xschem/ldo_v2.spice - third_party/shuttle/sky130/mpw-003/slot-002 - Git at Google

 **.subckt ldo_v2
 XM8 net2 net2 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=1.2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XM9 net2 bg_out net3 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=2 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM10 net1 pos net3 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=2 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM11 net1 net2 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=1.2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XM13 net3 vb GND GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=1 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM14 out net1 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=1.2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=12 m=12
 XM18 out vb GND GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=1 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=12 m=12
 XM20 vb vb GND GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=1 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XM24 ldo_out net5 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=0.5 W=10 nf=1 ad='int((nf+1)/2) * W/nf * 0.29'
 + as='int((nf+2)/2) * W/nf * 0.29' pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)'
 + nrd='0.29 / W' nrs='0.29 / W' sa=0 sb=0 sd=0 mult=800 m=800
 XM26 vb mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XC3 net1 net4 sky130_fd_pr__cap_mim_m3_1 W=60 L=60 MF=1 m=1
 XR7 out net4 GND sky130_fd_pr__res_xhigh_po_0p69 L=4.5 mult=1 m=1
 Vs VDD GND 2.3
 Vt net6 GND 0
 C2 net5 net6 5G m=1
 L1 out net5 5G m=1
 XR8 net7 ldo_out GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=8 m=8
 XR9 pos net7 GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=3 m=3
 XR12 net8 pos GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=2 m=2
 XR13 GND net8 GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=4 m=4
 XM1 inn mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM2 inp mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM3 bg_out mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XQ1 GND GND net10 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ5 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ6 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ7 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ9 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ11 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ13 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ15 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XQ17 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
 XM7 net12 net12 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XM12 net12 inp net11 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM21 mir inn net11 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM23 mir net12 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XM15 net11 net13 GND GND sky130_fd_pr__nfet_g5v0d10v5 L=2 W=5 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XM25 net13 mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=8 m=8
 XM16 net13 net13 GND GND sky130_fd_pr__nfet_g5v0d10v5 L=2 W=5 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 XC1 mir GND sky130_fd_pr__cap_mim_m3_1 W=16 L=16 MF=1 m=1
 XR1 net14 inp GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=3 m=3
 XR2 net10 inn GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=3 m=3
 XR3 net16 net10 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=1 m=1
 XR10 net9 net14 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=6 m=6
 XR4 GND net15 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=15 m=15
 XR11 GND net16 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=15 m=15
 XR6 net15 net14 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=1 m=1
 XR5 net17 bg_out GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=1 m=1
 XR14 GND net17 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=53 m=53
 XM19 mir en VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=0.5 W=0.42 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=2 m=2
 Ven en GND 2.3
 XM4 net18 bg_out VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=5 W=0.42 nf=1 ad='int((nf+1)/2) * W/nf * 0.29'
 + as='int((nf+2)/2) * W/nf * 0.29' pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)'
 + nrd='0.29 / W' nrs='0.29 / W' sa=0 sb=0 sd=0 mult=2 m=2
 XM5 net18 bg_out GND GND sky130_fd_pr__nfet_g5v0d10v5 L=0.5 W=10 nf=1 ad='int((nf+1)/2) * W/nf * 0.29'
 + as='int((nf+2)/2) * W/nf * 0.29' pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)'
 + nrd='0.29 / W' nrs='0.29 / W' sa=0 sb=0 sd=0 mult=8 m=8
 XM6 VDD net18 inn GND sky130_fd_pr__nfet_g5v0d10v5 L=0.5 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
 + pd='2*int((nf+1)/2) * (W/nf + 0.29)' ps='2*int((nf+2)/2) * (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
 + sa=0 sb=0 sd=0 mult=4 m=4
 **** begin user architecture code


 .param R=18k
 R10 ldo_out GND {R}
 IL ldo_out 0 PWL(0 0.1m 10u 0.1m 20u 10m 30u 10m)
 *CL ldo_out gnd 10p
 .lib /home/mustafa/mabrains/pdks/share/pdk/sky130A/libs.tech/ngspice/sky130.lib_mod.spice tt


 .nodeset v(inn)=1.2
 .nodeset v(inp)=1.2
 .nodeset v(mir)=1
 .nodeset v(net13)=1
 .nodeset v(bg_out)=1.1
 .nodeset v(ldo_out)=1.8
 .nodeset v(pos)=1.1
 *.nodeset v(net3)=0.8
 *.nodeset v(net1)=0.7
 .nodeset v(net14)=0.9
 *.nodeset v(net7)=0.75
 .nodeset v(vb)=0.9

 .option temp=27
 *User_defined_functions
 .control
 define max(vector_name) (vecmax(vector_name))
 define min(vector_name) (vecmin(vector_name))
 .endc


