This example shows how to implement a practical IEEE 802.15.4 PHY receiver decoding OQPSK waveforms that may have been received from wireless radios, using the Communications System Toolbox™ Library for the ZigBee® Protocol. This practical receiver has decoded standard-compliant waveforms received from commercial ZigBee radios enabling home automation in the 2.4 GHz band, using a USRP® B200-mini radio and the Communications System Toolbox Support Package for USRP® radio.
The IEEE® 802.15.4 standard specifies the MAC and PHY layers of Low-Rate Wireless Personal Area Networks (LR-WPANs) [ 1 ]. The IEEE 802.15.4 MAC and PHY layers provide the basis of other higher-layer standards, such as ZigBee, WirelessHart®, 6LoWPAN and MiWi. Such standards find application in home automation and sensor networking and are highly relevant to the Internet of Things (IoT) trend.
Overall, the receiver performs the following operations:
Coarse frequency compensation
Fine frequency compensation
Phase ambiguity resolution
Between these steps, the signal is visualized to illustrate the signal impairments and the corrections.
load lrwpanPHYCaptures % load OQPSK signals captured in the 2.4 GHz band spc = 12; % 12 samples per chip; the frame was captured at 12 x chiprate = 12 MHz
A matched filter improves the SNR of the signal. The 2.4 GHz OQPSK PHY uses half-sine pulses, therefore the following matched filtering operation is needed.
% Matched filter for captured OQPSK signal: halfSinePulse = sin(0:pi/spc:(spc)*pi/spc); decimationFactor = 3; % reduce spc to 4, for faster processing matchedFilter = dsp.FIRDecimator(decimationFactor, halfSinePulse); filteredOQPSK = matchedFilter(capturedFrame1); % matched filter output
Decoding a signal under the presence of frequency offsets is a challenge for any wireless receiver. Frequency offsets up to 30 kHz were measured for signals transmitted from commercial ZigBee radios and captured using a USRP® B200-mini radio.
Constellation diagrams can illustrate the quality of the received signal, but it is first important to note that the trajectory of an ideal OQPSK signal follows a circle.
% Plot constellation of ideal OQPSK signal msgLen = 8*120; % length in bits message = randi([0 1], msgLen, 1); % transmitted message idealOQPSK = lrwpan.PHYGeneratorOQPSK(message, spc, '2450 MHz'); constellation = comm.ConstellationDiagram('Name', 'Ideal OQPSK Signal', 'ShowTrajectory', true); constellation.Position = [constellation.Position(1:2) 300 300]; constellation(idealOQPSK);
The above constellation also contains one radius corresponding to the frame start, and one radius corresponding to the frame end. At the same time, frequency offsets circularly rotate constellations, resulting in ring-shaped constellations as well. Therefore, it is more meaningful to observe the constellation of a QPSK-equivalent signal that is obtained by delaying the in-phase component of the OQPSK signal by half a symbol. When half-sine pulse filtering is used, and the oversampling factor is greater than one, the ideal QPSK constellation resembles an 'X'-shaped region connecting the four QPSK symbols (red crosses) with the origin.
% Plot constellation of ideal QPSK-equivalent signal idealQPSK = complex(real(idealOQPSK(1:end-spc/2)), imag(idealOQPSK(spc/2+1:end))); % align I and Q release(constellation); constellation.Name = 'Ideal QPSK-Equivalent Signal'; constellation.ReferenceConstellation = [1+1i 1-1i 1i-1 -1i-1]; constellation(idealQPSK);
However, the samples of the captured frame are dislocated from this 'X'-shaped region due to frequency offsets:
% Plot constellation of QPSK-equivalent (impaired) received signal filteredQPSK = complex(real(filteredOQPSK(1:end-spc/(2*decimationFactor))), imag(filteredOQPSK(spc/(2*decimationFactor)+1:end))); % align I and Q constellation = comm.ConstellationDiagram('XLimits', [-7.5 7.5], 'YLimits', [-7.5 7.5], ... 'ReferenceConstellation', 5*qammod(0:3, 4), 'Name', 'Received QPSK-Equivalent Signal'); constellation.Position = [constellation.Position(1:2) 300 300]; constellation(filteredQPSK);
Such frequency offsets are first coarsely corrected using an FFT-based method [ 2 ] that squares the OQPSK signal and reveals two spectral peaks. The coarse frequency offset is obtained by averaging and halving the frequencies of the two spectral peaks.
% Coarse frequency compensation of OQPSK signal coarseFrequencyCompensator = comm.CoarseFrequencyCompensator('Modulation', 'OQPSK', ... 'SampleRate', spc*1e6/decimationFactor, 'FrequencyResolution', 1e3); [coarseCompensatedOQPSK, coarseFrequencyOffset] = coarseFrequencyCompensator(filteredOQPSK); fprintf('Estimated frequency offset = %.3f kHz\n', coarseFrequencyOffset/1000); % Plot QPSK-equivalent coarsely compensated signal coarseCompensatedQPSK = complex(real(coarseCompensatedOQPSK(1:end-spc/(2*decimationFactor))), imag(coarseCompensatedOQPSK(spc/(2*decimationFactor)+1:end))); % align I and Q release(constellation); constellation.Name = 'Coarse frequency compensation (QPSK-Equivalent)'; constellation(coarseCompensatedQPSK);
Estimated frequency offset = 26.855 kHz
Some samples still lie outside the 'X'-shaped region connecting the origin with the QPSK symbols (red crosses), as fine frequency compensation is also needed.
Fine frequency compensation follows the OQPSK carrier-recovery algorithm described in [ 3 ]. This algorithm is behaviorally different than its QPSK counterpart, which does not apply to OQPSK signals even if their in-phase signal component is delayed by half a symbol.
% Fine frequency compensation of OQPSK signal fineFrequencyCompensator = comm.CarrierSynchronizer('Modulation', 'OQPSK', 'SamplesPerSymbol', spc/decimationFactor); fineCompensatedOQPSK = fineFrequencyCompensator(coarseCompensatedOQPSK); % Plot QPSK-equivalent finely compensated signal fineCompensatedQPSK = complex(real(fineCompensatedOQPSK(1:end-spc/(2*decimationFactor))), imag(fineCompensatedOQPSK(spc/(2*decimationFactor)+1:end))); % align I and Q release(constellation); constellation.Name = 'Fine frequency compensation (QPSK-Equivalent)'; constellation(fineCompensatedQPSK);
The constellation is now closer to its ideal form, but still timing recovery is needed.
Symbol synchronization occurs according to the OQPSK timing-recovery algorithm described in [ 3 ]. In contrast to carrier recovery, the OQPSK timing recovery algorithm is equivalent to its QPSK counterpart for QPSK-equivalent signals that are obtained by delaying the in-phase component of the OQPSK signal by half a symbol.
% Timing recovery of OQPSK signal, via its QPSK-equivalent version symbolSynchronizer = comm.SymbolSynchronizer('Modulation', 'OQPSK', 'SamplesPerSymbol', spc/decimationFactor); syncedQPSK = symbolSynchronizer(fineCompensatedOQPSK); % Plot QPSK symbols (1 sample per chip) release(constellation); constellation.Name = 'Timing Recovery (QPSK-Equivalent)'; constellation(syncedQPSK);
Note that the output of the Symbol Synchronizer contains one sample per symbol. At this stage, the constellation truly resembles a QPSK signal. The few symbols that gradually move away from the origin correspond to the frame start and end.
Once the signal has been synchonized, the next step is preamble detection, which is more successful if the signal has been despreaded. It is worth noting that fine frequency compensation results in a /2-phase ambiguity, indicating the true constellation may have been rotated by 0, /2, , or /2 radians. Preamble detection resolves the phase ambiguity by considering all four possible constellation rotations. The next function operates on the synchronized OQPSK signal, performs joint despreading, resolution of phase ambiguity and preamble detection, and then outputs the MAC protocol data unit (MPDU).
MPDU = lrwpan.PHYDecoderOQPSKAfterSync(syncedQPSK);
Found preamble of OQPSK PHY. Found start-of-frame delimiter (SFD) of OQPSK PHY.
You can further explore the following generator and decoding functions, as well as the configuration object:
IEEE 802.15.4-2011 - IEEE Standard for Local and metropolitan area networks--Part 15.4: Low-Rate Wireless Personal Area Networks (LR-WPANs)
"Designing an OQPSK demodulator", Jonathan Olds: http://jontio.zapto.org/hda1/oqpsk.html
Rice, Michael. Digital Communications - A Discrete-Time Approach. 1st ed. New York, NY: Prentice Hall, 2008.