def standard_all():
Node.n = 100
# np.random.seed(521)
init()
a = dia()
b = mlpt()
c = deba()
d = my(1)
Node_G = [[a, "DIA"], [b, "MLPT"], [c, "DEBA"], [d, "EFTCG"]]
standard_algorithm(Node.n, Node_G)
def f_plot():
Node.n = 60
init()
(G, N) = deba()
plot.display_topology(G, N, "DEBA")
(G, N) = my(1)
plot.display_topology(G, N, "EFTCG-1")
(G, N) = my(2)
plot.display_topology(G, N, "EFTCG-2")
def avg_power():
x = range(30, 110, 10)
y = []
y_dia = []
y_mlpt = []
y_deba = []
y_eftcg = []
for i in x:
print("The number of nodes:", i)
Node.n = i
y_dia_ = []
y_mlpt_ = []
y_deba_ = []
y_eftcg_ = []
for j in range(3):
print("The count:", j)
np.random.seed(j)
init()
G, N = dia()
a = Simulator.average_power(len(N), N)
y_dia_.append(a)
G, N = mlpt()
a = Simulator.average_power(len(N), N)
y_mlpt_.append(a)
G, N = deba()
a = Simulator.average_power(len(N), N)
y_deba_.append(a)
G, N = my(1)
a = Simulator.average_power(len(N), N)
y_eftcg_.append(a)
###########################################
y_dia.append(np.mean(y_dia_))
y_mlpt.append(np.mean(y_mlpt_))
y_deba.append(np.mean(y_deba_))
y_eftcg.append(np.mean(y_eftcg_))
###############################################
y = [[y_dia, "DIA"], [y_mlpt, "MLPT"], [y_deba, "DEBA"],
[y_eftcg, "EFTCG"]]
plot.plot_performance(x, y, ylabel="Avarage Power")
def plot_deba():
(Gdeba, Ndeba) = deba()
plot.display_topology(Gdeba, Ndeba, "DEBA")
def performance_k():
x = range(40, 110, 10)
num = 5 # number of evaluation-index
times = 10 # number of iterations
y_deba = [[] for x in range(num)]
y_k1 = [[] for x in range(num)]
y_k2 = [[] for x in range(num)]
for i in x:
print("The number of nodes:", i)
Node.n = i
y_deba_ = [[] for x in range(num)]
y_k1_ = [[] for x in range(num)]
y_k2_ = [[] for x in range(num)]
for j in range(times):
print("The count:", j)
init()
n = Node.n
size_ = 10
fault_node = random.sample(range(n - 2), size_)
G, N = deba()
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.survival_time(len(N), N, G)
d, e = fault_k(len(N), G, fault_node)
y_deba_[0].append(a)
y_deba_[1].append(b)
y_deba_[2].append(c)
y_deba_[3].append(d)
y_deba_[4].append(e)
G, N = my(1)
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.survival_time(len(N), N, G)
d, e = fault_k(len(N), G, fault_node)
y_k1_[0].append(a)
y_k1_[1].append(b)
y_k1_[2].append(c)
y_k1_[3].append(d)
y_k1_[4].append(e)
G, N = my(2)
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.survival_time(len(N), N, G)
d, e = fault_k(len(N), G, fault_node)
y_k2_[0].append(a)
y_k2_[1].append(b)
y_k2_[2].append(c)
y_k2_[3].append(d)
y_k2_[4].append(e)
###########################################
# power
##########################################
y_deba[0].append(np.mean(y_deba_[0]))
y_k1[0].append(np.mean(y_k1_[0]))
y_k2[0].append(np.mean(y_k2_[0]))
###########################################
# degree
##########################################
y_deba[1].append(np.mean(y_deba_[1]))
y_k1[1].append(np.mean(y_k1_[1]))
y_k2[1].append(np.mean(y_k2_[1]))
##########################################
# survive time
##########################################
y_deba[2].append(np.mean(y_deba_[2]))
y_k1[2].append(np.mean(y_k1_[2]))
y_k2[2].append(np.mean(y_k2_[2]))
###########################################
# failure rate
##########################################
y_deba[3].append(np.mean(y_deba_[3]))
y_k1[3].append(np.mean(y_k1_[3]))
