// Generate multiple graphs about the different metrics as a function of
// size.
// Generate a different file for every source_min
public static void graphRateSize3(int tst_nr, int n_averages, int plot)
{
Console.WriteLine("Executing {0}({1:d2},{2:d6},{3})", G.current(),
tst_nr, n_averages, plot);
double tx_rg = 2;
double[] xv = null;
double[] yv = null;
if (tst_nr == 0)
{
xv = new double[] {tx_rg, 2 * tx_rg};
yv = new double[] {tx_rg, tx_rg};
}
else if (tst_nr == 1)
{
xv = G.linspace(tx_rg, 5 * tx_rg, 5);
yv = G.linspace(2 * tx_rg, 2.01 * tx_rg, 5);
}
if (xv.GetLength(0) != yv.GetLength(0))
{
throw new Exception("xv and yv should have equal length");
}
double rho = 15;
int sched_lgth = 10;
int n_tx_frames = 2000;
double opt = 0;
int[] types = new int[] {0, 1, 2, 3, 4, 5};
double[] rate_v = G.linspace(0.5, 3, 28);
int buffer_size = 30;
double[,] tota = new double[xv.GetLength(0), types.Length];
double[,] mean = new double[xv.GetLength(0), types.Length];
double[,] pmin = new double[xv.GetLength(0), types.Length];
double[,] ropt = new double[xv.GetLength(0), types.Length];
Pgf g = new Pgf();
string xlab = "normalized x size";
double[] xn = new double[xv.Length];
for (int q = 0; q < xn.Length; q++)
{
xn[q] = xv[q] / tx_rg;
}
for (double frac_source_min = 0.2; frac_source_min < 1;
frac_source_min += 0.3)
{
for (int k = 0; k < n_averages; k++)
{
Console.WriteLine("Repetition {0,4:D}. Total {1}",
k, G.elapsed());
for (int s = 0; s < xv.GetLength(0); s++)
{
Console.WriteLine("s={0,2}, x/t={1,4:F}. Total {2}",
s, xv[s] / tx_rg, G.elapsed());
int n = (int)(rho*xv[s]*yv[s]/Math.PI/tx_rg/tx_rg);
int source_min = (int) (frac_source_min * n);
G.rgen = new Random(k);
int[] fv = RandomTree.parents(n, xv[s], yv[s], tx_rg);
double[] ps = new double[n];
for (int u = 0; u < n; u++)
{
ps[u] = 0.5 + G.rgen.NextDouble() / 2;
}
for (int i = 0; i < types.Length; i++)
{
double m_tota = 0;
double m_mean = 0;
double m_pmin = 0;
double m_ropt = rate_v[0];
for (int j = 0; j < rate_v.Length; j++)
{
LossTree t = new LossTree(fv,ps,buffer_size);
if (types[i] == 3)
{
t.find_schedule(sched_lgth, source_min);
}
int[] results = t.simulate_it(n_tx_frames,
rate_v[j], types[i], k);
double a_tota = 0;
double a_mean = 0;
double a_pmin = 0;
foreach (int h in results)
{
a_tota += (double) h / n_tx_frames;
a_mean += (double) h / results.Length;
if (h < source_min)
{
a_pmin += (double)1 / results.Length;
}
}
if (a_tota > m_tota)
{
m_tota = a_tota;
m_mean = a_mean;
m_pmin = a_pmin;
m_ropt = rate_v[j];
}
}
tota[s, i] += m_tota / n_averages;
mean[s, i] += m_mean / n_averages;
pmin[s, i] += m_pmin / n_averages;
ropt[s, i] += m_ropt / n_averages;
}
}
}
Console.WriteLine("**** Printing results *****");
string[] legv = new string[] {"0", "1", "2",
String.Format("3={0:F3}",opt),
"4", "5" };
string append = String.Format("frac-source-min = {0:f2}",
frac_source_min);
g.add(xlab, "total " + append);
g.mplot(xn, tota, legv);
g.add(xlab, "mean " + append);
g.mplot(xn, mean, legv);
g.add(xlab, "pmin " + append);
g.mplot(xn, pmin, legv);
g.add(xlab, "ropt " + append);
g.mplot(xn, ropt, legv);
}
string filename = String.Format("{0}_{1:d2}_{2:d6}", G.current(),
tst_nr, n_averages);
Console.WriteLine(filename);
g.save(filename, plot);
}
public static void tst_Pgf1()
{
double[] xv = G.linspace(0, 9, 10);
double[,] y1 = new double[10, 2];
double[,] y2 = new double[10, 2];
for (int j = 0; j < y1.GetLength(1); j++)
{
for (int i = 0; i < y1.GetLength(0); i++)
{
y1[i, j] = i * j;
y2[i, j] = i * (j + 1);
}
}
Pgf p = new Pgf();
p.add("x", "y");
p.mplot(xv, y1, new string[] { "normal", "double" });
p.add("x", "y");
p.mplot(xv, y2, new string[] { "normal", "double" });
p.save("zb", 2);
}
// This function computes the average metrics at different rates for
// different topologies. This is quite useless, because different
// metrics have different operation points. It unfairly shows poor
// performance of the scheduled approach. The only useful part may be
// comparing the unscheduled approaches.
