OBSSd Spice MacroV1.00 98/01/15TINA Device Editor 6.02.006CV Copyright 1997 DesignSoft, Inc. -TMP20TMP20@C:\Program Files\DesignSoft\Tina Pro\New Macros\TMP20\tmp20.cirTMP20TMP20UÄÿØÿ?*ÆÿÚÿ=(pXÌÿd*2X èÿ @d*2  @d*3NDArial 8 @d*4ð?\/ àÿ @d*5outArialøÿ Èÿ @ fÐÿ0èÿÿÿÿgT(V)ArialÔÿøÿð?ÿgGNDArialÜÿð?ÿgV+Arialüÿìÿð?ÿgVoutArialøÿð?ÿgGNDArialð?ÿg4ArialØÿð?€€g1ArialÄÿìÿð?€€g5Arial$ð?€€g2Arialôÿð?€€g3Arial8ð?€€Ä å´Âã@Ä å´Âã@í.* TMP20 - Temperature Sensor SPICE MACROMODEL*)* +/2.5 Deg-C, low-power, analog output *a* Model definition by HPA Linear Products Applications Engineering (tek)- Texas Instruments Inc. * &* Rev. A - August 2010, by W.K. SANDS*L***************************************************************************K** (C) Copyright 2010 Texas Instruments Incorporated. All rights reserved.H** This model is designed as an aid for customers of Texas Instruments.X** TI and its licensors and suppliers make no warranties, either expressed or implied, X** with respect to this model, including the warranties of merchantability or fitness Z** for a particular purpose. The model is provided solely on an "as is" basis. The entireI** risk as to its quality and performance is with the customer. L***************************************************************************** BEGIN MODEL TMP20-* YOU MAY HAVE TO DO SLIGHT MODIFICATIONS TO-* THIS MODEL FOR YOUR SIMULATOR - SEE BELOW.* BEGIN FEATURES-* NOTE THAT MODEL OUTPUT VOLTAGE RESPONDS TO,* THE TEMPERATURE VOLTAGE INPUT WHILE MODEL$* IQ RESPONDS TO SPICE TEMPERATURE./* MODEL FEATURES INCLUDE TRANSFER FUNCTION PER.* DATA SHEET EQUATIONS, A TEMPERATURE VOLTAGE** INPUT WITH PROPER TIME RESPONSE, OUTPUT+* IMPEDANCE, CURRENT LIMIT, OUTPUT CURRENT)* THROUGH THE RAILS, STABILITY VS CLOAD,,* IQ VERSUS SPICE TEMPERATURE, NIL IQ BELOW+* 0.5 VOLTS SUPPLY, VCC MIN VERSUS VOLTAGE(* INPUT TEMPERATURE, ACCURACY VS SUPPLY/* VOLTAGE, LOAD REGULATION, AND OUTPUT VOLTAGE * NOISE.-* NOTE THAT THE TEMPERATURE VOLTAGE INPUT IS,* SCALED AT 1 V PER DEG C AND IS REFERENCED* TO THE TMP20 GND PIN.** MODEL SPICE TEMPERATURE RANGE IS -55 TO * +150 DEG C** NOTE THAT MODEL IS FUNCTIONAL OVER THIS+* RANGE BUT NOT ALL PARAMETERS TRACK THOSE* OF THE REAL PART.* PINOUT ORDER GND VOUT V+ VIN* PINOUT ORDER 2 3 4 5.SUBCKT TMP20 2 3 4 5* BEGIN MODEL PROGRAMMING0* TO VARY INTERNAL GAIN SLIGHTLY USE R123 BELOWR123 31 23 15E61* THE THREE SETS OF COMPUTATION LINES BELOW HAVE.* DIFFERENT SYNTAX FOR TINA/PSPICE AND PSPICE2* DERIVED SIMULATORS THAN FOR THE BERKELEY SPICE31* AND BERKELEY DERIVED SPICE3 SIMULATORS AND THE* HSPICE SIMULATOR.