Get Started with 6G Exploration Library

Subcarrier Spacings Greater Than 960 kHz

OFDM waveforms with increased subcarrier spacing are a candidate for 6G. Hexa-X Deliverable D2.3 Table 5-2 defines OFDM waveforms with subcarrier spacings of 1920 kHz and 3840 kHz [3]. Section 5.1.1 of the Hexa-X deliverable describes that OFDM symbols with increased subcarrier spacing are shorter in time, which facilitates reduced latency. Section 5.1.2.1.1 describes that wider subcarrier spacing improves the tolerance to phase noise, which is more severe at higher carrier frequencies.

You can use the SubcarrierSpacing property of the pre6GCarrierConfig object to specify a subcarrier spacing greater than 960 kHz.

For example, configure a carrier with a subcarrier spacing of 3840 kHz and 36 resource blocks.

carrier = pre6GCarrierConfig(SubcarrierSpacing=3840,NSizeGrid=36);

Compute the sample rate and transmission bandwidth.

ofdmInfo = hpre6GOFDMInfo(carrier);
sampleRate = ofdmInfo.SampleRate;
disp(['Sample rate = ' num2str(sampleRate/1e9) ' GHz'])

Sample rate = 1.9661 GHz

txBandwidth = carrier.NSizeGrid * 12 * carrier.SubcarrierSpacing * 1e3;
disp(['Transmission bandwidth = ' num2str(txBandwidth/1e9) ' GHz'])

Transmission bandwidth = 1.6589 GHz

Display the number of slots per subframe.

disp(['Slots per subframe = ' num2str(carrier.SlotsPerSubframe)])

Slots per subframe = 256

Display the cyclic prefix lengths of the first slot. Because the 6G Exploration Library for 5G Toolbox uses the numerology rules of 5G NR, the first cyclic prefix length is much larger than the others. As the subcarrier spacing increases, the first cyclic prefix every half subframe increases relative to the other cyclic prefixes.

disp(['Cyclic prefix lengths (in samples) = ' num2str(ofdmInfo.CyclicPrefixLengths(1:carrier.SymbolsPerSlot))])

Cyclic prefix lengths (in samples) = 1060    36    36    36    36    36    36    36    36    36    36    36    36    36

Resource Grids Larger Than 275 Resource Blocks

At World Radiocommunication Conference 2023 (WRC-23), ITU agreed to assign a new band 6.425 - 7.125 GHz for the terrestrial component of the International Mobile Telecommunications (IMT) system [4]. This band contains 700 MHz of spectrum and is a potential operating band for the next generation of IMT, which is IMT-2030 [5], also known as 6G.

To evaluate the performance of a 6G candidate waveform occupying 700 MHz bandwidth and using 120 kHz subcarrier spacing, you need a number of resource blocks greater than 275. You can use the NSizeGrid property of pre6GCarrierConfig to create resource grids with more than 275 resource blocks.

For example, configure a carrier with the largest number of resource blocks that can be allocated in a 700 MHz bandwidth by using 120 kHz subcarrier spacing and without exceeding a bandwidth occupancy of 0.9. The bandwidth occupancy is the ratio of occupied bandwidth to channel bandwidth. A larger bandwidth occupancy results in more capacity but requires better filtering to avoid emissions outside the channel bandwidth.

bandwidthOccupancy = 0.9;
carrier = pre6GCarrierConfig(SubcarrierSpacing=120);
channelBandwidth = 700e6;
carrier.NSizeGrid = floor((channelBandwidth/(carrier.SubcarrierSpacing*1e3)*bandwidthOccupancy)/12)

carrier = 
  pre6GCarrierConfig with properties:

                NCellID: 1
      SubcarrierSpacing: 120
           CyclicPrefix: 'normal'
              NSizeGrid: 437
             NStartGrid: 0
                  NSlot: 0
                 NFrame: 0
    IntraCellGuardBands: [0x2 double]

   Read-only properties:
         SymbolsPerSlot: 14
       SlotsPerSubframe: 8
          SlotsPerFrame: 80

Compute the sample rate and transmission bandwidth.

ofdmInfo = hpre6GOFDMInfo(carrier);
sampleRate = ofdmInfo.SampleRate;
disp(['Sample rate = ' num2str(sampleRate/1e6) ' MHz'])

Sample rate = 983.04 MHz

txBandwidth = carrier.NSizeGrid * 12 * carrier.SubcarrierSpacing * 1e3;
disp(['Transmission bandwidth = ' num2str(txBandwidth/1e6) ' MHz'])

Transmission bandwidth = 629.28 MHz

Create a pre6GPDSCHConfig object and configure it to allocate all carrier resource blocks and use 64-QAM modulation.

pdsch = pre6GPDSCHConfig;
pdsch.PRBSet = 0:(carrier.NSizeGrid-1);
pdsch.Modulation = '64QAM';

Create a carrier resource grid containing PDSCH and PDSCH DM-RS symbols.

nTxAnts = 1;
txGrid = hpre6GResourceGrid(carrier,nTxAnts);

[ind,indinfo] = hpre6GPDSCHIndices(carrier,pdsch);
cw = randi([0 1],indinfo.G,1);
sym = hpre6GPDSCH(carrier,pdsch,cw);
txGrid(ind) = sym;

dmrsind = hpre6GPDSCHDMRSIndices(carrier,pdsch);
dmrssym = hpre6GPDSCHDMRS(carrier,pdsch);
txGrid(dmrsind) = dmrssym;

OFDM-modulate the resource grid.

txWaveform = hpre6GOFDMModulate(carrier,txGrid);

Plot the spectrum of the OFDM waveform.

scope = spectrumAnalyzer(SampleRate=sampleRate);
scope.Title = "Waveform for 700 MHz channel in upper 6 GHz band";
scope.ChannelMeasurements.Enabled = true;
scope.ChannelMeasurements.Span = 700e6;
scope(txWaveform)

Further Exploration

6G Exploration Library for 5G Toolbox provides examples that you can further customize to explore 6G waveforms and related technologies. For example:

References

[1] 3GPP TS 38.211 "NR; Physical channels and modulation" 3rd Generation Partnership Project; Technical Specification Group Radio Access Network.

[2] 3GPP TS 38.331 "NR; Radio Resource Control (RRC); Protocol specification" 3rd Generation Partnership Project; Technical Specification Group Radio Access Network.

[3] Hexa-X Deliverable D2.3 - Radio models and enabling techniques towards ultra-high data rate links and capacity in 6G

[4] RESOLUTION COM4/7 (WRC-23), ITU WRC-23 Provisional Final Acts

[5] ITU Recommendation ITU-R M.2160-0 "Framework and overall objectives of the future development of IMT for 2030 and beyond"