aboutsummaryrefslogtreecommitdiffstats
path: root/host/docs/usrp_n3xx.dox
blob: 19a9fc650c2dd124076eab449daabb0fcc9753e2 (plain)
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
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
1012
1013
1014
1015
1016
1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
1031
1032
1033
1034
1035
1036
1037
1038
1039
1040
1041
1042
1043
1044
1045
1046
1047
1048
1049
1050
1051
1052
1053
1054
1055
1056
1057
1058
1059
1060
1061
1062
1063
1064
1065
1066
1067
1068
1069
1070
1071
1072
1073
1074
1075
1076
1077
1078
1079
1080
1081
1082
1083
1084
1085
1086
1087
1088
1089
1090
1091
1092
1093
1094
1095
1096
1097
1098
1099
1100
1101
1102
1103
1104
1105
1106
1107
1108
1109
1110
1111
1112
1113
1114
1115
1116
1117
1118
1119
1120
1121
1122
1123
1124
1125
1126
1127
1128
1129
1130
1131
1132
1133
1134
1135
1136
1137
1138
1139
1140
1141
1142
1143
1144
1145
1146
1147
1148
1149
1150
1151
1152
1153
1154
1155
1156
1157
1158
1159
1160
1161
1162
1163
1164
1165
1166
1167
1168
1169
1170
1171
1172
1173
1174
1175
1176
1177
1178
1179
1180
1181
1182
1183
1184
1185
1186
1187
1188
1189
1190
1191
1192
1193
1194
1195
1196
1197
1198
1199
1200
1201
1202
1203
1204
1205
1206
1207
1208
1209
1210
1211
1212
1213
1214
1215
1216
1217
1218
1219
1220
1221
1222
1223
1224
1225
1226
1227
1228
1229
1230
1231
1232
1233
1234
1235
1236
1237
1238
1239
1240
1241
1242
1243
1244
1245
1246
1247
1248
1249
1250
1251
1252
1253
1254
1255
1256
1257
1258
1259
1260
1261
1262
1263
1264
1265
1266
1267
1268
1269
1270
1271
1272
1273
1274
1275
1276
1277
1278
1279
1280
1281
1282
1283
1284
1285
1286
1287
1288
1289
1290
1291
1292
1293
1294
1295
1296
1297
1298
1299
1300
1301
1302
1303
1304
1305
1306
1307
1308
1309
1310
1311
1312
1313
1314
1315
1316
1317
1318
1319
1320
1321
1322
1323
1324
1325
1326
1327
1328
1329
1330
1331
1332
1333
1334
1335
1336
1337
1338
1339
1340
1341
1342
1343
1344
1345
1346
1347
1348
1349
1350
1351
1352
1353
1354
1355
1356
1357
1358
1359
1360
1361
1362
1363
1364
1365
1366
1367
1368
1369
1370
1371
1372
1373
1374
1375
1376
1377
1378
1379
1380
1381
1382
1383
1384
1385
1386
1387
1388
1389
1390
1391
1392
1393
1394
1395
1396
1397
1398
1399
1400
1401
1402
1403
1404
1405
1406
1407
1408
1409
1410
1411
1412
1413
1414
1415
1416
1417
1418
1419
1420
1421
1422
1423
1424
1425
1426
1427
1428
1429
1430
1431
1432
1433
1434
1435
1436
1437
1438
1439
1440
1441
1442
1443
1444
1445
1446
1447
1448
1449
1450
1451
1452
1453
1454
1455
1456
1457
1458
1459
1460
1461
1462
1463
1464
1465
1466
1467
1468
1469
1470
1471
1472
1473
1474
1475
1476
1477
1478
1479
1480
1481
1482
1483
1484
1485
1486
1487
1488
1489
1490
1491
1492
1493
1494
1495
1496
1497
1498
1499
1500
1501
1502
1503
1504
1505
1506
1507
1508
1509
1510
1511
1512
1513
1514
1515
1516
1517
1518
1519
1520
1521
1522
1523
1524
1525
1526
1527
1528
1529
1530
1531
1532
1533
1534
1535
1536
1537
1538
1539
1540
1541
1542
1543
1544
1545
1546
1547
1548
1549
1550
1551
1552
1553
1554
1555
1556
1557
1558
1559
1560
1561
1562
1563
1564
1565
1566
1567
1568
1569
1570
1571
1572
1573
1574
1575
1576
1577
1578
1579
1580
1581
1582
1583
1584
1585
1586
1587
1588
1589
1590
1591
1592
1593
1594
1595
1596
1597
1598
1599
1600
1601
1602
1603
1604
1605
1606
1607
1608
1609
1610
1611
1612
1613
1614
1615
1616
1617
1618
1619
1620
1621
1622
1623
1624
1625
1626
1627
1628
1629
1630
1631
1632
1633
1634
1635
1636
1637
1638
1639
1640
1641
1642
1643
1644
1645
1646
1647
1648
1649
1650
1651
1652
1653
1654
1655
1656
1657
1658
1659
1660
1661
1662
1663
1664
1665
1666
1667
1668
1669
1670
1671
1672
1673
1674
1675
1676
1677
1678
1679
1680
1681
1682
1683
1684
1685
1686
1687
1688
1689
1690
1691
1692
1693
1694
1695
1696
1697
1698
1699
1700
1701
1702
/*! \page page_usrp_n3xx USRP N3xx Series

\tableofcontents

\section n3xx_feature_list Comparative features list

- Hardware Capabilities:
	- Dual SFP+ Transceivers (can be used with 1 GigE, 10 GigE, and Aurora)
	- External PPS input & output
	- External 10 MHz input & output (20 MHz and 25 MHz inputs also supported)
	- External White Rabbit time/frequency reference input support
	- Internal 25 MHz reference clock
	- Internal GPSDO for timing, location, and 20 MHz reference clock + PPS
	- External GPIO Connector with UHD API control
	- External USB Connection for built-in JTAG debugger and serial console
        - Xilinx Zynq SoC with dual-core ARM Cortex A9 (Speedgrade 2) and
          Kintex-7 FPGA (XC7Z100 or XC7Z035 depending on variant)

- Software Capabilities:
        - Full Linux system running on the ARM core
        - Runs MPM (see also \ref page_mpm)

- FPGA Capabilities:
	- Timed commands in FPGA
	- Timed sampling in FPGA
        - RFNoC capability

The N3XX series of USRPs is designed as a platform. The following USRPs are
variants of the N3XX series:

\subsection n3xx_feature_list_mg N310/N300 4-channel/2-channel Transceiver

\image html N310isoExplode.png N310 Exploded View

- Supported master clock rates: 122.88 MHz, 125 MHz, 153.6 MHz
- Tuning range: 10 MHz to 6 GHz
    - Below 300 MHz, additional LOs and mixer stages
    are used to shift the signal into the frequency range of the AD9371
    - Tunable down to 1 MHz in UHD however performance is not guaranteed
- Support for external LOs
- 4 RX DDC chains in FPGA (2 for N300)
- 4 TX DUC chain in FPGA (2 for N300)
- 2 SFP+ connectors

The N310 is a 4-channel transmitter/receiver based on the AD9371 transceiver IC.
It has two daughterboards with one AD9371 each; every daughterboard provides
two RF channels. Note that the product code "N310" refers to the module
consisting of mother- and daughterboard, the daughterboard itself is referred to
by its codename, "Magnesium".

The N300 is a subset of the N310. It has 2 TX/RX channels (on a single
daughterboard; the daughterboard itself is the same as the N310) and a smaller
FPGA (XCZ035). Also, it does not have connectors for external LOs.

\subsection n3xx_feature_list_rh N320/N321 2-channel Transceiver

- Supported master clock rates: 200 MHz, 245.76 MHz, 250 MHz
- Tuning range: 3 MHz to 6 GHz
    - Below 450 MHz, an additional LO and mixer stage
    is used to shift the signal into the range of the main LO stage
    - Tunable down to 1 MHz in UHD however performance is not guaranteed
- Support for external LOs
- 2 RX DDC chains in FPGA
- 2 TX DUC chain in FPGA
- LO sharing between multiple devices (N321 only)
- 2 SFP+ connectors + 1 QSFP+ connector

The N320 is a 2-channel transmitter/receiver using discrete components instead
of an RFIC. It has two daughterboards, each has one ADC/DAC and provides one
RF channel.

The difference between the N320 and the N321 is in its LO sharing capability.
The N320 has a single input for the TX and RX LOs, respectively. The N321 also
has the ability to export its LO up to four times, making it possible to share
LOs between a large number of N321 devices without having to provide an
external, separate LO source. Due to number of connectors required to provide
the large number of LO outputs, the N321 does not have a front-panel GPIO
connector.

The N320 has a higher maximum analog bandwidth than the N310. It can provide
rates up to 250 Msps, resulting in a usable analog bandwidth of up to 200 MHz.
In order to better use the high available rates, the N320/N321 devices have an
additional QSFP+ connector on the back panel which can be used for streaming
data to and from the radios. In order to facilitate the higher bandwidth, UHD
uses a technology called \ref page_dpdk "Data Plane Development Kit (DPDK)".
See the DPDK page for details on how it can improve streaming, and how to use
it.

\section n3xx_overview Overview

\subsection n3xx_zynq The Zynq CPU/FPGA and host operating system

The main CPU of the N310 is a Xilinx Zynq SoC XC7Z100 (exception: The N300). It
is both a dual-core ARM Cortex A9 CPU and Kintex-7 FPGA on a single die. The
CPU is clocked at 800 MHz (speedgrade 2).

The programmable logic (PL, or FPGA) section of the SoC is responsible for
handling all sampling data, the 10 GigE network connections, and any other
high-speed utility such as custom RFNoC logic. The processing system (PS, or CPU)
is running a custom-build OpenEmbedded-based Linux operating system. The OS is
responsible for all the device and peripheral management, such as running MPM,
configuring the network interfaces, running local UHD sessions, etc.

It is possible to connect to the host OS either via SSH or serial console (see
sections \ref n3xx_getting_started_ssh and \ref n3xx_getting_started_serial,
respectively).

\subsection n3xx_micro The STM32 microcontroller

The STM32 microcontroller controls various low-level features of the N3xx series
motherboard: It controls the power sequencing, reads out fan speeds and some of
the temperature sensors. It is connected to the Zynq via an I2C bus.

It is possible to log into the STM32 using the serial interface
(see \ref n3xx_getting_started_serial_micro). This will allow certain low-level
controls, such as remote power cycling should the CPU have become unresponsive
for whatever reason.

\subsection n3xx_sdcard The SD card

The N3XX series uses a micro SD card as its main storage. The entire root file
system (Linux kernel, libraries) and any user data are stored on this SD card.

