/*! \page page_multiple Multiple USRP configurations \tableofcontents \section multiple_intro Introduction Some USRP devices are capable of being grouped to form a single, virtual device. A single uhd::usrp::multi_usrp instantiation can control such a compound of devices. Currently, the following devices support this capability: - USRP2 / N2x0 Series - X3x0 Series Note that only USRPs of the same type can be combined. \section multiple_setup Setting up devices A description of a multiple-USRP setup can be found on the respective device's manual pages. Addressing of a compound of devices is done by listing multiple addresses, e.g.: addr0=192.168.10.2,addr1=192.168.20.2 \section multiple_channumbers Channel and Device Numbering Assume we have combined 2 X310 USRPs into a single multi_usrp using the address string given above, maybe using the following command: \code{.cpp} uhd::device_addr_t args("addr0=192.168.10.2,addr1=192.168.20.2"); uhd::usrp::multi_usrp::sptr usrp = uhd::usrp::multi_usrp::make(args); \endcode Some uhd::usrp::multi_usrp commands require passing a device index. This is simply the index in the address list, so say we want to check the master clock rate on both devices, this would be valid: \code{.cpp} double mcr0 = usrp->get_master_clock_rate(0); double mcr1 = usrp->get_master_clock_rate(1); \endcode Some methods default to applying to all devices, so the following command would set the time on all devices to zero: \code{.cpp} usrp->set_time_next_pps(uhd::time_spec_t(0)); \endcode So, device indexes run from 0 to N-1 where N is the number of devices. Channels are indexed in a similar way. Channel indexes run from 0 to M-1 where M is the total number of channels on all devices. The number and order of channels per device depends on the subdev spec (see also \ref config_subdev). In the current example, assume all the X310 USRPs are using their standard configuration, and all have two daughterboards inside. In this case channels 0 and 1 map to slot A and B of the first USRP, respectively. Channels 2 and 3 map to slots A and B of the second USRP, and so on. However, by changing the subdev spec on individual devices, this can change. Say we have this unusual piece of code next: \code{.cpp} usrp->set_rx_subdev_spec("A:0 B:0", 0); usrp->set_rx_subdev_spec("A:0", 1); usrp->set_rx_subdev_spec("B:0 A:0", 2); \endcode The first device uses the default configuration. The second device artificially disables slot B, giving this USRP a single channel only. The third device uses both devices, but flips their order. Now, there's a total of 5 channels, mapped as: - Channel 0: Slot A of Device 0 - Channel 1: Slot B of Device 0 - Channel 2: Slot A of Device 1 - Channel 3: Slot A of Device 2 - Channel 4: Slot B of Device 2 While valid, this kind of configuration is not recommended unless heavily documented. It is usually simplest to call `set_rx_subdev_spec()` without a device index, which will set the same subdev spec on all devices. This assumes all devices have a similar daughterboard configuration \section multiple_mimo MIMO Operation When a multi-channel streamer is generated from a compound multi_usrp, and a streamer with multiple channels is generated, MIMO operations is automatically chosen. This means samples will be aligned between streams automatically. In order for this to work, all devices must use a common time and frequency reference. This can be achieved in different ways, e.g. by daisy-chaining devices (for a small number of X-Series devices), using the MIMO cable (when only 2 N2x0 devices are used), or using a clock distribution system, e.g. an OctoClock. See \ref page_sync and the individual device manuals on more details on how to do this. */ // vim:ft=doxygen: