Exemplo n.º 1
0
int main( int argc, char* argv[])
{
  //Arg initial here
  int Number_of_bits = 2048;

  //Declarations basic
  int i;
  double Ps, N0, dist_1, dist_2, h1, h2, Eb;
  double EbN0;
  double rcvd_power_1, rcvd_power_2;
  int nFFT, nCylicPrefix;

  //Read arg Simple
  if( argc == 4) {
    Number_of_bits = atoi( argv[1]);
    dist_1 = strtod(argv[2], NULL);
    dist_2 = strtod(argv[3], NULL);
  }

  //Declare vectors and others
  vec alpha;                                            //vec is a vector containing double
  vec bit_error_rate_1, bit_error_rate_2;
  vec ber_theo_1, ber_theo_2;                           // Theoretical results for multiple access

  bvec transmitted_bits_1, transmitted_bits_2;          //bvec is a vector containing bits
  bvec received_bits_1, received_bits_2;

  cvec transmitted_symbols_1, transmitted_symbols_2, transmitted_symbols; //cvec is a vector containing double_complex
  cvec received_symbols_1, received_symbols_2, feedback_symbols_1, feedback_symbols_2;
  cvec ofdm_symbols_1, ofdm_symbols_2;

  // Declarations of classes:
  QPSK mod;                     //The QPSK modulator class
  QAM qammod(16);                 //QAM-16
  //QAM mod(64);                 //   -64
  AWGN_Channel awgn_channel;     //The AWGN channel class
  it_file ff;                    //For saving the results to file
  BERC berc;                     //Used to count the bit errors
  Real_Timer tt;                 //The timer used to measure the execution time
  OFDM ofdm;                     //OFDM modulator class

  MA_Filter<std::complex<double>, std::complex<double>, std::complex<double> > multipath_channel; //Simulate multi-path enviornment
  int ch_nb_taps = 3;
  cvec ini_state = to_cvec( zeros(ch_nb_taps));
  vec ch_imp_response_real = "1.000000000000000 0.436232649307735 0.198694326007661";//randray( ch_nb_taps);
  ch_imp_response_real /= sqrt(sum_sqr( ch_imp_response_real));//normalized power profile
  cvec ch_imp_response = to_cvec( ch_imp_response_real);
  multipath_channel.set_coeffs( ch_imp_response);
  multipath_channel.set_state(ini_state);//inital state is zero

  //Reset and start the timer:
  tt.tic();

  //Init:
  //Ps = 5 * pow(10, -3);          //The transmitted energy per mod symbol is 1, 5e-3 W/MHz 802.11
  Ps = 4 * pow(10, 0.0);         //ETSI TS 136 104 V9.4.0 (2010-07) p17 LTE JAPAN 4 W/MHz  
  //Ps = 4 * pow(10, 1.0);         //max 46 dbm
  N0 = 4 * pow(10, -15);         //Thermal noise -144dBm/MHz
  //dist_1 = 800;                   //Distance form transmitter to receiver 1 (meter)
  //dist_2 = 1000;                  //                   *                  2
  double f = 2600; // Mhz 150-1500
  double hM = 2; // meter 1-10
  double hb = 120; // meter 30-200
  double C_H = 0.8 + (1.1 * log10(f) - 0.7) * hM - 1.56 * log10(f); // Hata medium size city
  double h1dB = 69.55 + 26.16 * log10(f) - 13.82*log10(hb) - C_H + (44.9 - 6.55*log10(hb)) * log10(dist_1/1000);
  double h2dB = 69.55 + 26.16 * log10(f) - 13.82*log10(hb) - C_H + (44.9 - 6.55*log10(hb)) * log10(dist_2/1000);
  //cout << "HatadB:" << h1dB << endl;
  //cout << "HatadB:" << h2dB << endl;
  
  //h1 = pow(10, -h1dB/10);
  //h2 = pow(10, -h2dB/10);
  h1 = pow(dist_1, -4.5);        //Channel gain for receiver 1
  h2 = pow(dist_2, -4.5);        //
  cout << "h1 = " << h1 << " h2 = " << h2 << endl;
  alpha = linspace(0.3, 0.0, 13);//Simulate for different weight on power
  nFFT = 2048;                   //FFT size, default is 2048 LTE-a
  nCylicPrefix = 144;            //Length of Prefix, standard 144 (first prefix is different in real case)

