Development of Evaluation Method for Estimating Stress-Induced Change in Drain Current in Deep-sub-micron MOSFETs

A novel constant-gm rail-to-rail input stage for CMOS operational amplifier is presented in this paper. The input stage mainly consists of a PMOS transistors differential pair and a NMOS transistors differential pair placed in parallel as a rail-to-rail differential input stage and the tail currents of the two differential pairs are controlled by a PMOS and a NMOS common-mode voltage sensor respectively. The gm of the input stage of the operational amplifier could be a constant value within the input common-mode voltage. The simulation result shows that when the power supply voltage is 1.8V and 3.3V respectively, the gm variation in the entire input range (0~1.8V or 0~3.3V) is within ± 1.38% and ± 3.38%. The power dissipation is 36.9μW and 51.74μW. SMIC 55nm CMOS process and Cadence SPECTRE simulator are used to layout and simulate this work.

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Structural Design of Three-dimensionally Stacked Silicon Chips Mounted by Flip Chip Technology for Minimizing Their Residual Stress

Ueta¹,

Sasaki²,

Miura

2009

Journal of Japan Institute of Electronics Packaging

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The residual stress in LSI chips mounted in synchronous stacked bump structures such as stacked memory structures varies drastically depending on their bump joint structures. It sometimes reaches a few hundred MPa and deteriorates their functions and the reliability of products. Thus, a new bump joint structure is proposed for minimizing the residual stress considering the relative positions between bumps and vias using a finite element analysis. The amplitude of the residual stress in each stacked chip in the optimum stacked structure can be decreased to less than 30 MPa and the difference of the residual stress between the stacked chips to nearly 0 MPa. The alternative alignment structure between bumps and vias is effective for minimizing the local residual stress in a chip. Introducing a stress-relaxation layer under the bump using a material with a low elastic modulus is also effective for minimizing the local residual stress. Therefore, it is important to optimize the assembly structure of the three-dimensionally stacked LSI chips in order to minimize the residual stress.

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Development of Evaluation Method for Estimating Stress-Induced Change in Drain Current in Deep-sub-micron MOSFETs

Cited by 3 publications

References 6 publications

Evaluation of Stress-Induced Effects in Electronic Characteristics of nMOSFETs

Evaluation of Stress-Induced Effects in Electronic Characteristics of nMOSFETs

A novel constant-g<sub>m</sub> rail-to-rail input stage for operational amplifiers

Structural Design of Three-dimensionally Stacked Silicon Chips Mounted by Flip Chip Technology for Minimizing Their Residual Stress

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