public static void graphRateRandom(int tst_nr, int n_averages, int plot)
{
Console.WriteLine("Executing {0}({1:d2},{2:d6},{3})", G.current(),
tst_nr, n_averages, plot);
double tx_rg = 2;
double x = 5 * tx_rg;
double y = 5 * tx_rg;
double rho = 9;
int n = (int)(rho * x * y / Math.PI / tx_rg / tx_rg);
int sched_lgth = 10;
int n_tx_frames = 2000;
double opt = 0;
double[] rate_v = G.linspace(0.1, 1.5, 28);
int source_min = 3;
int buffer_size = 30;
int[] types = new int[] {0, 1, 2, 3, 4};
G.VB = false;
double[,] tota = new double[rate_v.Length, types.Length];
double[,] mean = new double[rate_v.Length, types.Length];
double[,] pmin = new double[rate_v.Length, types.Length];
for (int k = 0; k < n_averages; k++)
{
Console.WriteLine("Repetition {0,4:D}. Total {1}",
k, G.elapsed());
G.rgen = new Random(k);
int[] fv = RandomTree.parents(n, x, y, tx_rg);
double[] ps = new double[n];
for (int u = 0; u < n; u++)
{
ps[u] = 0.5 + G.rgen.NextDouble() / 2;
}
for (int j = 0; j < rate_v.Length; j++)
{
for (int i = 0; i < types.Length; i++)
{
LossTree t = new LossTree(fv, ps, buffer_size);
if (types[i] == 3)
{
t.find_schedule(sched_lgth, source_min);
if (k == 0 && j == 0)
{
opt = ((double)t.count.Count / sched_lgth);
}
}
int[] results = t.simulate_it(n_tx_frames, rate_v[j],
types[i], k);
foreach (int h in results)
{
tota[j, i] += (double)h / n_averages / n_tx_frames;
mean[j, i] += (double)h / n_averages / results.Length;
if (h < source_min)
{
pmin[j, i] += (double)1 / n_averages /
results.Length;
}
}
}
}
}
Console.WriteLine("**** Printing results *****");
string[] legv = new string[] { "0", "1", "2",
String.Format("3={0:F3}", opt), "4" };
Pgf g = new Pgf();
g.add("rate", "total");
g.mplot(rate_v, tota, legv);
g.add("rate", "mean");
g.mplot(rate_v, mean, legv);
g.add("rate", "pmin");
g.mplot(rate_v, pmin, legv);
string filename = String.Format("{0}_{1:d2}_{2:d6}", G.current(),
tst_nr, n_averages);
g.save(filename, plot);
}
public static void graphRate1(int tst_nr, int n_averages, int plot)
{
Console.WriteLine("Executing {0}({1:d2},{2:d6},{3}). Total {4}",
G.current(), tst_nr, n_averages, plot, G.elapsed());
int sched_lgth = 10;
int[] fv;
int n_tx_frames = 2000;
double opt = 0;
double[] ps;
double[] rate_v = G.linspace(0.1, 1.5, 28);
int source_min = 3;
int buffer_size = 30;
int[] types = new int[] {0, 1, 2, 3, 4, 5};
G.VB = false;
// Shows the advantage of the scheduled approach, particularly in
// terms of
if (tst_nr == 0) {
fv = new int[] { -1, 0, 1, 1, 1, 1 };
ps = new double[] { 1, 0.8, 0.4, 0.4, 0.4, 0.4 }; }
// No advantage in the scheduled approach
else if (tst_nr == 1) {
fv = new int[] { -1, 0, 1, 1, 1, 1 };
ps = new double[] { 1, 0.4, 0.4, 0.4, 0.4, 0.4 }; }
// No advantage in scheduled approach
else if (tst_nr == 2) {
fv = new int[] { -1, 0, 1, 1, 1, 1 };
ps = new double[] { 1, 0.4, 0.8, 0.8, 0.8, 0.8 }; }
// Slight advantage of scheduled approach, all select/discard
// policies are similar.