  // test upconv
  cvec ocsi;
  cvec t_spanned;
  double unit_time = 3.25520833 * pow(10,-8); // 1/(2048*15k)
  const double pi = 3.1415926535897;
  const std::complex<double> unit_img (0.0,1.0);
  double fc = 2.6 * pow(10,9); // 2.6GHz
  t_spanned.set_size(2048, false);
  for (int i = 0; i < 2048; i++) {
    t_spanned[i] = exp(2*pi*fc*unit_time*i*unit_img);
  }

  // Declarations for equalizer & NSC coding
  ivec gen = "07 05";                                          //octal notation
  int constraint_length = 3;                                   //constraint length
  int blockSize = 13;//permutation length                //encoder output block size
  // other parameters
  int nb_bits_tail = blockSize / gen.length();                  //encoder input size + tail size
  int nb_bits = nb_bits_tail - (constraint_length - 1);        //encoder block size
  int nb_blocks;                                               //number of blocks
  // Convolutional code
  Convolutional_Code nsc;
  nsc.set_generator_polynomials(gen, constraint_length);

  //Allocate storage space for the result vector.
  //The "false" argument means "Do not copy the old content of the vector to the new storage area."
  bit_error_rate_1.set_size(alpha.length(), false);
  bit_error_rate_2.set_size(alpha.length(), false);

  //Storage for theoretical ber
  ber_theo_1.set_size(alpha.length(), false);
  ber_theo_2.set_size(alpha.length(), false);

  //Randomize the random number generators in it++:
  RNG_randomize();

  //Set OFDM parameters
  ofdm.set_parameters(nFFT, nCylicPrefix);

  //Iterate over all EbN0dB values:
  for (i = 0; i < alpha.length(); i++) {

    //Show how the simulation progresses:
    //cout << "Now simulating alpha value = " << alpha(i); 
    //cout << " # " << i + 1 << "/" << alpha.length() << endl;

    //Generate a vector of random bits to transmit:
    transmitted_bits_1 = randb(Number_of_bits*2);
    transmitted_bits_2 = randb(Number_of_bits);

    //convolutional code encode
    //bvec out_binary_1 = encode(nsc, constraint_length, transmitted_bits_1, blockSize, false);
    //bvec out_binary_2 = encode(nsc, constraint_length, transmitted_bits_2, blockSize, false);
    bvec out_binary_1 = transmitted_bits_1;
    bvec out_binary_2 = transmitted_bits_2;

    //Modulate the bits to mod symbols:
    transmitted_symbols_1 = qammod.modulate_bits(out_binary_1);
    transmitted_symbols_2 = mod.modulate_bits(out_binary_2);

    //Multiplex two signals
    transmitted_symbols = transmitted_symbols_1 * pow(alpha(i), 0.5) + transmitted_symbols_2 * pow(1 - alpha(i), 0.5);
    transmitted_symbols = transmitted_symbols * pow(Ps, 0.5);
    //eval_avg_power(transmitted_symbols);

    //Fading
    transmitted_symbols_1 = transmitted_symbols * pow(h1, 0.5);
    transmitted_symbols_2 = transmitted_symbols * pow(h2, 0.5);

    //OFDM modulate
    zero_pad_back(transmitted_symbols_1, 2048);
    zero_pad_back(transmitted_symbols_2, 2048);
    ofdm.modulate(transmitted_symbols_1, ofdm_symbols_1);
    ofdm.modulate(transmitted_symbols_2, ofdm_symbols_2);

    //Set the noise variance of the AWGN channel:
    //ofdm_symbols_1 = concat(ofdm_symbols_1, zeros_c(2)); //B
    //ofdm_symbols_2 = concat(ofdm_symbols_2, zeros_c(2)); //B
    //ofdm_symbols_1 = concat(ofdm_symbols_1, zeros_c(4));   //A
    //ofdm_symbols_2 = concat(ofdm_symbols_2, zeros_c(4));   //A
    //cout << "N0: " << N0 << endl;
    awgn_channel.set_noise(N0);

