Presentation is loading. Please wait.

Presentation is loading. Please wait.

Quantum Search of Spatial Regions Scott Aaronson (UC Berkeley) Joint work with Andris Ambainis (U. Latvia)

Published byKevin McDonald Modified over 11 years ago

Similar presentations

Presentation on theme: "Quantum Search of Spatial Regions Scott Aaronson (UC Berkeley) Joint work with Andris Ambainis (U. Latvia)"— Presentation transcript:

1 Quantum Search of Spatial Regions Scott Aaronson (UC Berkeley) Joint work with Andris Ambainis (U. Latvia)

2 Grovers Search Algorithm Unsorted database of n items Goal: Find one marked item Classically, (n) queries to database needed Grover 1996: O( n) queries quantumly BBBV 1996: Grovers algorithm is optimal Great for combinatorial searchbut can it help with a physical database?

3 What even a dumb computer scientist knows: THE SPEED OF LIGHT IS FINITE Marked item Robot n n Consider a quantum robot searching a 2D grid: We need n Grover iterations, each of which takes n time, so were screwed!

4 Undirected connected graph G=(V,E) Bit x i at each vertex v i Goal: Compute some Boolean f(x 1 …x n ) {0,1} State can have arbitrary workspace z: | = i,z |v i,z Alternate query transforms |v i,z (-1) x(i) |v i,z with local unitaries U What does local mean? Depends on your religion Whats the Model?

5 Defining Locality: 3 Choices (1)Decomposability U is a product of commuting edgewise operations (2) Zero pattern of U respects graph 0100 0010 0001 1000 (3) Zero pattern of Hamiltonian H respects graph U = e iH H has bounded eigenvalues (1) (2),(3) Upper bounds work for (1) Lower bounds for (2),(3) Whether theyre equivalent is open

6 So why not pack data in 3 dimensions? Then the complexity would be n n 1/3 = n 5/6 Trouble: Suppose our hard disk has mass density We saw Grover search of a 2D grid presented a problem…

7 Once radius exceeds Schwarzschild bound of (1/ ), database collapses to form a black hole Makes things harder to retrieve… Holographic Principle: Best one can do asymptotically is store data on a 2D surface, 1.4 10 69 bits/meter 2 So Quantum Mechanics and General Relativity both yield a n lower bound on search But can we search a 2D region in less than n steps? Benioff (2001): Guess we cant…

8 REVENGE OF COMPUTER SCIENCE We can. ( n time to move across grid is needed for subroutine anyway) By adding more levels of recursion, can make running time O(n 1/2+ ) Example: Take a classical subroutine that searches a square of size n in n steps Run n copies in superposition and use Grover O(n 3/4 ) Revenge of computer science Can we do better? Say n?

9 Amplitude Amplification Brassard, Høyer, Mosca, Tapp 2002 Theorem: If a quantum algorithm has success probability p and returns a certificate, then by invoking it m times, m=O(1/ p), we can amplify success probability to (1-m 2 p/3)m 2 p # of Iterations Success Probability Diminishing returns Better to keep prob low & amplify later

10 Assume theres a unique marked item Divide into n 1/5 subcubes, each of size n 4/5 Algorithm A: If n=1, check whether youre at a marked item Else pick a random subcube and run A on it Amplify n 1/11 times Algorithm for d 3 Dimensions T(n) n 1/11 (T(n 4/5 )+O(n 1/d )) = O(n 5/11 ) P(n) (1- )n 2/11 n -1/5 P(n 4/5 ) = (n -1/11 ) (we show is negligible) Running Time: Success Prob: Amplify whole algorithm n 1/22 times to get T(n) = O(n 1/22 n 5/11 ) = O( n),P(n) = (1)

11 Summary of Bounds d 3 d=2 Unique marked item ( n)O( n log 2 n) k marked items ( n / k 1/2-1/d )O( n log 3 n) Arbitrary graph O( n log c n) n 2 O( log n) Arbitrary graph, h possible marked items O( h (n/h) 1/d log c h) ( h (n/h) 1/d ) n 2 O( log n) When d=2, time for Grover search matches radius of grid An arbitrary graph is d-dimensional if for any vertex v, number of vertices at distance r from v is (min{r d,n}) When there are h possible marked items with known locations, the worst case is that theyre evenly scattered

12 Razborov 2002: ( n) Problem: Alice has x 1 …x n {0,1} n, Bob has y 1 …y n They want to know if x i y i =1 for some i Application: Disjointness How many qubits must they communicate? Buhrman, Cleve, Wigderson 1998: O( n log n) Høyer, de Wolf 2002: O( n c log*n )

13 A B State at any time: Communicating one of 6 directions takes only 3 qubits Disjointness in O( n) Communication i,z(A),z(B) |v i,z A |v i,z B

14 Recent Progress Childs-Goldstone: Spatial search by quantum walk O(n 5/6 ) for d=3, O( n log n) for d=4, O( n) for d>4 Running time not competitive with ours in low dimensions, but less memory needed Ambainis-Kempe: Discrete walk with 2-bit coin O( n log n) for d=2, O( n) for d 3 Connection to Dirac equation?