 *Temp_sweep
 .control
 alter IL 0
 dc temp 85 0 -1
 let temp_coeff=1000000*(max(ldo_out)-min(ldo_out))/85
 print temp_coeff
 plot v(ldo_out)
 set wr_singlescale
 set wr_vecnames
 set appendwrite
 .endc


 .control
 alter IL 0
 *alter R10 1G
 op
 let iq =i(Vs)
 print iq
 *print all
 set wr_singlescale
 set wr_vecnames
 set appendwrite
 if v(ldo_out)>1
 wrdata op_point_test v(ldo_out)
 end
 .endc


 *Stability_Analysis
 .control
 alter IL 0
 alter Vs AC =0
 alter Vt AC=1
 ac dec 10 1 1G
 plot vdb(out)
 plot (180/pi)*vp(out)
 let ph= (180/pi)*vp(out)
 meas ac pm FIND ph WHEN vdb(out)=0
 .endc


 *PSRR_Analysis
 .control
 alter IL 0
 alter Vs AC =1
 alter Vt AC=0
 alter L1 0
 alter C2 0
 ac dec 10 1 1G
 meas AC PSRR100 FIND vdb(ldo_out) AT=100
 meas AC PSRR100k FIND vdb(ldo_out) AT=100k
 plot vdb(ldo_out)
 .endc


 *supply_sweep
 .control
 alter IL 0
 dc Vs 2.8 0 -0.01
 plot vdd ldo_out
 meas DC Vldo_Sup_2 FIND ldo_out AT=2
 meas DC Vldo_nom FIND ldo_out AT=2.3
 meas DC Vldo_Sup_2_8 FIND ldo_out AT=2.8
 let line_reg = abs((Vldo_Sup_2_8-Vldo_Sup_2)/0.8)
 print line_reg
 meas DC vin WHEN v(ldo_out)=1.764
 let dropout=vin-1.764
 print dropout
 set wr_singlescale
 set wr_vecnames
 set appendwrite
 .endc


 *Load_Reg_switches
 *V1 c1 0 DC 0 PWL(0 5 20u 5 35u 0 50u 0 100u 0)
 *V2 c2 0 DC 0 PWL(0 0 20u 0 35u 0 50u 5 100u 5)
 *s1 ldo_out 2 c1 0 switch1 ON
 *s2 ldo_out 3 c2 0 switch1 OFF
 *.model switch1 sw vt=0.1 ron =0.1 roff =1G
 *R1 2 0 18k
 *R2 3 0 180

 *.control
 *alter R10 1G
 *tran 0.1u 90u
 *plot v(ldo_out) v(c1) v(c2)
 *meas TRAN V_ldo_100u FIND v(ldo_out) AT=10u
 *meas TRAN V_ldo_10m FIND v(ldo_out) AT=50u
 *let load_reg= V_ldo_100u-V_ldo_10m
 *print load_reg
 *.endc


 **Load_Transient
 .control
 alter IL 50u
 alter R10 3600k
 tran 0.1u 100u
 meas TRAN V_ldo_100u FIND v(ldo_out) AT=5u
 meas TRAN V_ldo_10m FIND v(ldo_out) AT=100u
 let load_reg= V_ldo_100u-V_ldo_10m
 let load_current =(-1*i(Vs)-131.8e-6)
 print load_reg
 plot load_current v(ldo_out)-1.8
 .endc


 **Transient
 .control
 alter R10 36k
 alter @IL[PWL] = [ 0 0 10u 0 20u 0 30u 0 ]
 alter @Vs[pulse] = [ 1 3 10u 10u 1u 100u 200u ]
 alter IL 0
 tran 0.1u 100u
 plot vdd ldo_out
 .endc

 .control
 alter R10 36k
 alter @IL[PWL] = [ 0 0 10u 0 20u 0 30u 0 ]
 alter @Vs[pulse] = [ 0 2.3 10u 0.1u 1u 100u 200u ]
 tran 0.1u 100u
 plot vdd ldo_out
 .endc

 .control
 alter R10 36k
 alter @IL[PWL] = [ 0 0 10u 0 20u 0 30u 0 ]
 alter @Ven[pulse] = [ 0 2.3 10u 0.1u 1u 100u 200u ]
 tran 0.1u 100u
 *meas TRAN st_up_time when v(ldo_out)>1.782
 plot en ldo_out
 .endc