The SD card is partitioned into four partitions:

1. Boot partition (contains the bootloader). This partition usually does not
   require touching.
2. A data partition, mounted in /data. This is the only partition that is not
   erased during file system updates.
2. Two identical system partitions (root file systems). These contain the
   operating system and the home directory (anything mounted under / that is not
   the data or boot partition). The reason there are two of these is to enable
   remote updates: An update running on one partition can update the other one
   without any effect to the currently running system. Note that the system
   partitions are erased during updates and are thus unsuitable for permanently
   storing information.

Note: It is possible to access the currently inactive root file system by
mounting it. After logging into the device using serial console or SSH (see the
following two sections), run the following commands:

    $ mkdir temp
    $ mount /dev/mmcblk0p3 temp
    $ ls temp # You are now accessing the idle partition:
    bin   data  etc   lib         media  proc  sbin  tmp    usr
    boot  dev   home  lost+found  mnt    run   sys   uboot  var

The device node in the mount command will likely differ, depending on which
partition is currently already mounted.

\section n3xx_getting_started Getting started

This will run you through the first steps relevant to getting your USRP N3XX
series up and running.

\subsection n3xx_getting_started_assembling Assembling the N3XX

Unlike the X300 or N200 series, there is no assembly of daughterboards required.
Members of the N3XX product family, such as the N310, ship with daughterboards
pre-installed.

Checklist:
- Connect power and network
- Read security settings
- Connect clocking (if required)
- Connect external LOs (if required)

\subsection n3xx_getting_started_fs_update Updating the file system

Before doing any major work with a newly acquired USRP N300/N310, it is
recommended to update the file system. Updating the filesystem can be
accomplished directly on the N300/N310 by using Mender or externally by
manually writing an image onto a micro SD card and inserting it.  While
manual updating is faster, Mender requires no direct physical access to the
device.  For details on using Mender, see Section \ref n3xx_rasm_mender .

Manual updating is simply loading an image on the micro SD card.  The first step
in that process is to obtain an image.

To obtain the default micro SD card image for a specific version of UHD, install
that version of UHD (3.11.0.1 or later) on a host system with Internet access and run:

    $ uhd_images_downloader -t n3xx_common_sdimg_default

   The image will be downloaded to
   `<UHD_INSTALL_DIR>/share/uhd/images/usrp_n3xx_fs.sdimg`,
   where `<UHD_INSTALL_DIR>` is the UHD installation directory.

To load an image onto the micro SD card, connect the card to the host and run:

    $ sudo dd if=<YOUR_IMAGE> of=/dev/<YOUR_SD_CARD> bs=1M

   The `<YOUR_IMAGE>` is the path to the micro SD card image
   (i.e.`<UHD_INSTALL_DIR>/share/uhd/images/usrp_n3xx_fs.sdimg`).

   The `<YOUR_SD_CARD>` device node depends on your operating system and which
   other devices are plugged in. Typical values are `sdb` or `mmcblk0`.<br>
   CAUTION:  Operating on the wrong device can cause damage to that device.

The micro SD card used can be the original SD card shipped with the device or
another one that is at least 16 GB in size.

Insert the updated micro SD card and power on the device.

\subsection n3xx_getting_started_serial Serial connection

It is possible to gain root access to the device using a serial terminal
emulator. Most Linux, OSX, or other Unix flavours have a tool called 'screen'
which can be used for this purpose, by running the following command:

    $ sudo screen /dev/ttyUSB2 115200

In this command, we prepend 'sudo' to elevate user privileges (by default,
accessing serial ports is not available to regular users), we specify the
device node (in this case, `/dev/ttyUSB2`), and the baud rate (115200).

The exact device node depends on your operating system's driver and other USB
devices that might be already connected. Modern Linux systems offer alternatives
to simply trying device nodes; instead, the OS might have a directory of
symlinks under `/dev/serial/by-id`:

    $ ls /dev/serial/by-id
    usb-Digilent_Digilent_USB_Device_25163511FE00-if00-port0
    usb-Digilent_Digilent_USB_Device_25163511FE00-if01-port0
    usb-Silicon_Labs_CP2105_Dual_USB_to_UART_Bridge_Controller_007F6CB5-if00-port0
    usb-Silicon_Labs_CP2105_Dual_USB_to_UART_Bridge_Controller_007F6CB5-if01-port0

Note: Exact names depend on the host operating system version and may differ.

Every N3XX series device connected to USB will by default show up as four
different devices. The devices labeled "USB_to_UART_Bridge_Controller" are the
devices that offer a serial prompt. The first (with the `if00` suffix) connects
to Linux, whereas the second connects to the STM32 microcontroller.
If you have multiple N3XX devices connect, you may have to try out multiple
devices. In this case, to use this symlink instead of the raw device node
address, modify the command above to:

    $ sudo screen /dev/serial/by-id/usb-Silicon_Labs_CP2105_Dual_USB_to_UART_Bridge_Controller_007F6CB5-if00-port0 115200

You should be presented with a shell prompt similar to the following:

    root@ni-n3xx-311FE00:~#

On this prompt, you can enter any Linux command available. Using the default
configuration, the serial console will also show all kernel log messages (unlike
when using SSH, for example), and give access to the boot loader (U-boot
prompt). This can be used to debug kernel or bootloader issues more efficiently
than when logged in via SSH.

\subsubsection n3xx_getting_started_serial_micro Connecting to the microcontroller

The STM32 microcontroller (which controls the power sequencing, among other
things) also has a serial console available. To connect to the microcontroller,
use the other UART device. In the example above:

    $ sudo screen /dev/serial/by-id/usb-Silicon_Labs_CP2105_Dual_USB_to_UART_Bridge_Controller_007F6CB5-if01-port0 115200

It provides a very simple prompt. The command 'help' will list all available
commands. A direct connection to the microcontroller can be used to hard-reset
the device without physically accessing it (i.e., emulating a power button press)
and other low-level diagnostics.

\subsection n3xx_getting_started_ssh SSH connection

The USRP N-Series devices have two network connections: The dual SFP ports,
and an RJ-45 connector. The latter is by default configured by DHCP; by plugging
it into into 1 Gigabit switch on a DHCP-capable network, it will get assigned
an IP address and thus be accessible via ssh.

In case your network setup does not include a DHCP server, refer to the section
\ref n3xx_getting_started_serial. A serial login can be used to assign an IP address manually.

After the device obtained an IP address you can log in from a Linux or OSX
machine by typing:

    $ ssh root@ni-n3xx-311FE00 # Replace with your actual device name!

Depending on your network setup, using a `.local` domain may work:

    $ ssh root@ni-n3xx-311FE00.local

Of course, you can also connect to the IP address directly if you know it (or
set it manually using the serial console).

Note: The device's hostname is derived from its serial number by default
(`ni-n3xx-$SERIAL`). You can change the hostname by creating the file
`/data/network/hostname`, saving the desired hostname in it, then rebooting.

On Microsoft Windows, the connection can be established using a tool such as
Putty, by selecting a username of root without password.

Like with the serial console, you should be presented with a prompt like the
following:

    root@ni-n3xx-311FE00:~#

\subsection n3xx_getting_started_connectivity Network Connectivity

The RJ45 port (eth0) comes up with a default configuration of DHCP,
that will request a network address from your DHCP server (if available on your
network).

The SFP+ (sfp0, sfp1) ports are configured with static addresses 192.168.10.2/24
and 192.168.20.2/24, respectively. Their default MTU value is 9000. These
settings are independent of the image type (HG vs. XG), i.e., the defaults are
the same for 1 GigE and 10 GigE (unlike the X310!).

The configuration for the `sfpX` port is stored in `/data/network/sfpX.network`.

For configuration please refer to the
<a href=https://www.freedesktop.org/software/systemd/man/systemd.network.html>systemd-networkd manual pages</a>

The factory settings are as follows:

    eth0 (DHCP):

        [Match]
        Name=eth0

        [Network]
        DHCP=v4

        [DHCPv4]
        UseHostname=false

    sfp0 (static):

        [Match]
        Name=sfp0

        [Network]
        Address=192.168.10.2/24

        [Link]
        MTUBytes=9000

    sfp1 (static):

        [Match]
        Name=sfp1

        [Network]
        Address=192.168.20.2/24

        [Link]
        MTUBytes=9000


Additional notes on networking:

- Care needs to be taken when editing these files on the device, since
  vi / vim sometimes generates undo files (e.g.
  `/data/network/sfp0.network~`), that systemd-networkd might
  accidentally pick up.
- Temporarily setting the IP addresses or MTU sizes via `ifconfig` or other
  command line tools will only change the value until the next reboot or reload
  of the FPGA image.
- If the MTU of the device and host computers differ, streaming issues can
  occur.

\subsection n3xx_getting_started_security Security-related settings

The N3XX ships without a root password set. It is possible to ssh into the
device by simply connecting as root, and thus gaining access to all subsystems.
To set a password, run the command

    $ passwd

on the device.

\subsection n3xx_getting_started_fpga_update Updating the FPGA

Updating the FPGA follows the same procedure as other USRPs. Use the `uhd_image_loader`
command line utility to upload a new FPGA image onto the device.

A common reason to update the FPGA image is in the case of a UHD/FPGA compat
number mismatch (for example, if UHD has been updated, and now expects a newer
version of the FPGA than is on the device). In this case, simply run

    $ uhd_images_downloader

to update the local cache of FPGA images. Then, run

    $ uhd_image_loader --args type=n3xx,addr=ni-n3xx-311fe00

to update the FPGA using the default settings. If a custom FPGA image is targeted
for uploading, use the `--fpga-path` command line argument. Run

    $ uhd_image_loader --help

to see a full list of command line options. Note that updating the FPGA image
will force a reload of the FPGA, which will temporarily take down the SFP
network interfaces (and temporary settings, such as applied via `ifconfig` on
the command line, will be lost).

\subsubsection n3xx_getting_started_fpga_update_flavors FPGA Image Flavors

The USRP-N300 Series devices contains two SFP+ ports for the two Ethernet channels.
Because SFP+ ports can be used for either 1 Gigabit (SFP) or 10 Gigabit (SFP+)
transceivers, several FPGA images are shipped with UHD to determine the
behavior of the above interfaces.

Interfaces can be used for either 1 Gigabit Ethernet, 10 Gigabit Ethernet,
Aurora (using 10 Gigabit speeds), and White Rabbit (the White Rabbit interface
does *not* support streaming, it only provides a time reference). See also
\ref n3xx_synchronization_whiterabbit. We provide the following flavors of FPGA
images in our default image set:

|  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                |
|  AA                 |  Aurora                |  Aurora                |
|  WX                 |  White Rabbit          |  10 Gigabit Ethernet   |

The N320 has an additional QSFP port, and therefore has additional FPGA flavors
(AQ, XQ). For more information on those, see \ref n3xx_rh_sfp_protocols.

