Data transmission from node to a gateway

Question

Syed Fahad Hassan 2017년 11월 30일

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https://kr.mathworks.com/matlabcentral/answers/370167-data-transmission-from-node-to-a-gateway

댓글: Walter Roberson 2020년 12월 31일

Hi,

I am creating a wireless sensor network in Matlab in which nodes transmit information to the central gateway which then processes this information for analysis. I want to know

How can I code this transmission in which a node transmits some amount of data to the gateway (say 1000kB at 250kBps) and gateway receives that transmission?
The transmission should also be timed such that the delay experienced by rest of the nodes while in queue is calculated.

Thanks in advance for any suggestions and help.

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Answer 1

Deepanshu Udhwani 2017년 11월 30일

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https://kr.mathworks.com/matlabcentral/answers/370167-data-transmission-from-node-to-a-gateway#answer_293910

편집: Walter Roberson 2017년 11월 30일

MATLAB Online에서 열기

e:\Bisection.txt
************************************************************************
clc;
clear all;
a=input('Initial point ');
b=input('Final Point ');
c=(a+b)/2;
f=@(x) x^3+4*(x^2)-10;
E=0.001;
ceil(n=(log(b-a)-log(E))/log(2))
while(abs(a-b)>E)
  if f(a)*f(c)<0
    b=c;
  else
  a=c;
end;
c=(a+b)/2;
end;
c
e:\Fixed_Point_Iteration.txt
************************************************************************
clc;
clear all;
a=input("a");
b=input('b');
%x0=(a+b)/2;
x0=1;
E=0.001;
N=ceil((log(b-a)-log(E))/(log(2)));
i=1;
g=@(x) x-((2*sin(3.14*x)+x)/(1+(2*3.14*cos(3.14*x))));  %Newton Method to find g(x);
while i<=N
  xx=g(x0);
if(abs(xx-x0)<E)
  break;
end;
  x0=xx;i=i+1;
end;
xx  
e:\Guass_Elimination.txt
************************************************************************
clc;
clear all;
n=input('N: ');
for i=1:n
  for j=1:n+1
    A(i,j)=input('Enter element');
  end;
end;
for i=1:n-1
  for j=i+1:n
    m=A(j,i)/A(i,i);
    for k=1:n+1
      A(j,k)=A(j,k)-m*A(i,k);
    end;
  end;
end;
X(n)=A(n,n+1)/A(n,n);
for i=(n-1):-1:1
  sum=0;
  for j=i+1:n
    sum=sum+(A(i,j)*X(j));
  end;
  X(i)=(A(i,n+1)-sum)/A(i,i);
end;
A
X
e:\GuassSeidal.txt
************************************************************************
clc;
clear all;
n=input('N ');
E=0.0001;
for i=1:n
  for j=1:n+1
    A(i,j)=input('Enter element');
  end;
end;
for i=1:n
  X(i)=0;
  Xold(i)=0;
end;
sum=0;
normval=2;
while abs(normval)>E
  Xold=X;
for i=1:n
  for j=1:n
    if j!=i
      sum=sum+A(i,j)*X(j);
    end;
   end; 
  X(i)=(A(i,n+1)-sum)/A(i,i);
  sum=0;
end;
normval=norm(Xold-X,inf);
end;
X
e:\Lagrange_Interpolation.txt
************************************************************************
% Q3
clc;
clear all;
n=input('N: ');
f=@(x) exp(2*x)*cos(3*x);
for i=1:n
  X(i)=input('Enter X: ');
  %Y(i)=input('Enter Y: ');
  Y(i)=f(X(i));
  l(i)=1;
end;
p=input('Enter the value of X where value is to be calculated');
for i=1:n
  for j=1:n
    if i!=j
      l(i)=((p-X(j))/(X(i)-X(j)))*l(i);
    end;
  end;
end;
sum=0;
for i=1:n
  sum=sum+l(i)*Y(i);
end;
sum
e:\Newton.txt
************************************************************************
clc;
clear all;
a=input('a ');
E=0.0001;
f=@(x) cos(x)-(x*exp(x));
g=@(x) -sin(x)-(x*exp(x)+exp(x));
while(true)
  b=a-(f(a)/g(a));
if(abs(b-a)<=E)
  break;
end;
a=b;
end;
b
e:\Newton_Divided_Difference_Interpolation.txt
************************************************************************
clc;
clear all;
n=input('N ');
p=input('p ');
for i=1:n
  X(i)=input('X');
  Y(i)=input('Y');
end;
for i=1:n
  F(1,i)=Y(i);
end;
for i=2:n
  for j=i:n
    F(i,j)=(F(i-1,j)-F(i-1,j-1))/(X(j)-X(j-i+1));
  end;
end;
for i=1:n
  product(i)=1;
  for j=1:(i-1)
    product(i)=product(i)*(p-X(j));
  end;
end;
F=transpose(F);
sum=0;
for i=1:n
  sum=sum+F(i,i)*product(i);
end;
sum
e:\Power_Method.txt
************************************************************************
clc;
clear all;
n=input('N: ');
E=0.001;
for i=1:n
  for j=1:n
    A(i,j)=input('Enter Element');
  end;
end;
for i=1:n
  X(i)=input('Element');
end;
X=transpose(X);
Y=A*X;
K=norm(Y,inf);
Kdash=100;
X=(1/K)*Y;
while abs(K-Kdash) >E
  Y=A*X;
  Kdash=K;
  K=norm(Y,inf);  
  X=(1/K)*Y;
end;
K
X
e:\RungeKutta.txt
************************************************************************
clc;
clear all;
a=input('a ');
b=input('b ');
h=input('h ');
n=(b-a)/h;
f=@(t,y) -y+(2*cos(t));
t0=0;y0=1;
for i=1:n
  k1=h*f(t0,y0);
  k2=h*f((t0+(h/2)),(y0+(k1/2)));
  k3=h*(f((t0+(h/2)),(y0+(k2/2))));
  k4=h*(f(t0+h,y0+k3));
  y1=y0+(1/6)*(k1+2*k2+2*k3+k4);
  y0=y1;
  t0=t0+h;
end;
y1
e:\Secant.txt
************************************************************************
clc;
clear all;
a=input('a ');
b=input('b ');
c=0;
E=0.0001;
f=@(x) x^2-17;
while(abs(b-a)>E)
  c=b-((b-a)/(f(b)-f(a)))*f(b);
  if(f(c)==0)
    break;
  end;
    a=b;
    b=c;
  end;
  b
e:\Simpson.txt
************************************************************************
clc;
clear all;
a=input('a ');
b=input('b ');
N=input('N ');
h=(b-a)/N;
f=@(x) 1/(x*log(x));
sum=0;
for i=1:N-1
  x=a+(i*h);
  if i%2==0
  sum=sum+(2*f(x));
  else
  sum=sum+(4*f(x));
end;
sum=(sum+f(a)+f(b));
end;
sum*(h/3)
e:\Trepozoidal.txt
************************************************************************
clc;
clear all;
a=input('a ');
b=input('b ');
N=input('N ');
h=(b-a)/N;
f=@(x) cos(x)*cos(x);
sum=0;
I=0;
for i=1:N-1 
  x=a+(i*h);
  sum=sum+(2*f(x));
  % Sum starts as Sigma i=1 to N-1 because f(a) and f(b) are adjusted later
end;
sum=sum+(f(a)+f(b));
sum*(h/2)
% I= h/2 * ( f(a) +f(b) ) + h*( sigma i=1 to N-1 f(a+h*i) )