 **** end user architecture code
 **.ends
 .GLOBAL GND
 .GLOBAL VDD
 ** flattened .save nodes
 .end
	**.subckt ldo_v2
	XM8 net2 net2 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=1.2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XM9 net2 bg_out net3 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=2 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM10 net1 pos net3 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=2 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM11 net1 net2 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=1.2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XM13 net3 vb GND GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=1 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM14 out net1 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=1.2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=12 m=12
	XM18 out vb GND GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=1 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=12 m=12
	XM20 vb vb GND GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=1 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XM24 ldo_out net5 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=0.5 W=10 nf=1 ad='int((nf+1)/2) * W/nf * 0.29'
	+ as='int((nf+2)/2) * W/nf * 0.29' pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)'
	+ nrd='0.29 / W' nrs='0.29 / W' sa=0 sb=0 sd=0 mult=800 m=800
	XM26 vb mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XC3 net1 net4 sky130_fd_pr__cap_mim_m3_1 W=60 L=60 MF=1 m=1
	XR7 out net4 GND sky130_fd_pr__res_xhigh_po_0p69 L=4.5 mult=1 m=1
	Vs VDD GND 2.3
	Vt net6 GND 0
	C2 net5 net6 5G m=1
	L1 out net5 5G m=1
	XR8 net7 ldo_out GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=8 m=8
	XR9 pos net7 GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=3 m=3
	XR12 net8 pos GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=2 m=2
	XR13 GND net8 GND sky130_fd_pr__res_xhigh_po_0p69 L=24 mult=4 m=4
	XM1 inn mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM2 inp mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM3 bg_out mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XQ1 GND GND net10 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ5 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ6 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ7 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ9 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ11 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ13 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ15 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XQ17 GND GND net9 sky130_fd_pr__pnp_05v5_W0p68L0p68
	XM7 net12 net12 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XM12 net12 inp net11 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM21 mir inn net11 GND sky130_fd_pr__nfet_g5v0d10v5 L=1 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM23 mir net12 VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XM15 net11 net13 GND GND sky130_fd_pr__nfet_g5v0d10v5 L=2 W=5 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XM25 net13 mir VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=2 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=8 m=8
	XM16 net13 net13 GND GND sky130_fd_pr__nfet_g5v0d10v5 L=2 W=5 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	XC1 mir GND sky130_fd_pr__cap_mim_m3_1 W=16 L=16 MF=1 m=1
	XR1 net14 inp GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=3 m=3
	XR2 net10 inn GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=3 m=3
	XR3 net16 net10 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=1 m=1
	XR10 net9 net14 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=6 m=6
	XR4 GND net15 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=15 m=15
	XR11 GND net16 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=15 m=15
	XR6 net15 net14 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=1 m=1
	XR5 net17 bg_out GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=1 m=1
	XR14 GND net17 GND sky130_fd_pr__res_xhigh_po_0p69 L=27 mult=53 m=53
	XM19 mir en VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=0.5 W=0.42 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=2 m=2
	Ven en GND 2.3
	XM4 net18 bg_out VDD VDD sky130_fd_pr__pfet_g5v0d10v5 L=5 W=0.42 nf=1 ad='int((nf+1)/2) * W/nf * 0.29'
	+ as='int((nf+2)/2) * W/nf * 0.29' pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)'
	+ nrd='0.29 / W' nrs='0.29 / W' sa=0 sb=0 sd=0 mult=2 m=2
	XM5 net18 bg_out GND GND sky130_fd_pr__nfet_g5v0d10v5 L=0.5 W=10 nf=1 ad='int((nf+1)/2) * W/nf * 0.29'
	+ as='int((nf+2)/2) * W/nf * 0.29' pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)'
	+ nrd='0.29 / W' nrs='0.29 / W' sa=0 sb=0 sd=0 mult=8 m=8
	XM6 VDD net18 inn GND sky130_fd_pr__nfet_g5v0d10v5 L=0.5 W=3 nf=1 ad='int((nf+1)/2) * W/nf * 0.29' as='int((nf+2)/2) * W/nf * 0.29'
	+ pd='2int((nf+1)/2) (W/nf + 0.29)' ps='2int((nf+2)/2) (W/nf + 0.29)' nrd='0.29 / W' nrs='0.29 / W'
	+ sa=0 sb=0 sd=0 mult=4 m=4
	**** begin user architecture code


	.param R=18k
	R10 ldo_out GND {R}
	IL ldo_out 0 PWL(0 0.1m 10u 0.1m 20u 10m 30u 10m)
	*CL ldo_out gnd 10p
	.lib /home/mustafa/mabrains/pdks/share/pdk/sky130A/libs.tech/ngspice/sky130.lib_mod.spice tt




	.nodeset v(inn)=1.2
	.nodeset v(inp)=1.2
	.nodeset v(mir)=1
	.nodeset v(net13)=1
	.nodeset v(bg_out)=1.1
	.nodeset v(ldo_out)=1.8
	.nodeset v(pos)=1.1
	*.nodeset v(net3)=0.8
	*.nodeset v(net1)=0.7
	.nodeset v(net14)=0.9
	*.nodeset v(net7)=0.75
	.nodeset v(vb)=0.9