\section n3xx_usage Using an N3XX USRP from UHD

Like any other USRP, all N3XX USRPs are controlled by the UHD software. To
integrate a USRP N3XX into your C++ application, you would generate a UHD
device in the same way you would for any other USRP:

~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~{.cpp}
auto usrp = uhd::usrp::multi_usrp::make("type=n3xx");
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

For a list of which arguments can be passed into make(), see Section
\ref n3xx_usage_device_args.

\subsection n3xx_usage_device_args Device arguments

 Key                   | Description                                                                  | Supported Devices | Example Value
-----------------------|------------------------------------------------------------------------------|-------------------|---------------------
 addr                  | IPv4 address of primary SFP+ port to connect to.                             | All N3xx          | addr=192.168.30.2
 second_addr           | IPv4 address of secondary SFP+ port to connect to.                           | All N3xx          | second_addr=192.168.40.2
 mgmt_addr             | IPv4 address or hostname which to connect the RPC client. Defaults to `addr'.| All N3xx          | mgmt_addr=ni-sulfur-311FE00 (can also go to RJ45)
 find_all              | When using broadcast, find all devices, even if unreachable via CHDR.        | All N3xx          | find_all=1
 force_reinit          | Force full reinitialization of all subsystems. Will increase init time.      | N310              | force_reinit=1
 master_clock_rate     | Master Clock Rate in Hz                                                      | N310              | master_clock_rate=125e6
 identify              | Causes front-panel LEDs to blink. The duration is variable.                  | N310              | identify=5 (will blink for about 5 seconds)
 serialize_init        | Force serial initialization of motherboards.                                 | All N3xx          | serialize_init=1
 skip_init             | Skip the initialization process for the device.                              | All N3xx          | skip_init=1
 time_source           | Specify the time (PPS) source.                                               | All N3xx          | time_source=internal
 clock_source          | Specify the reference clock source.                                          | All N3xx          | clock_source=internal
 ref_clk_freq          | Specify the external reference clock frequency, default is 10 MHz.           | N310              | ref_clk_freq=20e6
 init_cals             | Specify the bitmask for initial calibrations of the RFIC.                    | N310              | init_cals=BASIC
 init_cals_timeout     | Timeout for initial calibrations in milliseconds.                            | N310              | init_cals_timeout=45000
 discovery_port        | Override default value for MPM discovery port.                               | All N3xx          | discovery_port=49700
 rpc_port              | Override default value for MPM RPC port.                                     | All N3xx          | rpc_port=49701
 tracking_cals         | Specify the bitmask for tracking calibrations of the RFIC.                   | N310              | tracking_cals=ALL
 rx_lo_source          | Initialize the source for the RX LO.                                         | N310              | rx_lo_source=external
 tx_lo_source          | Initialize the source for the TX LO.                                         | N310              | tx_lo_source=external
 rfic_digital_loopback | Digital data loopback inside the RFIC.                                       | N310              | rfic_digital_loopback=1
 tx_gain_profile       | Initialize device with a specific TX gain profile.                           | N310              | tx_gain_profile=manual
 rx_gain_profile       | Initialize device with a specific RX gain profile.                           | N310              | rx_gain_profile=manual
 tx_band_map           | Semicolon-separated list of TX band edges.                                   | N310              | tx_band_map=0.0;723.18e6;1623.18e6;3323.18e6
 rx_band_map           | Semicolon-separated list of RX band edges.                                   | N310              | rx_band_map=0.0;431e6;601e6;1051e6;1601e6;2101e6;2701e6

\subsection n3xx_usage_init Device Initialization

To maximally speed up UHD, an initialization sequence is run when the device
(or more accurately, the MPM service) starts. This means even on the first run
of UHD, the device will already be initialized into a usable state. Note that
it will always come up in a default state, which can be changed by modifying the
configuration file in `/etc/uhd/mpm.conf` (see also \ref page_configfiles),
such as this:

~~~{.ini}
; Note: To boot into a fully initialized state, a clock reference must be
; connected before turning the device on if it set to external here:
[n3xx]
clock_source=external
~~~

If you prefer not to have the device initialize on boot, but rather have a fast
boot time, add the line `skip_boot_init=1` to your `/etc/uhd/mpm.conf` file.
This will force a full initialization of the device the first time a UHD session
is started, rather than during device boot.

For more details on the initialization sequence, see the corresponding section
for the specific N3XX device:
- \ref n3xx_mg_initialization


\subsection n3xx_usage_subdevspec Subdev Specifications

The RF ports on the front panel of the N300/N310 correspond to the following
subdev specifications:

Label | Subdev Spec
------|------------
RF0   | A:0
RF1   | A:1
RF2   | B:0 (N310 only)
RF3   | B:1 (N310 only)

The RF ports on the front panel of the N320/N321 correspond to the following
subdev specifications:

Label | Subdev Spec
------|------------
RF0   | A:0
RF1   | B:0

Note: Before UHD 3.12.0.0, the subdev spec options were different (A:0, B:0,
etc.). Make sure to update your application if you migrated from an earlier UHD
version.

The following example will map RF0 onto channel 0 of a uhd::usrp::multi_usrp
object, and RF3 onto channel 1:

~~~~~{.cpp}
auto usrp = uhd::usrp::multi_usrp("type=n3xx");
usrp->set_rx_subdev_spec("A:0 B:1");
// This line will now set the gain for RF3 to 20.0:
usrp->set_rx_gain(20.0, 1);
// And this will affect RF0:
usrp->set_rx_gain(20.0, 0);
~~~~~

See also uhd::usrp::subdev_spec_t.

\subsection n3xx_usage_sensors The sensor API

Like other USRPs, the N3x0 series have daughterboard and motherboard sensors.
When using uhd::usrp::multi_usrp, the following API calls are relevant to
interact with the sensor API:

- uhd::usrp::multi_usrp::get_mboard_sensor_names()
- uhd::usrp::multi_usrp::get_mboard_sensor()
- uhd::usrp::multi_usrp::get_tx_sensor_names()
- uhd::usrp::multi_usrp::get_rx_sensor_names()
- uhd::usrp::multi_usrp::get_tx_sensor()
- uhd::usrp::multi_usrp::get_rx_sensor()

The following motherboard sensors are always available:

- `ref_locked`: This will check that all the daughterboards have locked to the
  external reference.
- `temp`: The temperature of the die itself
- `fan`: The current fan speed
- `gps_lock`: GPS lock
- `gps_time`: GPS time in seconds sin ce the epch
- `gps_tpv`: A TPV report from GPSd serialized as JSON
- `gps_sky`: A SKY report from GPSd serialized as JSON


\section n3xx_rasm Remote Management

\subsection n3xx_rasm_mender Mender: Remote update capability

Mender is a third-party software that enables remote updating of the root
file system without physically accessing the device (see also the
[Mender website](https://mender.io)). Mender can be executed locally on the
device, or a Mender server can be set up which can be used to remotely update
an arbitrary number of USRP devices. Mender servers can be self-hosted, or
hosted by Mender (see [mender.io](https://mender.io) for pricing and
availability).

When updating the file system using Mender, the tool will overwrite the root file
system partition that is not currently mounted (note: every SD card comes with
two separate root file system partitions, only one is ever used at a single
time). Any data stored on that partition will be permanently lost. After
updating that partition, it will reboot into the newly updated partition. Only
if the update is confirmed by the user, the update will be made permanent. This
means that if an update fails, the device will be always able to reboot into the
partition from which the update was originally launched (which presumably is in
a working state). Another update can be launched now to correct the previous,
failed update, until it works.
See also Section \ref n3xx_sdcard.

To initiate an update from the device itself, download a Mender artifact
containing the update itself. These are files with a `.mender` suffix.

Then run mender on the command line:

    $ mender install /path/to/latest.mender

The artifact can also be stored on a remote server:

    $ mender install http://server.name/path/to/latest.mender

This procedure will take a while. After mender has logged a successful update,
reboot the device:

    $ reboot

If the reboot worked, and the device seems functional, commit the changes so
the boot loader knows to permanently boot into this partition:

    $ mender commit

To identify the currently installed Mender artifact from the command line, the
following file can be queried:

    $ cat /etc/mender/artifact_info

If you are running a hosted server, the updates can be initiated from a web
dashboard. From there, you can start the updates without having to log into the
device, and can update groups of USRPs with a few clicks in a web GUI. The
dashboard can also be used to inspect the state of USRPs. This is a simple way
to update groups of rack-mounted USRPs with custom file systems.

\subsection n3xx_rasm_salt Salt: Remote configuration management and execution

Salt (also known as SaltStack, see [Salt Website](https://saltstack.com)) is a
Python-based tool for maintaining fleets of remote devices. It can be used to
manage USRP N3XX series remotely for all types of settings that are not
controlled by UHD. For example, if an operator would like to reset the root
password on multiple devices, or install custom software, this tool might be a
suitable choice.

Salt is a third-party project with its [own documentation](https://docs.saltstack.com/en/latest/),
which should be consulted for configuring it. However, the Salt minion is
installed by default on every N3XX device. To start it, simply log on to the
device and run:

    $ systemctl start salt-minion

To permanently enable it at every boot, run (this won't by itself launch the
salt-minion):

    $ systemctl enable salt-minion

To make use of Salt, both the device needs to be configured (the "minion") and,
typically, a server to act as the Salt master. Refer to the Salt documentation
on how to configure the minion and the master. A typical sequence to get started
will look like this:

1. Install the salt-master package on the server (e.g. by running `apt install salt-master`
   if the server is an Ubuntu system), and make sure the Salt master is running.
2. Add the network address / hostname of that server to the `/etc/salt/minion`
   file on the device by editing the `master:` line.
3. Launch the Salt minion on the USRP by running the command `systemctl start salt-minion`.
4. The minion will try to connect to the master. You need to authorize the
   minion by running `salt-key -a $hostname` where `$hostname` is the name of
   the minion.
5. Once the device is authorized, you can try various commands to see if the
   communication was established:


    $ [sudo] salt '*' test.ping
    ni-n3xx-311FE00:
        True
    $ [sudo] salt '*' network.interfaces
    ni-n3xx-311FE00:
        ----------
        eth0:
            ----------
            hwaddr:
                02:00:03:11:fe:00
            inet:
                |_
                  ----------
                  address:
                      10.16.32.113
                  broadcast:
                      10.16.33.255
                  label:
                      eth0
                  netmask:
                      255.255.254.0
            up:
                True
    $ [...]


\section n3xx_synchronization Clock/Time Synchronization

\subsection n3xx_synchronization_internal Internal references

The N3xx series has an onboard GPSDO as well as a 25 MHz reference oscillator,
which can both be used as time- and clock references. The GPSDO will function
as a reference even when there is no GPS reception. It can be powered off to
reduce power usage and interference by supplying the `enable_gps=0` option in
the configuration file (in this case, `gpsdo` cannot be used as a time or clock
reference).

