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A '''Tsirelson bound''' is an upper limit to [[quantum mechanics|quantum mechanical]] correlations between distant events. Given that quantum mechanics is [[Quantum nonlocality|non-local]], i.e., that quantum mechanical correlations violates [[Bell's theorem|Bell inequalities]], a natural question to ask is "how non-local can quantum mechanics be?", or, more precisely, by how much can the Bell inequality be violated. The answer is precisely the Tsirelson bound for the particular Bell inequality in question. In general this bound is lower than what would be algebraically possible, and much research has been dedicated to the question of why this is the case. | |||
The Tsirelson bounds are named after [[Boris Tsirelson|B. S. Tsirelson]], (or Boris Cirel'son, in a different [[Romanization of Russian|transliteration]]) the author of the paper<ref>B. S. Cirel'son, ''[http://dx.doi.org/10.1007/BF00417500 Quantum Generalizations of Bell's Inequality]'', Lett. Math. Phys. 4, 93 (1980). [http://www.tau.ac.il/~tsirel/download/qbell80.html]</ref> in which the first one was derived. | |||
==Tsirelson bound for the CHSH inequality== | |||
The first Tsirelson bound was derived as an upper bound on the correlations measured in the [[CHSH inequality]]. It states that if we have four ([[Hermitian]]) dichotomic observables <math>A_0</math>, <math>A_1</math>, <math>B_0</math>, <math>B_1</math> (i.e., two observables for [[Alice and Bob|Alice]] and two for [[Alice and Bob|Bob]]) with outcomes <math>+1,-1</math> such that <math>[A_i,B_j]=0</math> for all <math>i,j</math>, then | |||
:<math> \langle A_0 B_0 \rangle + \langle A_0 B_1 \rangle + \langle A_1 B_0 \rangle - \langle A_1 B_1 \rangle \le 2\sqrt{2} </math> | |||
For comparison, in the classical (or local realistic case) the upper bound is 2, whereas if any arbitrary assignment of <math>+1,-1</math> is allowed it is 4. The Tsirelson bound is attained already if Alice and Bob each makes measurements on a [[qubit]], the simplest non-trivial quantum system. | |||
Lots of proofs have been developed for this bound, but perhaps the most enlightening one is based on the Khalfin-Tsirelson-Landau identity. If we define an observable | |||
:<math> \mathcal{B} = A_0 B_0 + A_0 B_1 + A_1 B_0 - A_1 B_1 </math> | |||
and <math> A_i^2 = B_j^2 = \mathbb{I} </math>, i.e., if the outcomes of the observables are associated to projective measurements, then | |||
:<math> \mathcal{B}^2 = 4 \mathbb{I} - [A_0,A_1][B_0,B_1] </math> | |||
If <math> [A_0,A_1] = 0 </math> or <math> [B_0,B_1] = 0 </math>, which can be regarded as the classical case, it already follows that <math> \langle \mathcal{B} \rangle \le 2 </math>. In the quantum case, we need only notice that <math> \|[A_0,A_1]\| \le 2 \|A_0\| \|A_1\| \le 2</math> and the Tsirelson bound <math> \langle \mathcal{B} \rangle \le 2\sqrt{2} </math> follows. | |||
==Tsirelson bounds for other Bell inequalities == | |||
{{Expand section|date=December 2012}} | |||
Obtaining a Tsirelson bound for a given Bell inequality is in general a hard problem that has to be solved in a case-by-case basis, although we do have numerical algorithms than can upperbound it. The exact values are known for a few more Bell inequalities: | |||
For the Braunstein-Caves inequalities we have that | |||
:<math> \langle BC_n \rangle \le n\cos(\pi/n) </math> | |||
For the WWŻB inequalities the Tsirelson bound is | |||
:<math> \langle WWZB_n \rangle \le 2^\frac{n-1}{2} </math> | |||
Finding the Tsirelson problem for the <math>I_{3322}</math> inequality is a notorious open problem in quantum information theory. | |||
==Tsirelson bounds from physical principles == | |||
{{Expand section|date=December 2012}} | |||
Lots of research have been dedicated to find a physical principle that explains why quantum correlations go only up to the Tsirelson bound and nothing more. Two such principles have been found, the non-triviality of communication complexity and information causality. Another relevant principle<ref>Gerd Niestegge, | |||
''[http://arxiv.org/abs/1104.0091v2 Three-Slit Experiments and Quantum Nonlocality - The Absence of 3rd-order Interference Implies Tsirelson's Bound]'', | |||
arXiv:1104.0091v2.</ref> | |||
is the absence of 3rd-order interference. | |||
<ref>Urbasi Sinha, Christophe Couteau, Thomas Jennewein, Raymond Laflamme, Gregor Weihs, ''[http://dx.doi.org/10.1126/science.1190545 Ruling Out Multi-Order Interference in Quantum Mechanics]'', Science 329 no. 5990 pp. 418-421 (2010).</ref> | |||
<ref>Craig, D., [[Fay Dowker|Dowker, F.]], Henson, J., Major, S., Rideout, D., & [[Rafael Sorkin|Sorkin, R. D.]], | |||
