* (C) Copyright Efficient Power Conversion Corporation. All rights reserved. ***************************************************************************** * Version History: * 1.00: 07/24/2015 - Initial Model Creation * 1.01: 04/19/2017 - Updated EPC2037 Model from the Preliminary Version * 1.02: 02/19/2019 - Updated the Capacitance Model .subckt EPC2037 gatein drainin sourcein .param aWg=16 A1=0.5748 k2=2.35 k3=0.15 rpara=0.29409 rpara_s_factor=0.21 + aITc=0.00288 arTc=-0.0072 k2Tc=0.0005 x0_0=1.4598 x0_1=4.6153e-06 x0_0_TC=-0.001 x0_1_TC=0 + dgs1=4.3e-07 dgs2=2.6e-13 dgs3=0.8 dgs4=0.23 + ags1=1.3857e-11 ags2=6.7586e-12 ags3=2.4044 ags4=0.18882 + ags5=-1.7947e-12 ags6=-13.267 ags7=4.0137 + agd1=1.8845e-15 agd2=2.8234e-13 agd3=-4.5385 agd4=30.25 + agd5=2.006e-12 agd6=-6.5869 agd7=3.9822 + agd8=2.4327e-13 agd9=-21.866 agd10=2.5136 + asd1=3.9406e-12 asd2=8.6789e-12 asd3=-22.408 asd4=5.4085 + asd5=1.0323e-11 asd6=-0.10137 asd7=41.925 rg_value=0.5 rd drainin drain {((1-rpara_s_factor)*rpara*(1-arTc*(Temp-25)))} rs sourcein source {(rpara_s_factor*rpara*(1-arTc*(Temp-25)))} rg gatein gate {(rg_value)} *Large resistors to aid convergence Rcsdconv drain source {100000Meg/aWg} Rcgsconv gate source {100000Meg/aWg} Rcgdconv gate drain {100000Meg/aWg} gswitch drain source Value {if(v(drain,source)>0, + (A1*(1-aITc*(Temp-25))*log(1.0+exp((v(gate,source)-(k2*(1-k2Tc*(Temp-25))))/k3))* + v(drain,source)/(1 + (x0_0*(1-x0_0_TC*(Temp-25))+x0_1*(1-x0_1_TC*(Temp-25))*v(gate,source))*v(drain,source)) ), + (-A1*(1-aITc*(Temp-25))*log(1.0+exp((v(gate,drain)-(k2*(1-k2Tc*(Temp-25))))/k3))* + v(source,drain)/(1 + (x0_0*(1-x0_0_TC*(Temp-25))+x0_1*(1-x0_1_TC*(Temp-25))*v(gate,drain))*v(source,drain)) ) )} ggsdiode gate source VALUE {if( v(gate,source) < 10, + 0.125*aWg/1077*(dgs1*(exp((v(gate,source))/dgs3)-1)+dgs2*(exp((v(gate,source))/dgs4)-1)), + 0.125*aWg/1077*(dgs1*(exp((10)/dgs3)-1)+dgs2*(exp((10)/dgs4)-1)) ) } ggddiode gate drain Value {if( v(gate,drain) < 10, + 0.125*aWg/1077*(dgs1*(exp((v(gate,drain))/dgs3)-1)+dgs2*(exp((v(gate,drain))/dgs4)-1)), + 0.125*aWg/1077*(dgs1*(exp((10)/dgs3)-1)+dgs2*(exp((10)/dgs4)-1)) ) } *Model for voltage dependent gate-source capacitance E_GS tl_gs bl_gs gate source 1.0 V_INGS 0 bl_gs 0V C_IGS tl_gs 0 1.0E-6 G_GS gate source VALUE = {1E6*I(V_INGS)* + (ags1 + 0.5*ags2/(1.0 + exp( (v(gate,source)-ags3)/ags4 ))*exp( (v(gate,source)-ags3)/ags4 ) + + ags5/(1.0 + exp((v(source,drain)-ags6)/ags7))*exp((v(source,drain)-ags6)/ags7))} *Model for voltage dependent gate-drain capacitance E_GD tl_gd bl_gd gate drain 1.0 V_INGD 0 bl_gd 0V C_IGD tl_gd 0 1.0E-6 G_GD gate drain VALUE = {1E6*I(V_INGD)*(agd1 + 0.5*ags2/(1.0 + exp((v(gate,drain)-ags3)/ags4))*exp((v(gate,drain)-ags3)/ags4) + + agd2/(1.0 + exp((v(gate,drain)-agd3)/agd4))*exp((v(gate,drain)-agd3)/agd4) + + agd5/(1.0 + exp((v(gate,drain)-agd6)/agd7))*exp((v(gate,drain)-agd6)/agd7) + + agd8/(1.0 + exp((v(gate,drain)-agd9)/agd10))*exp((v(gate,drain)-agd9)/agd10))} *Model for voltage dependent source-drain capacitance E_SD tl_ds bl_ds source drain 1.0 V_INSD 0 bl_ds 0V C_ISD tl_ds 0 1.0E-6 G_SD source drain VALUE = {1E6*I(V_INSD)*(asd1 + asd2/(1 + exp((v(source,drain)-asd3)/asd4))*exp((v(source,drain)-asd3)/asd4) + + asd5/(1 + exp((v(source,drain)-asd6)/asd7))*exp((v(source,drain)-asd6)/asd7))} .ends