of a correlation: …

6 6 /34 Operational Interpr of van Neumann Entropy data compression of a source: randomness-extraction rate of a cq-state: secret-key rate of a cqq-state: …

7 7 /34 van Neumann Entropy simple definition: for state “handy” calculus: chain rule: strong subadditivity: …

8 8 /34 van Neumann Entropy data compression: randomness extraction: Shannon entropy: … simple definition “handy” calculus operational: many iid settings one-shot setting? 

9 9 /34 Conditional Min- and Max-Entropy conditional van Neumann entropy: conditional min-entropy: conditional max-entropy: for pure [Renner 05] for pure Goal of this talk: Understanding these quantities!

10 10 /34 for product state: measure for the rank of ½ A Warm-Up Calculations for a product state classically:

11 11 /34 Warm-Up Calculations for a pure state

12 12 /34 Classical Min-Entropy without Conditioning suggests “smoothing”: … … 

13 13 /34 Smooth Min- and Max-Entropy where ± (, ) is the trace distance or (squared) fidelity for a purification [Renner 05]

14 14 /34 Smooth-Min-Entropy Calculus von Neumann entropy as special case: strong subadditivity: additivity: chain rules: 

15 15 /34 Single-Shot Data Compression [Renner,Wolf 04] with i.e. up to additive constant of order minimal encoding length: [Shannon]: for iid *

16 16 /34 Privacy Amplification [Renner, König 07] with maximum number of extractable bits such that

17 17 /34 Decoupling [Renner, Winter, Berta 07] with maximum size of A’ such that completely mixed state on A’

18 18 /34 State Merging with [Renner, Winter, Berta 07] minimal number of ebits required to transmit ½ A to B with LOCC LOCC maximal number of ebits generated by transmitting ½ A to B with LOCC [Horodecki, Oppenheim, Winter 05]

19 19 /34 Agenda von Neumann Entropy Min- and Max-Entropies Operational Meaning Conclusion

20 20 /34 Conditional Min- and Max-Entropy conditional van Neumann entropy: conditional min-entropy: conditional max-entropy: for pure [Renner 05] for pure Goal of this talk: Understanding these quantities!

21 21 /34 Warm-Up: Classical Case for classical states: corresponds to average probability of guessing X given Y notion used by [Dodis, Smith]

22 22 /34 The Operational Meaning of Min-Entropy for classical states: guessing probability for cq-states: guessing probability for a POVM {M x }

23 23 /34 The Operational Meaning of Min-Entropy for cq-states: guessing probability for qq-states: achievable singlet fraction F(, ) 2

24 24 /34 F(, ) 2 The Operational Meaning of Max-Entropy for cq-states: security of a key for

25 25 /34 F(, ) 2 The Operational Meaning of Max-Entropy for cq-states: security of a key for qq-states: decoupling accuracy for

26 26 /34 Proof: using Duality of SDPs for cq-states: guessing probability primal semi-definite program (SDP)

27 27 /34 Proof II: Choi-Jamiolkowski isomorphism bijective quantum operations

28 28 /34 Proof III: Putting It Together CPTP maps bijective

29 29 /34 Proof: Operational Interpr of Max-Entropy for follows using monotonicity of fidelity unitary relation of purifications

30 30 /34 connections between operational quantities, e.g. randomness extraction additivity of min-/max-entropies: · follows from definition Implications of our Results

31 31 /34 subadditivity of min-entropy: Implications of our Results implies subadditivity of von Neumann entropy

32 32 /34 van Neumann entropy: easy definition calculus shortcomings in single-shot setting replaced by min- and max-entropies scenarios for smooth versions operational interpretation of non-smooth versions Conclusions 

33 33 /34 Summary

34 34 /34 Summary

35 35 /34 operational meaning of smooth-min entropy calculus for fidelity-based smooth min-entropy Open questions

36 36 /34 Example: Channel Capacity maximum number of transmittable bits: [Shannon] (noisy-channel coding):

37 37 /34 Single-Shot Channel Capacity [Renner,Wolf,Wullschleger 06]: with maximum number of transmittable bits: [Shannon] (noisy-channel coding):

Download ppt "The Operational Meaning of Min- and Max-Entropy Christian Schaffner – CWI Amsterdam, NL joint work with Robert König – Caltech Renato Renner – ETH Zürich,"

Similar presentations

Efficient classification for metric data Lee-Ad GottliebWeizmann Institute Aryeh KontorovichBen Gurion U. Robert KrauthgamerWeizmann Institute TexPoint.