Note that this does not enable the synchronization of multiple devices.
Using an internal reference is the default.

\subsection n3xx_synchronization_external External references

In order to synchronize multiple USRPs, an external reference, such as the
CDA-2990 (OctoClock), is required. If only a clock reference is available, it is
possible to derive an internal PPS signal from the reference (which will allow
devices to share a frequency, but not a time reference). If both an external
clock and time source are provided, devices will be synchronized in frequency
and time.

```cpp
auto usrp = uhd::usrp::multi_usrp::make(
    "type=n3xx,clock_source=external,time_source=external");
```
To reduce phase noise, it may be necessary to power down the GPSDO when using
an external reference.  To do this, just add `enable_gps=False` to the
configuration file in `/etc/uhd/mpm.conf` (see also \ref page_configfiles).


Note: When disabling the GPS with `enable_gps=0` in the configuration file, or
when manually launching MPM, the `gpsdo` reference source is not available.

\subsection n3xx_synchronization_whiterabbit White Rabbit

White Rabbit is an Ethernet-based synchronization procedure; it is an extension
of the IEEE 1588 Precision Time Protocol (PTP). The N3xx device can be
configured as a White Rabbit slave.

To use White Rabbit, it is necessary to provide an appropriate reference via
Ethernet. This reference must be connected to SFP0. Finally, a White Rabbit-compatible
FPGA must be loaded. SFP0 will *not be available for data transport* in this mode.

The White Rabbit image is provided as a default image. To obtain the default
images, simply run:

    $ uhd_images_downloader -t n3xx -t fpga

Then, you can install the WX (or WA) image using `uhd_image_loader`:

    $ uhd_image_loader \
        --args type=n3xx,addr=ni-n3xx-<DEVICE_SERIAL>,WX

Once the image is loaded, select `internal` as the clock source and
`sfp0` as the time source (note: this will fail if the WX or WA image is not
currently loaded):

```cpp
auto usrp = uhd::usrp::multi_usrp::make(
    "type=n3xx,clock_source=internal,time_source=sfp0");
// Or if you want to change it to White Rabbit after initialization:
usrp->set_sync_source(device_addr_t("clock_source=internal,time_source=sfp0"));
// Using the older time/clock source APIs is also possible:
usrp->set_time_source("sfp0");
usrp->set_clock_source("internal");
// The 2nd call can technically be skipped because the device implementations
// will coerce, but for consistency with other code and for being explicit this
// is the preferred way. The 2nd call will immediately return in this case.
```

For more information, refer to the [White Rabbit Homepage](https://www.ohwr.org/projects/white-rabbit),
or the [Ettus Research Knowledge Base](https://kb.ettus.com/Using_Ethernet-Based_Synchronization_on_the_USRP%E2%84%A2_N3xx_Devices).

\section n3xx_fpgio The Front-Panel GPIO

\b Note: The N321 does not have a front-panel GPIO due to lack of panel space.

\b Note: Do not source high currents (more than 5 mA) per pin. The GPIOs are not
designed to drive high loads!

\b Note: Unlike the X300 series, the N3XX series does not have user-programmable
daughterboard GPIOs. The front-panel GPIOs can still be used to track the ATR
state of the radios, though (see below).

The USRP N3xx series has 12 programmable GPIO pins, accessible through the DB15
connector on the front panel. The front-panel GPIO on the N3xx series has a
programmable source per pin. For every pin, it is possible to either drive it
from the PS (i.e., from Linux), or via UHD.

When UHD is driving a pin, each one of the radios (up to four in the case of the
N310) can drive the GPIO pin. In that case, the pin can either track the ATR
register of that radio channel, or it can be freely programmed.

When the PS is driving the pin, UHD releases control of the GPIO pin and it can
be programmed from Linux using udev.

The following example demonstrates how the GPIO can be used:

~~~{.cpp}
auto usrp = uhd::usrp::multi_usrp::make("type=n3xx");
auto banks = usrp->get_gpio_src_banks();
// banks[0] == "FP0"
auto gpio_src = usrp->get_gpio_src("FP0");
// Pin 0 shall be controlled by the PS:
gpio_src[0] = "PS";
// Pin 1 and 2 shall be controlled by channel 0:
gpio_src[1] = "RF0";
gpio_src[2] = "RF0";
// Pin 3 shall be controlled by channel 1:
gpio_src[3] = "RF1";
// Now update who is driving which pin:
usrp->set_gpio_src("FP0", gpio_src);
// Pin 0 is no longer accessible from UHD.
// Pin 1 shall go high when channel 0 is receiving, or during full-duplex
// Pin 2 shall be hard-coded to go high (GPIO mode)
usrp->set_gpio_attr("FP0A", "CTRL", 0x2, 0x6); // 1 == ATR, 0 == GPIO
// Set the pins to be outputs:
usrp->set_gpio_attr("FP0A", "DDR", 0x6, 0x6); // 1 == output, 0 == input
// ATR on pin 1 is off when not receiving:
usrp->set_gpio_attr("FP0A", "ATR_0X", 0x0, 0x2);
usrp->set_gpio_attr("FP0A", "ATR_TX", 0x0, 0x2);
usrp->set_gpio_attr("FP0A", "ATR_RX", 0x2, 0x2);
usrp->set_gpio_attr("FP0A", "ATR_XX", 0x2, 0x2);
// Hard-code pin 2 to stay high:
usrp->set_gpio_attr("FP0A", "OUT", 0x4, 0x4);
~~~


\section n3xx_troubleshooting Troubleshooting

\subsection n3xx_troubleshooting_seqerrs Errors while streaming

If you are getting sequence or other errors while streaming, make sure the MTU
settings of the network devices match up. UHD will try and do an automatic MTU
discovery, but there are cases when the automatic MTU discovery will yield
incorrect values. Often, the host computer MTU is set smaller than the device
MTU, but the MTU discovery will detect a larger MTU than the host computer MTU
in this error case.

The default MTU for the N3x0 series is 9000. The simplest solution is often to
set the host computer MTU to 9000 as well:

    $ [sudo] ifconfig eth0 mtu 9000 # Replace eth0 with the device you're using

Of course, you can also reduce the MTU on the device to match your host
computer, see Section \ref n3xx_getting_started_connectivity.

\subsection n3xx_troubleshooting_bist Built-in Self-Test (BiST)

The N3x0 series devices have a built-in self-test that can be used to verify
the hardware. It is not automatically run, but it can be invoked anytime by
running the `n3xx_bist` executable. Calling

    n3xx_bist -h

will list the available options. Tests can be run by specifying their name, e.g.

    n3xx_bist gpsdo

will test the functionality of the GPSDO. Calling `n3xx_bist standard` will run
a standard set of tests, verifying some base peripherals such as the RTC, the
fan and temperature sensors, etc.

Some tests require special hardware connected. For example, there are multiple
tests to verify the SFP+ adapters. There are two types of test for those: For
the `sfp0_loopback` and `sfp1_loopback` tests, a loopback module must be plugged
into the SFP+. For the `sfp_loopback` test, the two ports need to be connected
together.

Tests may also load different FPGA images, if required. The aforementioned
SFP tests will load the AA FPGA image and use Aurora to run the BER tests on
the SFP ports. This is particularly relevant if either a custom image was
loaded, or if there is an active SSH or other connection coming in via the SFP+
ports.

\section n3xx_theory_of_ops Theory of Operation

The N3xx-series are devices based on the MPM architecture (see
also: \ref page_mpm). Inside the Linux operating system running on the ARM
cores, there is hardware daemon which needs to be active in order for the
device to function as a USRP (it is enabled to run by default).

A large portion of hardware-specific setup is handled by the daemon.

\section n3xx_fsbuild Building custom filesystems and SD card images

Ettus Research provides SD card images at regular intervals, but there can be
good reasons to build custom SD cards, e.g., to test the very latest UHD or MPM
for which there has not been an SD card release, to add own applications to the
SD card, or to run a modified version of UHD.

Note that building SD cards is very disk space and RAM intensive.

\subsection n3xx_fsbuild_docker Using Docker to build filesystems

Ettus Research provides a Docker containers to facilitate building filesystems.
Refer to the <a href="https://github.com/EttusResearch/ettus-docker/blob/master/oe-build/README.md"> README </a> for more details.

\section n3xx_software_dev Modifying and compiling UHD and MPM for the N3XX

N3xx devices ship with all relevant software installed on the SD card. Updating
UHD and/or MPM on the SD card is typically easiest done by updating the
filesystem image (see Section \ref n3xx_rasm_mender). However, it is certainly
possible to compile UHD and MPM by hand, e.g., in order to modify and try out
changes without having to build entire filesystems in between. At Ettus R&D,
this mode of operation is often used for rapid iteration cycles.

\subsection n3xx_software_dev_mpm_native Compiling MPM natively

In general, compiling natively is not a recommended way of compiling code for
the ARM processors. However, in the case of MPM, the amount of C++ code that
needs to be compiled is very little, and a full compile of MPM will take a few
minutes even on the N3xx. First, you need to get a copy of the MPM source code
onto your device. If you have an internet connection, you can use git to pull
it directly from the Ettus repository (all commands are run on the device
itself, inside the home directory):

    $ git clone https://github.com/EttusResearch/uhd.git

You can also SSHFS it from another computer:

    $ mkdir uhd # Create a new, empty directory called uhd
    $ sshfs user@yourcomputer:src/uhd uhd # This will mount ~/src/uhd from the remote machine to ~/uhd on the N3xx

Now, create a build directory and use the regular cmake/make procedure to kick
off a build. It can be advantageous (especially for slow network connections)
to create the build directory outside of the repository directory:

    $ mkdir build_mpm
    $ cd build_mpm # You are now in /home/root/build_mpm
    $ cmake ../uhd/mpm
    $ make -j2 install # This will take several minutes

Note that this overwrites your system MPM. You can install MPM to another
location by specifying `-DCMAKE_INSTALL_PREFIX`, but make sure to update all of
your paths appropriately.

If you prefer cross-compiling MPM the same way as UHD, refer to the following
sections and adapt the instructions for UHD appropriately.

\subsection n3xx_software_dev_sdk Obtaining an SDK

The recommended way to develop software for the N3xx is to cross-compile. By
running the compiles on a desktop or laptop computer, you will be able to speed
up compile times considerably (compiling UHD natively for the N3xx would take
many hours).

SDKs are distributed along with other binaries. They contain a cross-compiler,
a cross-linker, a cross-debugger, and all the libraries available on the device
to mirror its environment.

