How to generate random number generator in a nested loop

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Mariam Ali am 28 Jun. 2020

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https://de.mathworks.com/matlabcentral/answers/556102-how-to-generate-random-number-generator-in-a-nested-loop

Kommentiert: Mariam Ali am 28 Jun. 2020

Hi! I’m new to matlab. I’m actually taking a course on cellular network and for an assignment I need to generate random 0 and 1 for data or voice connection in a nested loop.. it is a relatively large code and I want to get it checked by someone proficient in matlab.. please help

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Rik am 28 Jun. 2020

Does there need to be a pattern in the randomness? Otherwise you can simply round the output of rand.

Mariam Ali am 28 Jun. 2020

In MATLAB Online öffnen

@henry, here is the code

% Matlab program for M/M/1 queue.
clear;
clc;
QLIMIT=3; %100;
TOTCUS=30000;
CHANNEL=10;	%total number of available channels 
NEVNTS=2;  % total number of events for data and voice 
BUSY=1;
IDLE=0;
K=20;
mu=60;   % service rate
 
for k=1:20
   
    lambda_d=k*3;    % arrival rate of data
    lambda_v=k*2;    % arrival rate of voice
y=randi([0,1]);  % Generate 0 and 1 randomly (Voice=0 and Data=1)
    
IN=0;        % total arrivals
INV=0;        % total voice arrivals
IND=0;        % total data arrivals
    
    % Initialization 
    SA=23541; SS=90458;   % rand seeds
    TIME=0.0;
    MARKEND=0;
    SERVER=IDLE;
    NIQ=0;                % Queue occupancy
    TLEVNT=0.0;           % Time of previous event
    
    NUMCUS=0;             % Total customers
    TOTDEL=0.0;           % Total delay
    DTOTDEL=0.0;           % Total delay of data connections	
    ANIQ=0.0;             % sum(Queue occupancy * time period)
    AUTIL=0.0;            % Server total utilization
    BLOCK=0;              
    
    % TNE: time of next event
    % TNE(1): time for next arrival
    % TNE(2): time for next departure
% exponentially dist. inter-arrival time
    rand('seed',SA);
    TNE(1)=TIME+(-(1./lambda_v)*log(rand));   
    SUP=rand('seed');
    
    TNE(2)=1.0e+30;           
    
    % Timing
    
    while (MARKEND == 0)
        
        MINTNE=1.0e+29;
        NEXT=0;                   % index of next event
        
     
 if(y==0) %voice arrival
        for i=1:NEVNTS			% if arrival (NEXT==1) and for departure (NEXT==2)
            if(TNE(i) < MINTNE)
                MINTNE=TNE(i);
                NEXT=i;
            end
        end
        
        
        if(NEXT == 0 )
            MARKEND=1;     % condition for ending simulation
        end
        
        TIME=MINTNE;
        
        
        
        % Updating
        
        TSLE=TIME-TLEVNT;         % time elapsed since last event
        TLEVNT=TIME;
        
        ANIQ=ANIQ+NIQ*TSLE;
        
        AUTIL=AUTIL+SERVER*TSLE;
        
    
        
        if (NEXT==1)
            
            % Arrival process for voice
            IN=IN+1;
            INV=INV+1;
	
           
 % update next arrival time
            rand('seed',SA);      
            TNE(1)=TIME+(-(1./lambda_v)*log(rand)); %interarrival time 
            SA=rand('seed');
            
            if(SERVER == BUSY)
                if(CHANNEL==0 && NIQ >= QLIMIT)  % blocked
                    BLOCK=BLOCK+1;
                elseif(CHANNEL==0 && NIQ<QLIMIT)
		NIQ=NIQ+1;              % queued
		TARRVL(NIQ)=TIME;       % record arrival time
		else 			%customer moves directly to channel  		
                CHANNEL=CHANNEL-1; 
		TARRVL(NIQ)=TIME;       % record arrival time
 
                end
                
            else                            % arrival incase the server is idle (no connection in system) 
                NUMCUS=NUMCUS+1;
                CHANNEL=CHANNEL-1;
                SERVER=BUSY;
                
                rand('seed',SS);
                TNE(2)=TIME+(-(1./mu)*log(rand));   % schedule departure time
                SS=rand('seed');
                
            end
            
        elseif(NEXT==2)
            
            % Departure process
            if(CHANNEL==10)					%all 10 channels are available 
                SERVER=IDLE;
                TNE(2)=1.0e+30;
            elseif((0<CHANNEL)&&(CHANNEL<10))                             % channel is partially occupied  
                SERVER=BUSY;	
		CHANNEL=CHANNEL+1;
		DELAY=TIME-TARRVL(1); 
		TOTDEL=TOTDEL+DELAY;
		NUMCUS=NUMCUS+1;
                rand('seed',SS);
                TNE(2)=TIME+(-(1./mu)*log(rand));
                SS=rand('seed');					
            else   					
                SERVER=BUSY;
		NIQ=NIQ-1;
		DELAY=TIME-TARRVL(1); 
                TOTDEL=TOTDEL+DELAY;
                
                NUMCUS=NUMCUS+1;
                rand('seed',SS);
                TNE(2)=TIME+(-(1./mu)*log(rand));
                SS=rand('seed');
                
                % queued customers moved one position toward head of queue
                for i=1:NIQ
                    TARRVL(i)=TARRVL(i+1);   
                end
            end
          end     
 