    //Up-conversion

    //Run the transmited symbols through the channel using the () operator:
    //ofdm_symbols_1 = awgn_channel( multipath_channel( ofdm_symbols_1));
    //ofdm_symbols_2 = awgn_channel( multipath_channel( ofdm_symbols_2));
    ofdm_symbols_1 = awgn_channel( ofdm_symbols_1);
    ofdm_symbols_2 = awgn_channel( ofdm_symbols_2);
    //ofdm_symbols_1 = ofdm_symbols_1.get(0, ofdm_symbols_1.length()-3);    //B
    //ofdm_symbols_2 = ofdm_symbols_2.get(0, ofdm_symbols_2.length()-3);    //B

    // test zone!! KEEP OUT!! //A
    /*cvec ofdm_symbols_eqed_tmp;
    mmse_equalizer_simple(ofdm_symbols_1, ofdm_symbols_eqed_tmp, ch_imp_response_real, N0, false);
    ofdm_symbols_1 = ofdm_symbols_eqed_tmp;
    mmse_equalizer_simple(ofdm_symbols_2, ofdm_symbols_eqed_tmp, ch_imp_response_real, N0, false);
    ofdm_symbols_2 = ofdm_symbols_eqed_tmp;*/

    //alpha no greater than 0.5
    //OFDM demodulate
    ofdm.demodulate(ofdm_symbols_1, received_symbols_1);
    ofdm.demodulate(ofdm_symbols_2, received_symbols_2);
    //cvec FDMtmp;                                                          //B
    //FDE(received_symbols_1, FDMtmp, ch_imp_response_real, 2048, false);   //B
    //ofdm_symbols_1 = FDMtmp;                                              //B
    //FDE(received_symbols_2, FDMtmp, ch_imp_response_real, 2048, false);   //B
    //ofdm_symbols_2 = FDMtmp;                                              //B

    //Demodulate the received mod symbols into received bits: Layer 1
    received_bits_2 = mod.demodulate_bits(received_symbols_2 / pow(1-alpha(i), 0.5) / pow(Ps, 0.5) / pow(h2, 0.5));
    //bvec out_binary_recover_2 = decode(nsc, constraint_length, received_bits_2, blockSize, false);
    bvec out_binary_recover_2 = received_bits_2;
    
    //Demodulate the received mod symbols into received bits: Layer 2
    received_bits_1 = mod.demodulate_bits(received_symbols_1 / pow(1-alpha(i), 0.5) / pow(Ps, 0.5) / pow(h1, 0.5));
    feedback_symbols_2 = pow(Ps * (1-alpha(i)) * h1, 0.5) * mod.modulate_bits(received_bits_1);
    received_bits_1 = qammod.demodulate_bits((received_symbols_1-feedback_symbols_2) / pow(alpha(i), 0.5) / pow(Ps, 0.5) / pow(h1, 0.5));
    //bvec out_binary_recover_1 = decode(nsc, constraint_length, received_bits_1, blockSize, false);
    bvec out_binary_recover_1 = received_bits_1;

    //Calculate the bit error rate:
    berc.clear();                               //Clear the bit error rate counter
    berc.count(transmitted_bits_2, out_binary_recover_2.get(0, Number_of_bits)); //Count the bit errors
    bit_error_rate_2(i) = berc.get_errorrate();   //Save the estimated BER in the result vector

    berc.clear();
    berc.count(transmitted_bits_1, out_binary_recover_1.get(0, Number_of_bits));
    bit_error_rate_1(i) = berc.get_errorrate();
  }

  tt.toc();

  // Theoretical results for multiple access
  for (size_t i = 0; i < alpha.length(); ++i) {        //BER for theo 1
    EbN0 = (Ps * 0.5 * h1 * alpha(i)) / (N0 + Ps * 0.5 * h1 * (1 - alpha(i)));
    ber_theo_1(i) = 0.5*erfc(pow(EbN0, 0.5));
  }
  for (size_t i = 0; i < alpha.length(); ++i) {        //BER for theo 2
    EbN0 = (Ps * 0.5 * h2 * (1-alpha(i))) / N0;
    ber_theo_2(i) = 0.5*erfc(pow(EbN0, 0.5));
  }

