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9 Mar 2017: Reference. Wardill, TJ et al. A novel interception strategy in a miniature robber fly with extreme visual acuity; Current Biology; 9 March 2017; DOI: 10.1016/j.cub.2017.01.050.

15 Jan 2017: where Xj R. 2, tj L, ij N. Fig. 3. ... D′ = {(X′1, t′1, 1),. } then D D′ iff(Xj, tj, ij ) D, tj = t′j and g G, g(Xj ) = X′j, g1(X′j ) = Xj or redrawrule R,

30 Sep 2017: Pj’s local state is WANT)– If (Tj, Pj) < (Ti, Pi) then queue request from Pi– Otherwise, reply with OK, and continue waiting. • ... Tj)– Processes adds all requests and ACKs to the queue in order– If process Pi sees his request is earliest

15 Mar 2017: Since {e1,. ,er1} is linearly independent there must besome 1 6 j 6 k such that λj 6= 0 and tj 6 {e1,. ... er1} = (Tr{tj}) {er1}. Now. tj =1. λjer1. i 6=j. λiλjti,.

13 Oct 2017: For sensor Si sensing Ci at time slot Tj , we use a randomvariable θi,j to represent whether Ci is idle (θi,j = 1) or not(θi,j = 0). ... We also use ωi,j to represent the data transmissionrequest of sensor Si at time slot Tj , where ωi,j = 1

18 Oct 2017: We use the average job slowdown as the primarysystem objective. Formally, for each job j, the slowdown isgiven by Sj = Cj/Tj, where Cj is the completion time ofthe job ... e., the time between arrival and completion of ex-ecution) and Tj is the (ideal)

13 Mar 2017: Reference. Stevens, TJ et al. 3D structures of individual mammalian genomes studied by single-cell Hi-C.

15 Jan 2017: Pj’s local state is WANT)– If (Tj, Pj) < (Ti, Pi) then queue request from Pi– Otherwise, reply with OK, and continue waiting. • ... Variant scheme (Lamport) - multicast for total ordering– To enter, process Pi multicasts request(Pi, Ti) [same

18 Oct 2017: We use the average job slowdown as the primarysystem objective. Formally, for each job j, the slowdown isgiven by Sj = Cj/Tj, where Cj is the completion time ofthe job ... e., the time between arrival and completion of ex-ecution) and Tj is the (ideal)

18 Oct 2017: We use the average job slowdown as the primarysystem objective. Formally, for each job j, the slowdown isgiven by Sj = Cj/Tj, where Cj is the completion time ofthe job ... e., the time between arrival and completion of ex-ecution) and Tj is the (ideal)