1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
|
/*! \page page_usrp_x3x0 USRP X3x0 Series
\tableofcontents
More information:
\li \subpage page_gpsdo_x3x0
\li \subpage page_gpio_api
\li \subpage page_usrp_x3x0_config
\li \subpage page_ni_rio_kernel
\section x3x0_feature_list Comparative features list
- Hardware Capabilities:
- 2 transceiver card slots (can do 2x2 MIMO out of the box)
- Dual SFP+ Transceivers (can be used with 1 GigE, 10 GigE)
- PCI Express over cable (MXI) gen1 x4
- External PPS input & output
- External 10 MHz input & output
- Expandable via 2nd SFP+ interface
- Supported master clock rates: 200 MHz and 184.32 MHz
- Variable daughterboard clock rates
- External GPIO Connector with UHD API control
- External USB Connection for built-in JTAG debugger
- Internal GPSDO option
- Kintex-7 FPGA (X310: XC7K410T, X300: XC7K325T)
- FPGA Capabilities:
- 2 RX DDC chains in FPGA
- 2 TX DUC chain in FPGA
- Timed commands in FPGA
- Timed sampling in FPGA
- Up to 120 MHz of RF bandwidth with 16-bit samples
\section x3x0_getting_started Getting started
This will run you through the first steps relevant to get your USRP X300/X310
up and running. Here, we assume you will connect your USRP using Gigabit Ethernet (1GigE),
as this interface is readily available in most computers. For 10 Gigabit Ethernet (10GigE) or
PCI Express (PCIe), see the corresponding sections in this manual page.
\subsection x3x0_getting_started_assembling Assembling the X300/X310 kit
Before you can start using your USRP, you might have to assemble the hardware,
if this has not yet happened. Make sure you are grounded (e.g. by touching a radiator)
in order not to damage sensitive electronics through static discharge!
1. Unscrew the top of your X300/X310 (there are 2 screws which can be easily loosened
using a small Phillips screwdriver).
2. Insert the daughterboards by inserting them into the slots and optionally screwing
them onto the motherboard.
3. Connect the RF connectors on the daughterboards to the front panel. In order to avoid
confusion, make sure the internal connections match the labels on the front panel (i.e.
TX/RX is connected to TX/RX).
4. If you have purchased an internal GPSDO, follow the instructions on
\ref page_gpsdo_x3x0 to insert the GPSDO. Note that you
will need an external GPS antenna connected to the rear GPS ANT connector in order to
make use of GPS, although your USRP will still be usable without.
5. Connect the 1 GigE SFP+ transceiver into the Ethernet port 0 and connect the X300/X310 with
your computer.
6. Connect the power supply and switch on the USRP.
\subsection x3x0_getting_started_connectivity Network Connectivity
The next step is to make sure your computer can talk to the USRP. An otherwise unconfigured
USRP device will have the IP address 192.168.10.2 when using 1GigE.
It is recommended to directly connect your USRP to the computer at first,
and to set the IP address on your machine to 192.168.10.1.
See \ref x3x0_setup_network_host_interface on details how to change your machine's IP address.
<b>Note</b>: If you are running an automatic IP configuration service such as Network Manager, make
sure it is either deactivated or configured to not change the network device! This can, in extreme cases,
lead to you bricking the USRP!
If your network configuration is correct, running `uhd_find_devices` will find your USRP
and print some information about it. You will also be able to ping the USRP by running:
ping 192.168.10.2
on the command line. At this point, you should also run:
uhd_usrp_probe --args addr=192.168.10.2
to make sure all of your components (daughterboards, GPSDO) are correctly detected and usable.
\subsection x3x0_getting_started_fpga_update Updating the FPGA
If the output from `uhd_find_devices` and `uhd_usrp_probe` didn't show any warnings, you
can skip this step. However, if there were errors regarding the FPGA version compatibility
number, you will have to update the FPGA image before you can start using your USRP.
1. Download the current UHD images. You can use the `uhd_images_downloader` script provided
with UHD (see also \ref page_images).
2. Use the `uhd_image_loader` utility to update the FPGA image. On the command line, run:
uhd_image_loader --args="type=x300,addr=192.168.10.2,fpga=HG"
If you have installed the images to a non-standard location, you might need to run (change the filename according to your device):
uhd_image_loader --args="type=x300,addr=192.168.10.2" --fpga-path="<path_to_images>/usrp_x310_fpga_HG.bit"
The process of updating the FPGA image will take several minutes. Make sure the process of flashing the image does not get interrupted.
See \ref x3x0_flash for more details.
When your FPGA is up to date, power-cycle the device and re-run `uhd_usrp_probe`. There should
be no more warnings at this point, and all components should be correctly detected. Your USRP is now
ready for development!
\section x3x0_hw Hardware Setup
\subsection x3x0_hw_1gige Gigabit Ethernet (1 GigE)
- Prior to installing the module, the host PC can remain powered on.
- Plug a 1 Gigabit SFP Transceiver into Ethernet Port 0 on the USRP X300/X310 device.
- Use the Ethernet cable to connect the SFP+ transceiver on the device to the host computer. For maximum throughput, Ettus Research recommends that you connect each device to its own dedicated Gigabit Ethernet interface on the host computer.
- Connect the AC/DC power supply to the device and plug the supply into a wall outlet.
- The OS will automatically recognize the device (e.g. when running `uhd_find_devices`).
\subsection x3x0_hw_10gige Ten Gigabit Ethernet (10 GigE)
### Installing the Host Ethernet Interface
Ettus Research recommends the Intel Ethernet Converged Network Adapter X520-DA2 interface for communication with the USRP X300/X310 device.
Installation instructions for this interface are available on the official Intel website.
### Installing the USRP X300/X310
- Prior to installing the module, the host PC can remain powered on.
- Use a 10 Gigabit SFP+ cable to connect Ethernet Port 1 on the USRP X300/X310 device to the host computer. For maximum throughput, Ettus Research recommends that you connect the device to its own dedicated Ten Gigabit, Ettus Research recommended Ethernet interface on the host computer.
- Connect the AC/DC power supply to the device and plug the supply into a wall outlet.
- The OS will automatically recognize the device (e.g. when running `uhd_find_devices`).
The LEDs on the front panel can be useful in debugging hardware and software issues (see \ref x3x0_hw_fpanel)
### Dual 10 Gigabit Ethernet
In order to utilize the X-series USRP over dual 10 Gigabit Ethernet interfaces, ensure
either the XG image is installed (see \ref x3x0_load_fpga_imgs_fpga_flavours).
In addition to burning the prerequisite FPGA image, it may also be necessary
to tune the network interface card (NIC) to eliminate drops (Ds) and reduce overflows (Os).
This is done by increasing the number of RX descriptors (see \ref transport_udp_linux).
The benchmark_rate tool can be used to test this capability.
Run the following commands to test the X-series USRP over both 10 Gigabit
Ethernet interfaces with the maximum rate of 200 Msps per channel:
cd <install-path>/lib/uhd/examples
./benchmark_rate --args="type=x300,addr=<Primary IP>,second_addr=<secondary IP>" --channels="0,1" --rx_rate 200e6
The second interface is specified by the extra argument <b>second_addr</b>.
\subsection x3x0_hw_pcie PCI Express (Desktop)
<b>Important Note: The USRP X-Series provides PCIe connectivity over MXI cable.
We will use the 'MXI' nomenclature for the rest of this manual.</b>
### Installing the PCIe Kernel Drivers
In order to use the USRP X-Series on a PCIe-over-MXI connection, you need to
install the NI RIO drivers on your system. Please follow the instructions here:
\ref page_ni_rio_kernel
### Installing the PCI Express Interface Kit
Follow the instructions listed in the <a href="http://www.ni.com/pdf/manuals/371976c.pdf">Set Up Your MXI-Express x4 System</a>
document to setup the NI PCIe-8371 module.
### Installing the USRP X300/X310
- Prior to installing the module, make sure that the PC is powered off.
- Using a MXI-Express Cable connect the USRP X300/X310 to the NI PCIe-8371.
- Connect the AC/DC power supply to the device and plug the supply into a wall outlet.
- Power on the USRP X300/X310 device using the power switch located in the bottom-right corner of the front panel.
- Power on the PC (The OS automatically recognizes the new device)
<b>Note:</b> The USRP device is not hot-pluggable over PCI Express. Any connection changes with only be detected by your
computer after a successful reboot.
