Table of Contents
A USRP device has two stages of tuning:
In a typical use-case, the user specifies an overall center frequency for the signal chain. The RF front-end will be tuned as close as possible to the center frequency, and the DSP will account for the error in tuning between target frequency and actual frequency. The user may also explicitly control both stages of tuning through through the tune_request_t object, which allows for more advanced tuning.
In general, Using UHD software's advanced tuning is highly recommended as it makes it easy to move the DC component out of your band-of-interest. This can be done by passing your desired LO offset to the tune_request_t object, and letting the UHD software handle the rest.
The tune_request_t object can also be used with certain daughterboards to use Integer-N tuning instead of the default fractional tuning, allowing for better spur performance. The daughterboards that support this functionality are:
//tuning to a desired center frequency usrp->set_rx_freq(target_frequency_in_hz);
—OR--
//advanced tuning with tune_request_t uhd::tune_request_t tune_req(target_frequency_in_hz, desired_lo_offset); tune_req.args = uhd::device_addr_t("mode_n=integer"); //to use Int-N tuning //fill in any additional/optional tune request fields... usrp->set_rx_freq(tune_req);
More information can be found in tune_request.hpp.
After tuning, the RF front-end will need time to settle into a usable state. Typically, this means that the local oscillators must be given time to lock before streaming begins. Lock time is not consistent; it varies depending upon the device and requested settings. After tuning and before streaming, the user should wait for the lo_locked sensor to become true or sleep for a conservative amount of time (perhaps a second).
usrp->set_rx_freq(...); sleep(1); usrp->issue_stream_command(...); --OR-- usrp->set_rx_freq(...); while (not usrp->get_rx_sensor("lo_locked").to_bool()){ //sleep for a short time in milliseconds } usrp->issue_stream_command(...);
A subdevice specification string for USRP family devices is composed of:
<motherboard slot name>:<daughterboard frontend name>
Ex: The subdev spec markup string to select a WBX on slot B.
B:0
Ex: The subdev spec markup string to select a BasicRX on slot B.
B:AB -- OR -- B:A -- OR -- B:B
All USRP family motherboards have a first slot named A:. The USRP1 has two daughterboard subdevice slots, known as A: and B:.
Daughterboard frontend names can be used to specify which signal path is used from a daughterboard. Most daughterboards have only one frontend :0. A few daughterboards (Basic, LF and TVRX2) have multiple frontend names available. The frontend names are documented in the Daughterboard Application Notes
Note: The following overflow/underflow notes do not apply to USRP1, which does not support the advanced features available in newer products.
When receiving, the device produces samples at a constant rate. Overflows occurs when the host does not consume data fast enough. When UHD software detects the overflow, it prints an "O" or "D" to stdout, and pushes an inline message packet into the receive stream.
Network-based devices: The host does not back-pressure the receive stream. When the kernel's socket buffer becomes full, it will drop subsequent packets. UHD software detects the overflow as a discontinuity in the packet's sequence numbers, and pushes an inline message packet into the receive stream. In this case the character "D" is printed to stdout as an indication.
Other devices: The host back-pressures the receive stream. Therefore, overflows always occur in the device itself. When the device's internal buffers become full, streaming is shut off, and an inline message packet is sent to the host. In this case the character "O" is printed to stdout as an indication. If the device was in continuous streaming mode, the UHD software will automatically restart streaming when the buffer has space again.
When transmitting, the device consumes samples at a constant rate. Underflow occurs when the host does not produce data fast enough. When UHD software detects the underflow, it prints a "U" to stdout, and pushes a message packet into the async message stream.
For the most part, UHD software is thread-safe. Please observe the following limitations:
Fast-path thread requirements: There are three fast-path methods for a device: send(), recv(), and recv_async_msg(). All three methods are thread-safe and can be called from different thread contexts. For performance, the user should call each method from a separate thread context. These methods can also be used in a non-blocking fashion by using a timeout of zero.
Slow-path thread requirements: It is safe to change multiple settings simultaneously. However, this could leave the settings for a device in an uncertain state. This is because changing one setting could have an impact on how a call affects other settings. Example: setting the channel mapping affects how the antennas are set. It is recommended to use at most one thread context for manipulating device settings.
When UHD software spawns a new thread it may try to boost the thread's scheduling priority. When setting the priority fails, the UHD software prints out an error. This error is harmless; it simply means that the thread will have a normal scheduling priority.
Linux Notes:
Non-privileged users need special permission to change the scheduling priority. Add the following line to /etc/security/limits.conf: :::::::::::::::::::::::::::::::::::::::::::::::::::::::
@<my_group> - rtprio 99
Replace <my_group> with a group to which your user belongs. Settings will not take effect until the user is in a different login session.
For a module to be loaded at runtime, it must be:
The user can disable the UHD library from printing directly to stdout by registering a custom message handler. The handler will intercept all messages, which can be dropped or redirected. Only one handler can be registered at a time. Make register_handler your first call into the UHD library:
#include <uhd/utils/msg.hpp> void my_handler(uhd::msg::type_t type, const std::string &msg){ //handle the message... } uhd::msg::register_handler(&my_handler);