The SDK is shipped in the same way as the other binaries, and you can download
the correct version using `uhd_images_downloader`

    $ uhd_images_downloader -t sdk -t n3xx

To unpack and install the SDK, simply execute it after downloading it:

    $ cd /usr/local/share/uhd/images # Change this to where your images are stored
    $ ./oecore-x86_64-cortexa9hf-neon-toolchain-nodistro.0.sh

If this doesn't work, the executable permissions of the file might have been
lost (this can occur with some versions of Python). In that case, add those
permissions back before executing the `.sh` file:

    $ chmod +x oecore-x86_64-cortexa9hf-neon-toolchain-nodistro.0.sh

Executing the `.sh` file will prompt you for an installation path.  Please
ensure you have sufficient disk space, as each of the SDKs may require several
gigabytes of disk space (depending on the image flavor selected).

This will allow you to compile UHD as well as (depending on the image flavor)
other software, such as GNU Radio.

Please note, that while several toolchains can be installed in parallel, they
have to be installed to different directories.

\subsection n3xx_software_dev_sdkusage SDK Usage

Having installed the toolchain in the last step,
in order to build software for your device open a new shell and type:

    $ . $SDKPATH/environment-setup-armv7ahf-vfp-neon-oe-linux-gnueabi

This will modify the PATH, CC, CXX etc, environment variables and allow you to compile software for your USRP N3xx device.
To verify all went well you can try:

    $ $CC -dumpmachine

which should return 'arm-oe-linux-gnueabi'.

\subsubsection n3xx_software_dev_uhd  Building UHD

-# Obtain the UHD source code via git or tarball
-# Set up your environment as described in \ref n3xx_software_dev_sdkusage
-# Type the following in the build directory (assuming a build in host/build):

        $ cmake -DCMAKE_TOOLCHAIN_FILE=../host/cmake/Toolchains/oe-sdk_cross.cmake -DCMAKE_INSTALL_PREFIX=/usr .. # Add any CMake options you desire
        $ make # You can run make -j12 to compile on 12 processes at once

Note: The UHD you are cross-compiling will not run on your host computer (the
one where you're doing the development). Compiling UHD regularly on your host
computer (with MPMD enabled) will allow you to talk to your N3xx.

\subsubsection n3xx_software_dev_gr Building GNU Radio

-# Obtain the GNU Radio source code via git or tarball
-# Set up your environment as described in \ref n3xx_software_dev_sdkusage
-# Use the following commands to create a build directory, configure and compile gnuradio. You only need create the build directory once.

\code{.sh}
$ mkdir build-arm
$ cd build-arm
$ cmake -Wno-dev -DCMAKE_TOOLCHAIN_FILE=../cmake/Toolchains/oe-sdk_cross.cmake \-DCMAKE_INSTALL_PREFIX=/usr -DENABLE_GR_VOCODER=OFF -DENABLE_GR_ATSC=OFF \
-DENABLE_GR_DTV=OFF -DENABLE_DOXYGEN=OFF ../ # Append any CMake options you desire
\endcode

Several GNU Radio components depend on running binaries built for the build
machine during compile. These binaries can be built and used for cross
compiling, but this is an advanced topic.

\section n3xx_mg N310-specific Features

\subsection n3xx_mg_panels Front and Rear Panel

Like the USRP X300 series, the N310 has connectors on both the front and back
panel. The back panel holds the power connector, all network connections, USB
connections for serial console (see \ref n3xx_getting_started_serial), JTAG,
peripherals, SMA connectors for GPS antenna input, 10 MHz clock reference,
PPS time reference input and output (TRIG in/out), the slot for the SD card
(see also \ref n3xx_sdcard), and indicator LEDs.

The following indicator LEDs are used:

- LINK: This LED will be lit when this USRP has been claimed by a UHD session.
- REF: Indicates a lock to the reference clock. In particular, when using an
       external reference clock, this LED is useful to see if the LMK04828 PLLs
       are locking to this reference clock. Note that some software interaction
       is necessary to enable the LMK04828, and thus this LED may be off even
       if a valid reference clock signal is connected.
- GPS: Indicates a GPS lock (i.e., GPS satellites are in view of the GPS
       antenna and signal levels are sufficient)
- PPS: This LED will blink once every second to indicate a valid PPS signal.

\image html N310rp.png N310 Rear Panel

The front panel is used for all RF connections (including the external LO
inputs, see \ref n3xx_mg_external_lo) and all TX/RX connections, as well as the
front-panel GPIO.

The connectors labeled RF0 and RF1 are also referred to as slot A, and the
connectors labeled RF2 and RF3 are also referred as slot B (matching the
internal connections to the daughterboard. Every slot is powered by a single
AD9371 RFIC).

\image html N310fp.png N310 Front Panel

\subsection n3xx_mg_initialization Device Initialization (Fast and Slow)

When a UHD session is created, an initialization sequence is started. As part of
the initialization sequence, the following steps are performed:

- All clocking is initialized
- The JESD links are trained and brought up (between the FPGA and the AD9371)
- The AD9371 is reset, its firmware is uploaded, and calibrations are
  initialized (See also \ref n3xx_mg_calibrations)
- N310 only: The multi-chip synchronization is performed to align all the RFICs
  to the common time and clock reference

This sequence can take a while, depending on the master clock rate and the
calibration sequence. To speed things up, the device will retain a state
between sessions, but only if no relevant settings were touched. In particular,
changing the master clock rate, the clock source, or the calibration masks will
force a full re-initialization which is very slow compared to the fast
re-initialization. By setting the log level to DEBUG you will be able to observe
the exact settings that cause fast vs. slow re-initialization.
If you require a full re-initialization every time a UHD session is spawned,
specify the `force_reinit` flag as a device arg. Specifying it will always do
the full, slow initialization, but will guarantee a full reset of the RFIC.

To maximally speed up UHD, an initialization sequence is run when the device
(or more accurately, the MPM service) starts. This means even on the first run
of UHD, the device will already be initialized into a usable state. Note that
it will always come up in a default state, which can be changed by modifying the
configuration file in `/etc/uhd/mpm.conf` (see also \ref page_configfiles),
such as this:

~~~{.ini}
; Note: To boot into a fully initialized state, a clock reference must be
; connected before turning the device on if it set to external here:
[n3xx]
master_clock_rate=122.88e6
clock_source=external
~~~

If you prefer not to have the device initialize on boot, but rather have a fast
boot time, add the line `skip_boot_init=1` to your `/etc/uhd/mpm.conf` file.

If there are multiple N3x0 devices in a single UHD session, they will be
initialized in parallel. Note that this behaviour can be changed serial
initialization by adding `serialize_init=1` to the device args
(see \ref n3xx_usage_device_args).

\subsection n3xx_mg_calibrations RF Calibrations

The onboard RFIC (AD9371) has built-in calibrations which can be enabled from
UHD. A more detailed description of the calibrations can be found in the AD9371
user guide, see chapter "Quadrature Error Correction, Calibration, and ARM
configuration".

Not all calibrations available on the AD9371 are applicable to the USRP N310.
However, those calibrations that are applicable can be enabled/disabled at
initialization time using the `tracking_cals` and `init_cals` device args (see
also \ref n3xx_usage_device_args). These device can be set to the precise bit
mask the chip uses to set those calibrations (e.g., `init_cals=0x4DFF,tracking_cals=0xC3`)
or they can use the following descriptive keys provided by UHD
(e.g.`init_cals=DEFAULT,tracking_cals=TX_QEC|RX_QEC`). The `|` symbol can be
used to combine keys (equivalent to a bitwise OR).

Calibrations can significantly delay the initialization of a session. By only
picking relevant calibrations, sessions can be initialized faster.

Key (`init_cal`)        | Function
------------------------|-----------------------------------
TX_BB_FILTER            | Tx baseband filter calibration
ADC_TUNER               | ADC tuner calibration
TIA_3DB_CORNER          | Rx TIA filter calibration
DC_OFFSET               | Rx DC offset calibration
TX_ATTENUATION_DELAY    | Tx attenuation delay
RX_GAIN_DELAY           | Rx gain delay calibration
FLASH_CAL               | ADC flash calibration
PATH_DELAY              | Path delay calibration
TX_LO_LEAKAGE_INTERNAL  | Tx LO leakage internal initial calibration
TX_LO_LEAKAGE_EXTERNAL  | Tx LO leakage external initial calibration (requires external LO)
TX_QEC_INIT             | Tx QEC initial
LOOPBACK_RX_LO_DELAY    | Loopback ORx LO delay (ORx not connected by default!)
LOOPBACK_RX_RX_QEC_INIT | Loopback Rx QEC initial calibration
RX_LO_DELAY             | Rx LO delay
RX_QEC_INIT             | Rx QEC initial calibration
BASIC                   | Preset for minimal calibrations (TX_BB_FILTER, ADC_TUNER, TIA_3DB_CORNER, DC_OFFSET and FLASH_CAL)
OFF                     | Preset for disabling all initial calibrations
DEFAULT                 | Preset for enabling most calibrations (BASIC plus TX_ATTENUATION_DELAY, RX_GAIN_DELAY, PATH_DELAY, RX_QEC_INIT, TX_LO_LEAKAGE_INTERNAL, TX_QEC_INIT, LOOPBACK_RX_LO_DELAY)
ALL                     | Enable all applicable calibrations

Key (`tracking_cal`)    | Function
------------------------|-----------------------------------
TRACK_RX1_QEC           | Rx1 QEC tracking
TRACK_RX2_QEC           | Rx2 QEC tracking
TRACK_ORX1_QEC          | ORx1 QEC tracking
TRACK_ORX2_QEC          | ORx1 QEC tracking
TRACK_TX1_LOL           | Tx1 LO leakage tracking
TRACK_TX2_LOL           | Tx2 LO leakage tracking
TRACK_TX1_QEC           | Tx1 QEC tracking
TRACK_TX2_QEC           | Tx2 QEC tracking
OFF                     | Disable all tracking
RX_QEC                  | Enable all RX QEC tracking
TX_QEC                  | Enable all TX QEC tracking
TX_LOL                  | Enable all TX LO leakage tracking
DEFAULT                 | Enable all QEC tracking
ALL                     | Enable all tracking (except ORx)

\subsection n3xx_mg_external_lo External LOs

The N310 has inputs for external local oscillators. For every daughterboard,
there is one input for TX and RX, respectively, resulting in 4 LO inputs total
per N310.

Reasons to use an external LO include:

- Improving phase alignment: The N310 itself has no way of aligning phase
  between channels, and phase will be random between runs.  By applying an
  external LO, the phase ambiguity is reduced to 180 degrees, produced by a
  by-2 divider in the AD9371 transceiver IC.
- Improving phase noise: The quality of the onboard LO depends on the external
  reference clock, among other things. By providing a custom LO signal, it is
  possible to more accurately tune, assuming the externally generated LO signal
  is coming from a high-quality oscillator.


