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Unconstrained distillation capacities of

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1 Unconstrained distillation capacities of
a pure-loss bosonic broadcast channel Masahiro Takeoka (NICT) Kaushik P. Seshadreesan (MPL) Mark M. Wilde (LSU) arXiv: AQIS2016 at Academia Sinica, Taipei 29 August 2016

2 Introduction: QKD and Ent. distillation
- Quantum key distribution (QKD) and entanglement distillation (ED) are two cornerstones of quantum communication. - Especially, QKD has been already deployed into field operations and practical uses Maintenance-free WDM QKD, Opt. Express 21, (2013). A. Tajima et al., Thursday (Sep 1)

3 QKD over quantum network channels
2) A Quantum Multiple-Access Network. 1) A Quantum Broadcast Network. 3) More complicated networks... Bernd Frohlich et al. Nature 501, 69–72 (2013) Townsend Nature 385, 47–49 (1997) sender multiple receivers What is the fundamental limit of multi-user entanglement distillation and quantum key distribution in optical network channels?

4 Entanglement distillation and QKD:
LOCC-assisted quantum and private capacities n-use of noisy quantum channel Alice Bob k bits of entanglement or secret key k bits of entanglement or secret key Eve Unlimited two-way classical communication Secret key or entanglement generation rate: LOCC-assisted quantum and private capacities Supremum of all achievable

5 Pure-loss optical (bosonic) channel
- All the above experiments use optical (bosonic) channel. - Simplest bosonic channel model: pure-loss channel :channel transmittance Alice Bob Eve Beam splitter model of a pure-loss bosonic channel

6 in a point-to-point pure-loss channel
- Squashed entanglement upper bound - Single-letter upper bound for arbitrary quantum channels Unconstrained (input power) upper bound solely a function of channel loss MT, Guha, Wilde, IEEE-IT 60, 4987 (2014), Nat Commun. 5:5253 (2014)

7 in a point-to-point pure-loss channel
- Squashed entanglement upper bound - Single-letter upper bound for arbitrary quantum channels Unconstrained (input power) upper bound solely a function of channel loss MT, Guha, Wilde, IEEE-IT 60, 4987 (2014), Nat Commun. 5:5253 (2014) - Relative entropy of entanglement upper bound - Improved upper bound for the pure-loss channel -> matches with the coherent information based lower bound. Capacity established for the pure-loss channel! Pirandola, Laurenza, Ottaviani, Banchi, arXiv:

8 - C-Q capacity, unassisted quantum capacity of QBC, QMAC
in network channels - C-Q capacity, unassisted quantum capacity of QBC, QMAC Allahverdyan and Saakian, quant-ph/ Winter, IEEE Trans. Inf. Theory 47, 7, 3059 (2001). Guha, Shapiro, Erkmen, Phy. Rev. A 76, (2007). Yard, Hayden, Devetak, IEEE Trans. Inf. Theory 54, 3091 (2008). Yard, Hayden, Devetak, IEEE Trans. Inf. Theory 57, 7147 (2011). Dupuis, Hayden, Li, IEEE Trans. Inf. Theory 56, 2946 (2010). - LOCC-assisted capacities (Q2, P2) Seshadreesan, MT, Wilde, IEEE Trans. Inf. Theory 62, 2849 (2016) - Single-letter upper bound for arbitrary quantum broadcast channel based on multipartite squashed entanglement

9 - C-Q capacity, unassisted quantum capacity of QBC, QMAC
in network channels - C-Q capacity, unassisted quantum capacity of QBC, QMAC Allahverdyan and Saakian, quant-ph/ Winter, IEEE Trans. Inf. Theory 47, 7, 3059 (2001). Guha, Shapiro, Erkmen, Phy. Rev. A 76, (2007). Yard, Hayden, Devetak, IEEE Trans. Inf. Theory 54, 3091 (2008). Yard, Hayden, Devetak, IEEE Trans. Inf. Theory 57, 7147 (2011). Dupuis, Hayden, Li, IEEE Trans. Inf. Theory 56, 2946 (2010). - LOCC-assisted capacities (Q2, P2) Seshadreesan, MT, Wilde, IEEE Trans. Inf. Theory 62, 2849 (2016) - Single-letter upper bound for arbitrary quantum broadcast channel based on multipartite squashed entanglement This work: Q2, P2 on pure-loss bosonic broadcast channel

10 Main result protocol 1-to-m pure-loss quantum broadcast channel (QBC)
pure-loss linear optical QBC : power transmittance from A’ to Bi protocol Protocol generating n-use of quantum channel and unlimited LOCC : maximally entangled state : private state

11 Main result Theorem: The LOCC-assisted unconstrained capacity region of the pure-loss bosonic QBC is given by for all non-empty , where , and

12 Example: 1-to-2 QBC 1-to-2 pure-loss quantum broadcast channel
Capacity region

13 Example: 1-to-2 QBC 1-to-2 pure-loss quantum broadcast channel
Capacity region Timesharing bound

14 Proof outline Achievability (1-to-2 QBC) Converse (1-to-2 QBC) Generalization to 1-to-m arbitrary linear optics network

15 Achievability Tool: State merging R R LOCC Alice Bob Bob Alice
Horodecki, Oppenheim, Winter, Nature 436, 673 (2005), Commun. Math. Phys. 136, 107 (2007). Tool: State merging Protocol to merge a copy of distributed states via LOCC. R R LOCC Alice Bob Alice Bob Resource gain/consumption If is positive consuming bits of entanglement If is negative generating bits of entanglement distilling entanglement : conditional quantum entropy

16 Achievability - Send two-mode squeezed vacuum with average photon number NS from A to BC via n QBCs. - State merging from BC to A. Achievable rate region of entanglement distillation Note: since 1 ebit of entanglement can generate 1 pbit of secret key, the lhs can be modified as etc.

