* DIODES INCORPORATED AND ITS AFFILIATED COMPANIES AND SUBSIDIARIES (COLLECTIVELY, "DIODES") 
* PROVIDE THESE SPICE MODELS AND DATA (COLLECTIVELY, THE "SM DATA") "AS IS" AND WITHOUT ANY 
* REPRESENTATIONS OR WARRANTIES, EXPRESS OR IMPLIED, INCLUDING ANY WARRANTY OF MERCHANTABILITY 
* OR FITNESS FOR A PARTICULAR PURPOSE, ANY WARRANTY ARISING FROM COURSE OF DEALING OR COURSE OF 
* PERFORMANCE, OR ANY WARRANTY THAT ACCESS TO OR OPERATION OF THE SM DATA WILL BE UNINTERRUPTED, 
* OR THAT THE SM DATA OR ANY SIMULATION USING THE SM DATA WILL BE ERROR FREE. TO THE MAXIMUM 
* EXTENT PERMITTED BY LAW, IN NO EVENT WILL DIODES BE LIABLE FOR ANY DIRECT OR INDIRECT, 
* SPECIAL, INCIDENTAL, PUNITIVE OR CONSEQUENTIAL DAMAGES ARISING OUT OF OR IN CONNECTION WITH 
* THE PRODUCTION OR USE OF SM DATA, HOWEVER CAUSED AND UNDER WHATEVER CAUSE OF ACTION OR THEORY 
* OF LIABILITY BROUGHT (INCLUDING, WITHOUT LIMITATION, UNDER ANY CONTRACT, NEGLIGENCE OR OTHER 
* TORT THEORY OF LIABILITY), EVEN IF DIODES HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES, 
* AND DIODES' TOTAL LIABILITY (WHETHER IN CONTRACT, TORT OR OTHERWISE) WITH REGARD TO THE SM 
* DATA WILL NOT, IN THE AGGREGATE, EXCEED ANY SUMS PAID BY YOU TO DIODES FOR THE SM DATA.


.subckt AS431 ANODE CATHODE REFIN
Q8 Q2_C Q2_C R4_N 0 P1
Q9 CATHODE Q7_C Q9_E 0 n1
R8 Q4_E ANODE 800
R9 Q2_E R9_N 1k
Q10 CATHODE R6_P ANODE 0 n1 5
Q11 Q7_C R10_P ANODE 0 n1
.nodeset R3_N 1
C2 Q2_E C2_N 2p
C3 R9_N R10_P 2p
R10 R10_P R1_N 1k
C1 CATHODE Q7_C 40p
D1 ANODE Q7_C DIODE
D2 ANODE CATHODE DIODE
R4 CATHODE R4_N 800
Q2 Q2_C Q1_E Q2_E 0 n1
Q3 R9_N C2_N ANODE 0 n1
R5 CATHODE R5_N 800
R6 R6_P Q9_E 150
Q1 CATHODE REFIN Q1_E 0 n1
R7 ANODE R6_P 10k
Q6 Q7_C Q7_C REFIN 0 n1
Q7 Q7_C Q2_C R5_N 0 P1
R1 R3_N R1_N 2.4k
R2 R3_N C2_N 7.2k
Q4 C2_N R1_N Q4_E 0 n1
Q5 R1_N R1_N ANODE 0 n1
R3 Q1_E R3_N 3.22k
.model p1 pnp bf=50
.model n1 npn bf=100 tf=2n cjc=1p is=5e-18 NF=1.07
.model diode d rs=1 cjo=2p
.ends


.subckt AZ431A ANODE CATHODE REF
Q10 Cathode Q10_B Q10_E  0 n1
Q3 Q3_C Q3_B Q3_E  0 n1
Q11 Cathode Q11_B Anode  0 n1 
Q1 Cathode REF Q3_B  0 n1 
Q8 Q3_C Q3_C Q8_E  0 p1 
Q9 Q10_B Q3_C Q9_E  0 p1 
C1 Cathode Q10_B  14p
C2 Q6_C Q6_B    13p
Q5 Q5_C Q5_C Anode  0 n1
Q4 Q6_B Q5_C Q4_E   0 n1
Q7 Q10_B Q7_B Anode  0 n1
Q6 Q6_C Q6_B Anode   0 n1
Q2 Q10_B Q10_B REF   0 n1 
R7 Q3_E Q6_C 4.1K
R6 Q5_C Q7_B 1.29K 
R5 Q4_E Anode 0.936K 
R28 R1_N Q6_B 7.488K 
R4 R1_N Q5_C 2.808K
R1 Q3_B R1_N 5.4K 
R9 Cathode Q9_E 1.01K
R8 Cathode Q8_E 1.01K
R10 Q10_E Q11_B 263.8
R11 Q11_B Anode 8.9K
.model p1 pnp bf=50
.model n1 npn bf=100 tf=2n cjc=1p is=5e-18 NF=1.07
*.model diode d rs=1 cjo=2p
.ends


