Cadence (R) Virtuoso (R) Spectre (R) Circuit Simulator Version 15.1.0.801.isr17 64bit -- 19 Apr 2017 Copyright (C) 1989-2017 Cadence Design Systems, Inc. All rights reserved worldwide. Cadence, Virtuoso and Spectre are registered trademarks of Cadence Design Systems, Inc. All others are the property of their respective holders. Includes RSA BSAFE(R) Cryptographic or Security Protocol Software from RSA Security, Inc. User: yafimv Host: micron.eng.tau.ac.il HostID: 428454C2 PID: 13136 Memory available: 16.7587 GB physical: 33.6702 GB Linux : Red Hat Enterprise Linux Server release 6.9 (Santiago) CPU Type: Intel(R) Xeon(R) CPU E5420 @ 2.50GHz Socket: Processors [Frequency] 0: 0 [1998.0], 2 [1998.0], 4 [2499.0], 6 [1998.0] 1: 1 [1998.0], 3 [1998.0], 5 [1998.0], 7 [1998.0] System load averages (1min, 5min, 15min) : 0.2 %, 0.8 %, 0.1 % Simulating `input.scs' on micron.eng.tau.ac.il at 1:03:05 AM, Mon Feb 25, 2019 (process id: 13136). Current working directory: /data.cc/data/a/home/cc/students/enginer/yafimv/simulation/ex5_mixerr_3_33_interfer23/spectre/schematic/netlist Command line: /eda_disk/cadence/tools/MMSIM/151/tools/bin/spectre -64 input.scs \ +escchars +log ../psf/spectre.out +inter=mpsc \ +mpssession=spectre0_3361_6 -format psfxl -raw ../psf \ +lqtimeout 900 -maxw 5 -maxn 5 spectre pid = 13136 Loading /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/cmi/lib/64bit/5.0/libinfineon_sh.so ... Loading /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/cmi/lib/64bit/5.0/libphilips_o_sh.so ... Loading /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/cmi/lib/64bit/5.0/libphilips_sh.so ... Loading /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/cmi/lib/64bit/5.0/libsparam_sh.so ... Loading /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/cmi/lib/64bit/5.0/libstmodels_sh.so ... Reading file: /data.cc/data/a/home/cc/students/enginer/yafimv/simulation/ex5_mixerr_3_33_interfer23/spectre/schematic/netlist/input.scs Reading file: /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/spectre/etc/configs/spectre.cfg Reading file: /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/spectre/etc/configs/mapsubckt.cfg Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_25IO_NVT_V021.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_25IO_NVT_V021.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_25IO_V111.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_25IO_V111.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_NCAP25_V113.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_NCAP25_V113.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_varmis_25_rf_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_varmis_25_rf_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_33IO_GOX52_VT21.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_33IO_GOX52_VT21.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_25IO_RF_V021.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_25IO_RF_V021.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90-resistor-control-V041.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_res.va Reading link: /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/spectre/etc/ahdl/constants.h Reading file: /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/spectre/etc/ahdl/constants.vams Reading link: /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/spectre/etc/ahdl/discipline.h Reading file: /eda_disk/cadence/tools/MMSIM/151/tools.lnx86/spectre/etc/ahdl/disciplines.vams Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_ppo_V031.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_ppo_V031.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_npo_V031.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_npo_V031.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_rnhr_V031.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_rnhr_V031.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_rsnwell_V031.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_rsnwell_V031.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_nd_V031.