  //Print the results:
  cout << endl;
  time_t rawtime;
  time (&rawtime);
  std::string nowTime( ctime( &rawtime));
  /*cout << nowTime << endl;
  cout << "alpha = " << alpha << " " << endl;
  cout << "BER 1 = " << bit_error_rate_1 << endl;
  cout << "BER 2 = " << bit_error_rate_2 << endl;
  cout << "Theoretical BER 1 = " << ber_theo_1 << endl;
  cout << "Theoretical BER 2 = " << ber_theo_2 << endl;
  cout << endl;*/
  
  //Chech feasibility
  bool feasibility = false;
  double threshold = 0.01;
  for (size_t i = 1; i < alpha.length(); i++) {
    if (bit_error_rate_1(i) < threshold && bit_error_rate_2(i) < threshold) {
      feasibility = true;
    }
  }
  if (feasibility) {
    cout << "  PASS  " << endl;
  }

  //Save the results to file:
  const char xFilename[] = "result";
  char oFilename[100];
  int fileIndex = 0;
  strcpy( oFilename, xFilename);
  while(std::ifstream( oFilename)){
    ++fileIndex;
    sprintf( oFilename, "%s%d", xFilename, fileIndex);
  }
  cout << "Saving results to " << oFilename << endl;
  std::ofstream oo;
  oo.open(oFilename);
    oo << alpha << endl;
    oo << bit_error_rate_1 << endl;
    oo << bit_error_rate_2 << endl;
  oo.close();

  //Exit program:
  return 0;

}
Exemplo n.º 2
0
int main()
{
  //Declarations of scalars and vectors:
  int i, Number_of_bits;
  double Ps, N0, dist_1, dist_2, h1, h2, Eb;
  double EbN0;
  double rcvd_power_1, rcvd_power_2;

  vec alpha;                                            //vec is a vector containing double
  vec bit_error_rate_1, bit_error_rate_2;
  vec ber_theo_1, ber_theo_2;                           // Theoretical results for multiple access

  bvec transmitted_bits_1, transmitted_bits_2;          //bvec is a vector containing bits
  bvec received_bits_1, received_bits_2;

  cvec transmitted_symbols_1, transmitted_symbols_2, transmitted_symbols; //cvec is a vector containing double_complex
  cvec received_symbols_1, received_symbols_2, feedback_symbols_1;

  //Declarations of classes:
  QPSK qpsk;                     //The QPSK modulator class
  QAM qam16(16);
  QAM qam64(64);
  AWGN_Channel awgn_channel;     //The AWGN channel class
  it_file ff;                    //For saving the results to file
  BERC berc;                     //Used to count the bit errors
  Real_Timer tt;                 //The timer used to measure the execution time

  //Reset and start the timer:
  tt.tic();

  //Init:
  Ps = 5 * pow(10, -3);          //The transmitted energy per QPSK symbol is 1, 5e-3 W/MHz
  N0 = 4 * pow(10, -15);         //Thermal noise -144dBm/MHz
  dist_1 = 150;                  //Distance form transmitter to receiver 1 (meter)
  dist_2 = 220;                  //                   *                  2
  h1 = pow(dist_1, -4.5);        //Channel gain for receiver 1
  h2 = pow(dist_2, -4.5);        //
  cout << "h1 = " << h1 << " h2 = " << h2 << endl;
  alpha = linspace(1.0, 0.0, 21);//Simulate for different weight on power

//  Eb = Ec / 2.0;                 //The transmitted energy per bit is 0.5.
//  EbN0dB = linspace(0.0, 9.0, 10); //Simulate for 10 Eb/N0 values from 0 to 9 dB.
//  EbN0 = inv_dB(EbN0dB);         //Calculate Eb/N0 in a linear scale instead of dB.
//  N0 = Eb * pow(EbN0, -1.0);     //N0 is the variance of the (complex valued) noise.
  Number_of_bits = 1000000;       //One hundred thousand bits is transmitted for each Eb/N0 value
//  alpha = 0.8;                   //Ratio of allocated power

  //Allocate storage space for the result vector.
  //The "false" argument means "Do not copy the old content of the vector to the new storage area."
  bit_error_rate_1.set_size(alpha.length(), false);
  bit_error_rate_2.set_size(alpha.length(), false);