### Troubleshooting
Two possible failure modes are your computer not booting when connected to your
USRP device through MXI-Express, and Windows not properly discovering your
devices (for example, there is a yellow exclamation point on a PCI to PCI
bridge in Windows Device Manager, despite drivers for all devices being
installed). These situations often are due to programming errors in PCI Express
device configuration of the BIOS. To use this software, you need a MXI-Express
device that supports Mode 1 operation.
Refer to <a href="http://download.ni.com/support/softlib//PXI/MXIe%20Compatibility%20Software/1.5.0/readme.html#SupportedHardware">NI MXI-Express BIOS Compatibility Software Readme</a>
for more information.
The BIOS Compatibility Software can be downloaded for Windows from the <a href="http://www.ni.com/download/mxi-express-bios-compatibility-software-1.5/3764/en/"> MXI-Express BIOS Compatibility Software page</a>.
\subsection x3x0_hw_pcie_laptop PCI Express (Laptop)
<b>Important Note: The USRP X-Series provides PCIe connectivity over MXI cable
We will use the 'MXI' nomenclature for the rest of this manual.</b>
### Installing the PCIe Kernel Drivers
In order to use the USRP X-Series on a PCIe-over-MXI connection, you need to
install the NI RIO drivers on your system. Please follow the instructions here:
\ref page_ni_rio_kernel
### Installing the PCI Express Card
Follow the instructions listed in the “Installing an NI ExpressCard-8360 Host Card” section of the
<a href="http://www.ni.com/pdf/manuals/373259d.pdf#page=10">Set Up Your MXI-Express x1 System</a>
document to setup the NI ExpressCard-8360B module.
### Installing the USRP X300/X310
Because a laptop computer is not grounded, follow this procedure to safely connect a laptop
computer to your USRP device.
- Connect the AC/DC power supply to the device and plug the supply into a wall outlet. Ensure that the USRP device is powered off.
- Touch the NI ExpressCard-8360B and a metal part of the USRP device simultaneously. Do not install the NI ExpressCard-8360B into the laptop computer yet.
- Connect the cable to the NI ExpressCard-8360B and USRP.
- Plug the NI ExpressCard-8360B into an available ExpressCard slot. If your laptop computer is already running (or hibernating, suspended, etc.) when you install an NI ExpressCard-8360B, you must reboot to detect the USRP. Otherwise, the USRP is detected when you start your computer.
\b Note: The USRP device is not hot-pluggable over PCI Express. Any connection changes will only be detected by your computer after a successful reboot.
\section x3x0_jtag On-Board JTAG Programmer
The USRP X3x0 includes an on-board JTAG programmer, built into the motherboard.
To connect to this JTAG device, simply connect your computer to the USB JTAG
port on the front of the X3x0 device. You may now use the JTAG programmer in
the same way you would use any other, including:
- Vivado (standard workflow, see below)
- <a href="http://www.xilinx.com/support/download/index.htm">Xilinx Programming Tools (ISE, iMPACT)</a>
- <a href="http://www.xilinx.com/tools/cspro.htm">Xilinx Chipscope</a>
- <a href="https://www.digilentinc.com/Products/Detail.cfm?NavPath=2,66,828&Prod=ADEPT2">Digilent ADEPT</a>
In order to use the JTAG programmer with the Xilinx tools, the Digilent drivers and plugin have to be installed first. Although recent versions of Vivado ship with the driver, it has to still be manually installed.
To install first locate your Vivado installation path on a Linux system (default is `/opt/Xilinx/Vivado/<Version>`):
sudo `find /opt/Xilinx/Vivado/<Version> -name install_digilent.sh`
The USRP-X series device should now be usable with all the tools mentioned above.
\section x3x0_load_fpga_imgs Load FPGA Images onto the Device
The USRP-X Series device ships with a bitstream pre-programmed in the flash,
which is automatically loaded onto the FPGA during device power-up. However,
a new FPGA image can be configured over the PCI Express interface or the
on-board USB-JTAG programmer. This process can be seen as a "one-time load", in
that if you power-cycle the device, it will not retain the FPGA image.
Please note that this process is *different* than replacing the FPGA image
stored in the flash, which will then be automatically loaded the next time the
device is reset.