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_nd_V031.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_pd_V031.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_pd_V031.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_metal_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_r_metal_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_BJT_V111.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_BJT_V111.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_DIODE_V101.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LL12_RF_V021.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LL12_RF_V021.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLLVT12_RF_VTAB.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLLVT12_RF_VTAB.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LL12_V102.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LL12_V102.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLHVT12_V101.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLHVT12_V101.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLLVT12_V102.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLLVT12_V102.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLNVT12_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_LLNVT12_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90SP_NCAP10_V112.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90SP_NCAP10_V112.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_NCAP12_LL_V102.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_NCAP12_LL_V102.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SP10_V061.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SP10_V061.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SPHVT10_V111.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SPHVT10_V111.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SPLVT10_V102.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SPLVT10_V102.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SPNVT10_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SPNVT10_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_mimcaps_20f_kf_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_mimcaps_20f_kf_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_momcaps_V041.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_momcaps_V041.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_vardiop_rf_v011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_vardiop_rf_v011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_varmis_12_llrf_V021.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_varmis_12_llrf_V021.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/momcaps_array_vp3_rfvcl_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/momcaps_array_vp3_rfvcl_V011.typ.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/momcaps_array_vp4_rfvcl_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/momcaps_array_vp4_rfvcl_V011.typ.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/rnhr_rf_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/rnhr_rf_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/res_poly.va Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/rnnpo_rf_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/rnnpo_rf_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/rnppo_rf_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/rnppo_rf_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_varmis_10_sprf_V011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_varmis_10_sprf_V011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/bond_pad_v011.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/bond_pad_v011.mdl.