''[http://dx.doi.org/10.1088/1751-8113/40/3/010 A Bell Inequality Analog in Quantum Measure Theory]'', Journal of Physics A: Mathematical and Theoretical, 40(3), 501 (2007).</ref> | |||
<ref>[[Rafael Sorkin|R. D. Sorkin]], | |||
''[http://dx.doi.org/10.1142/S021773239400294X Quantum Mechanics as Quantum Measure Theory]'', | |||
Mod. Phys. Lett. A, 09, 3119 (1994).</ref> | |||
<ref>Gerd Niestegge, | |||
''[http://dx.doi.org/10.1155/2012/156573 Conditional Probability, Three-Slit Experiments, and the Jordan Algebra Structure of Quantum Mechanics]''. | |||
Advances in Mathematical Physics Volume 2012 Article ID 156573, 20 pages (2012).</ref> | |||
==See also== | |||
*[[Bell's theorem]] | |||
*[[EPR paradox]] | |||
*[[CHSH inequality]] | |||
*[[Quantum pseudo-telepathy]] | |||
== References == | |||
<references/> | |||
{{DEFAULTSORT:Tsirelson's Bound}} | |||
[[Category:Quantum mechanics]] | |||
[[Category:Quantum measurement]] |
Revision as of 01:35, 3 May 2013
A Tsirelson bound is an upper limit to quantum mechanical correlations between distant events. Given that quantum mechanics is non-local, i.e., that quantum mechanical correlations violates Bell inequalities, a natural question to ask is "how non-local can quantum mechanics be?", or, more precisely, by how much can the Bell inequality be violated. The answer is precisely the Tsirelson bound for the particular Bell inequality in question. In general this bound is lower than what would be algebraically possible, and much research has been dedicated to the question of why this is the case.
The Tsirelson bounds are named after B. S. Tsirelson, (or Boris Cirel'son, in a different transliteration) the author of the paper[1] in which the first one was derived.
Tsirelson bound for the CHSH inequality
The first Tsirelson bound was derived as an upper bound on the correlations measured in the CHSH inequality. It states that if we have four (Hermitian) dichotomic observables , , , (i.e., two observables for Alice and two for Bob) with outcomes such that for all , then
For comparison, in the classical (or local realistic case) the upper bound is 2, whereas if any arbitrary assignment of is allowed it is 4. The Tsirelson bound is attained already if Alice and Bob each makes measurements on a qubit, the simplest non-trivial quantum system.
Lots of proofs have been developed for this bound, but perhaps the most enlightening one is based on the Khalfin-Tsirelson-Landau identity. If we define an observable
and , i.e., if the outcomes of the observables are associated to projective measurements, then
If or , which can be regarded as the classical case, it already follows that . In the quantum case, we need only notice that and the Tsirelson bound follows.
Tsirelson bounds for other Bell inequalities
Obtaining a Tsirelson bound for a given Bell inequality is in general a hard problem that has to be solved in a case-by-case basis, although we do have numerical algorithms than can upperbound it. The exact values are known for a few more Bell inequalities:
For the Braunstein-Caves inequalities we have that
For the WWŻB inequalities the Tsirelson bound is
Finding the Tsirelson problem for the inequality is a notorious open problem in quantum information theory.
Tsirelson bounds from physical principles
Lots of research have been dedicated to find a physical principle that explains why quantum correlations go only up to the Tsirelson bound and nothing more. Two such principles have been found, the non-triviality of communication complexity and information causality. Another relevant principle[2] is the absence of 3rd-order interference. [3] [4] [5] [6]
See also
References
- ↑ B. S. Cirel'son, Quantum Generalizations of Bell's Inequality, Lett. Math. Phys. 4, 93 (1980). [1]
- ↑ Gerd Niestegge, Three-Slit Experiments and Quantum Nonlocality - The Absence of 3rd-order Interference Implies Tsirelson's Bound, arXiv:1104.0091v2.
- ↑ Urbasi Sinha, Christophe Couteau, Thomas Jennewein, Raymond Laflamme, Gregor Weihs, Ruling Out Multi-Order Interference in Quantum Mechanics, Science 329 no. 5990 pp. 418-421 (2010).
- ↑ Craig, D., Dowker, F., Henson, J., Major, S., Rideout, D., & Sorkin, R. D., A Bell Inequality Analog in Quantum Measure Theory, Journal of Physics A: Mathematical and Theoretical, 40(3), 501 (2007).
- ↑ R. D. Sorkin, Quantum Mechanics as Quantum Measure Theory, Mod. Phys. Lett. A, 09, 3119 (1994).
- ↑ Gerd Niestegge, Conditional Probability, Three-Slit Experiments, and the Jordan Algebra Structure of Quantum Mechanics. Advances in Mathematical Physics Volume 2012 Article ID 156573, 20 pages (2012).