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Quantum communication from Alice to Bob Andreas Winter, Bristol quant-ph/0308044 Aram Harrow, MIT Igor Devetak, USC.

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Presentation on theme: "Quantum communication from Alice to Bob Andreas Winter, Bristol quant-ph/0308044 Aram Harrow, MIT Igor Devetak, USC."— Presentation transcript:

1 Quantum communication from Alice to Bob Andreas Winter, Bristol quant-ph/0308044 Aram Harrow, MIT Igor Devetak, USC

2 outline Introduction –basic concepts and resource inequalities –historical overview of quantum information theory A family of protocols –Rederive and connect old protocols –Prove new protocols (parents) Optimal trade-off curves

3 the setting two parties: Alice and Bob one-way communication from Alice to Bob we want asymptotic communication rates A lice B ob (noisy) classical communication (noisy) quantum communication (noisy) shared entanglement or classical correlations

4 cbit[c ! c]1 noiseless bit channel ebit[qq]the state (|0 i A |0 i B + |1 i A |1 i B )/ p 2 qubit[q ! q]1 noiseless qubit channel noisy state {qq}  noisy bipartite quantum state  AB noisy channel {q ! q} N noisy cptp map: N : H A’ !H B Information processing resources may be: classical / quantumc / q noisy / noiseless (unit){ } / [ ] dynamic / static ! / ¢ examples of bipartite resources

5 Church of the larger Hilbert space static  AB ) purification |  i ABE s.t.  AB = tr E  ABE. If  AB =  i p i |  i ih  i | AB, then |  i ABE =  i p p i |i i E ­ |  i i AB. |  i AA’ UNUN A A0A0 B E |  i ABE Channel N : H A’ !H B ) isometric extension U N : H A’ !H B ­H E s.t. N (  ) = tr E U N (  ). Use a test source |  i AA’ and define |  i ABE = (I A ­ U N )|  i AA’

6 information theoretic quantities von Neumann entropy: H(A)  = -tr [  A log  A ] mutual information: I(A:B) = H(A) + H(B) – H(AB) coherent information: I c (A i B) = H(B) – H(AB) = -H(A|B) conditional mutual information: I(A:B|X) = H(A|X) + H(B|X) – H(AB|X) = I(A:BX) – I(B:X)

7 resource inequalities Example: classical noisy channel coding [Shannon] {c ! c} N > I (A:B) p [c ! c] Meaning there exists an asymptotic and approximate protocol transforming the LHS into the RHS. For any  >0 and any R<I(A:B) and for sufficiently large n there exist encoding and decoding maps E : {0,1} nR ! X n and D : X n ! {0,1} ­ nR such that for any input x 2 {0,1} nR ( D ¢ N ­ n ¢ E )|x i ¼  |x i The capacity is given by max p I(A:B) p, where p is a distribution on AB resulting from B = N (A).

8 resource inequalities Example: quantum channel coding {q ! q} N > I c (A i B)  [q ! q] Meaning there exists an asymptotic and approximate protocol transforming the LHS into the RHS. For any  >0 and any R<I c (A i B) and for sufficiently large n there exist encoding and decoding maps E : H 2 ­ nR ! H A’ ­ n and D : H B ­ n ! H 2 ­ nR such that for any input |  i2H 2 ­ n, ( D ¢ N ­ n ¢ E )|  i ¼  |  i The capacity is given by lim n !1 (1/n) max  I c (A i B) , where the maximization is over all  arising from N ­ n.

9 the history of quantum information theory, part one

10 first generation: semi-classical Characterized by: Results depend only on average density matrix Protocols can be analyzed by looking at one party’s state Examples: Schumacher compression: [PRA 51, 2738 (1995)]  RA + S(  ) [q ! q] >  RB entanglement concentration/dilution: [BBPS, quant-ph/9511030]   = S(A)  [qq] remote state preparation: [BDSSTW, quant-ph/0006044] S(B) [c ! c] + S(B) [qq] > E AB = {p i, |  i i B }

11 first generation techniques semi-classical reductions: Schmidt decomposition: |  i AB =  i p p i |a i i A |b i i B matrix diagonalization:  =  i p i |v i ih v i | Typical sequences: p a probability distribution p-typical sequences i 1,…,i n have |#{i j = x} – np x | < n  for all x # of p-typical sequences is ¼ exp(n(S(p)+  )) each has probability exp(-n(S(p)   )) Typical projectors and subspaces:  a state with spectrum p  =  I typical |v I ih v I | projects onto a typical subspace where I=i 1,…,i n is a typical sequence and |v I i =|v i 1 i …|v i n i

12 2 nd generation: CQ ensembles HSW theorem: [H, IEEE IT 44, 269 (1998); SW, PRA 56, 131 (1997)] E =  i p i |i ih i| A ­  i B  {c ! q} >  [c ! c] I(A:B) = S(  i p i  i ) -  i S(   ) =  ( E ) Entanglement assisted channel capacity: [BSST, quant-ph/0106052] {q ! q} + H(A) ebits > I(A:B) [c ! c] RSP of entangled states: [BHLSW, quant-ph/0307100] H(A) [qq] + I(A:B) [c ! c] > E =  i p i |i ih i| X ­ |  i ih  i | AB Measurement compression: [Winter, quant-ph/0109050] I(X:R)[c ! c] + H(X|R) [cc] > T:A ! AEX A X B on |  i AR

