Handle the case when control voltages on and off are equal.

Update the linear switch: add the limits to resistance ron, roff
Update the log switch: correct the resistance calculation for
von < voff
Add some examples for the pswitch.

examples/xspice/vswitch-test-lin.cir

@@ -0,0 +1,52 @@
+* sw ring-oscillators
+
+.control
+destroy all
+run
+plot I(vmeasurea) I(vmeasureb) I(vmeasurec) I(vmeasured)
+plot V(outa) V(outb) V(outc) V(outd)
+rusage 
+.endc
+
+.tran 3m 3
+
+VDD VDD2 0 DC 3
+Rla VDD2 outa 1k
+Rlb VDD2 outb 1k
+Rlc VDD2 outc 1k
+Rld VDD2 outd 1k
+
+VMEASUREa DGNDa 0 dc 0
+VMEASUREb DGNDb 0 dc 0
+VMEASUREc DGNDc 0 dc 0
+VMEASUREd DGNDd 0 dc 0
+
+Vin in 0 pulse ( 0 3 0 3 3 10 10 )
+
+xsa in outa DGNDa switcha
+xsb in outb DGNDb switchb
+xsc in outc DGNDc switchc
+xsd in outd DGNDd switchd
+
+
+.subckt switcha In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=false cntl_on=1.5 cntl_off=2.5 r_on=1k r_off=2g)
+.ends
+
+.subckt switchb In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=false cntl_on=1.5 cntl_off=2.5 r_on=1k r_off=2k)
+.ends
+
+.subckt switchc In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=false cntl_on=2.5 cntl_off=1.5 r_on=1k r_off=2g)
+.ends
+
+.subckt switchd In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=false cntl_on=2.5 cntl_off=1.5 r_on=1k r_off=2k)
+.ends
+
+.end

examples/xspice/vswitch-test-log.cir

@@ -0,0 +1,52 @@
+* sw ring-oscillators
+
+.control
+destroy all
+run
+plot I(vmeasurea) I(vmeasureb) I(vmeasurec) I(vmeasured)
+plot V(outa) V(outb) V(outc) V(outd)
+rusage 
+.endc
+
+.tran 3m 3
+
+VDD VDD2 0 DC 3
+Rla VDD2 outa 1k
+Rlb VDD2 outb 1k
+Rlc VDD2 outc 1k
+Rld VDD2 outd 1k
+
+VMEASUREa DGNDa 0 dc 0
+VMEASUREb DGNDb 0 dc 0
+VMEASUREc DGNDc 0 dc 0
+VMEASUREd DGNDd 0 dc 0
+
+Vin in 0 pulse ( 0 3 0 3 3 10 10 )
+
+xsa in outa DGNDa switcha
+xsb in outb DGNDb switchb
+xsc in outc DGNDc switchc
+xsd in outd DGNDd switchd
+
+
+.subckt switcha In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=true cntl_on=1.5 cntl_off=2.5 r_on=1k r_off=2g)
+.ends
+
+.subckt switchb In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=true cntl_on=1.5 cntl_off=2.5 r_on=1k r_off=2k)
+.ends
+
+.subckt switchc In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=true cntl_on=2.5 cntl_off=1.5 r_on=1k r_off=2g)
+.ends
+
+.subckt switchd In Out DGND
+a.xx17.asn %gd in DGND %gd out DGND aswswitch
+.model aswswitch pswitch( log=true cntl_on=2.5 cntl_off=1.5 r_on=1k r_off=2k)
+.ends
+
+.end

src/xspice/icm/xtradev/pswitch/cfunc.mod

@@ -71,6 +71,8 @@ typedef struct {
                 the resistance of the switch when the
                 controlling voltage is between cntl_on
                 and cntl_of */
+    double cntl_on;      /* voltage above which switch come on */
+    double cntl_off;     /* voltage below the switch has resistance roff */
     double c1;           /* some constants */
     double c2;
     double c3;
@@ -167,8 +169,6 @@ void cm_pswitch(ARGS)  /* structure holding parms,
 
     /* Retrieve frequently used parameters... */
 
-    cntl_on = PARAM(cntl_on);
-    cntl_off = PARAM(cntl_off);
     r_on = PARAM(r_on);
     r_off = PARAM(r_off);
     r_cntl_in = PARAM(r_cntl_in);
@@ -180,9 +180,11 @@ void cm_pswitch(ARGS)  /* structure holding parms,
     if(INIT == 1) { /* first time through, allocate memory, set static parameters */
         char *cntl_error = "\n*****ERROR*****\nPSWITCH: CONTROL voltage delta less than 1.0e-12\n";
 