\subsection x3x0_load_fpga_imgs_fpga_flavours FPGA Image Flavors
The USRP-X Series devices contains two SFP+ ports for the two Ethernet channels.
Because the SFP+ ports support both 1 Gigabit (SFP) and 10 Gigabit (SFP+)
transceivers, several FPGA images are shipped with UHD to determine the
behavior of the above interfaces.
| FPGA Image Flavor | SFP+ Port 0 Interface | SFP+ Port 1 Interface |
|---------------------|------------------------|------------------------|
| HG (Default) | 1 Gigabit Ethernet | 10 Gigabit Ethernet |
| XG | 10 Gigabit Ethernet | 10 Gigabit Ethernet |
| HA | 1 Gigabit Ethernet | Aurora |
| XA | 10 Gigabit Ethernet | Aurora |
Note: The Aurora images need to be built manually from the FPGA source code.
FPGA images are shipped in 2 formats:
- **LVBITX**: LabVIEW FPGA configuration bitstream format (for use over PCI Express and Ethernet)
- **BIT**: Xilinx configuration bitstream format (for use over Ethernet and JTAG)
To get the latest images, simply use the uhd_images_downloader script. On Unix systems, use this command:
$ [sudo] uhd_images_downloader
On Windows, use:
<path_to_python.exe> <install-path>/bin/uhd_images_downloader.py
\subsection x3x0_load_fpga_imgs_pcie Use PCI Express to load FPGA images
UHD requires a valid LabVIEW FPGA configuration bitstream file (LVBITX) to use the USRP-X Series
device over the PCI Express bus. LabVIEW FPGA is \b not required to use UHD with a USRP-X Series device.
Because FPGA configuration is a part of normal operation over PCI Express, there is no setup required
before running UHD.
The \e fpga tag can be set in the optional device args passed to indicate the FPGA image flavor to UHD.
If the above tag is specified, UHD will attempt to load the FPGA image with the requested flavor from the
UHD images directory. If the tag is not specified, UHD will automatically detect the flavor of the image
and attempt to load the corresponding configuration bitstream onto the device. Note that if UHD detects
that the requested image is already loaded onto the FPGA then it will not reload it.
\subsection x3x0_load_fpga_imgs_jtag Use JTAG to load FPGA images
The USRP-X Series device features an on-board USB-JTAG programmer that can be accessed on the front-panel
of the device. There are multiple tools available to access the FPGA through the JTAG connector (see \ref x3x0_jtag).
If you have Vivado installed, we provide a command-line script to flash images. Make sure your X3x0 is powered on and connected to your computer using the front panel USB JTAG connector (USB 2.0 is fine for this). Head to the X3x0 FPGA directory, then run the following commands:
$ cd uhd/fpga-src/usrp3/top/x300 # Assuming this is where the FPGA code is checked out
$ source ./setupenv.sh
$ viv_jtag_program /path/to/bitfile.bit
If you have iMPACT installed, you can use the `impact_jtag_programmer.sh` tool to install images. Then run the tool:
<path_to_uhd_tools>/impact_jtag_programmer.sh --fpga-path=<fpga_image_path>
\section x3x0_flash Load the Images onto the On-board Flash
To change the FPGA image stored in the on-board flash, the USRP-X Series device
can be reprogrammed over the network or PCI Express. Once you have programmed an
image into the flash, that image will be automatically loaded on the FPGA
during the device boot-up sequence.
\b Note:
Different hardware revisions require different FPGA images.
Determine the revision number from the sticker on the rear of the device.
If you are manually specifying an FPGA path, the utility will not try to
detect your device information, and you will need to use this number to
select which image to burn.
\b Note:
The image loader utility will default to using the appropriate BIT file if no custom
FPGA image path is specified, but it is compatible with BIN, BIT, and LVBITX
images.
