Download Document

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
page
23
page
24
page
25
page
26
page
27
page
28
page
29
page
30
page
31
page
32
page
33
page
34
page
35
page
36
page
37
page
38
page
39
Document related concepts
no text concepts found
Transcript 
BOUNDS ON ENTANGLEMENT
DISTILLATION & SECRET KEY
AGREEMENT CAPACITIES FOR
QUANTUM BROADCAST CHANNELS
Kaushik P. Seshadreesan
Joint work with
Masahiro Takeoka & Mark M. Wilde
arXiv:1503.08139 [quant-ph]
QIPA, HRI,
12/12/2015
MOTIVATION
2
QUANTUM NETWORKS
One-Time Pad
Secure Key
Classical
Communication
Secret
Agreement
(SKA)
Teleportation
 Entanglement
Distillation
(ED)
Distributed Quantum
Information
Processing
(QIP)

Point-to-point
Links
End-user
domain
End-user
domain
Trusted
Relay nodes
3
End-user
domain
QUANTUM NETWORKS
Our Focus  End-User Domain


Multiuser Secret Key Agreement
Multipartite Entanglement Distillation
Quantum Internet
Alice
Bob
4
Charlie
END-USER DOMAIN: POSSIBLE ARCHITECTURES
1) Point-to-Point Links between each
pair of users.
Prohibitively Expensive!!
3) A Quantum Access Network.
Bernd Frohlich et al.
Nature 501, 69–72 (2013)
2) A Quantum Broadcast Network.
Townsend Nature 385, 47–49 (1997)
5
BACKGROUND
6
SKA AND ED OVER POINT-TO-POINT LINKS

Rate-loss tradeoff  A fundamental limitation of the optical
comm. channel.
Pirandola et al.,
arXiv:1510.08863
Reverse
Coherent Information
Lower Bound
Takeoka, Guha & Wilde
Nature Comm. (2014)
Main tool used:
Squashed
Entanglement
7
OUR CONTRIBUTION


Rate-loss tradeoffs for SKA and ED over quantum
broadcast channels
Main tool:
 Multipartite Squashed Entanglement
Yang et al. (2009)
8
OUTLINE

Setting up the Arena


Protocol:



One-sender two-receiver case
Tool


Entanglement Distillation and Secret Key Agreement
over a Quantum Broadcast Channel
Multipartite Squashed Entanglement
Bounds for ED and SKA over a QBC
Open Questions and Conclusions
9
SETTING UP THE ARENA:
ENTANGLEMENT DISTILLATION & SECRET KEY
AGREEMENT OVER A QUANTUM BROADCAST
CHANNEL
10
A QUANTUM BROADCAST CHANNEL


QBC as a resource to generate shared entanglement and
shared secret key
Other available resources:
Local Operations and Classical Communication (LOCC) for ED
 Local Operations and Public Class. Comm. (LOPC) for SKA

11
ENTANGLEMENT DISTILLATION
Distilling generalized “GHZ states” under
unlimited LOCC
 An
m-partite
GHZ state:
A bipartite
maximally
entangled state:


Entanglement Distillation Capacity of a Channel:
Largest achievable rate of distilling maximally
entangled states using the channel along with
unlimited two-way LOCC.
12
SECRET KEY AGREEMENT
Horodecki et al. , IEEE Trans.
Inf. Theory 55, 1898 (2009)
Key Distillation under LOPC
 “Private State” Distillation under LOCC
Shared Secret Key
 A bipartite Private State:

Measurement Maps. (In general, POVMs)

Explicit form:
A purification of the state
Shield Systems
Twisting Unitary
13
SECRET KEY AGREEMENT
Augusiak & P Horodecki,
Phys. Rev. A 80, 042307 (2009)
Key Distillation under LOPC
 “Private State” Distillation under LOCC
 An m-partite Private State:
Shield Systems

Twisting Unitary

Secret-Key Agreement Capacity of a Channel:
Largest achievable rate of distilling private states
using the channel along with unlimited two-way
LOCC.
14
ED AND SKA OVER A QBC

E.g., consider a one-sender two-receiver QBC
Power Set of S (sans null
and singleton elements)

Ideal State of Interest:
Alice
where
15
, etc.
Charlie
Bob
PROTOCOL:
ONE-SENDER TWO-RECEIVER CASE
16
PROTOCOL

We define a (n, EAB, EAC, EBC, EABC, KAB, KAC,
protocol as follows:
Initial state  Separable:
 State after ith channel use:
 State after (i+1)th round of LOCC:
 State after n channel uses:
such that

17
Ideal state
CAPACITY REGION


Achievable Rate:
A tuple
is achievable is for all ε≥ 0 and sufficiently large n,
there exists a protocol of the above type.
Capacity Region: Closure of all achievable rates.
18
TOOL:
MULTIPARTITE SQUASHED ENTANGLEMENT
19
SQUASHED ENTANGLEMENT (BIPARTITE)

Definition: Christandl & Winter (2004)
For a bipartite state
Eve tries her best to “squash down” the correlations
between Alice and Bob.
 Upper bounds on ED and SKA rates for point-topoint channels.

Takeoka, Guha and Wilde (2014)
20
PROPERTIES
Monotone non-increasing under LOCC
 Normalized on maximally entangled states
 Asymptotically Continuous
 Additive on tensor-product states

21
SQUASHED ENTANGLEMENT(S) (MULTIPARTITE)

Definition(s): Yang et al. (2009)
For an m-partite state
Incomparable
22
SQUASHED ENTANGLEMENT(S) (MULTIPARTITE)

Definition(s): Yang et al. (2009)
For an m-partite state
Eve tries her best to “squash down” the correlations
between the m parties.
 Upper bounds on ED and SKA rates for Quantum
Broadcast Channels.

Seshadreesan, Takeoka and Wilde (2015)
23
PROPERTIES AND SOME NOTATION


LOCC monotone, Continuous and Additive on tensorproduct states
Normalization on MES and Private States
24
BOUNDS FOR ED AND SKA OVER A QUANTUM
BROADCAST CHANNEL
25
BOUNDS FOR A ONE-SENDER TWORECEIVER QBC
26
PROOF SKETCH

1.
Consider
and its different partitions:
1
Additivity of SqE. on tensor product states
2
Normalization of SqE. on MES and
Private states
Consider the ideal state
1
2
27
PROOF SKETCH

2.
Well, actually, rate defined as “per channel use”. So,
Continuity of Squashed Entanglement

If
then
3.
Monotonicity under LOCC
28
PROOF SKETCH
4.
A TGW-type subadditivity inequality
Consider a pure state
. Then,
29
PROOF SKETCH


Repeated application of the TGW-type subadditivity
and monotonicity under LOCC gives
Therefore,
Time sharing
Register
Single Letter bound!
where
30
OPEN QUESTIONS AND CONCLUSIONS
31
OPEN QUESTIONS

Similar bounds for a Multiple Access Channel (MAC)
Bounds for a QBC and a MAC in the presence of
quantum repeaters
 Protocols for ED and SKA over QBC and MAC

32
CONCLUSIONS

Considered ED and SKA over a QBC

Described a LOCC protocol for the above task

Studied a multipartite squashed entanglement

Used it to upper bound rates for ED and SKA over QBC

The bounds are single-letter
33
Thank you for your attention!
34
PURE-LOSS BOSONIC BROADCAST CHANNEL

E.g., consider a three-way beamsplitter

Mean photon number
Constraint
35
BOUNDS ON ED AND SKA FOR A PURELOSS BOSONIC BROADCAST CHANNEL
36
BOUNDS ON ED AND SKA FOR A PURELOSS BOSONIC BROADCAST CHANNEL
37
PROOF SKETCH


Consider that
Due to the extremality of Gaussian states for
conditional entropy, we have the optimal entropies
, etc.
where
Correspond to
thermal states of
mean photon
number x
38
PROOF SKETCH

Further, for
monotonically increasing

Also,

Therefore,
By picking
Because the function is convex
39
And similarly, the other bounds…
Related documents
Topological Insulators
Topological Insulators
SWES 474 - Research Paper #1
SWES 474 - Research Paper #1
Exact reduced dynamics and
Exact reduced dynamics and
Quantum mechanical model
Quantum mechanical model
PPT - Henry Haselgrove`s Homepage
PPT - Henry Haselgrove`s Homepage
David Williams (University of Cambridge)
David Williams (University of Cambridge)
An Introduction to Quantum Computing
An Introduction to Quantum Computing
Quantum computing and the monogamy of entanglement
Quantum computing and the monogamy of entanglement
Quantum Information (QI) - BYU Physics and Astronomy
Quantum Information (QI) - BYU Physics and Astronomy
`12
`12
Quantum mechanics in electronics
Quantum mechanics in electronics
Quantum phase transition - Condensed Matter Theory and Quantum
Quantum phase transition - Condensed Matter Theory and Quantum
A framework for bounding nonlocality of state discrimination
A framework for bounding nonlocality of state discrimination
The swell and crash of ska`s first wave
The swell and crash of ska`s first wave
full version
full version