else if (tst_nr == 3) {
fv = new int[] { -1, 0, 1, 1, 1, 1 };
ps = new double[] { 1, 0.6, 0.6, 0.6, 0.2, 0.2 }; }
// Advantage of scheduled approach for low rate, great variety
// between select/discard policies, but 0 is overall the best.
else if (tst_nr == 4) {
fv = new int[] { -1, 0, 1, 1, 1, 1 };
ps = new double[] { 1, 0.3, 0.6, 0.6, 0.2, 0.2 }; }
// No schedule advantage and moderate advantage of packet
// selection. Strong peak at the optimal.
else if (tst_nr == 5) {
fv = new int[] { -1, 0, 1, 2, 3, 4, 5, 5, 5, 5, 5, 5 };
ps = new double[12];
for (int i = 0; i < fv.Length; i++)
ps[i] = 0.3;
} // No schedule advantage and moderate advantage of packet selection.
else if (tst_nr == 6) {
fv = new int[] { -1, 0, 1, 2, 3, 4, 5 };
ps = new double[fv.Length];
for (int i = 0; i < ps.Length; i++)
ps[i] = 0.3;
}
// Unsuccessful attempt to make the hybrid select/discard topology
// work.
else if (tst_nr == 7) {
fv = new int[] {-1, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2};
ps = new double[fv.Length];
for (int i = 0; i < ps.Length; i++)
ps[i] = 0.8;
}
else if (tst_nr == 8) {
fv = new int[] {-1, 0, 0, 1, 1, 1, 2, 2, 2};
ps = new double[fv.Length];
for (int i = 0; i < ps.Length; i++)
ps[i] = 0.8;
}
else if (tst_nr == 9) {
fv = new int[] {-1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 9, 10, 11, 12};
ps = new double[fv.Length];
for (int i = 0; i < ps.Length; i++) {
if (i < 9)
ps[i] = 0.8;
else
ps[i] = 0.4;
}
}
// These parameters are chosen to show the advantage of the
// scheduled approach vs the unscheduled approach.
else if (tst_nr == 10) {
fv = new int[] {-1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 9, 10, 11, 12};
ps = new double[fv.Length];
for (int i = 0; i < ps.Length; i++) {
if (i < 9)
ps[i] = 0.4;
else
ps[i] = 0.8;
}
}
else if (tst_nr == 11) {
fv = new int[] {-1, 0, 1, 1, 1, 0, 5, 6, 7, 8};
ps = new double[fv.Length];
for (int i = 0; i < ps.Length; i++) {
if (i < 5) ps[i] = 0.4;
else ps[i] = 0.8;
}
}
// These parameters were chosen to show that the optimal rate is
// hard to determine. In this case, the total is higher for 0.83,
// despite the fact that it means that node 1 has spare capacity
// that it could be using to transmit more packets.
else if (tst_nr == 12) {
fv = new int[] {-1, 0, 1, 1, 1, 1, 1};
ps = new double[] {1, 0.88, 0.83, 0.83, 0.83, 0.83, 0.83}; }
// These parameters were chosen to show the usefulness of the
// scheduling algorithm in a small network.
else if (tst_nr == 13) {
fv = new int[] {-1, 0, 1, 1, 0};
ps = new double[] {1, 0.8, 0.6, 0.2, 0.2}; }
// These parameters show that under a linear topology with all links
// equally good, all select/discard policies perform very similarly.
else if (tst_nr == 14) {
fv = new int[] {-1, 0, 1, 2, 3, 4, 5};
ps = new double[fv.Length];
for (int i = 0; i < fv.Length; i++)
ps[i] = 0.5;
}
// These parameters show a linear topology whose last node has many
// children. This is a good example of a situation in which the
// select/discard type 2 performs much better than the other types.
else if (tst_nr == 15) {
fv = new int[] { -1, 0, 1, 2, 3, 4, 5, 5, 5, 5, 5, 5 };
ps = new double[12];
for (int i = 0; i < fv.Length; i++)
{
if (i < 6)
ps[i] = 0.3;
else
ps[i] = 1;
}
}
// These parameters show that under a linear topology with unequal
// link qualities, the priority traffic may perform best.