\subsection n3xx_mg_eeprom Storing user data in the EEPROM

The N310 daughterboard has an EEPROM which is primarily used for storing the
serial number, product ID, and other product-specific information. However, it
can also be used to store user data, such as calibration information.

Note that EEPROMs have a limited number of write cycles, and storing user data
should happen only when necessary. Writes should be kept at a minimum.

Storing data on the EEPROM is done by loading a uhd::eeprom_map_t object into
the property tree. On writing this property, the driver code will serialize
the map into a binary representation that can be stored on the EEPROM.

\subsection n3xx_mg_revs Module and Motherboard/Daughterboard Revisions

The N310 module consists of three PCBs: The motherboard and two daughterboards.
Every PCB has a hardware revision number. Modules are always assembled such that
the daughterboards have the same revision number. The module revision number is
derived from the combination of daughterboard and motherboard hardware
revisions. The following table explains which module revision contains which
PCB revisions:

Module Revision | Motherboard Revision | Daughterboard Revision | Minimum UHD Version
----------------|----------------------|------------------------|--------------------
A               | D                    | D                      | 3.11.0.0
B               | F                    | E                      | 3.12.0.0
C               | G                    | E                      | 3.13.0.2
D               | H                    | E                      | 3.14.0.0

The module revision is printed on the sticker on the underside of an N310 module
chassis, it is contained within the part number. For example, if the sticker
says "P/N: 141064A-01L", it is a revision A module.

\subsection n3xx_mg_regmap FPGA Register Map

The following tables describe how FPGA registers are mapped into the PS.
This is for reference only, most users will not even have to know about this table.


AXI Slave | Address Range         | UIO Label        | Description
----------|-----------------------|------------------|-----------------------------------
Slave 0   | 4000_0000 - 4000_3fff | -                | Ethernet DMA SFP0
Slave 1   | 4000_4000 - 4000_4fff | misc-enet-regs0  | Ethernet registers SFP0
Slave 2   | 4000_8000 - 4000_bfff | -                | Ethernet DMA SFP1
Slave 3   | 4000_c000 - 4000_cfff | misc-enet-regs1  | Ethernet registers SFP1
Slave 4   | 4001_0000 - 4001_3fff | mboard-regs      | Motherboard control
Slave 5   | 4001_4000 - 4001_41ff | dboard-regs0     | Daughterboard control, slot A
Slave 6   | 4001_8000 - 4001_bfff | dboard-regs1     | Daughterboard control, slot B


<table>
<caption id="multi_row">N310 Register Map</caption>
<tr><th>AXI Slave              <th>Module                       <th>Address               <th>Name            <th>Read/Write  <th>Description
<tr><td rowspan="1">Slave 0    <td rowspan="1">axi_eth_dma0     <td>4000_0000 - 4000_4fff <td>Ethernet DMA    <td>RW          <td>See Linux Driver
<tr><td rowspan="44">Slave 1   <td rowspan="7">n3xx_mgt_io_core <td>4000_4000             <td>PORT_INFO       <td>RO          <td>SFP port information
<tr>                                                            <td>[31:24]               <td>COMPAT_NUM      <td>RO          <td>-
<tr>                                                            <td>[23:18]               <td>6'h0	          <td>RO          <td>-
<tr>                                                            <td>[17]                  <td>activity	      <td>RO          <td>-
<tr>                                                            <td>[16]                  <td>link_up	        <td>RO          <td>-
<tr>                                                            <td>[15:8]                <td>mgt_protocol    <td>RO          <td>0 - None, 1 - 1G, 2 - XG, 3 - Aurora
<tr>                                                            <td>[7:0]                 <td>PORTNUM         <td>RO          <td>-
<tr>                           <td rowspan="8">n3xx_mgt_io_core <td>4000_4004             <td>MAC_CTRL_STATUS <td>RW          <td>Control 10gE and Aurora mac
<tr>                                                            <td>[0]                   <td>ctrl_tx_enable (PROTOCOL = "10GbE")<td>RW<td>-
<tr>                                                            <td>[0]                   <td>bist_checker_en (PROTOCOL = "Aurora")<td>RW<td>-
<tr>                                                            <td>[1]                   <td>bist_gen_en    <td>RW           <td>-
<tr>                                                            <td>[2]                   <td>bist_loopback_en<td>RW          <td>-
<tr>                                                            <td>[8:3]                 <td>bist_gen_rate   <td>RW          <td>-
<tr>                                                            <td>[9]                   <td>phy_areset      <td>RW          <td>-
<tr>                                                            <td>[10]                  <td>mac_clear       <td>RW          <td>-
<tr>                           <td>n3xx_mgt_io_core             <td>4000_4008             <td>PHY_CTRL_STATUS <td>RW          <td>Phy reset control
<tr>                           <td rowspan="3">n3xx_mgt_io_core <td>4000_400C             <td>MAC_LED_CTL     <td>RW          <td>Used by ethtool to indicate port
<tr>                                                            <td>[1]                   <td>identify_enable <td>RW          <td>-
<tr>                                                            <td>[0]                   <td>identify_value  <td>RW          <td>-
<tr>                           <td rowspan="4">mdio_master      <td>4000_4010             <td>MDIO_DATA       <td>RW          <td>-
<tr>                                                            <td>4000_4014             <td>MDIO_ADDR       <td>RW          <td>-
<tr>                                                            <td>4000_4018             <td>MDIO_OP         <td>RW          <td>-
<tr>                                                            <td>4000_401C             <td>MDIO_CTRL_STATUS<td>RW          <td>-
<tr>                           <td rowspan="4">n3xx_mgt_io_core <td>4000_4020             <td>AURORA_OVERUNS  <td>RO          <td>-
<tr>                                                            <td>4000_4024             <td>AURORA_CHECKSUM_ERRORS<td>RO    <td>-
<tr>                                                            <td>4000_4028             <td>AURORA_BIST_CHECKER_SAMPS<td>RO <td>-
<tr>                                                            <td>4000_402C             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>-
<tr>                           <td rowspan="4">eth_switch       <td>4000_5000             <td>MAC_LSB         <td>RW          <td>Device MAC LSB
<tr>                                                            <td>4000_5004             <td>MAC_MSB         <td>RW          <td>Device MAC MSB
<tr>                                                            <td>4000_6000             <td>IP              <td>RW          <td>Device IP
<tr>                                                            <td>4000_6004             <td>PORT1, PORT0    <td>RW          <td>Device UDP port
<tr>                           <td rowspan="2">eth_dispatch     <td>4000_6008             <td>[1] ndest, [0] bcast<td>RW      <td>Enable Crossover
<tr>                                                            <td>4000_600c             <td>[1] my_icmp_type, [0] my_icmp_code<td>
<tr>                           <td rowspan="5">eth_switch       <td>4000_6010             <td>BRIDGE_MAC_LSB  <td>            <td>Bridge SFP ports in ARM
<tr>                                                            <td>4000_6014             <td>BRIDGE_MAC_MSB  <td>            <td>-
<tr>                                                            <td>4000_6018             <td>BRIDGE_IP       <td>            <td>-
<tr>                                                            <td>4000_601c             <td>BRIDGE_PORT1, BRIDGE_PORT0<td>  <td>-
<tr>                                                            <td>4000_6020             <td>BRIDGE_EN       <td>            <td>-
<tr>                           <td rowspan="6">chdr_eth_framer  <td>4000_6108 onwards     <td>LOCAL_DST_IP    <td>W           <td>Destination IP, MAC, UDP for Outgoing Packet for 256 SIDs
<tr>                                                            <td>4000_6208 onwards     <td>LOCAL_DST_UDP_MAC_MSB<td>W      <td>Destination MAC for outgoing packets (MSB)
<tr>                                                            <td>4000_6308 onwards     <td>LOCAL_DST_MAC_LSB<td>W          <td>Destination MAC for outgoing packets (LSB)
<tr>                                                            <td>4000_7000 onwards     <td>REMOTE_DST_IP   <td>W           <td>Destination IP, MAC, UDP for Outgoing Packet for 16 local addrs
<tr>                                                            <td>4000_7400 onwards     <td>REMOTE_DST_UDP_MAC_HI<td>W      <td>Destination MAC (MSB)
<tr>                                                            <td>4000_7800 onwards     <td>REMOTE_DST_MAC_LO<td>W          <td>Destination MAC (LSB)
<tr><td rowspan="1">Slave 2    <td>axi_eth_dma1                 <td>4000_8000             <td>-               <td>            <td>Same as Slave 0, different base address
<tr><td rowspan="3">Slave 3    <td>n3xx_mgt_io_core             <td>4000_c001 - 4000_cfff <td>-               <td>-           <td>Same as Slave 1, different base address
<tr>                           <td>eth_dispatch                 <td>4000_d000 - 4000_dfff <td>-               <td>-           <td>Same as Slave 1, different base address
<tr>                           <td>eth_switch                   <td>4000_e000 - 4000_efff <td>-               <td>-           <td>Same as Slave 1, different base address
<tr><td rowspan="71">Slave 4   <td rowspan="29">n3xx_core       <td>4001_0000             <td>COMPAT_NUM      <td>R           <td>FPGA Compat Number
<tr>                                                            <td>[31:16]               <td>Major           <td>RO          <td>-
<tr>                                                            <td>[15:0]                <td>Minor           <td>RO          <td>-
<tr>                                                            <td>4001_0004             <td>DATESTAMP       <td>RO          <td>-
<tr>                                                            <td>4001_0008             <td>GIT_HASH        <td>RO          <td>-
<tr>                                                            <td>4001_000C             <td>SCRATCH         <td>RO          <td>-
<tr>                                                            <td>4001_0010             <td>REG_DEVICE_ID   <td>RW          <td>RFNoC Device ID
<tr>                                                            <td>4001_0014             <td>REG_RFNOC_INFO  <td>RO          <td>RFNoC Information
<tr>                                                            <td>[31:16]               <td>CHDR_W          <td>RO          <td>RFNoC CHDR Width in Bits
<tr>                                                            <td>[15:0]                <td>RFNOC_PROTOVER  <td>RO          <td>RFNoC Protocol Version
<tr>                                                            <td>4001_0018             <td>CLOCK_CTRL      <td>            <td>
<tr>                                                            <td>[0]                   <td>pps select (internal 10 MHz)<td>RW<td>One-hot encoded pps_select to use the external PPS input.
<tr>                                                            <td>[1]                   <td>pps select (internal 25 MHz)<td>RW<td>One-hot encoded pps_select to use the internally generated PPS with a 10 MHz ref_clk.
<tr>                                                            <td>[2]                   <td>pps select (external)<td>RW     <td>One-hot encoded pps_select to use the internally generated PPS with a 25 MHz ref_clk.
<tr>                                                            <td>[3]                   <td>pps select (GPSDO)<td>RW        <td>One-hot encoded pps_select to use the PPS from the GPSDO input to the FPGA.
<tr>                                                            <td>[4]                   <td>pps output enable<td>RW         <td>
<tr>                                                            <td>[8]                   <td>ref clk mmcm reset<td>WO        <td>-
<tr>                                                            <td>[9]                   <td>ref clk mmcm locked<td>RO       <td>-
<tr>                                                            <td>[12]                  <td>meas clk mmcm reset<td>WO       <td>-
<tr>                                                            <td>[13]                  <td>meas clk mmcm locked<td>RO      <td>-
<tr>                                                            <td>4001_001C             <td>XADC_READBACK   <td>RO          <td>-
<tr>                                                            <td>[11:0]                <td>FPGA temperature<td>RO
<tr>                                                            <td>4001_0020             <td>BUS_CLK_RATE    <td>RO          <td>-
<tr>                                                            <td>4001_0024             <td>BUS_CLK_COUNT   <td>RO          <td>-
<tr>                                                            <td>4001_0028             <td>SFP_PORT0_INFO  <td>RO          <td>-
<tr>                                                            <td>4001_002C             <td>SFP_PORT1_INFO  <td>RO          <td>-
<tr>                                                            <td>4001_0030             <td>FP_GPIO_MASTER  <td>RO          <td>GPIO master select bits. One bit per GPIO. LSB is for GPIO 0. Set bit to 0 for Radio, 1 for PS.
<tr>                                                            <td>4001_0034             <td>FP_GPIO_RADIO_SRC <td>RO        <td>Radio channel source select bits. Two bits per GPIO. Bits [1:0] are for GPIO 0. Set to 00 for channel 0, 01 for channel 1, etc.
<tr>                                                            <td>4001_0048             <td>NUM_TIMEKEEPERS <td>RO          <td>Number of radio timekeepers
<tr>                  <td rowspan="7">n3xx_mgt_io_core (NPIO0)  <td>4001_0200             <td>PORT_INFO       <td>RO          <td>
<tr>                                                            <td>4001_0204             <td>MAC_CTRL_STATUS <td>RW          <td>
<tr>                                                            <td>4001_0208             <td>PHY_CTRL_STATUS <td>RW          <td>
<tr>                                                            <td>4001_0220             <td>AURORA_OVERUNS  <td>RO          <td>
<tr>                                                            <td>4001_0224             <td>AURORA_CHECKSUM_ERRORS<td>RO    <td>
<tr>                                                            <td>4001_0228             <td>AURORA_BIST_CHECKER_SAMPS<td>RO <td>
<tr>                                                            <td>4001_022c             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>
<tr>                  <td rowspan="7">n3xx_mgt_io_core (NPIO1)  <td>4001_0240             <td>PORT_INFO       <td>RO          <td>
<tr>                                                            <td>4001_0244             <td>MAC_CTRL_STATUS <td>RW          <td>
<tr>                                                            <td>4001_0248             <td>PHY_CTRL_STATUS <td>RW          <td>
<tr>                                                            <td>4001_0260             <td>AURORA_OVERUNS  <td>RO          <td>
<tr>                                                            <td>4001_0264             <td>AURORA_CHECKSUM_ERRORS<td>RO<td>
<tr>                                                            <td>4001_0268             <td>AURORA_BIST_CHECKER_SAMPS<td>RO<td>
<tr>                                                            <td>4001_026c             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>
<tr>                  <td rowspan="7">n3xx_mgt_io_core (QSFP0)  <td>4001_0280             <td>PORT_INFO<td>RO<td>
<tr>                                                            <td>4001_0284             <td>MAC_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_0288             <td>PHY_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_02a0             <td>AURORA_OVERUNS<td>RO<td>
<tr>                                                            <td>4001_02a4             <td>AURORA_CHECKSUM_ERRORS<td>RO<td>
<tr>                                                            <td>4001_02a8             <td>AURORA_BIST_CHECKER_SAMPS<td>RO<td>
<tr>                                                            <td>4001_02ac             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>
<tr>                  <td rowspan="7">n3xx_mgt_io_core (QSFP1)  <td>4001_02c0             <td>PORT_INFO<td>RO<td>
<tr>                                                            <td>4001_02c4             <td>MAC_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_02c8             <td>PHY_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_02e0             <td>AURORA_OVERUNS<td>RO<td>
<tr>                                                            <td>4001_02e4             <td>AURORA_CHECKSUM_ERRORS<td>RO<td>
<tr>                                                            <td>4001_02e8             <td>AURORA_BIST_CHECKER_SAMPS<td>RO<td>
<tr>                                                            <td>4001_02ec             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>
<tr>                  <td rowspan="7">n3xx_mgt_io_core (QSFP2)  <td>4001_0300             <td>PORT_INFO<td>RO<td>
<tr>                                                            <td>4001_0304             <td>MAC_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_0308             <td>PHY_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_0320             <td>AURORA_OVERUNS<td>RO<td>
<tr>                                                            <td>4001_0324             <td>AURORA_CHECKSUM_ERRORS<td>RO<td>
<tr>                                                            <td>4001_0328             <td>AURORA_BIST_CHECKER_SAMPS<td>RO<td>
<tr>                                                            <td>4001_032c             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>
<tr>                  <td rowspan="7">n3xx_mgt_io_core (QSFP3)  <td>4001_0340             <td>PORT_INFO<td>RO<td>
<tr>                                                            <td>4001_0344             <td>MAC_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_0348             <td>PHY_CTRL_STATUS<td>RW<td>
<tr>                                                            <td>4001_0360             <td>AURORA_OVERUNS<td>RO<td>
<tr>                                                            <td>4001_0364             <td>AURORA_CHECKSUM_ERRORS<td>RO<td>
<tr>                                                            <td>4001_0368             <td>AURORA_BIST_CHECKER_SAMPS<td>RO<td>
<tr>                                                            <td>4001_036C             <td>AURORA_BIST_CHECKER_ERRORS<td>RO<td>
<tr><td rowspan="6">Slave 5                                     <td>4001_4000<td>4001_41FF<td>Clocking<td>see Clocking regmap<td>
<tr>                                                            <td>4001_4200<td>4001_43FF<td>Sync<td>see Sync regmap<td>
<tr>                                                            <td>4001_4400<td>4001_45FF<td>open<td>open<td>open<td>
<tr>                                                            <td>4001_4600<td>4001_47FF<td>Daughterboard <td>see Daughterboard regmap (EISCAT)<td>
<tr>                                                            <td>4001_6000<td>4001_6FFF<td>JESD Core 0<td>see JESD regmap (EISCAT)<td>
<tr>                                                            <td>4001_7000<td>4001_7FFF<td>JESD Core 1<td>see JESD regmap (EISCAT)<td>
<tr><td rowspan="1">Slave 6                                     <td>4001_8000 - 4001_bfff <td>see above <td>-<td>same as Slave 5<td>
</table>

