Difference between revisions of "Selecting a USRP Device"

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!Details
 
!Details
 
|-
 
|-
|style="text-algin:center;"| 2016-05-01   
+
|style="text-align:center;"| 2016-05-01   
|style="text-algin:center;"| Neel Pandeya<br> Nate Temple  
+
|style="text-align:center;"| Neel Pandeya<br> Nate Temple  
|style="text-algin:center;"| Initial creation
+
|style="text-align:center;"| Initial creation
 +
 
 +
 
 +
|-
 +
|style="text-align:center;"| 2019-03-26 
 +
|style="text-align:center;"| Nate Temple
 +
|style="text-align:center;"| Update
 
|}
 
|}
  
 
==Abstract==
 
==Abstract==
 
This AN explores the USRP family at a high level, compares devices across several primary features, and walks the reader through the process of selecting a particular device for the their application.
 
This AN explores the USRP family at a high level, compares devices across several primary features, and walks the reader through the process of selecting a particular device for the their application.
 
Reference: https://www.ettus.com/content/files/kb/application_note_selecting_a_usrp.pdf
 
  
 
==USRP Product Selector==
 
==USRP Product Selector==
Line 25: Line 29:
  
 
==Understanding DSP Fundamentals==
 
==Understanding DSP Fundamentals==
If you are new to the USRP family of products, software defined radio, or digital signal processing in general, it may be useful to perform some simulation of the signals you wish to manipulate before selecting USRP hardware. Simulating signals and algorithms in software frameworks such as GNU Radio or LabVIEW will ensure a proper understanding of various concepts, such as Nyquist theorem, ADC/DAC and limitations, for example. Understanding the basics of signal theory and digital signal processing is the first step towards understanding how to make the best use of an appropriate USRP model. This link provides access to several resources that may be helpful in understanding the basics.
+
If you are new to the USRP family of products, software defined radio, or digital signal processing in general, it may be useful to perform some simulation of the signals you wish to manipulate before selecting USRP hardware. Simulating signals and algorithms in software frameworks such as [[GNU Radio]] or [[LabVIEW]] will ensure a proper understanding of various concepts, such as Nyquist theorem, ADC/DAC and limitations, for example. Understanding the basics of signal theory and digital signal processing is the first step towards understanding how to make the best use of an appropriate USRP model. The [[Suggested Reading]] page provides access to several resources that may be helpful in understanding the basics.
 
+
http://gnuradio.org/redmine/projects/gnuradio/wiki/SuggestedReading
+
  
 
==Common Applications==
 
==Common Applications==
Line 40: Line 42:
 
|-
 
|-
 
|PHY/MAC Research
 
|PHY/MAC Research
|N200/N210 X300/X310
+
|N200/N210 X300/X310 N300/N310<sup>1</sup>
 
|WBX/SBX/UBX/CBX
 
|WBX/SBX/UBX/CBX
 
|-
 
|-
Line 48: Line 50:
 
|-
 
|-
 
|OpenBTS
 
|OpenBTS
|B200/B210 X300/X310 E310/E312 N200/N210
+
|B200/B210<sup>1</sup> X300/X310 E310/E312<sup>1</sup> N200/N210 N300/N310<sup>1</sup> E320<sup>1</sup>
 
|WBX/SBX/UBX/CBX
 
|WBX/SBX/UBX/CBX
 
|-
 
|-
 
|Amarisoft LTE
 
|Amarisoft LTE
|N200/N210 X300/X310
+
|N200/N210 X300/X310 B210<sup>1</sup> E320<sup>1</sup> N300/N310<sup>1</sup>
 
|WBX/SBX/UBX/CBX
 
|WBX/SBX/UBX/CBX
 
|-
 
|-
 
|Education  
 
|Education  
|B200/B210 X300/X310 E310/E312 N200/N210
+
|B200/B210<sup>1</sup> X300/X310 E310/E312<sup>1</sup> N200/N210 N300/N310<sup>1</sup> E320<sup>1</sup>
 
|WBX/SBX/CBX/UBX
 
|WBX/SBX/CBX/UBX
 
|-
 
|-
Line 64: Line 66:
 
|-
 
|-
 
|Signals Intelligence
 
|Signals Intelligence
|X300/X310
+
|X300/X310 N300/N310<sup>1</sup> E320<sup>1</sup>
 
|SBX/UBX
 
|SBX/UBX
 
|-
 
|-
 
|Distributed RF Sensors
 
|Distributed RF Sensors
|E310/E312
+
|E310/E312 N300/N310 E320
 
|N/A
 
|N/A
 
|-
 
|-
 
|Mobile Radios
 
|Mobile Radios
|E310/E312
+
|E310/E312 E320
 
|N/A
 
|N/A
 
|-
 
|-
 
|MIMO
 
|MIMO
|X300/X310
+
|X300/X310 N310<sup>1</sup>
 
|SBX/UBX
 
|SBX/UBX
 
|-
 
|-
Line 84: Line 86:
 
|-
 
|-
 
|FPGA Computing
 
|FPGA Computing
|X310
+
|X310 N310<sup>1</sup> E320<sup>1</sup>
 
|WBX/SBX/UBX/CBX
 
|WBX/SBX/UBX/CBX
 
|-
 
|-
 
|Embedded Computing
 
|Embedded Computing
|E310/E312
+
|E310/E312 E320
 
|N/A
 
|N/A
 
|-
 
|-
 
|Small Form Factor (SWaP)
 
|Small Form Factor (SWaP)
|B200mini/B205mini E310/E312
+
|B200mini/B205mini E310/E312 E320
 
|N/A
 
|N/A
 
|-
 
|-
 
|}
 
|}
<center>Table 1 - Recommended USRP Selection for Various Application Areas</center>
+
<center>Table 1 - Recommended USRP Selection for Various Application Areas</center><br>
 +
<center><sup>1</sup> - The B2xx, E3xx and N3xx do not support swappable daughterboards</center>
  
 
==USRP Device Characteristics==
 
==USRP Device Characteristics==
Line 115: Line 118:
 