Efficient classification for metric data Lee-Ad GottliebWeizmann Institute Aryeh KontorovichBen Gurion U. Robert KrauthgamerWeizmann Institute TexPoint.
Tony Short University of Cambridge (with Sabri Al-Safi – PRA 84, 042323 (2011))

Tony Short University of Cambridge (with Sabri Al-Safi – PRA 84, (2011))
C&O 355 Mathematical Programming Fall 2010 Lecture 9

C&O 355 Mathematical Programming Fall 2010 Lecture 9
I NFORMATION CAUSALITY AND ITS TESTS FOR QUANTUM COMMUNICATIONS I- Ching Yu Host : Prof. Chi-Yee Cheung Collaborators: Prof. Feng-Li Lin (NTNU) Prof. Li-Yi.

I NFORMATION CAUSALITY AND ITS TESTS FOR QUANTUM COMMUNICATIONS I- Ching Yu Host : Prof. Chi-Yee Cheung Collaborators: Prof. Feng-Li Lin (NTNU) Prof. Li-Yi.
PAUL CUFF ELECTRICAL ENGINEERING PRINCETON UNIVERSITY Causal Secrecy: An Informed Eavesdropper.

PAUL CUFF ELECTRICAL ENGINEERING PRINCETON UNIVERSITY Causal Secrecy: An Informed Eavesdropper.
Paul Cuff THE SOURCE CODING SIDE OF SECRECY TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: AA.

Paul Cuff THE SOURCE CODING SIDE OF SECRECY TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: AA.
Entropy in the Quantum World Panagiotis Aleiferis EECS 598, Fall 2001.

Entropy in the Quantum World Panagiotis Aleiferis EECS 598, Fall 2001.
Michael A. Nielsen University of Queensland Quantum entropy Goals: 1.To define entropy, both classical and quantum. 2.To explain data compression, and.

Michael A. Nielsen University of Queensland Quantum entropy Goals: 1.To define entropy, both classical and quantum. 2.To explain data compression, and.
Serge Fehr & Christian Schaffner CWI Amsterdam, The Netherlands 1 Randomness Extraction via ± -Biased Masking in the Presence of a Quantum Attacker TCC.

Serge Fehr & Christian Schaffner CWI Amsterdam, The Netherlands 1 Randomness Extraction via ± -Biased Masking in the Presence of a Quantum Attacker TCC.
Quantum information as high-dimensional geometry Patrick Hayden McGill University Perspectives in High Dimensions, Cleveland, August 2010.

Quantum information as high-dimensional geometry Patrick Hayden McGill University Perspectives in High Dimensions, Cleveland, August 2010.
Short course on quantum computing Andris Ambainis University of Latvia.

Short course on quantum computing Andris Ambainis University of Latvia.
Chain Rules for Entropy

Chain Rules for Entropy
On the monotonicity of the expected volume of a random simplex Luis Rademacher Computer Science and Engineering The Ohio State University TexPoint fonts.

On the monotonicity of the expected volume of a random simplex Luis Rademacher Computer Science and Engineering The Ohio State University TexPoint fonts.
Stronger Subadditivity Fernando G.S.L. Brandão University College London -> Microsoft Research Coogee 2015 based on arXiv:1411.4921 with Aram Harrow Jonathan.

Stronger Subadditivity Fernando G.S.L. Brandão University College London -> Microsoft Research Coogee 2015 based on arXiv: with Aram Harrow Jonathan.
Chapter 6 Information Theory

Chapter 6 Information Theory
Revision of Chapter III For an information source {p i, i=1,2,…,N} its entropy is defined by Shannon’s first theorem: For an instantaneous coding, we have.

Revision of Chapter III For an information source {p i, i=1,2,…,N} its entropy is defined by Shannon’s first theorem: For an instantaneous coding, we have.
A Family of Quantum Protocols Igor Devetak, IBM Aram Harrow, MIT Andreas Winter, Bristol quant-ph/0308044 IEEE Symposium on Information Theory June 28,

A Family of Quantum Protocols Igor Devetak, IBM Aram Harrow, MIT Andreas Winter, Bristol quant-ph/ IEEE Symposium on Information Theory June 28,
Lattices for Distributed Source Coding - Reconstruction of a Linear function of Jointly Gaussian Sources -D. Krithivasan and S. Sandeep Pradhan - University.

Lattices for Distributed Source Coding - Reconstruction of a Linear function of Jointly Gaussian Sources -D. Krithivasan and S. Sandeep Pradhan - University.
Small Subgraphs in Random Graphs and the Power of Multiple Choices The Online Case Torsten Mütze, ETH Zürich Joint work with Reto Spöhel and Henning Thomas.

Small Subgraphs in Random Graphs and the Power of Multiple Choices The Online Case Torsten Mütze, ETH Zürich Joint work with Reto Spöhel and Henning Thomas.
Linear Codes for Distributed Source Coding: Reconstruction of a Function of the Sources -D. Krithivasan and S. Sandeep Pradhan -University of Michigan,

Linear Codes for Distributed Source Coding: Reconstruction of a Function of the Sources -D. Krithivasan and S. Sandeep Pradhan -University of Michigan,

Similar presentations

Ads by Google