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Software Defined Radio (SDR) for Amateur Radio – An Overview
Steve Dick, K1RF
May 9, 2012
What is Software Defined Radio?
As defined in Wikipedia: A software-defined radio system, or SDR, is a
radio communication system where components that have been typically implemented in hardware (e.g. mixers, filters, amplifiers, modulators/demodulators, detectors, etc.) are instead implemented by means of software on a personal computer or embedded computing devices.
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What is Software Defined Radio? A basic SDR system may consist of a personal computer equipped with
a sound card, or other analog-to-digital converter, preceded by some form of RF front end. Significant amounts of signal processing are handed over to the general-purpose processor, rather than being done in special-purpose hardware. Such a design produces a radio which can receive and transmit widely different radio protocols (sometimes referred to as waveforms) based solely on the software used.
In the long term, software-defined radios are expected to become the dominant technology in radio communications.
R.F.Front End
High QualitySound Card
P.C., Laptop,Netbook, orEmbeddedprocessor
Antenna
3
I,Q
I,Q
Example architecture
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Some Distinctions
Modern conventional Radios are usually controllable via a computer with CAT or similar interfaces. These are Software Controlled radios, not software defined radios.
Modern conventional radios may use Digital Signal Processing for enhanced filtering for better performance than conventional filters and to eliminate multiple downconversions. These are NOT software defined radios.
Conventional radios having single sideband capability can feed audio to/from a PC for what is known as digital modes. This is real audio, not complex baseband I,Q. However, the digital mode modulation and demodulation can be considered software defined radio (modulation, demodulation, and detection functions)
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Look and feel of Software Defined Radio Does not look or feel like a real conventional radio. Uses a computer-based
graphical user interface. No knobs!!! Needs some getting used to after many years using a conventional radio. Getting the software set up and working properly can be a challenge. It is
definitely not plug and play and requires integrating multiple software packages
There are processing time lags on the P.C. (on the order of milliseconds). This is generally not a problem except when using Morse Code (CW). You can’t listen to your own signal and try to send Morse Code. Your brain gets confused from the time lag. A separate tone source with zero lag solves this problem
You can’t receive signals at the center of the spectrum. This is D.C. and soundcards don’t go down to D.C. Also, a lot of noise is picked up in this part of the spectrum (60 cycle hum, noise due to ground loops, etc) so you tune on either side of the spectrum center.
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First, a few basic principles (P1 of 3):1. Sampling basics
Sampling basicsIn 1933, Harry Nyquist discovered that to accurately recover all the componentsof a periodic waveform, it is necessary to sample a signal at twice the maximum bandwidth of the signal being measured. That minimum sampling frequency is called the Nyquist criterion. This may be expressed as: fs = 2 bw where fs is the sampling rate and bw is the bandwidth.
See the math isn’t sobad, is it?
In real life, a good rule of thumb is to use the 80% relationship:Bandwidth = 0.8 x ƒs/2 to allow for readily achievable filtering instead of “brick wall” filtering
Courtesy Pentek - Software Defined Radio Handbook
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First, a few basic principles (p 2 of 3):2. The mixer The mixer is basically a
multiplier (analog or digital) in which the local oscillator is multiplied by the incoming signal. For sine waves, the output signals are sum and difference frequencies of the local oscillator and the incoming signal frequencies.
One of the two signals is kept by filtering. The other signal is rejected by filtering. Any residual is known as an “image” and is undesireable
Local oscillator = 14.000 MHzIncoming carrier = 14.001 MHz
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First, a few basic principles (p 3 of 3):3. Selectivity: Q of a tuned circuit Q = Quality factor Q = F0/Delta F where
F = center frequency Delta F = bandwidth
Higher Q = narrower bandwidth or high selectivity
Lower Q = wider bandwidth or low selectivity
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Classic (Non-SDR) Radio – the Superheterodyne receiver
The conventional heterodyne radio receiver (A.K.A. Supersonic Heterodyne or Superheterodyne) shown has been in use for nearly a century. Let’s review the structure of the analog receiver so comparison to a digital receiver becomes apparent.
First the RF signal from the antenna is amplified, typically with a tuned RF stage that amplifies a region of the frequency band of interest.
This amplified RF signal is then fed into a mixer stage. The other input to the mixer comes from the local oscillator whose frequency is determined by the tuning control of the radio. The mixer translates the desired input signal to the IF (Intermediate Frequency) .
The IF stage is a bandpass amplifier that only lets one signal or radio station through. Common center frequencies for IF stages are 455 kHz and 10.7 MHz for commercial AM and FM broadcasts.
The demodulator recovers the original modulating signal from the IF output using one of several different schemes. For example, AM uses an envelope detector and FM uses a frequency discriminator.
In a typical home radio, the demodulated output is fed to an audio power amplifier which drives a speaker.
Classic Addison 5 AM table radioCirca 1940
I.F. frequency Trades offImage rejectionvs. selectivity
This diagram shows a single conversion (local oscillator plus mixer, IF Amp). Multiple conversions provide increased selectivity. So does DSP filtering used in modern designs.
Courtesy Pentek Software Defined Radio Handbook
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SDR Receiver Block Diagrams
A/D at front end at R.F. Then all digital conversion to baseband – but costly
The “High Priced Spread” – Direct Digital Conversion
The “Low Priced Spread” – soundcard-based
RF Tuner
AnalogRF Signal Tayloe
Detector
Dual flip-flop Divide by
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Digital Local Oscillator(DDS or SI570)
PC orEmbeddedprocessor
I,Q
AnalogDownconverter
I,Q
SoundCard
P.C.Or laptop
AnalogBasebandSamples
I,Q
DigitalBasebandSamples
Performsdecimation
A/D at back end with A/D conversion done with sound card. – low cost
Courtesy Pentek Software Defined Radio Handbook
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More on Digital Down Conversion
The “tuning knob” sets the digital local oscillator to the center of the baseband spectrum in the area of interest
The “Bandwidth” control sets the bandwidth of the low pass filter using different amounts of decimation. Wider bandwidths result in higher final output sample rates; narrower bandwidths result in lower final output sample rates. Low pass filter can typically be adjusted from megahertz to kilohertz
Typical value 122.88 MHzSample rate
Typical value 96 KHzbasebandSample rate(Sound card)
Courtesy Pentek Software Defined Radio Handbook
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The RF Front-end generates baseband complex (I,Q) audio
R.F.Front End
AntennaA/D
Converter (sound card)
and processing
(PC)
Baseband I,Q
Positive frequencies
NegativeFrequencies
• Band limited by RF front end. • Typically limited to the KHz to 10s of KHz range
Zero frequency
Bandwidth approaches +/- 48KHz with good soundcards
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Seminal four-part article series on Software Defined Radio, QEX magazine 2002
A Software Defined Radio for the Masses Part 1 A Software Defined Radio for the Masses Part 2 A Software Defined Radio for the Masses Part 3 A Software Defined Radio for the Masses Part 4
Written by Gerald Youngblood, K5SDR, now CEO and President of FlexRadio Systems. In April of 2003 he founded FlexRadio Systems to market the first Software Defined Radio products to the Amateur Radio market
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SDR Receiver Software Architecture
Fists of FourierCourtesy garage-shoppe.com
The Fast Fourier Transform (FFT) does all the heavy lifting in SDR softwareto implement high performance filters in place of expensive hardware filters
Courtesy SDR for the masses, Part 1
Give me an I, give me a Q, and I can demodulate anything!!!
15
Examples of RF Front Ends
integrates all I/Q data and hardware control over a single FireWire ® (IEEE-1394a) connection to a user provided computer.
Top Performing Narrow-Spaced Two-Tone 3 rd Order IMD Dynamic Range of ~100 dB on 14 MHz Using a 2 KHz Spacing
Narrow Spaced 3 rd Order Intercept Point: Greater Than 39 dBm at 2 KHz Tone Spacing.
Integrated ultra high quality 192 KHz 24-bit ADC and DACs
Full Duplex Operation for Simultaneous Transmit and Receive
High Stability TCXO 100 watts PEP on 160 to 6 meters Cost $2799
High Performance Software Defined Radio at its Best!
FlexRadio Systems introduces the FLEX-5000A™ ultra high performance Software Defined Radio transceivers. The FLEX-5000A integrates all I/Q data and hardware control over a single FireWire ® (IEEE-1394a) connection to a user provided computer.
Flex 5000A “The Cadillac of SDR”www.flexradio.com
Rear view
16
Examples of SDR RF Front Ends c’d
Up to 5 band transceiver 10 watts out minimum on all bands QSD and QSE-based architecture Semi-kit. All Surface mount
components preassembled IP3 30-32dBm MDS is -116 to -122dBm. RF
preamplifier on: MDS is from -130 to -133dBm.
Image rejection: -35 to -60 dB [hardware], better than 60dB [software]
RX sensitivity: 0.15-0.2uV for 10 dB S/N ratio. Max S/N measured: 70dB.
SFDR (Spurious free dynamic range) is 93-100dB these results are with signals spaced 5 kHz or more.
Built-in extras incl. CW keyer Cost $299 less heatsink. You provide
your own chassis,soundcard,PC
Genesis Radio G11www.genesisradio.com.auhttp://groups.yahoo.com/group/GenesisRadio/Sample youtube video (SSB reception)
PCB ~ 8” X 8”
Built by K1RF
17
Examples of SDR RF Front Ends c’d
UHF SDR Yahoo GroupWB6DHW.comUHFSDR Parts cost - ~$200.00
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Examples of RF Front Ends c’d
Full duplex transceiver Architecture based on
Front end high speed ADC and FPGA based DDC and DUC
Built-in audio codec Very high performance ~ ½ watt output Connects to PC via
Ethernet Approximate cost will be
~900.00
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“We don’t need no Stinkin’ PCs” Several companies or amateur radio groups have developed self-
contained SDR transceivers that don’t use PCs. They are based on very low cost DSP microcomputers that have
significant digital signal processing capabilities, used in conjunction with low cost audio CODECs and a low cost programmable oscillator.
Example: Microchip dsPIC33FJ128MC804 “Digital Signal Controller”. Cost ~$6 qty 1. 40MIPS, I2C, ADC and DAC, PIO
Low cost helper chips: TI audio codec TLV320AIC3204IRHB Silicon Labs Si570 10 Mhz TO 1.4 Ghz I2C Programmable XO/VCXO
There is also the first ever standalone digital modem,the NUE-PSK, a digital modem for PSK31 and RTTY field use ... without a PC!
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“We don’t need no Stinkin’ PCs”
www.sdr-cube.comOverview slidesComplete kit $424
SDR Cube Transceiver SDR2GO
kit ~$70.00Austin QRP clubSee Austin Summerfest 2010
NUE-PSK Digital Modem
www.nue-psk.comFeatured inQEX Mar-Apr 2008Base price $220
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“We don’t need no Stinkin PCs”Elecraft KX3 –Where high volume commercial SDR is heading
KX3 Self-contained operation
Audio out to soundcard/PCFor use with 3rd party software for SDR apps and digital modes
• 160-6 meters, SSB/CQ/DATA/AM/FM modes• 10W PEP (100W with KXPA 100 amp)• Only 1.5 pounds (0.7Kg)• Current drain as low as 150 mA on receive• Ultra compact portable/mobile/home• Internal 8 - AA battery holder• Receiver performance rivals the best conventional transceivers•Base price $899 kit, $999 assembled
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Basic low cost RF Front End Approach:The amazing Tayloe detector
Invented by Dan Tayloe, Patent no. 6,230,000, May 2001. It has four unique properties:
▪ Less than 1 db of conversion loss!!!▪ “Free” tracking bandpass selectivity (Q = 3,500 at 7 MHz), with a user
definable bandwidth▪ Very high dynamic range - A high 3rd order intercept (+30 dbm).▪ An extremely compact and simple design using low cost components
compared to other zero IF I-Q quadrature detectors
Conventional passive mixers generate sum and difference frequencies. Therefore, the conversion loss using an ideal mixer is at least 3 db, with a typical conversion loss of 4-6 db in practice
The Taylor detector produces onlya difference frequency!!!
Basic design useful into the GHz range
A.K.A. Quadrature sampling Detector (QSD)
23
The amazing Human Ear
The human ear has about 130 dB of dynamic range. Sound cards strive to haveundetectable distortion to the human ear for hi-fi applications
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Why is this important? Because sound cards are designed to produce undetectable distortion to the human ear and have advanced significantly over the last few years in achieving that goal.
The standard for today’s audio reproduction and studio audio processing is 24 bits at 96 kbits/sec sampling rate, or even 192 kbits/sec sampling rate.
24 bit soundcards come in many flavors and qualities, few if any approaching the theoretical maximum dynamic range of human hearing
Soundcard maximum theoretical dynamic range: 6.02 dB x 24 bits - 3 dB = 141.48 dB. Lets shave 20 dB off this number for worst case realism: 121 dB dynamic range. This dynamic range has undetectable distortion at normal listening levels. When applied to SDR applications, This is still an impressive dynamic range and approaches the dynamic range of the best military radios if the RF front end had perfect linearity and steps are taken to avoid noise contributing ground loops.
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Representative sound cards used for SDR applications
Take your pick – everyone has their favorites Can be mounted in PC or used via USB (Preferred for
portability between different PCs or laptops) Representative list with some user comments:
Emu 0202, works well but can be a bit touchy to set up correctly. M- audio 2496 , works well easy set up.
Essence stx pic- e, excellent and easy set up. M-audio delta44, poor, pain in the *** to set set up Sdr widget, works well. (kit) Ederol FA66 Sound Blaster X-FI surround 5.1 pro (good performance at low
cost - ~ 49.00)
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Softrock Lite II Schematic
This is the entire schematic for a very high performance single bandRF Front end – Incredible!!! Representative of Tayloe detector (Quadrature Sampling Detector) - based RF front ends
Bandpass filter
USB power
XTAL oscillator/buffer
Dual flip-flop Divide by 4
Tayloe Detector:CMOS analog switch,Capacitors,Dual low noise op-amp
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An inexpensive SDR sampler kit-The Softrock_40_R for $19.00
http://www.kb9yig.com/To order
Join yahoo group:http://groups.yahoo.com/group/softrock40/
To check on availability (they go fast!!)
See http://www.qrz.lt/ly1gp/SDR/For a similar low cost SDR samplerTinySDR for 80M band
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We don’t even need no stinkin’ hardware!!
Latest SDRs are moving to client-server architectures Get on the internet and use someone else’s Antennas
and RF baseband converter!!
R.F.Front End
High QualitySound Card
P.C. based server(Linux)
Antenna
I,Q
I,Q
P.C. based client
(Linux or windows)
Internet
Yay! It works!
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Log in to a remote server from your windows PC or laptop for free!! Internet-based: No software required!!: www.websdr.org
More sophisticated but requires software download; Go to the following link for description: http://napan.ca/ghpsdr3/index.php/QtRadio_on_Windows
Download a zipped executable at:
http://napan.com/ve9gj/qtradio-master.zip Load to a new folder and extract contents Run QTRdio.exe. Allow access if windows firewall blocks or only provides
limited access Click on Receiver /Configure and select audio card Click on Receiver/Quick server list, highlight a server and connect (try
different ones, some are more capable than other, some may not be operating)
You can now control the other person’s radio over the internet!!
There is also an Android Client for SDR servers!!
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QT Radio screenshot
You can select band, tune it with your mouse scroll wheel, select operatingmode, look at received signal strength on S-meter, set control parameters, etcPretty cool to let you try SDR with just a PC and internet connection
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GSDR screenshotVariant of PowerSDR software
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Digital Modes- So many modes, so little time
PSK31, PSK63, SSTV, HD SSTV, RTTY, MFSK16, MFSK32, MT63, Hellschreiber, Olivia, Packet, PACTOR , Throb, Contestia, JT6M, Ham DRM, Domino, DominoEX, DominoF, WSPR, ROS, SITOR, SITOR-A, SITOR-B, Swedish ARQ, Clover, CHIP, ALE, PAX, PAX-2, STANAG, HFDL, NAVTEX, SYNOP, COQUELET, AOR, WinDRM….
Between amateur and commercial services, there are tens of modes, perhapsapproaching 100!!!
Courtesy George Heron, N2APB
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Using Digital modes with SDR Software
SDR software can feed other third party software using other internal software interconnects for IQ audio transfer andreceiver/transmitter control.
SDR software package
Third Party software package
(modulation,Demodulatio
n,Control)
Baseband I,Q
Baseband I,Q
Virtual audio cable
Virtual Com Port(Control)
Rocky, PowerSDR IQ, etc. Ham Radio Deluxe, FLDIGI, Digipan, etc.
34
Using digital modes with a conventional radio
A (good) Sound Card(An external USB sound card is most flexible)
A (fast) PCSSB transceiver
Software: - FLDIGI, …
Once you’ve wired your station for one HF mode, you can work another by just selecting a different mode in the software.
Courtesy George Heron, N2APB
35
CW Skimmer, developed by Alex Shovkoplyas, VE3NEA
Seen above is a 25 KHz spectrum during a “Pileup”. This program simultaneously detects and decodes up to 128 Morse Code signals, finds and decodes the amateur radio call signs simultaneously across the displayed spectrum
Use of this program has been banned from use in many amateur radio contests due to providing too great an advantage. CW Skimmer can be downloaded here
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PSK31 or or "Phase Shift Keying, 31 baud
• The Undisputed King!• Used to conduct
realtimeKeypoard to keyboard textchat
• “Phase Shift Keying” is the the most popular of the newer digital modes.
• Wealth of information on the web regarding BPSK (Binary PSK) and QPSK (Quadrature PSK)
• Because bandwidth only 31Hz, many signals can fit into the same bandwidth occupied by an SSB signal (2.4kHz approx.).
• Quite common to see 15 or more signals on a 2.5kHz waterfall display.
• Invented by Peter Martinez (G3PLX), Debuted in 1999
• Most popular HF digital mode• Heard near: 3.580, 7.070,
14.070, 21.070 MHz
Courtesy George Heron, N2APB
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JT65
• Developed originally as part of the WSJT weak signal modes software package by Joe Taylor, K1JT, but is now open source
• Can also be decoded by other packages, such as MultiPSK. • Has found a use on HF and can be found around 14.076MHz and 21.076MHz
amongst others. • Signals that are virtually inaudible can give perfect copy so its performance is
excellent on the noisy HF bands. • Transfer rate is slow, as are most modes that excel in low signal decoding.
Courtesy George Heron, N2APB
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And Now for Something Completely Different
Software Defined Radio Software Demos:(Video, HDSDR)
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Reference Links
DK3QN Example self-extracting WINRAD software and .wav files with instructions HDSDR (former WinradHD) is an advanced version of Winrad SDR Sharp a simple, small and fast PC-based DSP application for
Software Defined Radio. It’s written in C# with both object design correctness and performance in mind
Signals, Samples and Stuff, a DSP tutorial parts 1, 2, 3, and 4 QEX Mar April 1998 Comparison of “conventional”, “DDC based” and “soundcard based” receivers Quadrature Signals, complex, not complicated on the DSPGURU.com site Soundcard SDR Software Virtual Audio Cable software by Eugene Muzychenko [ $35] Software Defined Radio Explained – Fists of Fourier Parts 1, 2, 3, and 4 explains
how the QSD detector works VSP manager by Steve Nance - virtual com port software, free but requires amateur
radio call sign) FLDIGI digital mode software Digipan for PSK31 and PSK63 Ham Radio Deluxe, a widely used comprehensive program suite for CAT control, and
digital modes MultiPSK digital mode software The VITA Radio Transport Protocol for SDR architectures future standard in work