Adaptive Computation of the Swap-Insert Correction Distance

The cluster state model for quantum computation [Phys. Rev. Lett. \textbf{86}, 5188] outlines a scheme that allows one to use measurement on a large set of entangled quantum systems in what is known as a cluster state to undertake quantum computations. The model itself and many works dedicated to it involve using entangled qubits. In this paper we consider the issue of using entangled qudits instead. We present a complete framework for cluster state quantum computation using qudits, which not only contains the features of the original qubit model but also contains the new idea of adaptive computation: via a change in the classical computation that helps to correct the errors that are inherent in the model, the implemented quantum computation can be changed. This feature arises through the extra degrees of freedom that appear when using qudits. Finally, for prime dimensions, we give a very explicit description of the model, making use of mutually unbiased bases.

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Adaptive Computation over Dynamic and Heterogeneous Networks

Parallel Processing and Applied Mathematics - Lecture Notes in Computer Science ◽

10.1007/978-3-540-24669-5_140 ◽

2004 ◽

pp. 1083-1090

Author(s):

Kaoutar El Maghraoui ◽

Joseph E. Flaherty ◽

Boleslaw K. Szymanski ◽

James D. Teresco ◽

Carlos Varela

Keyword(s):

Heterogeneous Networks ◽

Adaptive Computation

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Reducing Design Margins by Adaptive Compensation for Thermal and Aging Variations

Sustainable ICTs and Management Systems for Green Computing ◽

10.4018/978-1-4666-1839-8.ch009 ◽

2012 ◽

pp. 201-230

Author(s):

Zhenyu Qi ◽

Yan Zhang ◽

Mircea Stan

Keyword(s):

Design Parameters ◽

Worst Case Analysis ◽

Transimpedance Amplifier ◽

Large Area ◽

Negative Bias Temperature Instability ◽

Worst Case ◽

Adaptive Computation ◽

Bias Temperature Instability ◽

Computation Efficiency ◽

On Chip

Corner-based design and verification are based on worst-case analysis, thus introducing over-pessimism and large area and power overhead and leading to unnecessary energy consumption. Typical case-based design and verification maximize energy efficiency through design margins reduction and adaptive computation, thus helping achieve sustainable computing. Dynamically adapting to manufacturing, environmental, and usage variations is the key to shaving unnecessary design margins, which requires on-chip modules that can sense and configure design parameters both globally and locally to maximize computation efficiency, and maintain this efficiency over the lifetime of the system. This chapter presents an adaptive threshold compensation scheme using a transimpedance amplifier and adaptive body biasing to overcome the effects of temperature variation, reliability degradation, and process variation. The effectiveness and versatility of the scheme are demonstrated with two example applications, one as a temperature aware design to maintain IONto IOFFcurrent ratio, the other as a reliability sensor for NBTI (Negative Bias Temperature Instability).

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Towards a Prehistory of Evolutionary and Adaptive Computation in Music

Lecture Notes in Computer Science - Applications of Evolutionary Computing ◽

10.1007/3-540-36605-9_46 ◽

2003 ◽

pp. 502-509

Author(s):

Colin G. Johnson

Keyword(s):

Adaptive Computation

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An Adaptive Approach Towards Computation Offloading for Mobile Cloud Computing

International Journal of Information Technology and Web Engineering ◽

10.4018/ijitwe.2019040104 ◽

2019 ◽

Vol 14 (2) ◽

pp. 52-73 ◽

Cited By ~ 2

Author(s):

Archana Kero ◽

Abhirup Khanna ◽

Devendra Kumar ◽

Amit Agarwal

Keyword(s):

Cloud Computing ◽

Mobile Cloud Computing ◽

Computation Offloading ◽

Mobile Cloud ◽

Adaptive Computation ◽

Proposed Model ◽

Environment Variables ◽

Real Time Information ◽

Time Information

The widespread acceptability of mobile devices in present times have caused their applications to be increasingly rich in terms of the functionalities they provide to the end users. Such applications might be very prevalent among users but the execution results in dissipating many of the device end resources. Mobile cloud computing (MCC) has a solution to this problem by offloading certain parts of the application to cloud. At the first place, one might find computation offloading quite promising in terms of saving device end resources but eventually may result in being the other way around if performed in a static manner. Frequent changes in device end resources and computing environment variables may lead to a reduction in the efficiency of offloading techniques and even cause a drop in the quality of service for applications involving the use of real-time information. In order to overcome this problem, the authors propose an adaptive computation offloading framework for data stream applications wherein applications are partitioned dynamically followed by being offloaded depending upon the device end parameters, network conditions, and cloud resources. The article also talks about the proposed algorithm that depicts the workflow of the offloading model. The proposed model is simulated using the CloudSim simulator. In the end, the authors illustrate the working of the proposed system along with the simulated results.

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