TY - GEN
T1 - Analytically modeling nonlinear DC-gain for Op-amps
AU - Chen, Fu-Chuang
AU - Lin, J. Y.
N1 - Publisher Copyright:
© 2015 Taylor & Francis Group, London.
PY - 2015
Y1 - 2015
N2 - Op-amp dc-gain is nonlinear, and this can cause distortions in various applications. However, so far no efficient tool is available for analyzing dc-gain nonlinearity; the dc-gain curve can only be generated from a designed op-amp. If the dc-gain nonlinearity is too serious, one has to redesign op-amps. Time-consuming iterations involving transistor-level designs and simulations may be needed before an acceptable result is achieved. In this brief, an analytical op-amp dc-gain curve model is proposed. After entering circuit parameters and process parameters into this model, it can generate op-amp nonlinear dc-gain curves to facilitate subsequent distortion analyses, requiring no transistor- level designs and simulations. This dc-gain model applies to general two-stage op-amps, and can accommodate various 1st stage configurations, including cascode and folded cascode ones. Our analyses show that the smaller VDD is, the more precise the analytical model becomes. Simulations demonstrate that, when VDD ≤ 1.8V, the error between the curve from the model and the curve generated from SPICE simulation is less than 2%.
AB - Op-amp dc-gain is nonlinear, and this can cause distortions in various applications. However, so far no efficient tool is available for analyzing dc-gain nonlinearity; the dc-gain curve can only be generated from a designed op-amp. If the dc-gain nonlinearity is too serious, one has to redesign op-amps. Time-consuming iterations involving transistor-level designs and simulations may be needed before an acceptable result is achieved. In this brief, an analytical op-amp dc-gain curve model is proposed. After entering circuit parameters and process parameters into this model, it can generate op-amp nonlinear dc-gain curves to facilitate subsequent distortion analyses, requiring no transistor- level designs and simulations. This dc-gain model applies to general two-stage op-amps, and can accommodate various 1st stage configurations, including cascode and folded cascode ones. Our analyses show that the smaller VDD is, the more precise the analytical model becomes. Simulations demonstrate that, when VDD ≤ 1.8V, the error between the curve from the model and the curve generated from SPICE simulation is less than 2%.
UR - http://www.scopus.com/inward/record.url?scp=84962193067&partnerID=8YFLogxK
U2 - 10.1201/b18470-51
DO - 10.1201/b18470-51
M3 - Conference contribution
AN - SCOPUS:84962193067
SN - 9781138028128
T3 - Testing and Measurement: Techniques and Applications - Proceedings of the 2015 International Conference on Testing and Measurement: Techniques and Applications, TMTA 2015
SP - 239
EP - 242
BT - Testing and Measurement
A2 - Chan, Kennis
PB - CRC Press/Balkema
T2 - International Conference on Testing and Measurement: Techniques and Applications, TMTA 2015
Y2 - 16 January 2015 through 17 January 2015
ER -