\subsection uhd_image_loader_tool Use the image loader over Ethernet
Automatic FPGA path, detect image type:
uhd_image_loader --args="type=x300,addr=<IP address>"
Automatic FPGA path, select image type:
uhd_image_loader --args="type=x300,addr=<IP address>,fpga=<HG or XG>"
Manual FPGA path:
uhd_image_loader --args="type=x300,addr=<IP address>" --fpga-path="<path to FPGA image>"
\subsection uhd_image_loader_tool_pcie Use the image loader over PCI Express
Automatic FPGA path, detect image type:
uhd_image_loader --args="type=x300,resource=<NI-RIO resource>"
Automatic FPGA path, select image type:
uhd_image_loader --args="type=x300,resource=<NI-RIO resource>,fpga=<HG or XG>"
Manual FPGA path:
uhd_image_loader --args="type=x300,resource=<NI-RIO resource>" --fpga-path="<path to FPGA image>"
\subsection x3x0_flash_bricking Device recovery and bricking
It is possible to put the device into an unusable state by loading bad images ("bricking").
Fortunately, the USRP-X Series device can be loaded with a good image temporarily using the USB-JTAG interface.
Once booted into the safe image, the user can once again load images onto the device over Ethernet or PCI Express.
See Section \ref x3x0_load_fpga_imgs_jtag on how to load the FPGA image onto the device using a JTAG interface.
After running the JTAG process, a new image can be flashed onto the device using the usual procedure
to permently recover the device.
\section x3x0_setup_network Setup Networking
The USRP-X Series only supports Gigabit and Ten Gigabit Ethernet and will not work with a 10/100 Mbps interface.
<b>Please note that 10 Gigabit Ethernet defines the protocol, not necessary the
medium. For example, you may use 10GigE over optical with optical SFP+
transceiver modules.</b>
\subsection x3x0_setup_network_host_interface Setup the host interface
The USRP-X Series communicates at the IP/UDP layer over the Gigabit and Ten Gigabit Ethernet.
The default IP address for the USRP X300/X310 device depends on the Ethernet Port and interface used.
You must configure the host Ethernet interface with a static IP address on the same subnet as the connected
device to enable communication, as shown in the following table:
Ethernet Interface | USRP Ethernet Port | Default USRP IP Address | Host Static IP Address | Host Static Subnet Mask | Address EEPROM key
---------------------|-------------------------|--------------------------|-------------------------|-------------------------|-------------------
Gigabit | Port 0 (HG Image) | 192.168.10.2 | 192.168.10.1 | 255.255.255.0 | `ip-addr0`
Ten Gigabit | Port 0 (XG Image) | 192.168.30.2 | 192.168.30.1 | 255.255.255.0 | `ip-addr2`
Ten Gigabit | Port 1 (HG/XG Image) | 192.168.40.2 | 192.168.40.1 | 255.255.255.0 | `ip-addr3`
As you can see, the X300/X310 actually stores different IP addresses, which all address the device differently: Each combination of Ethernet port and interface type (i.e., Gigabit or Ten Gigabit) has its own IP address. As an example, when addressing the device through 1 Gigabit Ethernet on its first port (Port 0), the relevant IP address is the one stored in the EEPROM with key `ip-addr0`, or 192.168.10.2 by default.
See \ref x3x0cfg_hostpc_netcfg_ip on details how to change your machine's IP address and MTU size to work well with the X300.
\subsection x3x0_setup_network_multidevs Multiple devices per host
For maximum throughput, one Ethernet interface per USRP is recommended,
although multiple devices may be connected via an Ethernet switch.
In any case, each Ethernet interface should have its own subnet,
and the corresponding USRP device should be assigned an address in that subnet.
Example:
### Configuration for USRP-X Series device 0:
- Ethernet interface IPv4 address: `192.168.10.1`
- Ethernet interface subnet mask: `255.255.255.0`
- USRP-X Series device IPv4 address: `192.168.10.2`
### Configuration for USRP-X Series device 1:
- Ethernet interface IPv4 address: `192.168.110.1`
- Ethernet interface subnet mask: `255.255.255.0`
- USRP-X Series device IPv4 address: `192.168.110.2`
If all devices are to be used in a compound, see also \ref page_multiple.
\subsection x3x0_setup_change_ip Change the USRP's IP address
You may need to change the USRP's IP address for several reasons:
- to satisfy your particular network configuration
- to use multiple USRP-X Series devices on the same host computer
- to set a known IP address into USRP (in case you forgot)
To change the USRP's IP address,
you must know the current address of the USRP,
and the network must be setup properly as described above.
You must also know which IP address of the X300 you want to change, as identified by their address EEPROM key (e.g. `ip-addr0`, see the table above).