17 Converse Main tool - Point-to-point capacity for the pure-loss bosonic channel (relative entropy of entanglement (REE) upper bound) Pirandola, et al., arXiv: Step 1. Extension to a quantum broadcast channel Seshadreesan, MT, Wilde, IEEE Trans. Inf. Theory 62, 2849 (2016) 2. Calculation of the REE - Linear optics network reconfiguration (new observation)

18 Point-to-point channel (REE upper bound)
Pirandola, et al., arXiv:

19 Point-to-point channel (REE upper bound)
Pirandola, et al., arXiv: 1. Show TMSV with average photon number NS -Teleportation simulation technique Bennett et al., Phys. Rev. A 76, 722 (1996) -Relative entropy of entanglement Vedral and Plenio, Phys. Rev. A 57, 1619 (1998)

20 Point-to-point channel (REE upper bound)
Pirandola, et al., arXiv: 1. Show TMSV with average photon number NS -Teleportation simulation technique Bennett et al., Phys. Rev. A 76, 722 (1996) -Relative entropy of entanglement Vedral and Plenio, Phys. Rev. A 57, 1619 (1998) 2. Calculation of the REE

21 Converse Main tool - Point-to-point capacity for the pure-loss bosonic channel (relative entropy of entanglement (REE) upper bound) Pirandola, et al., arXiv: Step 1. Extension to a quantum broadcast channel Seshadreesan, MT, Wilde, IEEE Trans. Inf. Theory 62, 2849 (2016) 2. Calculation of the REE - Linear optics network reconfiguration (new observation)

22 Step 1: REE bound for the QBC
Converse Step 1: REE bound for the QBC Target state: : maximally entangled state State generated by the protocol: : private state Properties of REE Partition the target state between B and AC, - Monotonicity under LOCC - Continuity - Additivity on product states

23 Step 1: REE bound for the QBC
Converse Step 1: REE bound for the QBC Upper bound of the rate region

24 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Key observation: reconfiguration of the linear optics network (a) (a): original pure-loss QBC MT, Seshadreesan, Wilde, arXiv:

25 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Key observation: reconfiguration of the linear optics network (a) (a): original pure-loss QBC (b), (C): equivalent QBCs (b) (c) MT, Seshadreesan, Wilde, arXiv:

26 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Bipartite case: (b)

27 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Bipartite case: (b) AB C pure-loss channel with

28 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Bipartite case: (b) - State at ABC’ is a pure state. - Observe the marginal state at C’ is a thermal state. - Thus the Schmidt decomposition of the state in ABC’ is in the form AB C pure-loss channel with

29 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Bipartite case: (b) - State at ABC’ is a pure state. - Observe the marginal state at C’ is a thermal state. - Thus the Schmidt decomposition of the state in ABC’ is in the form AB C pure-loss channel with - Applying the local unitary operation

30 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Bipartite case: (b) C with - As a consequence we have

31 Step 2: Calculation of the REE
Converse Step 2: Calculation of the REE Upper bound of the rate region

32 Proof outline Achievability (1-to-2 QBC) Converse (1-to-2 QBC) Generalization to 1-to-m arbitrary linear optics network

33 Generalization to 1-to-m QBC
sender sender m receivers ?

34 Generalization to 1-to-m QBC
Linear optical network decomposition Reck, Zeilinger, Bernstein, Bertani, Phys. Rev. Lett. 73, 58 (1994)

35 Generalization to 1-to-m QBC
Linear optical network decomposition Reck, Zeilinger, Bernstein, Bertani, Phys. Rev. Lett. 73, 58 (1994)

36 Generalization to 1-to-m QBC
Linear optical network decomposition Reck, Zeilinger, Bernstein, Bertani, Phys. Rev. Lett. 73, 58 (1994)

37 Generalization to 1-to-m QBC
sender sender m receivers

38 Conclusions - The LOCC-assisted unconstrained capacity region of
the pure-loss bosonic quantum broadcast channel for the protocol is established. - Proof techniques - state merging, teleportation simulation, relative entropy of entanglement, QBC upper bounding, BS network reconfiguration - Although our proof provides the weak converse, this can be strengthened to the strong converse with the recent result by Wilde, Tomamichel, Berta, arXiv: arXiv: Open questions - Entanglement and key distillation for - Capacity region for other network channels (multiple-access, interference, etc.). - Energy constrained capacity.

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