else if (tst_nr == 16) {
fv = new int[] {-1, 0, 1, 2, 3, 4, 5, 6, 7};
ps = new double[fv.Length];
for (int i = 0; i < fv.Length; i++) {
if (i < 4)
ps[i] = 0.4;
else
ps[i] = 1;
}
}
else if (tst_nr == 17) {
fv = new int[] {-1, 0, 1, 1};
ps = new double[] {1, 0.8, 0.4, 0.4};
source_min = 2;
}
else if (tst_nr == 18) {
fv = new int[] {-1, 0, 1, 1, 0};
ps = new double[] {1, 0.8, 0.6, 0.2, 0.2};
source_min = 2;
}
else if (tst_nr == 19) {
fv = new int[] {-1, 0, 1, 1, 0};
ps = new double[] {1, 0.66, 0.49, 0.16, 0.16};
source_min = 2;
sched_lgth = 5;
}
else throw new ArgumentException("Inappropriate tst_nr");
PltGlb.plot_logical3(fv, ps, plot);
double[,] tota = new double[rate_v.Length, types.Length];
double[,] mean = new double[rate_v.Length, types.Length];
double[,] pmin = new double[rate_v.Length, types.Length];
for (int k = 0; k < n_averages; k++) {
Console.WriteLine("Repetition {0} of {1}({2:d2},{3:d6},{4}) {5}",
k, G.current(), tst_nr, n_averages, plot, G.elapsed());
for (int j = 0; j < rate_v.Length; j++) {
for (int i = 0; i < types.Length; i++) {
LossTree t = new LossTree(fv, ps, buffer_size);
if (types[i] == 3) {
t.find_schedule(sched_lgth, source_min);
if (k == 0 && j == 0)
opt = ((double)t.count.Count / sched_lgth);
}
int[] results = t.simulate_it(n_tx_frames, rate_v[j],
types[i], k);
foreach (int h in results) {
tota[j, i] += (double)h / n_averages / n_tx_frames;
mean[j, i] += (double)h / n_averages / results.Length;
if (h < source_min)
pmin[j, i] += (double)1 / n_averages /
results.Length;
}
}
}
}
Console.WriteLine("**** Printing results *****");
string[] legv = new string[] { "0", "1", "2",
String.Format("3={0:F3}", opt), "4", "5" };
Pgf g = new Pgf();
g.add("rate", "total");
g.mplot(rate_v, tota, legv);
g.add("rate", "mean");
g.mplot(rate_v, mean, legv);
g.add("rate", "pmin");
g.mplot(rate_v, pmin, legv);
g.add("missing data tolerance", "rate efficiency");
g.implot(rate_v, pmin, legv);
g.extra_body.Add("\n\\includegraphics[scale=0.4]{ztree.pdf}\n");
string filename = String.Format("{0}_{1:d2}_{2:d6}", G.current(),
tst_nr, n_averages);
g.save(filename, plot);
}
// 438 seconds per iteration in ee-moda
public static void averSource(int tst_nr, int n_averages, int plot)
{
Console.WriteLine("Executing {0}({1:d2},{2:d6},{3})", G.current(),
tst_nr, n_averages, plot);
double tx_rg = 2;
double x = 3 * tx_rg;
double y = 3 * tx_rg;
double rho = 9;
int n = (int)(rho * x * y / Math.PI / tx_rg / tx_rg);
int sched_lgth = 20;
int n_tx_frames = 5000;
double infid_thresh = 0.15;
// Parameters for the all-transmit-in-all approach: number of blocks
// and packets per block.
int blocks = 200;
int n_packets = 8;
int[] source_min_v = new int[] {3, 5, 8, 11, 14, 17, 20};
Console.WriteLine("Simulating {0:d} nodes", n);
// Number of tree reconfiguration cycles used to balance the energy
// consumption.