!1 PPS/Ref Inputs
 
!1 PPS/Ref Inputs
 
|-
 
|-
 +
 
|N210
 
|N210
 
|GigE
 
|GigE
|50/100
+
|25/50
 
|1
 
|1
 
|14
 
|14
Line 127: Line 131:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|N200
 
|N200
 
|GigE
 
|GigE
|50/100
+
|25/50
 
|1
 
|1
 
|14
 
|14
Line 139: Line 144:
 
|Yes
 
|Yes
 
|-
 
|-
|B100
+
 
|USB 2.0
+
|N300
|8/16
+
|1 GigE
|1
+
10 GigE
|12
+
 
|64
+
|153.6, 125, 122.88
|14
+
|128
+
|No
+
|No
+
|No
+
|-
+
|USRP1
+
|USB 2.0
+
|8/*
+
 
|2
 
|2
|12
+
|16
|64
+
|153.6, 125, 122.88
 
|14
 
|14
|128
+
|153.6, 125, 122.88
 
|Yes
 
|Yes
|No
 
|No
 
|-
 
|E100
 
|Embedded
 
|8/16
 
|1
 
|12
 
|64
 
|14
 
|128
 
|No
 
 
|Yes
 
|Yes
 
|Yes
 
|Yes
 
|-
 
|-
|E110
+
 
|Embedded
+
|N310
|8/16
+
|1 GigE
|1
+
10 GigE
|12
+
 
|64
+
|153.6, 125, 122.88
 +
|2
 +
|16
 +
|153.6, 125, 122.88
 
|14
 
|14
|128
+
|153.6, 125, 122.88
|No
+
|Yes
 
|Yes
 
|Yes
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|B200mini
 
|B200mini
 
|USB 3.0
 
|USB 3.0
Line 199: Line 187:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|B205mini
 
|B205mini
 
|USB 3.0
 
|USB 3.0
Line 211: Line 200:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|B200
 
|B200
 
|USB 3.0
 
|USB 3.0
Line 223: Line 213:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|B210
 
|B210
 
|USB 3.0
 
|USB 3.0
Line 235: Line 226:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|X300
 
|X300
 
|USB 3.0
 
|USB 3.0
Line 252: Line 244:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|X310
 
|X310
 
|USB 3.0
 
|USB 3.0
Line 269: Line 262:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|E310
 
|E310
 
|Embedded
 
|Embedded
Line 281: Line 275:
 
|Yes
 
|Yes
 
|-
 
|-
 +
 
|E312
 
|E312
 
|Embedded
 
|Embedded
Line 291: Line 286:
 
|Yes
 
|Yes
 
|No
 
|No
 +
|Yes
 +
|-
 +
 +
|E320
 +
|Embedded
 +
1 GigE
 +
 +
10 GigE
 +
|61.44
 +
|N/A
 +
|12
 +
|61.44
 +
|12
 +
|61.44
 +
|Yes
 +
|Yes
 
|Yes
 
|Yes
 
|-
 
|-
Line 301: Line 312:
  
 
'''Do I want to perform processing on a host PC, or operate the USRP device in a standalone fashion?'''
 
'''Do I want to perform processing on a host PC, or operate the USRP device in a standalone fashion?'''
This is an obvious differentiator of the USRP Embedded Series. If you need the USRP to operate a USRP radio without a host PC, the USRP E310/E312 is the most appropriate. The USRP E310/E312 is ideal for applications that might require mobile transceivers or distributed RF sensors. Unless the user has a clear requirement for embedded operation, Ettus Research recommends the USRP N200, N210, B200, B210, X300 or X310. Developing with a host-based platform typically involves less risk and will require less effort to optimize various pieces of the software radio.
 
  
In many cases it may be easier to develop with a USRP B200/B210 or USRP N200/N210, then port the code to the USRP E310/E312. The UHD (USRP Hardware Driver) enables this portability. You must also consider the different processing capabilities of the host machine and ARM processor used on the USRP E310/E312.
+
This is an obvious differentiator of the USRP Embedded Series. If you need the USRP to operate a USRP radio without a host PC, the USRP E310/E312/E320 is the most appropriate. The USRP E310/E312/E320 is ideal for applications that might require mobile transceivers or distributed RF sensors. Unless the user has a clear requirement for embedded operation, Ettus Research recommends the USRP N200, N210, B200, B210, X300, X310, N300 or N310. Developing with a host-based platform typically involves less risk and will require less effort to optimize various pieces of the software radio.
 +
 
 +
In many cases it may be easier to develop with a USRP B200/B210 or USRP N200/N210, then port the code to the USRP E310/E312/E320. The UHD (USRP Hardware Driver) enables this portability. You must also consider the different processing capabilities of the host machine and ARM processor used on the USRP E310/E312/E320.
  
 
'''Do I Need Synchronization and/or MIMO Capability?'''
 
'''Do I Need Synchronization and/or MIMO Capability?'''
 +
 
Table 3 summarizes the synchronization features of each USRP device. Table 4 shows recommended solutions for MIMO systems of various sizes.
 
Table 3 summarizes the synchronization features of each USRP device. Table 4 shows recommended solutions for MIMO systems of various sizes.
  
If you need MIMO capability for your application, Ettus Research recommends the USRP N200/N210 or USRP X300/X310. These units can be synchronized by providing a common time and frequency reference. Two USRP N200/N210s can be synchronized for MIMO operation with an Ettus Research MIMO cable. Alternatively, external 10 MHz reference and 1 PPS signals can be distributed to multiple USRP radios. With proper consideration for interface issues, it is possible to create MIMO system of arbitrary size with the USRP N200/N210 or USRP X300/X310.
+
If you need MIMO capability for your application, Ettus Research recommends the USRP N200/N210, X300/X310, N300/N310 or E320. These units can be synchronized by providing a common time and frequency reference. Two USRP N200/N210s can be synchronized for MIMO operation with an Ettus Research MIMO cable. Alternatively, external 10 MHz reference and 1 PPS signals can be distributed to multiple USRP radios. With proper consideration for interface issues, it is possible to create MIMO system of arbitrary size with the USRP N200/N210, X300/X310, N300/N310 and E320.
  
The USRP B210 can serve a 2x2 MIMO capability because it has two integrated RF channels. However, the available bandwidth is limited dependent upon the USB controller, and selected MIMO configuration. Additional details of each configuration can be found in the [[USRP B200 and B210 - USB 3.0 Streaming Rate Benchmarks]] application note. <s>However, the USB 3.0 interface limits the bandwidth per channel. The combined throughput of all transmit and receive channels cannot exceed 8 MS/s.</s>
+
The USRP B210, N300, E310/E312/E320 can serve a 2x2 MIMO capability because it has two integrated RF channels. When using the USRP B210 the available bandwidth is limited dependent upon the USB controller, and selected MIMO configuration. The USRP E310/E312's streaming bandwidth is limited to the 1 GigE interface to the ARM CPU. The USRP E320 supports streaming at full rate of 61.44 MS/s (SISO) or 30.72 MS/s (MIMO) via the 10 Gb interface. The USRP N300 supports streaming at 153.6 MS/s (SISO) and 125 MS/s (MIMO) via the 10Gb interface.
 
