I have implemented the group leader Optimisation to form quantum circuits from unitary matrices. I have taken four variables to represent a gate and have taken 20 variables representing 5 gates (fixed number of gates) as one member. There are 15 such members in a group and a total of 25 groups that i have considered.

My code is only minimising the fidelity error and selecting the string which represent the circuit with minimum fidelity error(number of gates is fixed=5). What I want to do is set the max number of gates to 20 and have variable length string to represent circuits having variable number of gates. That is minimise the fidelity error and also the cost (less number of gates=less cost)

How do I do that???

Code(For Toffoli gate's Unitary Matrix Decomposition):

```
import matplotlib.pyplot as plt
import numpy,random
import functions
num_x = 20
num_groups=25
pop_per_group = 15
pop_size = (num_groups,pop_per_group,num_x)
leaders= numpy.empty((num_groups, num_x))
r1=0.8
r2=0.1
r3=0.1
new_mem=numpy.random.uniform(low=0, high=4, size=20)
new_population = numpy.random.uniform(low=0, high=4, size=pop_size)
for g in range (num_groups):#num_groups
fitness=functions.cal_fitness(new_population[g, : ,:])
#print("fitness of group", g+1)
#print (fitness)
leaders[g,:]=functions.select_leader(new_population[g,: ,:],num_groups,g)
print (leaders)
y=numpy.zeros(shape=600)
for i in range (600):
print("-----------------------------")
print ("Generation:" ,i)
#print("-----------------------------")
print("-----------------------------")
for g in range (num_groups):
for p in range (pop_per_group):
rand_mem=numpy.random.uniform(low=0, high=4, size=20)
new_mem=r1*new_population[g,p,:]+r2*leaders[g,:]+r3*rand_mem
#print(new_population[g,p,:])
new_population[g,p,:] = functions.select_new_mem(new_population[g,p,:],new_mem)
#print(new_population[g,p,:])
for g in range (num_groups):
t=random.randint(0,9)
#print ('old',g,k)
#print(new_population[g,k,:])
for t in range (t+1):
x=int(random.random()*num_groups)
k=int(random.random()*pop_per_group)
pr=random.randint(0,19)
new_mem=new_population[g,k,:].copy()
new_mem[pr]=new_population[x,k,pr]
next_mem=functions.select_new_mem(new_population[g,k,:],new_mem)
new_population[g,k,:]=next_mem
#print (new_population[g,k,:])
#print (next_mem)
#print ('new',g,k)
#print(new_population[g,k,:])
for g in range (num_groups):#num_groups
fitness=functions.cal_fitness(new_population[g, : ,:])
#print("fitness of group", g+1)
#print (fitness)
leaders[g,:]=functions.select_leader(new_population[g,: ,:],num_groups,g)
print (leaders)
print (functions.cal_fitness(leaders))
y[i]=functions.select_best_leader(leaders)
xl = numpy.linspace(0, 600,600)
#Plot the data
plt.plot(xl, y, label='Fitness')
```

Functions (Code):

```
import numpy
from math import pi,sqrt,e
import UnitaryCalculation
from qiskit.quantum_info import process_fidelity
def val_pop(one_mem):
i=1
for var in range (20):
if (i%4==0):
one_mem[var]=one_mem[var] % (2*3.14)
i+=1
elif ((i-1)%4==0):
one_mem[var]=int(one_mem[var])
i+=1
else:#Nq = 3
one_mem[var]=int(one_mem[var] %3 )
i+=1
return one_mem
def ifitness(mem):
unitary_t=[[1,0,0,0,0,0,0,0],[0,1,0,0,0,0,0,0],[0,0,1,0,0,0,0,0],[0,0,0,1,0,0,0,0],[0,0,0,0,1,0,0,0],[0,0,0,0,0,1,0,0],[0,0,0,0,0,0,0,1],[0,0,0,0,0,0,1,0]]
unitary_a=UnitaryCalculation.cal_unitary(mem)
fit=process_fidelity(unitary_t, unitary_a)
fit_mem=1-fit**2
return fit_mem
def cal_fitness(pop):
unitary_t=[[1,0,0,0,0,0,0,0],[0,1,0,0,0,0,0,0],[0,0,1,0,0,0,0,0],[0,0,0,1,0,0,0,0],[0,0,0,0,1,0,0,0],[0,0,0,0,0,1,0,0],[0,0,0,0,0,0,0,1],[0,0,0,0,0,0,1,0]]
#print(unitary_t)
fitness=numpy.ndarray(shape=(0))
for p in range (pop.shape[0]):
unitary_a=UnitaryCalculation.cal_unitary(pop[p, :])
fit=process_fidelity(unitary_t, unitary_a)
fitness=numpy.append(fitness, values=1-fit**2)
#print (fitness)
return (fitness)
def select_leader(pop,num_groups,g):
#print(pop.shape[0])
fitness=cal_fitness(pop)
max_fitness_idx = numpy.where(fitness == numpy.min(fitness))
max_fitness_idx = max_fitness_idx[0][0]
fitness[max_fitness_idx] = +99999999999
return (pop[max_fitness_idx, :])
def select_new_mem(old_mem,new_mem):
of=ifitness(old_mem)
#print(of)
nf=ifitness(new_mem)
#print(new_mem)
#print(nf)
if (nf < of):
#print('changed')
return new_mem
else :
return old_mem
def select_best_leader(leaders):
best_leader = numpy.zeros((leaders.shape[1]))
fitness=cal_fitness(leaders)
max_fitness_idx = numpy.where(fitness == numpy.min(fitness))
max_fitness_idx = max_fitness_idx[0][0]
best_leader= leaders[max_fitness_idx, :]
print ("Best Soln is: ")
print (best_leader)
print ("Its fitness is: ")
print (fitness[max_fitness_idx])
return (fitness[max_fitness_idx])
```