int n_tree_reconf = 5;
int buffer_size = 30;
int[] types = new int[] {0, 3, 9};
G.VB = false;
G.rx_consum = 0.001;
double[,] consum_mean = new double[source_min_v.Length, 3];
double[,] consum_median = new double[source_min_v.Length, 3];
double[,] consum_max = new double[source_min_v.Length, 3];
for (int k = 0; k < n_averages; k++)
{
Console.WriteLine("Repetition {0,4:D}. Total {1}", k,
G.elapsed());
Console.WriteLine(" Current time is {0}",
DateTime.Now.ToString("u"));
G.rgen = new Random(k);
AverTree at = new AverTree(n, x, y, tx_rg);
for (int a = 0; a < source_min_v.Length; a++)
{
for (int d = 0; d < types.Length; d++)
{
double[] tot_consum1 = new double[n];
G.rgen = new Random(k);
if (types[d] == 9)
{
for (int h = 0; h < n_tree_reconf; h++)
{
at.get_tree(tot_consum1);
LossTree e = new LossTree(at.fv, at.ps,
buffer_size);
e.simulate_it2(blocks, n_packets, h);
for (int i = 0; i < n; i++)
tot_consum1[i] += e.nodes[i].consum /
n_tree_reconf;
}
}
else
{
for (int h = 0; h < n_tree_reconf; h++)
{
double[] consum_old = new double[n];
for (double rate =0.1; ; rate *= 1.05)
{
at.get_tree(tot_consum1);
LossTree t = new LossTree(at.fv, at.ps,
buffer_size);
t.find_schedule(sched_lgth, source_min_v[a]);
// This is supposed to show the optimal rate.
// Console.WriteLine(((double)t.count.Count /
// sched_lgth));
int [] results = t.simulate_it(n_tx_frames,
rate, types[d], h);
// Fraction of reporting intervals with
// insufficient count
double infid_ratio = 0.0;
foreach (int m in results)
{
if (m < source_min_v[a])
infid_ratio
+=1.0/(double)results.Length;
}
if (infid_ratio < infid_thresh)
{
// This rate yields sufficiently low
// infid_ratio. Record the consumption in
// case this is the last rate to yield
// sufficiently low infid_ratio.
for (int q = 0; q < n; q++)
consum_old[q] = t.nodes[q].consum;
}
else
{
// Record statistics in permanent
// variable This rate is the smallest
// rate that is too high. Record
// consumption of the previous
// iteration.
for (int r=0; r < n; r++)
tot_consum1[r] += consum_old[r] /
n_tree_reconf;
break;
}
}
}
}
consum_mean[a,d] += G.Mean(tot_consum1) / n_averages;
consum_median[a,d] += G.Median(tot_consum1) / n_averages;
consum_max[a,d] += G.Max(tot_consum1) / n_averages;
}
}
}
string[] legv = new string[] {"0", "3", "9"};
Pgf g = new Pgf();
g.extra_body.Add(String.Format("\n\nThe number of nodes is {0:d}",
n));
for (int i = 0; i < 2; i++)
{
string xaxis = "source.min";
double[] xvec = new double[source_min_v.Length];
if (i == 0)
for (int q = 0; q < source_min_v.Length; q++)
xvec[q] = (double) source_min_v[q];
else if (i == 1)
{
for (int q = 0; q < source_min_v.Length; q++)
xvec[q] = 100 * source_min_v[q] / (double) (n-1);
xaxis = "percent source.min";
}
g.add(xaxis, "consum-mean");
g.mplot(xvec, consum_mean, legv);
g.add(xaxis, "consum-median");
g.mplot(xvec, consum_median, legv);
g.add(xaxis, "consum-max");
g.mplot(xvec, consum_max, legv);
double[,] gain_mean = new double [source_min_v.Length, 2];
double[,] gain_median = new double [source_min_v.Length, 2];
double[,] gain_max = new double [source_min_v.Length, 2];
for (int q = 0; q < source_min_v.Length; q++)
for (int s = 0; s < 2; s++)
{
gain_mean[q, s] = 100 * (consum_mean[q, 2] -
consum_mean[q, s]) / consum_mean[q, 2];
gain_median[q, s] = 100 * (consum_median[q, 2] -
consum_median[q, s]) / consum_median[q, 2];
gain_max[q, s] = 100 * (consum_max[q, 2] -
consum_max[q, s]) / consum_max[q, 2];
}
string[] legv2 = new string[] {"0", "3"};
g.add(xaxis, "gain-mean");
g.mplot(xvec, gain_mean, legv2);
g.add(xaxis, "gain-median");