+
<s>In most cases the USRP B100 and E100/E110 are not appropriate for applications requiring a MIMO system. However, if you intend to operate at low frequencies it may be possible to use the LFRX/TX and BasicRX/TX, which can provide two channels on each daughterboard. If only receive capability is needed, the TVRX2 can meet the requirements for multiple-input capability in all USRP devices.</s>
+
  
  
Line 321: Line 332:
 
!Ext Ref. Input
 
!Ext Ref. Input
 
!1 PPS Input
 
!1 PPS Input
!Internal GPS Disiplined Oscillator (Optional)
+
!Internal GPS Disciplined Oscillator (Optional)
 
!Plug and Play MIMO
 
!Plug and Play MIMO
 
|-
 
|-
|USRP1
+
 
|8
+
|style="text-align: center;"|X
+
|
+
|
+
|
+
|
+
|-
+
 
|N200
 
|N200
 
|25
 
|25
Line 340: Line 344:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
 +
 
|N210
 
|N210
 
|25
 
|25
Line 348: Line 353:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
|E100
+
 
|4
+
|N300
|
+
|153.6, 125, 122.88
 +
|style="text-align: center;"|X
 +
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
|
 
 
|-
 
|-
|E110
+
 
|4
+
|N310
|
+
|153.6, 125, 122.88
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
|
 
|-
 
|B100
 
|8
 
|
 
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
|
 
|
 
 
|-
 
|-
 +
 
|B200mini
 
|B200mini
 
|61.44
 
|61.44
Line 380: Line 380:
 
|
 
|
 
|-
 
|-
 +
 
|B205mini
 
|B205mini
 
|61.44
 
|61.44
Line 388: Line 389:
 
|
 
|
 
|-
 
|-
 +
 
|B200
 
|B200
 
|61.44
 
|61.44
Line 396: Line 398:
 
|
 
|
 
|-
 
|-
 +
 
|B210
 
|B210
 
|61.44
 
|61.44
Line 404: Line 407:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
 +
 
|X300
 
|X300
 
|200
 
|200
Line 412: Line 416:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
 +
 
|X310
 
|X310
 
|200
 
|200
Line 420: Line 425:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
 +
 
|E310
 
|E310
 
|61.44
 
|61.44
Line 428: Line 434:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
 +
 
|E312
 
|E312
 
|61.44
 
|61.44
Line 436: Line 443:
 
|style="text-align: center;"|X
 
|style="text-align: center;"|X
 
|-
 
|-
 +
 +
|E320
 +
|61.44
 +
|style="text-align: center;"|X
 +
|style="text-align: center;"|X
 +
|style="text-align: center;"|X
 +
|style="text-align: center;"|X
 +
|style="text-align: center;"|X
 +
|-
 +
 
|}
 
|}
  
Line 447: Line 464:
 
!4 x 4 MIMO
 
!4 x 4 MIMO
 
!M x N MIMO
 
!M x N MIMO
|-
 
|USRP1
 
|2x Daughterboard
 
|Not Recommended
 
|Not Recommended
 
 
|-
 
|-
 
|N200/N210
 
|N200/N210
 
|MIMO Cable
 
|MIMO Cable
|MIMO Cable + External
+
|OctoClock
|External
+
|OctoClock
 
|-
 
|-
|E100/E110
+
 
|Not Recommended
+
|N300
|Not Recommended
+
|Integrated
|Not Recommended
+
|Octoclock, White Rabbit
 +
|Octoclock, White Rabbit
 
|-
 
|-
|B100
+
 
|Not Recommended
+
|N310
|Not Recommended
+
|Integrated
|Not Recommended
+
|Integrated
 +
|Octoclock, White Rabbit
 
|-
 
|-
 +
 
|B200mini
 
|B200mini
|Not Recommended
+
|Not Recommended (SISO Only)
 
|Not Recommended
 
|Not Recommended
 
|Not Recommended
 
|Not Recommended
 
|-
 
|-
 +
 
|B205mini
 
|B205mini
|Not Recommended
+
|Not Recommended (SISO Only)
 
|Not Recommended
 
|Not Recommended
 
|Not Recommended
 
|Not Recommended
 
|-
 
|-
 +
 
|B200
 
|B200
|Not Recommended
+
|Not Recommended (SISO Only)
 
|Not Recommended
 
|Not Recommended
 
|Not Recommended
 
|Not Recommended
 
|-
 
|-
 +
 
|B210
 
|B210
 
|Integrated
 
|Integrated
Line 488: Line 506:
 
|Not Recommended
 
|Not Recommended
 
|-
 
|-
 +
 
|X300
 
|X300
|2x Daughterboard
+
|Integrated with Dual Daughterboards
 
|OctoClock
 
|OctoClock
 
|OctoClock
 
|OctoClock
 
|-
 
|-
 +
 
|X310
 
|X310
|2x Daughterboard
+
|Integrated with Dual Daughterboards
 
|OctoClock
 
|OctoClock
 
|OctoClock
 
|OctoClock
 
|-
 
|-
 +
 
|E310
 
|E310
 
|Integrated
 
|Integrated
Line 503: Line 524:
 
|Not Recommended
 
|Not Recommended
 
|-
 
|-
 +
 
|E312
 
|E312
 
|Integrated
 
|Integrated
Line 508: Line 530:
 
|Not Recommended
 
|Not Recommended
 
|-
 
|-
 +
 +
|E320
 +
|Integrated
 +
|Octoclock
 +
|Octoclock
 +
|-
 +
 
|}
 
|}
 
<center>Table 4 - Recommended Models for MIMO Systems</center>
 
<center>Table 4 - Recommended Models for MIMO Systems</center>
Line 513: Line 542:
  
 
'''What Are My Bandwidth Requirements?'''
 