y_k2[3].append(np.mean(y_k2_[3]))
###########################################
# links rate
##########################################
y_deba[4].append(np.mean(y_deba_[4]))
y_k1[4].append(np.mean(y_k1_[4]))
y_k2[4].append(np.mean(y_k2_[4]))
###############################################
y0 = [
[y_deba[0], "DEBA"],
[y_k1[0], "EFTCG-1"],
[y_k2[0], "EFTCG-2"],
]
y1 = [
[y_deba[1], "DEBA"],
[y_k1[1], "EFTCG-1"],
[y_k2[1], "EFTCG-2"],
]
y2 = [
[y_deba[2], "DEBA"],
[y_k1[2], "EFTCG-1"],
[y_k2[2], "EFTCG-2"],
]
y3 = [
[y_deba[3], "DEBA"],
[y_k1[3], "EFTCG-1"],
[y_k2[3], "EFTCG-2"],
]
y4 = [
[y_deba[4], "DEBA"],
[y_k1[4], "EFTCG-1"],
[y_k2[4], "EFTCG-2"],
]
plot.plot_performance(x, y0, ylabel="Average Transmit Power")
plot.plot_performance(x, y1, ylabel="Average Node Degree")
plot.plot_performance(x, y2, ylabel="Network Lifetime")
plot.plot_performance(x, y3, ylabel="Rate of Survival Nodes")
plot.plot_performance(x, y4, ylabel="Rate of Connectable Node Pairs")
def performance():
x = range(30, 110, 10)
num = 4 # number of evaluation-index
times = 10 # number of iterations
y_dia = [[] for x in range(num)]
y_mlpt = [[] for x in range(num)]
y_deba = [[] for x in range(num)]
y_eftcg = [[] for x in range(num)]
for i in x:
print("The number of nodes:", i)
Node.n = i
y_dia_ = [[] for x in range(num)]
y_mlpt_ = [[] for x in range(num)]
y_deba_ = [[] for x in range(num)]
y_eftcg_ = [[] for x in range(num)]
for j in range(times):
print("The count:", j)
init()
G, N = dia()
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.average_hop(len(N), G)
d = Simulator.survival_time(len(N), N, G)
y_dia_[0].append(a)
y_dia_[1].append(b)
y_dia_[2].append(c)
y_dia_[3].append(d)
G, N = mlpt()
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.average_hop(len(N), G)
d = Simulator.survival_time(len(N), N, G)
y_mlpt_[0].append(a)
y_mlpt_[1].append(b)
y_mlpt_[2].append(c)
y_mlpt_[3].append(d)
G, N = deba()
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.average_hop(len(N), G)
d = Simulator.survival_time(len(N), N, G)
y_deba_[0].append(a)
y_deba_[1].append(b)
y_deba_[2].append(c)
y_deba_[3].append(d)
G, N = my(1)
a = Simulator.average_power(len(N), N)
b = Simulator.average_degree(len(N), G)
c = Simulator.average_hop(len(N), G)
d = Simulator.survival_time(len(N), N, G)
y_eftcg_[0].append(a)
y_eftcg_[1].append(b)
y_eftcg_[2].append(c)
y_eftcg_[3].append(d)
###########################################
# power
##########################################
y_dia[0].append(np.mean(y_dia_[0]))
y_mlpt[0].append(np.mean(y_mlpt_[0]))
y_deba[0].append(np.mean(y_deba_[0]))
y_eftcg[0].append(np.mean(y_eftcg_[0]))
###########################################
# degree
##########################################
y_dia[1].append(np.mean(y_dia_[1]))
y_mlpt[1].append(np.mean(y_mlpt_[1]))
y_deba[1].append(np.mean(y_deba_[1]))
y_eftcg[1].append(np.mean(y_eftcg_[1]))
###########################################
# hop
##########################################
y_dia[2].append(np.mean(y_dia_[2]))
y_mlpt[2].append(np.mean(y_mlpt_[2]))
y_deba[2].append(np.mean(y_deba_[2]))
y_eftcg[2].append(np.mean(y_eftcg_[2]))
##########################################
y_dia[3].append(np.mean(y_dia_[3]))
y_mlpt[3].append(np.mean(y_mlpt_[3]))
y_deba[3].append(np.mean(y_deba_[3]))
y_eftcg[3].append(np.mean(y_eftcg_[3]))
###############################################
