Back Annotation

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Revision as of 21:54, 1 October 2009 by Mrg (Talk | contribs) (Back-Annotated Simulation)

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The above simulation did not actually include the parasitic capacitances and resistances of the interconnect. Spectre (or hSpice) will by default use the gate area (L and W) to estimate the gate capacitance, but additional poly is not considered. If you specified perimeters (ps, pd) and areas (as, ad) in the pcell form, it will include those estimates in simulation. However, it does not include any extra routing, contacts, diffusion, etc. In order to include these, you need to perform parasitic extraction and back-annotation. The extraction is similar to the device extraction you used to extract a netlist for LVS, but now it extracts parasitic resistances and capacitances too.

Your design must pass DRC and LVS to do this.

Extract Parasitics

This is very similar to LVS. Go to Calibre->Run PEX. You will need to specify a layer map like LVS again. Also, select the rule file as this:

/mada/software/techfiles/FreePDK45/ncsu_basekit/techfile/calibrexRC.rul

Under the Input section, in the Layout tab, make sure that GDSII and "Export from layout viewer" are selected. Under the Netlist tab, make sure that SPICE and "Export from schematic viewer" are selected.

Under the Output section, most options should be left as default. Under Netlist, we want SPECTRE format and names from the SCHEMATIC. By default, "All Nets" under the Nets tab should be checked. Under the Report tab, select "Generate PEX report" and "View report after PEX finishes". Under SVDB, make sure that "Start RVE after PEX" is checked.

After this, there are a few files that were created

  • The .pex file ("invx1.pex.netlist.pex") contains all of the parasitics in a hierarchical format:
// File: invx1.pex.netlist.pex
// Created: Thu Oct  1 14:51:55 2009
// Program "Calibre xRC"
// Version "v2008.3_16.12"
// Nominal Temperature: 27C
// Circuit Temperature: 27C
// 
simulator lang=spectre
subckt PM_INVX1\%A ( 2 6 10 17 )
c11 ( 17 0 ) capacitor c=0.00982231f
c12 ( 10 0 ) capacitor c=0.00443547f
c13 ( 6 0 ) capacitor c=0.0295338f
c14 ( 2 0 ) capacitor c=0.023213f
r15 ( 13 17 ) resistor r=6.448 
r16 ( 10 13 ) resistor r=89.3538 
r17 ( 5 17 ) resistor r=1.95 
r18 ( 5 6 ) resistor r=37.44 
r19 ( 1 17 ) resistor r=1.95 
r20 ( 1 2 ) resistor r=30.81 
ends PM_INVX1\%A 
subckt PM_INVX1\%Z ( 3 7 8 )
c8 ( 3 0 ) capacitor c=0.0253156f
r9 ( 7 8 ) resistor r=1.30077 
r10 ( 3 7 ) resistor r=1.43231 
ends PM_INVX1\%Z
etc.
  • The actual netlist ("NAND2.pex.netlist") with only the transistors is the .netlist file:
// File: invx1.pex.netlist
// Created: Thu Oct  1 14:51:55 2009
// Program "Calibre xRC"
// Version "v2008.3_16.12"
// 
simulator lang=spectre
include "invx1.pex.netlist.pex"
subckt invx1 (  )
// 
// GND!	GND!
// VDD!	VDD!
// Z	Z
// A	A
MM0 ( N_Z_MM0_d N_A_MM0_g N_GND!_MM0_s N_GND!_MM0_b ) NMOS_VTL l=5e-08 w=9e-08 \
 ad=9.45e-15 as=9.45e-15 pd=3.9e-07 ps=3.9e-07
MM1 ( N_Z_MM1_d N_A_MM1_g N_VDD!_MM1_s N_VDD!_MM1_b ) PMOS_VTL l=5e-08 \
 w=1.8e-07 ad=1.89e-14 as=1.89e-14 pd=5.7e-07 ps=5.7e-07
// 
include "invx1.pex.netlist.INVX1.pxi"
// 
ends INVX1
//  
// 


