K.F. Korver scite author profile

K.F. Korver

3Publications

18Citation Statements Received

74Citation Statements Given

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What designers of bus and network architectures should know about hypercubes

LaForge¹,

Korver²,

Fadali³

2003

IEEE Trans. Comput.

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We quantify why, as designers, we should prefer clique-based hypercubes (K-cubes) over traditional hypercubes based on cycles (C-cubes). Reaping fresh analytic results, we find that K-cubes minimize the wirecount and, simultaneously, the latency of hypercube architectures that tolerate failure of any f nodes. Refining the graph model of Hayes (1976), we pose the feasibility of configuration as a problem in multivariate optimization: What (f +1)-connected n-vertex graphs with fewest edges n(f+1)/2 minimize the maximum a) radius or b) diameter of subgraphs (i.e., quorums) induced by deleting up to f vertices? (1) We solve (1) for f that is superlogarithmic but sublinear in n, and in the process prove: I) the fault tolerance of K-cubes is proportionally greater than that of C-cubes; II) quorums formed from K-cubes have a diameter that is asymptotically convergent to the Moore Bound on radius; III) under any conditions of scaling, by contrast, C-cubes diverge from the Moore Bound. Thus, K-cubes are optimal, while C-cubes are suboptimal. Our exposition furthermore: IV) counterexamples, corrects, and generalizes a mistaken claim by Armstrong and Gray (1981) concerning binary cubes; V) proves that K-cubes and certain of their quorums are the only graphs which can be labeled such that the edge distance between any two vertices equals the Hamming distance between their labels; and VI) extends our results to K-cube-connected cycles and edges. We illustrate and motivate our work with applications to the synthesis of multicomputer architectures for deep space missions.

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Graph-theoretic fault tolerance for spacecraft bus avionics

LaForge¹,

Korver²

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Introducing new analytic results, we minimize the cost of point-to-point fault tolerant avionics architectures. Refining the graph model of Hayes [23], we formulate the worst-case feasibility of configuration as:What Cf+l)-connected n-vertex graphs with fewest edges minimize the maximum radius or diameter4 of subgraphs (i.e., quorums) induced by deleting up to f of the n vertices?We solve this problem by proving: i) K-cubes (cubes based on cliques) can tolerate a greater proportion of faults than can traditional C-cubes (cubes based on cycles); ii) quorums formed from K-cubes have a diameter that is asymptotically equal to the Moore bound, while under no conditions of scaling can the Moore bound be attained by C-cubes whose radix exceeds 4. Thus, for fault tolerance logarithmic in n, K-cubes are optimal, whereas C-cubes are suboptimal. Our exposition also corrects and generalizes a mistaken claim by Armstrong and Gray [ 191 concerning binary cubes.

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Mutual test and diagnosis: architectures and algorithms for spacecraft avionics

LaForge¹,

Korver²

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K.F. Korver

What designers of bus and network architectures should know about hypercubes

Graph-theoretic fault tolerance for spacecraft bus avionics

Mutual test and diagnosis: architectures and algorithms for spacecraft avionics

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