break branches.append((currentNode,currentNodes[index+1])) upperNodes=currentNodes numBranches=(3*n**2+3*n)/2 numNodes=(n**2+3*n+2)/2 populateBranches() numBranches+=1 #add 1 to the number of branches (for source branch) #build incidence matrix from branches list A=Matrix(i=numNodes,j=numBranches) for j,branch in enumerate(branches): A.set(branch[0],j+1,1) A.set(branch[1],j+1,-1) #set source branch A.set(1,numBranches,-1) A.set(numNodes,numBranches,1) f=open(output,'w') f.write(str(numBranches)+'\n') #number of nodes (subtract one taken as ground) f.write(str(numNodes-1)+'\n')
def buildMatrices(filename):
global Y, E, J, A
#assumes proper formatting (no error detection/correction)
f=open(filename)
lines=f.readlines()
f.close()
branches=int(lines[0])
nodes=int(lines[1])
Y=Matrix(i=branches,j=branches)
E=Matrix(i=branches,j=1)
J=Matrix(i=branches,j=1)
A=Matrix(i=nodes,j=branches)
#NB: lines list uses array indexing (starts at 0), but Matrix class uses indexing starting at 1.
for lineNum in range(2,(branches+1)+1): #skip first two lines already read (adjusted for array indexing, i.e. starts at 0)
branch=lineNum-1
for i,v in enumerate(lines[lineNum].split(',')):
if (i==0):
J.set(branch,1,float(v))
elif (i==1):
Y.set(branch,branch,1/float(v))
else:
E.set(branch,1,float(v))
for lineNum in range((branches+1)+1,(branches+1+nodes)+1):
node=lineNum-(branches+1)
for j,v in enumerate(lines[lineNum].split(',')):
A.set(node,j+1,float(v))
