Revision as of 15:40, 7 July 2007 edit Michael Hardy (talk \| contribs) Administrators 210,577 edits No edit summary ← Previous edit		Revision as of 15:41, 7 July 2007 edit undo Michael Hardy (talk \| contribs) Administrators 210,577 edits links Next edit →
Line 7: * In their standard monograph Nielsen and Chuang state "Of particular interest is a decisive answer to the problem whether quantum computers are more powerful than classical computers." To answer this question one must know the classical and quantum computational complexities We discuss the second motivation. By computational complexity (complexity for brevity) is meant the '''minimal''' computational resources needed to solve a problem. Two of the most important resources for quantum computing are [[qubit]]s and queries. Classical complexity has been extensively studied in [[~~Information~~information-~~Based~~based ~~Complexity\| Information-Based Complexity~~complexity]]. The classical complexity of many continuous problems is known. Therefore, when the quantum complexity of these problems is obtained, the question as to whether quantum computers are more powerful than classical can be answered. Furthermore, it can be established how much more powerful. In contrast, the complexity of discrete problems is typically unknown; one has to settle for the complexity hierarchy. For example, the classical complexity of integrer factorization is unknown. ==An example: path integration== Path integration has numerous applications including [[quantum mechanics]], [[quantum chemistry]], [[statistical mechanics]], and [[computational finance]]. We want to compute an approximation to within error at most <math>\scriptstyle\varepsilon</math> with probability, say, at least 3/4. Then the following was [http://arXiv.org/quant-ph/0109113 shown] by Traub and Woźniakowski: * A quantum computer enjoys exponential speedup over the classical worst case and quadratic speedup over the classical randomized case. * The query complexity is of order <math>\scriptstyle\varepsilon^{-1}</math>.

Continuous quantum computation: Difference between revisions