// genesis // Arranging the P6RSb cells in space. //float P6RSb_SEPX = 25e-6 //float P6RSb_SEPY = 25e-6 //float P6RSb_NX = 5 //float P6RSb_NY = 5 float originxmin float originymin // Unique number for each cell type (same as spike number) int typenum = 12 int ydex float placer float randzpos int i,j int k = 0 placer = {mynode}/{sqrtNnodes} ydex = { round {placer} } originxmin = {regionoffsetx}+({mynode}-{ydex}*sqrtNnodes)*P6RSb_NX*P6RSb_SEPX originymin = {regionoffsety}+{ydex}*P6RSb_NY*P6RSb_SEPY create neutral /P6RSbnet // Random orientation float randrotation addfield /P6RSb rotation if ({{{output} == 1} & {{membranepotentialoutput} == 1}}) create asc_file /Vmwrite{typenum} setfield /Vmwrite{typenum} filename ./data-latest/membrane.celltype{typenum}.{myzeropadnode} flush 1 leave_open 1 append 0 float_format %0.9g end // CREATING THE PLANE OF P6RSb cells //createmap /P6RSb /P6RSbnet \ // {P6RSb_NX} {P6RSb_NY} \ // -delta {P6RSb_SEPX} {P6RSb_SEPY} \ // -origin {originxmin} {originymin} // Note that these cells' positions overlap. This doesn't cause any // problems since we can refer to them as separate groups. for (j = 0; j < P6RSb_NY; j = j+1) for (i = 0; i < P6RSb_NX; i = i+1) int newrandseed = {{ {typenum} @0@ {trunc {{{originxmin}+{P6RSb_SEPX}*{i}}/{SEPX}}} @0@ {trunc {{{originymin}+{P6RSb_SEPY}*{j}}/{SEPY}}} } + {myrandseed}} randseed {newrandseed} randzpos = { rand 0 550e-6 } copy /P6RSb /P6RSbnet/P6RSb[{k}] position /P6RSbnet/P6RSb[{k}] \ {originxmin + P6RSb_SEPX*i} {originymin + P6RSb_SEPY*j} {randzpos} // Rotate about z-axis ("twirl" in GENESIS cellsheet terminology) if ({rotateneurons} == 1) randrotation = {rand 0 6.283185308 } setfield /P6RSbnet/P6RSb[{k}] rotation {randrotation} // save for posterity rotcoord /P6RSbnet/P6RSb[{k}] {randrotation} -z -center {originxmin + P6RSb_SEPX*i} {originymin + P6RSb_SEPY*j} {randzpos} end if ({{{output} == 1} & {{membranepotentialoutput} == 1}}) addmsg /P6RSbnet/P6RSb[{k}]/soma /Vmwrite{typenum} SAVE Vm end k=k+1 end end