OFDM with MIMO Simulation
This example shows how to use an OFDM modulator and demodulator in a simple, 2x2 MIMO error rate simulation. The OFDM parameters are based on the 802.11n standard.
Create a QPSK modulator and demodulator pair.
qpskMod = comm.QPSKModulator; qpskDemod = comm.QPSKDemodulator;
Create an OFDM modulator and demodulator pair with user-specified pilot indices, an inserted DC null, two transmit antennas, and two receive antennas. Specify pilot indices that vary across antennas.
ofdmMod = comm.OFDMModulator('FFTLength',128,'PilotInputPort',true,... 'PilotCarrierIndices',cat(3,[12; 40; 54; 76; 90; 118],... [13; 39; 55; 75; 91; 117]),'InsertDCNull',true,... 'NumTransmitAntennas',2); ofdmDemod = comm.OFDMDemodulator(ofdmMod); ofdmDemod.NumReceiveAntennas = 2;
Show the resource mapping of pilot subcarriers for each transmit antenna. The gray lines in the figure denote the insertion of null subcarriers to minimize pilot signal interference.
showResourceMapping(ofdmMod)
Determine the dimensions of the OFDM modulator by using the info method.
ofdmModDim = info(ofdmMod); numData = ofdmModDim.DataInputSize(1); % Number of data subcarriers numSym = ofdmModDim.DataInputSize(2); % Number of OFDM symbols numTxAnt = ofdmModDim.DataInputSize(3); % Number of transmit antennas
Generate data symbols to fill 100 OFDM frames.
nframes = 100; data = randi([0 3],nframes*numData,numSym,numTxAnt);
Apply QPSK modulation to the random symbols and reshape the resulting column vector to match the OFDM modulator requirements.
modData = qpskMod(data(:)); modData = reshape(modData,nframes*numData,numSym,numTxAnt);
Create an error rate counter.
errorRate = comm.ErrorRate;
Simulate the OFDM system over 100 frames assuming a flat, 2x2, Rayleigh fading channel. Remove the effects of multipath fading using a simple, least squares solution, and demodulate the OFDM waveform and QPSK data. Generate error statistics by comparing the original data with the demodulated data.
for k = 1:nframes % Find row indices for kth OFDM frame indData = (k-1)*ofdmModDim.DataInputSize(1)+1:k*numData; % Generate random OFDM pilot symbols pilotData = complex(rand(ofdmModDim.PilotInputSize), ... rand(ofdmModDim.PilotInputSize)); % Modulate QPSK symbols using OFDM dataOFDM = ofdmMod(modData(indData,:,:),pilotData); % Create flat, i.i.d., Rayleigh fading channel chGain = complex(randn(2,2),randn(2,2))/sqrt(2); % Random 2x2 channel % Pass OFDM signal through Rayleigh and AWGN channels receivedSignal = awgn(dataOFDM*chGain,30); % Apply least squares solution to remove effects of fading channel rxSigMF = chGain.' \ receivedSignal.'; % Demodulate OFDM data receivedOFDMData = ofdmDemod(rxSigMF.'); % Demodulate QPSK data receivedData = qpskDemod(receivedOFDMData(:)); % Compute error statistics dataTmp = data(indData,:,:); errors = errorRate(dataTmp(:),receivedData); end
Display the error statistics.
fprintf('\nSymbol error rate = %d from %d errors in %d symbols\n',errors)Symbol error rate = 9.471154e-02 from 1970 errors in 20800 symbols