A methodology for the automatic synthesis of full-custom IC layout with analog constraints is presented. The methodology guarantees that all performance constraints are met when feasible, or otherwise infeasibility is detected as soon as possible, thus providing a robust and efficient design environment. In the proposed approach, performance specifications are translated into lower level bounds on parasitics or geometric parameters, using sensitivity analysis. Bounds can be used by a set of specialized layout tools performing stack generation, placement, routing and compaction. For each tool, a detailed description is provided of its functionality, of the way constraints are mapped and enforced, and of its impact on the design flow. Examples drawn from industrial applications are reported to illustrate the effectiveness of the approach. Keywords--- Layout, Analog Design, Constraint-Driven Layout. I. Introduction The layout of analog circuits is intrinsically more difficult than the d...

Characterizing setup/hold times of latches and registers, a crucial component for achieving timing closure of large digital designs, typically occupies months of computation in industries such as Intel and IBM. We present a novel approach to speed up latch characterization by formulating the setup/hold time problem as a scalar nonlinear equation h(τ) =0 derived using state-transition functions, and then solving this equation by Newton-Raphson (NR). The local quadratic convergence of NR results in rapid improvements in accuracy at every iteration, thereby significantly reducing the computation needed for accurate determination of setup/hold times. We validate the fast convergence and computational advantage of the new method on transmission gate and C 2 MOS latch/register structures, obtaining speedups of 4-10 × over the current standard of binary search. I.