Download ppt "Quantum Search of Spatial Regions Scott Aaronson (UC Berkeley) Joint work with Andris Ambainis (U. Latvia)"

Similar presentations

Improved Simulation of Stabilizer Circuits Scott Aaronson (UC Berkeley) Joint work with Daniel Gottesman (Perimeter) 0 0 0 0 1 0 0 1 0 0 1 0 0 0 0 0 0.

Improved Simulation of Stabilizer Circuits Scott Aaronson (UC Berkeley) Joint work with Daniel Gottesman (Perimeter)
Quantum Computing: Whats It Good For? Scott Aaronson Computer Science Department, UC Berkeley January 10, 2002 www.cs.berkeley.edu/~aaronson.

Quantum Computing: Whats It Good For? Scott Aaronson Computer Science Department, UC Berkeley January 10,
Computation, Quantum Theory, and You Scott Aaronson, UC Berkeley Qualifying Exam May 13, 2002.

Computation, Quantum Theory, and You Scott Aaronson, UC Berkeley Qualifying Exam May 13, 2002.
The Polynomial Method In Quantum and Classical Computing Scott Aaronson (MIT) OPEN PROBLEM.

The Polynomial Method In Quantum and Classical Computing Scott Aaronson (MIT) OPEN PROBLEM.
Quantum Lower Bounds You probably Havent Seen Before (which doesnt imply that you dont know OF them) Scott Aaronson, UC Berkeley 9/24/2002.

Quantum Lower Bounds You probably Havent Seen Before (which doesnt imply that you dont know OF them) Scott Aaronson, UC Berkeley 9/24/2002.
Quantum Search of Spatial Regions Scott Aaronson (UC Berkeley) Joint work with Andris Ambainis (IAS / U. Latvia)

Quantum Search of Spatial Regions Scott Aaronson (UC Berkeley) Joint work with Andris Ambainis (IAS / U. Latvia)
Quantum Lower Bound for the Collision Problem Scott Aaronson 1/10/2002 quant-ph/0111102 I was born at the Big Bang. Cool! We have the same birthday.

Quantum Lower Bound for the Collision Problem Scott Aaronson 1/10/2002 quant-ph/ I was born at the Big Bang. Cool! We have the same birthday.
The Complexity of Sampling Histories Scott Aaronson, UC Berkeley August 5, 2003.

The Complexity of Sampling Histories Scott Aaronson, UC Berkeley August 5, 2003.
Quantum Lower Bounds The Polynomial and Adversary Methods Scott Aaronson September 14, 2001 Prelim Exam Talk.

Quantum Lower Bounds The Polynomial and Adversary Methods Scott Aaronson September 14, 2001 Prelim Exam Talk.
The Learnability of Quantum States Scott Aaronson University of Waterloo.

The Learnability of Quantum States Scott Aaronson University of Waterloo.
Quantum t-designs: t-wise independence in the quantum world Andris Ambainis, Joseph Emerson IQC, University of Waterloo.

Quantum t-designs: t-wise independence in the quantum world Andris Ambainis, Joseph Emerson IQC, University of Waterloo.
Quantum Versus Classical Proofs and Advice Scott Aaronson Waterloo MIT Greg Kuperberg UC Davis | x {0,1} n ?

Quantum Versus Classical Proofs and Advice Scott Aaronson Waterloo MIT Greg Kuperberg UC Davis | x {0,1} n ?
Quantum Software Copy-Protection Scott Aaronson (MIT) |

Quantum Software Copy-Protection Scott Aaronson (MIT) |
The Future (and Past) of Quantum Lower Bounds by Polynomials Scott Aaronson UC Berkeley.

The Future (and Past) of Quantum Lower Bounds by Polynomials Scott Aaronson UC Berkeley.
SPEED LIMIT n Quantum Lower Bounds Scott Aaronson (UC Berkeley) August 29, 2002.

SPEED LIMIT n Quantum Lower Bounds Scott Aaronson (UC Berkeley) August 29, 2002.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 1 23 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 Lower Bounds for Local Search by Quantum Arguments Scott Aaronson.

Lower Bounds for Local Search by Quantum Arguments Scott Aaronson.
Quantum Computing and Dynamical Quantum Models ( quant-ph/0205059) Scott Aaronson, UC Berkeley QC Seminar May 14, 2002.

Quantum Computing and Dynamical Quantum Models ( quant-ph/ ) Scott Aaronson, UC Berkeley QC Seminar May 14, 2002.
Limitations of Quantum Advice and One-Way Communication Scott Aaronson UC Berkeley IAS Useful?

Limitations of Quantum Advice and One-Way Communication Scott Aaronson UC Berkeley IAS Useful?
NP-complete Problems and Physical Reality

NP-complete Problems and Physical Reality
Quantum Double Feature Scott Aaronson (MIT) The Learnability of Quantum States Quantum Software Copy-Protection.

Quantum Double Feature Scott Aaronson (MIT) The Learnability of Quantum States Quantum Software Copy-Protection.

Similar presentations

Ads by Google