Run the following commands:
\b UNIX:
cd <install-path>/lib/uhd/utils
./usrp_burn_mb_eeprom --args=<optional device args> --values="ip-addr0=192.168.10.3"
\b Windows:
cd <install-path>\lib\uhd\utils
usrp_burn_mb_eeprom.exe --args=<optional device args> --values="ip-addr0=192.168.10.3"
You must power-cycle the device before you can use this new address.
\section x3x0_setup_clocking Setup Clocking
\subsection x3x0_set_clocking_dboard Daughterboard clock
The X3x0 provides a clock signal to the daughterboards which is used as a
reference clock for synthesizers and other components that require clocks.
There are daughterboards that require non-default clock values. See
Section \ref config_devaddr on how to change the clock value, and \ref page_dboards
for information specific to certain daughterboards.
Not all combinations of daughterboards work within the same device, if
daughterboard clock requirements conflict. Note that some daughterboards
will try and set the daughterboard clock rate themselves. Refer to the
<a href="https://kb.ettus.com/X300/X310#Choosing_an_RF_Daughterboard">Ettus Research
Knowledge Base article on the X300/X310</a> for more information on daughterboard
compatibilty.
\section x3x0_addressing Addressing the Device
\subsection x3x0_addressing_singledev Single device configuration
In a single-device configuration,
the USRP device must have a unique IPv4 address on the host computer.
The USRP can be identified through its IPv4 address, resolvable hostname, NI-RIO resource name or by other means.
See the application notes on \ref page_identification.
Use this addressing scheme with the uhd::usrp::multi_usrp interface (not a typo!).
Example device address string representation for a USRP-X Series device with IPv4 address 192.168.10.2:
addr=192.168.10.2
Example device address string representation for a USRP-X Series device with RIO resource name `RIO0` over PCI Express:
resource=RIO0
\subsection x3x0_addressing_multidevcfg Multiple device configuration
In a multi-device configuration,
each USRP device must have a unique IPv4 address on the host computer.
The device address parameter keys must be suffixed with the device index.
Each parameter key should be of the format \<key\>\<index\>.
Use this addressing scheme with the uhd::usrp::multi_usrp interface.
- The order in which devices are indexed corresponds to the indexing of the transmit and receive channels.
- The key indexing provides the same granularity of device identification as in the single device case.
Example device address string representation for 2 USRPs with IPv4 addresses **192.168.10.2** and **192.168.20.2**:
addr0=192.168.10.2, addr1=192.168.20.2
See also \ref page_multiple.
\section x3x0_troubleshooting Troubleshooting
\subsection x3x0_comm_issues Communication Issues
When setting up a development machine for the first time,
you may have various difficulties communicating with the USRP device.
The following tips are designed to help narrow down and diagnose the problem.
\subsection x3x0_comm_issues_runtimeerr RuntimeError: no control response
This is a common error that occurs when you have set the subnet of your network
interface to a different subnet than the network interface of the USRP device. For
example, if your network interface is set to **192.168.20.1**, and the USRP device is **192.168.10.2**
(note the difference in the third numbers of the IP addresses), you
will likely see a 'no control response' error message.
Fixing this is simple - just set the your host PC's IP address to the same
subnet as that of your USRP device. Instructions for setting your IP address are in the
previous section of this documentation.
\subsection x3x0_comm_issues_firewall Firewall Issues
When the IP address is not specified,
the device discovery broadcasts UDP packets from each Ethernet interface.
Many firewalls will block the replies to these broadcast packets.
If disabling your system's firewall
or specifying the IP address yields a discovered device,
then your firewall may be blocking replies to UDP broadcast packets.
If this is the case, we recommend that you disable the firewall
or create a rule to allow all incoming packets with UDP source port **49152**.
\subsection x3x0_comm_issues_ping Ping the device
The USRP device will reply to ICMP echo requests ("ping").