g.mplot(xvec, gain_median, legv2);
g.add(xaxis, "gain-max");
g.mplot(xvec, gain_max, legv2);
}
string filename = String.Format("{0}_{1:d2}_{2:d6}", G.current(),
tst_nr, n_averages);
g.save(filename, plot);
//Console.WriteLine("consum_mean = {0,8:F3} {1,8:F3}
//{2,8:F3}",
// consum_mean[0], consum_mean[1], consum_mean[2]);
//Console.WriteLine("consum_median = {0,8:F3} {1,8:F3}
//{2,8:F3}",
// consum_median[0], consum_median[1], consum_median[2]);
//Console.WriteLine("consum_max = {0,8:F3} {1,8:F3}
//{2,8:F3}",
// consum_max[0], consum_max[1], consum_max[2]);
}
// Vary node density and keep constant the fraction of n_source_nodes
// 1044s per iteration at ee-modalap
public static void averSize(int tst_nr, int n_averages, int plot)
{
Console.WriteLine("Executing {0}({1:d2},{2:d6},{3})", G.current(),
tst_nr, n_averages, plot);
double tx_rg = 2;
double x = 2 * tx_rg;
double[] y_v_n = new double[] {2, 3};// y vector normalized by tx_rg
int[] types = new int[] {0, 3, 9};
if (tst_nr == 1)
{
y_v_n = new double[] {2, 3, 4, 5, 6};
types = new int[] {0, 1, 3, 4, 5, 9};
}
double[] y_v = new double[y_v_n.Length];
for (int i = 0; i < y_v.Length; i++)
y_v[i] = y_v_n[i] * tx_rg;
double rho = 10;
int sched_lgth = 20;
int n_tx_frames = 5000;
double infid_thresh = 0.15;
// Parameters for the all-transmit-in-all approach: number of blocks
// and packets per block.
int blocks = 200;
int n_packets = 8;
// Number of tree reconfiguration cycles used to balance the energy
// consumption.
int n_tree_reconf = 5;
int buffer_size = 30;
G.VB = false;
G.rx_consum = 0.001;
double[,] consum_mean = new double[y_v.Length, types.Length];
double[,] consum_median = new double[y_v.Length, types.Length];
double[,] consum_max = new double[y_v.Length, types.Length];
double[,] rate_min_v = new double[y_v.Length, types.Length - 1];
for (int k = 0; k < n_averages; k++) {
Console.WriteLine("Repetition {0,4:D}. Total {1}", k,
G.elapsed());
for (int a = 0; a < y_v.Length; a++) {
int n = (int)(rho * x * y_v[a] / Math.PI / tx_rg / tx_rg);
int source_min = (int) (0.4 * (double) n);
Console.WriteLine("Simulating {0:d} nodes", n);
G.rgen = new Random(k);
AverTree at = new AverTree(n, x, y_v[a], tx_rg);
for (int d = 0; d < types.Length; d++) {
double[] tot_consum1 = new double[n];
G.rgen = new Random(k);
if (types[d] == 9) {
for (int h = 0; h < n_tree_reconf; h++) {
at.get_tree(tot_consum1);
LossTree e = new LossTree(at.fv, at.ps,
buffer_size);
e.simulate_it2(blocks, n_packets, h);
for (int i = 0; i < n; i++)
tot_consum1[i] += e.nodes[i].consum /
n_tree_reconf;
}
}
else {
for (int h = 0; h < n_tree_reconf; h++) {
double[] consum_old = new double[n];
double expon = 1.05;
for (double rate =0.1; ; rate *= expon) {
at.get_tree(tot_consum1);
LossTree t = new LossTree(at.fv, at.ps,
buffer_size);
t.find_schedule(sched_lgth, source_min);
// This is supposed to show the optimal rate.
// Console.WriteLine(((double)t.count.Count /
// sched_lgth));
int [] results = t.simulate_it(n_tx_frames,
rate, types[d], h);
// Fraction of reporting intervals with
// insufficient count
double infid_ratio = 0.0;
foreach (int m in results)
if (m < source_min)
infid_ratio +=
1.0/(double)results.Length;
// This rate yields sufficiently low
// infid_ratio. Record the consumption in
// case this is the last rate to yield
// sufficiently low infid_ratio.
if (infid_ratio < infid_thresh)
for (int q = 0; q < n; q++)
consum_old[q] = t.nodes[q].consum;
else {
// Record statistics in permanent
// variable This rate is the smallest
// rate that is too high. Record
// consumption of the previous
// iteration.