Unitary Calculation(Code):

```
import numpy
from math import sqrt,e,pi
from qiskit.quantum_info import process_fidelity
def get_gate(num):
i_=numpy.complex(0,1)
H=1./sqrt(2)*numpy.matrix('1 1; 1 -1')
X=numpy.matrix('0 1; 1 0')
Y=numpy.matrix([[0, -i_],[i_, 0]])
Z=numpy.matrix([[1,0],[0,-1]])
W=1/sqrt(2)*(X+Z)
V=numpy.matrix([[1+i_,1-i_],[1-i_,1+i_]]) * 1/2
Vdagger = V.conjugate().transpose()
S=numpy.matrix([[1,0],[0,i_]])
Sdagger=numpy.matrix([[1,0],[0,-i_]]) # convenience Sdagger = S.conjugate().transpose()
T=numpy.matrix([[1,0],[0, e**(i_*pi/4.)]])
Tdagger=numpy.matrix([[1,0],[0, e**(-i_*pi/4.)]]) # convenience Tdagger= T.conjugate().transpose()
if (num==0):
return V
elif (num==1):
return Z
elif (num==2):
return S
elif (num==3):
return Vdagger
def cal_mc_gate(gate):
Nq=3
zeros=[[1,0],[0,0]]
ones=[[0,0],[0,1]]
mat_to_tensor=numpy.empty(shape=(Nq,2,2),dtype=complex)
for n in range(Nq):
mat_to_tensor[n]=numpy.identity(2)
Cq=int(gate[2] %3)
Tq=int(gate[1] %3)
theta=gate[3]
g_matrix=get_gate(gate[0])
#print (g_matrix)
if (Cq!=Tq):
mat_to_tensor[Cq]=zeros
u1=numpy.kron(numpy.kron(mat_to_tensor[0],mat_to_tensor[1]),mat_to_tensor[2])
mat_to_tensor[Cq]=ones
mat_to_tensor[Tq]=g_matrix
u2=numpy.kron(numpy.kron(mat_to_tensor[0],mat_to_tensor[1]),mat_to_tensor[2])
unitary=numpy.add(u1,u2)
else:
mat_to_tensor[Tq]=g_matrix
unitary=numpy.kron(numpy.kron(mat_to_tensor[0],mat_to_tensor[1]),mat_to_tensor[2])
#print (unitary)
return unitary
def cal_u_gate(gate):
Nq=3
zeros=[[1,0],[0,0]]
ones=[[0,0],[0,1]]
mat_to_tensor=numpy.empty(shape=(Nq,2,2),dtype=complex)
for n in range(Nq):
mat_to_tensor[n]=numpy.identity(2)
Cq=int(gate[2] %3)
Tq=int(gate[1] %3)
theta=gate[3]
g_matrix=get_gate(gate[0])
#print (g_matrix)
if (Cq!=Tq):
mat_to_tensor[Cq]=zeros
u1=numpy.kron(numpy.kron(mat_to_tensor[0],mat_to_tensor[1]),mat_to_tensor[2])
mat_to_tensor[Cq]=ones
mat_to_tensor[Tq]=g_matrix
u2=numpy.kron(numpy.kron(mat_to_tensor[0],mat_to_tensor[1]),mat_to_tensor[2])
unitary=numpy.add(u1,u2)
else:
mat_to_tensor[Tq]=g_matrix
unitary=numpy.kron(numpy.kron(mat_to_tensor[0],mat_to_tensor[1]),mat_to_tensor[2])
#print (unitary)
return unitary #[[0,2,1,0],[1,2,0,0],[2,1,0,0],[3,2,1,0],[1,0,2,0]]
def cal_unitary(one_mem):
#one_mem=[0,2,1,0,1,2,0,0,2,1,0,0,3,2,1,0,1,0,2,0]
x=numpy.zeros(shape=(5,4))
u=numpy.zeros(shape=(5,8,8),dtype=complex)
k=0
for gate in range (5):
for var in range (0,3):
x[gate][var]=int(one_mem[k])
k+=1
x[gate][var+1]=one_mem[k]
k+=1
for gate in range (5):
u[gate]=cal_u_gate(x[gate,:])
#print ("The unitary matrix of U", gate )
#print (u[gate])
unitary=numpy.dot(numpy.dot(numpy.dot(numpy.dot(u[0],u[1]),u[2]),u[3]),u[4])
#np.set_printoptions(precision=1)
return unitary
```