\subsection n3xx_mg_eeprom_flags EEPROM flags

EEPROM flags can be set with

    $ eeprom-set-flags 0xFLAGS

where FLAGS is the hex number that you can construct with the following table of bits:

| Bit | Description           |
|-----|-----------------------|
| 0   | Auto-boot (1=on)      |
| 2   | TPM (0=present)       |

For example, to set your device to auto-boot, with TPM, the flag value is 0x1, so

    $ eeprom-set-flags 0x1

\subsection n3xx_mg_gain_profiles Gain Profiles

The N310 supports four gain profiles: `default`, `manual`,
`default_rf_filter_bypass_always_on`, and `default_rf_filter_bypass_always_off`.

Usually, UHD will program individual gain components to create an overall gain
that is selected. The N310 daughterboards have three gain stages per path (two
digital step attenuators (DSAs), and one amplifier).  When using the `manual`
profile, the DSAs and amplifiers can be programmed directly. In the other gain
profiles, a single, overall gain can be given, and UHD will attempt to program
the gain stages based on hard-coded gain tables. The difference between the
three "default" profiles is how the amplifier is used: Either it is always on,
always off, or it is switched on and off to optimize linearity.

\subsection n3xx_mg_custom_band_edges Custom Band Edges

\b Note: This is a highly advanced feature. Most users will not have to use this!

The N310 daughterboard splits the TX and RX paths into 4 and 7 different bands,
respectively, to hardware-optimize the RF fidelity at all available frequencies.

See the [schematics](https://kb.ettus.com/N300/N310#Schematics) for more details.

Using the `rx_band_map` and `tx_band_map` device args, it is possible to move
the band edges in software. This may be useful if the hardware was modified to
use different filters, for example, because a signal of interest always falls
onto a band edge. Using the `tx_band_map` or `rx_band_map` device arguments,
you can provide a list of lower band edges for every band. Make sure to provide
4 (for Tx) or 7 (for Rx) floating-point values. The first value should always be
zero (0.0). It may make sense to encode these values in your `uhd.conf` file:

~~~{.ini}
[type=n3xx]
rx_gain_profile=default_rf_filter_bypass_always_off
tx_gain_profile=default_rf_filter_bypass_always_on
rx_band_map=0.0;431e6;601e6;1051e6;1601e6;2101e6;2701e6
tx_band_map=0.0;723.18e6;1623.18e6;3323.18e6
~~~

In this example, the second Rx band would start at 431 MHz.
=======
\subsection n3xx_filter_api Filter API

The N300/N310 utilize the Analog Devices AD9371 AFE which contain programmable
FIR filters in both the transmit and receive paths for each of the RF channels.
These filters are available using the Digital Filter API in UHD.

| Filter Name | AD9371 Channel | Max Taps |
|-------------|----------------|----------|
| RX1_FIR     | 1              | 48       |
| RX2_FIR     | 2              | 48       |
| RX1RX2_FIR  | 1 and 2        | 48       |
| TX1_FIR     | 1              | 32       |
| TX2_FIR     | 2              | 32       |
| TX1TX2_FIR  | 1 and 2        | 32       |

Each filter is applied at 2x the `master_clock_rate`, or 250 MHz by default.

The Filter API also allows to set some 3 dB analog filters on the AD9371 through
the `set_tx_bandwidth` and `set_rx_bandwidth` UHD functions.