'''What Are My Bandwidth Requirements?'''
Many Bandwidth requirements can also be used to narrow down the USRP selection. As seen in the table, the USRP N200/N210 is capable of streaming up to 50 MS/s in each direction in 8-bit mode, and 25 MS/s in 16-bit mode. The USRP B200 is capable of streaming up to 61.44MS/s total in 16-bit or 8-bit modes, respectively. <s>The USRP1 only operates in 16-bit modes, and is limited to 8 MS/s applications, such as OpenBTS, only utilizing a few hundred kHz of instantaneous BW. In these cases, the BW capability of the USRP1 and USRP B100 are more than adequate.</s>
 
  
However, if there is interest in transmit and/or receiving larger bandwidth signals such as 802.11, the USRP N200/N210 would be more appropriate.
+
Many Bandwidth requirements can also be used to narrow down the USRP selection. As seen in the table, the USRP N200/N210 is capable of streaming up to 50 MS/s in each direction in 8-bit mode, and 25 MS/s in 16-bit mode. The USRP B200 is capable of streaming up to 61.44MS/s total in 16-bit, 12-bit or 8-bit modes. The USRP E320 is capable of streaming up to 61.44 MS/s in 16-bit mode. The X300/X310 is capable of streaming up to 200 MS/s per channel (400 MS/s total) with 160 MHz of usable bandwidth per channel. The N300/N310 is capable of streaming up 122.88, 125 or 153.6 MS/s per channel. The N300/N310 is limited to 2x2 operation when using a 153.6 MS/s sample rate.
Note these limitations are based on the data throughputs provided by the corresponding interfaces. It is important to consider the performance of the processing platform, and the computational intensity of the application. The constraints of the processing platform are independent of the full capability of the Ettus Research USRP radio and UHD.
+
  
The USRP E310/E312 FPGA interface provides a maximum throughput of [ADD STAT] <s>40 MB/s</s>. This bandwidth can be used distributed across transmit and receive sample transfer. At 4 bytes/sample, this provides for a total of [ADD STAT] <s>10 MS/s</s>. Note this does not guarantee that the embedded processor will be able to process that many samples. Additional care must be taken to understand the processing limitations and best DSP practices for optimum performance.
+
However, if there is interest in transmit and/or receiving larger bandwidth signals such as 802.11, the USRP N200/N210, X300/X310, N300/N310 or E320 would be appropriate. Note these limitations are based on the data throughput provided by the corresponding interfaces. It is important to consider the performance of the processing platform, and the computational intensity of the application. The constraints of the processing platform are independent of the full capability of the Ettus Research USRP radio and UHD.
  
 
'''What interface do I prefer to work with?'''
 
'''What interface do I prefer to work with?'''
Line 524: Line 551:
 
Assuming you have narrowed the viable devices down based on bandwidth, MIMO and channel count requirements, it is possible to select a USRP device based on the interface.
 
Assuming you have narrowed the viable devices down based on bandwidth, MIMO and channel count requirements, it is possible to select a USRP device based on the interface.
  
In general, USB 3.0 ports are more plentiful on computers. This makes the USRP B200/B210 <s>and USRP1</s> slightly more usable at short ranges. The USRP N200/N210 requires a Gigabit Ethernet port and a PC typically only provides one such port. If internet access is required, the user will also need to plan for an additional network adaptor.
+
In general, USB 3.0 ports are more plentiful on computers. This makes the USRP B200/B210/B200mini/B205mini slightly more usable at short ranges. The USRP N200/N210 requires a Gigabit Ethernet port and a PC typically only provides one such port. If internet access is required, the user will also need to plan for an additional network adapter. The USRP X300/X310, N300/N310 and USRP E320 all support streaming via either a 1 GigE or 10 GigE interface.  
  
The Gigabit Ethernet interface of the USRP N200/N210 can operate over significantly longer ranges. This makes it possible to operate the USRP radio it more remote locations further from the host computer. The GigE interface can be accessed via a Gigabit Ethernet switch, allowing access to multiple devices. However, Ettus Research recommends a homogeneous network without other devices, such as network routers attached.
+
The Gigabit Ethernet interface of the USRP N200/N210 can operate over significantly longer ranges (typically up to 100ft) compared to the USB interface of the USRP B2xx. This makes it possible to operate the USRP radio it more remote locations further from the host computer. The GigE interface can be accessed via a Gigabit Ethernet switch, allowing access to multiple devices. However, Ettus Research recommends a homogeneous network without other devices, such as network routers attached.
 +
 
 +
The 10 Gigabit Ethernet interfaces of the USRP N300/N310, X300/X310 and E320 can be operated using multimode fiber optic cables with appropriate adapters which increases the distance from the host computer.  
  
 
'''Will I develop custom IP for the USRP device’s FPGA?'''
 
'''Will I develop custom IP for the USRP device’s FPGA?'''
While most users deploy their USRP devices in a stock configuration, many others customize the FPGA with their own functionality. For example, you may want to offload modulation, demodulation, or other PHY/ MAC operations to the USRP radio. This reduces host processing requirements, and may allow data reduction before passing data over the host interface. A summary of the FPGAs used on each USRP model are shown in Table 5.
+
 
 +
While most users deploy their USRP devices in a stock configuration, many others customize the FPGA with their own functionality. For example, you may want to offload modulation, demodulation, or other PHY/ MAC operations to the FPGA. This reduces host processing requirements, and may allow data reduction before passing data over the host interface. A summary of the FPGAs used on each USRP model are shown in Table 5.
  
  
 
{| class="wikitable" style="margin: auto;"
 
{| class="wikitable" style="margin: auto;"
!
+
!Model
!N210
+
!N200
+
!E110
+
!E100
+
!USRP1
+
!B100
+
!B200mini
+
!B205mini
+
!B200
+
!B210
+
!X300
+
!X310
+
!E310
+
!E312
+
|-
+
 