A successful ping response means that the device has booted properly
and that it is using the expected IP address.
ping 192.168.10.2
\subsection x3x0_comm_issues_not_enumerated Device not enumerated over PCI-Express (Linux)
UHD requires the RIO device manager service to be running in order to
communicate with an X-Series USRP over PCIe. This service is installed as
a part of the USRP RIO (or NI-USRP) installer. On Linux, the service is not
started at system boot time, and is left to the user to control. To start it,
run the following command:
sudo niusrprio_pcie start
If the device still does not enumerate after starting the device manager, make sure that the host computer
has successfully detected it. You can do so by running the following command:
lspci -k -d 1093:c4c4
A device similar to the following should be detected:
$ lspci -k -d 1093:c4c4
04:00.0 Signal processing controller: National Instruments ...
Subsystem: National Instruments Device 76ca
Kernel driver in use: niusrpriok_shipped
- All USRP X-Series devices should appear with 'Subsystem: National Instruments Device'
- The device ID following can be:
- USRP X300: 7736 or 7861
- USRP X310: 76CA or 7862
- NI-USRP 294xR: 772B, 77FB, 772C, 77FC, 772D, 77FD, 772E, 7853, 785B, 7854, 785C, 7855, 785D or 7856
- NI-USRP 295xR: 772F, 77FE, 7730, 77FF, 7731, 7800, 7732, 7857, 785E, 7858, 785F, 7859, 7860 or 785A
\subsection x3x0_comm_issues_not_enumerated_win Device not enumerated over PCI-Express (Windows)
UHD requires the RIO device manager service to be running in order to
communicate with an X-Series USRP over PCIe.
This service is installed as a part of the USRP RIO (or NI-USRP) installer. On Windows, it can be found in
the **Services** section in the Control Panel and it is started at system boot time. To ensure that the
service is indeed started, navigate to the Services tag in the Windows Task Manager and ensure that the
status of **niusrpriorpc** is "Running".
If the device still does not enumerate after starting the device manager, make sure that the host computer
has successfully detected it. You can do so by checking if your device shows up in the Windows Device Manager.
\subsection x3x0_comm_issues_monitor Monitor the host network traffic
Use Wireshark to monitor packets sent to and received from the device.
\subsection x3x0_comm_problems_leds Observe Ethernet port LEDs
When there is network traffic arriving at the Ethernet port, LEDs will light up.
You can use this to make sure the network connection is correctly set up, e.g.
by pinging the USRP and making sure the LEDs start to blink.
\subsection x3x0_corrupt_eeprom Corrupt EEPROM
This is a rare bug in which the X-Series device's on-board EEPROM becomes corrupt and reports an incorrect
firmware and FPGA version. In this situation, UHD cannot properly use the device. To fix this bug, use
the **usrp_burn_mb_eeprom** utility as follows:
usrp_burn_mb_eeprom --args="type=x300,recover_mb_eeprom,disable_adc_self_test" --values="revision=(NUM HERE)"
Afterward, power-cycle your X-Series device for the changes to take effect.
\section x3x0_hw_notes Hardware Notes
\subsection x3x0_hw_fpanel Front Panel
\image html x3x0_fp_overlay.png "X3x0"
- **JTAG**: USB connector for the on-board USB-JTAG programmer
- **RF A Group**
+ **TX/RX LED**: Indicates that data is streaming on the TX/RX channel on daughterboard A
+ **RX2 LED**: Indicates that data is streaming on the RX2 channel on daughterboard A
- **REF**: Indicates that the external Reference Clock is locked
- **PPS**: Indicates a valid PPS signal by pulsing once per second
- **AUX I/O**: Front panel GPIO connector.
- **GPS**: Indicates that GPS reference is locked
- **LINK**: Indicates that the host computer is communicating with the device (Activity)
- **RF B Group**
+ **TX/RX LED**: Indicates that data is streaming on the TX/RX channel on daughterboard B
+ **RX2 LED**: Indicates that data is streaming on the RX2 channel on daughterboard B
- **PWR**: Power switch
\subsection x3x0_hw_rear_panel Rear Panel
\image html x3x0_rp_overlay.png "X3x0 Rear Panel"
- **PWR**: Connector for the USRP-X Series power supply
- **1G/10G ETH**: SFP+ ports for Ethernet interfaces
- **REF OUT**: Output port for the exported reference clock
- **REF IN**: Reference clock input
- **PCIe x4**: Connector for Cabled PCI Express link
- **PPS/TRIG OUT**: Output port for the PPS signal
- **PPS/TRIG IN**: Input port for the PPS signal
- **GPS**: Connection for the GPS antenna
\subsection x3x0_hw_x3x0_hw_ref10M Ref Clock - 10 MHz
Using an external 10 MHz reference clock, a square wave will offer the best phase
noise performance, but a sinusoid is acceptable. The power level of the reference clock cannot exceed +15 dBm.