This is a small example on how to set the TX FIR and TX bandwidth.
~~~{.cpp}
// Create my USRP object
auto usrp = uhd::usrp::multi_usrp::make(args);

// Set to use channel 3
auto chan = 3;

// Set the Analog Bandwidth to be 20 MHz wide
auto bw = 20e6;

// Get the names of the filters
auto tx_names = usrp->get_tx_filter_names(chan);

// Get the first filter and print out the filter properties
auto filt = usrp->get_tx_filter(tx_names[0], chan);

// Some taps for our coefficients
const std::vector<int16_t> taps{
           0,
          42,
         169,
         374,
         650,
         987,
        1371,
        1786,
        2215,
        2641,
        3045,
        3412,
        3726,
        3973,
        4144,
        4232,
        4232,
        4144,
        3973,
        3726,
        3412,
        3045,
        2641,
        2215,
        1786,
        1371,
         987,
         650,
         374,
         169,
          42,
           0
};

// Create a custom filter with taps as our coefficients
auto filter(std::make_shared<uhd::digital_filter_fir<int16_t>>(
     uhd::filter_info_base::filter_type::DIGITAL_FIR_I16,
     false,
     0,
     1.0,
     1,
     1,
     32767,
     32,
     taps)
);

// Apply the filter to the channel
usrp->set_tx_bandwidth(bw, chan);
usrp->set_tx_filter(tx_names[0], filter, chan);
~~~

\section n3xx_rh N32x-specific Features

\subsection n3xx_rh_panels Front and Rear Panel

Like the USRP X300 series, the N320/N321 has connectors on both the front and back
panel. The back panel holds the power connector, all network connections, USB
connections for serial console (see \ref n3xx_getting_started_serial), JTAG,
peripherals, SMA connectors for GPS antenna input, 10 MHz clock reference,
PPS time reference input and output (TRIG in/out), the slot for the SD card
(see also \ref n3xx_sdcard), and indicator LEDs.

The following indicator LEDs are used:

- LINK: This LED will be lit when this USRP has been claimed by a UHD session.
- REF: Indicates a lock to the reference clock. In particular, when using an
       external reference clock, this LED is useful to see if the LMK04828 PLLs
       are locking to this reference clock. Note that some software interaction
       is necessary to enable the LMK04828, and thus this LED may be off even
       if a valid reference clock signal is connected.
- GPS: Indicates a GPS lock (i.e., GPS satellites are in view of the GPS
       antenna and signal levels are sufficient)
- PPS: This LED will blink once every second to indicate a valid PPS signal.

The rear panel is identical between the N320 and the N321 with the exception of
the product name above the SFP+ connectors.

\image html N320_Rear.png N320 Rear Panel

\image html N321_Rear.png N321 Rear Panel

The front panel is used for all RF connections (including the external LO
inputs, see \ref n3xx_rh_external_lo) and all TX/RX connections, as well as the
front-panel GPIO (N320 only!).

The connectors labeled RF0 are also referred to as slot A, and the connectors
labeled RF1 are also referred as slot B (matching the internal connections to
the daughterboard).

\image html N320_Front.png N320 Front Panel

\image html N321_Front.png N321 Front Panel

\subsection n3xx_rh_initialization Device Initialization (Fast and Slow)

When a UHD session is created, an initialization sequence is started. As part of
the initialization sequence, the following steps are performed:

- All clocking is initialized
- The JESD links are trained and brought up (between the FPGA and the ADC/DAC)

This sequence can take a while, depending on the master clock rate and the
calibration sequence. To speed things up, the device will retain a state
between sessions, but only if no relevant settings were touched. In particular,
changing the master clock rate or the clock source will
force a full re-initialization which is slower compared to the fast
re-initialization. By setting the log level to DEBUG you will be able to observe
the exact settings that cause fast vs. slow re-initialization.
If you require a full re-initialization every time a UHD session is spawned,
specify the `force_reinit` flag as a device arg. Specifying it will always do
the full, slow initialization, but will guarantee a full reset digital chains.

To maximally speed up UHD, an initialization sequence is run when the device
(or more accurately, the MPM service) starts. This means even on the first run
of UHD, the device will already be initialized into a usable state. Note that
it will always come up in a default state, which can be changed by modifying the
configuration file in `/etc/uhd/mpm.conf` (see also \ref page_configfiles),
such as this:

~~~{.ini}
; Note: To boot into a fully initialized state, a clock reference must be
; connected before turning the device on if it set to external here:
[n3xx]
master_clock_rate=200e6
clock_source=external
~~~

If you prefer not to have the device initialize on boot, but rather have a fast
boot time, add the line `skip_boot_init=1` to your `/etc/uhd/mpm.conf` file.


\subsection n3xx_rh_calibrations RF Calibrations

The N320/N321 can perform some simple calibration for I/Q imbalance and DC
offset, the same way as the X300 series. Refer to \ref page_calibration for more
details.

\subsection n3xx_rh_external_lo External LOs

The N320/N321 can utilize an external LO that is connected to the front panel
connectors.  For the N320, the LO IN TX and LO IN RX connectors are used. For
the N321, the RX LO IN1 and TX LO IN1 connectors are used. One or both
daughterboards may use this external LO signal by setting the channel's LO
source to "external".  When the source is set to "external", reading the LO
frequency will return the ideal frequency for an external LO source.

The nominal LO input level is +5 dBm. Actual LO input levels should be within
+/- 2 dB of that value (i.e., between +3 dBm and +7 dBm).

\subsection n3xx_rh_lo_sharing N321 LO Distribution Board

The N321 has an additional board to perform LO signal splitting and
distribution.  The 4 output ports, OUT0 through OUT3, are driven by a 1:4
splitter which can be sourced from the corresponding IN0 front panel port or
the LO on the daughterboard in slot A.  To use the IN0 front panel port, set LO
export enabled to false.  To use the LO located on the daughterboard in slot A,
set LO export enabled to true.

Each of the 4 output ports, OUT0 through OUT3, have an internal terminator
which must be disabled before use.  These can be controlled through the RFNoC
radio block's API, the property tree, or directly through commands in the MPM
shell.

\image html N321_LO_Distribution_Block_Diagram.png "N321 LO Distribution Diagram"

\subsection n3xx_rh_lo_chaining N320/N321 LO Sharing

By using matched length cabling with N321s, up to 16 modules can use both of
their RX and TX channels while sharing a single N321's LO signal, resulting in
a 32 by 32 channel single shared LO configuration.  This 32 by 32 channel
configuration can also utilize an external LO signal, allowing an already split
external LO signal to support larger configurations of 64 by 64 channels, 128
by 128 channels, and larger.

The following diagram shows the connections necessary to create a 16 by 16
channel configuration with a single shared LO source.

\image html N321_16_Channel_Example.png "N321 16 Channel LO Sharing"

\subsection n3xx_rh_sfp_protocols SFP+ and QSFP+ protocols

The protocols supported on the SFP+ and QSFP+ ports depend on the FPGA image
currently loaded.

Interface    | HG     | XG     | WX           | XQ           | AQ
-------------|--------|--------|--------------|--------------|--------
SFP+ 0       | 1 GbE  | 10 GbE | White Rabbit | White Rabbit | 10 GbE
SFP+ 1       | 10 GbE | 10 GbE | 10 GbE       | Unused       | 10 GbE
QSFP+ lane 0 | Unused | Unused | Unused       | 10 GbE       | Aurora
QSFP+ lane 1 | Unused | Unused | Unused       | 10 GbE       | Aurora
QSFP+ lane 2 | Unused | Unused | Unused       | Unused       | Aurora
QSFP+ lane 3 | Unused | Unused | Unused       | Unused       | Aurora

\subsection n3xx_rh_frontend_corrections N320/N321 Frontend Corrections

In an unmodified FPGA image, N320/N321 perform several steps of digital signal
processing between the RFNoC Radio block and the ADC/DAC.

It should be noted that the DACs/ADCs run at twice the master clock rate (e.g.,
if the master clock rate is 250 MHz, the DACs/ADCs are clocked at 500 MHz). We
perform a sample rate conversion to the master clock rate within the FPGA.

```
  ┌───────┐  ┌──────────────┐   ┌─────────────┐  ┌──────────────┐         ┌─────┐
  │       │  │ TX           │   │TX           │  │ Halfband     │ 2x MCR  │     │
  │       ├─>│ IQ Offset    ├──>│DC Offset    ├─>│ Interpolator ├────────>│ DAC │
  │       │  │ Compensation │   │Compensation │  │ (47 taps)    │         │     │
  │ RFNoC │  └──────────────┘   └─────────────┘  └──────────────┘         └─────┘
  │ Radio │
  │ Block │  ┌──────────────┐   ┌─────────────┐  ┌──────────────┐         ┌─────┐
  │       │  │ RX           │   │RX           │  │Halfband      │ 2x MCR  │     │
  │       │<─┤ IQ Offset    │<──┤DC Offset    │<─┤Decimator     │<────────┤ ADC │
  │       │  │ Compensation │   │Compensation │  │(47 taps)     │         │     │
  └───────┘  └──────────────┘   └─────────────┘  └──────────────┘         └─────┘
```

The IQ and DC offset compensation components can be controlled from the host
side using the correction APIs. The following snippet shows the control of these
APIs from the host side using the multi_usrp APIs:

~~~{.cpp}
// Generate an N320/N321 multi_usrp object
auto usrp = uhd::usrp::multi_usrp::make("type=n3xx");
// Set TX IQ offset value on channel zero:
usrp->set_tx_iq_balance(my_tx_iq_offset_value, 0);
// Set TX DC offset value on channel zero:
usrp->set_tx_dc_offset(my_tx_dc_offset_value, 0);
// Set RX IQ offset value on channel zero:
usrp->set_tx_iq_balance(my_rx_iq_offset_value, 0);
// Enable auto-RX-DC-offset on all channels:
usrp->set_rx_dc_offset(true);
// Set RX DC offset value to specific value on channel zero:
usrp->set_tx_dc_offset(my_tx_dc_offset_value, 0);
~~~

When using the RFNoC API, use the uhd::rfnoc::radio_control API calls with the
same names.

Notes:
- Other than the RX DC offset calibration, there are no automatic compensation
  procedures. N320 uses a simple, single-tap IIR filter for automatic DC offset
  correction (like X310).
- The automatic RX DC offset correction acts as a notch filter around the LO
  frequency.
- For more details on the internals of these corrections, see \ref calibration_fe_corr.

The halfband decimators/interpolators are not configurable. They are 47-tap
halfband filters with the following coefficients:

-62, 0, 194, 0, -440, 0, 855, 0, -1505, 0, 2478, 0, -3900, 0, 5990, 0, -9187, 0, 14632, 0, -26536, 0, 83009, 131071, 83009, 0, -26536, 0, 14632, 0, -9187, 0, 5990, 0, -3900, 0, 2478, 0, -1505, 0, 855, 0, -440, 0 194, 0, -62.

\subsection n3xx_rh_eeprom_flags EEPROM flags

EEPROM flags can be set with

    $ eeprom-set-flags 0xFLAGS

where FLAGS is the hex number that you can construct with the following table of bits:

| Bit | Description           |
|-----|-----------------------|
| 0   | Auto-boot (1=on)      |
| 2   | TPM (0=present)       |

For example, to set your device to auto-boot, with TPM, the flag value is 0x1, so

    $ eeprom-set-flags 0x1

*/
// vim:ft=doxygen: