Demand for off-chip bandwidth has continued to increase. It is projected by the Semiconductor Industry Association in their International Technology Roadmap for Semiconductors (ITRS) that by the year 2015, the chip-to-substrate area-array input-output interconnects will require a pitch of 70 μm. Compliant off-chip interconnects show great potential to address these needs. G-Helix is a lithography-based electroplated compliant interconnect that can be fabricated at the wafer level. G-Helix interconnects exhibit excellent compliance in all three orthogonal directions, and can accommodate the CTE mismatch between the silicon die and the organic substrate without requiring an underfill. Also, these compliant interconnect are less likely to crack or delaminate the low-K dielectric material in current and future ICs. The interconnects are also potentially cost effective as they can be fabricated using conventional wafer fabrication infrastructure. In this paper we present an integrative approach which uses interconnects with varying compliance and thus varying electrical preformance from the center to the edge of the die. Using such a varying geometry from the center to the edge of the die, the system performance can be tailored by balancing electrical requirements against thermo-mechanical reliability concerns. We also discuss the reliability assessment results of helix interconnects assembled on an organic substrate. Results from mechanical characterization experiments are also presented.