        % remove effect of initial conditions
        if (NUMCUS==3000)
            TIME1=TIME;
            TOTDEL=0;
            ANIQ=0;
            AUTIL=0;
            BLOCK=0;
            NUMCUS1=NUMCUS;
            IN=0;
        elseif (NUMCUS > TOTCUS)
            MARKEND=1;
        end  
        
     
  
 elseif(y==1) %data arrival will use 2 channels, available channels=10
% exponentially dist. inter-arrival time
    rand('seed',SA);
    TNE(1)=TIME+(-(1./lambda_d)*log(rand));   
    SUP=rand('seed');
    
    TNE(2)=1.0e+30;           
    
    % Timing
    MINTNE=1.0e+29;     
     
        for i=1:NEVNTS			
            if(TNE(i) < MINTNE)
                MINTNE=TNE(i);
                NEXT=i;
            end
        end
        
        
        if(NEXT == 0 )
            MARKEND=1;     % condition for ending simulation
        end
        
        TIME=MINTNE;
        
        
        
        % Updating
        
        TSLE=TIME-TLEVNT;         % time elapsed since last event
        TLEVNT=TIME;
        
        ANIQ=ANIQ+NIQ*TSLE;
        
        AUTIL=AUTIL+SERVER*TSLE;
        
    
        
        if (NEXT==1)
            
            % Arrival process for data
            IN=IN+1;
            IND=IND+1;
	
           
 % update next arrival time
            rand('seed',SA);      
            TNE(1)=TIME+(-(1./lambda_d)*log(rand));
            SA=rand('seed');
            
            if(SERVER == BUSY)
                if(CHANNEL<2 && NIQ >= QLIMIT)  % blocked
                    BLOCK=BLOCK+1;
                elseif(CHANNEL<2 && NIQ<QLIMIT) 
		NIQ=NIQ+1;              % queued
		TARRVL(NIQ)=TIME;       % record arrival time
		else 			%customer moves to channel  		
                 CHANNEL=CHANNEL-2;  
                end
                
            else                            % in service
                NUMCUS=NUMCUS+1;
                SERVER=BUSY;
                
                rand('seed',SS);
                TNE(2)=TIME+(-(1./mu)*log(rand));   % schedule departure time
                SS=rand('seed');
                
            end
            
        elseif(NEXT==2)
            
            % Departure process
            if(CHANNEL==10)					% all channels are available 
                SERVER=IDLE;
                TNE(2)=1.0e+30;
            elseif((1<CHANNEL) && (CHANNEL<9)) % channel is partially occupied 
                SERVER=BUSY;	
		CHANNEL=CHANNEL+2;
		DELAY=TIME-TARRVL(1); 
                DTOTDEL=DTOTDEL+DELAY;
                
                NUMCUS=NUMCUS+1;
                rand('seed',SS);
                TNE(2)=TIME+(-(1./mu)*log(rand));
                SS=rand('seed');					
            else   						%customer in both queue and channel 
                SERVER=BUSY;
		NIQ=NIQ-1;
		DELAY=TIME-TARRVL(1); 
                DTOTDEL=DTOTDEL+DELAY;
                
                NUMCUS=NUMCUS+1;
                rand('seed',SS);
                TNE(2)=TIME+(-(1./mu)*log(rand));
                SS=rand('seed');
                
                % queued customers moved one position toward head of queue
                for i=1:NIQ
                    TARRVL(i)=TARRVL(i+1);   
                end
            end
          end  
       end   
 
        % remove effect of initial conditions
        if (NUMCUS==300)
            TIME1=TIME;
            TOTDEL=0;
	    DTOTDEL=0;
            ANIQ=0;
            AUTIL=0;
            BLOCK=0;
            NUMCUS1=NUMCUS;
            IN=0;
        elseif (NUMCUS > TOTCUS)
            MARKEND=1;
        end  
        
        
    end     % end of while(MARKEND==0)
  %Report
    
    AVGDEL=DTOTDEL/(NUMCUS-NUMCUS1);                % average delay of data connections
    AVGNIQ(k)=ANIQ/(TIME-TIME1);                      % average queue length
    UTIL(k)=AUTIL/(TIME-TIME1);                       % server utilization
    PBV=BLOCK/INV;                                   % blocking rate of voice
    PBD=BLOCK/IND;					% blocking rate of data
 
    rho_d(k)=lambda_d/mu; 
    rho_v(k)=lambda_v/mu;                         
    Pb_d(k)=(1-rho_d(k)).*rho_d(k).^(QLIMIT+1)/(1-rho_d(k).^(QLIMIT+2));  % theoretical data blocking prob.
    Pb_v(k)=(1-rho_v(k)).*rho_v(k).^(QLIMIT+1)/(1-rho_v(k).^(QLIMIT+2));  % theoretical voice blocking prob.
   
end     %end of k
k=1:TOTCUS;
    lambda_d=k*3;   
    lambda_v=k*2;
figure(1)
plot(lambda_v,Pb_v(k),'-')
hold;
xlabel('lambda_V');
ylabel('Voice Blocking probability');
figure(2)
plot(lambda_d,Pb_v(k),'--')
hold;
xlabel('lambda_D');
ylabel('Data Blocking probability');
figure(3)
plot(lambda_v,AVGDEL,'-')
hold;
xlabel('lambda_V');
ylabel('Mean Delay of Data Connection');
figure(4)
plot(lambda_d,AVGDEL,'--')
hold;
xlabel('lambda_D');
ylabel('Mean Delay of Data Connection');
It goes on for  a long time and generates no result 