  • The .pxi file ("invx1.pex.netlist.INVX1.pxi") contains the connections between the parasitics and the transistors. It looks like this:
// File: invx1.pex.netlist.INVX1.pxi
// Created: Thu Oct  1 14:51:55 2009
// 
simulator lang=spectre
x_PM_INVX1\%A ( N_A_MM0_g N_A_MM1_g A N_A_c_5_p )  PM_INVX1\%A
x_PM_INVX1\%Z ( N_Z_MM0_d Z N_Z_MM1_d )  PM_INVX1\%Z
x_PM_INVX1\%VDD! ( N_VDD!_MM1_s N_VDD!_c_23_n VDD! N_VDD!_MM1_b N_VDD!_c_31_p ) \
  PM_INVX1\%VDD!
x_PM_INVX1\%GND! ( N_GND!_MM0_s N_GND!_c_34_n GND! N_GND!_MM0_b N_GND!_c_42_n ) \
  PM_INVX1\%GND!
cc_1 ( N_A_MM0_g N_Z_MM0_d ) capacitor c=0.0134654f
cc_2 ( A N_Z_MM0_d ) capacitor c=0.0128328f
cc_3 ( N_A_MM1_g N_VDD!_MM1_s ) capacitor c=0.00495734f
cc_4 ( A N_VDD!_MM1_s ) capacitor c=0.00457153f
cc_5 ( N_A_c_5_p N_VDD!_MM1_s ) capacitor c=2.12927e-19
cc_6 ( N_A_MM1_g N_VDD!_c_23_n ) capacitor c=6.83531e-19
cc_7 ( N_A_MM1_g N_VDD!_MM1_b ) capacitor c=0.00138401f
cc_8 ( N_A_MM0_g N_GND!_MM0_s ) capacitor c=0.00284806f
cc_9 ( A N_GND!_MM0_s ) capacitor c=0.00348315f
cc_10 ( N_A_MM0_g N_GND!_c_34_n ) capacitor c=6.08173e-19
cc_11 ( N_A_MM0_g N_GND!_MM0_b ) capacitor c=3.76006e-19
cc_12 ( N_Z_MM0_d N_VDD!_MM1_s ) capacitor c=0.00899139f
cc_13 ( N_Z_MM0_d N_VDD!_c_23_n ) capacitor c=0.00422637f
cc_14 ( N_Z_MM0_d N_VDD!_MM1_b ) capacitor c=0.00644008f
cc_15 ( N_Z_MM0_d N_GND!_MM0_s ) capacitor c=0.00899139f
cc_16 ( N_Z_MM0_d N_GND!_c_34_n ) capacitor c=0.0106885f
cc_17 ( N_Z_MM0_d N_GND!_MM0_b ) capacitor c=0.0085131f
cc_18 ( N_VDD!_MM1_s N_GND!_MM0_s ) capacitor c=7.55743e-19
cc_19 ( N_VDD!_c_23_n N_GND!_c_34_n ) capacitor c=0.00124773f
cc_20 ( N_VDD!_MM1_b N_GND!_MM0_b ) capacitor c=0.00144067f
cc_21 ( N_VDD!_c_31_p N_GND!_c_42_n ) capacitor c=9.1113e-19


If the above simulation gets too slow, you can run without resistive parasitics but with less accuracy. To do this, change the extraction type to "C+CC" instead of "R+C+CC".

Now, you are ready to run a back-annotated simulation.

Back-Annotated Simulation

To run simulations, copy the .pex, .pxi and .netlist file to your prior spectre simulation directory. By default, this will was "spectre.run1".

Rename the .netlist file to just "netlist". This will over-write your original netlist without parasitics.

Now, re-run Spectre as before, but right before you run, uncheck the "netlist" option to prevent it from generating a new netlist from your schematic as shown here:

Netlist.jpg

Everything else should be the same as before back-annotation!