rate_min_v[a,d] +=rate/expon/
n_tree_reconf / n_averages;
for (int r=0; r < n; r++)
tot_consum1[r] += consum_old[r] /
n_tree_reconf;
break;
}
}
}
}
consum_mean[a,d] += G.Mean(tot_consum1) / n_averages;
consum_median[a,d] += G.Median(tot_consum1) / n_averages;
consum_max[a,d] += G.Max(tot_consum1) / n_averages;
}
}
}
string[] legv = new string[types.Length];
for (int i = 0; i < types.Length; i++)
legv[i] = types[i].ToString();
Pgf g = new Pgf();
string xaxis = "normalized y-v";
g.add(xaxis, "consum-mean");
g.mplot(y_v_n, consum_mean, legv);
g.add(xaxis, "consum-median");
g.mplot(y_v_n, consum_median, legv);
g.add(xaxis, "consum-max");
g.mplot(y_v_n, consum_max, legv);
double[,] gain_mean = new double [y_v_n.Length, types.Length - 1];
double[,] gain_median = new double [y_v_n.Length, types.Length -1];
double[,] gain_max = new double [y_v_n.Length, types.Length - 1];
int refz = types.Length - 1; // Column used as a benchmark
for (int q = 0; q < y_v_n.Length; q++)
for (int s = 0; s < types.Length - 1; s++)
{
gain_mean[q, s] = 100 * (consum_mean[q, refz] -
consum_mean[q, s]) / consum_mean[q, refz];
gain_median[q, s] = 100 * (consum_median[q, refz] -
consum_median[q, s]) / consum_median[q, refz];
gain_max[q, s] = 100 * (consum_max[q, refz] -
consum_max[q, s]) / consum_max[q, refz];
}
string[] legv2 = new string[types.Length - 1];
for (int i = 0; i < types.Length - 1; i++)
legv2[i] = types[i].ToString();
g.add(xaxis, "normalized load");
g.mplot(y_v_n, rate_min_v, legv2);
g.add(xaxis, "gain-mean");
g.mplot(y_v_n, gain_mean, legv2);
g.add(xaxis, "gain-median");
g.mplot(y_v_n, gain_median, legv2);
g.add(xaxis, "gain-max");
g.mplot(y_v_n, gain_max, legv2);
g.add(xaxis, "max-rate");
g.mplot(y_v_n, rate_min_v, legv2);
string filename = String.Format("{0}_{1:d2}_{2:d6}", G.current(),
tst_nr, n_averages);
g.save(filename, plot);
//Console.WriteLine("consum_mean = {0,8:F3} {1,8:F3} {2,8:F3}",
// consum_mean[0], consum_mean[1], consum_mean[2]);
//Console.WriteLine("consum_median = {0,8:F3} {1,8:F3} {2,8:F3}",
// consum_median[0], consum_median[1], consum_median[2]);
//Console.WriteLine("consum_max = {0,8:F3} {1,8:F3} {2,8:F3}",
// consum_max[0], consum_max[1], consum_max[2]);
}
public static void averRxConsum(int tst_nr, int n_averages, int plot)
{
Console.WriteLine("Executing {0}({1:d2},{2:d6},{3})", G.current(),
tst_nr, n_averages, plot);
double tx_rg = 2;
double x = 3 * tx_rg;
double y = 3 * tx_rg;
double rho = 9;
int n = (int)(rho * x * y / Math.PI / tx_rg / tx_rg);
int sched_lgth = 20;
int n_tx_frames = 5000;
double infid_thresh = 0.15;
// Parameters for the all-transmit-in-all approach: number of blocks
// and packets per block.
int blocks = 200;
int n_packets = 8;
int source_min = 1;
if (tst_nr == 0)
source_min = 3;//(int) (n * 0.2);
else if (tst_nr == 1)
source_min = 5;
else if (tst_nr == 2)
source_min = 8;
else
throw new Exception("Invalid tst_nr");
Console.WriteLine("source_min = {0:d}", source_min);
Console.WriteLine("Simulating {0:d} nodes", n);
// Number of tree reconfiguration cycles used to balance the energy
// consumption.