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SP10_RF_V021.lib.scs Reading file: /eda_disk/pdks/UMC/UMC90nm/Models/Spectre/L90_SP10_RF_V021.mdl.scs Time for NDB Parsing: CPU = 208.968 ms, elapsed = 372.757 ms. Time accumulated: CPU = 241.962 ms, elapsed = 372.768 ms. Peak resident memory used = 45.4 Mbytes. The CPU load for active processors is : Spectre 0 (52.6 %) 1 (5.4 %) 2 (7.9 %) 3 (2.6 %) 4 (33.3 %) 5 (5.6 %) 6 (10.5 %) 7 (5.6 %) Other Warning from spectre during circuit read-in. WARNING (SFE-2654): VerilogA module `respoly_va' override primitive/(verilogA module) `respoly_va'. WARNING (SFE-2654): VerilogA module `respoly_va' override primitive/(verilogA module) `respoly_va'. Warning from spectre during hierarchy flattening. WARNING (SFE-1131): Duplicate scope option `tnom' with scope `TopCircuit'. (using last value specified). Time for Elaboration: CPU = 55.992 ms, elapsed = 57.405 ms. Time accumulated: CPU = 297.954 ms, elapsed = 430.419 ms. Peak resident memory used = 53.6 Mbytes. Time for EDB Visiting: CPU = 1 ms, elapsed = 1.77312 ms. Time accumulated: CPU = 299.954 ms, elapsed = 432.579 ms. Peak resident memory used = 54.3 Mbytes. Notice from spectre during topology check. Only one connection to the following 2 nodes: LO LO_not No DC path from node `LO' to ground, Gmin installed to provide path. No DC path from node `LO_not' to ground, Gmin installed to provide path. Global user options: reltol = 0.001 vabstol = 1e-06 iabstol = 1e-12 temp = 27 gmin = 1e-12 rforce = 1 maxnotes = 5 maxwarns = 5 digits = 5 cols = 80 pivrel = 0.001 sensfile = ../psf/sens.output checklimitdest = psf save = allpub tnom = 25 tnom = 27 scalem = 1 scale = 1 Scoped user options: Circuit inventory: nodes 26 bsim4 6 capacitor 38 diode 2 inductor 6 resistor 17 vsource 4 Analysis and control statement inventory: hb 1 info 6 Output statements: .probe 0 .measure 0 save 0 Time for parsing: CPU = 3.999 ms, elapsed = 4.76098 ms. Time accumulated: CPU = 303.953 ms, elapsed = 437.536 ms. Peak resident memory used = 55.8 Mbytes. ~~~~~~~~~~~~~~~~~~~~~~ Pre-Simulation Summary ~~~~~~~~~~~~~~~~~~~~~~ ~~~~~~~~~~~~~~~~~~~~~~ Entering remote command mode using MPSC service (spectre, ipi, v0.0, spectre0_3361_6, ). Warning from spectre. WARNING (SPECTRE-16707): Only tran supports psfxl format, result of other analyses will be in psfbin format. Warning from spectre. WARNING (SPCRTRF-15267): The number of sources 0 is less than the number of funds 1 set in analysis.Please make sure the analysis is set up correctly. Fundamental 0 in fundfreqs: period = 303.03 ps, freq = 3.3 GHz, harms = 5, oversample = 1. Fundamental 1 in fundfreqs: period = 151.515 ps, freq = 6.6 GHz, harms = 5, oversample = 1. **************************************************************** Harmonic Balance Steady State Analysis `hb': largefund = 3.3 GHz **************************************************************** Use semi-autonomous solver Warning: Commensurate tone frequencies are detected. Although simulation result won't be affected, you might want to use incommensurate frequencies for convenience Trying `homotopy = gmin'. DC simulation time: CPU = 11.999 ms, elapsed = 12.1269 ms. Output and IC/nodeset summary: ic 1 Using linear IC Warning from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. WARNING (CMI-2682): M0: The bulk-drain junction forward bias voltage (4.83857 V) exceeds `VjdmFwd' = 951.351 mV. The results are now incorrect because the junction current model has been linearized WARNING (CMI-2682): M2: The bulk-drain junction forward bias voltage (4.72324 V) exceeds `VjdmFwd' = 951.351 mV. The results are now incorrect because the junction current model has been linearized WARNING (CMI-2377): M2: Vgd has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. Notice from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. M2: Device leaves the gate-drain oxide breakdown region. Warning from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. WARNING (CMI-2682): M0: The bulk-source junction forward bias voltage (1.12284 V) exceeds `VjsmFwd' = 932.242 mV. The results are now incorrect because the junction current model has been linearized WARNING (CMI-2682): M2: The bulk-source junction forward bias voltage (1.11078 V) exceeds `VjsmFwd' = 932.242 mV. The results are now incorrect because the junction current model has been linearized Notice from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. M0: The bulk-drain junction returns to normal bias condition M2: The bulk-drain junction returns to normal