  //Storage for theoretical ber
  ber_theo_1.set_size(alpha.length(), false);
  ber_theo_2.set_size(alpha.length(), false);

  //Randomize the random number generators in it++:
  RNG_randomize();

  //Iterate over all EbN0dB values:
  for (i = 0; i < alpha.length(); i++) {

    //Show how the simulation progresses:
    cout << "Now simulating alpha value = " << alpha(i); 
    cout << " # " << i + 1 << "/" << alpha.length() << endl;

    //Generate a vector of random bits to transmit:
    transmitted_bits_1 = randb(Number_of_bits*2);
    transmitted_bits_2 = randb(Number_of_bits);

    //Modulate the bits to QPSK symbols:
    transmitted_symbols_1 = qam16.modulate_bits(transmitted_bits_1);
    transmitted_symbols_2 = qpsk.modulate_bits(transmitted_bits_2);

    //Multiplex two signals
    transmitted_symbols = transmitted_symbols_1 * pow(alpha(i), 0.5) + transmitted_symbols_2 * pow(1 - alpha(i), 0.5);
    transmitted_symbols = transmitted_symbols * pow(Ps, 0.5);
    //eval_avg_power(transmitted_symbols);

    //Fading
    transmitted_symbols_1 = transmitted_symbols * pow(h1, 0.5);
    transmitted_symbols_2 = transmitted_symbols * pow(h2, 0.5);

    //Set the noise variance of the AWGN channel:
    awgn_channel.set_noise(N0);

    //Run the transmited symbols through the channel using the () operator:
    received_symbols_1 = awgn_channel(transmitted_symbols_1);
    received_symbols_2 = awgn_channel(transmitted_symbols_2);

    //Demodulate the received QPSK symbols into received bits: Layer 1
    received_bits_1 = qam16.demodulate_bits(received_symbols_1 * pow(Ps * alpha(i) * h1, -0.5));

    //Demodulate the received QPSK symbols into received bits: Layer 2
    received_bits_2 = qam16.demodulate_bits(received_symbols_2 * pow(Ps * alpha(i) * h2, -0.5));
    feedback_symbols_1 = pow(Ps * alpha(i) * h2, 0.5) * qam16.modulate_bits(received_bits_2);
    received_bits_2 = qpsk.demodulate_bits(received_symbols_2 - feedback_symbols_1);

    //Calculate the bit error rate:
    berc.clear();                               //Clear the bit error rate counter
    berc.count(transmitted_bits_1, received_bits_1); //Count the bit errors
    bit_error_rate_1(i) = berc.get_errorrate();   //Save the estimated BER in the result vector

    berc.clear();
    berc.count(transmitted_bits_2, received_bits_2);
    bit_error_rate_2(i) = berc.get_errorrate();
  }

  tt.toc();

  // Theoretical results for multiple access
  for (size_t i = 0; i < alpha.length(); ++i) {        //BER for theo 1
    EbN0 = (Ps * 0.5 * h1 * alpha(i)) / (N0 + Ps * 0.5 * h1 * (1 - alpha(i)));
    ber_theo_1(i) = 0.5*erfc(pow(EbN0, 0.5));
  }
  for (size_t i = 0; i < alpha.length(); ++i) {        //BER for theo 2
    EbN0 = (Ps * 0.5 * h2 * (1-alpha(i))) / N0;
    ber_theo_2(i) = 0.5*erfc(pow(EbN0, 0.5));
  }

  //Print the results:
  cout << endl;
  cout << "alpha = " << alpha << " " << endl;
  cout << "BER 1 = " << bit_error_rate_1 << endl;
  cout << "BER 2 = " << bit_error_rate_2 << endl;
  cout << "Theoretical BER 1 = " << ber_theo_1 << endl;
  cout << "Theoretical BER 2 = " << ber_theo_2 << endl;
  cout << "Saving results to ./qam16_result_file.it" << endl;
  cout << endl;

  //Save the results to file:
  std::ofstream oo;
  oo.open("qam16_result_file.it");
  oo << alpha;
  oo << bit_error_rate_1;
  oo << bit_error_rate_2;
  ff.close();

  //Exit program:
  return 0;

}