* BEGIN TINA AND PSPICE SYNTAX&E45 83 84 VALUE ={-3.88E-6*V(1)*V(1)}!E46 84 85 VALUE ={-1.15E-2*V(1)}* END TINA AND PSPICE SYNTAX* BEGIN BERKELEY SYNTAX&*B45 83 84 V = -3.88E-6 * V(1) * V(1)*B46 84 85 V = -1.15E-2 * V(1)* END BERKELEY SYNTAX* BEGIN HSPICE SYNTAX$*E53 83 84 VOL='-3.88E-6*V(1)*V(1)'*E56 84 85 VOL='-1.15E-2*V(1)'* END HSPICE SYNTAX* END MODEL PROGRAMMINGQ21 6 7 8 QNL R77 9 10 2 R78 11 10 2 R79 12 7 100R80 13 14 100 R81 15 16 50 R82 2 17 50R84 18 19 500 R85 20 21 50 R86 8 22 50 D21 23 16 DD D22 2 23 DD D23 24 0 DIN D24 25 0 DINI24 0 24 0.1E-3I25 0 25 0.1E-3E25 8 0 2 0 1E26 21 0 16 0 1 D25 26 0 DVN D26 27 0 DVNI26 0 26 0.1E-3I27 0 27 0.1E-3E27 28 29 26 27 3G13 30 31 24 25 2E-9E28 32 0 21 33 1E29 34 0 8 33 1E30 35 0 36 0 1R88 32 37 1E6R89 34 38 1E6R90 35 39 1E6 R91 0 37 100 R92 0 38 100 R93 0 39 100E31 40 41 39 0 2E-9R94 42 36 1E3R95 36 43 1E3C29 32 37 0.2E-12C30 34 38 0.2E-12C31 35 39 10E-12E32 44 40 38 0 -1.42E33 30 44 37 0 1.42E34 33 8 21 8 0.5 D27 45 21 DD D28 8 45 DD M24 46 47 17 17 NOUT L=3U W=30U!M25 48 49 15 15 POUT L=3U W=800U!M26 50 50 20 20 POUT L=3U W=800UM27 51 52 9 9 PIN L=3U W=25UM28 53 28 11 11 PIN L=3U W=25U M29 54 54 22 22 NOUT L=3U W=30UR96 55 49 100R97 56 47 100G14 45 33 57 33 0.02E-3R98 33 45 4.5E8C32 19 23 25E-12R99 8 51 2.6E3R100 8 53 2.6E3C33 51 53 1.2E-10C34 30 0 2E-12C35 28 0 2E-12 C36 23 0 1P D29 47 6 DD D30 58 49 DDQ22 58 13 21 QPL V27 30 52 0M30 59 60 61 61 NIN L=3U W=25U R101 62 61 2M31 63 28 64 64 NIN L=3U W=25U R102 62 64 2R103 59 21 2.6E3R104 63 21 2.6E3C37 59 63 1.2E-10 V28 52 60 5U!M32 65 66 67 67 PINT L=6U W=500U M33 68 69 21 21 PIN L=6U W=500UV29 21 66 1.37M34 62 65 8 8 NIN L=6U W=500UM35 65 65 8 8 NIN L=6U W=500UG15 45 33 70 33 0.02E-3I28 50 54 1E-6E35 43 0 30 0 1E36 42 0 31 0 1 M36 69 69 21 21 PIN L=6U W=500UI29 69 8 3.3E-7 V30 68 10 0R105 23 48 25R106 46 23 25J5 71 30 71 JCJ6 71 28 71 JCJ7 28 72 28 JCJ8 30 72 30 JCC38 30 28 0.2E-12E37 73 33 63 59 1R107 73 70 10E3C39 70 33 4E-11E38 74 33 53 51 1R108 74 57 10E3C40 57 33 4E-11 C41 3 75 1PR109 0 75 0.1G16 76 33 45 33 -1E-3G17 33 77 45 33 1E-3G18 33 78 54 8 1E-3G19 79 33 21 50 1E-3 D31 79 76 DD D32 77 78 DDR110 76 79 100E6R111 78 77 100E6R112 79 21 1E3R113 8 78 1E3E39 21 55 21 79 1E40 56 8 78 8 1R114 77 33 1E10R115 78 33 1E10R116 33 79 1E10R117 33 76 1E10R118 2 16 1E12G20 16 2 80 0 -3.7E-6 D33 81 0 DDV33 81 80 0.65R119 0 80 1E6I31 16 2 1.68E-6I32 30 0 1E-12I33 28 0 1E-12R120 67 68 80E3 V43 45 18 0I34 0 81 1E-3 R121 41 82 1V45 21 71 0.3 V46 72 8 0.3E42 16 14 16 15 10E43 12 2 17 2 10R169 45 23 2E10R326 8 31 15E6E44 82 8 83 8 0.5V48 85 8 1.8639R328 83 8 1E6 D34 86 87 DL V143 87 0 3R329 0 86 1E8G52 16 2 86 0 3.1E-7E48 29 31 88 0 2.05R330 88 0 4E7R331 88 0 4E7R332 1 89 1E6 C43 8 1 1E-6E49 89 8 5 8 1 R333 5 8 1E9 R334 1 8 1E9M38 16 90 4 4 PSD L=3U W=3000UE50 90 2 80 0 -0.69 R335 23 3 1R336 83 84 1E9R337 84 85 1E9R338 89 8 1E9*.MODEL PSD PMOS KP=200U VTO=-0.5 IS=1E-18'.MODEL DL D IS=0.95E-11 N=1.63 XTI=1.5.MODEL JC NJF IS=1E-18.MODEL DVN D KF=7E-14 IS=1E-16 .MODEL DIN D .MODEL DD D.MODEL DE D IS=3E-17.MODEL QPL PNP.MODEL QNL NPN".MODEL POUT PMOS KP=200U VTO=-0.7!.MODEL NOUT NMOS KP=200U VTO=0.7".MODEL PIN PMOS KP=200U VTO=-0.35!.MODEL NIN NMOS KP=200U VTO=0.35/.MODEL PINT PMOS KP=200U VTO=-0.35 LAMBDA=0.01.ENDS* END MODEL TMP2022345ÿ