int n_tree_reconf = 5;
double [] tx_factor_v = new double[] {0, 4, 8, 12, 16};
double [] rx_consum_v = new double[tx_factor_v.Length];
for (int i = 0; i < tx_factor_v.Length; i++)
{
rx_consum_v[i] = Math.Pow(10, - tx_factor_v[i] / 10);
Console.WriteLine(rx_consum_v[i]);
}
int buffer_size = 30;
int[] types = new int[] {0, 3, 9};
G.VB = false;
double[,] consum_mean = new double[rx_consum_v.Length, 3];
double[,] consum_median = new double[rx_consum_v.Length, 3];
double[,] consum_max = new double[rx_consum_v.Length, 3];
for (int k = 0; k < n_averages; k++)
{
G.rgen = new Random(k);
AverTree at = new AverTree(n, x, y, tx_rg);
for (int a = 0; a < rx_consum_v.Length; a++)
{
G.rx_consum = rx_consum_v[a];
for (int d = 0; d < types.Length; d++)
{
double[] tot_consum1 = new double[n];
G.rgen = new Random(k);
if (types[d] == 9)
{
for (int h = 0; h < n_tree_reconf; h++)
{
at.get_tree(tot_consum1);
LossTree e = new LossTree(at.fv, at.ps,
buffer_size);
e.simulate_it2(blocks, n_packets, h);
for (int i = 0; i < n; i++)
tot_consum1[i] += e.nodes[i].consum /
n_tree_reconf;
}
}
else
{
for (int h = 0; h < n_tree_reconf; h++)
{
double[] consum_old = new double[n];
for (double rate =0.1; ; rate *= 1.05)
{
at.get_tree(tot_consum1);
LossTree t = new LossTree(at.fv, at.ps,
buffer_size);
t.find_schedule(sched_lgth, source_min, false);
// This is supposed to show the optimal rate.
// Console.WriteLine(((double)t.count.Count /
// sched_lgth));
int [] results = t.simulate_it(n_tx_frames,
rate, types[d], h);
// Fraction of reporting intervals with
// insufficient count
double infid_ratio = 0.0;
foreach (int m in results)
{
if (m < source_min)
infid_ratio
+=1.0/(double)results.Length;
}
if (infid_ratio < infid_thresh)
{
// This rate yields sufficiently low
// infid_ratio. Record the consumption in
// case this is the last rate to yield
// sufficiently low infid_ratio.
for (int q = 0; q < n; q++)
consum_old[q] = t.nodes[q].consum;
}
else
{
// Record statistics in permanent
// variable This rate is the smallest
// rate that is too high. Record
// consumption of the previous
// iteration.
for (int r=0; r < n; r++)
tot_consum1[r] += consum_old[r] /
n_tree_reconf;
break;
}
}
}
}
consum_mean[a,d] += G.Mean(tot_consum1) / n_averages;
consum_median[a,d] += G.Median(tot_consum1) / n_averages;
consum_max[a,d] += G.Max(tot_consum1) / n_averages;
}
}
}
string[] legv = new string[] {"0", "3", "9"};
Pgf g = new Pgf();
string xaxis = "$10\\,\\mathrm{log}_{10}(P_{tx}/P_{rx})$";
g.add(xaxis, "consum-mean");
g.mplot(tx_factor_v, consum_mean, legv);
g.add(xaxis, "consum-median");
g.mplot(tx_factor_v, consum_median, legv);
g.add(xaxis, "consum-max");
g.mplot(tx_factor_v, consum_max, legv);
double[,] gain_mean = new double [rx_consum_v.Length, 2];
double[,] gain_median = new double [rx_consum_v.Length, 2];
double[,] gain_max = new double [rx_consum_v.Length, 2];
for (int q = 0; q < rx_consum_v.Length; q++)
for (int s = 0; s < 2; s++)
{
gain_mean[q, s] = 100 * (consum_mean[q, 2] -
consum_mean[q, s]) / consum_mean[q, 2];
gain_median[q, s] = 100 * (consum_median[q, 2] -
consum_median[q, s]) / consum_median[q, 2];
gain_max[q, s] = 100 * (consum_max[q, 2] -
consum_max[q, s]) / consum_max[q, 2];
}
string[] legv2 = new string[] {"0", "3"};
g.add(xaxis, "gain-mean");
g.mplot(tx_factor_v, gain_mean, legv2);
g.add(xaxis, "gain-median");
g.mplot(tx_factor_v, gain_median, legv2);
g.add(xaxis, "gain-max");
g.mplot(tx_factor_v, gain_max, legv2);
string filename = String.Format("{0}_{1:d2}_{2:d6}", G.current(),
tst_nr, n_averages);
g.save(filename, plot);
//Console.WriteLine("consum_mean = {0,8:F3} {1,8:F3} {2,8:F3}",
// consum_mean[0], consum_mean[1], consum_mean[2]);
//Console.WriteLine("consum_median = {0,8:F3} {1,8:F3} {2,8:F3}",
// consum_median[0], consum_median[1], consum_median[2]);
//Console.WriteLine("consum_max = {0,8:F3} {1,8:F3} {2,8:F3}",
// consum_max[0], consum_max[1], consum_max[2]);
}