	.option temp=27
	*User_defined_functions
	.control
	define max(vector_name) (vecmax(vector_name))
	define min(vector_name) (vecmin(vector_name))
	.endc


	*Temp_sweep
	.control
	alter IL 0
	dc temp 85 0 -1
	let temp_coeff=1000000*(max(ldo_out)-min(ldo_out))/85
	print temp_coeff
	plot v(ldo_out)
	set wr_singlescale
	set wr_vecnames
	set appendwrite
	.endc


	.control
	alter IL 0
	*alter R10 1G
	op
	let iq =i(Vs)
	print iq
	*print all
	set wr_singlescale
	set wr_vecnames
	set appendwrite
	if v(ldo_out)>1
	wrdata op_point_test v(ldo_out)
	end
	.endc



	*Stability_Analysis
	.control
	alter IL 0
	alter Vs AC =0
	alter Vt AC=1
	ac dec 10 1 1G
	plot vdb(out)
	plot (180/pi)*vp(out)
	let ph= (180/pi)*vp(out)
	meas ac pm FIND ph WHEN vdb(out)=0
	.endc


	*PSRR_Analysis
	.control
	alter IL 0
	alter Vs AC =1
	alter Vt AC=0
	alter L1 0
	alter C2 0
	ac dec 10 1 1G
	meas AC PSRR100 FIND vdb(ldo_out) AT=100
	meas AC PSRR100k FIND vdb(ldo_out) AT=100k
	plot vdb(ldo_out)
	.endc




	*supply_sweep
	.control
	alter IL 0
	dc Vs 2.8 0 -0.01
	plot vdd ldo_out
	meas DC Vldo_Sup_2 FIND ldo_out AT=2
	meas DC Vldo_nom FIND ldo_out AT=2.3
	meas DC Vldo_Sup_2_8 FIND ldo_out AT=2.8
	let line_reg = abs((Vldo_Sup_2_8-Vldo_Sup_2)/0.8)
	print line_reg
	meas DC vin WHEN v(ldo_out)=1.764
	let dropout=vin-1.764
	print dropout
	set wr_singlescale
	set wr_vecnames
	set appendwrite
	.endc





	*Load_Reg_switches
	*V1 c1 0 DC 0 PWL(0 5 20u 5 35u 0 50u 0 100u 0)
	*V2 c2 0 DC 0 PWL(0 0 20u 0 35u 0 50u 5 100u 5)
	*s1 ldo_out 2 c1 0 switch1 ON
	*s2 ldo_out 3 c2 0 switch1 OFF
	*.model switch1 sw vt=0.1 ron =0.1 roff =1G
	*R1 2 0 18k
	*R2 3 0 180

	*.control
	*alter R10 1G
	*tran 0.1u 90u
	*plot v(ldo_out) v(c1) v(c2)
	*meas TRAN V_ldo_100u FIND v(ldo_out) AT=10u
	*meas TRAN V_ldo_10m FIND v(ldo_out) AT=50u
	*let load_reg= V_ldo_100u-V_ldo_10m
	*print load_reg
	*.endc


	**Load_Transient
	.control
	alter IL 50u
	alter R10 3600k
	tran 0.1u 100u
	meas TRAN V_ldo_100u FIND v(ldo_out) AT=5u
	meas TRAN V_ldo_10m FIND v(ldo_out) AT=100u
	let load_reg= V_ldo_100u-V_ldo_10m
	let load_current =(-1*i(Vs)-131.8e-6)
	print load_reg
	plot load_current v(ldo_out)-1.8
	.endc


	**Transient
	.control
	alter R10 36k
	alter @IL[PWL] = [ 0 0 10u 0 20u 0 30u 0 ]
	alter @Vs[pulse] = [ 1 3 10u 10u 1u 100u 200u ]
	alter IL 0
	tran 0.1u 100u
	plot vdd ldo_out
	.endc

	.control
	alter R10 36k
	alter @IL[PWL] = [ 0 0 10u 0 20u 0 30u 0 ]
	alter @Vs[pulse] = [ 0 2.3 10u 0.1u 1u 100u 200u ]
	tran 0.1u 100u
	plot vdd ldo_out
	.endc

	.control
	alter R10 36k
	alter @IL[PWL] = [ 0 0 10u 0 20u 0 30u 0 ]
	alter @Ven[pulse] = [ 0 2.3 10u 0.1u 1u 100u 200u ]
	tran 0.1u 100u
	*meas TRAN st_up_time when v(ldo_out)>1.782
	plot en ldo_out
	.endc





	**** end user architecture code
	**.ends
	.GLOBAL GND
	.GLOBAL VDD
	** flattened .save nodes
	.end