%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Transmitting and Receiving Data using Warplab (SISO COnfiguration) %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % To run this code the boards must be programmed with the % warplab_siso_v02.bit bitstream % The specific steps implemented in this script are the following % 0. Initializaton and definition of parameters % 1. Generate a vector of samples to transmit and send the samples to the % Warp board (Sample Frequency is 40MHz) % 2. Prepare boards for transmission and reception and send trigger to % start transmission and reception (trigger is the SYNC packet) % 3. Read the received samples from the Warp board % 4. Reset and disable the boards % 5. Plot the transmitted and received data %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 0. Initializaton and definition of parameters %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %Load some global definitions (packet types, etc.) warplab_defines % Create Socket handles and intialize nodes [socketHandles, packetNum] = warplab_initialize; %Separate the socket handles for easier access % The first socket handle is always the magic SYNC % The rest can be arranged in any combination of Tx and Rx udp_Sync = socketHandles(1); udp_Tx = socketHandles(2); udp_RxA = socketHandles(3); % Define the warplab options (parameters) CaptOffset = 1000; %Number of noise samples per Rx capture. In [0:2^14] TxLength = 2^14-1000; %Length of transmission. In [0:2^14-CaptOffset] TransMode = 0; %Transmission mode. In [0:1] % 0: Single Transmission % 1: Continuous Transmission. Tx board will continue % transmitting the vector of samples until the user manually % disables the transmitter. CarrierChannel = 8; % Channel in the 2.4 GHz band. In [1:14] TxGainBB = 3; %Tx Baseband Gain. In [0:3] TxGainRF = 40; %Tx RF Gain. In [0:63] RxGainBB = 15; %Rx Baseband Gain. In [0:31] RxGainRF = 1; %Rx RF Gain. In [1:3] % Define the options vector; the order of options is set by the FPGA's code % (C code) optionsVector = [CaptOffset TxLength-1 TransMode CarrierChannel (RxGainBB + RxGainRF*2^16) (TxGainRF + TxGainBB*2^16)]; % Send options vector to the nodes warplab_setOptions(socketHandles,optionsVector); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 1. Generate a vector of samples to transmit and send the samples to the % Warp board (Sample Frequency is 40MHz) %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Prepare some data to be transmitted t = 0:(1/40e6):TxLength/40e6 - 1/40e6; % Create time vector. TxData = exp(t*j*2*pi*1e6); % Create a signal to transmit. Signal must be a % row vector. The signal can be real or complex, the only constraint is % that the amplitude of the real part must be in [-1:1] and the amplitude % of the imaginary part must be in [-1:1] % Download the samples to be transmitted warplab_writeSMWO(udp_Tx, TxData, RADIO2_TXDATA); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 2. Prepare boards for transmission and reception and send trigger to % start transmission and reception (trigger is the SYNC packet) %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Enable transmitter radio path in transmitter node warplab_sendCmd(udp_Tx, RADIO2_TXEN, packetNum); % Enable receiver radio path in receiver node warplab_sendCmd(udp_RxA, RADIO2_RXEN, packetNum); % Prime transmitter state machine in transmitter node. Transmitter will be % waiting for the SYNC packet. Transmission will be triggered when the % transmitter node receives the SYNC packet. warplab_sendCmd(udp_Tx, TX_START, packetNum); % Prime receiver state machine in receiver node. Receiver will be waiting % for the SYNC packet. Capture will be triggered when the receiver % node receives the SYNC packet. warplab_sendCmd(udp_RxA, RX_START, packetNum); % Send the SYNC packet warplab_sendSync(udp_Sync); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 3. Read the received samples from the Warp board %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Read back the received samples [RawRxData] = warplab_readSMRO(udp_RxA, RADIO2_RXDATA, TxLength+CaptOffset); % Process the received samples to obtain meaningful data [RxData,RxOTR] = warplab_processRawRxData(RawRxData); % Read stored RSSI data [RawRSSIData] = warplab_readSMRO(udp_RxA, RADIO2_RSSIDATA, (TxLength+CaptOffset)/8); % Procecss Raw RSSI data to obtain meningful RSSI values [RxRSSI] = warplab_processRawRSSIData(RawRSSIData); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 4. Reset and disable the boards %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Reset the receiver warplab_sendCmd(udp_RxA, RX_DONEREADING, packetNum); % Disable the receiver radio warplab_sendCmd(udp_RxA, RADIO2_RXDIS, packetNum); % Disable the transmitter radio warplab_sendCmd(udp_Tx, RADIO2_TXDIS, packetNum); % Close sockets pnet('closeall'); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % 5. Plot the transmitted and received data %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% figure; subplot(2,2,1); plot(real(TxData)); title('Tx I'); xlabel('n (samples)'); ylabel('Amplitude'); axis([0 2^14 -1 1]); % Set axis ranges. subplot(2,2,2); plot(imag(TxData)); title('Tx Q'); xlabel('n (samples)'); ylabel('Amplitude'); axis([0 2^14 -1 1]); % Set axis ranges. subplot(2,2,3); plot(real(RxData)); title('Rx I'); xlabel('n (samples)'); ylabel('Amplitude'); axis([0 2^14 -1 1]); % Set axis ranges. subplot(2,2,4); plot(imag(RxData)); title('Rx Q'); xlabel('n (samples)'); ylabel('Amplitude'); axis([0 2^14 -1 1]); % Set axis ranges.