\subsection x3x0_hw_pps PPS - Pulse Per Second
Using a PPS signal for timestamp synchronization requires a square wave signal with the following a 5Vpp amplitude.
To test the PPS input, you can use the following tool from the UHD examples:
- `<args>` are device address arguments (optional if only one USRP device is on your machine)
cd <install-path>/lib/uhd/examples
./test_pps_input --args=\<args\>
\subsection x3x0_hw_gpsdo Internal GPSDO
Please see \ref page_gpsdo_x3x0 for information on configuring and using the internal GPSDO.
\subsection x3x0_hw_gpio Front Panel GPIO
### Connector
\image html x3x0_gpio_conn.png "X3x0 GPIO Connector"
The GPIO port is not meant to drive big loads. You should not try to source more than 5mA per pin.
The +3.3V is for ESD clamping purposes only and not designed to deliver high currents.
### Pin Mapping
- Pin 1: +3.3V
- Pin 2: Data[0]
- Pin 3: Data[1]
- Pin 4: Data[2]
- Pin 5: Data[3]
- Pin 6: Data[4]
- Pin 7: Data[5]
- Pin 8: Data[6]
- Pin 9: Data[7]
- Pin 10: Data[8]
- Pin 11: Data[9]
- Pin 12: Data[10]
- Pin 13: Data[11]
- Pin 14: 0V
- Pin 15: 0V
Please see the \ref page_gpio_api for information on configuring and using the GPIO bus.
\subsection x3x0_hw_on_board_leds On-Board LEDs
|LED | | Description |
|-------|---------------|-------------------------------|
|DS1 |1.2V |power |
|DS2 |TXRX1 |Red: TX, Green: RX |
|DS3 |RX1 |Green: RX |
|DS4 |REF |reference lock |
|DS5 |PPS |flashes on edge |
|DS6 |GPS |GPS lock |
|DS7 |SFP0 |link |
|DS8 |SFP0 |link activity |
|DS10 |TXRX2 |Red: TX Green: RX |
|DS11 |RX2 |Green: RX |
|DS12 |6V |daughterboard power |
|DS13 |3.8V |power |
|DS14 |3.3V |management power |
|DS15 |3.3V |auxiliary management power |
|DS16 |1.8V |FPGA power |
|DS16 |3.3V |FPGA power |
|DS19 |SFP1 |link |
|DS20 |SFP1 |link active |
|DS21 |LINK |link activity |
\subsection x3x0_hw_chipscope Debugging custom FPGA designs with Xilinx Chipscope
Xilinx chipscope allows for debugging custom FPGA designs similar to a logic analyzer.
USRP-X series devices can be used with Xilinx chipscope using the onboard USB JTAG connector.
Further information on how to use Chipscope can be found in the Xilinx Chipscope Pro Software and Cores User Guide (UG029).
\section x3x0_misc Miscellaneous
\subsection x3x0_misc_settings Configuring the device in an application
During runtime, the device can be configured in several different ways.
The following pages may shed some light:
- \ref page_configuration
- uhd::stream_args_t
- \ref multiple_channumbers
\subsection x3x0_misc_multirx Multiple RX channels
There are two complete DDC and DUC DSP chains in the FPGA. In the single channel case,
only one chain is ever used. To receive from both channels, the user must set the **RX** or **TX**
subdevice specification.
In the following example, a TVRX2 is installed.
Channel 0 is sourced from subdevice **RX1**,
and channel 1 is sourced from subdevice **RX2** (**RX1** and **RX2** are antenna connectors on the TVRX2 daughterboard).
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~{.cpp}
usrp->set_rx_subdev_spec("A:RX1 A:RX2");
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
\subsection x3x0_misc_sensors Available Sensors
The following sensors are available for the USRP-X Series motherboards;
they can be queried through the API.
- **ref_locked** - clock reference locked (internal/external)
- Other sensors are added when the GPSDO is enabled
*/
// vim:ft=doxygen:
|