*ZETEX ZHT431 Spice Model v1.0 Last Revised 22/7/2005
    *              
    *NOTE: This is a simplified Model.  Do not rely on this Model for 
    *validation of circuit stability.  It does not accurately replicate 
    *stability boundary conditions with additional load capacitance.  
    *Check stability by normal breadboarding techniques.
    *
    .SUBCKT ZHT431 1 2 3
    *Connections  Vz Vref Gnd
    *Input current
    L2 2 12 2E-9
    Rin 12 13 Rmod1 20E6
    Cin 12 13 1E-12
    D1 13 12 Dmod
    D2 12 11 Dmod
    *Reference voltage, Voltage dependence
    Iref 13 21 2.4985E-3
    Rref 21 13 Rmod2 1000
    G1 21 13 11 13 1.43E-6
    *Gain, time constant  and  clamp voltage
    G2 13 31 12 21 0.004
    Rt1 31 13 1E8
    Ct1 31 32  800E-12
    Rt2 32 13 2000
    Ct2 31 33  50E-12
    Rt3 33 13 5
    D3 31 13 Dmod
    D4 13 31 Dmod
    *Buffer,Output
    G3 13 41 13 31 0.22
    L1 1 11 2E-9
    Rz 11 42 10
    D5 42 41 Dmod
    D6 13 41 Dmod
    D7 13 11 Dmod
    Rx 13 23 0.5
    L3 3 23 2E-9
    Rq 11 13  Rmod3 74E3
    *
    .MODEL Rmod1 RES (TC1=2.95E-3 TC2=-5E-7)
    .MODEL Rmod2 RES (TC1=8.5E-6 TC2=-3.3E-7)
    .MODEL Rmod3 RES (TC1=-2.5E-3 TC2=2E-5)
    .MODEL Dmod D IS=1E-14 RS=0.1 BV=22 CJO=0.1E-12
    .ENDS  ZHT431
    *
    *$
    *


*ZETEX ZR431 Spice Model v1.0 Last Revised 31/3/2005
    *              
    *NOTE: This is a simplified Model.  Do not rely on this Model for 
    *validation of circuit stability.  It does not accurately replicate 
    *stability boundary conditions with additional load capacitance.  
    *Check stability by normal breadboarding techniques.
    *
    .SUBCKT ZR431 1 2 3
    *Connections  Vz Vref Gnd
    *Input current
    L2 2 12 2E-9
    Rin 12 13 Rmod1 20E6
    Cin 12 13 1E-12
    D1 13 12 Dmod
    D2 12 11 Dmod
    *Reference voltage, Voltage dependence
    Iref 13 21 2.4985E-3
    Rref 21 13 Rmod2 1000
    G1 21 13 11 13 1.43E-6
    *Gain, time constant  and  clamp voltage
    G2 13 31 12 21 0.004
    Rt1 31 13 1E8
    Ct1 31 32  800E-12
    Rt2 32 13 2000
    Ct2 31 33  50E-12
    Rt3 33 13 5
    D3 31 13 Dmod
    D4 13 31 Dmod
    *Buffer,Output
    G3 13 41 13 31 0.22
    L1 1 11 2E-9
    Rz 11 42 10
    D5 42 41 Dmod
    D6 13 41 Dmod
    D7 13 11 Dmod
    Rx 13 23 0.5
    L3 3 23 2E-9
    Rq 11 13  Rmod3 74E3
    *
    .MODEL Rmod1 RES (TC1=2.95E-3 TC2=-5E-7)
    .MODEL Rmod2 RES (TC1=8.5E-6 TC2=-3.3E-7)
    .MODEL Rmod3 RES (TC1=-2.5E-3 TC2=2E-5)
    .MODEL Dmod D IS=1E-14 RS=0.1 BV=22 CJO=0.1E-12
    .ENDS  ZR431
    *
    *$
    *