======================================================================== UHD - Synchronization Application Notes ======================================================================== .. contents:: Table of Contents The following application notes explain how to synchronize multiple USRPs with the goal of transmitting or receiving time-aligned samples for MIMO or other applications requiring multiple USRPs operating synchronously. **Note:** The following synchronization notes do not apply to USRP1, which does not support the advanced features available in newer products. ------------------------------------------------------------------------ Common reference signals ------------------------------------------------------------------------ USRPs take two reference signals in order to synchronize clocks and time: * A 10MHz reference to provide a single frequency reference for both devices, and * A pulse-per-second (1PPS) to synchronize the sample time across devices. ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Provide reference signals ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ USRPs have two primary means of providing synchronization: **Method 1:** Connect the front panel SMA connectors to the reference sources. Typically, these signals are provided by an external GPSDO. However, some USRP models can provide these signals from an optional internal GPSDO. **Method 2:** Use the MIMO Expansion cable to share reference sources (USRP2 and N-Series). The MIMO cable can be used synchronize one device to another device. Users of the MIMO cable may use method 1 to synchronize multiple pairs of devices. **Note:** For users generating their own signals for the external SMA connectors, the pulse-per-second should be clocked from the 10MHz reference. See the application notes for your device for specific signal requirements. ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Set the clock configuration ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ In order to synchronize to an external clock, configure the USRP device using the "external" clock configuration: :: usrp->set_clock_config(uhd::clock_config_t::external()); Sometimes the delay on the PPS signal will cause it to arrive inside the timing margin the FPGA sampling clock, causing PPS edges to be separated by less or more than 100million cycles of the FPGA clock. If this is the case, you can change the edge reference of the PPS clock with the clock_config_t: :: uhd::clock_config_t clock_config = uhd::clock_config_t::external(); clock_config.pps_polarity = uhd::clock_config_t::PPS_NEG; usrp->set_clock_config(clock_config); ------------------------------------------------------------------------ Synchronizing the device time ------------------------------------------------------------------------ The purpose of the PPS signal is to synchronously latch a time into the device. You can use the set_time_next_pps(...) function to either initialize the sample time to 0, or to an absolute time such as GPS time or UTC time. For the purposes of synchronizing devices, it doesn't matter what time you initialize to when using set_time_next_pps(...). ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Method 1 - poll the USRP time registers ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ One way to initialize the PPS edge is to poll the "last PPS" time from the USRP device. When the last PPS time increments, the user can determine that a PPS has occurred: :: const uhd::time_spec_t last_pps_time = usrp->get_time_last_pps(); while (last_pps_time != usrp->get_time_last_pps()){ //sleep 100 milliseconds (give or take) } usrp->set_time_next_pps(uhd::time_spec_t(0.0)); ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Method 2 - query the GPSDO for seconds ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Most GPSDO can be configured to output a NMEA string over the serial port once every PPS. The user can wait for this string to determine the PPS edge, and the user can also parse this string to determine GPS time: :: //call user's function to wait for NMEA message... usrp->set_time_next_pps(uhd::time_spec_t(0.0)); -- OR -- //call user's function to wait for NMEA message... //call user's function to parse the NMEA message... usrp->set_time_next_pps(uhd::time_spec_t(gps_time+1)); ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Method 3 - internal GPSDO ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ USRPs with internal GPSDOs properly configured will automatically configure themselves to set the VITA time to current UTC time. See the GPSDO application note for more details. ------------------------------------------------------------------------ Synchronizing channel phase ------------------------------------------------------------------------ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Align CORDICs in the DSP ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ In order to achieve phase alignment between USRPs, the CORDICS in both devices must be aligned with respect to each other. This is easily achieved by issuing stream commands with a time spec property, which instructs the streaming to begin at a specified time. Since the devices are already synchronized via the 10MHz and PPS inputs, the streaming will start at exactly the same time on both devices. The CORDICs are reset at each start-of-burst command, so users should ensure that every start-of-burst also has a time spec set. For receive, a burst is started when the user issues a stream command. This stream command should have a time spec set: :: uhd::stream_cmd_t stream_cmd(uhd::stream_cmd_t::STREAM_MODE_NUM_SAMPS_AND_DONE); stream_cmd.num_samps = samps_to_recv; stream_cmd.stream_now = false; stream_cmd.time_spec = time_to_recv; usrp->issue_stream_cmd(stream_cmd); For transmit, a burst is started when the user calls send(). The metadata should have a time spec and start of burst set: :: uhd::tx_metadata_t md; md.start_of_burst = true; md.end_of_burst = false; md.has_time_spec = true; md.time_spec = time_to_send; //send a single packet size_t num_tx_samps = usrp->get_device()->send( buffs, samps_to_send, md, uhd::io_type_t::COMPLEX_FLOAT32, uhd::device::SEND_MODE_ONE_PACKET, timeout ); ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Align LOs in the front-end ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ After tuning the RF front-ends, each local oscillator may have a random phase offset due to the dividers in the VCO/PLL chains. This offset will remain constant after the device has been initialized, and will remain constant until the device is closed or re-tuned. This phase offset is typically removed by the user in MIMO applications, using a training sequence to estimate the offset. It will be necessary to re-align the LOs after each tune command.