This study presents a comprehensive thermal stress analysis of critical components in an embedded multi-die interconnect bridge(EMIB)within a chiplet package using finite element analysis(FEA).We systematically evalua...This study presents a comprehensive thermal stress analysis of critical components in an embedded multi-die interconnect bridge(EMIB)within a chiplet package using finite element analysis(FEA).We systematically evaluated key design parameters—including bump diameter-to-pitch ratios,bump distribution patterns,EMIB thickness,number of EMIBs,and aspect ratios—to assess their impact on stresses.An ABAQUS-based FEA model was used to simulate thermal loading with a 165°C temperature increase.The results indicate that a bump diameter-to-pitch ratio of 0.3 optimizes stress distribution,while a peripheral bump arrangement is superior in stress reduction compared to other patterns.Thinner EMIBs linearly reduce maximum principal stress,whereas multiple EMIBs and aspect ratio variations have minimal effects.These findings offer practical guidelines for optimizing EMIB design in chiplet packages,emphasizing the importance of bump geometry,distribution patterns,and EMIB thickness for improved reliability.展开更多
基金supported in part by the National Natural Science Foundation of China under Grant 61774044in part by the Ministry of Education(MOE)Innovation Platform.
文摘This study presents a comprehensive thermal stress analysis of critical components in an embedded multi-die interconnect bridge(EMIB)within a chiplet package using finite element analysis(FEA).We systematically evaluated key design parameters—including bump diameter-to-pitch ratios,bump distribution patterns,EMIB thickness,number of EMIBs,and aspect ratios—to assess their impact on stresses.An ABAQUS-based FEA model was used to simulate thermal loading with a 165°C temperature increase.The results indicate that a bump diameter-to-pitch ratio of 0.3 optimizes stress distribution,while a peripheral bump arrangement is superior in stress reduction compared to other patterns.Thinner EMIBs linearly reduce maximum principal stress,whereas multiple EMIBs and aspect ratio variations have minimal effects.These findings offer practical guidelines for optimizing EMIB design in chiplet packages,emphasizing the importance of bump geometry,distribution patterns,and EMIB thickness for improved reliability.