y0 = [[y_dia[0], "DIA"], [y_mlpt[0], "MLPT"], [y_deba[0], "DEBA"],
[y_eftcg[0], "EFTCG"]]
y1 = [[y_dia[1], "DIA"], [y_mlpt[1], "MLPT"], [y_deba[1], "DEBA"],
[y_eftcg[1], "EFTCG"]]
y2 = [[y_dia[2], "DIA"], [y_mlpt[2], "MLPT"], [y_deba[2], "DEBA"],
[y_eftcg[2], "EFTCG"]]
y3 = [[y_dia[3], "DIA"], [y_mlpt[3], "MLPT"], [y_deba[3], "DEBA"],
[y_eftcg[3], "EFTCG"]]
plot.plot_performance(x, y0, ylabel="Average Transmit Power")
plot.plot_performance(x, y1, ylabel="Average Node Degree")
plot.plot_performance(x, y2, ylabel="Average Hop")
plot.plot_performance(x, y3, ylabel="Network Lifetime")
def fault():
size_ = 10
n = 60
times = 1
k1_in_num_ = []
k1_links_ = []
k2_in_num_ = []
k2_links_ = []
deba_in_num_ = []
deba_links_ = []
###########################################################
for i in range(times):
Node.n = n
init()
n = Node.n
size_ = 10
fault_node = random.sample(range(n - 2), size_) #= fault_node
print("Fault Node is:", fault_node)
#######################################################
# EFTCG-1 #
#######################################################
G, N = my(1)
in_num, links = robust(n, G, fault_node)
# ad_1 = Simulator.average_degree(n, G)
# st_1 = Simulator.survival_time(n, N, G)
k1_in_num_.append(in_num)
k1_links_.append(links)
#######################################################
# EFTCG-2 #
#######################################################
G, N = my(2)
in_num, links = robust(n, G, fault_node)
# ad_2 = Simulator.average_degree(n, G)
# st_2 = Simulator.survival_time(n, N, G)
k2_in_num_.append(in_num)
k2_links_.append(links)
#######################################################
# DEBA #
#######################################################
G, N = deba()
in_num, links = robust(n, G, fault_node)
# ad_3 = Simulator.average_degree(n, G)
# st_3 = Simulator.survival_time(n, N, G)
deba_in_num_.append(in_num)
deba_links_.append(links)
##############################################################
def avg(*lst):
# global size_
avg_ = 0
for x in lst:
avg_ += x / size_
return avg_
def fr(x):
# global n
return x / n * 100
def rl(x):
# global n
return x / (n * (n - 1)) * 100
#############################################################
# failure rate
#############################################################
k1_fr = list(map(fr, list(map(avg, *(k1_in_num_)))))
k2_fr = list(map(fr, list(map(avg, *(k2_in_num_)))))
deba_fr = list(map(fr, list(map(avg, *(deba_in_num_)))))
#############################################################
# links
#############################################################
k1_rl = list(map(rl, list(map(avg, *(k1_links_)))))
k2_rl = list(map(rl, list(map(avg, *(k2_links_)))))
deba_rl = list(map(rl, list(map(avg, *(deba_links_)))))
#############################################################
x = list(range(1, size_ + 1))
y0 = [
[deba_fr, "DEBA"],
[k1_fr, "EFTCG-1"],
[k2_fr, "EFTCG-2"],
]
y1 = [
[[100 - x for x in deba_fr], "DEBA"],
[[100 - x for x in k1_fr], "EFTCG-1"],
[[100 - x for x in k2_fr], "EFTCG-2"],
]
y2 = [
[deba_rl, "DEBA"],
[k1_rl, "EFTCG-1"],
[k2_rl, "EFTCG-2"],
]
# plot.plot_performance(x,y0,xlabel="Number of fault nodes",ylabel="Rate of Failure Nodes")
plot.plot_performance(x,
y1,
xlabel="Number of fault nodes",
ylabel="Rate of Survival Nodes")
plot.plot_performance(x,
y2,
xlabel="Number of fault nodes",
ylabel="Rate of Connectable Node Pairs")
pass