!FPGA Vendor
 
!FPGA Vendor
|Xilinx
 
|Xilinx
 
|Xilinx
 
|Xilinx
 
|Altera
 
|Xilinx
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
 
!FPGA Series
 
!FPGA Series
|Spartan 3A DSP
 
|Spartan 3A DSP
 
|Spartan 3A DSP
 
|Spartan 3A DSP
 
|Cyclone
 
|Spartan 3A
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
 
!FPGA Part Number
 
!FPGA Part Number
|XC3SD3400A
 
|XC3SD1800A
 
|XC3SD3400A
 
|XC3SD1800A
 
|
 
|XC3S1400A
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
 
!System Gates
 
!System Gates
|3200k
 
|1800k
 
|3200k
 
|1800k
 
|
 
|1400k
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
 
!Logic Elements
 
!Logic Elements
| -
 
| -
 
| -
 
| -
 
|12000
 
| -
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
 
!Logic Cells
 
!Logic Cells
|53714
 
|37440
 
|53714
 
|37440
 
| -
 
|25344
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
 
!Slices
 
!Slices
|23872
+
!DSP48's
|16640
+
!BRAM
|23872
+
!DCM's
|16640
+
!Free Tools?
| -
+
|11264
+
|
+
|
+
|
+
|
+
|
+
|
+
|
+
|
+
 
|-
 
|-
!DSP48's
+
 
|126
+
|N200
 +
|Xilinx
 +
|Spartan 3A DSP
 +
|XC3SD1800A
 +
|1800k
 +
|style="text-align:center;"| -
 +
|37,440
 +
|16,640
 
|84
 
|84
|126
+
|260k
|84
+
|8
|0
+
|Yes
|0
+
|
+
|
+
|
+
|
+
|
+
|
+
|
+
|
+
 
|-
 
|-
!BRAM
+
 
 +
|N210
 +
|Xilinx
 +
|Spartan 3A DSP
 +
|XC3SD3400A
 +
|3200k
 +
|style="text-align:center;"| -
 +
|53,714
 +
|23,872
 +
|126
 
|373k
 
|373k
|260k
 
|373k
 
|260k
 
|234k
 
|576k
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|-
 
!DCM's
 
 
|8
 
|8
|8
+
|No
|8
+
|8
+
|2
+
|8
+
|
+
|
+
|
+
|
+
|
+
|
+
|
+
|
+
 
|-
 
|-
!Free Tools?
+
 
 +
|B200mini
 +
|Xilinx
 +
|Spartan-6
 +
|XC6SLX75
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|74,637
 +
|93,296
 +
|132
 +
|3,096k
 +
|12
 +
|Yes
 +
|-
 +
 
 +
 
 +
|B205mini
 +
|Xilinx
 +
|Spartan-6
 +
|XC6SLX150
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|147,443
 +
|184,304
 +
|180
 +
|4,824k
 +
|12
 
|No
 
|No
 +
|-
 +
 +
|B200
 +
|Xilinx
 +
|Spartan 6
 +
|XC6SLX75
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|74,637
 +
|93,296
 +
|132
 +
|3,096k
 +
|12
 
|Yes
 
|Yes
 +
|-
 +
 +
|B210
 +
|Xilinx
 +
|Spartan 6
 +
|XC6SLX150
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|147,443
 +
|184,304
 +
|180
 +
|4,824k
 +
|12
 
|No
 
|No
 +
|-
 +
 +
|X300
 +
|Xilinx
 +
|Kintex-7
 +
|XC7K325T
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|321k
 +
|407,600
 +
|840
 +
|16,020k
 +
|style="text-align:center;"| -
 +
|No
 +
|-
 +
 +
|X310
 +
|Xilinx
 +
|Kintex-7
 +
|XC7K410T
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|406k
 +
|508,400
 +
|1540
 +
|28,620k
 +
|style="text-align:center;"| -
 +
|No
 +
|-
 +
 +
|E310
 +
|Xilinx
 +
|Zynq-7000
 +
|XC7Z020
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|85k
 +
|106,400
 +
|220
 +
|560k
 +
|style="text-align:center;"| -
 
|Yes
 
|Yes
 +
|-
 +
 +
|E312
 +
|Xilinx
 +
|Zynq-7000
 +
|XC7Z020
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|85k
 +
|106,400
 +
|220
 +
|560k
 +
|style="text-align:center;"| -
 
|Yes
 
|Yes
|Yes
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
|
 
 
|-
 
|-
 +
 +
|E320
 +
|Xilinx
 +
|Zynq-7000
 +
|XC7Z045
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|350k
 +
|437,200
 +
|900
 +
|19.2 Mb
 +
|style="text-align:center;"| -
 +
|No
 +
|-
 +
 +
|N300
 +
|Xilinx
 +
|Zynq-7000
 +
|XC7Z035
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|275k
 +
|343,800
 +
|900
 +
|17.6 Mb
 +
|style="text-align:center;"| -
 +
|No
 +
|-
 +
 +
|N310
 +
|Xilinx
 +
|Zynq-7000
 +
|XC7Z100
 +
|style="text-align:center;"| -
 +
|style="text-align:center;"| -
 +
|444K
 +
|554,800
 +
|2020
 +
|26.5 Mb
 +
|style="text-align:center;"| -
 +
|No
 +
|-
 +
 
|}
 
|}
<center>Table 5 - FPGA Resources</center>
 
  
 +
<center>Table 5 - FPGA Resources</center>
  
The USRP N200 and USRP N210 are great, generic platforms to experiment with FPGA development. However, the important difference between these two is the FPGA size, and requirements for Xilinx development tools. The USRP N200 includes a Xilinx Spartan XC3SD1800A FPGA. This FPGA is optimized for DSP capability, and the logic can be modified with free Xilinx ISE tools. The USRP N210 includes a Xilinx Spartan XC3D3400A FPGA. This FPGA provides nearly twice the resources, but requires a licensed seat of the Xilinx development tools for development. <s>The USRP E100/110 use the same, respective FPGA sizes as the USRP N200/N210.</s>
 
  
The USRP B100 provides a cost-optimized Spartan 3A-1400 FPGA. This can also be modified by the free version of Xilinx tools. The USRP B100 FPGA design does not contain many unused resources.  
+
The USRP N200 and USRP N210 are great, generic platforms to experiment with FPGA development. However, the important difference between these two is the FPGA size, and requirements for Xilinx development tools. The USRP N200 includes a Xilinx Spartan XC3SD1800A FPGA. This FPGA is optimized for DSP capability, and the logic can be modified with free Xilinx ISE tools. The USRP N210 includes a Xilinx Spartan XC3D3400A FPGA. This FPGA provides nearly twice the resources, but requires a licensed seat of the Xilinx development tools for development.  
  
 
'''Do I need flexible sample clock frequencies?'''
 
'''Do I need flexible sample clock frequencies?'''
Some applications may benefit from a flexible sample clock frequency. The USRP E100/110 and USRP B100 both include a flexible frequency clocking solution. This flexibility allows ideal sample clock frequencies to be used for various communications standards. For example, the GSM implementations commonly use a 52 MHz sample clock.
+
 
 +
Some applications may benefit from a flexible sample clock frequency. The USRP E310/E312/E320 and USRP B200/B210/B200mini/B205mini include a flexible frequency clocking solution. This flexibility allows ideal sample clock frequencies to be used for various communications standards. For example, the GSM implementations commonly use a 52 MHz sample clock.
  
 
'''Do I want or need a rack-mountable solution?'''
 
'''Do I want or need a rack-mountable solution?'''
Generally speaking, the selection of the USRP is based on performance requirements of the electrical components. However, the convenience of a rack-mounted solution may be an attractive feature that drives your decision. The USRP B100, E100/E110, and N200/N210 can all be mounted in the Ettus Research 3U rack chassis. Up to four USRP devices can be mounted in the chassis. Note there is no off- the-shelf rack mounting solution for the USRP1 device.
+
 
 +
Generally speaking, the selection of the USRP is based on performance requirements of the electrical components. However, the convenience of a rack-mounted solution may be an attractive feature that drives your decision. The USRP N200/N210, X300/X310 and N300/N310 can all be mounted in Ettus Research rack chassis. Up to four N200/N210 USRP devices can be mounted in the 3U chassis. Up to two X300/X310 or N300/N310 USRP devices can be mounted in the 1U chassis.  
  
 
'''Will my requirements become more demanding as I learn more about the USRP and RF systems?'''
 
'''Will my requirements become more demanding as I learn more about the USRP and RF systems?'''
One final thing to consider is how your requirements will change over time. While a lower-cost USRP device, such as the USRP B100, may meet your immediate requirements, it is possible that the USRP N200/N210 would be a more appropriate platform as you continue to develop more advanced RF systems. Key improvements to note in the higher-end USRP N200/N210 is the increased bandwidth, increased dynamic range, and MIMO capability.
 
  
Fortunately, UHD allows the user to develop a single application compatible with all USRP models. Within certain limitations, the code you develop to work on a USRP B100 will generally work on a USRP N200/N210. You must still consider variables such as sample rate, host interface bandwidth, and synchronization features to ensure compatibility.
+
One final thing to consider is how your requirements will change over time. While a lower-cost USRP device, such as the USRP B200/B200mini, may meet your immediate requirements, it is possible that the USRP N200/N210, N300/N310 or E320 would be a more appropriate platform as you continue to develop more advanced RF systems. Key improvements to note in the higher-end USRP N200/N210/X300/X310/N300/N310/E320 is the increased bandwidth, increased dynamic range, and MIMO capability.
 +
 
 +
Fortunately, UHD allows the user to develop a single application compatible with all USRP models. Within certain limitations, the code you develop to work on a USRP B2xx will generally work on any other USRP. You must still consider variables such as sample rate, host interface bandwidth, and synchronization features to ensure compatibility.
  
 
==Conclusion==
 
==Conclusion==
This application note presents the functional specifications of each USRP device sold by Ettus Research. The data from this document can be used to make an educated selection of the most appropriate USRP device for a particular user or application. If you have any additional questions, do not hesitate to contact us at sales@ettus.com.
+
This application note presents the functional specifications of each USRP device sold by Ettus Research. The data from this document can be used to make an educated selection of the most appropriate USRP device for a particular user or application. If you have any additional questions, do not hesitate to contact us at [mailto:sales@ettus.com sales@ettus.com].

Latest revision as of 15:56, 26 March 2019

Application Note Number

AN-881

Revision History

Date Author Details
2016-05-01 Neel Pandeya
Nate Temple
Initial creation


2019-03-26 Nate Temple Update

Abstract

This AN explores the USRP family at a high level, compares devices across several primary features, and walks the reader through the process of selecting a particular device for the their application.

USRP Product Selector

The USRP Product Selector will help you choose the Ettus Research USRP Software Defined Radio products that are the best fit for your application. Based on your answers to a series of questions, the USRP Product Selector will generate a PDF price quote and e-mail it to you. The Ettus Research sales team may follow up with you to answer any additional questions that you might have. If you would like a person to talk you through the USRP product selection process, please send an e-mail to sales@ettus.com.

Overview

This guide is provided by Ettus Research to help users select the most appropriate Universal Software Radio Peripheral (USRP™) for their specific application. In order to make the selection process as straightforward as possible, a table showing various features is provided as a basis for the selection process.

Understanding DSP Fundamentals

If you are new to the USRP family of products, software defined radio, or digital signal processing in general, it may be useful to perform some simulation of the signals you wish to manipulate before selecting USRP hardware. Simulating signals and algorithms in software frameworks such as GNU Radio or LabVIEW will ensure a proper understanding of various concepts, such as Nyquist theorem, ADC/DAC and limitations, for example. Understanding the basics of signal theory and digital signal processing is the first step towards understanding how to make the best use of an appropriate USRP model. The Suggested Reading page provides access to several resources that may be helpful in understanding the basics.

Common Applications

Table 1 shows USRP/daughterboard combinations commonly used in various application areas. While Table 1 can serve as a starting point for selecting a USRP device, Ettus Research recommends new users evaluate their application requirements against the specifications of the USRP devices. sections of this document will assist in the selection process.


Application Area Common USRP Model Common Daughterboard
PHY/MAC Research N200/N210 X300/X310 N300/N3101 WBX/SBX/UBX/CBX
Radar Research X300/X310 SBX/UBX
OpenBTS B200/B2101 X300/X310 E310/E3121 N200/N210 N300/N3101 E3201 WBX/SBX/UBX/CBX
Amarisoft LTE N200/N210 X300/X310 B2101 E3201 N300/N3101 WBX/SBX/UBX/CBX
Education B200/B2101 X300/X310 E310/E3121 N200/N210 N300/N3101 E3201 WBX/SBX/CBX/UBX
HF Communications N200/N210 X300/X310 LFRX/LFTX
Signals Intelligence X300/X310 N300/N3101 E3201 SBX/UBX
Distributed RF Sensors E310/E312 N300/N310 E320 N/A
Mobile Radios E310/E312 E320 N/A
MIMO X300/X310 N3101 SBX/UBX
Phased Array X300/X310 SBX/UBX
FPGA Computing X310 N3101 E3201 WBX/SBX/UBX/CBX
Embedded Computing E310/E312 E320 N/A
Small Form Factor (SWaP) B200mini/B205mini E310/E312 E320 N/A
Table 1 - Recommended USRP Selection for Various Application Areas

1 - The B2xx, E3xx and N3xx do not support swappable daughterboards

USRP Device Characteristics

Table 2 shows the key characteristics of all USRP models available from Ettus Research. The table is useful for determining the interface type, bandwidth capabilities, and synchronization mechanisms specified for each USRP model. You can use this information, and the requirements for the application in question, to select a USRP radio.


USRP Model Interface Total Host BW (MSPS 16b/8b) Daughterboard Slots ADC Resolution (bits) ADC Rate (MSPS) DAC Resolution (bits) DAC Rate (MSPS) MIMO Capable Internal GPS Disciplined Oscillator (Optional) 1 PPS/Ref Inputs
N210 GigE 25/50 1 14 100 16 400 Yes Yes Yes
N200 GigE 25/50 1 14 100 16 400 Yes Yes Yes
N300 1 GigE

10 GigE

153.6, 125, 122.88 2 16 153.6, 125, 122.88 14 153.6, 125, 122.88 Yes Yes Yes
N310 1 GigE

10 GigE

153.6, 125, 122.88 2 16 153.6, 125, 122.88 14 153.6, 125, 122.88 Yes Yes Yes
B200mini USB 3.0 61.44 N/A 12 61.44 12 61.44 No No Yes
B205mini USB 3.0 61.44 N/A 12 61.44 12 61.44 No No Yes
B200 USB 3.0 61.44 N/A 12 61.44 12 61.44 No Yes Yes
B210 USB 3.0 61.44 N/A 12 61.44 12 61.44 Yes Yes Yes
X300 USB 3.0

1 GigE

10 GigE

PCIe

200 2 14 200 16 800 Yes Yes Yes
X310 USB 3.0

1 GigE

10 GigE

PCIe

200 2 14 200 16 800 Yes Yes Yes
E310 Embedded 61.44 N/A 12 61.44 12 61.44 Yes No Yes
E312 Embedded 61.44 N/A 12 61.44 12 61.44 Yes No Yes
E320 Embedded

1 GigE

10 GigE

61.44 N/A 12 61.44 12 61.44 Yes Yes Yes
Table 2 - USRP Characteristics by Model


The following sections cover frequently asked questions in choosing a USRP device that’s right for your application.

Do I want to perform processing on a host PC, or operate the USRP device in a standalone fashion?

This is an obvious differentiator of the USRP Embedded Series. If you need the USRP to operate a USRP radio without a host PC, the USRP E310/E312/E320 is the most appropriate. The USRP E310/E312/E320 is ideal for applications that might require mobile transceivers or distributed RF sensors. Unless the user has a clear requirement for embedded operation, Ettus Research recommends the USRP N200, N210, B200, B210, X300, X310, N300 or N310. Developing with a host-based platform typically involves less risk and will require less effort to optimize various pieces of the software radio.

In many cases it may be easier to develop with a USRP B200/B210 or USRP N200/N210, then port the code to the USRP E310/E312/E320. The UHD (USRP Hardware Driver) enables this portability. You must also consider the different processing capabilities of the host machine and ARM processor used on the USRP E310/E312/E320.

Do I Need Synchronization and/or MIMO Capability?

Table 3 summarizes the synchronization features of each USRP device. Table 4 shows recommended solutions for MIMO systems of various sizes.

If you need MIMO capability for your application, Ettus Research recommends the USRP N200/N210, X300/X310, N300/N310 or E320. These units can be synchronized by providing a common time and frequency reference. Two USRP N200/N210s can be synchronized for MIMO operation with an Ettus Research MIMO cable. Alternatively, external 10 MHz reference and 1 PPS signals can be distributed to multiple USRP radios. With proper consideration for interface issues, it is possible to create MIMO system of arbitrary size with the USRP N200/N210, X300/X310, N300/N310 and E320.

The USRP B210, N300, E310/E312/E320 can serve a 2x2 MIMO capability because it has two integrated RF channels. When using the USRP B210 the available bandwidth is limited dependent upon the USB controller, and selected MIMO configuration. The USRP E310/E312's streaming bandwidth is limited to the 1 GigE interface to the ARM CPU. The USRP E320 supports streaming at full rate of 61.44 MS/s (SISO) or 30.72 MS/s (MIMO) via the 10 Gb interface. The USRP N300 supports streaming at 153.6 MS/s (SISO) and 125 MS/s (MIMO) via the 10Gb interface.


USRP Model BW Capability (MSPS w/ 16-bit) MIMO Capable Ext Ref. Input 1 PPS Input Internal GPS Disciplined Oscillator (Optional) Plug and Play MIMO
N200 25 X X X X X
N210 25 X X X X X
N300 153.6, 125, 122.88 X X X X X
N310 153.6, 125, 122.88 X X X X X
B200mini 61.44 X X
B205mini 61.44 X X
B200 61.44 X X X
B210 61.44 X X X X X
X300 200 X X X X X
X310 200 X X X X X
E310 61.44 X X X X
E312 61.44 X X X X
E320 61.44 X X X X X
Table 3 - Synchronization Capability of USRP Devices


USRP Model 2 x 2 MIMO 4 x 4 MIMO M x N MIMO
N200/N210 MIMO Cable OctoClock OctoClock
N300 Integrated Octoclock, White Rabbit Octoclock, White Rabbit
N310 Integrated Integrated Octoclock, White Rabbit
B200mini Not Recommended (SISO Only) Not Recommended Not Recommended
B205mini Not Recommended (SISO Only) Not Recommended Not Recommended
B200 Not Recommended (SISO Only) Not Recommended Not Recommended
B210 Integrated Not Recommended Not Recommended
X300 Integrated with Dual Daughterboards OctoClock OctoClock
X310 Integrated with Dual Daughterboards OctoClock OctoClock
E310 Integrated Not Recommended Not Recommended
E312 Integrated Not Recommended Not Recommended
E320 Integrated Octoclock Octoclock
Table 4 - Recommended Models for MIMO Systems


What Are My Bandwidth Requirements?

Many Bandwidth requirements can also be used to narrow down the USRP selection. As seen in the table, the USRP N200/N210 is capable of streaming up to 50 MS/s in each direction in 8-bit mode, and 25 MS/s in 16-bit mode. The USRP B200 is capable of streaming up to 61.44MS/s total in 16-bit, 12-bit or 8-bit modes. The USRP E320 is capable of streaming up to 61.44 MS/s in 16-bit mode. The X300/X310 is capable of streaming up to 200 MS/s per channel (400 MS/s total) with 160 MHz of usable bandwidth per channel. The N300/N310 is capable of streaming up 122.88, 125 or 153.6 MS/s per channel. The N300/N310 is limited to 2x2 operation when using a 153.6 MS/s sample rate.

However, if there is interest in transmit and/or receiving larger bandwidth signals such as 802.11, the USRP N200/N210, X300/X310, N300/N310 or E320 would be appropriate. Note these limitations are based on the data throughput provided by the corresponding interfaces. It is important to consider the performance of the processing platform, and the computational intensity of the application. The constraints of the processing platform are independent of the full capability of the Ettus Research USRP radio and UHD.

What interface do I prefer to work with?

Assuming you have narrowed the viable devices down based on bandwidth, MIMO and channel count requirements, it is possible to select a USRP device based on the interface.

In general, USB 3.0 ports are more plentiful on computers. This makes the USRP B200/B210/B200mini/B205mini slightly more usable at short ranges. The USRP N200/N210 requires a Gigabit Ethernet port and a PC typically only provides one such port. If internet access is required, the user will also need to plan for an additional network adapter. The USRP X300/X310, N300/N310 and USRP E320 all support streaming via either a 1 GigE or 10 GigE interface.

The Gigabit Ethernet interface of the USRP N200/N210 can operate over significantly longer ranges (typically up to 100ft) compared to the USB interface of the USRP B2xx. This makes it possible to operate the USRP radio it more remote locations further from the host computer. The GigE interface can be accessed via a Gigabit Ethernet switch, allowing access to multiple devices. However, Ettus Research recommends a homogeneous network without other devices, such as network routers attached.

The 10 Gigabit Ethernet interfaces of the USRP N300/N310, X300/X310 and E320 can be operated using multimode fiber optic cables with appropriate adapters which increases the distance from the host computer.

Will I develop custom IP for the USRP device’s FPGA?

While most users deploy their USRP devices in a stock configuration, many others customize the FPGA with their own functionality. For example, you may want to offload modulation, demodulation, or other PHY/ MAC operations to the FPGA. This reduces host processing requirements, and may allow data reduction before passing data over the host interface. A summary of the FPGAs used on each USRP model are shown in Table 5.


Model FPGA Vendor FPGA Series FPGA Part Number System Gates Logic Elements Logic Cells Slices DSP48's BRAM DCM's Free Tools?
N200 Xilinx Spartan 3A DSP XC3SD1800A 1800k - 37,440 16,640 84 260k 8 Yes
N210 Xilinx Spartan 3A DSP XC3SD3400A 3200k - 53,714 23,872 126 373k 8 No
B200mini Xilinx Spartan-6 XC6SLX75 - - 74,637 93,296 132 3,096k 12 Yes
B205mini Xilinx Spartan-6 XC6SLX150 - - 147,443 184,304 180 4,824k 12 No
B200 Xilinx Spartan 6 XC6SLX75 - - 74,637 93,296 132 3,096k 12 Yes
B210 Xilinx Spartan 6 XC6SLX150 - - 147,443 184,304 180 4,824k 12 No
X300 Xilinx Kintex-7 XC7K325T - - 321k 407,600 840 16,020k - No
X310 Xilinx Kintex-7 XC7K410T - - 406k 508,400 1540 28,620k - No
E310 Xilinx Zynq-7000 XC7Z020 - - 85k 106,400 220 560k - Yes
E312 Xilinx Zynq-7000 XC7Z020 - - 85k 106,400 220 560k - Yes
E320 Xilinx Zynq-7000 XC7Z045 - - 350k 437,200 900 19.2 Mb - No
N300 Xilinx Zynq-7000 XC7Z035 - - 275k 343,800 900 17.6 Mb - No
N310 Xilinx Zynq-7000 XC7Z100 - - 444K 554,800 2020 26.5 Mb - No
Table 5 - FPGA Resources


The USRP N200 and USRP N210 are great, generic platforms to experiment with FPGA development. However, the important difference between these two is the FPGA size, and requirements for Xilinx development tools. The USRP N200 includes a Xilinx Spartan XC3SD1800A FPGA. This FPGA is optimized for DSP capability, and the logic can be modified with free Xilinx ISE tools. The USRP N210 includes a Xilinx Spartan XC3D3400A FPGA. This FPGA provides nearly twice the resources, but requires a licensed seat of the Xilinx development tools for development.

Do I need flexible sample clock frequencies?

Some applications may benefit from a flexible sample clock frequency. The USRP E310/E312/E320 and USRP B200/B210/B200mini/B205mini include a flexible frequency clocking solution. This flexibility allows ideal sample clock frequencies to be used for various communications standards. For example, the GSM implementations commonly use a 52 MHz sample clock.

Do I want or need a rack-mountable solution?

Generally speaking, the selection of the USRP is based on performance requirements of the electrical components. However, the convenience of a rack-mounted solution may be an attractive feature that drives your decision. The USRP N200/N210, X300/X310 and N300/N310 can all be mounted in Ettus Research rack chassis. Up to four N200/N210 USRP devices can be mounted in the 3U chassis. Up to two X300/X310 or N300/N310 USRP devices can be mounted in the 1U chassis.

Will my requirements become more demanding as I learn more about the USRP and RF systems?

One final thing to consider is how your requirements will change over time. While a lower-cost USRP device, such as the USRP B200/B200mini, may meet your immediate requirements, it is possible that the USRP N200/N210, N300/N310 or E320 would be a more appropriate platform as you continue to develop more advanced RF systems. Key improvements to note in the higher-end USRP N200/N210/X300/X310/N300/N310/E320 is the increased bandwidth, increased dynamic range, and MIMO capability.

Fortunately, UHD allows the user to develop a single application compatible with all USRP models. Within certain limitations, the code you develop to work on a USRP B2xx will generally work on any other USRP. You must still consider variables such as sample rate, host interface bandwidth, and synchronization features to ensure compatibility.

Conclusion

This application note presents the functional specifications of each USRP device sold by Ettus Research. The data from this document can be used to make an educated selection of the most appropriate USRP device for a particular user or application. If you have any additional questions, do not hesitate to contact us at sales@ettus.com.