13 2 nd generation techniques conditionally typical subspaces: E =  i p i |i ih i| A ­  i B Compressing B requires S(B) qubits, but if you know (or have) A then you need S(B|A) = S(AB) – S(A) =  i p i S(  i ) qubits. The difference is S(B)-S(B|A) = S(A)+S(B)-S(AB) = I(A:B) = . operator Chernoff bounds: [AW, quant-ph/0012127] X 1,…,X n i.i.d. Hermitian matrices s.t. 0 6 X i 6 I and  = E X i >  I

14 3rd generation: fully quantum quantum channel capacity: {q ! q} > I c (A i B) super-dense coding of quantum states double and triple-tradeoff curves: N > R [c ! c] + Q[q ! q] + E[qq] unification of different protocols entanglement distillation using limited quantum or classical communication

15 3 rd generation techniques derandomization: If the output state is pure, [cc] inputs are unnecessary. piggybacking: Time-sharing protocol P x with probability p x allows an extra output of I(X:B) [c ! c]. [DS, quant-ph/0311131] coherent classical communication: [H, quant-ph/0307091] Modify protocols to obtain [[c ! c]]: |x i A ! |x i A |x i B use coherent TP and SD to get 2 [[c ! c]] = [q ! q] + [qq].

16 main result #1: parent protocols father: {q ! q} + ½ I(A:E) [qq] > ½ I(A:B) [q ! q] mother: {qq} + ½ I(A:E) [q ! q] > ½ I(A:B) [qq] Basic protocols combine with parents to get children. (TP)2[c ! c] + [qq] > {q ! q} (SD)[q ! q] + [qq] > 2[c ! c] (QE)[q ! q] > [qq]

17 the family tree  {q ! q} + ½ I(A:E) [qq] > ½ I(A:B) [q ! q]  {qq} + ½ I(A:E) [q ! q] > ½ I(A:B) [qq] {q ! q} + H(A) [qq] > I(A:B) [c ! c] BSST, [IEEE IT 48, 2002], E-assisted cap. {q ! q} > I c (A i B) [q ! q] L/S/D, quantum channel cap. {qq} + H(A) [q ! q] > I(A:B) [c ! c] H 3 LT, [QIC 1, 2001], noisy SD {qq} + I(A:B) [c ! c] > I c (A i B) [q ! q] DHW, noisy TP SD QE TPSD TP {qq} + I(A:E) [c ! c] > I c (A i B) [q ! q] DW, entanglement distillation TP (TP) 2[c ! c] + [qq] > {q ! q} (SD)[q ! q] + [qq] > 2[c ! c] (QE)[q ! q] > [qq]

18 coherent classical communication rule I: X + C [c ! c] > Y ) X + C/2 ( [q ! q] – [qq] ) > Y rule O: X > Y + C [c ! c] ) X > Y + C/2 ( [q ! q] + [qq] ) Whenever the classical message in the original protocol is almost uniformly distributed and is almost decoupled from the remaining quantum state of Alice, Bob and Eve. based on PRL 92, 097902 (2004)

19 generating the parents  {q ! q} + ½ I(A:E) [qq] > ½ I(A:B) [q ! q]  {qq} + ½ I(A:E) [q ! q] > ½ I(A:B) [qq] {q ! q} + H(A) [qq] > I(A:B) [c ! c] BSST, [IEEE IT 48, 2002], E-assisted cap. {q ! q} > I c (A i B) [q ! q] L/S/D, quantum channel cap. {qq} + H(A) [q ! q] > I(A:B) [c ! c] H 3 LT, [QIC 1, 2001], noisy SD {qq} + I(A:B) [c ! c] > I c (A i B) [q ! q] DHW, noisy TP SD QE TPSD TP {qq} + I(A:E) [c ! c] > I c (A i B) [q ! q] DW, entanglement distillation TP O O I

20 I(A:B)/2 [BSST; quant-ph/0106052] H(A)+I(A:B) main result #2: tradeoff curves Q : qubits sent per use of channel E : ebits allowed per use of channel I c (A>B) [L/S/D] qubit > ebit bound 45 o example: quantum channel capacity with limited entanglement

21 father trade-off curve Q : qubits sent per use of channel E : ebits allowed per use of channel I c (A i B) [L/S/D] 45 o I(A:E)/2 = I(A:B)/2 - I c (A i B) I(A:B)/2 father

22 mother trade-off curve {qq} + ½ I(A:E) [q ! q] > ½ I(A:B)[qq] preprocessing instrument T:A ! AE’X {qq} + ½ I(A:EE’|X) [q ! q] + H(X)[c ! c] > ½ I(A:B|X)[qq] H(X) [c ! c] measurement compression I(X:BE) [c ! c] + H(X|BE) [cc] I(X:BE) [c ! c] derandomization ½ I(X:BE) ( [q ! q] – [qq] ) rule I {qq} + ½ (I(A:EE’|X) + I(X:BE)) [q ! q] > ½ (I(A:B|X) + I(X:BE)) [qq]

23 converse proof techniques Holevo bound/data processing inequality: X  Q  Y: I(X:Y) 6 I(X:Q) Fano/Fannes inequality: error  on n qubits makes entropy change by O (  (n+log(1/  )). unnamed identity that shows up everywhere: I(X:AB) = H(A) + I c (A i BX) – I(A:B) + I(X:B) quantum data processing inequality: [quant-ph/9604022] RQ  RQ’E 1  RQ’’E 1 E 2 : H(R)=I c (R i Q) > I c (R i Q’) > I c (R i Q’’)

24 what’s left In quant-ph/0308044, we prove similar tradeoff curves for the rest of the resource inequalities in the family. Remaining open questions include – Finding single-letter formulae (i.e. additivity) – Reducing the optimizations over instruments – Addressing two-way communication – Multiple noisy resources – Reverse coding theorems

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