+        cntl_on = PARAM(cntl_on);
+        cntl_off = PARAM(cntl_off);
         if( (fabs(cntl_on - cntl_off) < 1.0e-12) ) {
-            cm_message_send(cntl_error);
-            return;
+            cntl_on += 0.001;
+            cntl_off -= 0.001;
         }
 
         CALLBACK = cm_pswitch_callback;
@@ -191,6 +193,9 @@ void cm_pswitch(ARGS)  /* structure holding parms,
         STATIC_VAR (locdata) = calloc (1 , sizeof ( Local_Data_t ));
         loc = STATIC_VAR (locdata);
 
+        loc->cntl_on = cntl_on;
+        loc->cntl_off = cntl_off;
+
         if ( PARAM(log) == MIF_TRUE ) {   /* Logarithmic Variation in 'R' */
             if (cntl_on > cntl_off)
             {
@@ -219,6 +224,8 @@ void cm_pswitch(ARGS)  /* structure holding parms,
 
     loc = STATIC_VAR (locdata);
 
+    cntl_on = loc->cntl_on;
+    cntl_off = loc->cntl_off;
     if ( PARAM(log) == MIF_TRUE ) {   /* Logarithmic Variation in 'R' */
         logmean = loc->logmean;
         logratio = loc->logratio;
@@ -228,7 +235,7 @@ void cm_pswitch(ARGS)  /* structure holding parms,
         double inmean;// = INPUT(cntl_in) - cntl_mean;
         int outOfLimit = 0;
         if (cntl_on > cntl_off) {
-            inmean = ((INPUT(cntl_in) - PARAM(cntl_off)) / (PARAM(cntl_on) - PARAM(cntl_off))) - cntl_mean;
+            inmean = (INPUT(cntl_in) - cntl_off) / (cntl_on - cntl_off) - cntl_mean;
             if (INPUT(cntl_in) > cntl_on) {
                 r = r_on;
                 outOfLimit = 1;
@@ -242,7 +249,7 @@ void cm_pswitch(ARGS)  /* structure holding parms,
                 if(r<r_on) r=r_on;/* minimum resistance limiter */
             }
         } else {
-            inmean = ((PARAM(cntl_on) - INPUT(cntl_in)) / (PARAM(cntl_off) - PARAM(cntl_on))) - cntl_mean;
+            inmean = (cntl_on - INPUT(cntl_in)) / (cntl_on - cntl_off) - cntl_mean;
             if (INPUT(cntl_in) < cntl_on) {
                 r = r_on;
                 outOfLimit = 1;
@@ -267,11 +274,38 @@ void cm_pswitch(ARGS)  /* structure holding parms,
     else {                      /* Linear Variation in 'R' */
         intermediate = loc->intermediate;
         cntl_diff = loc->cntl_diff;
+        if (cntl_diff >=0) {
+            if (INPUT(cntl_in) < cntl_off) {
+                r = r_off;
+                pi_pcntl = 0;
+            }
+            else if (INPUT(cntl_in) > cntl_on) {
+                r = r_on;
+                pi_pcntl = 0;
+            }
+            else {
                 r = INPUT(cntl_in) * intermediate + ((r_off*cntl_on -
                     r_on*cntl_off) / cntl_diff);
+                pi_pcntl = -intermediate * INPUT(out) / (r*r);
+            }
+        }
+        else {
+            if (INPUT(cntl_in) > cntl_off) {
+                r = r_off;
+                pi_pcntl = 0;
+            }
+            else if (INPUT(cntl_in) < cntl_on) {
+                r = r_on;
+                pi_pcntl = 0;
+            }
+            else {
+                r = INPUT(cntl_in) * intermediate + ((r_off*cntl_on -
+                    r_on*cntl_off) / cntl_diff);
+                pi_pcntl = -intermediate * INPUT(out) / (r*r);
+            }        
+        }
         if(r<=1.0e-9) r=1.0e-9;/* minimum resistance limiter */
         pi_pvout = 1.0 / r;
-        pi_pcntl = -intermediate * INPUT(out) / (r*r);
     }
 
     if(ANALYSIS != MIF_AC) {            /* Output DC & Transient Values  */