bias condition Warning from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. WARNING (CMI-2375): M_ver_n: Vgs has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. WARNING (CMI-2377): M_ver_n: Vgd has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. WARNING (CMI-2375): M_ver_p: Vgs has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. WARNING (CMI-2377): M_ver_p: Vgd has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. Notice from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. M0: The bulk-source junction returns to normal bias condition Warning from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. WARNING (CMI-2377): M0: Vgd has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. Notice from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. M2: The bulk-source junction returns to normal bias condition Warning from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. WARNING (CMI-2377): M2: Vgd has exceeded the oxide breakdown voltage of `vbox' = 8.85 V. Further occurrences of this warning will be suppressed. Notice from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. M_ver_n: Device leaves the gate-source oxide breakdown region. M_ver_n: Device leaves the gate-drain oxide breakdown region. M_ver_p: Device leaves the gate-source oxide breakdown region. M_ver_p: Device leaves the gate-drain oxide breakdown region. M0: Device leaves the gate-drain oxide breakdown region. M2: Device leaves the gate-drain oxide breakdown region. Further occurrences of this notice will be suppressed. Warning from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. WARNING (CMI-2682): M0: The bulk-drain junction forward bias voltage (2.10131 V) exceeds `VjdmFwd' = 951.351 mV. The results are now incorrect because the junction current model has been linearized Further occurrences of this warning will be suppressed. Notice from spectre at time = 1.51515 ps during periodic steady state analysis, during Harmonic Balance Steady State Analysis `hb'. M0: The bulk-drain junction returns to normal bias condition Further occurrences of this notice will be suppressed. Linear IC: estimated frequency is 2.86703e+09 Hz ================================ `hb': time = (0 s -> 15.1515 ns) ================================ Output and IC/nodeset summary: ic 1 Important parameter values in tstab integration: start = 0 s outputstart = 0 s stop = 15.1515 ns step = 15.1515 ps maxstep = 1.51515 ps ic = all useprevic = no skipdc = no reltol = 1e-03 abstol(V) = 1 uV abstol(I) = 1 pA temp = 27 C tnom = 27 C tempeffects = all method = traponly lteratio = 10 relref = sigglobal cmin = 0 F gmin = 1 pS hb: time = 379.7 ps (2.51 %), step = 1.515 ps (10 m%) hb: time = 1.137 ns (7.51 %), step = 1.515 ps (10 m%) hb: time = 1.895 ns (12.5 %), step = 1.515 ps (10 m%) hb: time = 2.652 ns (17.5 %), step = 1.515 ps (10 m%) hb: time = 3.41 ns (22.5 %), step = 1.515 ps (10 m%) hb: time = 4.168 ns (27.5 %), step = 1.515 ps (10 m%) hb: time = 4.925 ns (32.5 %), step = 1.515 ps (10 m%) hb: time = 5.683 ns (37.5 %), step = 1.515 ps (10 m%) 99% of the nodes have reached steady-state after 6.06154 ns. hb: time = 6.44 ns (42.5 %), step = 1.212 ps (8 m%) hb: time = 7.197 ns (47.5 %), step = 1.212 ps (8 m%) The Estimated oscillating frequency from Tstab Tran is = 3.2597 GHz . ======================================= `hb': time = (7.27366 ns -> 7.58044 ns) ======================================= Output and IC/nodeset summary: ic 1 hb: time = 7.282 ns (2.84 %), step = 1.515 ps (494 m%) hb: time = 7.298 ns (7.78 %), step = 1.515 ps (494 m%) hb: time = 7.313 ns (12.7 %), step = 1.515 ps (494 m%) hb: time = 7.328 ns (17.7 %), step = 1.515 ps (494 m%) hb: time = 7.343 ns (22.6 %), step = 1.515 ps (494 m%) hb: time = 7.358 ns (27.5 %), step = 1.515 ps (494 m%) hb: time = 7.375 ns (33 %), step = 1.515 ps (494 m%) hb: time = 7.39 ns (37.9 %), step = 1.515 ps (494 m%) hb: time = 7.405 ns (42.8 %), step = 1.515 ps (494 m%) hb: time = 7.42 ns (47.8 %), step = 1.515 ps (494 m%) hb: time = 7.435 ns (52.7 %), step = 1.515 ps (494 m%) hb: time = 7.451 ns (57.7 %), step = 1.515 ps (494 m%) hb: time = 7.466 ns (62.6 %), step = 1.515 ps (494 m%) hb: time = 7.481 ns (67.5 %), step = 1.515 ps (494 m%) hb: time = 7.498 ns (73 %), step = 1.515 ps (494 m%) hb: time = 7.513 ns (77.9 %), step = 1.515 ps (494 m%) hb: time = 7.528 ns (82.9 %), step = 1.515 ps (494 m%) hb: time = 7.543 ns (87.8 %), step = 1.515 ps (494 m%) hb: time = 7.558 ns (92.7 %), step = 1.515 ps (494 m%) hb: time = 7.573 ns (97.7 %), step = 1.515 ps (494 m%) Notice from spectre during Harmonic Balance Steady State Analysis `hb'. Auto harmonic calculation has chosen 5 harmonics for tone-1. Warning: Commensurate tone frequencies are detected. Although simulation result won't be affected, you might want to use incommensurate frequencies for convenience Pin node is 56, amplitude is 0.212674 Pinning node: 56, harm: 1, name: M4:int_d, value: (-0.194879, -0.085161) ============================== Harmonic balance hbhomotopy=tone (1-tone) ============================== Important HB parameters: RelTol=1.00e-05 abstol(I)=1.00e-12 A abstol(V)=1.00e-06 V residualtol=1.00e+00 lteratio=1.00e+01 steadyratio=1.00e+00 maxperiods=100 ********** initial residual ********** Resd Norm=2.64e+03 at node M4:int_g harm=(5 0) ********** iter = 1 ********** Delta Norm=4.48e+01 at node LO harm=(0 0) Resd Norm=1.18e+03 at node M4:int_g harm=(4 0) Frequency= 3.2597e+09 Hz, delta f= 0.00e+00 ********** iter = 2 ********** Delta Norm=6.64e+00 at node V3:p harm=(4 0) Resd Norm=7.07e+02 at node M4:int_g harm=(4 0) Frequency= 3.2597e+09 Hz, delta f= -2.63e+04 ********** iter = 3 ********** Delta Norm=6.06e+00 at node V3:p harm=(4 0) Resd Norm=3.09e+02 at node M3:int_g harm=(5 0) Frequency= 3.2597e+09 Hz, delta f= -1.01e+04 ********** iter = 4 ********** Delta Norm=2.99e+00 at node V2:p harm=(2 0) Resd Norm=1.88e+02 at node M3:int_g harm=(4 0) Frequency= 3.2597e+09 Hz, delta f= 8.17e+04 ********** iter = 5 ********** Delta Norm=2.08e+00 at node V3:p harm=(2 0) Resd Norm=1.33e+02 at node M3:int_g harm=(4 0) Frequency= 3.2600e+09 Hz, delta f= 2.30e+05 ********** iter = 6 ********** Delta Norm=3.40e+00 at node V2:p harm=(2 0) Resd Norm=8.16e+00 at node M3:int_g harm=(4 0) Frequency= 3.2599e+09 Hz, delta f= -1.20e+05 ********** iter = 7 ********** Delta Norm=1.63e-01 at node V3:p harm=(4 0) Resd Norm=5.00e-01 at node M3:int_g harm=(2 0) Frequency= 3.2599e+09 Hz, delta f= 2.19e+03 Pinning node: 56, harm: 1, name: M4:int_d, value: (-0.194942, -0.085161) ============================== Harmonic balance hbhomotopy=tone (all-tone) ============================== Important HB parameters: RelTol=1.00e-05 abstol(I)=1.00e-12 A abstol(V)=1.00e-06 V residualtol=1.00e+00 lteratio=1.00e+01 steadyratio=1.00e+00 maxperiods=100 ********** initial residual ********** Resd Norm=5.00e-01 at node M3:int_g harm=(2 0) ********** iter = 1 ********** Delta Norm=7.91e-03 at node V3:p harm=(4 0) Resd Norm=3.61e-01 at node M3:int_g harm=(2 0) Frequency= 3.2599e+09 Hz, delta f= -1.52e+01 ************************************************* Fundamental frequency is 3.25985 GHz. ************************************************* CPU time=0 s Opening the PSF file ../psf/hb.fd.qpss_hb ... Opening the PSF file ../psf/hb.fi.qpss_hb ... Total time required for hb analysis `hb': CPU = 979.851 ms, elapsed = 993.78 ms. Time accumulated: CPU = 1.2858 s, elapsed = 1.98361 s. Peak resident memory used = 63.2 Mbytes. Notice from spectre. 43 notices suppressed. 43 warnings suppressed. modelParameter: writing model parameter values to rawfile. Opening the PSF file ../psf/modelParameter.info ... element: writing instance parameter values to rawfile. Opening the PSF file ../psf/element.info ... outputParameter: writing output parameter values to rawfile. Opening the PSF file ../psf/outputParameter.info ... designParamVals: writing netlist parameters to rawfile. Opening the PSFASCII file ../psf/designParamVals.info ... primitives: writing primitives to rawfile. Opening the PSFASCII file ../psf/primitives.info.primitives ... subckts: writing subcircuits to rawfile. Opening the PSFASCII file ../psf/subckts.info.subckts ...